15051	MI0000001	cel-let-7	Caenorhabditis elegans let-7 stem-loop	UACACUGUGGAUCCGGUGAGGUAGUAGGUUGUAUAGUUUGGAAUAUUACCACCGGUGAACUAUGCAAUUUUCUACCUUACCGGAGACAGAACUCUUCGA	let-7 is found on chromosome X in Caenorhabditis elegans [1] and pairs to sites within the 3' untranslated region (UTR) of target mRNAs, specifying the translational repression of these mRNAs and triggering the transition to late-larval and adult stages [2]. 	3
15052	MI0000002	cel-lin-4	Caenorhabditis elegans lin-4 stem-loop	AUGCUUCCGGCCUGUUCCCUGAGACCUCAAGUGUGAGUGUACUAUUGAUGCUUCACACCUGGGCUCUCCGGGUACCAGGACGGUUUGAGCAGAU	lin-4 is found on chromosome II in Caenorhabditis elegans [1] and is complementary to sequences in the 3' untranslated region (UTR) of lin-14 mRNA. lin-4 acts to developmentally repress the accumulation of lin-14 protein. This repression is essential for the proper timing of numerous events of Caenorhabditis elegans larval development [2]. 	3
15053	MI0000003	cel-mir-1	Caenorhabditis elegans miR-1 stem-loop	AAAGUGACCGUACCGAGCUGCAUACUUCCUUACAUGCCCAUACUAUAUCAUAAAUGGAUAUGGAAUGUAAAGAAGUAUGUAGAACGGGGUGGUAGU	miR-1 was independently identified in C. elegans [1,2] and Drosophila melanogaster (MIR:MI0000116) [3].  The sequence is also conserved in C. briggsae (MIR:MI0000493). 	3
15054	MI0000004	cel-mir-2	Caenorhabditis elegans miR-2 stem-loop	UAAACAGUAUACAGAAAGCCAUCAAAGCGGUGGUUGAUGUGUUGCAAAUUAUGACUUUCAUAUCACAGCCAGCUUUGAUGUGCUGCCUGUUGCACUGU		3
15055	MI0000005	cel-mir-34	Caenorhabditis elegans miR-34 stem-loop	CGGACAAUGCUCGAGAGGCAGUGUGGUUAGCUGGUUGCAUAUUUCCUUGACAACGGCUACCUUCACUGCCACCCCGAACAUGUCGUCCAUCUUUGAA		3
15056	MI0000006	cel-mir-35	Caenorhabditis elegans miR-35 stem-loop	UCUCGGAUCAGAUCGAGCCAUUGCUGGUUUCUUCCACAGUGGUACUUUCCAUUAGAACUAUCACCGGGUGGAAACUAGCAGUGGCUCGAUCUUUUCC		3
15057	MI0000007	cel-mir-36	Caenorhabditis elegans miR-36 stem-loop	CACCGCUGUCGGGGAACCGCGCCAAUUUUCGCUUCAGUGCUAGACCAUCCAAAGUGUCUAUCACCGGGUGAAAAUUCGCAUGGGUCCCCGACGCGGA		3
15058	MI0000008	cel-mir-37	Caenorhabditis elegans miR-37 stem-loop	UUCUAGAAACCCUUGGACCAGUGUGGGUGUCCGUUGCGGUGCUACAUUCUCUAAUCUGUAUCACCGGGUGAACACUUGCAGUGGUCCUCGUGGUUUCU		3
15059	MI0000009	cel-mir-38	Caenorhabditis elegans miR-38 stem-loop	UCUGUGAGCCAGGUCCUGUUCCGGUUUUUUCCGUGGUGAUAACGCAUCCAAAAGUCUCUAUCACCGGGAGAAAAACUGGAGUAGGACCUGUGACUCAU		3
15060	MI0000010	cel-mir-39	Caenorhabditis elegans miR-39 stem-loop	UAUACCGAGAGCCCAGCUGAUUUCGUCUUGGUAAUAAGCUCGUCAUUGAGAUUAUCACCGGGUGUAAAUCAGCUUGGCUCUGGUGUC	The excised miRNA sequence was initially predicted [1], and confirmed later by sequencing [3]. 	3
15061	MI0000011	cel-mir-40	Caenorhabditis elegans miR-40 stem-loop	UCCUGUCCGCACCUCAGUGGAUGUAUGCCAUGAUGAUAAGAUAUCAGAAAUCCUAUCACCGGGUGUACAUCAGCUAAGGUGCGGGUACAGGU		3
15062	MI0000012	cel-mir-41	Caenorhabditis elegans miR-41 stem-loop	GGGUCCCAGAGACCUUGGUGGUUUUUCUCUGCAGUGAUAGAUACUUCUAACAACUCGCUAUCACCGGGUGAAAAAUCACCUAGGUCUGGAGCCUCCU		3
15063	MI0000013	cel-mir-42	Caenorhabditis elegans miR-42 stem-loop	UUCGCGGACCUUUGUGGGUGUUUGCUUUUUCGGUGAAGUUGUCUUCCGUAGCUUCUUCUUCACCGGGUUAACAUCUACAGAGGUCCAAAAAGGGG	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [5]. 	3
15064	MI0000014	cel-mir-43	Caenorhabditis elegans miR-43 stem-loop	UAUUGGCACUAGUCGCCCGUGACAUCAAGAAACUAGUGAUUAUGCCAAACCACAGGGACAUAUCACAGUUUACUUGCUGUCGCGGGCGGUGCUGAGUU		3
15065	MI0000015	cel-mir-44	Caenorhabditis elegans miR-44 stem-loop	GAGAAAAUGGCCAAUCUGGAUGUGCUCGUUGGUCAUAGACGUCAACACGAACUGUUCAUAUGACUAGAGACACAUUCAGCUUGGCCUGCUUCUCUA		3
15066	MI0000016	cel-mir-45	Caenorhabditis elegans miR-45 stem-loop	CACCAUGUGCCACGCUGGAUGUGCUCGUUAGUCAUAAUAUCCUCCACAAAGCAAGGACUAUGACUAGAGACACAUUCAGCUUGGCGCCGAAUGCAU		3
15067	MI0000017	cel-mir-46	Caenorhabditis elegans miR-46 stem-loop	CUGAGGUGAAGCUGAAGAGAGCCGUCUAUUGACAGUUCAAGACCACGAGUCGUUGUGUGCUGUCAUGGAGUCGCUCUCUUCAGAUGAUCCGGUCAAU		3
15068	MI0000018	cel-mir-47	Caenorhabditis elegans miR-47 stem-loop	GAGAGCCGACUGAAACUGAAGAGAGCAGUCUAUUGACAGUCGGUUACUCGAAAUCUUUACUGUCAUGGAGGCGCUCUCUUCAGAUGAUGUCUGGCCC		3
15069	MI0000019	cel-mir-48	Caenorhabditis elegans miR-48 stem-loop	AAACUCCCGGGAACUUGAGGUAGGCUCAGUAGAUGCGAAUUGAACGGUAUCUCACAUCCACCAGCCUAGCUCGCAUUCCCAGAGUUUACGGUAUUGUU		3
15070	MI0000020	cel-mir-49	Caenorhabditis elegans miR-49 stem-loop	UUUUGAAAAAGACCACCGUCCGCAGUUUGUUGUGAUGUGCUCCAAGCAAUCAUGAGUCUGAAGCACCACGAGAAGCUGCAGAUGGAGGUUCUGAUUU		3
15071	MI0000021	cel-mir-50	Caenorhabditis elegans miR-50 stem-loop	CUGCCCGCCGGCCGCUGAUAUGUCUGGUAUUCUUGGGUUUGAACUUCCAGCGUUGAACCCGCAUAUUAGACGUAUCGACGGCCGGCGGGGCAGGUAAUG	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [3]. 	3
15072	MI0000022	cel-mir-51	Caenorhabditis elegans miR-51 stem-loop	GUCCGAAAAGUCCGUCUACCCGUAGCUCCUAUCCAUGUUACUGGUCAAAAAGUGAACAUGGAAGCAGGUACAGGUGCACGGCGAGUAGGGUCAUGAAGCU		3
15073	MI0000023	cel-mir-52	Caenorhabditis elegans miR-52 stem-loop	UCCAACUCUAACAGUCCACCCGUACAUAUGUUUCCGUGCUUGACAGCGAAGCUCAAUCACGUUACAAUGAAAGGGUAGCCGGUUAUUGAAGUUGGGUCUU		3
15074	MI0000024	cel-mir-53	Caenorhabditis elegans miR-53 stem-loop	CCGAUUCUGACAGUCCACCCGUACAUUUGUUUCCGUGCUUGACUUCAAAGCUCAAUCACGGCACAAUAUAUGGGUCGCCAGUCAUUGUAGUCGGAAUUU		3
15075	MI0000025	cel-mir-54	Caenorhabditis elegans miR-54 stem-loop	GUGAGUCGCGCUCUGACUAGGAUAUGAGACGACGAGAACAUUGCUUUUUUAAAAGACUUGUACCCGUAAUCUUCAUAAUCCGAGUCAGGGCUAGCUGAC		3
15076	MI0000026	cel-mir-55	Caenorhabditis elegans miR-55 stem-loop	AGAUUUGGAACUUAAUGGGACUCGGCAGAAACCUAUCGGUUAUACUUUUUGGAUAUGCUAUACCCGUAUAAGUUUCUGCUGAGCCCCUUAUUCCUGUU		3
15077	MI0000027	cel-mir-56	Caenorhabditis elegans miR-56 stem-loop	GAGCCAGUGUCUGUUCUUGGCGGAUCCAUUUUGGGUUGUACCUCAUCCUAAAUUUGACGGUACCCGUAAUGUUUCCGCUGAGAACCGACUGUGCACC		3
15078	MI0000028	cel-mir-57	Caenorhabditis elegans miR-57 stem-loop	AUCGACAUGCUCGUCUACCCUGUAGAUCGAGCUGUGUGUUUGAAACAAUCAUACACGAGCUAGACUACAAGGUGCACGAACAAACCGAAGAUUUAUGAA		3
15079	MI0000029	cel-mir-58	Caenorhabditis elegans miR-58 stem-loop	GCUCGUCAUAUCCAUUGCCCUACUCUUCGCAUCUCAUCACUUCGUCCAAUACCAUAGGGAUGAGAUCGUUCAGUACGGCAAUGGACUGAGCUAGAGU		3
15080	MI0000030	cel-mir-59	Caenorhabditis elegans miR-59 stem-loop	AGUUGAUCUAGAUAUGACAUCGUCCUGAAAACGAAACGGAACAAAAGUUCAAGAUAUUGAUUUCGAAUCGUUUAUCAGGAUGAUGUGAUUAAAAUCAACU		3
15081	MI0000031	cel-mir-60	Caenorhabditis elegans miR-60 stem-loop	CUCGAAAACCGCUUGUUCUUGAACUGGAAGAGUGCCAUAAAAUCAUGACAAAGUACGUGAUAUUAUGCACAUUUUCUAGUUCAAGACUUGAGAAAUCG		3
15082	MI0000032	cel-mir-61	Caenorhabditis elegans miR-61 stem-loop	UUCCAUUAUCGCUGAACCUCGAGAUGGGUUACGGGGCUUAGUCCUUCCUCCGUAUGGCAAUGACUAGAACCGUUACUCAUCUCGAGGUUUCGGUGAU	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [4]. 	3
15083	MI0000033	cel-mir-62	Caenorhabditis elegans miR-62 stem-loop	GUGAGUUAGAUCUCAUAUCCUUCCGCAAAAUGGAAAUGAUAUGUAAUCUAGCUUACAG		3
15084	MI0000034	cel-mir-63	Caenorhabditis elegans miR-63 stem-loop	UCAACAAGCAGACACAAUUUCUAACUCGUCGGUAGUCAUCGUUCUAGCUGAAAAGGACACUAUGACACUGAAGCGAGUUGGAAAUAGUGGUUCUACUUGAGCAA		3
15085	MI0000035	cel-mir-64	Caenorhabditis elegans miR-64 stem-loop	CUCCCCGCUGACCUCGCCGAAUAUGACACUGAAGCGUUACCGAACCGUUUUCCCACACCUGGAUUCGGUGCAACGAUCAGUGGCAUGCUCGGCUAGCGCCAGUUAAGUAU		3
15086	MI0000036	cel-mir-65	Caenorhabditis elegans miR-65 stem-loop	AUGGAGCCUUCGCCGAUUAUGACACUGAAGCGUAACCGAACACCAUAUUUUGAGAUUCUGCUACGCGCAGUGCCAUGCUCGGCGCGUUGGCUCCAUUAAA		3
15087	MI0000037	cel-mir-66	Caenorhabditis elegans miR-66 stem-loop	CCACAAAAAUGCCAUACAUGACACUGAUUAGGGAUGUGAUGAAUGUUAAGAUCCCGAUCAAAUUCCUAACGGUGUCAAACAUGGCGUAUGUGGUUGUAG		3
15088	MI0000038	cel-mir-67	Caenorhabditis elegans miR-67 stem-loop	GAUCAAAGAUUCGUCGAUCCGCUCAUUCUGCCGGUUGUUAUGCUAUUAUCAGAUUAAGCAUCACAACCUCCUAGAAAGAGUAGAUCGAUUUUAAAACUU		3
15089	MI0000041	cel-mir-70	Caenorhabditis elegans miR-70 stem-loop	UCAAAAUAAAACGAUGAAAACUAUCGAAAUACUAUCGACGAAUAACACUUAUGAAGAAAUGUAAUACGUCGUUGGUGUUUCCAUAGUUUGAAUUGUUUAU		3
15090	MI0000042	cel-mir-71	Caenorhabditis elegans miR-71 stem-loop	GUCUGCUCUGAACGAUGAAAGACAUGGGUAGUGAGACGUCGGAGCCUCGUCGUAUCACUAUUCUGUUUUUCGCCGUCGGGAUCGUGACCUGGAA		3
15091	MI0000043	cel-mir-72	Caenorhabditis elegans miR-72 stem-loop	AGGUCCCGUCAGAGCUAGGCAAGAUGUUGGCAUAGCUGAAUGAUCGCUAUAACAACUAUCAGCUUCGCCACAUUCUGCCACGCACUGAUGUGAGGACCU	The expression of C. elegans miR-72 was confirmed by PCR amplification, cloning and sequencing. The predicted hairpin precursor sequence presented here is supported by conservation in C. elegans and C. briggsae (MIR:MI0000751), and differs from that shown in [1] (Uwe Ohler, pers. comm.).  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [5]. 	3
15092	MI0000044	cel-mir-73	Caenorhabditis elegans miR-73 stem-loop	CAGUGAGAGUCCCACACACGACUGGACUUCCAUAUCGAGCCACAGCUAUCAACGAAUUUGCUGGCAAGAUGUAGGCAGUUCAGUUGUGCGUUUAUGGAG		3
15093	MI0000045	cel-mir-74	Caenorhabditis elegans miR-74 stem-loop	AAAUGGUUCAAAAAACGUUCGGGCUUCCAUCUCUUUCCCAGCCUACAUCUCAACCUGGGCUGGCAAGAAAUGGCAGUCUACACGUUUUUCAACCAAA		3
15094	MI0000046	cel-mir-75	Caenorhabditis elegans miR-75 stem-loop	UUCUUGUUGCUUUGAAGAAUUGCAGUCGGUUGCAAGCUUAAAUACAAAUCCGAAUUGUUAUUAAAGCUACCAACCGGCUUCAAGUCUGAAAGAGCAG		3
15095	MI0000047	cel-mir-76	Caenorhabditis elegans miR-76 stem-loop	AUUUCAGCUCCUGUCUGGGCUUCACAAUAGUCGAAUACCUUAAAUUUCAAAAUUUGGAUAUUCGUUGUUGAUGAAGCCUUGAUGGGGGUGAGAAAGA		3
15096	MI0000048	cel-mir-77	Caenorhabditis elegans miR-77 stem-loop	GCAUCUGCCAAACCGCCCGUUUGGAUGGUUGUGCUCUGAGGAAAUACGCACAGAAUGUCAUUUCAUCAGGCCAUAGCUGUCCAAAUUGGUAUAGAGUUUG		3
15097	MI0000049	cel-mir-78	Caenorhabditis elegans miR-78 stem-loop	AAUAAAAUAUAUUGUUUCAUAGUGUCCGUAAAAUAACUAGAUUUAUUUUGUAAAAACUAUUGGAGGCCUGGUUGUUUGUGCUGGAAUGUUUCGAGA		3
15098	MI0000050	cel-mir-79	Caenorhabditis elegans miR-79 stem-loop	UAGUAGACAUUCUCCGAUCUUUGGUGAUUCAGCUUCAAUGAUUGGCUACAGGUUUCUUUCAUAAAGCUAGGUUACCAAAGCUCGGCGUCUUGAUCUAC		3
15099	MI0000051	cel-mir-80	Caenorhabditis elegans miR-80/miR-227 stem-loop	AUGGACACUCGUUCGCUCAGCUUUCGACAUGAUUCUGAACAAUCCGCAAGCCCAUGUUGUUGAGAUCAUUAGUUGAAAGCCGAAUGAUCAGAGAUAUC	mir-80 is conserved in C.briggsae (MIR:MI0000518) [1].  Reference [3] reports the identification of miR-227, which appears to be expressed from the 5' arm of the same precursor. 	3
15100	MI0000052	cel-mir-81	Caenorhabditis elegans miR-81 stem-loop	AUCAGUGCCAUCGUGCCCAACAGUCGGUUUUCACCGUGAUCUGAGAGCAAUCCAAAAAUGCUUUUCUGAGAUCAUCGUGAAAGCUAGUUGUUGGUCUACGGGCUUUUG		3
15101	MI0000053	cel-mir-82	Caenorhabditis elegans miR-82 stem-loop	GAAAUAGGUUCUUUUAGCAACCGGUUUUCUCUGUGAUCUACAGAAUGACAGCUAAUCGUCUGAGAUCAUCGUGAAAGCCAGUUGUUUUUAUGAACUC		3
15102	MI0000054	cel-mir-83	Caenorhabditis elegans miR-83 stem-loop	AGCACCACUCGGAACCACUGAAUUUAUGUGUGUACUUGACGGCCAACAAGAGCAUCGAUCUAGCACCAUAUAAAUUCAGUAAUUUCGCGUCGAGAGCU		3
15103	MI0000055	cel-mir-84	Caenorhabditis elegans miR-84 stem-loop	GUGGCAUCUGAGGUAGUAUGUAAUAUUGUAGACUGUCUAUAAUGUCCACAAUGUUUCAACUAACUCGGCUGUUCU		3
15104	MI0000056	cel-mir-85	Caenorhabditis elegans miR-85 stem-loop	UAUAGAAUUUUGGCGUCGGAGCCCGAUUUUUCAAUAGUUUGAAACCAGUGUACACAUAAAUGGUUACAAAGUAUUUGAAAAGUCGUGCUCUGAAAAUGAAUUCUUA		3
15105	MI0000057	cel-mir-86	Caenorhabditis elegans miR-86 stem-loop	CGUGUCCACGCCGUCUAAGUGAAUGCUUUGCCACAGUCUUCGAUGUUCUGAAAUGAAGCCUGGGCUCAGAUUCGCUUAGGCCGGAGUUUGACACGGCA		3
15106	MI0000058	cel-mir-87	Caenorhabditis elegans miR-87 stem-loop	GGUUGUGCCAUCCGGCCGCCUGAUACUUUCGUCUCAACCUCGCUGUCAGAUUGGUCGUAGGUGAGCAAAGUUUCAGGUGUGCCGGAACACACCC	mir-87 is has found to be most abundant in the L1 stage of larval development in Caenorhabditis elegans. mir-87 orthologues have been found in C. briggsae, Drosophila melanogaster and humans [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [4]. 	3
15107	MI0000059	cel-mir-90	Caenorhabditis elegans miR-90 stem-loop	GGGCGCCAUUUCGAGCGGCUUUCAACGACGAUAUCAACCGACAACUCACACUUUUGCGUGUUGAUAUGUUGUUUGAAUGCCCCUUGAAUUGGAUGCCA	mir-90 is has found to be most abundant in the L1 stage of larval development in Caenorhabditis elegans [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [4]. 	3
15108	MI0000060	hsa-let-7a-1	Homo sapiens let-7a-1 stem-loop	UGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUA	let-7a* cloned in [6] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
15109	MI0000061	hsa-let-7a-2	Homo sapiens let-7a-2 stem-loop	AGGUUGAGGUAGUAGGUUGUAUAGUUUAGAAUUACAUCAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCU		5
15110	MI0000062	hsa-let-7a-3	Homo sapiens let-7a-3 stem-loop	GGGUGAGGUAGUAGGUUGUAUAGUUUGGGGCUCUGCCCUGCUAUGGGAUAACUAUACAAUCUACUGUCUUUCCU	let-7a* cloned in [6] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
15111	MI0000063	hsa-let-7b	Homo sapiens let-7b stem-loop	CGGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGCAGUGAUGUUGCCCCUCGGAAGAUAACUAUACAACCUACUGCCUUCCCUG		5
15112	MI0000064	hsa-let-7c	Homo sapiens let-7c stem-loop	GCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGC		5
15113	MI0000065	hsa-let-7d	Homo sapiens let-7d stem-loop	CCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUAGGGCAGGGAUUUUGCCCACAAGGAGGUAACUAUACGACCUGCUGCCUUUCUUAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15114	MI0000066	hsa-let-7e	Homo sapiens let-7e stem-loop	CCCGGGCUGAGGUAGGAGGUUGUAUAGUUGAGGAGGACACCCAAGGAGAUCACUAUACGGCCUCCUAGCUUUCCCCAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15115	MI0000067	hsa-let-7f-1	Homo sapiens let-7f-1 stem-loop	UCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGA		5
15116	MI0000068	hsa-let-7f-2	Homo sapiens let-7f-2 stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		5
15117	MI0000069	hsa-mir-15a	Homo sapiens miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Reference [1] named this sequence miR-15.  This is renamed miR-15a here to avoid confusion with miR-15b (MIR:MI0000438) identified later by others. This gene and miR-16 are clustered within 0.5 kb at 13q14.  This region has been shown to be deleted in more than half of B cell chronic lymphocytic leukemias (CLL).  Both miR-15a and miR-16 are deleted or down-regulated in more than two thirds of CLL cases [2]. 	5
15118	MI0000070	hsa-mir-16-1	Homo sapiens miR-16-1 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Human miR-16 has been cloned by independent groups [1,2].  This precursor sequence maps to chromosome 13, and was named mir-16 in [1] and mir-16-precursor-13 in [2].  Lim et al. reported 2 identical chromosome 13 loci, which appear to map to the same locus in subsequent genome assemblies. This gene and miR-15a are clustered within 0.5 kb at 13q14. This region has been shown to be deleted in more than half of B cell chronic lymphocytic leukemias (CLL).  Both miR-15a and miR-16 are deleted or down-regulated in more than two thirds of CLL cases [3].  A second putative mir-16 hairpin precursor is located on chromosome 3 (MIR:MI0000738). 	5
15119	MI0000071	hsa-mir-17	Homo sapiens miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Two groups independently reported miRs derived from the same precursor. Lagos-Quintana et al. [1] reported miR-17 expressed from the 3' arm of the hairpin precursor in HeLa cells.  Mourelatos et al. [2] reported the cloning of miR-91 from the 5' arm of the same precursor.  The sequences were previously known as miR-17-5p and miR-17-3p here.  Landgraf et al. [7] showed that the 5' product is the predominant one -- the 3' sequence is therefore renamed miR-17*.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [7]. 	5
15120	MI0000072	hsa-mir-18a	Homo sapiens miR-18a stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	This sequence maps to chromosome 13 and is named miR-18 precursor-13 in reference [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	5
15121	MI0000073	hsa-mir-19a	Homo sapiens miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	This sequence maps to chromosome 13 and is named miR-19a precursor-13 in reference [2]. 	5
15122	MI0000074	hsa-mir-19b-1	Homo sapiens miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG		5
15123	MI0000075	hsa-mir-19b-2	Homo sapiens miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU		5
15124	MI0000076	hsa-mir-20a	Homo sapiens miR-20a stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC		5
15125	MI0000077	hsa-mir-21	Homo sapiens miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Mourelatos et al. named this sequence miR-21 precursor-17 and also reported the exact reverse complement of this predicted stem-loop sequence and erroneously assigned the name miR-104 [2]. 	5
15126	MI0000078	hsa-mir-22	Homo sapiens miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC		5
15127	MI0000079	hsa-mir-23a	Homo sapiens miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	This miRNA was previously named miR-23 [1,2] but is renamed here to avoid confusion with the more recently described miR-23b (MIR:MI0000439). Kawasaki and Taira reported that miR-23 regulates the transcriptional repressor Hairy enhancer of split (HES1) [3].  This finding was later retracted after the discovery that the regulated gene was human homolog of ES1 (HES1), whose function is unknown. 	5
15128	MI0000080	hsa-mir-24-1	Homo sapiens miR-24 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUUACACACUGGCUCAGUUCAGCAGGAACAGGAG	miR-24 was identified independently in references [1] and [2], and is predicted to be excised from the 3' arm of a hairpin originating from chromosome 9.  The human homologue of mouse miR-189 (MIR:MI0000231) [3] appears to originate from the 5' arm of the same precursor.  Landgraf et al. show that the 3' product is the predominant one [7].  miR-189 is therefore renamed miR-24* here. 	5
15129	MI0000081	hsa-mir-24-2	Homo sapiens miR-24-2 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGUACACUGGCUCAGUUCAGCAGGAACAGGG	mir-24-2 was identified independently by two groups.  This sequence was named miR-24 precursor-19 in reference [2]. 	5
15130	MI0000082	hsa-mir-25	Homo sapiens miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC		5
15131	MI0000083	hsa-mir-26a-1	Homo sapiens miR-26a-1 stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [6]. 	5
15132	MI0000084	hsa-mir-26b	Homo sapiens miR-26b stem-loop	CCGGGACCCAGUUCAAGUAAUUCAGGAUAGGUUGUGUGCUGUCCAGCCUGUUCUCCAUUACUUGGCUCGGGGACCGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15133	MI0000085	hsa-mir-27a	Homo sapiens miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	This miRNA was previously named miR-27 [1,2] but is renamed here to avoid confusion with the more recently described miR-27b (MIR:MI0000440). 	5
15134	MI0000086	hsa-mir-28	Homo sapiens miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUACCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU		5
15135	MI0000087	hsa-mir-29a	Homo sapiens miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	miR-29a was previously know as miR-29 here and in [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [6]. 	5
15136	MI0000088	hsa-mir-30a	Homo sapiens miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	The mature sequences miR-30 [1] and miR-97 [2] appear to originate from the same precursor.  Subsequent data confirm that both arms of the precursor appear to give rise to mature miRNA sequences (Pfeffer S, pers. comm.).  Landgraf et al. later showed that the 5' product is the predominant one [5].  Related miRNAs are processed from the 5' arms of other precursor loci (mir-30b, MIR:MI0000441; mir-30c-1, MIR:MI0000736; mir-30c-2, MIR:MI0000254; mir-30d, MIR:MI0000255; mir-30e, MI0000749). 	5
15137	MI0000089	hsa-mir-31	Homo sapiens miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15138	MI0000090	hsa-mir-32	Homo sapiens miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15139	MI0000091	hsa-mir-33a	Homo sapiens miR-33a stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUCACAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15140	MI0000093	hsa-mir-92a-1	Homo sapiens miR-92a-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Human miR-92a (previously named miR-92 here) has two predicted hairpin precursor sequences: mir-92a-1 (MIR:MI0000093) on chromosome 13 (named mir-92-13 in [1]) and mir-92a-2 (MIR:MI0000094) on chromosome X (named mir-92-X in [1]).  miR-92a has also been cloned from mouse embryonic stem cells [2] and is predicted to be expressed from two closely related precursor hairpins (MIR:MI0000719 and MIR:MI0000580).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [7]. 	5
15141	MI0000094	hsa-mir-92a-2	Homo sapiens miR-92a-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Human miR-92a (previously named miR-92 here) has two predicted hairpin precursor sequences: mir-92a-1 (MIR:MI0000093) on chromosome 13 (named mir-92-13 in [1]) and mir-92a-2 (MIR:MI0000094) on chromosome X (named mir-92-X in [1]).  miR-92a has also been cloned from mouse embryonic stem cells [2] and is predicted to be expressed from two closely related precursor hairpins (MIR:MI0000719 and MIR:MI0000580).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [7]. 	5
15142	MI0000095	hsa-mir-93	Homo sapiens miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCAACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Mourelatos et al. identified two copies of this sequence mapping to chromosome 7, and assigned the names mir-93-7.1 and mir-93-7.2 [1]. Subsequent genome assemblies suggest the presence of only one miR-93 locus on chromosome 7.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15143	MI0000097	hsa-mir-95	Homo sapiens miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	This sequence is localised to chromosome 4 and was named mir-95-4 in reference [1]. 	5
15144	MI0000098	hsa-mir-96	Homo sapiens miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	This sequence is localised to chromosome 7 and was named mir-96-7 in reference [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15145	MI0000100	hsa-mir-98	Homo sapiens miR-98 stem-loop	AGGAUUCUGCUCAUGCCAGGGUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCCCUGGUGUGUGGCAUAUUCA	This sequence is localised to chromosome X and was named mir-98-X reference [1].  The predicted stem-loop precursor sequence is clearly related to let-7. 	5
15146	MI0000101	hsa-mir-99a	Homo sapiens miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	This sequence is localised to chromosome 21 and was named mir-99-21 in reference [1]. 	5
15147	MI0000102	hsa-mir-100	Homo sapiens miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUAUCUAUAGGUAUGUGUCUGUUAGG	This sequence is localised to chromosome 11 and was named mir-100-11 in reference [1]. 	5
15148	MI0000103	hsa-mir-101-1	Homo sapiens miR-101-1 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCUAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Reference [1] reports two miR-101 precursor hairpin structures in human, on chromosome 1 (MIR:MI0000103) and 9 (MIR:MI0000739, named mir-101-precursor-9 in [1]).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15149	MI0000105	hsa-mir-29b-1	Homo sapiens miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Mourelatos et al. identified two copies of this sequence mapping to chromosome 7, and assigned the names mir-102-7.1 and mir-102-7.2 [1]. Subsequent genome assemblies suggest the presence of only one miR-102 locus on chromosome 7.  Human miR-102 is a homologue of mouse miR-29b (MIR:MI0000143) and so has been renamed here for consistency. 	5
15150	MI0000107	hsa-mir-29b-2	Homo sapiens miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	This sequence was named mir-102-1 in reference [1].  Human miR-102 is a homologue of mouse miR-29b (MIR:MI0000143) and so has been renamed here for consistency. 	5
15151	MI0000108	hsa-mir-103-2	Homo sapiens miR-103-2 stem-loop	UUGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUUCAGGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACCA	This sequence was localised to chromosome 20 and named mir-103-20 in reference [1]. 	5
15152	MI0000109	hsa-mir-103-1	Homo sapiens miR-103-1 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	This sequence was localised to chromosome 5 and named mir-103-5 in reference [1]. 	5
15153	MI0000111	hsa-mir-105-1	Homo sapiens miR-105-1 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Mourelatos et al. [1] reported two identical predicted stem loop sequences located on chromosome X, which they named mir-105-X.1 and mir-105-X.2. These sequences have been renamed mir-105-1 (MIR:MI0000111) and mir-105-2 (MIR:MI0000112) here.  mir-105-2 differs slightly from that published in [1] and deposited in EMBL (EMBL:AF480548).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15154	MI0000112	hsa-mir-105-2	Homo sapiens miR-105-2 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUUAUGCACCACGGAUGUUUGAGCAUGUGCUAUGGUGUCUA	Mourelatos et al. [1] reported two identical predicted stem loop sequences located on chromosome X, which they named mir-105-X.1 and mir-105-X.2. These sequences have been renamed mir-105-1 (MIR:MI0000111) and mir-105-2 (MIR:MI0000112) here.  mir-105-2 differs slightly from that published in [1] and deposited in EMBL (EMBL:AF480548).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15155	MI0000113	hsa-mir-106a	Homo sapiens miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGUAAGCACUUCUUACAUUACCAUGG	This miRNA was not cloned in reference [1], rather it was identified by homology to miR-91 (MIR:MI0000071).  This sequence is localised to chromosome X and was named mir-106-X in [1].  Mouse and human miR-106a (MIR:MI0000406 and MIR:MI0000113) differ at two positions but the precursor sequences are clearly closely related.  The sequences are also related to mir-17 (MIR:MI0000071 and MIR:MI0000687).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15156	MI0000114	hsa-mir-107	Homo sapiens miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	This miRNA was identified by homology to miR-103 [1], and later verified by cloning in human [2]. 	5
15157	MI0000115	hsa-mir-16-2	Homo sapiens miR-16-2 stem-loop	GUUCCACUCUAGCAGCACGUAAAUAUUGGCGUAGUGAAAUAUAUAUUAAACACCAAUAUUACUGUGCUGCUUUAGUGUGAC	This entry represents a second putative hairpin precursor sequence for miR-16, located on chromosome 3 (see also MIR:MI0000070).  The sequence was previously named mir-16-3 here and in references [1] and [2]. 	5
15158	MI0000116	dme-mir-1	Drosophila melanogaster miR-1 stem-loop	UUCAGCCUUUGAGAGUUCCAUGCUUCCUUGCAUUCAAUAGUUAUAUUCAAGCAUAUGGAAUGUAAAGAAGUAUGGAGCGAAAUCUGGCGAG		4
15159	MI0000117	dme-mir-2a-1	Drosophila melanogaster miR-2a-1 stem-loop	GCUGGGCUCUCAAAGUGGUUGUGAAAUGCAUUUCCGCUUUGCGCGGCAUAUCACAGCCAGCUUUGAUGAGCUUAGC	Stark et al. [2] have identified targets for miR-2 in Drosophila using computational prediction followed by experimental validation.   miR-2 regulates the proapoptotic genes reaper, grim and sickle, suggesting that it may be involved in the control of apoptosis. 	4
15160	MI0000118	dme-mir-2a-2	Drosophila melanogaster miR-2a-2 stem-loop	AUCUAAGCCUCAUCAAGUGGUUGUGAUAUGGAUACCCAACGCAUAUCACAGCCAGCUUUGAUGAGCUAGGAU	Stark et al. [2] have identified targets for miR-2 in Drosophila using computational prediction followed by experimental validation.   miR-2 regulates the proapoptotic genes reaper, grim and sickle, suggesting that it may be involved in the control of apoptosis. 	4
15161	MI0000119	dme-mir-2b-1	Drosophila melanogaster miR-2b-1 stem-loop	CUUCAACUGUCUUCAAAGUGGCAGUGACAUGUUGUCAACAAUAUUCAUAUCACAGCCAGCUUUGAGGAGCGUUGCGG	Stark et al. [2] have identified targets for miR-2 in Drosophila using computational prediction followed by experimental validation.   miR-2 regulates the proapoptotic genes reaper, grim and sickle, suggesting that it may be involved in the control of apoptosis. 	4
15162	MI0000120	dme-mir-2b-2	Drosophila melanogaster miR-2b-2 stem-loop	UUGUGUCAUUCUUCAAAGUGGUUGUGAAAUGUUUGCCUUUUUAUGCCUAUUCAUAUCACAGCCAGCUUUGAGGAGCGACGCGA	Stark et al. [2] have identified targets for miR-2 in Drosophila using computational prediction followed by experimental validation.   miR-2 regulates the proapoptotic genes reaper, grim and sickle, suggesting that it may be involved in the control of apoptosis. 	4
15163	MI0000121	dme-mir-3	Drosophila melanogaster miR-3 stem-loop	GAUCCUGGGAUGCAUCUUGUGCAGUUAUGUUUCAAUCUCACAUCACUGGGCAAAGUGUGUCUCAAGAUC		4
15164	MI0000122	dme-mir-4	Drosophila melanogaster miR-4 stem-loop	UUGCAAUUAGUUUCUUUGGUCGUCCAGCCUUAGGUGAUUUUUCCGGUCAUAAAGCUAGACAACCAUUGAAGUUCGUUGUGG		4
15165	MI0000123	dme-mir-5	Drosophila melanogaster miR-5 stem-loop	GCUAAAAGGAACGAUCGUUGUGAUAUGAGUUGUUUCCUAACAUAUCACAGUGAUUUUCCUUUAUAACGC		4
15166	MI0000124	dme-mir-6-1	Drosophila melanogaster miR-6-1 stem-loop	UUUAAUGUAGAGGGAAUAGUUGCUGUGCUGUAAGUUAAUAUACCAUAUCUAUAUCACAGUGGCUGUUCUUUUUGUACCUAAA		4
15167	MI0000125	dme-mir-6-2	Drosophila melanogaster miR-6-2 stem-loop	UAACCCAAGGGAACUUCUGCUGCUGAUAUAUUAUUGAAAAACUACUAUAUCACAGUGGCUGUUCUUUUUGGUUG		4
15168	MI0000126	dme-mir-6-3	Drosophila melanogaster miR-6-3 stem-loop	CAAAAAGAAGGGAACGGUUGCUGAUGAUGUAGUUUGAAACUCUCACAAUUUAUAUCACAGUGGCUGUUCUUUUUUGUUUG		4
15169	MI0000127	dme-mir-7	Drosophila melanogaster miR-7 stem-loop	GAGUGCAUUCCGUAUGGAAGACUAGUGAUUUUGUUGUUUGGUCUUUGGUAAUAACAAUAAAUCCCUUGUCUUCUUACGGCGUGCAUUU	Stark et al. [2] have identified targets for miR-7 in Drosophila using computational prediction followed by experimental validation.   miR-7 regulates a family of Notch targets including the Enhancer of split  and Bearded complex genes Tom and m4, and the basic helix-loop-helix transcriptional repressors HLHm3 and hairy. 	4
15170	MI0000128	dme-mir-8	Drosophila melanogaster miR-8 stem-loop	AAGGACAUCUGUUCACAUCUUACCGGGCAGCAUUAGAUCCUUUUUAUAACUCUAAUACUGUCAGGUAAAGAUGUCGUCCGUGUCCUU		4
15171	MI0000129	dme-mir-9a	Drosophila melanogaster miR-9a stem-loop	GCUAUGUUGUCUUUGGUUAUCUAGCUGUAUGAGUGAUAAAUAACGUCAUAAAGCUAGCUUACCGAAGUUAAUAUUAGC	This sequence was named miR-9 in reference [1].  The 5' end has been determined by cloning.  A length distribution of 21-23 nt was reported with 23 nt most commonly expressed.  The sequence maps to chromosome 3L. 	4
15172	MI0000130	dme-mir-10	Drosophila melanogaster miR-10 stem-loop	CCACGUCUACCCUGUAGAUCCGAAUUUGUUUUAUACUAGCUUUAAGGACAAAUUCGGUUCUAGAGAGGUUUGUGUGG		4
15173	MI0000131	dme-mir-11	Drosophila melanogaster miR-11 stem-loop	GCACUUGUCAAGAACUUUCUCUGUGACCCGCGUGUACUUAAAAGCCGCAUCACAGUCUGAGUUCUUGCUGAGUGC		4
15174	MI0000132	dme-mir-12	Drosophila melanogaster miR-12 stem-loop	UACGGUUGAGUAUUACAUCAGGUACUGGUGUGCCUUAAAUCCAACAACCAGUACUUAUGUCAUACUACGCCGUG		4
15175	MI0000133	dme-mir-13a	Drosophila melanogaster miR-13a stem-loop	UACGUAACUCCUCAAAGGGUUGUGAAAUGUCGACUAUUAUCUACUCAUAUCACAGCCAUUUUGAUGAGUUUCGUG		4
15176	MI0000134	dme-mir-13b-1	Drosophila melanogaster miR-13b-1 stem-loop	CCAUGUCGUUAAAAUGUUUGUGAACUUAUGUAUUCACAAUCAUAUCACAGCCAUUUUGACGAGUUUGG		4
15177	MI0000135	dme-mir-13b-2	Drosophila melanogaster miR-13b-2 stem-loop	UAUUAACGCGUCAAAAUGACUGUGAGCUAUGUGGAUUUGACUUCAUAUCACAGCCAUUUUGACGAGUUUG		4
15178	MI0000136	dme-mir-14	Drosophila melanogaster miR-14 stem-loop	UGUGGGAGCGAGACGGGGACUCACUGUGCUUAUUAAAUAGUCAGUCUUUUUCUCUCUCCUAUA	miR-14 was identified in D. melanogaster by cloning and Northern blot [1]. miR-14 has been reported to act as a cell death repressor and regulator of fat metabolism [2]. 	4
15179	MI0000137	mmu-let-7g	Mus musculus let-7g stem-loop	CCAGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCCAGG	The mature sequence reported in [1] has a 3' terminal A residue, which is incompatible with the reported precursor sequence from [1] and in this entry.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15180	MI0000138	mmu-let-7i	Mus musculus let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15181	MI0000139	mmu-mir-1-1	Mus musculus miR-1-1 stem-loop	GCUUGGGACACAUACUUCUUUAUAUGCCCAUAUGAACCUGCUAAGCUAUGGAAUGUAAAGAAGUAUGUAUUUCAGGC	Lagos-Quintana et al. [1] reported the cloning of miR-1b, miR-1c and miR-1d.  The mature processed miR sequences are identical apart from the 3' residues (A in mir-1b, C in mir-1c and UU in mir-1d).  The 3' residues of both miR-1b and miR-1c conflict with the predicted stem-loop precursor sequence shown here and these sequences are not found in current assemblies of human and mouse genomes.  It is suggested that polyA polymerase may add 1-3 nts to the 3' end of the mature transcript (Tom Tuschl, pers. comm.).  The common 21 nts of the 3 reported miR sequences have been rationalised here and named miR-1.  There are 2 pairs of orthologous putative hairpin precursor structures named mir-1-1 (human MIR:MI0000651, mouse MIR:MI0000139), and mir-1-2 (human MIR:MI0000437, mouse MIR:MI0000652).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15182	MI0000140	mmu-mir-15b	Mus musculus miR-15b stem-loop	CUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAG		6
15183	MI0000141	mmu-mir-23b	Mus musculus miR-23b stem-loop	GGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUGAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACC		6
15184	MI0000142	mmu-mir-27b	Mus musculus miR-27b stem-loop	AGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGCACCU		6
15185	MI0000143	mmu-mir-29b-1	Mus musculus miR-29b-1 stem-loop	AGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCU		6
15186	MI0000144	mmu-mir-30a	Mus musculus miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAAAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Landgraf et al. confirm that the 5' mature miRNA product is the predominant one [4]. 	6
15187	MI0000145	mmu-mir-30b	Mus musculus miR-30b stem-loop	CUAAGCCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUCAUACAUGCGUUGGCUGGGAUGUGGAUGUUUACGUCAGCUGUCUUGGAGUAU		6
15188	MI0000146	mmu-mir-99a	Mus musculus miR-99a stem-loop	CAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCGCAAGCUCGUUUCUAUGGGUCUGUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15189	MI0000147	mmu-mir-99b	Mus musculus miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC	Expression of this miRNA in mouse was independently verified in the brain [1], embryonic stem cells [2] and testes [3]. 	6
15190	MI0000148	mmu-mir-101a	Mus musculus miR-101a stem-loop	AGGCUGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCAGCCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15191	MI0000150	mmu-mir-124-3	Mus musculus miR-124-3 stem-loop	CUCUGCGUGUUCACAGCGGACCUUGAUUUAAUGUCUAUACAAUUAAGGCACGCGGUGAAUGCCAAGAG	miR-124 was cloned from mouse brain [1] and embryonic stem cells [2] by independent groups.  There are 3 predicted precursor hairpin sequences: mir-124-1 (MIR:MI0000716) on chromosome 14, mir-124-2 (MIR:MI0000717) on chromosome 3, and mir-124-3 (previously known as miR-124a here, MIR:MI0000150) on chromosome 2.  All have closely related predicted human homologues (MIR:MI0000443, MIR:MI0000444 and MIR:MI0000445). Lagos-Quintana et al. also report a mature miRNA sequence miR-124b, with a G insertion at position 12 [1].  miR-124b is not found in either the mouse or human genome assemblies. 	6
15192	MI0000151	mmu-mir-125a	Mus musculus miR-125a stem-loop	CUGGGUCCCUGAGACCCUUUAACCUGUGAGGACGUCCAGGGUCACAGGUGAGGUUCUUGGGAGCCUGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15193	MI0000152	mmu-mir-125b-2	Mus musculus miR-125b-2 stem-loop	GCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGUUCUUGGGACCUAGGC	Mouse miR-125b was cloned from mouse brain tissues in [1].  There are 2 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [2] (mir-125b-1, MIR:MI0000725; mir-125b-2, MIR:MI0000152; the latter was previously named mir-125b here). 	6
15194	MI0000153	mmu-mir-126	Mus musculus miR-126 stem-loop	UGACAGCACAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGCGGUCA	miR-123 identified in [1] was later found to originate from the same precursor as miR-126 and was hence renamed miR-126-5p.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15195	MI0000154	mmu-mir-127	Mus musculus miR-127 stem-loop	CCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [6]. 	6
15196	MI0000155	mmu-mir-128-1	Mus musculus miR-128-1 stem-loop	GUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGC	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	6
15197	MI0000156	mmu-mir-130a	Mus musculus miR-130a stem-loop	GAGCUCUUUUCACAUUGUGCUACUGUCUAACGUGUACCGAGCAGUGCAAUGUUAAAAGGGCAUC	This sequence was named miR-130 in reference [1], but is renamed here to avoid confusion with miR-130b (MIR:MI0000408). 	6
15198	MI0000157	mmu-mir-9-2	Mus musculus miR-9-2 stem-loop	GUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAC	Mouse miR-9 was cloned from mouse brain tissues in [1].  There are 3 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [3].  Two copies of mir-9-1 (MIR:MI0000720) are found as part of a larger duplicated region on mouse chromosome 3, mir-9-2 (MIR:MI0000157, previously named mir-9 here) is found on chromosome 13, and mir-9-3 (MIR:MI0000721) on chromosome 7. miR-9* was described as miR-131 in reference [1], but appears to be expressed from the opposite arm of all 3 mir-9 predicted stem-loops.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15199	MI0000158	mmu-mir-132	Mus musculus miR-132 stem-loop	GGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACCGGAGGUAACAGUCUACAGCCAUGGUCGCCC		6
15200	MI0000159	mmu-mir-133a-1	Mus musculus miR-133a-1 stem-loop	GCUAAAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGC	This mature miRNA sequence was named miR-133 in reference [1], and renamed miR-133a on subsequent identification of a homologue differing at the terminal 3' position (MIR:MI0000821).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15201	MI0000160	mmu-mir-134	Mus musculus miR-134 stem-loop	AGGGUGUGUGACUGGUUGACCAGAGGGGCGUGCACUCUGUUCACCCUGUGGGCCACCUAGUCACCAACCCU		6
15202	MI0000161	mmu-mir-135a-1	Mus musculus miR-135-1 stem-loop	AGGCCUCACUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUAUUGCUCGCUCAUAUAGGGAUUGGAGCCGUGGCGUACGGUGAGGAUA		6
15203	MI0000162	mmu-mir-136	Mus musculus miR-136 stem-loop	GAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAAGCUCCAUCAUCGUCUCAAAUGAGUCUUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15204	MI0000163	mmu-mir-137	Mus musculus miR-137 stem-loop	CUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGG		6
15205	MI0000164	mmu-mir-138-2	Mus musculus miR-138-2 stem-loop	CAGCUGGUGUUGUGAAUCAGGCCGACGAGCAGCGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUUG	Mouse miR-138 was cloned from mouse brain tissue in [1].  There are 2 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [2].  mir-138-1 (MIR:MI0000722) is found on mouse chromosome 8, and mir-138-2 (MIR:MI0000164, previously named mir-138 here) on chromosome 9.  Kim et al. and Obernosterer et al. independently show that the mature product is a 23mer [3,4]. 	6
15206	MI0000165	mmu-mir-140	Mus musculus miR-140 stem-loop	CCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGG		6
15207	MI0000166	mmu-mir-141	Mus musculus miR-141 stem-loop	GGGUCCAUCUUCCAGUGCAGUGUUGGAUGGUUGAAGUAUGAAGCUCCUAACACUGUCUGGUAAAGAUGGCCC		6
15208	MI0000167	mmu-mir-142	Mus musculus miR-142 stem-loop	ACCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUG	Expression of miRNAs from both 5' and 3' arms of this precursor have been independently verified in the mouse gut tissue [1] and in embryonic stem cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15209	MI0000168	mmu-mir-144	Mus musculus miR-144 stem-loop	GGCUGGGAUAUCAUCAUAUACUGUAAGUUUGUGAUGAGACACUACAGUAUAGAUGAUGUACUAGUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15210	MI0000169	mmu-mir-145	Mus musculus miR-145 stem-loop	CUCACGGUCCAGUUUUCCCAGGAAUCCCUUGGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15211	MI0000170	mmu-mir-146a	Mus musculus miR-146a stem-loop	AGCUCUGAGAACUGAAUUCCAUGGGUUAUAUCAAUGUCAGACCUGUGAAAUUCAGUUCUUCAGCU		6
15212	MI0000171	mmu-mir-149	Mus musculus miR-149 stem-loop	GGCUCUGGCUCCGUGUCUUCACUCCCGUGUUUGUCCGAGGAGGGAGGGAGGGACGGGGGCGGUGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15213	MI0000172	mmu-mir-150	Mus musculus miR-150 stem-loop	CCCUGUCUCCCAACCCUUGUACCAGUGCUGUGCCUCAGACCCUGGUACAGGCCUGGGGGAUAGGG		6
15214	MI0000173	mmu-mir-151	Mus musculus miR-151 stem-loop	CCUGCCCUCGAGGAGCUCACAGUCUAGUAUGUCUCCUCCCUACUAGACUGAGGCUCCUUGAGGACAGG		6
15215	MI0000174	mmu-mir-152	Mus musculus miR-152 stem-loop	CCGGGCCUAGGUUCUGUGAUACACUCCGACUCGGGCUCUGGAGCAGUCAGUGCAUGACAGAACUUGGGCCCGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15216	MI0000175	mmu-mir-153	Mus musculus miR-153 stem-loop	CGGUGUCAUUUUUGUGACGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUG		6
15217	MI0000176	mmu-mir-154	Mus musculus miR-154 stem-loop	GAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUCGUGACGAAUCAUACACGGUUGACCUAUUUUU		6
15218	MI0000177	mmu-mir-155	Mus musculus miR-155 stem-loop	CUGUUAAUGCUAAUUGUGAUAGGGGUUUUGGCCUCUGACUGACUCCUACCUGUUAGCAUUAACAG	Mouse mir-155 resides in the non-coding BIC transcript (EMBL:AY096003), located on chromosome 16 [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15219	MI0000178	ath-MIR156a	Arabidopsis thaliana miR156a stem-loop	CAAGAGAAACGCAAAGAAACUGACAGAAGAGAGUGAGCACACAAAGGCAAUUUGCAUAUCAUUGCACUUGCUUCUCUUGCGUGCUCACUGCUCUUUCUGUCAGAUUCCGGUGCUGAUCUCUUU	MIR156a is found on chromosome 2 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15220	MI0000179	ath-MIR156b	Arabidopsis thaliana miR156b stem-loop	GCUAGAAGAGGGAGAGAUGGUGAUUGAGGAAUGCAACAGAGAAAACUGACAGAAGAGAGUGAGCACAUGCAGGCACUGUUAUGUGUCUAUAACUUUGCGUGUGCGUGCUCACCUCUCUUUCUGUCAGUUGCCUAUCUCUGCCUGCUUGACCUCUCUCUCUCUCUCUCUCUCUCAAAUUUGGCU	MIR156b is found on chromosome 4 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15221	MI0000180	ath-MIR156c	Arabidopsis thaliana miR156c stem-loop	CGCAUAGAAACUGACAGAAGAGAGUGAGCACACAAAGGCACUUUGCAUGUUCGAUGCAUUUGCUUCUCUUGCGUGCUCACUGCUCUAUCUGUCAGAUUCCGGCU	MIR156c is found on chromosome 4 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15222	MI0000181	ath-MIR156d	Arabidopsis thaliana miR156d stem-loop	GAUGGGGGAAAAGAAGUUGACAGAAGAGAGUGAGCACACAAAGGGGAAGUUGUAUAAAAGUUUUGUAUAUGGUUGCUUUUGCGUGCUCACUCUCUUUUUGUCAUAACUUCUCCUUCAU	MIR156d is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15223	MI0000182	ath-MIR156e	Arabidopsis thaliana miR156e stem-loop	AGGAGGUGACAGAAGAGAGUGAGCACACAUGGUGGUUUCUUGCAUGCUUUUUUGAUUAGGGUUUCAUGCUUGAAGCUAUGUGUGCUUACUCUCUCUCUGUCACCCCU	MIR156e is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15224	MI0000183	ath-MIR156f	Arabidopsis thaliana miR156f stem-loop	GAGUGGUGAGGAAUUGAUGGUGACAGAAGAGAGUGAGCACACAUGGUGGCUUUCUUGCAUAUUUGAAGGUUCCAUGCUUGAAGCUAUGUGUGCUCACUCUCUAUCCGUCACCCCCUUCUCUCCCUCUCCCUC	MIR156f is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target 10 mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box. The complementary sites are downstream of this conserved domain, within a poorly conserved protein-coding context or the 3' UTR [2]. 	1
15225	MI0000184	ath-MIR157a	Arabidopsis thaliana miR157a stem-loop	GUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAGAUACAAUUCGGAGCAUGUUCUUUGCAUCUUACUCCUUUGUGCUCUCUAGCCUUCUGUCAUCACC	MIR157a is found on chromosome 1 in Arabidopsis thaliana [1] and is thought, like the miR156 family, to target mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box [2]. 	1
15226	MI0000185	ath-MIR157b	Arabidopsis thaliana miR157b stem-loop	UGGGAGGCAUUGAUAGUGUUGACAGAAGAUAGAGAGCACAGAUGAUAAGAUACAAUUCCUCGCAGCUUCUUUGCAUCUUACUCCUUUGUGCUCUCUAGCCUUCUGUCAUCACCCGUUAUUUGCCAUCACCCA	MIR157b is found on chromosome 1 in Arabidopsis thaliana [1] and is thought, like the miR156 family, to target mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box [2]. 	1
15227	MI0000186	ath-MIR157c	Arabidopsis thaliana miR157c stem-loop	AGGUUUGAGAGUGAUGUUGGUUGUUGACAGAAGAUAGAGAGCACUAAGGAUGACAUGCAAGUACAUACAUAUAUAUCAUCACACCGCAUGUGGAUGAUAAAAUAUGUAUAACAAAUUCAAAGAAAGAGAGGGAGAGAAAGAGAGAGAACCUGCAUCUCUACUCUUUUGUGCUCUCUAUACUUCUGUCACCACCUUUAUCUCUUCUUCUCUCUAACCU	MIR157c is found on chromosome 3 in Arabidopsis thaliana [1] and is thought, like the miR156 family, to target mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box [2]. 	1
15228	MI0000187	ath-MIR157d	Arabidopsis thaliana miR157d stem-loop	GUGGAGGGUGAUAGUGUGGUUGCUGACAGAAGAUAGAGAGCACUAAGGAUGCUAUGCAAAACAGACACAGAUAUGUGUUUCUAAUUGUAUUUCAUACUUUAACCUCAAAGUUGAUAUAAAAAAAGAAAGAAAGAUAGAAGAGCUAGAAGACUAUCUGCAUCUCUAUUCCUAUGUGCUCUCUAUGCUUCUGUCAUCACCUUUCUUUCUCUAUUUCUCUCUAC	MIR157d is found on chromosome 1 in Arabidopsis thaliana [1] and is thought, like the MIR156 family, to target mRNAs coding for proteins containing the Squamosa-promoter Binding Protein (SBP) box [2]. 	1
15229	MI0000188	ath-MIR158a	Arabidopsis thaliana miR158a stem-loop	ACACGUCAUCUCUGUGCUUCUUUGUCUACAAUUUUGGAAAAAGUGAUGACGCCAUUGCUCUUUCCCAAAUGUAGACAAAGCAAUACCGUGAUGAUGUCGU	MIR158 is found on chromosome 3 in Arabidopsis thaliana [1]. The target of this miRNA is unknown [2]. 	1
15230	MI0000189	ath-MIR159a	Arabidopsis thaliana miR159a stem-loop	GUAGAGCUCCUUAAAGUUCAAACAUGAGUUGAGCAGGGUAAAGAAAAGCUGCUAAGCUAUGGAUCCCAUAAGCCCUAAUCCUUGUAAAGUAAAAAAGGAUUUGGUUAUAUGGAUUGCAUAUCUCAGGAGCUUUAACUUGCCCUUUAAUGGCUUUUACUCUUCUUUGGAUUGAAGGGAGCUCUAC	MIR159a was identified independently by Reinhart et al. [1] and Mette et al. [2].  The latter group referred to this sequence by the internal identifier MIR40a.  This sequence is not related to C. elegans miR-40. MIR159a is found on chromosome 1 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for MYB proteins which are known to  bind to the promoter of the floral meristem identity gene LEAFY [3]. 	1
15231	MI0000190	ath-MIR160a	Arabidopsis thaliana miR160a stem-loop	GUAUGCCUGGCUCCCUGUAUGCCAUAUGCUGAGCCCAUCGAGUAUCGAUGACCUCCGUGGAUGGCGUAUGAGGAGCCAUGCAUAU	MIR160a is found on chromosome 2 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for auxin response factor proteins [2]. 	1
15232	MI0000191	ath-MIR160b	Arabidopsis thaliana miR160b stem-loop	GUCGUGCCUGGCUCCCUGUAUGCCACAAGAAAACAUCGAUUUAGUUUCAAAAUCGAUCACUAGUGGCGUACAGAGUAGUCAAGCAUGAC	MIR160b is found on chromosome 4 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for auxin response factor proteins [2]. 	1
15233	MI0000192	ath-MIR160c	Arabidopsis thaliana miR160c stem-loop	GUUAUGCCUGGCUCCCUGUAUGCCACGAGUGGAUACCGAUUUUGGUUUUAAAAUCGGCUGCCGGUGGCGUACAAGGAGUCAAGCAUGAC	MIR160c is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for auxin response factor proteins [2]. 	1
15234	MI0000193	ath-MIR161	Arabidopsis thaliana miR161 stem-loop	UGCUUGAUCUCGGUUUUUGACCAGUUUAUUGCGUCGAUCAAUGCAUUGAAAGUGACUACAUCGGGGUUCCGAUUUUUUUUGUUCUUCAUAUGAUGAAGCGGAAACAGUAAUCAACCCUGGUUUAGUCACUUUCACUGCAUUAAUCAAUGCAUUUGUAAAAAGAGGGAAAAGCA	MIR161 is found on chromosome 1 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for PPR repeat proteins [2]. 	1
15235	MI0000194	ath-MIR162a	Arabidopsis thaliana miR162a stem-loop	UAGUUGGAAGAAGAGUGAGAGUCGCUGGAGGCAGCGGUUCAUCGAUCUCUUCCUGUGAACACAUUAAAAAUGUAAAAGCAUGAAUAGAUCGAUAAACCUCUGCAUCCAGCGUUUGCCUCUUGUAUCUUUCUUAUUGACUU	MIR162a is found on chromosome 5 in Arabidopsis thaliana [1] and its target is unknown. 	1
15236	MI0000195	ath-MIR162b	Arabidopsis thaliana miR162b stem-loop	GAGUGAAGUCGCUGGAGGCAGCGGUUCAUCGAUCAAUUCCUGUGAAUAUUUAUUUUUGUUUACAAAAGCAAGAAUCGAUCGAUAAACCUCUGCAUCCAGCGCUGCUUGCUC	MIR162b is found on chromosome 5 in Arabidopsis thaliana [1] and its target is unknown. 	1
15237	MI0000196	ath-MIR163	Arabidopsis thaliana miR163 stem-loop	ACCCGGUGGAUAAAAUCGAGUUCCAACCUCUUCAACGACAACGAUUUCAACACUCUCUUCCAGGAACAACUUCCUCCAGGCAGAUGAUACUAAAGUGCUGGAGUUCCCGGUUCCUGAGAGUGAGUCCAUAUCAAAAUGCGCAUUCGUUAUCACUUGGUUGAACCCAUUUGGGGAUUUAAAUUUGGAGGUGAAAUGGAACGCGUAAUUGAUGACUCCUACGUGGAACCUCUUCUUAGGAAGAGCACGGUCGAAGAAGUAACUGCGCAGUGCUUAAAUCGUAGAUGCUAAAGUCGUUGAAGAGGACUUGGAACUUCGAUAUUAUCCCCCGUGU	MIR163 is found on chromosome 1 in Arabidopsis thaliana [1] and its target is unknown. 	1
15238	MI0000197	ath-MIR164a	Arabidopsis thaliana miR164a stem-loop	GGGUGAGAAUCUCCAUGUUGGAGAAGCAGGGCACGUGCAAACCAACAAACACGAAAUCCGUCUCAUUUGCUUAUUUGCACGUACUUAACUUCUCCAACAUGAGCUCUUCACCC	MIR164a is found on chromosome 2 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for NAC domain containing proteins such as Cup-Shaped Cotyledon 2 (CUC2) which is required for shoot apical meristem formation [2]. 	1
15239	MI0000198	ath-MIR164b	Arabidopsis thaliana miR164b stem-loop	GAUGGAGAAGCAGGGCACGUGCAUUACUAGCUCAUAUAUACACUCUCACCACAAAUGCGUGUAUAUAUGCGGAAUUUUGUGAUAUAGAUGUGUGUGUGUGUUGAGUGUGAUGAUAUGGAUGAGUUAGUUCUUCAUGUGCCCAUCUUCACCAUC	MIR164b is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for NAC domain containing proteins such as Cup-Shaped Cotyledon 2 (CUC2) which is required for shoot apical meristem formation [2]. 	1
15240	MI0000199	ath-MIR165a	Arabidopsis thaliana miR165a stem-loop	GUUGAGGGGAAUGUUGUCUGGAUCGAGGAUAUUAUAGAUAUAUACAUGUGUAUGUUAAUGAUUCAAGUGAUCAUAGAGAGUAUCCUCGGACCAGGCUUCAUCCCCCCCAAC	MIR165a is found on chromosome 1 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15241	MI0000200	ath-MIR165b	Arabidopsis thaliana miR165b stem-loop	UGAAGAGGCUAUUUCUGUUGUGGGGAAUGUUGUUUGGAUCGAGGAUAUCAUAAACGCAUACACAUGUUUAUAUGUUAUGAUGCAUUAUAUGACUGAUGUAAUGUACAUAUAUAUACAUACAUGCCACAUGGUAUCGUCGGACCAGGCUUCAUCCCCCUCAACAUGUUAAUUGCCUUCAAUCA	MIR165b is found on chromosome 4 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15242	MI0000201	ath-MIR166a	Arabidopsis thaliana miR166a stem-loop	AGGGGCUUUCUCUUUUGAGGGGACUGUUGUCUGGCUCGAGGACUCUGGCUCGCUCUAUUCAUGUUGGAUCUCUUUCGAUCUAACAAUCGAAUUGAACCUUCAGAUUUCAGAUUUGAUUAGGGUUUUAGCGUCUUCGGACCAGGCUUCAUUCCCCCCAAUUGUUGCUCCCU	MIR166a is found on chromosome 2 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15243	MI0000202	ath-MIR166b	Arabidopsis thaliana miR166b stem-loop	UUGAGGGGACUGUUGUCUGGCUCGAGGACUCUUAUUCUAAUACAAUCUCAUUUGAAUACAUUCAGAUCUGAUGAUUGAUUAGGGUUUUAGUGUCGUCGGACCAGGCUUCAUUCCCCCCAA	MIR166b is found on chromosome 3 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15244	MI0000203	ath-MIR166c	Arabidopsis thaliana miR166c stem-loop	GCGAUUUAGUGUUGAGAGGAUUGUUGUCUGGCUCGAGGUCAUGAAGAAGAGAAUCACUCGAAUUAAUUUGGAAGAACAAAUUAAGAAAACCCUAGAUGAUUCUCGGACCAGGCUUCAUUCCCCCUAACCUACUUAUCGC	MIR166c is found on chromosome 5 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15245	MI0000204	ath-MIR166d	Arabidopsis thaliana miR166d stem-loop	GGUUGAGAGGAAUAUUGUCUGGCUCGAGGUCAUGAAGAAGAUCGGUAGAUUGAUUCAUUUUAAAGAGUGAAAUCCCUAAAUGAUUCUCGGACCAGGCUUCAUUCCCCCCAACC	MIR166d is found on chromosome 5 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15246	MI0000205	ath-MIR166e	Arabidopsis thaliana miR166e stem-loop	UUGAGGGGAAUGUUGUCUGGCACGAGGCCCUUAACUUAGAUCUAUAUUUGAUUAUAUAUAUAUGUCUCUUCUUUAUUCAUUAGUCUAUACAUGAAUGAUCAUUUUACGGUUAAUGACGUCGGACCAGGCUUCAUUCCCCUCAA	MIR166e is found on chromosome 5 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15247	MI0000206	ath-MIR166f	Arabidopsis thaliana miR166f stem-loop	AAGUUCAGGUGAAUGAUGCCUGGCUCGAGACCAUUCAAUCUCAUGAUCUCAUGAUUAUAACGAUGAUGAUGAUGAUGUCGGACCAGGCUUCAUUCCCCUCAACUU	MIR166f is found on chromosome 5 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15248	MI0000207	ath-MIR166g	Arabidopsis thaliana miR166g stem-loop	GCGAUUUAGGGUUUAGAGGAAUGUUGUUUGGCUCGAGGUCAUGGAGAGUAAUUCGUUAACCCAACUCAAAACUCUAAAUGAUUCUCGGACCAGGCUUCAUUCCCCUCAACCUAUUUUAUCGC	MIR166g is found on chromosome 5 in Arabidopsis thaliana [1] and, like miR165, is thought to target mRNAs coding for HD-Zip transcription factors including Phabulosa (PHB) and Phavoluta (PHV) that regulate axillary meristem initiation and leaf development [2]. 	1
15249	MI0000208	ath-MIR167a	Arabidopsis thaliana miR167a stem-loop	UGGUGCACCGGCAUCUGAUGAAGCUGCCAGCAUGAUCUAAUUAGCUUUCUUUAUCCUUUGUUGUGUUUCAUGACGAUGGUUAAGAGAUCAGUCUCGAUUAGAUCAUGUUCGCAGUUUCACCCGUUGACUGUCGCACCC	MIR167a is found on chromosome 3 in Arabidopsis thaliana [1] and is thought, like miR160, to target mRNAs coding for auxin response factors, DNA binding proteins that are thought to control transcription in response to the phytohormone auxin. Transcriptional regulation is important for many of the diverse developmental responses to auxin signals, which include cell elongation, division, and differentiation in both roots and shoots [2]. 	1
15250	MI0000209	ath-MIR167b	Arabidopsis thaliana miR167b stem-loop	GGGAACAAGUGAAGCUGCCAGCAUGAUCUAUCUUUGGUUAAGAGAUGAAUGUGGAAACAUAUUGCUUAAACCCAAGCUAGGUCAUGCUCUGACAGCCUCACUCCUUCCU	MIR167b is found on chromosome 3 in Arabidopsis thaliana [1] and is thought, like miR160, to target mRNAs coding for auxin response factors, DNA binding proteins that are thought to control transcription in response to the phytohormone auxin. Transcriptional regulation is important for many of the diverse developmental responses to auxin signals, which include cell elongation, division, and differentiation in both roots and shoots [2]. 	1
15251	MI0000210	ath-MIR168a	Arabidopsis thaliana miR168a stem-loop	CACCAUCGGGCUCGGAUUCGCUUGGUGCAGGUCGGGAACCAAUUCGGCUGACACAGCCUCGUGACUUUUAAACCUUUAUUGGUUUGUGAGCAGGGAUUGGAUCCCGCCUUGCAUCAACUGAAUCGGAUCCUCGAGGUG	MIR168a is found on chromosome 4 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for Argonaute (AGO1), which is required for axillary shoot meristem formation and leaf development in Arabidopsis. It has been suggested that AGO1 may also influence miRNA accumulation in plants and that miR168 may act as a negative-feedback mechanism for controlling expression of the AGO1 gene [2]. 	1
15252	MI0000211	ath-MIR168b	Arabidopsis thaliana miR168b stem-loop	UUACCGGCGGUCUCGGAUUCGCUUGGUGCAGGUCGGGAACUGAUUGGCUGACACCGACACGUGUCUUGUCAUGGUUGGUUUGUGAGCUCCCGUCUUGUAUCAACUGAAUCGGAGUCCGAGGUGA	MIR168b is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for Argonaute (AGO1), which is required for axillary shoot meristem formation and leaf development in Arabidopsis. It has been suggested that AGO1 may also influence miRNA accumulation in plants and that miR168 may act as a negative-feedback mechanism for controlling expression of the AGO1 gene [2]. 	1
15253	MI0000212	ath-MIR169a	Arabidopsis thaliana miR169a stem-loop	GUGACGAAAGUAGUGUGCAGCCAAGGAUGACUUGCCGAUUUAAAUGAUCUUUCUUUAUACUCUAUUAAGACAAUUUAGUUUCAAACUUUUUUUUUUUUUUUUUUUUGAAGGAUUCAGGAAGAAAUUAGGAUAUAUUAUUCCGUAUAAAAUACAAGAUAUAUAAAACCAAAAAGAAAAAGUAACAUGAUCGGCAAGUUGUCCUUGGCUACACGUUACUUUGUGUCGC	MIR169 is found on chromosome 3 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for CCAAT binding factor (CBF)-HAP2-like proteins [2]. 	1
15254	MI0000213	ath-MIR170	Arabidopsis thaliana miR170 stem-loop	CGAGAGAGUCCCUCUGAUAUUGGCCUGGUUCACUCAGAUUCUCUUUUACUAACUCAUCUGAUUGAGCCGUGUCAAUAUCUCAGUCCUCUCUCG	MIR170 is found on chromosome 5 in Arabidopsis thaliana [1] and is thought to target mRNAs coding for GRAS domain or SCARECROW-like proteins, a family of transcription factors whose members have been implicated in radial patterning in roots, signaling by the phytohormone gibberellin, and light signaling [2]. 	1
15255	MI0000214	ath-MIR171a	Arabidopsis thaliana miR171a stem-loop	AUGAGAGAGUCCCUUUGAUAUUGGCCUGGUUCACUCAGAUCUUACCUGACCACACACGUAGAUAUACAUUAUUCUCUCUAGAUUAUCUGAUUGAGCCGCGCCAAUAUCUCAGUACUCUCUCGU	MIR171 is found on chromosomes 2, 3 and 4 in Arabidopsis thaliana [1] and is thought, like miR170, to target mRNAs coding for GRAS domain or SCARECROW-like proteins, a family of transcription factors whose members have been implicated in radial patterning in roots, signaling by the phytohormone gibberellin, and light signaling [2]. 	1
15256	MI0000215	ath-MIR172a	Arabidopsis thaliana miR172a stem-loop	UGCUGUGGCAUCAUCAAGAUUCACAUCUGUUGAUGGACGGUGGUGAUUCACUCUCCACAAAGUUCUCUAUGAAAAUGAGAAUCUUGAUGAUGCUGCAUCGGC	This sequence was independently identified by two groups.  Park et al. described miR172a1, found on chromosome 2 in Arabidopsis thaliana and thought to target mRNAs coding for Apetala 2 (AP2) proteins, and miR172a2 (MIR:MI0000216) [1].  These sequences have been renamed miR172a and miR172b here to match previous plant miRNA nomenclature.  This sequence was referred to by Mette et al. by the internal identifier MIR123a [2], and was previously identified as MIR180a here.  This sequence is not related to mouse miR-123. 	1
15257	MI0000216	ath-MIR172b	Arabidopsis thaliana miR172b stem-loop	AGGCGCAGCACCAUUAAGAUUCACAUGGAAAUUGAUAAAUACCCUAAAUUAGGGUUUUGAUAUGUAUAUGAGAAUCUUGAUGAUGCUGCAUCAAC	This sequence was independently identified by two groups.  Park et al. described miR172a2, found on chromosome 5 in Arabidopsis thaliana and thought to target mRNAs coding for Apetala 2 (AP2) proteins, and miR172a1 (MIR:MI0000215) [1].  These sequences have been renamed miR172b and miR172a here to match previous plant miRNA nomenclature.  This sequence was referred to by Mette et al. by the internal identifier MIR123b [2], and was previously identified as MIR180b here.  This sequence is not related to mouse miR-123.  Wang et al. [2] report Northern blot evidence for the miR172b* sequence from the opposite arm of the precursor. 	1
15258	MI0000217	ath-MIR173	Arabidopsis thaliana miR173 stem-loop	UAAGUACUUUCGCUUGCAGAGAGAAAUCACAGUGGUCAAAAAAGUUGUAGUUUUCUUAAAGUCUCUUUCCUCUGUGAUUCUCUGUGUAAGCGAAAGAGCUUG	MIR173 is found on chromosome 3 in Arabidopsis thaliana and is thought to target mRNAs coding for a protein of unknown function (At3g28460) [1]. 	1
15259	MI0000218	ath-MIR159b	Arabidopsis thaliana miR159b stem-loop	GGAAGAGCUCCUUGAAGUUCAAUGGAGGGUUUAGCAGGGUGAAGUAAAGCUGCUAAGCUAUGGAUCCCAUAAGCCUUAUCAAAUUCAAUAUAAUUGAUGAUAAGGUUUUUUUUAUGGAUGCCAUAUCUCAGGAGCUUUCACUUACCCCUUUAAUGGCUUCACUCUUCUUUGGAUUGAAGGGAGCUCUUCAUCUCUC	Reference [1] described the discovery of MIR159b, but referred to the sequence by the internal identifier MIR40b.  This sequence is not related to C. elegans miR-40.  MIR159b is found on chromosome 1 in Arabidopsis thaliana [2] and is thought to target mRNAs coding for MYB proteins which are known to bind to the promoter of the floral meristem identity gene LEAFY [3]. 	1
15260	MI0000221	mmu-mir-10b	Mus musculus miR-10b stem-loop	UAUAUACCCUGUAGAACCGAAUUUGUGUGGUACCCACAUAGUCACAGAUUCGAUUCUAGGGGAAUAUA	The sequence of mouse miR-10b, as reported by Lagos-Quintana et al. [1], is offset by 2 nt in the 3' direction with respect to sequences cloned from human (MIR:MI0000267) and zebrafish (MIR:MI0001364).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15261	MI0000222	mmu-mir-129-1	Mus musculus miR-129-1 stem-loop	UGGAUCUUUUUGCGGUCUGGGCUUGCUGUUCUCUCGACAGUAGUCAGGAAGCCCUUACCCCAAAAAGUAUCUA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15262	MI0000223	mmu-mir-181a-2	Mus musculus mir-181a-2 stem-loop	CCAUGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUCAAAAACAAAAAAACCACCGACCGUUGACUGUACCUUGG	Mouse miR-181a (previously named miR-181 here and in [1]) was cloned from various mouse tissues in [1].  Expression has also been validated in zebrafish [2]. 	6
15263	MI0000224	mmu-mir-182	Mus musculus miR-182 stem-loop	ACCAUUUUUGGCAAUGGUAGAACUCACACCGGUAAGGUAAUGGGACCCGGUGGUUCUAGACUUGCCAACUAUGGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15264	MI0000225	mmu-mir-183	Mus musculus miR-183 stem-loop	CUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCAGUCAGUGAAUUACCGAAGGGCCAUAAACAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15265	MI0000226	mmu-mir-184	Mus musculus miR-184 stem-loop	CCUUUCCUUAUCACUUUUCCAGCCAGCUUUGUGACUCUAAGUGUUGGACGGAGAACUGAUAAGGGUAGG		6
15266	MI0000227	mmu-mir-185	Mus musculus miR-185 stem-loop	AGGGAUUGGAGAGAAAGGCAGUUCCUGAUGGUCCCCUCCCAGGGGCUGGCUUUCCUCUGGUCCUU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15267	MI0000228	mmu-mir-186	Mus musculus miR-186 stem-loop	ACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUCAUUUUAUUUUAAGCCCUAAGGUGAAUUUUUUGGGAAGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15268	MI0000229	mmu-mir-187	Mus musculus miR-187 stem-loop	UCAGGCUACAACACAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGG		6
15269	MI0000230	mmu-mir-188	Mus musculus miR-188 stem-loop	UCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUCUCUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15270	MI0000231	mmu-mir-24-1	Mus musculus miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUCACACACUGGCUCAGUUCAGCAGGAACAGGAG	miR-24 was identified in mouse by cloning [1], and is predicted to be excised from the 3' arm of a hairpin originating from chromosome 13. Mouse miR-189 identified in reference [2] appears to originate from the 5' arm of the same precursor.  Subsequent analyses suggest that miR-189 may be the miR* sequence, so is renamed miR-24* here.  A second predicted hairpin sequence on mouse chromosome 8 (MIR:MI0000572) may also express miR-24. 	6
15271	MI0000232	mmu-mir-190	Mus musculus miR-190 stem-loop	CUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAGCAUAUUCCUACAG		6
15272	MI0000233	mmu-mir-191	Mus musculus miR-191 stem-loop	AGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCACUUGGAUUUCGUUCCCUGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15273	MI0000234	hsa-mir-192	Homo sapiens miR-192 stem-loop	GCCGAGACCGAGUGCACAGGGCUCUGACCUAUGAAUUGACAGCCAGUGCUCUCGUCUCCCCUCUGGCUGCCAAUUCCAUAGGUCACAGGUAUGUUCGCCUCAAUGCCAGC	Lagos-Quintana et al. validated the presence of an 18 nt excised sequence by cloning [1].  Lim et al. predicted the miR by computational methods using conservation with mouse and Fugu rubripes sequences.  Expression of the excised miR was validated in zebrafish, and the 5' end mapped by PCR [2].  The 3' ends of the reported sequences differ by 3 nt - this entry contains the longer sequence.  Lim et al. report three separate copies of this gene named mir-192-1, -2 and -3 based on 2001 human genome assemblies [2]. Subsequent assemblies suggest the presence of only one gene located on chromosome 11. 	5
15274	MI0000235	mmu-mir-193	Mus musculus miR-193 stem-loop	GAGAGCUGGGUCUUUGCGGGCAAGAUGAGAGUGUCAGUUCAACUGGCCUACAAAGUCCCAGUCCUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15275	MI0000236	mmu-mir-194-1	Mus musculus miR-194-1 stem-loop	AUCGGGUGUAACAGCAACUCCAUGUGGACUGUGCUCGGAUUCCAGUGGAGCUGCUGUUACUUCUGAU	Lagos-Quintana cloned miR-194 from mouse kidney tissue [1].  Michael et al. subsequently verified expression of miR-194 in human [2].  Two putative pairs of orthologous hairpin precursors structures are found in mouse  (mir-194-1 (MIR:MI0000236) on chromosome 1, and mir-194-2 (MIR:MI0000733) on chromosome 19) and human (mir-194-1 (MIR:MI0000488) on chromosome 1, and mir-194-2 (MIR:MI0000732) on chromosome 11). 	6
15276	MI0000237	mmu-mir-195	Mus musculus miR-195 stem-loop	ACACCCAACUCUCCUGGCUCUAGCAGCACAGAAAUAUUGGCAUGGGGAAGUGAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUGA		6
15277	MI0000238	hsa-mir-196a-1	Homo sapiens miR-196a-1 stem-loop	GUGAAUUAGGUAGUUUCAUGUUGUUGGGCCUGGGUUUCUGAACACAACAACAUUAAACCACCCGAUUCAC	Lagos-Quintana et al. [1] cloned this miRNA from human osteoblast sarcoma cells.  Lim et al [2] independently predicted this miRNA by computational methods using conservation with mouse and Fugu rubripes sequences [2]. Expression of the excised miR was validated in zebrafish.  The sequence maps to human chromosome 17.  Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196.  Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15278	MI0000239	hsa-mir-197	Homo sapiens miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC		5
15279	MI0000240	hsa-mir-198	Homo sapiens miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUAUAGAAUAAAUGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15280	MI0000241	mmu-mir-199a-1	Mus musculus miR-199a-1 stem-loop	GCCAUCCCAGUGUUCAGACUACCUGUUCAGGAGGCUGGGACAUGUACAGUAGUCUGCACAUUGGUUAGGC	The hairpin precursor sequence mir-199 maps to two loci within 50 kb on mouse chromosome 9.  This sequence was named mir-199 in [1] and [2], but is renamed here to avoid overlap with the predicted homologues of human mir-199a-2 and mir-199b.  Landgraf et al. demonstrate comparable expression for products from both arms of the hairpin, which are therefore renamed miR-199a-5p and miR-199a-3p here [4].  The mature sequences shown here represent the most commonly cloned forms from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15281	MI0000242	hsa-mir-199a-1	Homo sapiens miR-199a-1 stem-loop	GCCAACCCAGUGUUCAGACUACCUGUUCAGGAGGCUCUCAAUGUGUACAGUAGUCUGCACAUUGGUUAGGC	Lagos-Quintana et al. [1] cloned miR-199 from human osteoblast sarcoma cells.  They also reported identification of a miRNA from the opposite arm in mouse cells.  This sequence was named miR-199-s and the sequence from the 3' arm of the homologous mouse precursor miR-199-as.  Lim et al. [2] independently predicted this miRNA computationally using conservation with mouse and Fugu rubripes sequences [2].  Expression of the miR excised from the 5' arm was validated in zebrafish, and the ends mapped by cloning. The excised miR sequences are renamed miR-199a (to avoid confusion with the subsequently identified miR-199b (MIR:MI0000282)) and miR-199a* (from the 3' arm) here.  The two putative hairpin precursors in human map to chromosome 19 (mir-199a-1, MIR:MI0000242) and chromosome 1 (mir-199a-2, MIR:MI0000281).  Landgraf et al. show that both mature products are expressed, prompting the renaming to miR-199a-5p and miR-199a-3p [4]. 	5
15282	MI0000243	mmu-mir-200b	Mus musculus miR-200b stem-loop	GCCGUGGCCAUCUUACUGGGCAGCAUUGGAUAGUGUCUGAUCUCUAAUACUGCCUGGUAAUGAUGACGGC		6
15283	MI0000244	mmu-mir-201	Mus musculus miR-201 stem-loop	UACCUUACUCAGUAAGGCAUUGUUCUUCUAUAUUAAUAAAUGAACAGUGCCUUUCUGUGUAGGGUA		6
15284	MI0000245	mmu-mir-202	Mus musculus miR-202 stem-loop	GUUCCUUUUUCCUAUGCAUAUACUUCUUUGUGGAUCUGGUCUAAAGAGGUAUAGCGCAUGGGAAGAUGGAGC		6
15285	MI0000246	mmu-mir-203	Mus musculus miR-203 stem-loop	GCCUGGUCCAGUGGUUCUUGACAGUUCAACAGUUCUGUAGCACAAUUGUGAAAUGUUUAGGACCACUAGACCCGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15286	MI0000247	mmu-mir-204	Mus musculus miR-204 stem-loop	UGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15287	MI0000248	mmu-mir-205	Mus musculus miR-205 stem-loop	CUCUUGUCCUUCAUUCCACCGGAGUCUGUCUUAUGCCAACCAGAUUUCAGUGGAGUGAAGCUCAGGAG		6
15288	MI0000249	mmu-mir-206	Mus musculus miR-206 stem-loop	CCAGGCCACAUGCUUCUUUAUAUCCUCAUAGAUAUCUCAGCACUAUGGAAUGUAAGGAAGUGUGUGGUUUUGG		6
15289	MI0000250	mmu-mir-207	Mus musculus miR-207 stem-loop	AAGGCAGGGGUGAGGGGCUGCGGGAGGAGCCGGGCGGAGGCUGCGGCUUGCGCUUCUCCUGGCUCUCCUCCCUCUCUUU		6
15290	MI0000251	hsa-mir-208a	Homo sapiens miR-208a stem-loop	UGACGGGCGAGCUUUUGGCCCGGGUUAUACCUGAUGCUCACGUAUAAGACGAGCAAAAAGCUUGUUGGUCA		5
15291	MI0000252	hsa-mir-129-1	Homo sapiens miR-129-1 stem-loop	GGAUCUUUUUGCGGUCUGGGCUUGCUGUUCCUCUCAACAGUAGUCAGGAAGCCCUUACCCCAAAAAGUAUCU	This miRNA sequence was predicted based on homology to a verified miRNA cloned from mouse cerebellum [1].  Expression of this miRNA was subsequently verified in a human osteoblast sarcoma cell line [2]. Reference [2] named the human/mouse conserved sequence miR-129b, but subsequent genome searches suggest that the same mature sequence may be expressed from two predicted hairpin precursors in both human (this entry and MIR:MI0000473) and mouse (MIR:MI0000222 and MIR:MI0000585).  Landgraf et al. show that the 5' product of mir-129-1 (this entry) is the predominant one, whereas both 5' and 3' products are significantly expressed from mir-129-2 (MIR:MI0000585) [3]. 	5
15292	MI0000253	hsa-mir-148a	Homo sapiens miR-148a stem-loop	GAGGCAAAGUUCUGAGACACUCCGACUCUGAGUAUGAUAGAAGUCAGUGCACUACAGAACUUUGUCUC		5
15293	MI0000254	hsa-mir-30c-2	Homo sapiens miR-30c-2 stem-loop	AGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUUUCU	miR-30c was cloned from mouse heart and brain tissues by Lagos-Quintana et al. [1].  Two human hairpin precursor sequences are predicted based on homology with the mouse sequences, on chromosomes 1 (MIR:MI0000736) and 6 (MIR:MI0000254) [3].  Expression of miR-30c was later independently verified in human HL-60 leukemia cells [2]. 	5
15294	MI0000255	hsa-mir-30d	Homo sapiens miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC		5
15295	MI0000256	mmu-mir-122	Mus musculus miR-122 stem-loop	AGCUGUGGAGUGUGACAAUGGUGUUUGUGUCCAAACCAUCAAACGCCAUUAUCACACUAAAUAGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15296	MI0000257	mmu-mir-143	Mus musculus miR-143 stem-loop	CCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGG	Expression of this miRNA in mouse was independently verified in heart and brain [1], embryonic stem cells [2] and testes [3].  The predominant miRNA cloned by Langraf et al. has a 3' terminal U residue, which is incompatible with the genome sequence [4]. 	6
15297	MI0000259	mmu-mir-30e	Mus musculus miR-30e stem-loop	GGGCAGUCUUUGCUACUGUAAACAUCCUUGACUGGAAGCUGUAAGGUGUUGAGAGGAGCUUUCAGUCGGAUGUUUACAGCGGCAGGCUGCCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15298	MI0000261	hsa-mir-139	Homo sapiens miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15299	MI0000262	hsa-mir-147	Homo sapiens miR-147 stem-loop	AAUCUAAAGACAACAUUUCUGCACACACACCAGACUAUGGAAGCCAGUGUGUGGAAAUGCUUCUGCUAGAUU	Lagos-Quintana et al. cloned miR-147 from mouse spleen tissue [1], but the sequence is not present in the mouse genome assembly (NCBI32).  The human genome sequence contains a predicted precursor hairpin for miR-147 shown in [1] (supplementary information) and represented here.  The expression of miR-147 has not been verified in human. 	5
15300	MI0000263	hsa-mir-7-1	Homo sapiens miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15301	MI0000264	hsa-mir-7-2	Homo sapiens miR-7-2 stem-loop	CUGGAUACAGAGUGGACCGGCUGGCCCCAUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACAAAUCCCAGUCUACCUAAUGGUGCCAGCCAUCGCA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15302	MI0000265	hsa-mir-7-3	Homo sapiens miR-7-3 stem-loop	AGAUUAGAGUGGCUGUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUACUACGACAACAAGUCACAGCCGGCCUCAUAGCGCAGACUCCCUUCGAC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Expression in human was later verified by cloning [1,2]. 	5
15303	MI0000266	hsa-mir-10a	Homo sapiens miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCU	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Mature products were later verified in human [2]. 	5
15304	MI0000267	hsa-mir-10b	Homo sapiens miR-10b stem-loop	CCAGAGGUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCGUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Michael et al. subsequently verified expression of miR-10b in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15305	MI0000268	hsa-mir-34a	Homo sapiens miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.   Dostie et al. independently cloned this sequence in human but misnamed the sequence miR-172 (the sequence is unrelated to MIR172 from Arabidopsis) [2].  The sequence maps to human chromosome 1.  Human miR-34a was previously named miR-34 here and in [1], but is renamed to clarify homology with the alternatively named mouse sequence (MIR:MI0000584).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15306	MI0000269	hsa-mir-181a-2	Homo sapiens mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGCCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUUGGGGUCCUUA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. and Lui et al. later verify expression in human [4-5]. 	5
15307	MI0000270	hsa-mir-181b-1	Homo sapiens miR-181b-1 stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Its expression was later verified in human BC-1 cells [3].  There are two predicted hairpin precursor sequences in the human genome; mir-181b-1 (MIR:MI0000270) is found on chromosome 1 [1], and mir-181b-2 (MIR:MI0000683) on chromosome 9 [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15308	MI0000271	hsa-mir-181c	Homo sapiens miR-181c stem-loop	CGGAAAAUUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCUGAGGCCUGGAAUUGCCAUCCU	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. confirm the expression of miR-181c in human [2]. 	5
15309	MI0000272	hsa-mir-182	Homo sapiens miR-182 stem-loop	GAGCUGCUUGCCUCCCCCCGUUUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAACAGGAUCCGGUGGUUCUAGACUUGCCAACUAUGGGGCGAGGACUCAGCCGGCAC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR was validated in zebrafish, and the 5' end mapped by PCR.  A less predominantly expressed miR was identified originating from the opposite arm of the precursor (designated miR-182*).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  Additionally, Landgraf et al. clone a minor product which appears to originate from the loop region (GUGAGGUAACAGGAUCCGGUGG) [2]. 	5
15310	MI0000273	hsa-mir-183	Homo sapiens miR-183 stem-loop	CCGCAGAGUGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCAGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Expression was later confirmed in human [2,3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15311	MI0000274	hsa-mir-187	Homo sapiens miR-187 stem-loop	GGUCGGGCUCACCAUGACACAGUGUGAGACCUCGGGCUACAACACAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15312	MI0000279	hsa-mir-196a-2	Homo sapiens miR-196a-2 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  miR-196a was later validated in human [3,4]. Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196.  Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15313	MI0000281	hsa-mir-199a-2	Homo sapiens miR-199a-2 stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Lagos-Quintana et al. [1] cloned miR-199 from human osteoblast sarcoma cells.  They also reported identification of a miRNA from the opposite arm in mouse cells.  This sequence was named miR-199-s and the sequence from the 3' arm of the homologous mouse precursor miR-199-as.  Lim et al. [2] independently predicted this miRNA computationally using conservation with mouse and Fugu rubripes sequences [2].  Expression of the miR excised from the 5' arm was validated in zebrafish, and the ends mapped by cloning. The excised miR sequences are renamed miR-199a (to avoid confusion with the subsequently identified miR-199b (MIR:MI0000282)) and miR-199a* (from the 3' arm) here.  The two putative hairpin precursors in human map to chromosome 19 (mir-199a-1, MIR:MI0000242) and chromosome 1 (mir-199a-2, MIR:MI0000281).  Landgraf et al. show that both mature products are expressed, prompting the renaming to miR-199a-5p and miR-199a-3p [4]. 	5
15314	MI0000282	hsa-mir-199b	Homo sapiens miR-199b stem-loop	CCAGAGGACACCUCCACUCCGUCUACCCAGUGUUUAGACUAUCUGUUCAGGACUCCCAAAUUGUACAGUAGUCUGCACAUUGGUUAGGCUGGGCUGGGUUAGACCCUCGG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised 5' miR has been validated in zebrafish, the ends mapped by cloning [2], and later verified in human [3]. 	5
15315	MI0000283	hsa-mir-203	Homo sapiens miR-203 stem-loop	GUGUUGGGGACUCGCGCGCUGGGUCCAGUGGUUCUUAACAGUUCAACAGUUCUGUAGCGCAAUUGUGAAAUGUUUAGGACCACUAGACCCGGCGGGCGCGGCGACAGCGA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. confirm expression in human [2]. 	5
15316	MI0000284	hsa-mir-204	Homo sapiens miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. confirm expression in human [2]. 	5
15317	MI0000285	hsa-mir-205	Homo sapiens miR-205 stem-loop	AAAGAUCCUCAGACAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. confirm expression in human [2]. 	5
15318	MI0000286	hsa-mir-210	Homo sapiens miR-210 stem-loop	ACCCGGCAGUGCCUCCAGGCGCAGGGCAGCCCCUGCCCACCGCACACUGCGCUGCCCCAGACCCACUGUGCGUGUGACAGCGGCUGAUCUGUGCCUGGGCAGCGCGACCC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Its expression was later verified in human BC-1 cells [2]. 	5
15319	MI0000287	hsa-mir-211	Homo sapiens miR-211 stem-loop	UCACCUGGCCAUGUGACUUGUGGGCUUCCCUUUGUCAUCCUUCGCCUAGGGCUCUGAGCAGGGCAGGGACAGCAAAGGGGUGCUCAGUUGUCACUUCCCACAGCACGGAG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  The sequence maps to human chromosome 15. 	5
15320	MI0000288	hsa-mir-212	Homo sapiens miR-212 stem-loop	CGGGGCACCCCGCCCGGACAGCGCGCCGGCACCUUGGCUCUAGACUGCUUACUGCCCGGGCCGCCCUCAGUAACAGUCUCCAGUCACGGCCACCGACGCCUGGCCCCGCC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  The 3' end was not experimentally determined.  The sequence maps to human chromosome 17, but its expression has not been experimentally verified in human. 	5
15321	MI0000289	hsa-mir-181a-1	Homo sapiens miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Human miR-181a, cloned by Dostie et al [2], is predicted to be expressed from two genomic hairpin loci, hsa-mir-181a-1 (MIR:MI0000289) and hsa-mir-181a-2 (MIR:MI0000269).  A miRNA from the 3' arm of this hairpin, named miR-213, was predicted by computational methods using conservation with mouse and Fugu rubripes sequences, and validated in zebrafish [1]. Subsequent cloning and Northern evidence shows that the 3' mature sequence is the biogenesis byproduct miR-181a* (Chang-Zheng Chen and David Bartel, pers. comm.). 	5
15322	MI0000290	hsa-mir-214	Homo sapiens miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Landgraf et al. confirm expression in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15323	MI0000291	hsa-mir-215	Homo sapiens miR-215 stem-loop	AUCAUUCAGAAAUGGUAUACAGGAAAAUGACCUAUGAAUUGACAGACAAUAUAGCUGAGUUUGUCUGUCAUUUCUUUAGGCCAAUAUUCUGUAUGACUGUGCUACUUCAA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2]. 	5
15324	MI0000292	hsa-mir-216a	Homo sapiens miR-216a stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUAGCCCUCACGA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15325	MI0000293	hsa-mir-217	Homo sapiens miR-217 stem-loop	AGUAUAAUUAUUACAUAGUUUUUGAUGUCGCAGAUACUGCAUCAGGAACUGAUUGGAUAAGAAUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAAG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  The sequence maps to human chromosome 2.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15326	MI0000294	hsa-mir-218-1	Homo sapiens miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. later verified the expression of miR-218 in human [2]. 	5
15327	MI0000295	hsa-mir-218-2	Homo sapiens miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2]. 	5
15328	MI0000296	hsa-mir-219-1	Homo sapiens miR-219-2 stem-loop	CCGCCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUAUGGCUCCGGCCGAGAGUUGAGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGCGGG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the 5' excised miR has been validated in zebrafish, and the 5' end mapped by PCR [2]. The mature products were later validated in human [3].  Two hairpin precursor structures are predicted, mir-219-1 on chromosome 6 (MIR:MI0000296) and mir-219-2 on chromosome 9 (MIR:MI0000740) [2]. 	5
15329	MI0000297	hsa-mir-220a	Homo sapiens miR-220a stem-loop	GACAGUGUGGCAUUGUAGGGCUCCACACCGUAUCUGACACUUUGGGCGAGGGCACCAUGCUGAAGGUGUUCAUGAUGCGGUCUGGGAACUCCUCACGGAUCUUACUGAUG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  The 3' end was not experimentally determined. 	5
15330	MI0000298	hsa-mir-221	Homo sapiens miR-221 stem-loop	UGAACAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUCGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACAUGUUCUC	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and later validated in human HL-60 leukemia cells [2]. 	5
15331	MI0000299	hsa-mir-222	Homo sapiens miR-222 stem-loop	GCUGCUGGAAGGUGUAGGUACCCUCAAUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUCGUAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCUUCUAGCU	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR was validated in zebrafish, and the ends mapped by cloning.  Subsequent cloning studies have also verified the expression of miR-222 in human ES cells.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15332	MI0000300	hsa-mir-223	Homo sapiens miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCAUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCACAUGCUUACCAG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  Landgraf et al. confirm expression in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15333	MI0000301	hsa-mir-224	Homo sapiens miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	This miR was identified and ends mapped by cloning from Weri cells in human.  The sequence maps to chromosome X.  An erratum corrected the originally published name miR-175 to miR-224.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15334	MI0000302	cel-mir-124	Caenorhabditis elegans miR-124 stem-loop	GUCCCACUUGUCAUCUGGCAUGCACCCUAGUGACUUUAGUGGACAUCUAAGUCUUCCAACUAAGGCACGCGGUGAAUGCCACGUGGCCAUGAUGGG		3
15335	MI0000303	cel-mir-228	Caenorhabditis elegans miR-228 stem-loop	CCUUAUCCCGUUCGCAAUGGCACUGCAUGAAUUCACGGCUAUGCAUAACGACAGACCGCGGAUCAUACGGUACCAUAGCGGACGGUGAUGAGGUUAAU	This precursor sequence was predicted by comparative computational approaches [1,2].  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed, and the 5' and 3' ends were confirmed later [4]. 	3
15336	MI0000304	cel-mir-229	Caenorhabditis elegans miR-229 stem-loop	CGCCGGCAAUGACACUGGUUAUCUUUUCCAUCGUGGAAUGCCCCCCAUUGAUUUUUUCCCCUUUUCGGGGGGAAAAAAUUGGAAACGAGAAAGGUAUCGGGUGUCAUAGCCGGCG	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [3]. 	3
15337	MI0000305	cel-mir-230	Caenorhabditis elegans miR-230 stem-loop	UUGAUGUAAUGCCGUCACUUGGUCGGCGAUUUAAUAUUAUCAGAACAUAGGAAAUUGUUAGUAUUAGUUGUGCGACCAGGAGACGGUAUUCGCAUAUU		3
15338	MI0000306	cel-mir-231	Caenorhabditis elegans miR-231 stem-loop	UAGCACCACAGGUUGUUCUGACUGUUUCAAAAGCUUGUAGUAUCUUAAUAAAUAAACAUAUAAGCUCGUGAUCAACAGGCAGAACAACUCGGUUUUGUG		3
15339	MI0000307	cel-mir-232	Caenorhabditis elegans miR-232 stem-loop	AAGUUCAAUUUUUGGAUCCCUGCAGUUUCGAUGAUUUUAUCCUUAAUUCUGAAGAUGUGAUAAAUGCAUCUUAACUGCGGUGAUCUAGAUCAUGAACA		3
15340	MI0000308	cel-mir-233	Caenorhabditis elegans miR-233 stem-loop	AUAUAGCAUCUUUCUGUCUCGCCCAUCCCGUUGCUCCAAUAUUCUAACAACAAGUGAUUAUUGAGCAAUGCGCAUGUGCGGGAUAGACUGAUGGCUGC	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [3]. 	3
15341	MI0000309	cel-mir-234	Caenorhabditis elegans miR-234 stem-loop	CAAAAAAUGAUCAAACGGUAUUCCAGAGUUGAUAAUAAAAAUGCGUCAGUCCGCAAUCUAUUAUUGCUCGAGAAUACCCUUUGACUACUAUGUGUA		3
15342	MI0000310	cel-mir-235	Caenorhabditis elegans miR-235 stem-loop	UCCGAAGAUAUCAGGAUCAGGCCUUGGCUGAUUGCAAAAUUGUUCACCGUGAAAAUUAAAUAUUGCACUCUCCCCGGCCUGAUCUGAGAGUAAGGCG		3
15343	MI0000311	cel-mir-236	Caenorhabditis elegans miR-236 stem-loop	UCGGUGACCGAUGUCCAGCGUCUUACCUGUUCAAUAUUUAGACUGACUAUCAAAGAGAUCUAAUACUGUCAGGUAAUGACGCUGGAUUGUCAUGUCAU	This precursor sequence was predicted by comparative computational approaches [1,3].  The excised miRNA sequence was predicted to comprise bases 64 to 87, and the precise 5' and 3' ends were determined later [4]. Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed. 	3
15344	MI0000312	cel-mir-237	Caenorhabditis elegans miR-237 stem-loop	UUCUACAUUGCGUGGUCCCUGAGAAUUCUCGAACAGCUUCAAAGUGUUCAAGCUGUCGAGUUUUGUCAAGGACCAAACAAUAGAAGAUCACUUGGGAAC	The sequence is reported to be related to lin-4 [2].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [3]. 	3
15345	MI0000313	cel-mir-238	Caenorhabditis elegans miR-238 stem-loop	UCUCCAUUGACUGUUUGGAUGUUCUCGGACGUUCAAAGCUACAUCCAACAAAUUGGUAGCUUUGUACUCCGAUGCCAUUCAGAUAGUUAUGAGCCAUG		3
15346	MI0000314	cel-mir-239a	Caenorhabditis elegans miR-239a stem-loop	UACACGUUUGCAAUUUUUGUACUACACAUAGGUACUGGACAAUUUUCAAAAUAUAUCCAGUGUCUAGUCUAGUGCAAACAUUGCUCGGUGUUGUUUGA		3
15347	MI0000315	cel-mir-239b	Caenorhabditis elegans miR-239b stem-loop	GCGACAGAUGCAAUUUUUGUACUACACAAAAGUACUGGUCAUUUAAGUUGAGGCUCAGCACUUUUGUGGUGUGCAAAAAUGGCAAGUUGCUUUUAUCU	miR-239b was predicted by computational analysis and conservation in C. elegans and C. briggsae, and the microRNA confirmed by PCR amplification, cloning and sequencing [1].  A large scale cloning and sequencing study finds two dominant mature miRNA products: the second is 1 nt shorter at the 5' end [3]. 	3
15348	MI0000316	cel-mir-240	Caenorhabditis elegans miR-240 stem-loop	UUGUUAGAAACUUUUUCAAAUCGAGGAUUUUGAGACUAGAAUGCUUGAAUUGUACUAGCAUACUGGCCCCCAAAUCUUCGCUUAGAAAUACAGUUCA		3
15349	MI0000317	cel-mir-241	Caenorhabditis elegans miR-241 stem-loop	CGGGGGUGUCAAAGUUGAGGUAGGUGCGAGAAAUGACGGCAUCCAUAUAGUAAUCGUUCAUUGUCUCUCAGCUGCUUCAUCUGUGACAUGGCUACG		3
15350	MI0000318	cel-mir-242	Caenorhabditis elegans miR-242 stem-loop	UGGCUCGCGAGAGUAUUGCGUAGGCCUUUGCUUCGAGAGAGAAGCUUCAGUUCGCAGCAAUAUCCUCCGCAAAACUUUCCCCGGCUAUGCAAAAAA		3
15351	MI0000319	cel-mir-243	Caenorhabditis elegans miR-243 stem-loop	UGUUCACGCAUAAGCCUGAUAUCUCGGUGCGAUCGUACCGUAUCGCUCACACUUAGAUUACGGUACGAUCGCGGCGGGAUAUCAGGUACGUGAUUGGA		3
15352	MI0000320	cel-mir-244	Caenorhabditis elegans miR-244 stem-loop	CUCCAUAUCUCAAUCUCUUUGGUUGUACAAAGUGGUAUGGCUCAUCGAAUAAGCACAUACUGCUUUUCAGCUAAAGGAAUUGAGAUUUUGUAGGCUUUU		3
15353	MI0000321	cel-mir-245	Caenorhabditis elegans miR-245 stem-loop	CUGAAUUCAAUGUUGGAGAGCUAUUUGCAAGGUACCUAAUUGUUUGAUUAUUGAUUCUCAAUUGGUCCCCUCCAAGUAGCUCUAUUGCAUUGUUUGC		3
15354	MI0000322	cel-mir-246	Caenorhabditis elegans miR-246 stem-loop	AUCUGAAUUAUAAAACAUCGCCUAACCGUUGUCAUGUAAUAUUUCCCAGAGAAAAUGAUAUUACAUGUUUCGGGUAGGAGCUGUUCAAACUUUGGAC	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15355	MI0000323	cel-mir-247	Caenorhabditis elegans miR-247 stem-loop	AUUACCAGCUAUUUUCCAAGUAGAGAAAAGUUUCUAAUUACCCAUCAUGCACAAAUGUGGUGACUAGAGCCUAUUCUCUUCUUGGAAAAGUGGCGACU	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15356	MI0000324	cel-mir-248	Caenorhabditis elegans miR-248 stem-loop	UUUCCCGGCUGCAACUACGGUAAGCGGUAUCCAGCCGAUGUUUUCAAUACUGCAUUUGAAUACACGUGCACGGAUAACGCUCAUUGUUUUUCGCAUGC	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15357	MI0000325	cel-mir-249	Caenorhabditis elegans miR-249 stem-loop	AUACUCUUGAACGACUAGCAACGCACAAACGUCUUCUGUGCGACAACAUCUGAAUGUUUGUCACAGGACUUUUGAGCGUUGCCAGUCGAAAGAGGAA	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15358	MI0000326	cel-mir-250	Caenorhabditis elegans miR-250 stem-loop	AGGGUCUUCGGACCACGCCUUCAGUUGCCUCGUGAUCCGCCAAACACAAUAAAUGGACGAAUCACAGUCAACUGUUGGCAUGGUGCUCGUACCCAUUUU	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15359	MI0000327	cel-mir-251	Caenorhabditis elegans miR-251 stem-loop	ACUUUCAAUGACCCCUUGUUAAGUAGUGGUGCCGCUCUUAUUAGGUUGAAAAGUAAUAAGAGUAGUUCACUACUUAUCAAGGUGAAAUUUGAAAUUU		3
15360	MI0000328	cel-mir-252	Caenorhabditis elegans miR-252 stem-loop	UCCAGGGGUCUCUUUCAGUUAUAAGUAGUAGUGCCGCAGGUAACCGCCAGUCUAAAAGGCUUACCUACUGCCUUCUGCUUAAAAUUGAAAUAUUGAUG	The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15361	MI0000329	cel-mir-253	Caenorhabditis elegans miR-253 stem-loop	GAAUUGUUCCGAUCGCCGCUCUUUUCACACACCUCACUAACACUGACCACCGAUGCAUAGAUGUUAGUAGGCGUUGUGGGAAGGGCGGCGACAGUGAACGUCGUUUC	A mature miRNA product from the 5' arm of this hairpin precursor was first identified [1].  A later large scale cloning and sequencing study identified a 3' product and showed it to be the dominant mature miRNA [2]. 	3
15362	MI0000330	cel-mir-254	Caenorhabditis elegans miR-254 stem-loop	ACUAUGCAUAUUGCCGCCUACAGAAGCAUAGAUUUCCACAAACCAUUCGAGGUGUUUGUGCAAAUCUUUCGCGACUGUAGGCGGCGAACAUGCAGUUUUU		3
15363	MI0000331	cel-mir-255	Caenorhabditis elegans miR-255 stem-loop	CAGUGGUUCGACUAAAUUUUGGAGGUAAGAAAUCUUUGUAGUUCUCCGUAUUGUGACGUGAAAACUGAAGAGAUUUUUUACAGACUUCACAAAUUUGAAAUAUAUUCCUG	This precursor sequence was identified computationally using sequence homology with C. briggsae [1].  The mature microRNA was identified later [2]. 	3
15364	MI0000333	cel-mir-256	Caenorhabditis elegans miR-256 stem-loop	GCAAGGAGUGCAGAGGCUUACUAUGAGACGGUCAAGAGGCGCCUCCGUCACGUGGAUACGUCGGGUGGAAUGCAUAGAAGACUGUACUCAAAAAAUUUUAC	This sequence maps to chromosome V and appears to be related to mir-1. 	3
15365	MI0000334	cel-mir-257	Caenorhabditis elegans miR-257 stem-loop	AUAAUAUUUCCCGCUGAGUAUCAGGAGUACCCAGUGAUCGCCUUCACAUAUUGGGAAGAAGUAUGUGAUUGCGUCCUGCAGUUCUUCCAUGAUGUACUCAGG	This sequence maps to chromosome IV. 	3
15366	MI0000335	cel-mir-258	Caenorhabditis elegans miR-258 stem-loop	GCAAUGGUUUUGAGAGGAAUCCUUUUACAUAUUUGUUGAAGUUUUCGCUCGAAUUUGUGGUCGAAUACUGUAGAAGGAAGCCUGCACGAAGUUUUG	The predicted hairpin portion of the primary transcript of mir-258 is found in two exact copies within 10kb on chromosome X in C. elegans. 	3
15367	MI0000336	cel-mir-259	Caenorhabditis elegans miR-259 stem-loop	UCAGUCAUUGAAACGAGUAAAUCUCAUCCUAAUCUGGUAGCAUCUUUCGAACCUUGCCACCGAUUUGGCAUGGGAUUGACUUGUUAAAUAGUGACUUUUUU	miR-259 was predicted by computational analysis and conservation in C. elegans and C. briggsae, and the microRNA confirmed by PCR amplification, cloning and sequencing [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [3]. 	3
15368	MI0000337	cel-mir-260	Caenorhabditis elegans miR-260 stem-loop	CGUACAACAAAAUUAUUGCGAGAGAAUUUUUUAACAUGGCGUUUGCUUUACCAGGUCGAUAGACUAUCGUGAUGUCGAACUCUUGUAGGACAAUCUGGUAUUU	This sequence maps to chromosome II. 	3
15369	MI0000338	cel-mir-261	Caenorhabditis elegans miR-261 stem-loop	UGAUGGCUUUUCUGGAUUUGUUCCCUUCACGUGUAGAAAGAAACGAGCAAAAAAAAUCUUAGUGUUAGCUUUUUAGUUUUCACGGUGAAUAUGGAUAUU	This sequence maps to chromosome II. 	3
15370	MI0000339	cel-mir-262	Caenorhabditis elegans miR-262 stem-loop	GUGCAAAAUUGUAUUAAAAUAAACUUUAUUGGAUUACAAAAAAAAUGUAUCAAUUUUUCUUUUUCAUUUUUACGUUUCUCGAUGUUUUCUGAUACUGUUGCUAGCAGU	This sequence maps to chromosome V. 	3
15371	MI0000342	hsa-mir-200b	Homo sapiens miR-200b stem-loop	CCAGCUCGGGCAGCCGUGGCCAUCUUACUGGGCAGCAUUGGAUGGAGUCAGGUCUCUAAUACUGCCUGGUAAUGAUGACGGCGGAGCCCUGCACG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15372	MI0000343	dme-mir-263a	Drosophila melanogaster miR-263a stem-loop	UAGAUCUCGGCACAGUUAAUGGCACUGGAAGAAUUCACGGGGUAAUUUUUAUACAACCCGUGAUCUCUUAGUGGCAUCUAUGGUGCGAGAAUAA	This sequence was computationally predicted by two independent groups based on similarity with C. elegans miR-228 (MIR:MI0000303) [1] and conservation in D. pseudoobscura [2].  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed, but the precise 5' or 3' ends are unknown.  The sequence was named miR-263 in in reference [1], and maps to chromosome 2L. 	4
15373	MI0000344	cel-mir-264	Caenorhabditis elegans miR-264 stem-loop	UGGCGGCGGUCGACAUGUACAUAUCACCAGUCUGGCUUUUCCCGUUUCCGCGAGCAAGCGGCGGGUGGUUGUUGUUAUGGGAUACCGGAGCCA	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15374	MI0000345	cel-mir-265	Caenorhabditis elegans miR-265 stem-loop	GGUUUGACUUACCCCCUCCUUCCGCUGGCCGCCGUUUUUAUUAUGAACUUGAUGUGGUUUGAGGGAGGAAGGGUGGUAUUUGAACC	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15375	MI0000346	cel-mir-266	Caenorhabditis elegans miR-266 stem-loop	UGUCUAAACUUGGGCAAAAGUUAGGCAAGACUUUGGCAAAGCUUGAAUCCAAGUUUUGCCAAAGUUUUGCCCAACUUUUGCCCAAAUUCAGCCA	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15376	MI0000347	cel-mir-267	Caenorhabditis elegans miR-267 stem-loop	UAAAAGUUUCAAAACCCCGUGAAGUGUCUGCUGCAAUCUAAAUUUUUAGAUAUAGAUGCAGUCGACUCUUCAUUGGGUUUUCAGGAACCCGUA	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15377	MI0000348	cel-mir-268	Caenorhabditis elegans miR-268 stem-loop	GGAAGUGGCUUUGAAGCGGCAAGAAUUAGAAGCAGUUUGGUGUCAGACACACUACUCACUCACUGCUUCUUGUUUUUUCUGCUUUCUUUGCUUUU	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15378	MI0000349	cel-mir-269	Caenorhabditis elegans miR-269 stem-loop	GGGCAAAAGUUGGGCAAGACUCUGGCAAAACUUGGAUUUAUGCUGCGCCAAAGUUUAACCCAAGUUUGACCCAACUCUUGUCAAAUUUUUGUCC	This precursor sequence was predicted by comparative computational approaches.  The excised miRNA sequence is predicted and the precise  5' or 3' end unknown.  A PCR amplification protocol confirmed that  the strand containing the predicted miR is predominantly expressed. 	3
15379	MI0000350	cel-mir-270	Caenorhabditis elegans miR-270 stem-loop	GUCGCUAGCCUCUUUACCUGCCUACACACCUUUCUGCCUACGUGGCACAUUGGUAGGCAAGAGGGCAUGAUGUAGCAGUGGAGAUGGACUGCCAC	This sequence was predicted by computational approaches and validated using a PCR amplification protocol. 	3
15380	MI0000351	cel-mir-271	Caenorhabditis elegans miR-271 stem-loop	AAUAGAAAACGGGGCCCGCCGGCUCGCCGGGUGGGAAAGCAUUCGACAGCAAGACGUGUUUUUCAAUCUGCGACUCGGCGAUUCCCAUCAUCACU	This sequence was predicted by computational approaches and validated using a PCR amplification protocol. 	3
15381	MI0000352	cel-mir-272	Caenorhabditis elegans miR-272 stem-loop	CGCAGGCACGUGCAGGUAUGUAGGCAGGCGUAGGCCCGUAGGCAAGUGUAGGUCUGCAGGCAUGAAUGUAGGCAUGGGUGUUUGGAAGACCUGCG	This sequence was predicted by computational approaches and validated using a PCR amplification protocol. 	3
15382	MI0000353	cel-mir-273	Caenorhabditis elegans miR-273 stem-loop	ACCUCGUUUUGGGAGCAGCCGGCAUUUUACGGGCUACACUUUUUUUAAAAUUGAUGUGUGCCCGUACUGUGUCGGCUGCUUUGAAAAUUUCGGU	This sequence was predicted by computational approaches and validated using a PCR amplification protocol. 	3
15383	MI0000354	dme-mir-184	Drosophila melanogaster miR-184 stem-loop	GGUUGGCCGGUGCAUUCGUACCCUUAUCAUUCUCUCGCCCCGUGUGCACUUAAAGACAACUGGACGGAGAACUGAUAAGGGCUCGUAUCACCAAUUCAUC	miR-184 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 19-23 nt with 22 nt the most commonly expressed.  They also reported the less predominantly expressed sequence miR-184* from the opposite 5' arm.  The sequence is localised to chromosome 2R. 	4
15384	MI0000355	dme-mir-274	Drosophila melanogaster miR-274 stem-loop	UCCUGUGUUGCAGUUUCGUUUUGUGACCGACACUAACGGGUAAUUGUUUGGCCGCCAGGAUUACUCGUUUUUGCGAUCACAAAUUAUGAAAUUGCAGCAA	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 3L. 	4
15385	MI0000356	dme-mir-275	Drosophila melanogaster miR-275 stem-loop	UGUAAAGUCUCCUACCUUGCGCGCUAAUCAGUGACCGGGGCUGGUUUUUUAUAUACAGUCAGGUACCUGAAGUAGCGCGCGUGGUGGCAGACAUAUAU	miR-275 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 19-25 nt with 22 nt the most commonly expressed.  The sequence is localised to chromosome 2L. 	4
15386	MI0000357	dme-mir-92a	Drosophila melanogaster miR-92a stem-loop	AAUAUGAAUUUCCCGUAGGACGGGAAGGUGUCAACGUUUUGCAUUUCGAAUAAACAUUGCACUUGUCCCGGCCUAUGGGCGGUUUGUAAUAAACA	miR-92a was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 22-25 nt with 22 nt the most commonly expressed.  The sequence is localised to chromosome 3R. 	4
15387	MI0000358	dme-mir-219	Drosophila melanogaster miR-219 stem-loop	UAAUUCGAUUUUUAGCUAUGAUUGUCCAAACGCAAUUCUUGUUGAUAUUCAAUAUUCAAGGGUUGCGACUGGGCAUCGCGGCUCGAAAUAAGAAUACAAC	This sequence is computationally predicted based on conservation in D. pseudoobscura [1].  The sequence of the excised miR is strikingly conserved in human (MIR:MI0000296), but the expression of the miR has not been  confirmed in fly and the precise 5' or 3' ends are unknown.  The sequence  is localised to chromosome 3L. 	4
15388	MI0000359	dme-mir-276a	Drosophila melanogaster miR-276a stem-loop	CCUGGUUUUUGCCAUCAGCGAGGUAUAGAGUUCCUACGUUCAUUAUAAACUCGUAGGAACUUCAUACCGUGCUCUUGGAAGACCAAAAAACAACCAAG	miR-276 was reported independently in references [1] and [2].   Reference [2] reported a 22 nt excised sequence from the 3' arm of the precursor by cloning.  Computational approaches followed by Northern blotting predicted an excised sequence from the 5' arm which is designated miR-276a* here [1].  The sequence is localised to chromosome 3L. 	4
15389	MI0000360	dme-mir-277	Drosophila melanogaster miR-277 stem-loop	UUGAAGGUUUUGGGCUGCGUGUCAGGAGUGCAUUUGCACUGAAACUAUCUGAAGCAUGUAAAUGCACUAUCUGGUACGACAUUCCAGAACGUACAAUCUU	miR-277 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 21-23 nt with 23 nt the most commonly expressed.  The sequence is localised to chromosome 3R.  Stark et al. [3] have predicted that miR-277 controls the pathway for valine, leucine and isoleucine degradation by downregulating many of its enzymes. 	4
15390	MI0000361	dme-mir-278	Drosophila melanogaster miR-278 stem-loop	GUAAUGGUACGGUGCGACCGGAUGAUGGUUCACAACGACCGUGUCAUUUAAACGGGUCGGUGGGACUUUCGUCCGUUUGUAACGCCAUUUGUCAACGA	miR-278 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 20-22 nt with 22 nt the most commonly expressed.  The sequence is localised to chromosome 2R. 	4
15391	MI0000362	dme-mir-133	Drosophila melanogaster miR-133 stem-loop	ACCUGCAACACUGUGUGUAGCUGGUUGACAUCGGGUCAGAUCUGUUUUUCAAGCAUUUGGUCCCCUUCAACCAGCUGUAGCCAGUGGUUGAUGACAAC	miR-133 was reported independently by three groups using computational prediction [2], Northern blot analysis [1] and cloning [3].  References [1] and [2] confirmed that the strand containing the predicted miR is predominantly expressed [1].  Reference [3] confirmed the ends of the excised miRNA by cloning.  The sequence maps to chromosome 2L. 	4
15392	MI0000363	dme-mir-279	Drosophila melanogaster miR-279 stem-loop	GGAAUUCAUACUACUGUUUUUAGUGGGUGGGGGUCCAGUGUUUCACAUUGAUUUUCUUAGUAUUUGUGACUAGAUCCACACUCAUUAAUAACGGUAGUUC	miR-279 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome 3R. 	4
15393	MI0000364	dme-mir-33	Drosophila melanogaster miR-33 stem-loop	CUCUUCCUCUGGAGAUGACACGAAGGUGCAUUGUAGUCGCAUUGUCUGUCCCAAUUGCUUCAGGCAAUACAACUUCAGUGCAAGCUCUGUGCAUUUCAC	This sequence is computationally predicted based on conservation in D. pseudoobscura [1].  The sequence of the excised miR is strikingly conserved in human (MIR:MI0000091), but the expression of the miR has not been  confirmed in fly and the precise 5' or 3' ends are unknown.  The sequence  is localised to chromosome 3L. 	4
15394	MI0000365	dme-mir-280	Drosophila melanogaster miR-280 stem-loop	UGGCUUUUAUGUAUUUACGUUGCAUAUGAAAUGAUAUUUAUAGUAAACAGAUUAUUUUAUAUGCAGGUAUAUGCAAGUCGAGGUCCUCCACACUG	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 2R. 	4
15395	MI0000366	dme-mir-281-1	Drosophila melanogaster miR-281-1 stem-loop	CGAAUAAGUGAAUAAAGAGAGCUGUCCGUCGACAGUCCAGAAACUAUUUAAUAUCACUGUCAUGGAAUUGCUCUCUUUGUAUAAUAUUCG	miR-281 was reported independently in references [1] and [2].  The sequence in this entry is from reference [2] which identified a 23 nt excised sequence from the 3' arm of the precursor by cloning. Reference [1] reported the reverse complement of this foldback precursor from computational prediction and northern blotting.  The predicted mature sequence (5' and 3' ends unknown) from the 3' arm of the reverse complement was named miR-281a in reference [1] and is designated miR-281-1* here.   The predicted precursor maps to chromosome 2R. 	4
15396	MI0000367	dme-mir-282	Drosophila melanogaster miR-282 stem-loop	AGUUUCCUUCUAAAUCUAGCCUCUACUAGGCUUUGUCUGUGCAUUCGAAAGCCGAUCAGACAUAGCCUAUAAGAGGUUAGGUGUACCAAGGCGAACA	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 3L. 	4
15397	MI0000368	dme-mir-283	Drosophila melanogaster miR-283 stem-loop	CUCACACGAUUCUCAAAGGUAAAUAUCAGCUGGUAAUUCUGGGAGCUAAGCCUAAAUAUGAAACACUCGGAAUUUCAGUUGGUAUCGACUUUUUUGAAUU	miR-283 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome X. 	4
15398	MI0000369	dme-mir-284	Drosophila melanogaster miR-284 stem-loop	GUUGCAGUUCCUGGAAUUAAGUUGACUGUGUAGCCUGUGAGGGCAAGGCUUGAAUAAUGCUCCUGAAGUCAGCAACUUGAUUCCAGCAAUUGCGGCCCGA	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 3R. 	4
15399	MI0000370	dme-mir-281-2	Drosophila melanogaster miR-281-2 stem-loop	CGAAUUGUGAAAUGAAGAGAGCUAUCCGUCGACAGUCAAGUUAAGACCGAUUGUAAUACUGUCAUGGAAUUGCUCUCUUUGUAUAACAUUCG	miR-281 was reported independently in references [1] and [2].  The sequence in this entry is from reference [2] which identified a 23 nt excised sequence from the 3' arm of the precursor by cloning. Reference [1] reported the reverse complement of this foldback precursor from computational prediction and northern blotting.  The predicted mature sequence (5' and 3' ends unknown) from the 3' arm of the reverse complement was named miR-281b in reference [1] and is  designated miR-281-2* here.  The predicted precursor maps to chromosome 2R. 	4
15400	MI0000371	dme-mir-34	Drosophila melanogaster miR-34 stem-loop	AAUUGGCUAUGCGCUUUGGCAGUGUGGUUAGCUGGUUGUGUAGCCAAUUAUUGCCGUUGACAAUUCACAGCCACUAUCUUCACUGCCGCCGCGACAAGC	This sequence is computationally predicted based on conservation in D. pseudoobscura and C. elegans.  The precise 5' or 3' ends are unknown. Expression in D. melanogaster was confirmed by Northern blot analysis [1]. Aravin et al. later identify the 5' and 3' ends by cloning [3]. 	4
15401	MI0000373	dme-mir-124	Drosophila melanogaster miR-124 stem-loop	UCAUUUGGUACGUUUUUCUCCUGGUAUCCACUGUAGGCCUAUAUGUAUUUCCACCAUAAGGCACGCGGUGAAUGCCAAGAGCGAACGCAGUUCUACAAAU	miR-124 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 19-23 nt with 23 nt the most commonly expressed.  The sequence is localised to chromosome 2L. 	4
15402	MI0000374	dme-mir-79	Drosophila melanogaster miR-79 stem-loop	UGAAGCUGACUUGCCAUUGCUUUGGCGCUUUAGCUGUAUGAUAGAUUUAAACUACUUCAUAAAGCUAGAUUACCAAAGCAUUGGCUUCUGCAGGUCA	miR-79 was reported independently by three groups using computational prediction [2], Northern blot analysis [1] and cloning [3].  References [1] and [2] confirmed that the strand containing the predicted miR is predominantly expressed [1].  Reference [3] confirmed the ends of the excised miRNA by cloning.  The sequence maps to chromosome 2L. 	4
15403	MI0000375	dme-mir-276b	Drosophila melanogaster miR-276b stem-loop	AAAACCGAAGUCUUUUUACCAUCAGCGAGGUAUAGAGUUCCUACGUUCCUAUAUUCAGUCGUAGGAACUUAAUACCGUGCUCUUGGAGGACUGUCGACC	miR-276b was reported independently in references [1] and [2].   Reference [2] reported a 22 nt excised sequence from the 3' arm of the precursor by cloning.  Computational approaches followed by northern  blotting predicted an excised sequence from the 5' arm which is designated miR-276b* here [1].  The sequence is localised to chromosome 3L. 	4
15404	MI0000376	dme-mir-210	Drosophila melanogaster miR-210 stem-loop	AAAGGUGCUUAUUGCAGCUGCUGGCCACUGCACAAGAUUAGACUUAAGACUCUUGUGCGUGUGACAGCGGCUAUUGUAAGAGGCCAUAGAAGCAACAGCC	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome X. 	4
15405	MI0000377	dme-mir-285	Drosophila melanogaster miR-285 stem-loop	UCGAAUCGAAGAACUGAGAUCGAUUGGUGCAUAGAUAUCAGGAGAACCCACUCAAUUUAACUCUAGCACCAUUCGAAAUCAGUGCUUUUGAUAAGAAAC	miR-285 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome 3L. 	4
15406	MI0000378	dme-mir-100	Drosophila melanogaster miR-100 stem-loop	CCAUUAACAGAAACCCGUAAAUCCGAACUUGUGCUGUUUUAUAUCUGUUACAAGACCGGCAUUAUGGGAGUCUGUCAAUGCAAACAACUGGUUUUUGGCA	miR-100 was reported independently by three groups using computational prediction [2], Northern blot analysis [1] and cloning [3].  References [1] and [2] confirmed that the strand containing the predicted miR is predominantly expressed [1].  Reference [3] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome 2L. 	4
15407	MI0000379	dme-mir-92b	Drosophila melanogaster miR-92b stem-loop	UAAAACGUCACCUGAUGUAGGCCGUGCCCAGUGCUUAUUUGUUGCAUUUUCGAAAUACAAAUUGCACUAGUCCCGGCCUGCAAUGAGUGUCGCAGUCGAC	miR-92b was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome 3R. 	4
15408	MI0000380	dme-mir-286	Drosophila melanogaster miR-286 stem-loop	UUAAAAUUGAAUGGCGAAUGUCGGUAUGGUCUCUUUUUCAAAGAAAGGUUUCGAUUAAGCGAAGUGACUAGACCGAACACUCGUGCUAUAAUUUUAAAAU	miR-286 was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the 5' end of the excised miRNA by cloning and reported a length distribution of 22-24 nt with 23 nt the most commonly expressed.  The sequence is localised to chromosome 2R. 	4
15409	MI0000381	dme-mir-287	Drosophila melanogaster miR-287 stem-loop	GGACGCCGGGGAUGUAUGGGUGUGUAGGGUCUGAAAUUUUGCACACAUUUACAAUAAUUGUAAAUGUGUUGAAAAUCGUUUGCACGACUGUGA	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 2L. 	4
15410	MI0000382	dme-mir-87	Drosophila melanogaster miR-87 stem-loop	AACACAUUUCAUUCGCGCCUGUAUCUUGCUGAACCGCUGCCAUUAUGGCCAACGAUCCGGUUGAGCAAAAUUUCAGGUGUGUGAGAAAUGUGUUUAGCA	miR-87 was predicted by computational approaches based on conservation in C. elegans [2,3].  Northern blot analysis confirmed that the strand containing the predicted miR is predominantly expressed [1,2].  The precise 5' and 3' ends are not known, but alignment with the worm miR suggests the sequence shown here is closest [2].  This miR maps to chromosome 2L. 	4
15411	MI0000383	dme-mir-263b	Drosophila melanogaster miR-263b stem-loop	UUGCUGACUUUGAGUCUUGGCACUGGGAGAAUUCACAGUUGACUUUAUUAUUCUGUGGUUCUGCGGGUGCCAAAACUUAAAAACCGGCUU	miR-263b was reported independently in references [1] and [2]. Computational prediction followed by northern blotting confirmed that  the strand containing the predicted miR is predominantly expressed [1]. Reference [2] confirmed the ends of the excised miRNA by cloning.  The sequence is localised to chromosome 3L. 	4
15412	MI0000384	dme-mir-288	Drosophila melanogaster miR-288 stem-loop	CGGCCAUGUCGUAAUUAGCGGAGCACGGCAUCGCCGGCGAUAAUUAAUGACGGUGGUCACGUUGGUUUCAUGUCGAUUUCAUUUCAUGACACGGCCG	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 2L. 	4
15413	MI0000385	dme-mir-289	Drosophila melanogaster miR-289 stem-loop	GAGUUUACAGUAAAAUAAAUAUUUAAGUGGAGCCUGCGACUUCAGUCCCUCUGACUGACUGGGGUAAGUCACUUGAGCGUUUGUUGGCACGUAAAAGAC	This sequence is computationally predicted based on conservation in D. pseudoobscura.  The precise 5' or 3' ends are unknown.  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed.  The sequence is localised to chromosome 3L. 	4
15414	MI0000387	dme-bantam	Drosophila melanogaster bantam stem-loop	AUUUGACUACGAAACCGGUUUUCGAUUUGGUUUGACUGUUUUUCAUACAAGUGAGAUCAUUUUGAAAGCUGAUUUUGUCAA	bantam microRNA was predicted independently by two groups using computational approaches [1,2].  Northern blotting confirmed that the strand containing the predicted miR is predominantly expressed. Subsequent cloning studies have independently identified the same miRNA and confirmed the 5' end [3].  A length distribution of 20-23 nt was reported with a 23 nt sequence the most commonly expressed.  bantam is  reported to promote tissue growth [1]. bantam expression is temporally  and spatially regulated in response to patterning cues. bantam microRNA  simultaneously stimulates cell proliferation and prevents apoptosis and  is predicted to target the pro-apoptotic gene hid [1].  The sequence maps to chromosome 3L. 	4
15415	MI0000388	mmu-mir-290	Mus musculus miR-290 stem-loop	CUCAUCUUGCGGUACUCAAACUAUGGGGGCACUUUUUUUUUUCUUUAAAAAGUGCCGCCUAGUUUUAAGCCCCGCCGGUUGAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15416	MI0000389	mmu-mir-291a	Mus musculus miR-291a stem-loop	CCUAUGUAGCGGCCAUCAAAGUGGAGGCCCUCUCUUGAGCCUGAAUGAGAAAGUGCUUCCACUUUGUGUGCCACUGCAUGGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15417	MI0000390	mmu-mir-292	Mus musculus miR-292 stem-loop	CAGCCUGUGAUACUCAAACUGGGGGCUCUUUUGGAUUUUCAUCGGAAGAAAAGUGCCGCCAGGUUUUGAGUGUCACCGGUUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15418	MI0000391	mmu-mir-293	Mus musculus miR-293 stem-loop	UUCAAUCUGUGGUACUCAAACUGUGUGACAUUUUGUUCUUUGUAAGAAGUGCCGCAGAGUUUGUAGUGUUGCCGAUUGAG		6
15419	MI0000392	mmu-mir-294	Mus musculus miR-294 stem-loop	UUCCAUAUAGCCAUACUCAAAAUGGAGGCCCUAUCUAAGCUUUUAAGUGGAAAGUGCUUCCCUUUUGUGUGUUGCCAUGUGGAG		6
15420	MI0000393	mmu-mir-295	Mus musculus miR-295 stem-loop	GGUGAGACUCAAAUGUGGGGCACACUUCUGGACUGUACAUAGAAAGUGCUACUACUUUUGAGUCUCUCC		6
15421	MI0000394	mmu-mir-296	Mus musculus miR-296 stem-loop	GGGCCUUUCUGGAGGGCCCCCCCUCAAUCCUGUUGUGCUCGCUUCAGAGGGUUGGGUGGAGGCUCUCCUGAAGGUGUCC		6
15422	MI0000395	mmu-mir-297a-1	Mus musculus miR-297a-1 stem-loop	AUAUGUAUGUAUGUAUGUAUGUGUGCAUGUGCAUGUGCAUGUAUGCAUAUUGCAUGUAUAUAUUAUGCAUACAUGU	Houbaviy et al. report that the cloned sequence of miR-297 is found over 20 times in the mouse genomic sequence [1].  This sequence appears to match several low complexity repetitive regions.  Confidence in which loci actually express miR-297 is low because of the low complexity nature of the sequence.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	6
15423	MI0000397	mmu-mir-297a-2	Mus musculus miR-297a-2 stem-loop	UGUAUGUGCAUGCAUAUGUGCUCAUGUGUGUGUACAUGUAUGUGUGCAUGUGCAUGUAUAUAUG	Houbaviy et al. report that the cloned sequence of miR-297 is found over 20 times in the mouse genomic sequence [1].  This sequence appears to match several low complexity repetitive regions.  Confidence in which loci actually express miR-297 is low because of the low complexity nature of the sequence. 	6
15424	MI0000398	mmu-mir-298	Mus musculus miR-298 stem-loop	CCAGGCCUUUGGCAGAGGAGGGCUGUUCUUCCCUUGAGUUUUAUGACUGGGAGGAACUAGCCUUCUCUCAGCUUAGGAGUGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15425	MI0000399	mmu-mir-299	Mus musculus miR-299 stem-loop	AAGAAAUGGUUUACCGUCCCACAUACAUUUUGAGUAUGUAUGUGGGACGGUAAACCGCUUCUU	Houbaviy et al. identified a mature miRNA from the 5' arm of this hairpin, and named it miR-299 [1].  Landgraf et al. later show that the 3' product is the predominant one [2].  The 5' miRNA is renamed miR-299* here. 	6
15426	MI0000400	mmu-mir-300	Mus musculus miR-300 stem-loop	GCUACUUGAAGAGAGGUUAUCCUUUGUGUGUUUGCUUUACGCGAAAUGAAUAUGCAAGGGCAAGCUCUCUUCGAGGAGC		6
15427	MI0000401	mmu-mir-301a	Mus musculus miR-301a stem-loop	CCUGCUAACGGCUGCUCUGACUUUAUUGCACUACUGUACUUUACAGCGAGCAGUGCAAUAGUAUUGUCAAAGCAUCCGCGAGCAGG		6
15428	MI0000402	mmu-mir-302a	Mus musculus miR-302a stem-loop	CCACCACUUAAACGUGGUUGUACUUGCUUUAGACCUAAGAAAGUAAGUGCUUCCAUGUUUUGGUGAUGG		6
15429	MI0000403	mmu-mir-34c	Mus musculus miR-34c stem-loop	AGUCUAGUUACUAGGCAGUGUAGUUAGCUGAUUGCUAAUAGUACCAAUCACUAACCACACAGCCAGGUAAAAAGACU	Houbaviy et al. cloned 3 closely related sequences from mouse embryonic stem cells [1], and named them miR-34a, miR-34b and miR-172.  These names have been remapped to miR-34c (MIR:MI0000403), miR-34b (MIR:MI0000404) and miR-34a (MIR:MI0000584) to clarify homology with human sequences. 	6
15430	MI0000404	mmu-mir-34b	Mus musculus miR-34b stem-loop	GUGCUCGGUUUGUAGGCAGUGUAAUUAGCUGAUUGUAGUGCGGUGCUGACAAUCACUAACUCCACUGCCAUCAAAACAAGGCAC	Houbaviy et al. cloned 3 closely related sequences from mouse embryonic stem cells [1], and named them miR-34a, miR-34b and miR-172.  These names have been remapped to miR-34c (MIR:MI0000403), miR-34b (MIR:MI0000404) and miR-34a (MIR:MI0000584) to clarify homology with human sequences.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15431	MI0000405	mmu-let-7d	Mus musculus let-7d stem-loop	AAUGGGUUCCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUAGGGCAGAGAUUUUGCCCACAAGGAGUUAACUAUACGACCUGCUGCCUUUCUUAGGGCCUUAUU	Lagos-Quintana et al. identified let-7d by cloning in a number of mouse tissues [1].  Houbaviy et al. identified an miRNA, let-7d-as, which appears to be cleaved from the opposite strand of the same precursor [2]. Because of the similarity of let-7d to other let-7 miRNAs in a variety of organisms, the miRNA from the 3' arm of the precursor has been named let-7d* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15432	MI0000406	mmu-mir-106a	Mus musculus miR-106a stem-loop	AUGUCAAAGUGCUAACAGUGCAGGUAGCUUUUUGAGUUCUACUGCAGUGCCAGCACUUCUUACAU	Mouse and human miR-106a (MIR:MI0000406 and MIR:MI0000113) differ at two positions but the precursor sequences are clearly closely related.  The sequences are also related to mir-17 (MIR:MI0000071 and MIR:MI0000687). The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15433	MI0000407	mmu-mir-106b	Mus musculus miR-106b stem-loop	CCUGCUGGGACUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCUGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Reference [1] reported the same miRNA sequence with two different identifiers - miR-106b and miR-94.  This sequence maps to mouse chromosome 5. 	6
15434	MI0000408	mmu-mir-130b	Mus musculus miR-130b stem-loop	GGCUUGUUGGACACUCUUUCCCUGUUGCACUACUGUGGGCCUCUGGGAAGCAGUGCAAUGAUGAAAGGGCAUCUGUCGGGCC		6
15435	MI0000409	dme-mir-303	Drosophila melanogaster miR-303 stem-loop	UCUUGGUUUAGGUUUCACAGGAAACUGGUUUAAUAACGAAAACUAGUUUCCUCUAAAAUCCUAAUCAAGA	miR-303 was identified and ends mapped by cloning.  The sequence is localised to chromosome X. 	4
15436	MI0000410	dme-mir-31b	Drosophila melanogaster miR-31b stem-loop	CAAAUAAUGAAUUUGGCAAGAUGUCGGAAUAGCUGAGAGCACAGCGGAUCGAACAUUUUAUCGUCCGAAAAAAUGUGAUUAUUUUUGAAAAGCGGCUAUGCCUCAUCUAGUCAAUUGCAUUACUUUG	miR-31b was identified and ends mapped by cloning.  The sequence is localised to chromosome X. 	4
15437	MI0000411	dme-mir-304	Drosophila melanogaster miR-304 stem-loop	GCAGCAUUGAAUAAUCUCAAUUUGUAAAUGUGAGCGGUUUAAGCCAUUUGACGCACUCACUUUGCAAUUGGAGAUUGCUCGAGACUGC	miR-304 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 21-23 nt, with 23 nt most commonly expressed.  The  sequence is localised to chromosome X. 	4
15438	MI0000412	dme-mir-305	Drosophila melanogaster miR-305 stem-loop	CAUGUCUAUUGUACUUCAUCAGGUGCUCUGGUGUGUCUCGUAACCCGGCACAUGUUGAAGUACACUCAAUAUG	Lai et al. predicted this sequence based on conservation in D. pseudoobscura, but did not verify expression [2].  Aravin et al. describe identification and mapping of the 5' end of the excised sequence by cloning [1].  They report a length distribution of 19-23 nt, with 23 nt most commonly expressed.  The sequence maps to chromosome 2L. 	4
15439	MI0000413	dme-mir-9c	Drosophila melanogaster miR-9c stem-loop	AUUUUUGCUGUUUCUUUGGUAUUCUAGCUGUAGAUUGUUUCACGCACAUUGUAUAUCAUCUAAAGCUUUUAUACCAAAGCUCCAGCUUAAAU	Lai et al. predicted this sequence based on conservation in D. pseudoobscura, but did not verify expression [2].  Aravin et al. describe identification and mapping of the ends of the excised sequence by cloning [1].  The sequence maps to chromosome 2L. 	4
15440	MI0000414	dme-mir-306	Drosophila melanogaster miR-306 stem-loop	GUCCACUCGAUGGCUCAGGUACUUAGUGACUCUCAAUGCUUUUGACAUUUUGGGGGUCACUCUGUGCCUGUGCUGCCAGUGGGAC	miR-306 was identified and ends mapped by cloning.  Reference [1] also identified a less predominantly expressed miR from the opposite arm of the precursor, designated miR-306* here.  The sequence is localised to chromosome X. 	4
15441	MI0000415	dme-mir-9b	Drosophila melanogaster miR-9b stem-loop	UGCAUAUUAUUUGCUCUUUGGUGAUUUUAGCUGUAUGGUGUUUAUGUAUAUUCCAUAGAGCUUUAUUACCAAAAACCAAAUGGUUUCUGCA	Lai et al. predicted this sequence based on conservation in D. pseudoobscura, but did not verify expression [2].  Aravin et al. describe identification and mapping of the 5' end of the excised sequence by cloning [1].  They report a length distribution of 21-23 nt, with 23 nt most commonly expressed.  The sequence maps to chromosome 2L. 	4
15442	MI0000416	dme-let-7	Drosophila melanogaster let-7 stem-loop	UCUGGCAAAUUGAGGUAGUAGGUUGUAUAGUAGUAAUUACACAUCAUACUAUACAAUGUGCUAGCUUUCUUUGCUUGA	let-7 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 20-21 nt, with 21 nt most commonly expressed. The sequence is localised to chromosome 2L. 	4
15443	MI0000417	dme-mir-125	Drosophila melanogaster miR-125 stem-loop	GACAUGUGCAAAUGUUUGUAUGGCUGAUUCCCUGAGACCCUAACUUGUGACUUUUAAUACCAGUUUCACAAGUUUUGAUCUCCGGUAUUGGACGCAAACUUGCUGAUGUU	miR-125 was identified and ends mapped by cloning.  The sequence is localised to chromosome 2L. 	4
15444	MI0000418	dme-mir-307	Drosophila melanogaster miR-307 stem-loop	UGUCUUGCUUUGACUCACUCAACCUGGGUGUGAUGUUAUUUCGAUAUGGUAUCCAUCACAACCUCCUUGAGUGAGCGAUAGCAGGACA	miR-307 was identified and ends mapped by cloning.  The sequence is localised to chromosome 2R. 	4
15445	MI0000419	dme-mir-308	Drosophila melanogaster miR-308 stem-loop	CUCGCAGUAUAUUUUUGUGUUUUGUUUCGUUUUGCAAUCCAAAUCACAGGAUUAUACUGUGAG	miR-308 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 18-22 nt, with 22 nt most commonly expressed.  The  sequence is localised to chromosome 2R. 	4
15446	MI0000420	dme-mir-31a	Drosophila melanogaster miR-31a stem-loop	UCCGUUGGUAAAUUGGCAAGAUGUCGGCAUAGCUGACGUUGAAAAGCGAUUUUGAAGAGCGCUAUGCUGCAUCUAGUCAGUUGUUCAAUGGA	miR-31a was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 22-23 nt, with 23 nt most commonly expressed.  The  sequence is localised to chromosome 2R. 	4
15447	MI0000421	dme-mir-309	Drosophila melanogaster miR-309 stem-loop	AUUAUACGACAAACCUUGUUCGGUUUUGCCAAUUUCCAAGCCAGCACUGGGUAAAGUUUGUCCUAUAAU	miR-309 was identified and ends mapped by cloning.  The sequence is localised to chromosome 2R. 	4
15448	MI0000422	dme-mir-310	Drosophila melanogaster miR-310 stem-loop	AACAUAAACAUUUGCAGGGCGGGUCGUGUGUCAGUGUAUUUAUAUCUUAGCUAUAUUGCACACUUCCCGGCCUUUAAAUGUCCAAUGUU	miR-310 was identified and ends mapped by cloning.  The sequence is localised to chromosome 2R. 	4
15449	MI0000423	dme-mir-311	Drosophila melanogaster miR-311 stem-loop	UCUAGAUCAUUUUUCGGACGGUAUAUGGGUUAAUAUUUCAUUUGUCGAAUAUAUUGCACAUUCACCGGCCUGAAAAUAUCAAGA	miR-311 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 22-23 nt, with 22 nt most commonly expressed.  The  sequence is localised to chromosome 2R. 	4
15450	MI0000424	dme-mir-312	Drosophila melanogaster miR-312 stem-loop	GAUUUGGUUCGUCACAAGGGCAAUUCUGCAUUUUUUAACUAGUAUUGCACUUGAGACGGCCUGAUU	miR-312 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 22-23 nt, with 22 nt most commonly expressed.  The  sequence is localised to chromosome 2R. 	4
15451	MI0000425	dme-mir-313	Drosophila melanogaster miR-313 stem-loop	AUUUUCUGCUGCGGAUGGGGGCAGUACUGUUUUUUUAACAUUGAGUAUUGCACUUUUCACAGCCCGAAAAU	miR-313 was predicted based on conservation of clustering with miR-310 (MIR:MI0000422), miR-311 (MIR:MI0000423) and miR-312 (MIR:MI0000424). Its expression has not been verified. 	4
15452	MI0000426	dme-mir-314	Drosophila melanogaster miR-314 stem-loop	UCGUAACUUGUGUGGCUUCGAACUUACCUAGUUGAGGAAAACUCCCAUGUCGGAUUUUGUUACCUCUGGUAUUCGAGCCAAUAAGUUCGG	miR-314 was identified and ends mapped by cloning.  The sequence is localised to chromosome 3L. 	4
15453	MI0000427	dme-mir-315	Drosophila melanogaster miR-315 stem-loop	CACUUAUAUAAUUUUGAUUGUUGCUCAGAAAGCCCUCAUUGUUUACCAGUUGGCUUUCGAGCAAUAAUUGAAACCAGAUAAGUG	Lai et al. predicted this sequence based on conservation in D. pseudoobscura, but did not verify expression [2].  Aravin et al. describe identification and mapping of the ends of the excised sequence by cloning [1].  The sequence maps to chromosome 3L. 	4
15454	MI0000428	dme-mir-316	Drosophila melanogaster miR-316 stem-loop	AAAUUCUAGUCGAUUUGUCUUUUUCCGCUUACUGGCGUUUCAAUUCCACAACGACAGGAAAGGGAAAAAGGCGUAUUUACUAUGAGUUU	Lai et al. predicted this sequence based on conservation in D. pseudoobscura, but did not verify expression [2].  Aravin et al. describe identification and mapping of the 5' end of the excised sequence by cloning [1].  They report a length distribution of 20-22 nt, with 22 nt most commonly expressed.  The sequence maps to chromosome 3L. 	4
15455	MI0000429	dme-mir-317	Drosophila melanogaster miR-317 stem-loop	AUGCAACUGCCAUUGGGAUACACCCUGUGCUCGCUUUGAAUGAAAUGCAAGCAAGUGAACACAGCUGGUGGUAUCCAGUGGCCGUUUGGCAU	miR-317 was identified and 5' end mapped by cloning.  Reference [1] reports a length distribution of 20-24 nt, with 24 nt most commonly expressed.  The  sequence is localised to chromosome 3R. 	4
15456	MI0000430	dme-mir-318	Drosophila melanogaster miR-318 stem-loop	UUUAUGGGAUACACACAGUUCAGUUUUGUCACACUUCAAGCAUCACUGGGCUUUGUUUAUCUCAUGAG	miR-318 was identified and ends mapped by cloning.  The sequence is localised to chromosome 3R. 	4
15457	MI0000431	dme-mir-2c	Drosophila melanogaster miR-2c stem-loop	UCGUAUCUUACUUUCAAUGUCAUCAAAAAGGGCUGAAGAAAGAUAUUUCUGCAUUUGAAUCGUAUCACAGCCAGCUUUGAUGGGCAUUGCAAUGAGCAGCGA	miR-2c was predicted by similarity to miR-2a (MIR:MI0000117).  Expression in Drosophila was independently confirmed by Northern blot analysis [1] and by cloning [2].  The latter study confirmed the ends of the excised miR. The sequence is localised to chromosome 3R.  Stark et al. [3] have identified targets for miR-2 in Drosophila using computational prediction followed by experimental validation.   miR-2 regulates the proapoptotic genes reaper, grim and sickle, suggesting that it may be involved in the control of apoptosis. 	4
15458	MI0000432	dme-mir-iab-4	Drosophila melanogaster miR-iab-4 stem-loop	UCGUAAACGUAUACUGAAUGUAUCCUGAGUGUAUCCUAUCCGGUAUACCUUCAGUAUACGUAACACGA	iab-4 is a transcript of the Bithorax complex which has been previously shown to contribute to proper formation of abdominal segments [2]. Reference [1] identified a miRNA gene within the transcript and mapped the ends of the mature miR sequence by cloning.  Excised miR sequences were identified from both arms of the precursor and are named miR-iab-4-5p (5') and miR-iab-4-3p (3') as too few sequences were cloned to decide on which was predominantly expressed. 	4
15459	MI0000433	hsa-let-7g	Homo sapiens let-7g stem-loop	AGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2].  let-7g* cloned in [2] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
15460	MI0000434	hsa-let-7i	Homo sapiens let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15461	MI0000437	hsa-mir-1-2	Homo sapiens miR-1-2 stem-loop	ACCUACUCAGAGUACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUGGUAGGC	Lagos-Quintana et al. [1] reported the cloning of miR-1b, miR-1c and miR-1d.  The mature processed miR sequences are identical apart from the 3' residues (A in mir-1b, C in mir-1c and UU in mir-1d).  The 3' residues of both miR-1b and miR-1c conflict with the predicted stem-loop precursor sequence shown here and these sequences are not found in current assemblies of human and mouse genomes.  It is suggested that polyA polymerase may add 1-3 nts to the 3' end of the mature transcript (Tom Tuschl, pers. comm.).  The common 21 nts of the 3 reported miR sequences have been rationalised here and named miR-1.  There are 2 pairs of orthologous putative hairpin precursor structures named mir-1-1 (human MIR:MI0000651, mouse MIR:MI0000139), and mir-1-2 (human MIR:MI0000437, mouse MIR:MI0000652).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15462	MI0000438	hsa-mir-15b	Homo sapiens miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUGCUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-15b in human [2]. 	5
15463	MI0000439	hsa-mir-23b	Homo sapiens miR-23b stem-loop	CUCAGGUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCACGACCUUGGC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15464	MI0000440	hsa-mir-27b	Homo sapiens miR-27b stem-loop	ACCUCUCUAACAAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGUG	Lagos-Quintana et al. determined the expression of miR-27b in mouse [1] - a human sequence was predicted based on homology.  Michael et al. subsequently verified the expression of this miRNA in human cells [2]. 	5
15465	MI0000441	hsa-mir-30b	Homo sapiens miR-30b stem-loop	ACCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15466	MI0000442	hsa-mir-122	Homo sapiens miR-122 stem-loop	CCUUAGCAGAGCUGUGGAGUGUGACAAUGGUGUUUGUGUCUAAACUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGCUAGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15467	MI0000443	hsa-mir-124-1	Homo sapiens miR-124-1 stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG	miR-124 was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15468	MI0000444	hsa-mir-124-2	Homo sapiens miR-124-2 stem-loop	AUCAAGAUUAGAGGCUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	miR-124 was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15469	MI0000445	hsa-mir-124-3	Homo sapiens miR-124-3 stem-loop	UGAGGGCCCCUCUGCGUGUUCACAGCGGACCUUGAUUUAAUGUCUAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGGCGCCUCC	miR-124 was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15470	MI0000446	hsa-mir-125b-1	Homo sapiens miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Its expression was later verified in human BC-1 cells [2]. 	5
15471	MI0000447	hsa-mir-128-1	Homo sapiens miR-128-1 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	5
15472	MI0000448	hsa-mir-130a	Homo sapiens miR-130a stem-loop	UGCUGCUGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUGUCACUAGCAGUGCAAUGUUAAAAGGGCAUUGGCCGUGUAGUG	miR-130a was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2]. 	5
15473	MI0000449	hsa-mir-132	Homo sapiens miR-132 stem-loop	CCGCCCCCGCGUCUCCAGGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACUGGAGGUAACAGUCUACAGCCAUGGUCGCCCCGCAGCACGCCCACGCGC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15474	MI0000450	hsa-mir-133a-1	Homo sapiens miR-133a-1 stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15475	MI0000451	hsa-mir-133a-2	Homo sapiens miR-133a-2 stem-loop	GGGAGCCAAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGACUGUCCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGUGCAUUGAUGGCGCCG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1] later verified in human [2]. 	5
15476	MI0000452	hsa-mir-135a-1	Homo sapiens miR-135a-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCACUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACA	miR-135a was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2]. 	5
15477	MI0000453	hsa-mir-135a-2	Homo sapiens miR-135a-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	miR-135a was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2]. 	5
15478	MI0000454	hsa-mir-137	Homo sapiens miR-137 stem-loop	GGUCCUCUGACUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGGAGAGUACCAGCGGCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15479	MI0000455	hsa-mir-138-2	Homo sapiens miR-138-2 stem-loop	CGUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACGAGCAGCGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUUGCAUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15480	MI0000456	hsa-mir-140	Homo sapiens miR-140 stem-loop	UGUGUCUCUCUCUGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACCGGGGCACC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Its expression was later verified in human [2,3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15481	MI0000457	hsa-mir-141	Homo sapiens miR-141 stem-loop	CGGCCGGCCCUGGGUCCAUCUUCCAGUACAGUGUUGGAUGGUCUAAUUGUGAAGCUCCUAACACUGUCUGGUAAAGAUGGCUCCCGGGUGGGUUC	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-141 in human [2]. 	5
15482	MI0000458	hsa-mir-142	Homo sapiens miR-142 stem-loop	GACAGUGCAGUCACCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Michael et al. verified the expression of a sequence from the 3' arm of this stem-loop (named miR-142-3p here) [2], and both miR-142-5p (from the 5' arm) and miR-142-3p ware later detected in human HL-60 leukemia cells [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15483	MI0000459	hsa-mir-143	Homo sapiens miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUGUUCUGCAGC	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-143 in human, and demonstrated significantly reduced levels of the miRNA in precancerous and neoplastic colorectal tissue [2].  miR-143 cloned in [3] has a 1 nt 3' extension (A), which is incompatible with the genome sequence. 	5
15484	MI0000460	hsa-mir-144	Homo sapiens miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGCGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCCGGGCACCCCC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  The expression of this miRNA has not been verified in human.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15485	MI0000461	hsa-mir-145	Homo sapiens miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-145 in human, and demonstrated significantly reduced levels of the miRNA in precancerous and neoplastic colorectal tissue [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15486	MI0000462	hsa-mir-152	Homo sapiens miR-152 stem-loop	UGUCCCCCCCGGCCCAGGUUCUGUGAUACACUCCGACUCGGGCUCUGGAGCAGUCAGUGCAUGACAGAACUUGGGCCCGGAAGGACC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15487	MI0000463	hsa-mir-153-1	Homo sapiens miR-153-1 stem-loop	CUCACAGCUGCCAGUGUCAUUUUUGUGAUCUGCAGCUAGUAUUCUCACUCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGCAGGUGUGGC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15488	MI0000464	hsa-mir-153-2	Homo sapiens miR-153-2 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15489	MI0000465	hsa-mir-191	Homo sapiens miR-191 stem-loop	CGGCUGGACAGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCGCUUGGAUUUCGUCCCCUGCUCUCCUGCCU	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  The expression of this miRNA was later confirmed in human HL-60 leukemia cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15490	MI0000466	hsa-mir-9-1	Homo sapiens miR-9-1 stem-loop	CGGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15491	MI0000467	hsa-mir-9-2	Homo sapiens miR-9-2 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15492	MI0000468	hsa-mir-9-3	Homo sapiens miR-9-3 stem-loop	GGAGGCCCGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUGCCACAGAGCCGUCAUAAAGCUAGAUAACCGAAAGUAGAAAUGAUUCUCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15493	MI0000469	hsa-mir-125a	Homo sapiens miR-125a stem-loop	UGCCAGUCUCUAGGUCCCUGAGACCCUUUAACCUGUGAGGACAUCCAGGGUCACAGGUGAGGUUCUUGGGAGCCUGGCGUCUGGCC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15494	MI0000470	hsa-mir-125b-2	Homo sapiens miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Its expression was later verified in human BC-1 cells [2]. 	5
15495	MI0000471	hsa-mir-126	Homo sapiens miR-126 stem-loop	CGCUGGCGACGGGACAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGCCGUCCACGGCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  The expression of this miRNA has not been verified in human.  miR-123 identified in the same mouse study was later found to originate from the same precursor as miR-126 and was hence renamed miR-126*.  miR-126* also appears to be conserved in human.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15496	MI0000472	hsa-mir-127	Homo sapiens miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  The expression of this miRNA was later confirmed by cloning in human cells [2,3]. 	5
15497	MI0000473	hsa-mir-129-2	Homo sapiens miR-129-2 stem-loop	UGCCCUUCGCGAAUCUUUUUGCGGUCUGGGCUUGCUGUACAUAACUCAAUAGCCGGAAGCCCUUACCCCAAAAAGCAUUUGCGGAGGGCG	This miRNA sequence was predicted based on homology to a verified miRNA cloned from mouse cerebellum [1].  Expression of this miRNA was subsequently verified in a human osteoblast sarcoma cell line [2]. Reference [2] named the human/mouse conserved sequence miR-129b, but subsequent genome searches suggest that the same mature sequence may be expressed from two predicted hairpin precursors in both human (this entry and MIR:MI0000252) and mouse (MIR:MI0000222 and MIR:MI0000585).  Landgraf et al. show that the 5' product of mir-129-1 (MIR:MI0000222) is the predominant one, whereas both 5' and 3' products are significantly expressed from mir-129-2 (this entry) [3]. 	5
15498	MI0000474	hsa-mir-134	Homo sapiens miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCAUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC	miR-134 was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15499	MI0000475	hsa-mir-136	Homo sapiens miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU	miR-136 was first identified by cloning studies in mouse [1].  Its expression was later verified in human embryonic stem cells [2]. 	5
15500	MI0000476	hsa-mir-138-1	Homo sapiens miR-138-1 stem-loop	CCCUGGCAUGGUGUGGUGGGGCAGCUGGUGUUGUGAAUCAGGCCGUUGCCAAUCAGAGAACGGCUACUUCACAACACCAGGGCCACACCACACUACAGG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Expression in human was later validated by cloning [2,3]. 	5
15501	MI0000477	hsa-mir-146a	Homo sapiens miR-146a stem-loop	CCGAUGUGUAUCCUCAGCUUUGAGAACUGAAUUCCAUGGGUUGUGUCAGUGUCAGACCUCUGAAAUUCAGUUCUUCAGCUGGGAUAUCUCUGUCAUCGU	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Its expression was later verified in human [2,3]. 	5
15502	MI0000478	hsa-mir-149	Homo sapiens miR-149 stem-loop	GCCGGCGCCCGAGCUCUGGCUCCGUGUCUUCACUCCCGUGCUUGUCCGAGGAGGGAGGGAGGGACGGGGGCUGUGCUGGGGCAGCUGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15503	MI0000479	hsa-mir-150	Homo sapiens miR-150 stem-loop	CUCCCCAUGGCCCUGUCUCCCAACCCUUGUACCAGUGCUGGGCUCAGACCCUGGUACAGGCCUGGGGGACAGGGACCUGGGGAC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15504	MI0000480	hsa-mir-154	Homo sapiens miR-154 stem-loop	GUGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	miR-154 is predicted based on homology to a verified miRNA from mouse (MIR:MI0000176) [1].  Its expression was verifed later in human cell lines [3].  Suh et al. [2] have cloned a sequence from human ES cells, which appears to originate from the opposite arm of this hairpin precursor, so is named miR-154* here. 	5
15505	MI0000481	hsa-mir-184	Homo sapiens miR-184 stem-loop	CCAGUCACGUCCCCUUAUCACUUUUCCAGCCCAGCUUUGUGACUGUAAGUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15506	MI0000482	hsa-mir-185	Homo sapiens miR-185 stem-loop	AGGGGGCGAGGGAUUGGAGAGAAAGGCAGUUCCUGAUGGUCCCCUCCCCAGGGGCUGGCUUUCCUCUGGUCCUUCCCUCCCA	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1].  Its expression was later verified in human BC-1 cells [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15507	MI0000483	hsa-mir-186	Homo sapiens miR-186 stem-loop	UGCUUGUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGGUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU	This miRNA sequence is predicted based on homology to a verified miRNA from mouse.  Expression of this miRNA was also verified in a human osteoblast sarcoma cell line [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15508	MI0000484	hsa-mir-188	Homo sapiens miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUUUCUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGCGAGCC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15509	MI0000486	hsa-mir-190	Homo sapiens miR-190 stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCUUGCC	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15510	MI0000487	hsa-mir-193a	Homo sapiens miR-193a stem-loop	CGAGGAUGGGAGCUGAGGGCUGGGUCUUUGCGGGCGAGAUGAGGGUGUCGGAUCAACUGGCCUACAAAGUCCCAGUUCUCGGCCCCCG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15511	MI0000488	hsa-mir-194-1	Homo sapiens miR-194-1 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-194 in human [2].  Two putative pairs of orthologous hairpin precursors structures are found in mouse (mir-194-1 (MIR:MI0000236) on chromosome 1, and mir-194-2 (MIR:MI0000733) on chromosome 19) and human (mir-194-1 (MIR:MI0000488) on chromosome 1, and mir-194-2 (MIR:MI0000732) on chromosome 11). 	5
15512	MI0000489	hsa-mir-195	Homo sapiens miR-195 stem-loop	AGCUUCCCUGGCUCUAGCAGCACAGAAAUAUUGGCACAGGGAAGCGAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15513	MI0000490	hsa-mir-206	Homo sapiens miR-206 stem-loop	UGCUUCCCGAGGCCACAUGCUUCUUUAUAUCCCCAUAUGGAUUACUUUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCGGCAAGUG	This miRNA sequence is predicted based on homology to a verified miRNA from mouse [1], later verified in human [2]. 	5
15514	MI0000491	cbr-let-7	Caenorhabditis briggsae let-7 stem-loop	ACUGGGGUACGGUGAGGUAGUAGGUUGUAUAGUUUAGAAUAUUACUCUCGGUGAACUAUGCAAGUUUCUACCUCACCGAAUACCAGG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15515	MI0000492	cbr-lin-4	Caenorhabditis briggsae lin-4 stem-loop	AUCAGAUGCUUUCGGCCUGUUCCCUGAGACCUCAAGUGUGAGCGUUCUGAACAUGCUUCACGCCUGGGCUCUCCGGGUACCAGGACGGUCUGAG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15516	MI0000493	cbr-mir-1	Caenorhabditis briggsae miR-1 stem-loop	UGCUGUGCCGAGCUGCAUACUUCCUUACAUGCCCAUACUGUACUGUGAAUGGAUAUGGAAUGUAAAGAAGUAUGUAGAACGGAAUCUAACGGCG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15517	MI0000494	cbr-mir-34	Caenorhabditis briggsae miR-34 stem-loop	AAGCACUCAUGGUCGUGAGGCAGUGUGGUUAGCUGGUUGCAUACACAGGUUGACAACGGCUACCUUCACUGCCACCCCGAACAUGUAGUCCUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15518	MI0000495	cbr-mir-42	Caenorhabditis briggsae miR-42 stem-loop	UAACCCUUGUCGGACCUUUGUGGGUGUUCGCCUUUUCGGUGAAGUUACUGAAUGCUUCUUCACCGGGUUAACAUCUACAGAGGUCCUAAAGGGUUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15519	MI0000496	cbr-mir-43	Caenorhabditis briggsae miR-43 stem-loop	AGGCGAUUCUGCCCGUGACAUCAAGAUGCUUGUGAUUAUGCGAAAAUGUUGGGACAUAUCACAGUUUACUUGCUGUCGCAGGCGGAUUAUUGCUA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15520	MI0000497	cbr-mir-44	Caenorhabditis briggsae miR-44 stem-loop	GAGAAGGGCCGAUCUGGAUGUGCUCGUUAGUCAUAGACGAAUCACACUUGAAAGGUCAUAUGACUAGAGACACAUUCAGCUUGGCCUGGAUCUCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15521	MI0000498	cbr-mir-45-1	Caenorhabditis briggsae miR-45-1 stem-loop	AGUGCCACGCUGGAUGUGCUCGUUAGUCAUAGUAACCUCAUCAAUUCAGGCUUAUGACUAGAGACACAUUCAGCUUGGCGCC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15522	MI0000499	cbr-mir-45-2	Caenorhabditis briggsae miR-45-2 stem-loop	AGUGCCACGCUGGAUGUGUUCGUUAGUCAUAGUAACCUCAUCAAUUCAGGCUUAUGACUAGAGACACAUUCAGCUUGGCGCC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15523	MI0000500	cbr-mir-46	Caenorhabditis briggsae miR-46 stem-loop	GAGAUACAAGUGAAGCUGAAGAGAGCCGUCUAUUGACAGUUCGCUUGUUUCAUGUGCUGUCAUGGAGUCGCUCUCUUCAGAUGAUCUGAAUCUA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15524	MI0000501	cbr-mir-47	Caenorhabditis briggsae miR-47 stem-loop	UAGCUGAGGAAGACUGAAGGGAGCUUUCUUUUGACAGUUCGAUUUCGAACUCUUACUGUCAUGGAGGCGCUCUCUUCAGGUGAACUCUGGCUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15525	MI0000502	cbr-mir-48	Caenorhabditis briggsae miR-48 stem-loop	AGAACCAUUCGGGAUGUUGAGGUAGGCUCAGUAGAUGCGAGGAGAUCCACCAUUCCUCACAUCGUCUGUCCUAACUCGCCUUCCCUUGUGCUUCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15526	MI0000503	cbr-mir-49	Caenorhabditis briggsae miR-49 stem-loop	ACCGAAACCAUUUGCCAUCCGCAGUUUUUUGUAGUGUGCUCCGCGCCAUCUUAGUGCCCGAAGCACCACGAGAAGCUGCAGAUGGAAGUUUUGGUU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15527	MI0000504	cbr-mir-50	Caenorhabditis briggsae miR-50 stem-loop	UUCCACCCACCGGCCGCUGAUAUGUCUGAUAUUCUUGGGUUAUCUGAUAAUGAUUGUUGUAACUCAAGUAUUAGACGUAUCGACGGCCGGCUGGGUUGGAA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15528	MI0000505	cbr-mir-52	Caenorhabditis briggsae miR-52 stem-loop	UUUCCCGCUCUGACAGUCCACCCGUACAUAUGUUUCCGUGCUUGACAUAGAGCUCAAUCACGAUACAAUGAGCGGGUAGCCGGUCAUCGAGUCGGAAC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15529	MI0000507	cbr-mir-57	Caenorhabditis briggsae miR-57 stem-loop	GCUCUGAGUUCGUCUACCCUGUAGAUCGAGCUGUGUGUUCUGAAGUAUCAUACACGAGCUAGACUACUAGGUGAACGAUGGAAUGGAGCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15530	MI0000508	cbr-mir-58	Caenorhabditis briggsae miR-58 stem-loop	AUCCAUUGCCCUACUAUUCGCAUCUCAUCACUCCAGUAUAUAUAUAUAUAUAUAAGGAUGAGAUCGUUCAGUACGGCAAUGGAA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15531	MI0000509	cbr-mir-60	Caenorhabditis briggsae miR-60 stem-loop	UUCUUGAGCUGGAAAGGUGACAUAAAAUCAUGUCCAAGCACGCGAUAUUAUGCACAUUUUCUAGUCCAAGAC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15532	MI0000510	cbr-mir-67	Caenorhabditis briggsae miR-67 stem-loop	UAGAUAUUUCGAUCAACUCAUUCUGCUGGUUGUUAUGCUGACAAUUGAUGAUUAAGCAUCACAACCUCCUAGAAAGAGUAGACCGAUUCUAUCUU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15533	MI0000511	cbr-mir-71	Caenorhabditis briggsae miR-71 stem-loop	AGCUGAACGAUGAAAGACAUGGGUAGUGAGACGUCGGAGCCUCGUCGUAUCACUAUUCUGUUUUUCGCCGAUCAGUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15534	MI0000512	cbr-mir-73	Caenorhabditis briggsae miR-73 stem-loop	CGGUCCCUCAAACAACCGAGCUUCCCCGUCAAGCCACAGCUAUCUCUGACAUUGCUGGCAAGAUGUUGGCAGUUCAGUUGUAUGACGGAGACCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15535	MI0000513	cbr-mir-74	Caenorhabditis briggsae miR-74 stem-loop	CGCACUUUUGGGCUUCCAUAUCUUUCCCAGCUCCUCUCAUUUACUAUGGAUGCUGGCAAGAAAUGGCAGUCUAGAUGUGCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15536	MI0000514	cbr-mir-75	Caenorhabditis briggsae miR-75 stem-loop	UGCGAGACCGAAUUGCAGUCGGUUGCAAGCUUCAAUACAGACAAUGGUUCUUGAUAUUAAAGCUACCAACCGCCUUCAAAUCGUGCAUCGCG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15537	MI0000515	cbr-mir-77	Caenorhabditis briggsae miR-77 stem-loop	GAGCUGUGAAUUUGGAUAGCUGUGCUCUGAGGAAAUAACAAUAGUCACACCCCAUGUCAUUUCAUCAGGCCAUAGCUGUCCAAAUUUCUCGGUUCG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae.  The hairpin precursor sequence represented here matches two positions on FPC contig 2260 in the C. briggsae genome sequence. 	2
15538	MI0000517	cbr-mir-79	Caenorhabditis briggsae miR-79 stem-loop	AGAACAUUCUCCGAUCUUUGGUGAUUCAGCUUAAAUGAUAGAAUUCAGACGUCUUCAUAAAGCUAGGUUACCAAAGCUCGGCGUUCCAGUUCG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15539	MI0000518	cbr-mir-80	Caenorhabditis briggsae miR-80 stem-loop	UGGACACUCUUUCGCUCAGCUUUCGACAUGAUUCUAAACAAUACGCUGUCGCAAUGUUGUUGAGAUCAUUAGUUGAAAGCCGAACGAUUCGAGAUAUCCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1,2].  The expression of this miRNA has not been verified in C. briggsae. 	2
15540	MI0000519	cbr-mir-81	Caenorhabditis briggsae miR-81 stem-loop	CGUGAUUAACGGUCGGUUUUCACCUUGAUCUGAGAGCAAUAACCAGAAUGCUUAUCUGAGAUCAUCGUGAAAGCUAGUUGUUACUUCACU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15541	MI0000520	cbr-mir-82	Caenorhabditis briggsae miR-82 stem-loop	AAGUUCUUCUAGCGACAGGUUUUCGCCGUGAUCUGCAGAGUUCCAUGAAGAAAACAUCUGAGAUCAUCGUGAAAGCCAGUUGCUUAAGAGGACUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15542	MI0000521	cbr-mir-85	Caenorhabditis briggsae miR-85 stem-loop	CCCCGGUGCCCGCUUUUUCAGUAGUUUGAAACCAGAGAUGAUAGUUGGUUACAAAGUAUUUGAAAAGGCGUGCACUGGGU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15543	MI0000522	cbr-mir-86	Caenorhabditis briggsae miR-86 stem-loop	CGAGUCAAUGCCGUUUAAGUGAAUGCUUUGCCACAGUCUUCGAUCAUGUCACAUGAAGCCUGGGCUUAGAUUCACUUAGGCCGGCGUUCCUUGACUCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15544	MI0000523	cbr-mir-87	Caenorhabditis briggsae miR-87 stem-loop	GGUUGUGCCCACCCGGCCGCCUGAUACUUUCGUCUCAACCUCGCUGUCAGAAUGUCGUAGGUGAGCAAAGUUUCAGGUGUGCCGGAACACACCCA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15545	MI0000524	cbr-mir-90	Caenorhabditis briggsae miR-90 stem-loop	CGCACUCAUUUCAAGCGGCUUUCAACGACUAUAUCAACCAAAUCAAGCUAGAUACGUUGAUAUGUUGUUUGAAUGCCCCUUGAGAUUUUGGAGUGUU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15546	MI0000525	cbr-mir-124	Caenorhabditis briggsae miR-124 stem-loop	UUUCCAGUCGUCAUAUGGCGUCCACCUGAGUGACUUUAGUGGACAUGUAUAGUUUCCAACUAAGGCACGCGGUGAAUGCCACGUGGCAAUUCUGGGAU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15547	MI0000526	cbr-mir-228	Caenorhabditis briggsae miR-228 stem-loop	AUCCCACCCUGUUCGCAAUGGCACUGCAUGAAUUCACGGAUGCAAAGCGACAGACCGCGGAUCAUGCGGUACCAUAGCUGACGGUGGUGAGAU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15548	MI0000527	cbr-mir-230	Caenorhabditis briggsae miR-230 stem-loop	AAAAUGCCUUACCGAUACUUGGUCGACAAUUUAAUAGUAUCUGAUUAAUUGAUGGAUAGUAUUAGUUGUGCGACCAGGAAAUGGUAUGAGCAUUUC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15549	MI0000528	cbr-mir-232	Caenorhabditis briggsae miR-232 stem-loop	AUUCAAGAUUUCGGAUCUCCGUAGUUUUGACCAUUUUAUCCAACCUAAUAAUGUGAUAAAUGCAUCUUAACUGCGGUGAUCUGGAUUUUGUGAAC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae.  The hairpin precursor sequence represented here matches two positions on FPC contig 143 in the C. briggsae genome sequence. 	2
15550	MI0000530	cbr-mir-233	Caenorhabditis briggsae miR-233 stem-loop	AAGCAUUUUUCUGUCCCGCGCAUCCCUUUGUUCCAAUAUUCAAACCAGUAGAAAGAUUAUUGAGCAAUGCGCAUGUGCGGGACAGAUUGAAUAGCUG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15551	MI0000531	cbr-mir-234	Caenorhabditis briggsae miR-234 stem-loop	GACUCUAGCAAAGAUCAAACGGUAUUCCUGAGUGAAUAAUAAAAAUGAGUCCAUUCUAUUAUUGCUCGAGAAUACCCUUUGACAAGCUGAAAAGUG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15552	MI0000532	cbr-mir-236	Caenorhabditis briggsae miR-236 stem-loop	AAGUGACCAAUGUCCAGCGUCUUACCUGUUCAAUAUUUAGACUGACCAAACCCAUAGCUCUAAUACUGUCAGGUAAUGACGCUGGAUAGUCUUGUCAUUG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15553	MI0000533	cbr-mir-241	Caenorhabditis briggsae miR-241 stem-loop	ACGGUGUCAAAGCUGAGGUAGGUGUGAGAAAUGACGAAAGGCUCUUAAUCGUUUCAUUGUCUCGCAGCUGCUUCAACUGUGAUUUACCGA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15554	MI0000534	cbr-mir-244	Caenorhabditis briggsae miR-244 stem-loop	ACCCAAAUUUCUCGAUUUCUUUGGUUGUACAAAGUGGUAUGGCUCUCUUGCUCAUACCGCUUUACAGCUAAAGGAAUCGAUUGAUUUUGGA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15555	MI0000535	cbr-mir-245	Caenorhabditis briggsae miR-245 stem-loop	UCAAUGUCGAAGAGCUGCUUGCAAGGUACCUAAUUGUUUGACUCUAUUCUCAAUUGGUCCCCUCCAAGUAGCUCUAUUGCAUUGU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15556	MI0000536	cbr-mir-248	Caenorhabditis briggsae miR-248 stem-loop	UGCAAACUGAUAUUCACGAUAAGCGCUAUCCUUCCGUUGUAUUCAAGCUUGGUUGUCGAGUACACGUGCUCGGAUAACGCUCAUCGAGUCUGAUCGGUUAUGUU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15557	MI0000537	cbr-mir-250	Caenorhabditis briggsae miR-250 stem-loop	UCUUCGGACCACGCCUUCAGUUGCCUCGUGAUCCGCCGAAUCUGUAAUGGACGAAUCACAGUCAACUGUUGGCACGGUCCUUGAAGU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15558	MI0000538	cbr-mir-251	Caenorhabditis briggsae miR-251 stem-loop	CCCAAAUGACAUCUCGUUAAGUAGUGGUGCCGCUCUUAUUAGAAUUAUCAAGUAAUAAGAGUUGUUCGCUACUUAACGAGAGGAAAUUUGGA	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15559	MI0000539	cbr-mir-252	Caenorhabditis briggsae miR-252 stem-loop	AGGUCUCUCCCAGUUAUAAGUAGUAGUGCCGCAGGUAACCGCUUCCAGAAAAUUGGUUUACCUACUGCCUUCUGCUUAGAAUUGGGAUUUUGAUGACCG	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15560	MI0000540	cbr-mir-259	Caenorhabditis briggsae miR-259 stem-loop	AGUCAUCGAAACGAGUAAAUCUCAUCCUAAUCUGGUUGCAUUUUCAAUACUUUUUGCUACCGAUUUGGUUUGGGAUUGGCUUGUCUAGUAUUGAC	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15561	MI0000541	cbr-mir-268	Caenorhabditis briggsae miR-268 stem-loop	UGAAGCGGCAAGAAUUAGAAGCAGUUUUGGUGUCAGACACACUCACUGACUCACUGCUUCUUGUUUUUCUUCUUCUUCU	This miRNA sequence is predicted based on homology to a verified miRNA from C. elegans [1].  The expression of this miRNA has not been verified in C. briggsae. 	2
15562	MI0000542	hsa-mir-320a	Homo sapiens miR-320a stem-loop	GCUUCGCUCCCCUCCGCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGAAAAAGGAUGAGGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15563	MI0000544	ath-MIR319a	Arabidopsis thaliana miR319a stem-loop	AGAGAGAGCUUCCUUGAGUCCAUUCACAGGUCGUGAUAUGAUUCAAUUAGCUUCCGACUCAUUCAUCCAAAUACCGAGUCGCCAAAAUUCAAACUAGACUCGUUAAAUGAAUGAAUGAUGCGGUAGACAAAUUGGAUCAUUGAUUCUCUUUGAUUGGACUGAAGGGAGCUCCCUCU	The A. thaliana jaw-D mutant has crinkly leaves and fruits, delayed flowering time and greenish petals.  The jaw-D phenotype is caused by the over-expression of miR319 (also therefore known as miR-JAW), which is produced from a ~500 base long primary transcript RNA [1].  The mir-JAW microRNA is expressed in two forms, 20 and 21 nt, differing by the presence of the 3' terminal U.  Cloned microRNA sequence was obtained from the jaw-D mutant.  This miR has been shown targets TCP genes for cleavage [1].  This sequence is located on BAC F9D16.  miR-JAW has a homologue located in BAC MBK23 (MIR:MI0000545).  The mature excised miR shows sequence similarity to miR159 (MIR:MI0000189, MIR:MI0000218). 	1
15564	MI0000545	ath-MIR319b	Arabidopsis thaliana miR319b stem-loop	AGAGAGCUUUCUUCGGUCCACUCAUGGAGUAAUAUGUGAGAUUUAAUUGACUCUCGACUCAUUCAUCCAAAUACCAAAUGAAAGAAUUUGUUCUCAUAUGGUAAAUGAAUGAAUGAUGCGAGAGACAAAUUGAGUCUUCACUUCUCUAUGCUUGGACUGAAGGGAGCUCCCU	This sequence is a homologue of miR319a (MIR:MI0000544) -- also called miR-JAW -- and is located on BAC MBK23. 	1
15565	MI0000546	mmu-mir-19b-2	Mus musculus miR-19b-2 stem-loop	ACUUACGAUUAGUUUUGCAGAUUUGCAGUUCAGCGUAUAUGUGAAUAUAUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGGGA	Mouse miR-19b was cloned from mouse tissues by independent groups [1,2]. There are two predicted hairpin precursors, with closely related human homologues [4]: mir-19b-1 (MIR:MI0000718) on chromosome 14, and mir-19b-2 (previously named mir-19b here, MIR:MI0000546) on mouse chromosome X. 	6
15566	MI0000547	mmu-mir-30c-1	Mus musculus miR-30c-1 stem-loop	ACCAUGUUGUAGUGUGUGUAAACAUCCUACACUCUCAGCUGUGAGCUCAAGGUGGCUGGGAGAGGGUUGUUUACUCCUUCUGCCAUGGA		6
15567	MI0000548	mmu-mir-30c-2	Mus musculus miR-30c-2 stem-loop	GAGUGACAGAUAUUGUAAACAUCCUACACUCUCAGCUGUGAAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUCUCUGCCUU	miR-30c was cloned and mapped to chromosome 4 in reference [1] (MIR:MI0000547).  A search of more recent mouse genome assemblies suggests the presence of a second locus encoding miR-30c on chromosome 1, represented by this entry. 	6
15568	MI0000549	mmu-mir-30d	Mus musculus miR-30d stem-loop	AAGUCUGUGUCUGUAAACAUCCCCGACUGGAAGCUGUAAGCCACAGCCAAGCUUUCAGUCAGAUGUUUGCUGCUACUGGCUC		6
15569	MI0000550	mmu-mir-148a	Mus musculus miR-148a stem-loop	AGCCAGUUUGGUCUUUUGAGACAAAGUUCUGAGACACUCCGACUCUGAGUAUGAUAGAAGUCAGUGCACUACAGAACUUUGUCUCUAGAGGCUGUGGUC	This sequence was previsouly named mir-148 here and in [1], but is renamed to avoid confusion with mir-148b (MIR:MI0000617).  This sequence maps to mouse chromosome 6. 	6
15570	MI0000551	mmu-mir-192	Mus musculus miR-192 stem-loop	CGUGCACAGGGCUCUGACCUAUGAAUUGACAGCCAGUACUCUUUUCUCUCCUCUGGCUGCCAAUUCCAUAGGUCACAGGUAUGUUCACC		6
15571	MI0000552	mmu-mir-196a-1	Mus musculus miR-196a-1 stem-loop	UGAGCCGGGACUGUUGAGUGAAGUAGGUAGUUUCAUGUUGUUGGGCCUGGCUUUCUGAACACAACGACAUCAAACCACCUGAUUCAUGGCAGUUACUGCUUC	Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196.  Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15572	MI0000553	mmu-mir-196a-2	Mus musculus miR-196a-2 stem-loop	AGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUC	Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196.  Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15573	MI0000554	mmu-mir-200a	Mus musculus miR-200a stem-loop	CUGGGCCUCUGUGGGCAUCUUACCGGACAGUGCUGGAUUUCUUGGCUUGACUCUAACACUGUCUGGUAACGAUGUUCAAAGGUGACCCAC		6
15574	MI0000555	mmu-mir-208a	Mus musculus miR-208a stem-loop	UUCCUUUGACGGGUGAGCUUUUGGCCCGGGUUAUACCUGACACUCACGUAUAAGACGAGCAAAAAGCUUGUUGGUCAGAGGAG		6
15575	MI0000556	mmu-let-7a-1	Mus musculus let-7a-1 stem-loop	UUCACUGUGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUAAGGUGAU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15576	MI0000557	mmu-let-7a-2	Mus musculus let-7a-2 stem-loop	CUGCAUGUUCCCAGGUUGAGGUAGUAGGUUGUAUAGUUUAGAGUUACAUCAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCUUGGGACUUGCAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15577	MI0000558	mmu-let-7b	Mus musculus let-7b stem-loop	GCAGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGCAGUGAUGUUGCCCCUCCGAAGAUAACUAUACAACCUACUGCCUUCCCUGA		6
15578	MI0000559	mmu-let-7c-1	Mus musculus let-7c-1 stem-loop	UGUGUGCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGCACACU		6
15579	MI0000560	mmu-let-7c-2	Mus musculus let-7c-2 stem-loop	ACGGCCUUUGGGGUGAGGUAGUAGGUUGUAUGGUUUUGGGCUCUGCCCCGCUCUGCGGUAACUAUACAAUCUACUGUCUUUCCUGAAGUGGCCGC		6
15580	MI0000561	mmu-let-7e	Mus musculus let-7e stem-loop	CGCGCCCCCCGGGCUGAGGUAGGAGGUUGUAUAGUUGAGGAAGACACCCGAGGAGAUCACUAUACGGCCUCCUAGCUUUCCCCAGGCUGCGCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15581	MI0000562	mmu-let-7f-1	Mus musculus let-7f-1 stem-loop	AUCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUUAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15582	MI0000563	mmu-let-7f-2	Mus musculus let-7f-2 stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15583	MI0000564	mmu-mir-15a	Mus musculus miR-15a stem-loop	CCCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUGUUGAAAAGGUGCAGGCCAUACUGUGCUGCCUCAAAAUACAAGGA		6
15584	MI0000565	mmu-mir-16-1	Mus musculus miR-16-1 stem-loop	AUGUCAGCGGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUGAAAUUACCUCCAGUAUUGACUGUGCUGCUGAAGUAAGGUUGGCAA	This sequence is a clear homologue of human mir-16 and maps to mouse chromosome 14 [1].  A search of NCBIM30 genome assembly suggests a possible second hairpin precursor for miR-16 (MIR:MI0000566). 	6
15585	MI0000566	mmu-mir-16-2	Mus musculus miR-16-2 stem-loop	CAUGCUUGUUCCACUCUAGCAGCACGUAAAUAUUGGCGUAGUGAAAUAAAUAUUAAACACCAAUAUUAUUGUGCUGCUUUAGUGUGACAGGGAUA		6
15586	MI0000567	mmu-mir-18a	Mus musculus miR-18a stem-loop	UGCGUGCUUUUUGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGACUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCAUAAGAAGUUAUGUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	6
15587	MI0000568	mmu-mir-20a	Mus musculus miR-20a stem-loop	GUGUGAUGUGACAGCUUCUGUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUGUAGCCAUCUACUGCAUUACGAGCACUUAAAGUACUGCCAGCUGUAGAACUCCAG		6
15588	MI0000569	mmu-mir-21	Mus musculus miR-21 stem-loop	UGUACCACCUUGUCGGAUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUCUGACAUUUUGGUAUC		6
15589	MI0000570	mmu-mir-22	Mus musculus miR-22 stem-loop	ACCUGGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCCCCUGGC		6
15590	MI0000571	mmu-mir-23a	Mus musculus miR-23a stem-loop	CGGACGGCUGGGGUUCCUGGGGAUGGGAUUUGAUGCCAGUCACAAAUCACAUUGCCAGGGAUUUCCAACUGACCC		6
15591	MI0000572	mmu-mir-24-2	Mus musculus miR-24-2 stem-loop	GCCUCUCUCCGGGCUCCGCCUCCCGUGCCUACUGAGCUGAAACAGUUGAUUCCAGUGCACUGGCUCAGUUCAGCAGGAACAGGAGUCCAGCCCCCUAGGAGCUGGCA		6
15592	MI0000573	mmu-mir-26a-1	Mus musculus miR-26a-1 stem-loop	AAGGCCGUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAGGGGCCUAUUCUUGGUUACUUGCACGGGGACGCGGGCCUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15593	MI0000575	mmu-mir-26b	Mus musculus miR-26b stem-loop	UGCCCGGGACCCAGUUCAAGUAAUUCAGGAUAGGUUGUGGUGCUGACCAGCCUGUUCUCCAUUACUUGGCUCGGGGGCCGGUGCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [6]. 	6
15594	MI0000576	mmu-mir-29a	Mus musculus miR-29a stem-loop	ACCCCUUAGAGGAUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAGAAUUUUCUAGCACCAUCUGAAAUCGGUUAUAAUGAUUGGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15595	MI0000577	mmu-mir-29c	Mus musculus miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15596	MI0000578	mmu-mir-27a	Mus musculus miR-27a stem-loop	UGGCCUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAAGGUCCACAGCAAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCUGGACCC	This sequence maps to mouse chromosome 8. 	6
15597	MI0000579	mmu-mir-31	Mus musculus miR-31 stem-loop	UGCUCCUGUAACUCGGAACUGGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGAGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCCUGUCUGACAGCAGCU	This sequence maps to mouse chromosome 4. 	6
15598	MI0000580	mmu-mir-92a-2	Mus musculus miR-92a-2 stem-loop	UGCCCAUUCAUCCACAGGUGGGGAUUGGUGGCAUUACUUGUGUUAGAUAUAAAGUAUUGCACUUGUCCCGGCCUGAGGAAGAAAGAGGGUU		6
15599	MI0000581	mmu-mir-93	Mus musculus miR-93 stem-loop	AGUCAUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUAAUUACCUGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCAGGACA		6
15600	MI0000583	mmu-mir-96	Mus musculus miR-96 stem-loop	CCAGUACCAUCUGCUUGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUGUGAGCAAUCAUGUGUAGUGCCAAUAUGGGAAAAGCGGGCUGCUGC		6
15601	MI0000584	mmu-mir-34a	Mus musculus miR-34a stem-loop	CCAGCUGUGAGUAAUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGUAUUAGCUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACAUUGU	Houbaviy et al. cloned this miRNA from embryonic stem cells and named it miR-172 [1].  This sequence is homologous to human miR-34a (MIR:MI0000268), and so is renamed miR-34a here.  This sequence is not related to miR172 from plants (MIR:MI0000215 and MIR:MI0000216).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15602	MI0000585	mmu-mir-129-2	Mus musculus miR-129-2 stem-loop	UGCCUUUCGCGAAUCUUUUUGCGGUCUGGGCUUGCUGUACAUAACUCAAUAGCCGGAAGCCCUUACCCCAAAAAGCAUUCGCGGAGGGCG	The miRNA from the 5' arm of this precursor was verified by cloning in mouse [1].  Reference [2] named the human/mouse conserved sequence miR-129b, but subsequent genome searches suggest that the same mature sequence may be expressed from two predicted hairpin precursors in both mouse (this entry and MIR:MI0000222) and human (MIR:MI0000252 and MIR:MI0000473).  Poy et al. independently cloned a mature miRNA from the 3' arm of the precursor, called mmu-miR-129-3p [3].  This sequence is not perfectly conserved in the other predicted mouse miR-129 precursor (MIR:MI0000222).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15603	MI0000586	mmu-mir-98	Mus musculus miR-98 stem-loop	CUGCACAUGCUGGGGUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUUUUAGGCCCCAGUAAGAAGAUAACUAUACAACUUACUACUUUCCUUGGUGUGUGGCAU		6
15604	MI0000587	mmu-mir-103-1	Mus musculus miR-103-1 stem-loop	UUCUUACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUGAGAC	This miRNA sequence was predicted based on homology to a verified miRNA from human [1], and subsequently verified by cloning [2-4]. 	6
15605	MI0000588	mmu-mir-103-2	Mus musculus miR-103-2 stem-loop	GUCUUCGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUUCAGGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACCAAGAA	This miRNA sequence was predicted based on homology to a verified miRNA from human [1], and subsequently verified by cloning [2,3]. 	6
15606	MI0000589	rno-mir-322	Rattus norvegicus miR-322/miR-424 stem-loop	CCUCGCUGACUCCGAAGGGAUGCAGCAGCAAUUCAUGUUUUGGAGUAUUGCCAAGGUUCAAAACAUGAAGCGCUGCAACACCCCUUCGUGGGAAA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The miR-322 locus has an orthologous sequence in human (MIR:MI0001446), which expresses an experimentally validated mature miRNA sequence from its 5' arm, named miR-424.  The human mir-424 locus does not appear to contain a homolog of the miR-322 sequence.  The mouse ortholog (MIR:MI0000590) appears able to express both miR-322 and miR-424.  Both miR-322 and miR-424 have been experimentally verified in rat.  Landgraf et al. show that the 5' product is the predominant one [3].  The 5' product is therefore renamed miR-322 and the 3' product renamed miR-322*. 	8
15607	MI0000590	mmu-mir-322	Mus musculus miR-322/miR-424 stem-loop	CCUCGUUGACUCCGAAGGGCUGCAGCAGCAAUUCAUGUUUUGGAGUAUUGCCAAGGUUCAAAACAUGAAGCGCUGCAACACCCCUUCGUGGGGAA	The mir-322 locus appears able to express two mature miRNA sequences.  Poy et al. cloned a sequence originating from the 5' arm from mouse pancreatic beta cells [2].  This sequence is orthologous to the experimentally validated miR-424 sequence from human (MIR:MI0001446), but was named miR-322-5p in [2].  The mature product from the 3' arm of this precursor sequence is the predicted mouse homologue of miR-322, experimentally verified in rat (MIR:MI0000589) [1], and later in mouse [3].  The orthologous human locus does not appear to contain the miR-322 sequence. Landgraf et al. confirm that the 5' product is the predominant one [4]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15608	MI0000591	rno-mir-323	Rattus norvegicus miR-323 stem-loop	UUGGUACUUGGAGAGAGGUGGUCCGUGGCGCGUUCGCUUCAUUUAUGGCGCACAUUACACGGUCGACCUCUUUGCGGUAUCUAAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15609	MI0000592	mmu-mir-323	Mus musculus miR-323 stem-loop	UUGGUACUUGGAGAGAGGUGGUCCGUGGCGCGUUCGCUUCAUUUAUGGCGCACAUUACACGGUCGACCUCUUUGCGGUAUCUAAUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000591).  Seitz et al. independently predicted the miRNA hairpin precursor sequence by conservation between mouse and human [2]. Landgraf et al. later cloned and sequenced mature products from both arms of the predicted hairpin [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15610	MI0000593	rno-mir-301a	Rattus norvegicus miR-301a stem-loop	CCUGCUGGCUACUGCUGACGACUGCUCUGACUUUAUUGCACUACUGUACUGUACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCAUCCGGGAGCAGGCUAC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This rat miRNA has an independently verified homologue in mouse (MIR:MI0000401).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15611	MI0000594	rno-mir-324	Rattus norvegicus miR-324 stem-loop	CUGACUAUGCCUCCUCGCAUCCCCUAGGGCAUUGGUGUAAAGCUGGAGACCCACUGCCCCAGGUGCUGCUGGGGGUUGUAGUC		8
15612	MI0000595	mmu-mir-324	Mus musculus miR-324 stem-loop	AACUGACUAUGCCUCCUCGCAUCCCCUAGGGCAUUGGUGUAAAGCUGGAGACCCACUGCCCCAGGUGCUGCUGGGGGUUGUAGUCUGAC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000594) - expression of miRNAs from both arms was later independently verified in mouse [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The predominant miR-324-3p clone has a 3' terminal U residue, which is incompatible with the genome sequence [3]. 	6
15613	MI0000596	rno-mir-325	Rattus norvegicus miR-325 stem-loop	AUAUAGUGCUUGGUUCCUAGUAGGUGCUCAGUAAGUGUUUGUGACAUAAUUCGUUUAUUGAGCACCUCCUAUCAAUCAAGCACUGUGCUAGGCUCUGG		8
15614	MI0000597	mmu-mir-325	Mus musculus miR-325 stem-loop	AUAUAGUGCUUGGUUCCUAGUAGGUGCUCAGUAAGUGUUUGUGACAUAAUUCGUUUAUUGAGCACCUCCUAUCAAUCAAGCACUGUGCUAGGCUCUGG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000596).  Landgraf et al. later cloned a mature product from the 3' arm [2].  The 5' product is renamed miR-325* here. 	6
15615	MI0000598	mmu-mir-326	Mus musculus miR-326 stem-loop	CUCAUCUGUCUGUUGGGCUGGGGGCAGGGCCUUUGUGAAGGCGGGUUAUGCUCAGAUCGCCUCUGGGCCCUUCCUCCAGUCCCGAGGCAGAUUUA		6
15616	MI0000599	rno-mir-326	Rattus norvegicus miR-326 stem-loop	CUCAUCUGUCUGUGGGGCUGGGGGCAGGGCCUUUGUGAAGGCGGGUUAUGCUCAGAUCGCCUCUGGGCCCUUCCUCCAGUCCCGAGGCAGAUUUA		8
15617	MI0000600	rno-mir-327	Rattus norvegicus miR-327 stem-loop	GUCUGAUGCCCUCAUCCUUGAGGGGCAUGAGGGUAGUCAGUAGCCUGAUGUCCCUCUUGAUGGCACUUCGGACAUGUUGGAAUGGCUUGUGAGG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. 	8
15618	MI0000601	rno-let-7d	Rattus norvegicus let-7d stem-loop	UGGGCUCCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUAGGGCAGAGAUUUUGCCCACAAGGAGUUAACUAUACGACCUGCUGCCUUUCUUAGGGCCUU	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons, including the sequence identical to the miRNA cloned from the reverse strand of mouse let-7d (MIR:MI0000405), named let-7* [1].  The predicted precursor sequence from a newer assembly of the rat genome also contains the let-7d sequence in the 5' arm.  The let-7d* sequence published in [1] had an extra 3' A residue, which conflicts with the sequence of the precursor shown here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15619	MI0000602	rno-mir-328	Rattus norvegicus miR-328 stem-loop	UGGGGCAGGGGGGCAGGAGGGGCUCAGGGAGAAAGCAUCUACAGCCCCUGGCCCUCUCUGCCCUUCCGUCCCCUGUCCCCAAAU		8
15620	MI0000603	mmu-mir-328	Mus musculus miR-328 stem-loop	CUGUCUCGGAGCCUGGGGCAGGGGGGCAGGAGGGGCUCAGGGAGAAAGUAUCUACAGCCCCUGGCCCUCUCUGCCCUUCCGUCCCCUGUCCCCAAGU	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000602) - its expression was later independently verified in mouse [2]. 	6
15621	MI0000604	rno-mir-329	Rattus norvegicus miR-329 stem-loop	UGUUCGCUUCUGGUACCGGAAGAGAGGUUUUCUGGGUCUCUGUUUCUUUGAUGAGAAUGAAACACACCCAGCUAACCUUUUUUUCAGUAUCAAAUCC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This rat miRNA has a predicted homologue in mouse (MIR:MI0000605). 	8
15622	MI0000605	mmu-mir-329	Mus musculus miR-329 stem-loop	UGUUCGCUUCUGGUACCGGAAGAGAGGUUUUCUGGGUCUCUGUUUCUUUGAUGAGAAUGAAACACACCCAGCUAACCUUUUUUUCAGUAUCAAAUCC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000604).  Seitz et al. independently predicted the miRNA hairpin precursor sequence by conservation between mouse and human [2]. Landgraf et al. verified expression by cloining [3]. 	6
15623	MI0000606	rno-mir-330	Rattus norvegicus miR-330 stem-loop	ACCCUUUGGCGAUCUCUGCCUCUCUGGGCCUGUGUCUUAGGCUCUUCAAGAUCUAACGAGCAAAGCACAGGGCCUGCAGAGAGGUAGCGCUCUGCUC	The mature miRNA originating from the 3' arm reported in [1] contains an extra 3' A residue, which conflicts with the precursor sequence shown here.  Landgraf et al. show that the 5' miRNA is the predominant one [2]. The 3' mature sequence is renamed miR-300* here. 	8
15624	MI0000607	mmu-mir-330	Mus musculus miR-330 stem-loop	GACCCUUUGGCGAUCUCUGCCUCUCUGGGCCUGUGUCUUAGGCUCUUCAAGAUCCAACGAGCAAAGCACAGGGCCUGCAGAGAGGUAGCGCUCUGCUC		6
15625	MI0000608	rno-mir-331	Rattus norvegicus miR-331 stem-loop	GAGUCUGGUCUUGUUUGGGUUUGUUCUAGGUAUGGUCCCAGGGAUCCCAGAUCAAACCAGGCCCCUGGGCCUAUCCUAGAACCAACCUAAACCCAU	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This rat miRNA has a predicted homologue in mouse (MIR:MI0000609). 	8
15626	MI0000609	mmu-mir-331	Mus musculus miR-331 stem-loop	GAGUCUGGUUUUGUUUGGGUUUGUUCUAGGUAUGGUCCCAGGGAUCCCAGAUCAAACCAGGCCCCUGGGCCUAUCCUAGAACCAACCUAAACCCGU		6
15627	MI0000610	rno-mir-333	Rattus norvegicus miR-333 stem-loop	CCCCGGUGGAACCACGUGGUGUGCUAGUUACUUUUGGGCUGGAGAGACGGCUCAGGGGUUAAGAGCACAGACUGCUCUUCCAGAGGUCCUGAGUU	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. 	8
15628	MI0000611	rno-mir-140	Rattus norvegicus miR-140 stem-loop	GUGUCUCUCUCUGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACAUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACUGGAGCACC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The cloned miRNA appears to be expressed from the 3' strand of the precursor, and is therefore named miR-140* here.  The sequence of miR-140 is predicted based on homology with mouse and human - its expression has not been verified in rat.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15629	MI0000612	rno-mir-335	Rattus norvegicus miR-335 stem-loop	UCUUUUGGGCGGGGGUCAAGAGCAAUAACGAAAAAUGUUUGUUUUUCGUAAACCGUUUUUCAUUAUUGCUCCUGACCUCCUCUCAUUUGUUAUAGCCA		8
15630	MI0000613	rno-mir-336	Rattus norvegicus miR-336 stem-loop	AUGUGACCGUGCCUCUCACCCUUCCAUAUCUAGUCUCUGAGAAAAAUGAAGACUGGAUUCCAUGAAGGGAUGUGAGGCCUGGAAACUGGAGCUUUA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. 	8
15631	MI0000614	rno-mir-337	Rattus norvegicus miR-337 stem-loop	AGUGUAGUGAGAAGUUGGGGGGUGGGAACGGCGUCAUGCAGGAGUUGAUUGCACAGCCAUUCAGCUCCUAUAUGAUGCCUUUCUUCACCCCCUUCAA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This rat miRNA has a predicted homologue in mouse (MIR:MI0000615). 	8
15632	MI0000615	mmu-mir-337	Mus musculus miR-337 stem-loop	CAGUGUAGUGAGAAGUUGGGGGGUGGGAACGGCGUCAUGCAGGAGUUGAUUGCACAGCCAUUCAGCUCCUAUAUGAUGCCUUUCUUCACCCCCUUCA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000614).  Seitz et al. later predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [2].  Landgraf et al. later cloned and sequenced mature products from both arms of the hairpin, named here miR-337-5p and miR-337-3p [3]. 	6
15633	MI0000616	rno-mir-148b	Rattus norvegicus miR-148b stem-loop	CAGGCACUCUUAGCAUUUGAGGUGAAGUUCUGUUAUACACUCAGGCUGUGGCUCUGAAAGUCAGUGCAUCACAGAACUUUGUCUCGAAAGCUUUCUA		8
15634	MI0000617	mmu-mir-148b	Mus musculus miR-148b stem-loop	CAGGCACCCUUAGCAUUUGAGGUGAAGUUCUGUUAUACACUCAGGCUGUGGCUCUGAAAGUCAGUGCAUCACAGAACUUUGUCUCGAAAGCUUUCUA		6
15635	MI0000618	rno-mir-338	Rattus norvegicus miR-338 stem-loop	UCCCCAACAAUAUCCUGGUGCUGAGUGGGUGCACAGUGACUCCAGCAUCAGUGAUUUUGUUGAAGA		8
15636	MI0000619	mmu-mir-338	Mus musculus miR-338 stem-loop	CAACGCUGCACAGGCCGUCCUCCCCAACAAUAUCCUGGUGCUGAGUGGGUGCACAGUGACUCCAGCAUCAGUGAUUUUGUUGAAGAGGGCAGCUGCCA		6
15637	MI0000620	rno-mir-339	Rattus norvegicus miR-339 stem-loop	ACGGGGUGGACACCGUCCCUGUCCUCCAGGAGCUCACGUAUGCCUGCCUGUGAGCGCCUCGACGACAGAGCCAGAGUCCACCCCUGCACUGCCCAA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The miR-339-5p sequence reported in [1] contains two 3' terminal U residues, which conflict with the precursor sequence shown here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15638	MI0000621	mmu-mir-339	Mus musculus miR-339 stem-loop	ACGGGGUGGCCACUAUCCCUGUCCUCCAGGAGCUCACGUAUGCCUGCCUGUGAGCGCCUCGGCGACAGAGCCGGUGUCCACCCCUGCACUGUCCAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [1]. 	6
15639	MI0000622	rno-mir-340	Rattus norvegicus miR-340 stem-loop	CACUUGUACUCGGUGUGAUUAUAAAGCAAUGAGACUGAUUGUCAUGUGUCGUUUGUGGGAUCCGUCUCAGUUACUUUAUAGCCAUACCUGGUAUCUUA		8
15640	MI0000623	mmu-mir-340	Mus musculus miR-340 stem-loop	CAAUUGUACUUGGUGUGAUUAUAAAGCAAUGAGACUGAUUGUCAUAUGUCGUUUGUGGGAUCCGUCUCAGUUACUUUAUAGCCAUACCUGGUAUCUUA		6
15641	MI0000624	rno-mir-341	Rattus norvegicus miR-341 stem-loop	AAAAUGAUGAUGUCAGUUGGCCGGUCGGCCGAUCGCUCGGUCUGUCAGUCAGUCGGUCGGUCGAUCGGUCGGUCGGUCAGUCGGCUUCCUGUCUUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15642	MI0000625	mmu-mir-341	Mus musculus miR-341 stem-loop	AAAAUGAUGAUGUCAGUUGGCCGGUCGGCCGAUCGCUCGGUCUGUCAGUCAGUCGGUCGGUCGAUCGGUCGGUCGGUCAGUCGGCUUCCUGUCUUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000624) - its expression was later verified in mouse [2]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15643	MI0000626	rno-mir-342	Rattus norvegicus miR-342 stem-loop	GAAAAUGGGCUCAAGGUGAGGGGUGCUAUCUGUGAUUGAGGGACAUGGUCAAUGGAAUUGUCUCACACAGAAAUCGCACCCGUCACCUUGGCCUGCUGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15644	MI0000627	mmu-mir-342	Mus musculus miR-342 stem-loop	GAAAAUGGGCUCAAGGUGAGGGGUGCUAUCUGUGAUUGAGGGACAUGGUCAAUGGAAUUGUCUCACACAGAAAUCGCACCCGUCACCUUGGCCUGCUGA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000626).  Seitz et al. independently predicted the miRNA hairpin precursor sequence by conservation between mouse and human [2]. Landgraf et al. later cloned and sequenced mature products from both arms of the predicted hairpin [3].  The mature sequences shown here represent the most commonly cloned forms from large-scale cloning studies [3]. 	6
15645	MI0000628	rno-mir-343	Rattus norvegicus miR-343 stem-loop	GCACCUUCAUGGACCUGGAGUAGAGUGGGUGUGGCGGGGGGAGCAGGGCCCAGGGCAACCUCUCCCUCCGUGUGCCCAGAUCCUGCAUGCCAA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The sequence reported in [1] contains a 3' terminal UU sequence, which conflicts with the precursor sequence shown here. 	8
15646	MI0000629	rno-mir-344-1	Rattus norvegicus miR-344-1 stem-loop	CUGCAGCCAGAGUUUUUACCAGUCAGGCUCCUGGCUAGAUUCCAGGUACCAACUGGUACCUGAUCUAGCCAAAGCCUGACCGUAAGCUGCAAAAGAAA		8
15647	MI0000630	mmu-mir-344-1	Mus musculus miR-344-1 stem-loop	CUGCAGCCAGGGUUUUUACCAGUCAGGCUCCUGGCUAGAUUCCAGGUACCAGCUGGUACCUGAUCUAGCCAAAGCCUGACUGUAAGCCCUGAACA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000629) - its expression was later independently verified in mouse [2]. 	6
15648	MI0000631	rno-mir-345	Rattus norvegicus miR-345 stem-loop	ACCCAAGUCCAGGCCUGCUGACCCCUAGUCCAGUGCUUGUGGUGGCUACUGGGCCCUGAACUAGGGGUCUGGAGACCUGGGUUUGAUCUCCACAGG		8
15649	MI0000632	mmu-mir-345	Mus musculus miR-345 stem-loop	ACCCAAGUCCAGGCCUGCUGACCCCUAGUCCAGUGCUUGUGGUGGCUACUGGGCCCUGAACUAGGGGUCUGGAGACCUGGGUUUGAUCUCCACAGG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA was predicted based on homology to the verified rat sequence (MIR:MI0000631).  Seitz et al. independently predicted the miRNA hairpin precursor sequence by conservation between mouse and human [2]. Landgraf et al. later verified mature miRNA expression from both arms of the hairpin precursor [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15650	MI0000633	rno-mir-346	Rattus norvegicus miR-346 stem-loop	UCUGUGUUGGGCAUCUGUCUGCCUGAGUGCCUGCCUCUCUGUUGCUCUGAAGGAGGCAGGGGCUGGGCCUGCAGCUGCCUGGGCAGAGCUGCUCCUUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The sequence reported in [1] contains two 3' terminal A residues, which conflict with the precursor sequence shown here. 	8
15651	MI0000634	mmu-mir-346	Mus musculus miR-346 stem-loop	UCUGUGUUGGGCGUCUGUCUGCCCGAGUGCCUGCCUCUCUGUUGCUCUGAAGGAGGCAGGGGCUGGGCCUGCAGCUGCCUGGGCAGAGCUGCUCCUUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000633) - its expression has not been verified in mouse. The sequence reported in [1] contains two 3' terminal A residues, which conflict with the precursor sequence shown here. 	6
15652	MI0000635	rno-mir-347	Rattus norvegicus miR-347 stem-loop	GAGCCCCUGCUGGUGGGCGCGGGGCGGGGGUUUCAGGUGGUCUCGCGGUGGCCGCCCGACUGUCCCUCUGGGUCGCCCAGCUGGGGAGUUCC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. 	8
15653	MI0000636	rno-mir-349	Rattus norvegicus miR-349 stem-loop	GAAGACUCUAGCAUGUAAGGUUGGGGGAGGGGGCUGUGUCUAGCAAGUCUUCUUCCCCCACAGCCCUGCUGUCUUAACCUCUAGGUGUUCCGGCUCC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. 	8
15654	MI0000637	rno-mir-129-2	Rattus norvegicus miR-129-2 stem-loop	AGACUGCCCUUCGCGAAUCUUUUUGCGGUCUGGGCUUGCUGUACAUAACUCAAUAGCCGGAAGCCCUUACCCCAAAAAGCAUUCGCGGAGGGCGCGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations.  Kim et al [1] and He et al [4] both identify the mature product from the 3' arm, named miR-129* here. 	8
15655	MI0000638	rno-mir-20a	Rattus norvegicus miR-20a stem-loop	CAGCUUCUGUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUGUCGUCAUCUACUGCAUUACGAGCACUUACAGUACUGCCAGCUG		8
15656	MI0000639	rno-mir-350	Rattus norvegicus miR-350 stem-loop	AGAUGCCUUGCUCCUACAAGAGUAAAGUGCACGUGCUUUGGGACAGUGAGGAAAAUAAUGUUCACAAAGCCCAUACACUUUCACCCUUUAGGAGAGUUG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This rat miRNA has a predicted homologue in mouse (MIR:MI0000640).  The sequence reported in [1] contains a 5' terminal A residue, which conflicts with the precursor sequence shown here. 	8
15657	MI0000640	mmu-mir-350	Mus musculus miR-350 stem-loop	AGAUGCCUUGCUCCUACAAGAGUAAAGUGCAUGCGCUUUGGGACAGUGAGGAAAAUAAUGUUCACAAAGCCCAUACACUUUCACCCUUUAGGAGAGUUG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000639) - its expression was later independently verified in mouse [2].  The sequence reported in [1] contains a 5' terminal A residue, which conflicts with the precursor sequence shown here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15658	MI0000641	rno-mir-7a-1	Rattus norvegicus miR-7a-1 stem-loop	UGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAGACGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCACCU	Landgraf et al. show that the 5' product is the predominant one [3].  The 3' product is renamed miR-7a*.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15659	MI0000642	rno-mir-351	Rattus norvegicus miR-351 stem-loop	CAUGGCACCUCCAUUUCCCUGAGGAGCCCUUUGAGCCUGAGGUGAAAAAAAAACAGGUCAAGAGGCGCCUGGGAACUGGAG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The sequence reported in [1] contains a 3' terminal U residue, which conflicts with the precursor sequence shown here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15660	MI0000643	mmu-mir-351	Mus musculus miR-351 stem-loop	CAUGGCACCUCCGUUUCCCUGAGGAGCCCUUUGAGCCUGGAGUGAAAAAAAAAAACAGGUCAAGAGGCGCCUGGGAACUGGAGAAGAGUGUUAAACUUC	The predominant miRNA cloned by Langraf et al. has a 3' terminal U residue, which is incompatible with the genome sequence [1]. 	6
15661	MI0000644	rno-mir-352	Rattus norvegicus miR-352 stem-loop	GUACAUAUGUUGAAGAUUAUUAAUAUAUAGAGUGGGUGUUGUGGUGGUAGUAUGAUAUGUAGAGUAGUAGGUUGCAUAGUACGAUGUAGUGUAUGA	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. miR-352 is closely related to let-7d (a single deletion), but the predicted hairpin precursor sequences are unrelated, and express their mature forms from opposite strands. 	8
15662	MI0000645	rno-mir-135b	Rattus norvegicus miR-135b stem-loop	CGCUCUGCUGUGGCCUAUGGCUUUUCAUUCCUAUGUGAUUGCUGUUCCGAACUCAUGUAGGGCUAAAAGCCAUGGGCUACAGUGAGGGGCAAGCUCC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15663	MI0000646	mmu-mir-135b	Mus musculus miR-135b stem-loop	CGCUCUGCUGUGGCCUAUGGCUUUUCAUUCCUAUGUGAUUGCUGCUCCGAACUCAUGUAGGGCUAAAAGCCAUGGGCUACAGUGAGGGGCAAGCUCC		6
15664	MI0000647	rno-mir-151	Rattus norvegicus miR-151 stem-loop	AGCGCUUUCCUGCCCUCGAGGAGCUCACAGUCUAGUAUGUCUCCUCCCUACUAGACUGAGGCUCCUUGAGGACAGGGAUCGUCAUACUCACCUCCCG	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. Landgraf et al show that the 5' product is the predominant one [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15665	MI0000648	rno-mir-101b	Rattus norvegicus miR-101b stem-loop	AUCUGAGACUGAACUGUCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAGAUCUGAAAGGUACAGUACUGUGAUAGCUGAAGAAUGGUGGUGCCAUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15666	MI0000649	mmu-mir-101b	Mus musculus miR-101b stem-loop	AUCUGAGACUGAACUGCCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAGCUCUGAAAGGUACAGUACUGUGAUAGCUGAAGAAUGGCGGUGCCAUC	Kim et al. cloned 40 new miRNAs from rat E18 primary cortical neurons [1]. This mouse miRNA is predicted based on homology to the verified rat sequence (MIR:MI0000648) -- expression in mouse was verified independently [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15667	MI0000650	hsa-mir-200c	Homo sapiens miR-200c stem-loop	CCCUCGUCUUACCCAGCAGUGUUUGGGUGCGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15668	MI0000651	hsa-mir-1-1	Homo sapiens miR-1-1 stem-loop	UGGGAAACAUACUUCUUUAUAUGCCCAUAUGGACCUGCUAAGCUAUGGAAUGUAAAGAAGUAUGUAUCUCA	Lagos-Quintana et al. [1] reported the cloning of miR-1b, miR-1c and miR-1d.  The mature processed miR sequences are identical apart from the 3' residues (A in mir-1b, C in mir-1c and UU in mir-1d).  The 3' residues of both miR-1b and miR-1c conflict with the predicted stem-loop precursor sequence shown here and these sequences are not found in current assemblies of human and mouse genomes.  It is suggested that polyA polymerase may add 1-3 nts to the 3' end of the mature transcript (Tom Tuschl, pers. comm.).  The common 21 nts of the 3 reported miR sequences have been rationalised here and named miR-1.  There are 2 pairs of orthologous putative hairpin precursor structures named mir-1-1 (human MIR:MI0000651, mouse MIR:MI0000139), and mir-1-2 (human MIR:MI0000437, mouse MIR:MI0000652).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15669	MI0000652	mmu-mir-1-2	Mus musculus miR-1-2 stem-loop	UCAGAGCACAUACUUCUUUAUGUACCCAUAUGAACAUUCAGUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUG	Lagos-Quintana et al. [1] reported the cloning of miR-1b, miR-1c and miR-1d.  The mature processed miR sequences are identical apart from the 3' residues (A in mir-1b, C in mir-1c and UU in mir-1d).  The 3' residues of both miR-1b and miR-1c conflict with the predicted stem-loop precursor sequence shown here and these sequences are not found in current assemblies of human and mouse genomes.  It is suggested that polyA polymerase may add 1-3 nts to the 3' end of the mature transcript (Tom Tuschl, pers. comm.).  The common 21 nts of the 3 reported miR sequences have been rationalised here and named miR-1.  There are 2 pairs of orthologous putative hairpin precursor structures named mir-1-1 (human MIR:MI0000651, mouse MIR:MI0000139), and mir-1-2 (human MIR:MI0000437, mouse MIR:MI0000652).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15670	MI0000653	osa-MIR156a	Oryza sativa miR156a stem-loop	GGAGGGUGACAGAAGAGAGUGAGCACACGUGGUUGUUUCCUUGCAUAAAUGAUGCCUAUGCUUGGAGCUACGCGUGCUCACUUCUCUCUCUGUCACCUCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15671	MI0000654	osa-MIR156b	Oryza sativa miR156b stem-loop	UUGUCUUGAGAGGGGAAGAGAUCUCUAUGGGUUUUGGAGGUCUGACAGAAGAGAGUGAGCACACACGGUGCUUUCUUAGCAUGCAAGAGCCAUGCUGGGAGCUGUGCGUGCUCACUCUCUAUCUGUCAGCCGUUCACCAUGCCCAAUAUGAUUAAUCUCCUUCUCUCAGUUGACAG	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15672	MI0000655	osa-MIR156c	Oryza sativa miR156c stem-loop	GGAGGAAGAGAGGGGUGAGAGGUGAGGCUGACAGAAGAGAGUGAGCACACAUGGUGACUUUCUUGCAUGCUGAAUGGACUCAUGCUUGAAGCUAUGUGUGCUCACUUCUCUCUCUGUCAGCCAUUUGAUCUCUCUUUCUCUCUUUCUCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15673	MI0000656	osa-MIR156d	Oryza sativa miR156d stem-loop	GGAGAAGCUCUCAUGAGAUUGACAGAAGAGAGUGAGCACACGGCGUGAUGGCCGGCAUAAAAUCUAUCCCGUCCUCGCCGCGUGCUCACUCCUCUUUCUGUCACCCUCUUUCUCUCAGGGCUCAACUCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15674	MI0000657	osa-MIR156e	Oryza sativa miR156e stem-loop	GGCGCGAGGUGACAGAAGAGAGUGAGCACACGGCCGGGCGUGACGGCACCGGCGGGCGUGCCGUCGCGGCCGCGUGCUCACUGCUCUUUCUGUCAUCCGGUGCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15675	MI0000658	osa-MIR156f	Oryza sativa miR156f stem-loop	AGUUGACAGAAGAGAGUGAGCACACAGCGGCCAGACUGCAUCGAUCUAUCAAUCUUCCCUUCGACAGGAUAGCUAGAUAGAAAGAAAGAGAGGCCGUCGGCGGCCAUGGAAGAGAGAGAGAGAGAGAGAUGAAAUGAUGAUGAUGAUACAGCUGCCGCUGCGUGCUCACUUCUCUUUCUGUCAGCU	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15676	MI0000659	osa-MIR156g	Oryza sativa miR156g stem-loop	GGCUGACAGAAGAGAGUGAGCACACAGCGGGCAGACUGCAUCUGAAUUACCUGUUGCGACGAAGAAGACGACGGACGCAGCUUGCCGUUGCGUGCUCACUUCUCUCUCUGUCAGCU	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15677	MI0000660	osa-MIR156h	Oryza sativa miR156h stem-loop	GAGAUUGUUGACAGAAGAGAGUGAGCACACGGCGCGGCGGCUAGCCAUCGGCGGGAUGCCUGCCCCCGCCGCGUGCUCGCUCCUCUUUCUGUCAGCAUCUC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15678	MI0000661	osa-MIR156i	Oryza sativa miR156i stem-loop	GGUGACAGAAGAGAGUGAGCACACGGCCGGGCGGAACGGCACCGGCGGAUGUGCCGUCGCGGCCGCGUGCUCACUGCUCUGUCUGUCAUC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15679	MI0000662	osa-MIR156j	Oryza sativa miR156j stem-loop	UUGGGGCGGGGCGGGAUCGAGCAUAUGAAAGGCGAGAUUGUUGACAGAAGAGAGUGAGCACACGGCGCGGCGGCUAGCCAUCGGCGGGAUGCCUGCCCCCGCCGCGUGCUCGCUCCUCUUUCUGUCAGCAUCUCUCAUCACUCCCUCCCGCAUCCCCCGCCCCGA	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15680	MI0000663	osa-MIR160a	Oryza sativa miR160a stem-loop	GUGUGCCUGGCUCCCUGUAUGCCACACAUGUAGACCAACCCAUGGUGUCUGGUUGCCUACUGGGUGGCGUGCAAGGAGCCAAGCAUGC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15681	MI0000664	osa-MIR160b	Oryza sativa miR160b stem-loop	AAGGUUUGGUUUUGAUCGGCUUGAGAGCGUGCCUGGCUCCCUGUAUGCCACUCAUGUAGCCCAAUCCAUGGUGUGUUUGGAUGCUGUGGGUGGCGUGCAAGGAGCCAAGCAUGCGUGCCAUGAUCUCUCUUUCUGCCUU	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15682	MI0000665	osa-MIR160c	Oryza sativa miR160c stem-loop	GGAAUGUGCCUGGCUCCCUGUAUGCCACUCAUCUAGAGCAACAAACUUCUGCGAGAGGUUGCCUAUGAUGGAUGGCGUGCACGGAGCCAAGCAUAUUCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15683	MI0000666	osa-MIR160d	Oryza sativa miR160d stem-loop	GGGGAUAUGCCUGGCUCCCUGUAUGCCACUCGCGUAGCUGCCAAACUCAGUUGAAACAACUGCCUUCUCCCGGCGAGAUUCAGGCAUUGUGUUCGUACGUUUGGCUCUACUGCGGAUGGCGUGCGAGGAGCCAAGCAUGACC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15684	MI0000667	osa-MIR162a	Oryza sativa miR162a stem-loop	GGUGAUGCCUGGGCGCAGUGGUUUAUCGAUCCCUUCCCUGCCUUGUGGCGCUGAUCCAGGAGCGGCGAAUUUCUUUGAGAGGGUGUUCUUUUUUUUUCUUCCUUUUGGUCCUUGUUGCAGCCAACGACAACGCGGGAAUCGAUCGAUAAACCUCUGCAUCCAGUUCUCGCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15685	MI0000668	osa-MIR164a	Oryza sativa miR164a stem-loop	GUGAGAAGGACCGCGUUGGAGAAGCAGGGCACGUGCAUGCAUAUGUUCAUCAUCAUCUUCUUCCUCCUCCUCUAGCUCCAGCCUUGUGUGGGUUGGAAGUUUAGAUAGAACUCGCACUGCACGUGGUCUCCUUCUCCAUCCCGGUCUUUUUCUCAC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15686	MI0000669	osa-MIR164b	Oryza sativa miR164b stem-loop	GUGCACGGUGGAGAAGCAGGGCACGUGCAUUACCAUCCACUCGCCUGCCGGCCGCCGGCCGCCAUUGCCAUGGAUGGUUCUUCAUGUGCCCGUCUUCUCCACCGAGCAC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15687	MI0000670	osa-MIR166a	Oryza sativa miR166a stem-loop	UGAAGCUAUUUGCUUCUGAGUGGAAUGUUGUCUGGUUCAAGGUCUCAUGCACCUUGCGGUUUUGAGGAUGAUUUGUGCAAGGUUUUUCAUUCCUCUCAUCCGUGGGAUCUCGGACCAGGCUUCAUUCCCCUCAGAGAUAGCUUCA	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15688	MI0000671	osa-MIR166b	Oryza sativa miR166b stem-loop	GGGAGCCUUUUCAUUUUGAGGGGAAUGUUGUCUGGCUCGGGGCUACUUUUAAUUUCUCUCUCUUUUGAUAUCUUCUUUUCUCGAUCUCCUAGCUUGAUCUUUUGAUCUCUCAAAUCGAUCUUAAGAAAAAGAUCAGUCAAAGAGAUGAGAGUAGAUGUCUGUAGAUCUCGGACCAGGCUUCAUUCCCCCCAAACAGAAGGGCUCCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15689	MI0000672	osa-MIR166c	Oryza sativa miR166c stem-loop	GGCAGUUGAGGGGAAUGUUGUCUGGUCCGAGACCUAACACCGGGCGGAAUGGCGGAUUCAGCUGCAGCUAAGCAAGCUAGGUGGGGGGUUUCGGACCAGGCUUCAUUCCCCCCAACUCAACUGUU	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15690	MI0000673	osa-MIR166d	Oryza sativa miR166d stem-loop	GAAGCUUUUUCACUUUGAGGGGAAUGUUGUCUGGCUCGAGGUGCAUGGAGAAACCUCUGAUCGAUCAGGUUUGAUCUGUAGAGACUGAUCUCGGACCAGGCUUCAUUCCCCUCAAGUAAAGCUCC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15691	MI0000674	osa-MIR166e	Oryza sativa miR166e stem-loop	UGUUUCUGGGUGGAAUGUUGUCUGGUUCAAGGCCCCUUAGGAUGUGUGAUUUUUGAUGGUUUAUGCAUUCAUCUUGAUGCGAACAUCUAUCUCGGAUCUUUGGGUUCUCGAACCAGGCUUCAUUCCCCUCAGAGAUA	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15692	MI0000675	osa-MIR166f	Oryza sativa miR166f stem-loop	CGAUCAUCUUGUUGAGAGGAAUGUCGUCUGGCCUGAGAUCGUACCACAGUGGUGGGUACACGUGGACGGUCUCGGACCAGGCUUCAUUCCCCUCAACAACUCGUCGG	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15693	MI0000676	osa-MIR167a	Oryza sativa miR167a stem-loop	UAGUGUGAAUGAGUGAAGCUGCCAGCAUGAUCUAGCUCUGAUUAAUCGGCACUGUUGGCGUACAGUCGAUUGACUAAUCGUCAGAUCUGUGUGUGUAAAUCACUGUUAGAUCAUGCAUGACAGCCUCAUUUCUUCACACUG	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15694	MI0000677	osa-MIR167b	Oryza sativa miR167b stem-loop	GUGCCCAAGAGAAAGCGUGAAGCUGCCAGCAUGAUCUAACUUGCAGACAAGAAAUCAGCUCAGCUCGCUGGUUUCGAACAGGAAGGCGGCUAGCUGAGGCUUCUUCUGAGUACGUGAUGGUUAGAUCAUGCUGUGACAGUUUCACUCCUUCCCUGUUGGGCAC	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15695	MI0000678	osa-MIR167c	Oryza sativa miR167c stem-loop	UGUCCAAGGGAACGAGUGAAGCUGCCAGCAUGAUCUAGCUCUGAAUGAUCAACAAGAUGUGCUCCCACACUGCCUUCCUGUGGAUCUUGAGCUGUUGCUAGUCUUGUGGUCAUGCCUUGCUAGGUCAUGCUGCGGCAGCCUCACUUCUUCCCAUUGUUGGGCA	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15696	MI0000679	osa-MIR169a	Oryza sativa miR169a stem-loop	CGCCGGCGGCCUGACAUUGGGAUCGGAGGCCAUGGUGCAGCCAAGGAUGACUUGCCGAUCGAUCGAUCUAUCUAUGAAGCUAAGCUAGCUGGCCAUGGAUCCAUCCAUCAAUUGGCAAGUUGUUCUUGGCUACAUCUUGGCCCCUGCUCCUCAUGUAAGGCCGGCCUGUGGCG	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15697	MI0000680	osa-MIR171a	Oryza sativa miR171a stem-loop	GGAAAGAGCGAUAUUGGUGAGGUUCAAUCCGAUGAUUGGUUUUACAGCAGUGGUAAAAUCAGUAUCUGAUUGAGCCGCGCCAAUAUCUCUUCCUCU	The stem-loop sequence represented here is predicted based on homology to miRNAs cloned from Arabidopsis [1].  Its expression has not been verified in rice. 	7
15698	MI0000681	hsa-mir-155	Homo sapiens miR-155 stem-loop	CUGUUAAUGCUAAUCGUGAUAGGGGUUUUUGCCUCCAACUGACUCCUACAUAUUAGCAUUAACAG	Human mir-155 is predicted based on homology to a cloned miR from mouse (MIR:MI0000177) [1], and later experimentally validated in human HL-60 leukemia cells [2].  Like the mouse miRNA, human mir-155 resides in the non-coding BIC transcript (EMBL:AF402776), located on chromosome 21 [3]. The mature form differs from that in mouse at a single position.  Eis et al. confirm that miR-155 is processed from the BIC transcript in human, and demonstrate elevated expression of miR-155 in lymphoma samples [4]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	5
15699	MI0000683	hsa-mir-181b-2	Homo sapiens miR-181b-2 stem-loop	CUGAUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGAGUCUGAAUCAACUCACUGAUCAAUGAAUGCAAACUGCGGACCAAACA	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  Its expression was later verified in human BC-1 cells [3].  There are two predicted hairpin precursor sequences in the human genome; mir-181b-1 (MIR:MI0000270) is found on chromosome 1 [1], and mir-181b-2 (MIR:MI0000683) on chromosome 9 [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15700	MI0000684	mmu-mir-107	Mus musculus miR-107 stem-loop	UUCUCUGUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGAGAGC	Mouse mir-107 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000114) [1], and later verified in mouse [3,4]. 	6
15701	MI0000685	mmu-mir-10a	Mus musculus miR-10a stem-loop	GACCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCA		6
15702	MI0000687	mmu-mir-17	Mus musculus miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUGUGUGCAUCUACUGCAGUGAGGGCACUUGUAGCAUUAUGCUGAC	Mouse mir-17 is predicted [4] based on homology to a cloned miR from human (MIR:MI0000071) [1,2].  miRNAs derived from the 5' [1] and 3' [2] arms of the human mir-17 precursor have been reported.  Landgraf et al. show that the 5' product is the predominant one [5].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15703	MI0000688	mmu-mir-19a	Mus musculus miR-19a stem-loop	GCAGCCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC		6
15704	MI0000689	mmu-mir-25	Mus musculus miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Mouse mir-25 is predicted [3] based on homology to a cloned miR from human (MIR:MI0000082) [1].  Its expression has been later independently verified in mouse [2,4]. 	6
15705	MI0000690	mmu-mir-28	Mus musculus miR-28 stem-loop	GGUCCCUACCUUCAAGGAGCUCACAGUCUAUUGAGUUGCCUUUCUGAUUCUCCCACUAGAUUGUGAGCUGCUGGAGGGCAGGCACU	Mouse mir-28 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000086) [1].  Its expression was later verified by cloning [3]. 	6
15706	MI0000691	mmu-mir-32	Mus musculus miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Mouse mir-32 is predicted [3] based on homology to a cloned miR from human (MIR:MI0000090) [1].  Its expression in mouse was later independently verified [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15707	MI0000692	mmu-mir-100	Mus musculus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGCUGAUUCUGCACACAAGCUUGUGUCUAUAGGUAUGUGUCUGUUAGG	Mouse mir-100 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000102) [1].  Its expression was later verified in mouse [3]. 	6
15708	MI0000693	mmu-mir-139	Mus musculus miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
15709	MI0000694	mmu-mir-200c	Mus musculus miR-200c stem-loop	CCCUCGUCUUACCCAGCAGUGUUUGGGUGCUGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	Mouse mir-200c is predicted [3] based on homology to a cloned miR from human (MIR:MI0000650) [1].  Its expression in mouse was later verified independently [2,4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15710	MI0000695	mmu-mir-210	Mus musculus miR-210 stem-loop	CCGGGGCAGUCCCUCCAGGCUCAGGACAGCCACUGCCCACCGCACACUGCGUUGCUCCGGACCCACUGUGCGUGUGACAGCGGCUGAUCUGUCCCUGGGCAGCGCGAACC	Mouse mir-210 is predicted [3] based on homology to a reported miR from human (MIR:MI0000286) [1].  Its expression in mouse was later verified independently [2,4]. 	6
15711	MI0000696	mmu-mir-212	Mus musculus miR-212 stem-loop	GGGCAGCGCGCCGGCACCUUGGCUCUAGACUGCUUACUGCCCGGGCCGCCUUCAGUAACAGUCUCCAGUCACGGCCACCGACGCCUGGCCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15712	MI0000697	mmu-mir-181a-1	Mus musculus miR-181a-1 stem-loop	GGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUCAAAUAAAAACCAUCGACCGUUGAUUGUACCCUAUAGCUAACC	Mouse miR-181a, cloned by Poy et al [2], is predicted to be expressed from two genomic hairpin loci, mmu-mir-181a-1 (MIR:MI0000697) and mmu-mir-181a-2 (MIR:MI0000223).  A miRNA from the 3' arm of this hairpin, named miR-213 was predicted [3] based on homology to a human miRNA (MIR:MI0000289), and later cloned [2].  Subsequent cloning and Northern evidence shows that the 3' mature sequence is the biogenesis byproduct miR-181a* (Chang-Zheng Chen and David Bartel, pers. comm.). 	6
15713	MI0000698	mmu-mir-214	Mus musculus miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Mouse mir-214 is predicted [2] based on homology to a reported miR from human (MIR:MI0000290) [1].  Its expression was later verified by cloning [3]. 	6
15714	MI0000699	mmu-mir-216a	Mus musculus miR-216a stem-loop	UUGGUUUAAUCUCAGCUGGCAACUGUGAGAUGUCCCUAUCAUUCCUCACAGUGGUCUCUGGGAUUAUGCUAA	Mouse mir-216 is predicted [2] based on homology to a reported miR from human (MIR:MI0000292) [1].  Its expression was later verified by cloning [3]. 	6
15715	MI0000700	mmu-mir-218-1	Mus musculus miR-218-1 stem-loop	GUGAUAAUGGAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGCUUGCGAGGUAUGAGAAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Mouse miR-218 is predicted [2] based on homology to a reported miR from human (MIR:MI0000294) [1].  Its expression was later verified by cloning [3]. 	6
15716	MI0000701	mmu-mir-218-2	Mus musculus miR-218-2 stem-loop	GACCAGUUGCCGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCAUCGCUCUCUCCUGCA	Mouse miR-218 is predicted [2] based on homology to a reported miR from human (MIR:MI0000295) [1].  Its expression was later verified by cloning [3]. 	6
15717	MI0000702	mmu-mir-219-1	Mus musculus miR-219-1 stem-loop	CCGUCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUCUGGCUCCGGCCGAGAGUUGCGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGGGGG	Mouse mir-219 is predicted [2] based on homology to a reported miR from human (MIR:MI0000296) [1].  Its expression was later verified in mouse [3]. 	6
15718	MI0000703	mmu-mir-223	Mus musculus miR-223 stem-loop	UCUGGCCAUCUGCAGUGUCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCUGUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGUGGCUCAUGCCUAUCAG	Mouse mir-223 is predicted [2] based on homology to a reported miR from human (MIR:MI0000300) [1].  Its expression was later verified by cloning [3]. 	6
15719	MI0000704	mmu-mir-320	Mus musculus miR-320 stem-loop	GCCUCGCCGCCCUCCGCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGAAAAAGGAUGUGGG	Mouse mir-320 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000542) [1].  Its expression was later verified in mouse [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15720	MI0000706	mmu-mir-26a-2	Mus musculus miR-26a-2 stem-loop	GGCUGCGGCUGGAUUCAAGUAAUCCAGGAUAGGCUGUGUCCGUCCAUGAGGCCUGUUCUUGAUUACUUGUUUCUGGAGGCAGCG	This sequence is a second predicted hairpin precursor for miR-26a (MIR:MI0000573), conserved in human [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15721	MI0000707	mmu-mir-33	Mus musculus miR-33 stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGCAAUACCUGUGCAAUGUUUCCACAGUGCAUCACGG	Mouse mir-33 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000091) [1].  Its expression was later verified by cloning [3]. 	6
15722	MI0000708	mmu-mir-211	Mus musculus miR-211 stem-loop	CUGCUUGGACCUGUGACCUGUGGGCUUCCCUUUGUCAUCCUUUGCCUAGGCCUCUGAGUGAGGCAAGGACAGCAAAGGGGGGCUCAGUGGUCACCUCUACUGCAGA	Mouse mir-211 is predicted [2] based on homology to a reported miR from human (MIR:MI0000287) [1].  Its expression has not been verified in mouse. The mature miR differs from the human sequence at a single base.  This sequence maps to mouse chromosome 7. 	6
15723	MI0000709	mmu-mir-221	Mus musculus miR-221 stem-loop	AUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUUGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAA	Mouse mir-221 is predicted [2] based on homology to a reported miR from human (MIR:MI0000298) [1].  Its expression was later verified by cloning [3]. 	6
15724	MI0000710	mmu-mir-222	Mus musculus miR-222 stem-loop	CCCUCAGUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUGGUAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGGUGGC	Mouse mir-222 is predicted [2] based on homology to a reported miR from human (MIR:MI0000299) [1].  Its expression was later verified in mouse by cloning [3]. 	6
15725	MI0000711	mmu-mir-224	Mus musculus miR-224 stem-loop	GGGCUUUUAAGUCACUAGUGGUUCCGUUUAGUAGAUGGUUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Mouse mir-224 is predicted [2] based on homology to a cloned miR from human (MIR:MI0000301) [1].  Its expression was later verified by cloning [3]. 	6
15726	MI0000712	mmu-mir-29b-2	Mus musculus miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG		6
15727	MI0000713	mmu-mir-199a-2	Mus musculus miR-199a-2 stem-loop	UGGAAGCUUCAGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGCCAGCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15728	MI0000714	mmu-mir-199b	Mus musculus miR-199b stem-loop	CCAGAGGAUACCUCCACUCCGUCUACCCAGUGUUUAGACUACCUGUUCAGGACUCCCAAAUUGUACAGUAGUCUGCACAUUGGUUAGGCUGGGCUGGGUUAGACCCUCGG	Mouse miR-199b is predicted based on homology with the previously identified human miR-199b (MIR:MI0000282) [1,2].  Landgraf et al. later showed that the 3' product is the predominant one [3]. 	6
15729	MI0000715	mmu-mir-135a-2	Mus musculus miR-135a-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUCGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAUUCA		6
15730	MI0000716	mmu-mir-124-1	Mus musculus miR-124-1 stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG	miR-124 was cloned from mouse brain [1] and embryonic stem cells [2] by independent groups.  There are 3 predicted precursor hairpin sequences: mir-124-1 (MIR:MI0000716) on chromosome 14, mir-124-2 (MIR:MI0000717) on chromosome 3, and mir-124-3 (previously known as miR-124 here, MIR:MI0000150) on chromosome 2.  All have closely related predicted human homologues (MIR:MI0000443, MIR:MI0000444 and MIR:MI0000445). Lagos-Quintana et al. also report a mature miRNA sequence miR-124b, with a G insertion at position 12 [1].  miR-124b is not found in either the mouse or human genome assemblies. 	6
15731	MI0000717	mmu-mir-124-2	Mus musculus miR-124-2 stem-loop	AUCAAGAUCAGAGACUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	miR-124 was cloned from mouse brain [1] and embryonic stem cells [2] by independent groups.  There are 3 predicted precursor hairpin sequences: mir-124-1 (MIR:MI0000716) on chromosome 14, mir-124-2 (MIR:MI0000717) on chromosome 3, and mir-124-3 (previously known as miR-124 here, MIR:MI0000150) on chromosome 2.  All have closely related predicted human homologues (MIR:MI0000443, MIR:MI0000444 and MIR:MI0000445). Lagos-Quintana et al. also report a mature miRNA sequence miR-124b, with a G insertion at position 12 [1].  miR-124b is not found in either the mouse or human genome assemblies. 	6
15732	MI0000718	mmu-mir-19b-1	Mus musculus miR-19b-1 stem-loop	CACUGGUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUAUAAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUGGUG	Mouse miR-19b was cloned from mouse tissues by independent groups [1,2]. There are two predicted hairpin precursors, with closely related human homologues [4]: mir-19b-1 (MIR:MI0000718) on chromosome 14, and mir-19b-2 (previously named mir-19b here, MIR:MI0000546) on mouse chromosome X. -- CONFLICT -- Mouse mir-92-1 and mir-19b-1 map to an unfinished region of chromosome 14. 	6
15733	MI0000719	mmu-mir-92a-1	Mus musculus miR-92a-1 stem-loop	CUUUCUACACAGGUUGGGAUUUGUCGCAAUGCUGUGUUUCUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	The predominant miR-92 form cloned by Landgraf et al. has a additional 3' U residue, which is compatible with this precursor sequence, but not with that of mir-92-2 (MIR:MI0000580) [4]. 	6
15734	MI0000720	mmu-mir-9-1	Mus musculus miR-9-1 stem-loop	CGGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA	Mouse miR-9 was cloned from mouse brain tissues in [1].  There are 3 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [3].  Two copies of mir-9-1 (MIR:MI0000720) are found as part of a larger duplicated region on mouse chromosome 3, mir-9-2 (MIR:MI0000157, previously named mir-9 here) is found on chromosome 13, and mir-9-3 (MIR:MI0000721) on chromosome 7. miR-9* was described as miR-131 in reference [1], but appears to be expressed from the opposite arm of all 3 mir-9 predicted stem-loops.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15735	MI0000721	mmu-mir-9-3	Mus musculus miR-9-3 stem-loop	GGAGGCCCGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUGCCACAGAGCCGUCAUAAAGCUAGAUAACCGAAAGUAGAAAUGACUCUCA	Mouse miR-9 was cloned from mouse brain tissues in [1].  There are 3 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [3].  Two copies of mir-9-1 (MIR:MI0000720) are found as part of a larger duplicated region on mouse chromosome 3, mir-9-2 (MIR:MI0000157, previously named mir-9 here) is found on chromosome 13, and mir-9-3 (MIR:MI0000721) on chromosome 7. miR-9* was described as miR-131 in reference [1], but appears to be expressed from the opposite arm of all 3 mir-9 predicted stem-loops.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15736	MI0000722	mmu-mir-138-1	Mus musculus miR-138-1 stem-loop	CUCUAGCAUGGUGUUGUGGGACAGCUGGUGUUGUGAAUCAGGCCGUUGCCAAUCAGAGAACGGCUACUUCACAACACCAGGGCCACACUGCACUGCAAG	Mouse miR-138 was cloned from mouse brain tissue in [1].  There are 2 predicted hairpin precursor structures in the mouse genome, each has a closely related human homologue [2].  mir-138-1 (MIR:MI0000722) is found on mouse chromosome 8, and mir-138-2 (MIR:MI0000164, previously named mir-138 here) on chromosome 9.  Kim et al. and Obernosterer et al. independently show that the mature product is a 23mer [3,4]. 	6
15737	MI0000723	mmu-mir-181b-1	Mus musculus miR-181b-1 stem-loop	AGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUAGAAAAGCUCACUGAACAAUGAAUGCAACUGUGGCC	Mouse miR-181b was predicted by computational methods using conservation with human and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and independently in mouse [2,3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15738	MI0000724	mmu-mir-181c	Mus musculus miR-181c stem-loop	GCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGACAAACCAUCGACCGUUGAGUGGACCCCGAGGCCUGGA	Mouse miR-181c was predicted by computational methods using conservation with human and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish and independently in mouse [2,3]. 	6
15739	MI0000725	mmu-mir-125b-1	Mus musculus miR-125b-1 stem-loop	UGCGCUCCCCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUG		6
15740	MI0000726	mmu-mir-128-2	Mus musculus miR-128-2 stem-loop	CAGUGGGAAGGGGGGCCGAUGCACUGUAAGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUCCCUACUG	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	6
15741	MI0000727	hsa-mir-128-2	Homo sapiens miR-128-2 stem-loop	UGUGCAGUGGGAAGGGGGGCCGAUACACUGUACGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUCCCUACUGUGUC	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	5
15742	MI0000728	mmu-mir-7a-1	Mus musculus miR-7a-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAACGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCACCUCUACAG	miR-7a (previously named miR-7) was predicted by computational methods using conservation between mouse, human and Fugu rubripes sequences [1]. Expression of the excised miR has been validated in zebrafish, and later independently verified in mouse [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	6
15743	MI0000729	mmu-mir-7a-2	Mus musculus miR-7a-2 stem-loop	GGUCGGGCCAGCCCCGUUUGGAAGACUAGUGAUUUUGUUGUUGUGUCUCUGUAUCCAACAACAAGUCCCAGUCUGCCACAUGGUGCUGGUCAUUUCA	miR-7a (previously named miR-7) was predicted by computational methods using conservation between mouse, human and Fugu rubripes sequences [1]. Expression of the excised miR has been validated in zebrafish, and later independently verified in mouse [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	6
15744	MI0000730	mmu-mir-7b	Mus musculus miR-7b stem-loop	AGGAGCGGAGUACGUGAGCCAGUGCUAUGUGGAAGACUUGUGAUUUUGUUGUUCUGAUAUGAUAUGACAACAAGUCACAGCCAGCCUCAUAGCGUGGACUCCUAUCACCUU	miR-7 was predicted by computational methods using conservation between mouse, human and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  This sequence represents the mouse homologue of human mir-7-3 -- the derived mature form differs at a single position from that expressed from mir-7-1 (MIR:MI0000728) and mir-7-2 (MIR:MI0000729) in mouse, and mir-7-1 (MIR:MI0000263), mir-7-2 (MIR:MI0000264) and mir-7-3 (MIR:MI0000265) in human.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies in mouse [2]. 	6
15745	MI0000731	mmu-mir-217	Mus musculus miR-217 stem-loop	AAACAUAGUCAUUACAGUUUUUGAUGUUGCAGAUACUGCAUCAGGAACUGACUGGAUAAGACUUAAUCCCCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAA	This miRNA was predicted by computational methods using conservation in with human, mouse and Fugu rubripes [1].  Expression of the excised miR has been validated in zebrafish, and the ends mapped by cloning.  The mature mouse and human (MIR:MI0000293) sequences differ at a single position [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies in mouse [3]. 	6
15746	MI0000732	hsa-mir-194-2	Homo sapiens miR-194-2 stem-loop	UGGUUCCCGCCCCCUGUAACAGCAACUCCAUGUGGAAGUGCCCACUGGUUCCAGUGGGGCUGCUGUUAUCUGGGGCGAGGGCCAG	This miRNA sequence was predicted based on homology to a verified miRNA from mouse [1].  Michael et al. subsequently verified expression of miR-194 in human [2].  Two putative pairs of orthologous hairpin precursors structures are found in mouse (mir-194-1 (MIR:MI0000236) on chromosome 1, and mir-194-2 (MIR:MI0000733) on chromosome 19) and human (mir-194-1 (MIR:MI0000488) on chromosome 1, and mir-194-2 (MIR:MI0000732) on chromosome 11). 	5
15747	MI0000733	mmu-mir-194-2	Mus musculus miR-194-2 stem-loop	GUGGCUCCCACCCUCUGUAACAGCAACUCCAUGUGGAAGUGCCCACUGGUUCCAGUGGGGCUGCUGUUAUCUGGGGUGGCGGCUAG	Lagos-Quintana cloned miR-194 from mouse kidney tissue [1].  Michael et al. subsequently verified expression of miR-194 in human [2].  Two putative pairs of orthologous hairpin precursors structures are found in mouse  (mir-194-1 (MIR:MI0000236) on chromosome 1, and mir-194-2 (MIR:MI0000733) on chromosome 19) and human (mir-194-1 (MIR:MI0000488) on chromosome 1, and mir-194-2 (MIR:MI0000732) on chromosome 11). 	6
15748	MI0000734	hsa-mir-106b	Homo sapiens miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG		5
15749	MI0000735	hsa-mir-29c	Homo sapiens miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15750	MI0000736	hsa-mir-30c-1	Homo sapiens miR-30c-1 stem-loop	ACCAUGCUGUAGUGUGUGUAAACAUCCUACACUCUCAGCUGUGAGCUCAAGGUGGCUGGGAGAGGGUUGUUUACUCCUUCUGCCAUGGA	miR-30c was cloned from mouse heart and brain tissues by Lagos-Quintana et al. [1].  Two human hairpin precursor sequences are predicted based on homology with the mouse sequences, on chromosomes 1 (MIR:MI0000736) and 6 (MIR:MI0000254) [3].  Expression of miR-30c was later validated in human HL-60 leukemia cells [2]. 	5
15751	MI0000737	hsa-mir-200a	Homo sapiens miR-200a stem-loop	CCGGGCCCCUGUGAGCAUCUUACCGGACAGUGCUGGAUUUCCCAGCUUGACUCUAACACUGUCUGGUAACGAUGUUCAAAGGUGACCCGC	miR-200a was cloned from mouse kidney tissue [1], and expression later confirmed by cloning in human [3]. 	5
15752	MI0000738	hsa-mir-302a	Homo sapiens miR-302a stem-loop	CCACCACUUAAACGUGGAUGUACUUGCUUUGAAACUAAAGAAGUAAGUGCUUCCAUGUUUUGGUGAUGG	miR-302 was first cloned from mouse embryonic stem cells (MIR:MI0000402) [1].  Human miR-302 was predicted based on homology with mouse [3], and later confirmed by cloning in human embryonic stem cells.  miR-302a is located in a cluster with the related miRNAs miR-302b (MIR:MI0000772), miR-302c (MIR:MI0000773), miR-302d (MI0000774), and miR-367 (MIR:MI0000775) on human chromosome 4. 	5
15753	MI0000739	hsa-mir-101-2	Homo sapiens miR-101-2 stem-loop	ACUGUCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAUAUCUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGU	Reference [1] reports two miR-101 precursor hairpin structures in human, on chromosome 1 (MIR:MI0000103) and 9 (MIR:MI0000739, named mir-101-precursor-9 in [1]).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15754	MI0000740	hsa-mir-219-2	Homo sapiens miR-219-2 stem-loop	ACUCAGGGGCUUCGCCACUGAUUGUCCAAACGCAAUUCUUGUACGAGUCUGCGGCCAACCGAGAAUUGUGGCUGGACAUCUGUGGCUGAGCUCCGGG	This human miRNA was predicted by computational methods using conservation with mouse and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR [2].  The mature products were later verified in human [3].  Two hairpin precursor structures are predicted, mir-219-1 on chromosome 6 (MIR:MI0000296) and mir-219-2 on chromosome 9 (MIR:MI0000740) [2]. 	5
15755	MI0000741	mmu-mir-219-2	Mus musculus miR-219-2 stem-loop	ACUCAGGGGCUUCGCCACUGAUUGUCCAAACGCAAUUCUUGUACGAGUCUGCGGCCAACCGAGAAUUGUGGCUGGACAUCUGUGGUUGAGCUCCGGG	Mouse mir-219 is predicted [2] based on homology to a reported miR from human (MIR:MI0000740) [1].  Its expression has not been verified in mouse. Two hairpin precursor structures are predicted, mir-219-1 on chromosome 17 (MIR:MI0000702) and mir-219-2 on chromosome 2 (MIR:MI0000741). 	6
15756	MI0000742	hsa-mir-34b	Homo sapiens miR-34b stem-loop	GUGCUCGGUUUGUAGGCAGUGUCAUUAGCUGAUUGUACUGUGGUGGUUACAAUCACUAACUCCACUGCCAUCAAAACAAGGCAC	Houbaviy et al. cloned 3 closely related sequences from mouse embryonic stem cells [1], and named them miR-34a, miR-34b and miR-172.  These names have been remapped to miR-34c (MIR:MI0000403), miR-34b (MIR:MI0000404) and miR-34a (MIR:MI0000584) to clarify homology with human sequences.  The predominant mature miRNA in human is expressed from the 3' arm (in contrast to previous annotation) [2].  Both arms express mature products in mouse. 	5
15757	MI0000743	hsa-mir-34c	Homo sapiens miR-34c stem-loop	AGUCUAGUUACUAGGCAGUGUAGUUAGCUGAUUGCUAAUAGUACCAAUCACUAACCACACGGCCAGGUAAAAAGAUU	Houbaviy et al. cloned 3 closely related sequences from mouse embryonic stem cells [1], and named them miR-34a, miR-34b and miR-172.  These names have been remapped to miR-34c (MIR:MI0000403), miR-34b (MIR:MI0000404) and miR-34a (MIR:MI0000584) to clarify homology with human sequences. 	5
15758	MI0000744	hsa-mir-299	Homo sapiens miR-299 stem-loop	AAGAAAUGGUUUACCGUCCCACAUACAUUUUGAAUAUGUAUGUGGGAUGGUAAACCGCUUCUU	The sequence from the 5' arm of this miRNA precursor is the predicted human homologue of mouse miR-299, cloned from mouse embryonic stem cells [1,2], later validated in human [4].  Altuvia et al [3] report the cloning of a miRNA sequence from the 3' arm of the same precursor in human. 	5
15759	MI0000745	hsa-mir-301a	Homo sapiens miR-301a stem-loop	ACUGCUAACGAAUGCUCUGACUUUAUUGCACUACUGUACUUUACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCAUCUGAAAGCAGG	This sequence is the predicted human homologue of mouse miR-301, cloned from mouse embryonic stem cells [1,3].  Its expression has also been confirmed in human ES cells [2]. 	5
15760	MI0000746	hsa-mir-99b	Homo sapiens miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC	This sequence is the predicted human homologue of mouse miR-99b, cloned from mouse brain [1] and embryonic stem cells [2,3].  Its expression was later validated in human [4-6]. 	5
15761	MI0000747	hsa-mir-296	Homo sapiens miR-296 stem-loop	AGGACCCUUCCAGAGGGCCCCCCCUCAAUCCUGUUGUGCCUAAUUCAGAGGGUUGGGUGGAGGCUCUCCUGAAGGGCUCU	This sequence is the predicted human homologue of mouse miR-296 cloned from mouse embryonic stem cells [1,3].  Its expression has also been verified in human ES cells [2]. 	5
15762	MI0000748	hsa-mir-130b	Homo sapiens miR-130b stem-loop	GGCCUGCCCGACACUCUUUCCCUGUUGCACUACUAUAGGCCGCUGGGAAGCAGUGCAAUGAUGAAAGGGCAUCGGUCAGGUC	This sequence is the predicted human homologue of mouse miR-130b cloned from mouse embryonic stem cells [1,2].  Its expression was later verified in human BC-1 cells [3]. 	5
15763	MI0000749	hsa-mir-30e	Homo sapiens miR-30e stem-loop	GGGCAGUCUUUGCUACUGUAAACAUCCUUGACUGGAAGCUGUAAGGUGUUCAGAGGAGCUUUCAGUCGGAUGUUUACAGCGGCAGGCUGCCA	This sequence is the predicted human homologue of mouse miR-30e [1,2,4]. Mature products from both arms of the precursor (hsa-miR-30e-5p and hsa-miR-30e-3p) were later independently verified in human myelocytic leukemia (HL-60) cells [3].  Landgraf et al. later showed that the 5' product is the predominant one [5].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	5
15764	MI0000750	hsa-mir-26a-2	Homo sapiens miR-26a-2 stem-loop	GGCUGUGGCUGGAUUCAAGUAAUCCAGGAUAGGCUGUUUCCAUCUGUGAGGCCUAUUCUUGAUUACUUGUUUCUGGAGGCAGCU	miR-26a was cloned from HeLa cells [1].  Two predicted hairpin precursor sequences are present on chromosome 3 (MIR:MI0000083) and 12 (MIR:MI0000750), each with homologues in mouse (MIR:MI0000573 and MIR:MI0000706).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [6]. 	5
15765	MI0000751	cbr-mir-72	Caenorhabditis briggsae miR-72 stem-loop	UGGACUCGCCCGAGCUAGGCAGAUGUUGGCAUAGCUGAAUGCAAAUCAGAAAUCGAAAUUCGAAAAGUUUGAAUUUCGCGCGCUCAGCUUCGCCACAUCGUGCCAUGCGUAGGCUUGAGACCA	This sequence is the predicted C. briggsae homologue of a miRNA cloned from C. elegans (MIR:MI0000043) (Uwe Ohler, pers. comm.). 	2
15766	MI0000752	cel-mir-353	Caenorhabditis elegans miR-353 stem-loop	UGUUGAAGUAUUGCAAAAGCAAAGGACGGGCACAAUUGCCAUGUGUUGGUAUUAUUGCUUCAAGUUAUUUGAAGCUGUAAUAUCAAUAAGCAUGUCUCGUGUGAAGUCCG	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing.  The 5' end of the mature sequence ws mapped by PCR, but the 3' ends have not been experimentally determined. 	3
15767	MI0000753	cel-mir-354	Caenorhabditis elegans miR-354 stem-loop	CAGAGCCGACUAAGCACCUUGGUGCGGCUGCAGACGGGUAUCCGGCUCGACGUUCAUACAUCACGACUUCUUUCCUUUUACCUUGUUUGUUGCUGCUCCUAUUGGUUUUG	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing.  The 5' end of the mature sequence ws mapped by PCR, but the 3' ends have not been experimentally determined. 	3
15768	MI0000754	cel-mir-355	Caenorhabditis elegans miR-355 stem-loop	AAUAAUGUCAAGAAUUGAAUGGUUUGUUUUAGCCUGAGCUAUGAGUCAUCGGAAUAUGCAUAGCUUCUUGCUAAAACAUGCCAAUCAAUCUUAAUUGACGAAGUUUUUGA	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing [1].  The 5' end of the mature sequence was mapped by PCR, and the 3' end confirmed later [2]. 	3
15769	MI0000755	cel-mir-356	Caenorhabditis elegans miR-356 stem-loop	UAAAGUUUCCUUGAGAACAAUGUGGUUGAGCAACGCGAACAAAUCAUCAAUGUAAAUUUCAGCGGAUUCGUUACGACGUGUCUCACCACAUCGUUAGUAGGAUUUCAGAA	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing.  The 5' end of the mature sequence ws mapped by PCR, but the 3' ends have not been experimentally determined. 	3
15770	MI0000756	cel-mir-357	Caenorhabditis elegans miR-357 stem-loop	ACGCUGUACUACUCACCAGCGGAUCCCUACAACGCUGCGCAUAUGCAUGAACACAAUGAAAAUGUAAAUGCCAGUCGUUGCAGGAGUUCGCAUACAGUAGUAAAAUGCGC	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15771	MI0000757	cel-mir-358	Caenorhabditis elegans miR-358 stem-loop	AAACUCGCGACGGCUGGCGACCUGGCCAGGCAUUCCAACUGUCAAACUUACAAAGCUUUCUCGACAAUUGGUAUCCCUGUCAAGGUCUCAAUCCGUUCAGCGAAUUCGUU	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15772	MI0000758	cel-mir-359	Caenorhabditis elegans miR-359 stem-loop	AAUGCUCCUUGAAAUUUCAAUCGUUAGAGUAACACACAGUUACACGACCUCAUCAAUCGUGUCACUGGUCUUUCUCUGACGAAUUGAAGUUCUGGAGACAAUUUUGGUUG	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing [1].  The extents of the dominant mature miRNA species are adjusted here in accordance with a large scale cloning and sequencing study [2]. 	3
15773	MI0000759	cel-mir-360	Caenorhabditis elegans miR-360 stem-loop	CAUUCUGUUAGGAAGCAUCAAUGUGUUGUGACCGUUGUUACGGUCAAUUUGCAAAUUGAAAAAAUGACCGUAAUCCCGUUCACAAUACAUUGUUCGUUUUCUCCAAAGGU	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing.  The 5' end of the mature sequence ws mapped by PCR, but the 3' ends have not been experimentally determined. 	3
15774	MI0000760	hsa-mir-361	Homo sapiens miR-361 stem-loop	GGAGCUUAUCAGAAUCUCCAGGGGUACUUUAUAAUUUCAAAAAGUCCCCCAGGUGUGAUUCUGAUUUGCUUC		5
15775	MI0000761	mmu-mir-361	Mus musculus miR-361 stem-loop	GAAGCUUAUCAGAAUCUCCAGGGGUACUUAGUAUUUGAAAAGUCCCCCAGGUGUGAUUCUGAUUUGUUUC		6
15776	MI0000762	hsa-mir-362	Homo sapiens miR-362 stem-loop	CUUGAAUCCUUGGAACCUAGGUGUGAGUGCUAUUUCAGUGCAACACACCUAUUCAAGGAUUCAAA		5
15777	MI0000763	mmu-mir-362	Mus musculus miR-362 stem-loop	CUCGAAUCCUUGGAACCUAGGUGUGAAUGCUGCUUCAGUGCAACACACCUGUUCAAGGAUUCAAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
15778	MI0000764	hsa-mir-363	Homo sapiens miR-363 stem-loop	UGUUGUCGGGUGGAUCACGAUGCAAUUUUGAUGAGUAUCAUAGGAGAAAAAUUGCACGGUAUCCAUCUGUAAACC		5
15779	MI0000765	mmu-mir-363	Mus musculus miR-363 stem-loop	UGUUAUCAGGUGGAACACGAUGCAAUUUUGGUUGGUGUAAUAGGAGGAAAAUUGCACGGUAUCCAUCUGUAAACC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15780	MI0000767	hsa-mir-365-1	Homo sapiens miR-365-1 stem-loop	ACCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUCCACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA	Xie et al. [1] refer to this sequence by the internal identifier MIR245. The sequence is unrelated to C. elegans mir-245 (MIR:MI0000321). 	5
15781	MI0000768	mmu-mir-365-1	Mus musculus miR-365-1 stem-loop	ACCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUCCGCUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA	Xie et al. [1] refer to this sequence by the internal identifier MIR245. The sequence is unrelated to C. elegans mir-245 (MIR:MI0000321). 	6
15782	MI0000769	hsa-mir-365-2	Homo sapiens miR-365-2 stem-loop	AGAGUGUUCAAGGACAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUUCUGACUCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCAGUGUGCAUCGGG	Xie et al. [1] refer to this sequence by the internal identifier MIR190. The sequence is unrelated to mammalian mir-190 (MIR:MI0000486). 	5
15783	MI0000772	hsa-mir-302b	Homo sapiens miR-302b stem-loop	GCUCCCUUCAACUUUAACAUGGAAGUGCUUUCUGUGACUUUAAAAGUAAGUGCUUCCAUGUUUUAGUAGGAGU	Human miR-302a (MIR:MI0000738), miR-302b (MIR:MI0000772), miR-302c (MIR:MI0000773), miR-302d (MIR:MI0000774) and miR-367 (MIR:MI0000775) are clustered on chromosome 4.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
15784	MI0000773	hsa-mir-302c	Homo sapiens miR-302c stem-loop	CCUUUGCUUUAACAUGGGGGUACCUGCUGUGUGAAACAAAAGUAAGUGCUUCCAUGUUUCAGUGGAGG		5
15785	MI0000774	hsa-mir-302d	Homo sapiens miR-302d stem-loop	CCUCUACUUUAACAUGGAGGCACUUGCUGUGACAUGACAAAAAUAAGUGCUUCCAUGUUUGAGUGUGG	Human miR-302a (MIR:MI0000738), miR-302b (MIR:MI0000772), miR-302c (MIR:MI0000773), miR-302d (MIR:MI0000774) and miR-367 (MIR:MI0000775) are clustered on chromosome 4. 	5
15786	MI0000775	hsa-mir-367	Homo sapiens miR-367 stem-loop	CCAUUACUGUUGCUAAUAUGCAACUCUGUUGAAUAUAAAUUGGAAUUGCACUUUAGCAAUGGUGAUGG		5
15787	MI0000776	hsa-mir-376c	Homo sapiens miR-376c stem-loop	AAAAGGUGGAUAUUCCUUCUAUGUUUAUGUUAUUUAUGGUUAAACAUAGAGGAAAUUCCACGUUUU	This miRNA has been named both miR-368 and miR376c in the literature, and previously here.  The mature miR-376c product has been shown to be modified by A to I edits [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15788	MI0000777	hsa-mir-369	Homo sapiens miR-369 stem-loop	UUGAAGGGAGAUCGACCGUGUUAUAUUCGCUUUAUUGACUUCGAAUAAUACAUGGUUGAUCUUUUCUCAG		5
15789	MI0000778	hsa-mir-370	Homo sapiens miR-370 stem-loop	AGACAGAGAAGCCAGGUCACGUCUCUGCAGUUACACAGCUCACGAGUGCCUGCUGGGGUGGAACCUGGUCUGUCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15790	MI0000779	hsa-mir-371	Homo sapiens miR-371 stem-loop	GUGGCACUCAAACUGUGGGGGCACUUUCUGCUCUCUGGUGAAAGUGCCGCCAUCUUUUGAGUGUUAC	Human miR-371 (MIR:MI0000779), miR-372 (MIR:MI0000780) and miR-373 (MIR:MI0000781) are clustered within 1.1kb on chromosome 19.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15791	MI0000780	hsa-mir-372	Homo sapiens miR-372 stem-loop	GUGGGCCUCAAAUGUGGAGCACUAUUCUGAUGUCCAAGUGGAAAGUGCUGCGACAUUUGAGCGUCAC		5
15792	MI0000781	hsa-mir-373	Homo sapiens miR-373 stem-loop	GGGAUACUCAAAAUGGGGGCGCUUUCCUUUUUGUCUGUACUGGGAAGUGCUUCGAUUUUGGGGUGUCCC		5
15793	MI0000782	hsa-mir-374a	Homo sapiens miR-374a stem-loop	UACAUCGGCCAUUAUAAUACAACCUGAUAAGUGUUAUAGCACUUAUCAGAUUGUAUUGUAAUUGUCUGUGUA		5
15794	MI0000783	hsa-mir-375	Homo sapiens miR-375 stem-loop	CCCCGCGACGAGCCCCUCGCACAAACCGGACCUGAGCGUUUUGUUCGUUCGGCUCGCGUGAGGC		5
15795	MI0000784	hsa-mir-376a-1	Homo sapiens miR-376a-1 stem-loop	UAAAAGGUAGAUUCUCCUUCUAUGAGUACAUUAUUUAUGAUUAAUCAUAGAGGAAAAUCCACGUUUUC	The mature miR-376a products have been shown to be modified by A to I edits [3]. 	5
15796	MI0000785	hsa-mir-377	Homo sapiens miR-377 stem-loop	UUGAGCAGAGGUUGCCCUUGGUGAAUUCGCUUUAUUUAUGUUGAAUCACACAAAGGCAACUUUUGUUUG		5
15797	MI0000786	hsa-mir-378	Homo sapiens miR-378 stem-loop	AGGGCUCCUGACUCCAGGUCCUGUGUGUUACCUAGAAAUAGCACUGGACUUGGAGUCAGAAGGCCU	miR-422b was the most abundant miRNA cloned from human promyelocytic leukemia (HL-60) cells [2].  The sequence originates from the opposite arm of the human homologue of previously identified mouse mir-378 [1]. Landgraf et al. show that the 3' product (previously called miR-422b) is the predominant one [3].  Further, mir-378 and mir-422a loci are unrelated.  miR-422b is thus renamed miR-378 here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15798	MI0000787	hsa-mir-379	Homo sapiens miR-379 stem-loop	AGAGAUGGUAGACUAUGGAACGUAGGCGUUAUGAUUUCUGACCUAUGUAACAUGGUCCACUAACUCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15799	MI0000788	hsa-mir-380	Homo sapiens miR-380 stem-loop	AAGAUGGUUGACCAUAGAACAUGCGCUAUCUCUGUGUCGUAUGUAAUAUGGUCCACAUCUU	Landgraf et al. confirm that the 3' product is the predominant one [3]. 	5
15800	MI0000789	hsa-mir-381	Homo sapiens miR-381 stem-loop	UACUUAAAGCGAGGUUGCCCUUUGUAUAUUCGGUUUAUUGACAUGGAAUAUACAAGGGCAAGCUCUCUGUGAGUA		5
15801	MI0000790	hsa-mir-382	Homo sapiens miR-382 stem-loop	UACUUGAAGAGAAGUUGUUCGUGGUGGAUUCGCUUUACUUAUGACGAAUCAUUCACGGACAACACUUUUUUCAGUA		5
15802	MI0000791	hsa-mir-383	Homo sapiens miR-383 stem-loop	CUCCUCAGAUCAGAAGGUGAUUGUGGCUUUGGGUGGAUAUUAAUCAGCCACAGCACUGCCUGGUCAGAAAGAG		5
15803	MI0000792	mmu-mir-375	Mus musculus miR-375 stem-loop	CCCCGCGACGAGCCCCUCGCACAAACCGGACCUGAGCGUUUUGUUCGUUCGGCUCGCGUGAGGC		6
15804	MI0000793	mmu-mir-376a	Mus musculus miR-376a stem-loop	UAAAAGGUAGAUUCUCCUUCUAUGAGUACAAUAUUAAUGACUAAUCGUAGAGGAAAAUCCACGUUUUC	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [1].  The expression of miR-376a was independently verified by Poy et al. [2].  The mature miR-376a products have been shown to be modified by A to I edits [4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
15805	MI0000794	mmu-mir-377	Mus musculus miR-377 stem-loop	UGAGCAGAGGUUGCCCUUGGUGAAUUCGCUUUAUUGAUGUUGAAUCACACAAAGGCAACUUUUGUUUG		6
15806	MI0000795	mmu-mir-378	Mus musculus miR-378 stem-loop	AGGGCUCCUGACUCCAGGUCCUGUGUGUUACCUCGAAAUAGCACUGGACUUGGAGUCAGAAGGCCU	Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product (identified in [1]) is renamed miR-378* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15807	MI0000796	mmu-mir-379	Mus musculus miR-379 stem-loop	AGAGAUGGUAGACUAUGGAACGUAGGCGUUAUGUUUUUGACCUAUGUAACAUGGUCCACUAACUCU		6
15808	MI0000797	mmu-mir-380	Mus musculus miR-380 stem-loop	AAGAUGGUUGACCAUAGAACAUGCGCUACUUCUGUGUCGUAUGUAGUAUGGUCCACAUCUU	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse, including a sequence from the 3' arm of this precursor [1].  Poy et al. cloned a sequence from the 5' arm from mouse pancreatic beta cell line MIN6 [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15809	MI0000798	mmu-mir-381	Mus musculus miR-381 stem-loop	UACUUAAAGCGAGGUUGCCCUUUGUAUAUUCGGUUUAUUGACAUGGAAUAUACAAGGGCAAGCUCUCUGUGAGUA		6
15810	MI0000799	mmu-mir-382	Mus musculus miR-382 stem-loop	UACUUGAAGAGAAGUUGUUCGUGGUGGAUUCGCUUUACUUGUGACGAAUCAUUCACGGACAACACUUUUUUCAGUA		6
15811	MI0000800	mmu-mir-383	Mus musculus miR-383 stem-loop	CUCAGAUCAGAAGGUGACUGUGGCUUUGGGUGGAUAUUAAUCAGCCACAGCACUGCCUGGUCAGAAAGAG		6
15812	MI0000801	cel-lsy-6	Caenorhabditis elegans lsy-6 stem-loop	CCAUCAAAUGCGUCUAGUAUCAAAAUCAUGUAAAAACUGUAAAACAGAUUUUGUAUGAGACGCAUUUCGAUGA	The bilateral taste receptor neurons ASE left (ASEL) and ASE right (ASER) are thought to be responsible for an assymetrical pattern of chemoreceptor gene expression in C. elegans.  miRNA lsy-6 is expressed in ASEL but not ASER and has been shown to control this bilateral assymetry by binding to a complementary site in the 3' UTR of cog-1, an Nkx-type homeobox gene. Johnston and Hobert determined the locus of lsy-6, and predicted the position of the mature miR sequence [1].  The miR location was refined by Ohler et al. who mapped the 5' end by PCR and confirmed the 3' end from the cloning of the miR* sequence from the opposite arm of the precursor [2]. 	3
15813	MI0000802	hsa-mir-340	Homo sapiens miR-340 stem-loop	UUGUACCUGGUGUGAUUAUAAAGCAAUGAGACUGAUUGUCAUAUGUCGUUUGUGGGAUCCGUCUCAGUUACUUUAUAGCCAUACCUGGUAUCUUA	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2].  Landgraf et al. show that the 5' product is the predominant one in human, mouse and rat [3], in contrast to the previous annotation.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15814	MI0000803	hsa-mir-330	Homo sapiens miR-330 stem-loop	CUUUGGCGAUCACUGCCUCUCUGGGCCUGUGUCUUAGGCUCUGCAAGAUCAACCGAGCAAAGCACACGGCCUGCAGAGAGGCAGCGCUCUGCCC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15815	MI0000804	hsa-mir-328	Homo sapiens miR-328 stem-loop	UGGAGUGGGGGGGCAGGAGGGGCUCAGGGAGAAAGUGCAUACAGCCCCUGGCCCUCUCUGCCCUUCCGUCCCCUG	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15816	MI0000805	hsa-mir-342	Homo sapiens miR-342 stem-loop	GAAACUGGGCUCAAGGUGAGGGGUGCUAUCUGUGAUUGAGGGACAUGGUUAAUGGAAUUGUCUCACACAGAAAUCGCACCCGUCACCUUGGCCUACUUA	This sequence was predicted by homology to a rat miRNA [1,2] and later verified in human [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15817	MI0000806	hsa-mir-337	Homo sapiens miR-337 stem-loop	GUAGUCAGUAGUUGGGGGGUGGGAACGGCUUCAUACAGGAGUUGAUGCACAGUUAUCCAGCUCCUAUAUGAUGCCUUUCUUCAUCCCCUUCAA	This sequence was predicted based on homology with a verified rat miRNA [1,2], and later confirmed in human [3]. 	5
15818	MI0000807	hsa-mir-323	Homo sapiens miR-323 stem-loop	UUGGUACUUGGAGAGAGGUGGUCCGUGGCGCGUUCGCUUUAUUUAUGGCGCACAUUACACGGUCGACCUCUUUGCAGUAUCUAAUC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15819	MI0000808	hsa-mir-326	Homo sapiens miR-326 stem-loop	CUCAUCUGUCUGUUGGGCUGGAGGCAGGGCCUUUGUGAAGGCGGGUGGUGCUCAGAUCGCCUCUGGGCCCUUCCUCCAGCCCCGAGGCGGAUUCA	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3].  miR-326 cloned in [3] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
15820	MI0000809	hsa-mir-151	Homo sapiens miR-151 stem-loop	UUUCCUGCCCUCGAGGAGCUCACAGUCUAGUAUGUCUCAUCCCCUACUAGACUGAAGCUCCUUGAGGACAGGGAUGGUCAUACUCACCUC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3,4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15821	MI0000810	hsa-mir-135b	Homo sapiens miR-135b stem-loop	CACUCUGCUGUGGCCUAUGGCUUUUCAUUCCUAUGUGAUUGCUGUCCCAAACUCAUGUAGGGCUAAAAGCCAUGGGCUACAGUGAGGGGCGAGCUCC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15822	MI0000811	hsa-mir-148b	Homo sapiens miR-148b stem-loop	CAAGCACGAUUAGCAUUUGAGGUGAAGUUCUGUUAUACACUCAGGCUGUGGCUCUCUGAAAGUCAGUGCAUCACAGAACUUUGUCUCGAAAGCUUUCUA	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2].  Its expression was later verified in human [3,4]. 	5
15823	MI0000812	hsa-mir-331	Homo sapiens miR-331 stem-loop	GAGUUUGGUUUUGUUUGGGUUUGUUCUAGGUAUGGUCCCAGGGAUCCCAGAUCAAACCAGGCCCCUGGGCCUAUCCUAGAACCAACCUAAGCUC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15824	MI0000813	hsa-mir-324	Homo sapiens miR-324 stem-loop	CUGACUAUGCCUCCCCGCAUCCCCUAGGGCAUUGGUGUAAAGCUGGAGACCCACUGCCCCAGGUGCUGCUGGGGGUUGUAGUC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2].  Expression of the miRNA from the 3' arm of the hairpin was later verified in human BC-1 cells [3].  The 5' end of the miRNA may be offset with respect to previous annotations.  miR-324-3p cloned in [4] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
15825	MI0000814	hsa-mir-338	Homo sapiens miR-338 stem-loop	UCUCCAACAAUAUCCUGGUGCUGAGUGAUGACUCAGGCGACUCCAGCAUCAGUGAUUUUGUUGAAGA	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
15826	MI0000815	hsa-mir-339	Homo sapiens miR-339 stem-loop	CGGGGCGGCCGCUCUCCCUGUCCUCCAGGAGCUCACGUGUGCCUGCCUGUGAGCGCCUCGACGACAGAGCCGGCGCCUGCCCCAGUGUCUGCGC	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,3].  Expression of mature miRNA was later verified in human [2,4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	5
15827	MI0000816	hsa-mir-335	Homo sapiens miR-335 stem-loop	UGUUUUGAGCGGGGGUCAAGAGCAAUAACGAAAAAUGUUUGUCAUAAACCGUUUUUCAUUAUUGCUCCUGACCUCCUCUCAUUUGCUAUAUUCA	This sequence is the predicted homologue of a miRNA cloned from rat neuronal tissue [1,2], later verified in human [3]. 	5
15828	MI0000817	mmu-mir-335	Mus musculus miR-335 stem-loop	UCUUUUGGGCGGGGGUCAAGAGCAAUAACGAAAAAUGUUUGUUUUUCGUAAACCGUUUUUCAUUAUUGCUCCUGACCCCCUCUCAUGGGUUAUAGCCA		6
15829	MI0000818	cbr-lsy-6	Caenorhabditis briggsae lsy-6 stem-loop	CCACAGAAUGCGUCCAGUAUCAAAAUCACAUCAAAGAGAAUACGGUGGAUUUUGUAUGAGACGCAUUCCGUGGC	The bilateral taste receptor neurons ASE left (ASEL) and ASE right (ASER) are thought to be responsible for an assymetrical pattern of chemoreceptor gene expression in C. elegans.  miRNA lsy-6 is expressed in ASEL but not ASER and has been shown to control this bilateral assymetry by binding to a complementary site in the 3' UTR of cog-1, an Nkx-type homeobox gene [1].  This sequence is the predicted C. briggsae homologue of miR-lsy-6 from elegans.  Its expression has not been verified in briggsae. 	2
15830	MI0000819	cel-mir-392	Caenorhabditis elegans miR-392 stem-loop	UUUUUGAAAAUCUCGCAGACGUGUUCAGUCAGCAUUCGUGGUUGAGGAUAUCGAACACAAAAAAAGAUAUCAUCGAUCACGUGUGAUGACAGAUUUUCUGCGACUAACAG	This miRNA was predicted by computational analysis of C. elegans and C. briggsae, and expression of the mature microRNA confirmed by PCR amplification, cloning and sequencing [1].  The 5' end of the mature sequence was mapped by PCR, and the 3' end confirmed later [2]. 	3
15831	MI0000820	mmu-mir-133a-2	Mus musculus miR-133a-2 stem-loop	AGAAGCCAAAUGCUUUGCUGAAGCUGGUAAAAUGGAACCAAAUCAGCUGUUGGAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGCGCAUUGAUCACGCCGCA	This mature miRNA sequence was named miR-133 in reference [1], and renamed miR-133a on subsequent identification of a homologue differing at the terminal 3' position (MIR:MI0000821).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15832	MI0000821	mmu-mir-133b	Mus musculus miR-133b stem-loop	CCUCCAAAGGGAGUGGCCCCCUGCUCUGGCUGGUCAAACGGAACCAAGUCCGUCUUCCUGAGAGGUUUGGUCCCCUUCAACCAGCUACAGCAGGGCUGGCAAAGCUCAAUAUUUGGAGA	miR-133b was predicted based on comparative analysis of human, mouse and Fugu [1].  It is homologous to miR-133a (MIR:MI0000159 and MIR:MI0000820). The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
15833	MI0000822	hsa-mir-133b	Homo sapiens miR-133b stem-loop	CCUCAGAAGAAAGAUGCCCCCUGCUCUGGCUGGUCAAACGGAACCAAGUCCGUCUUCCUGAGAGGUUUGGUCCCCUUCAACCAGCUACAGCAGGGCUGGCAAUGCCCAGUCCUUGGAGA	miR-133b was predicted based on comparative analysis of human, mouse and Fugu [1], and later verified in human [2]. 	5
15834	MI0000823	mmu-mir-181b-2	Mus musculus miR-181b-2 stem-loop	UUGAUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGAAUGUCAACCAACUCACUGAUCAAUGAAUGCAAACUGCGGGCCAAAAA	Mouse miR-181b was predicted by computational methods using conservation with human and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and independently in mouse [2,3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
15835	MI0000824	hsa-mir-325	Homo sapiens miR-325 stem-loop	AUACAGUGCUUGGUUCCUAGUAGGUGUCCAGUAAGUGUUUGUGACAUAAUUUGUUUAUUGAGGACCUCCUAUCAAUCAAGCACUGUGCUAGGCUCUGG	This sequence is the predicted human homologue [2] of a sequence cloned from rat neuronal tissue [1].  The mature miRNA differs from the rat sequence at two positions, and its expression has not been verified in human. 	5
15836	MI0000825	hsa-mir-345	Homo sapiens miR-345 stem-loop	ACCCAAACCCUAGGUCUGCUGACUCCUAGUCCAGGGCUCGUGAUGGCUGGUGGGCCCUGAACGAGGGGUCUGGAGGCCUGGGUUUGAAUAUCGACAGC	This sequence is the predicted human homologue [2] of a sequence cloned from rat neuronal tissue [1], later validated in human [3,4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
15837	MI0000826	hsa-mir-346	Homo sapiens miR-346 stem-loop	GGUCUCUGUGUUGGGCGUCUGUCUGCCCGCAUGCCUGCCUCUCUGUUGCUCUGAAGGAGGCAGGGGCUGGGCCUGCAGCUGCCUGGGCAGAGCGG	This sequence is the predicted human homologue [2] of a sequence cloned from rat neuronal tissue [1].  The mature miRNA differs from the rat sequence at two positions, and its expression has not been verified in human. 	5
15838	MI0000827	rno-let-7a-1	Rattus norvegicus let-7a-1 stem-loop	UUCACUGUGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUAAGGUGAU		8
15839	MI0000828	rno-let-7a-2	Rattus norvegicus let-7a-2 stem-loop	CGGCAUGCUCCCAGGCUGAGGUAGUAGGUUGUAUAGUUUAGAGUUACAACAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCUUGGGACUUGCAC		8
15840	MI0000829	rno-let-7b	Rattus norvegicus let-7b stem-loop	GCGGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGCAGUGAUGUCGCCCCUCCGAAGAUAACUAUACAACCUACUGCCUUCCCUGA		8
15841	MI0000830	rno-let-7c-1	Rattus norvegicus let-7c-1 stem-loop	UGUGUGCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGCACACU		8
15842	MI0000831	rno-let-7c-2	Rattus norvegicus let-7c-2 stem-loop	ACGGCCUUUGGGGUGAGGUAGUAGGUUGUAUGGUUUUGGGCUCUGCCCCGCUCUGCGGUAACUAUACAAUCUACUGUCUUUCCUGAAGUGGCCGC		8
15843	MI0000832	rno-let-7e	Rattus norvegicus let-7e stem-loop	CGCGCCCCCCGGGCUGAGGUAGGAGGUUGUAUAGUUGAGGAAGACACCCGAGGAGAUCACUAUACGGCCUCCUAGCUUUCCCCAGGCUGCGCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15844	MI0000833	rno-let-7f-1	Rattus norvegicus let-7f-1 stem-loop	AUCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUUAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGAG		8
15845	MI0000834	rno-let-7f-2	Rattus norvegicus let-7f-2 stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		8
15846	MI0000835	rno-let-7i	Rattus norvegicus let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15847	MI0000836	rno-mir-7a-2	Rattus norvegicus miR-7a-2 stem-loop	GGACAGACCAGCCCUGUCUGGAAGACUAGUGAUUUUGUUGUUGUGUCUGUGUCCAACAACAAGUCCCAGUCUGCCACAUGGUGUUGGUCACAUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15848	MI0000837	rno-mir-7b	Rattus norvegicus miR-7b stem-loop	AGGCCAGAACACAUGAGCCAAUGCUAUGUGGAAGACUUGUGAUUUUGUUGUUCUGAUAUGAUAUGACAACAAGUCACAGCCAGCCUCAUAGAGUGGACUCCCAUCACCUU		8
15849	MI0000838	rno-mir-9-1	Rattus norvegicus miR-9-1 stem-loop	CGGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA		8
15850	MI0000839	rno-mir-9-3	Rattus norvegicus miR-9-3 stem-loop	GGAGGCCCGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUGCCACAGAGCCGUCAUAAAGCUAGAUAACCGAAAGUAGAAAUGACUCUAA		8
15851	MI0000840	rno-mir-9-2	Rattus norvegicus miR-9-2 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA		8
15852	MI0000841	rno-mir-10a	Rattus norvegicus miR-10a stem-loop	GACCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCA		8
15853	MI0000842	rno-mir-10b	Rattus norvegicus miR-10b stem-loop	CCAAAGUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUACCCACAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA		8
15854	MI0000843	rno-mir-15b	Rattus norvegicus miR-15b stem-loop	UUGGAACCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU		8
15855	MI0000844	rno-mir-16	Rattus norvegicus miR-16 stem-loop	CAUACUUGUUCCGCUCUAGCAGCACGUAAAUAUUGGCGUAGUGAAAUAAAUAUUAAACACCAAUAUUAUUGUGCUGCUUUAGUGUGACAGGGAUA		8
15856	MI0000845	rno-mir-17-1	Rattus norvegicus miR-17-1 stem-loop	GUCAGGAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGGUGUGUGCAUCUACUGCAGUGAAGGCACUUGUGGCAUUGUGCUGAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15857	MI0000846	rno-mir-18a	Rattus norvegicus miR-18a stem-loop	UGCGUGCUUUUUGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGACUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCAUAAGAAGUUAUGUC	This miRNA was predicted based on homology to a verified miRNA from mouse [1].  Its expression in rat was later verified by cloning [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15858	MI0000847	rno-mir-19b-1	Rattus norvegicus miR-19b-1 stem-loop	CACUGGUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUAUAAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUGGUG		8
15859	MI0000848	rno-mir-19b-2	Rattus norvegicus miR-19b-2 stem-loop	ACAUUGCUACUUACGGUUAGUUUUGCAGAUUUGCAGUUCAGCGUAUAUGUGGAUAUAUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUGAUGU		8
15860	MI0000849	rno-mir-19a	Rattus norvegicus miR-19a stem-loop	GCAGCCCUCUGUUCGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC		8
15861	MI0000850	rno-mir-21	Rattus norvegicus miR-21 stem-loop	UGUACCACCUUGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUCUGACAUUUUGGUAUC		8
15862	MI0000851	rno-mir-22	Rattus norvegicus miR-22 stem-loop	ACCUGGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCCACUGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15863	MI0000852	rno-mir-23a	Rattus norvegicus miR-23a stem-loop	CGGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGAUGCCAGUCACAAAUCACAUUGCCAGGGAUUUCCAACUGACCC		8
15864	MI0000853	rno-mir-23b	Rattus norvegicus miR-23b stem-loop	CUCACCUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUGAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCAUGACCUUGGC		8
15865	MI0000854	rno-mir-24-1	Rattus norvegicus miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUCACACACUGGCUCAGUUCAGCAGGAACAGGAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15866	MI0000855	rno-mir-24-2	Rattus norvegicus miR-24-2 stem-loop	GCCUCUCCCUGGGCUCCGCCUCCUGUGCCUACUGAGCUGAAACAGUUGAUUCCAGUGCACUGGCUCAGUUCAGCAGGAACAGGAGUCCAGCCCCCAUAGGAGCUGGCA		8
15867	MI0000856	rno-mir-25	Rattus norvegicus miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACACGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC		8
15868	MI0000857	rno-mir-26a	Rattus norvegicus miR-26a stem-loop	AAGGCCGUGGCCUUGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAGGGGCCUAUUCUUGGUUACUUGCACGGGGACGCGGGCCUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15869	MI0000858	rno-mir-26b	Rattus norvegicus miR-26b stem-loop	UGCCCGGGACCCAGUUCAAGUAAUUCAGGAUAGGUUGUGGUGCUGGCCAGCCUGUUCUCCAUUACUUGGCUCGGGGGCCGGUGCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15870	MI0000859	rno-mir-27b	Rattus norvegicus miR-27b stem-loop	ACCUCUCUAACAAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGUG		8
15871	MI0000860	rno-mir-27a	Rattus norvegicus miR-27a stem-loop	UGGCCUGUGGAGCAGGGCUUAGCUGCUUGUGAGCAAGGUCUACAGCAAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCUGGACCC		8
15872	MI0000861	rno-mir-28	Rattus norvegicus miR-28 stem-loop	GGUCCCUACCCGCAAGGAGCUCACAGUCUAUUGAGUUCCUUUUCUGAUUCUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU		8
15873	MI0000862	rno-mir-29b-2	Rattus norvegicus miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG		8
15874	MI0000863	rno-mir-29a	Rattus norvegicus miR-29a stem-loop	ACCCCUUAGAGGAUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAGAAUUUUCUAGCACCAUCUGAAAUCGGUUAUAAUGAUUGGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15875	MI0000864	rno-mir-29b-1	Rattus norvegicus miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGUGG		8
15876	MI0000865	rno-mir-29c	Rattus norvegicus miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15877	MI0000866	rno-mir-30c-1	Rattus norvegicus miR-30c-1 stem-loop	ACCAUGUUGUAGUGUGUGUAAACAUCCUACACUCUCAGCUGUGAGCUCAAGGUGGCUGGGAGAGGGUUGUUUACUCCUUCUGCCAUGGA		8
15878	MI0000867	rno-mir-30e	Rattus norvegicus miR-30e stem-loop	GGGCAGUCUUUGCUACUGUAAACAUCCUUGACUGGAAGCUGUAAGGUGUUGAGAGGAGCUUUCAGUCGGAUGUUUACAGCGGCAGGCUGCCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15879	MI0000868	rno-mir-30b	Rattus norvegicus miR-30b stem-loop	CCGAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUCAUACAUGAGUUGGCUGGGAUGUGGAUGUUUACGUCAGCUGUCUUGGA	Landgraf et al. show that miRNA sequences from both arms of this hairpin precursor are similarly expressed [4]. 	8
15880	MI0000869	rno-mir-30d	Rattus norvegicus miR-30d stem-loop	AAGUCUGUGUCUGUAAACAUCCCCGACUGGAAGCUGUAAGCCACAGCCAAGCUUUCAGUCAGAUGUUUGCUGCUACUGGCUC		8
15881	MI0000870	rno-mir-30a	Rattus norvegicus miR-30a stem-loop	GCAACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAAAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC		8
15882	MI0000871	rno-mir-30c-2	Rattus norvegicus miR-30c-2 stem-loop	GAGUGACAGAUACUGUAAACAUCCUACACUCUCAGCUGUGAAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUCUCUGCCUU		8
15883	MI0000872	rno-mir-31	Rattus norvegicus miR-31 stem-loop	UGCUCCUGAAACUUGGAACUGGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGAGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCCUGUCUGACAGCAGCU		8
15884	MI0000873	rno-mir-32	Rattus norvegicus miR-32 stem-loop	GGGGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUCUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15885	MI0000874	rno-mir-33	Rattus norvegicus miR-33 stem-loop	CCGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGCAGUACCUGUGCAAUGUUUCCACAGUGCAUCACGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15886	MI0000875	rno-mir-34b	Rattus norvegicus miR-34b stem-loop	GUGCUCGGUUUGUAGGCAGUGUAAUUAGCUGAUUGUAGUGCGGUGCUGACAAUCACUAACUCCACUGCCAUCAAAACAAGGCAC	This sequence is the predicted rat homologue of a confirmed miRNA from human [1].  Its expression has not been experimentally verified in rat. 	8
15887	MI0000876	rno-mir-34c	Rattus norvegicus miR-34c stem-loop	AGUCUAGUUACUAGGCAGUGUAGUUAGCUGAUUGCUAAUAGUACCAAUCACUAACCACACAGCCAGGUAAAAAGACU		8
15888	MI0000877	rno-mir-34a	Rattus norvegicus miR-34a stem-loop	CCGGCUGUGAGUAAUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGUAUUAGCUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15889	MI0000878	rno-mir-92a-1	Rattus norvegicus miR-92a-1 stem-loop	CUUUCUACACAGGUUGGGAUUUGUCGCAAUGCUGUGUUUCUGUAUAGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG		8
15890	MI0000879	rno-mir-92a-2	Rattus norvegicus miR-92a-2 stem-loop	UGCCCAUUCAUCCACAGGUGGGGAUUAGUGCCAUUACUUGUGUUAGAUAAAAAGUAUUGCACUUGUCCCGGCCUGAGGAAGAAAAGAGGGUU		8
15891	MI0000880	rno-mir-93	Rattus norvegicus miR-93 stem-loop	AGUCAUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGCAUUGCCUGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCAGGACA		8
15892	MI0000881	rno-mir-96	Rattus norvegicus miR-96 stem-loop	CCAGUACCAUCUGCUUGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAAAGCGGGCUGCUGC		8
15893	MI0000882	rno-mir-98	Rattus norvegicus miR-98 stem-loop	CUGCACAUGCUGGGGUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUUUUAGGCCCCAAUAAGAAGAUAACUAUACAACUUACUACUUUCCCUGGUGUGUGGCAU		8
15894	MI0000883	rno-mir-99a	Rattus norvegicus miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGUUUCUAUGGGUCUGUGGCAGUGUG		8
15895	MI0000884	rno-mir-99b	Rattus norvegicus miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC		8
15896	MI0000885	rno-mir-100	Rattus norvegicus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGCUGACCAUGCACACAAGCUUGUGUCUAUAGGUAUGUGUCUGUUAGG		8
15897	MI0000886	rno-mir-101a	Rattus norvegicus miR-101a stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15898	MI0000887	rno-mir-103-2	Rattus norvegicus miR-103-2 stem-loop	GUCUUCGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUUCAGGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACCAAGAA		8
15899	MI0000888	rno-mir-103-1	Rattus norvegicus miR-103-1 stem-loop	UUCUUACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUGAGAC		8
15900	MI0000889	rno-mir-106b	Rattus norvegicus miR-106b stem-loop	CCUGCUGGGACUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCUGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG		8
15901	MI0000890	rno-mir-107	Rattus norvegicus miR-107 stem-loop	UUCUCUCUGCUUUAAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGAGAGC		8
15902	MI0000891	rno-mir-122	Rattus norvegicus miR-122 stem-loop	CCUUAGCAGAGCUCUGGAGUGUGACAAUGGUGUUUGUGUCCAAAACAUCAAACGCCAUCAUCACACUAAACAGCUACUGCUAGGC		8
15903	MI0000892	rno-mir-124-3	Rattus norvegicus miR-124-3 stem-loop	UGAGGGCCCCUCUGCGUGUUCACAGCGGACCUUGAUUUAAUGUCUAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGGCGCCUCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15904	MI0000893	rno-mir-124-1	Rattus norvegicus miR-124-1 stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15905	MI0000894	rno-mir-124-2	Rattus norvegicus miR-124-2 stem-loop	AUCAAGAUCAGAGACUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15906	MI0000895	rno-mir-125a	Rattus norvegicus miR-125a stem-loop	UGCCGGCCUCUGGGUCCCUGAGACCCUUUAACCUGUGAGGACGUCCAGGGUCACAGGUGAGGUUCUUGGGAGCCUGGCGCCUGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15907	MI0000896	rno-mir-125b-1	Rattus norvegicus miR-125b-1 stem-loop	UGCGCUCCCCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGC		8
15908	MI0000897	rno-mir-125b-2	Rattus norvegicus miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGAGG		8
15909	MI0000898	rno-mir-126	Rattus norvegicus miR-126 stem-loop	UGACAGCACAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGUGGUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15910	MI0000899	rno-mir-127	Rattus norvegicus miR-127 stem-loop	UUUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC		8
15911	MI0000900	rno-mir-128-1	Rattus norvegicus miR-128-1 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	8
15912	MI0000901	rno-mir-128-2	Rattus norvegicus miR-128-2 stem-loop	UGUGCAGUGGGAAGGGGGGCCGAUGCACUGUAAGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUCCCUACUGUGUC	The most commonly cloned mature sequences derived from the previously annotated mir-128a and mir-128b were shown by Landgraf et al to be identical [3].  The sequences are therefore renamed mir-128-1 and mir-128-2. 	8
15913	MI0000902	rno-mir-129-1	Rattus norvegicus miR-129-1 stem-loop	UGGGUCUUUUUGCGGUCUGGGCUUGCUGUUCUCUCCACAGUAGUCAGGAAGCCCUUACCCCAAAAAGUAUCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15914	MI0000903	rno-mir-130a	Rattus norvegicus miR-130a stem-loop	UGCUGCUGGCCGGAGCUCUUUUCACAUUGUGCUACUGUCUACACGUGUACCGAGCAGUGCAAUGUUAAAAGGGCAUCGGCCUUGUAGU		8
15915	MI0000904	rno-mir-130b	Rattus norvegicus miR-130b stem-loop	GGCUUGCUGGACACUCUUUCCCUGUUGCACUACUGUGGGCCUCUGGGAAGCAGUGCAAUGAUGAAAGGGCAUCCGUCAGGCC		8
15916	MI0000905	rno-mir-132	Rattus norvegicus miR-132 stem-loop	CCGCCCCCGCGUCUCCAGGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACCGGAGGUAACAGUCUACAGCCAUGGUCGCCCCGCAGCACGCCCACGCUC		8
15917	MI0000906	rno-mir-133a	Rattus norvegicus miR-133a stem-loop	CAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA		8
15918	MI0000907	rno-mir-134	Rattus norvegicus miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCGUGCACUUUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC		8
15919	MI0000908	rno-mir-135a	Rattus norvegicus miR-135a stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUCGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAUUCA		8
15920	MI0000909	rno-mir-136	Rattus norvegicus miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAAGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU		8
15921	MI0000910	rno-mir-137	Rattus norvegicus miR-137 stem-loop	GGCCCUCUGACUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGGAGAGUACCAGCGGCA		8
15922	MI0000911	rno-mir-138-2	Rattus norvegicus miR-138-2 stem-loop	GUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACGAGCAACGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUUGCACC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15923	MI0000912	rno-mir-138-1	Rattus norvegicus miR-138-1 stem-loop	CUCUGGCAUGGUGUUGUGGGACAGCUGGUGUUGUGAAUCAGGCCGUUGCCAAUCAGAGAACGGCUACUUCACAACACCAGGGUCUCACUGCACUGCAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15924	MI0000913	rno-mir-139	Rattus norvegicus miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15925	MI0000914	rno-mir-141	Rattus norvegicus miR-141 stem-loop	GGCUGACUCUGAGUCCAUCUUCCAGUGCAGUGUUGGAUGGUUGAAGUACGAAGCUCCUAACACUGUCUGGUAAAGAUGGCCCCCGGGUCAGUUC		8
15926	MI0000915	rno-mir-142	Rattus norvegicus miR-142 stem-loop	GACAGUGCAGUCACCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15927	MI0000916	rno-mir-143	Rattus norvegicus miR-143 stem-loop	GCGGAGCGCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGGGAGAAGAUGUUCUGCAGC		8
15928	MI0000917	rno-mir-144	Rattus norvegicus miR-144 stem-loop	GGGCCUUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGUGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCUGGGUACCCC		8
15929	MI0000918	rno-mir-145	Rattus norvegicus miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUGGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15930	MI0000919	rno-mir-146a	Rattus norvegicus miR-146a stem-loop	UGUGUAUCCUCAGCUCUGAGAACUGAAUUCCAUGGGUUAUAGCAAUGUCAGACCUGUGAAGUUCAGUUCUUUAGCUGGGAUAGCUCUAUCGUCAU		8
15931	MI0000920	rno-mir-150	Rattus norvegicus miR-150 stem-loop	CUUCUCAAGGCCCUGUCUCCCAACCCUUGUACCAGUGCUGUGCCUCAGACCCUGGUACAGGCCUGGGGGACAGGGACUUGGGGAC		8
15932	MI0000921	rno-mir-152	Rattus norvegicus miR-152 stem-loop	UGUUCCCCGGGCCCAGGUUCUGUGAUACACUCCGACUCGGGCUCUGGAGCAGUCAGUGCAUGACAGAACUUGGGCCCGGUAGGAC		8
15933	MI0000922	rno-mir-153	Rattus norvegicus miR-153 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG		8
15934	MI0000923	rno-mir-154	Rattus norvegicus miR-154 stem-loop	GCGGUGCUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUCGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA		8
15935	MI0000924	rno-mir-181c	Rattus norvegicus miR-181c stem-loop	AGAACUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGACAAACCAUCGACCGUUGAGUGGACCCCGAGGCCUGGAACUGCCACCC		8
15936	MI0000925	rno-mir-181a-2	Rattus norvegicus mir-181a-2 stem-loop	AGAUGGGCAACCAAGGCAGCCUUAAGAGGACUCCAUGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUCAAAAACAAAAAAAACCACCAACCGUUGACUGUACCUUGGGAUUCUUA		8
15937	MI0000926	rno-mir-181b-1	Rattus norvegicus miR-181b-1 stem-loop	CCUGUGCAGAGAUGAUGUUUACAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUAGAAAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU		8
15938	MI0000927	rno-mir-181b-2	Rattus norvegicus miR-181b-2 stem-loop	UGAUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGAAUGUCAACCAACUCACUGGUCAAUGAAUGCAAACUGCGGGCCAAAAA		8
15939	MI0000928	rno-mir-183	Rattus norvegicus miR-183 stem-loop	CCAGAGAGUGUGACUCCUGUCCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCGCGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15940	MI0000929	rno-mir-184	Rattus norvegicus miR-184 stem-loop	CACUUUCCCUUAUCAGUUUUCCAGCCAGCUUUGUGACUGUAAAUGUUGGACGGAGAACUGAUAAGGGUAAGUGACUG		8
15941	MI0000930	rno-mir-185	Rattus norvegicus miR-185 stem-loop	GGGGGUGAGGGAUUGGAGAGAAAGGCAGUUCCUGAUGGUCCCCUCCCAGGGGCUGGCUUUCCUCUGGUCCUUCUCUCCCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15942	MI0000931	rno-mir-186	Rattus norvegicus miR-186 stem-loop	UGCUUACAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUCAUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15943	MI0000932	rno-mir-187	Rattus norvegicus miR-187 stem-loop	GGGCUCACAGGACACAAUGCGGAUCCUCAGGCUACAACACAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCUGCA		8
15944	MI0000933	rno-mir-190	Rattus norvegicus miR-190 stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAGCAUAUUCCUACAGUGUCUUGCC	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15945	MI0000934	rno-mir-191	Rattus norvegicus miR-191 stem-loop	GGCUGGACAGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCACUUGGAUUUCGUUCCCUGCUCUCCUGCCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15946	MI0000935	rno-mir-192	Rattus norvegicus miR-192 stem-loop	GUCAAGAUGGAGUGCACAGGGCUCUGACCUAUGAAUUGACAGCCAGUACUCUGAUCUCGCCUCUGGCUGCCAGUUCCAUAGGUCACAGGUAUGUUCGCCUCAAUGCCAGC		8
15947	MI0000936	rno-mir-193	Rattus norvegicus miR-193 stem-loop	GCGGACGGGAGCUGAGAGCUGGGUCUUUGCGGGCAAGAUGAGGGUGUCAGUUCAACUGGCCUACAAAGUCCCAGUCCUCGGCUCCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15948	MI0000937	rno-mir-194-1	Rattus norvegicus miR-194-1 stem-loop	AUGGAGUCAUCACGUGUAACAGCAACUCCAUGUGGACUGUGCACAGAUCCCAGUGGAGCUGCUGUUACUUUUGAUGGCCUCCA		8
15949	MI0000938	rno-mir-194-2	Rattus norvegicus miR-194-2 stem-loop	UGGCUCCCACCCCCUGUAACAGCAACUCCAUGUGGAAGUGCCCACUGAUUCCAGUGGGGCUGCUGUUAUCUGGGGUGGAGGCUGG		8
15950	MI0000939	rno-mir-195	Rattus norvegicus miR-195 stem-loop	AACUCUCCUGGCUCUAGCAGCACAGAAAUAUUGGCACGGGUAAGUGAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG		8
15951	MI0000940	rno-mir-196a	Rattus norvegicus miR-196a stem-loop	UGUUUGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196.  Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	8
15952	MI0000941	rno-mir-199a	Rattus norvegicus miR-199a stem-loop	UGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGCCAGCA		8
15953	MI0000942	rno-mir-200c	Rattus norvegicus miR-200c stem-loop	CCCUCGUCUUACCCAGCAGUGUUUGGGUGCUGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	This sequence is the predicted rat homologue of a confirmed miRNA from human [1].  Its expression has not been experimentally verified in rat. 	8
15954	MI0000943	rno-mir-200a	Rattus norvegicus miR-200a stem-loop	CUGGGCCUCUGUGGGCAUCUUACCGGACAGUGCUGGAUUUCUUGGCUUGACUCUAACACUGUCUGGUAACGAUGUUCAAAGGUGACCCA		8
15955	MI0000944	rno-mir-200b	Rattus norvegicus miR-200b stem-loop	CCAACUUGGGCAGCCGUGGCCAUCUUACUGGGCAGCAUUGGAUAGUGUCUGAUCUCUAAUACUGCCUGGUAAUGAUGACGGCGGAGCCCUGCACG		8
15956	MI0000945	rno-mir-203	Rattus norvegicus miR-203 stem-loop	GCGCGCCUGGUCCAGUGGUUCUUAACAGUUCAACAGUUCUGUAGCGCAAUUGUGAAAUGUUUAGGACCACUAGACCCGGCGCGCACGGCAGCGGCGA		8
15957	MI0000946	rno-mir-204	Rattus norvegicus miR-204 stem-loop	GGCUACAGCCCUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC		8
15958	MI0000947	rno-mir-205	Rattus norvegicus miR-205 stem-loop	AAACAGCCCCAGACAAUCCAUGGGUCCUCCUGUCCUUCAUUCCACCGGAGUCUGUCUUAUGCCAACCAGAUUUCAGUGGAGUGAAGCUCAGGAGGCAUGGAGCUGCCA	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15959	MI0000948	rno-mir-206	Rattus norvegicus miR-206 stem-loop	CUUCCCCAGGCCACAUGCUUCUUUAUAUCCUCAUAGAUAUCACUGCGCUAUGGAAUGUAAGGAAGUGUGUGGUUUUGGCAAGUG		8
15960	MI0000949	rno-mir-208	Rattus norvegicus miR-208 stem-loop	UUCCUUUGACGGGUGAGCUUUUGGCCCGGGUUAUACCUGACUCUCACGUAUAAGACGAGCAAAAAGCUUGUUGGUCAGAGGAG	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15961	MI0000950	rno-mir-210	Rattus norvegicus miR-210 stem-loop	CCGGGGCAGUCCCUCCAGGCUCAGGACAGCCACUGCCCACAGCACACUGCGUUGCUCCGGACCCACUGUGCGUGUGACAGCGGCUGAUCUGUCCCUGGGCAGCGCGAACC		8
15962	MI0000951	rno-mir-211	Rattus norvegicus miR-211 stem-loop	CAGCUUGGACCUGUGACCUCUGGGCUUCCCUUUGUCAUCCUUUGCCUAGGCCUCUGAGUGGGGCAAGGACAGCAAAGGGGGGCUCAGUGGUCACCUCUACUGCAGA	This sequence is the predicted rat homologue of a miRNA from human [1]. Its expression has not been experimentally verified in rat. 	8
15963	MI0000952	rno-mir-212	Rattus norvegicus miR-212 stem-loop	CGGGAUAUCCCCGCCCGGGCAGCGCGCCGGCACCUUGGCUCUAGACUGCUUACUGCCCGGGCCGCCCUCAGUAACAGUCUCCAGUCACGGCCACCGACGCCUGGCCCCGCC		8
15964	MI0000953	rno-mir-181a-1	Rattus norvegicus miR-181a-1 stem-loop	AGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUCAAAUAAAAACCAUCGACCGUUGAUUGUACCCUAUAGCUAACCAUUAUCUACUCC		8
15965	MI0000954	rno-mir-214	Rattus norvegicus miR-214 stem-loop	GUCCUGGAUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU		8
15966	MI0000955	rno-mir-216a	Rattus norvegicus miR-216a stem-loop	GUUAGCUAUGAGUUAGUUUAAUCUCAGCUGGCAACUGUGAGAUGUCCCUAUCAUUCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUUGACCUC		8
15967	MI0000956	rno-mir-217	Rattus norvegicus miR-217 stem-loop	ACCACAGUCAUUGUAGUUUUGAUGUCGCAGAUACUGCAUCAGGAACUGACUGGAUAAGACUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACA	This sequence is the predicted rat homologue of a miRNA from human [1]. Its expression has not been experimentally verified in rat. 	8
15968	MI0000957	rno-mir-218-2	Rattus norvegicus miR-218-2 stem-loop	GACCAGUUGCCGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCAUCGCUCUCUCCUGCA		8
15969	MI0000958	rno-mir-218-1	Rattus norvegicus miR-218-1 stem-loop	GUGAUAACGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGCUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		8
15970	MI0000959	rno-mir-219-1	Rattus norvegicus miR-219-1 stem-loop	CUGUCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUCUGGCUCCGGCCGAGAGUUGCGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGGGGG		8
15971	MI0000960	rno-mir-219-2	Rattus norvegicus miR-219-2 stem-loop	ACUCAGGGGCUUCACCACUGAUUGUCCAAACGCAAUUCUUGUACGAGUCUGCGGCCAACCGAGAAUUGUGGCUGGACAUCUGUGGUUGAGCUCCGG		8
15972	MI0000961	rno-mir-221	Rattus norvegicus miR-221 stem-loop	UGAAUAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUUGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAGCAUUUCUC		8
15973	MI0000962	rno-mir-222	Rattus norvegicus miR-222 stem-loop	AAGGAUUAGGGUGCCCUCAGUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUGGUAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCAUCUAGCU		8
15974	MI0000963	rno-mir-223	Rattus norvegicus miR-223 stem-loop	UCUGGCCUUCUGCAGUGUUACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCUGUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGUGGCUCAUGCUUAUCAG		8
15975	MI0000964	rno-mir-290	Rattus norvegicus miR-290 stem-loop	UCAUCUUGCGGUUCUCAAACUAUGGGGGCACUUUUUUUUUCUUUAAAAAGUGCCGCCAGGUUUUAGGGCCUGCCGGUUGAG	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15976	MI0000965	rno-mir-291a	Rattus norvegicus miR-291a stem-loop	CCGGUGUAGUAGCCAUCAAAGUGGAGGCCCUCUCUUGGGCCCGAGCUAGAAAGUGCUUCCACUUUGUGUGCCACUGCAUGGG	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15977	MI0000966	rno-mir-292	Rattus norvegicus miR-292 stem-loop	CAACCUGUGAUACUCAAACUGGGGGCUCUUUUGGGUUUUCUUUGGAAGAAAAGUGCCGCCAGGUUUUGAGUGUUACCGAUUG	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15978	MI0000967	rno-mir-296	Rattus norvegicus miR-296 stem-loop	GGACCUUUCUGGAGGGCCCCCCCUCAAUCCUGUUGUGCUCGCUUCAGAGGGUUGGGUGGAGGCUCUCCUGAAGGUGUC		8
15979	MI0000968	rno-mir-297	Rattus norvegicus miR-297 stem-loop	AUGCAUGUAUGUGUGCAUGUAUGCAUGCAUGCAUGUAUGUAUGUAUGGUGCACUUGUGUGUGUGUG	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15980	MI0000969	rno-mir-298	Rattus norvegicus miR-298 stem-loop	CCAGGCCUUCGGCAGAGGAGGGCUGUUCUUCCCUUGGGUUUUAUGACUGGGAGGAACUAGCCUUCUCUCUGCUUAGGAGUGG		8
15981	MI0000970	rno-mir-299	Rattus norvegicus miR-299 stem-loop	AAGAAAUGGUUUACCGUCCCACAUACAUUUUGAGUAUGUAUGUGGGACGGUAAACCGCUUCUU	This sequence is the predicted rat homologue of a confirmed miRNA from mouse [1].  Its expression has not been experimentally verified in rat. 	8
15982	MI0000971	rno-mir-300	Rattus norvegicus miR-300 stem-loop	GCUACUUGAAGAGAGGUUAUCCUUUGUGUGUUUGCUUUACGCGAAAUGAAUAUGCAAGGGCAAGCUCUCUUCGAGGAGC		8
15983	MI0000972	rno-mir-320	Rattus norvegicus miR-320 stem-loop	GCCUCGCUGUCCUCCGCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGAAAAAGGAUAUGGG		8
15984	MI0000974	mmu-mir-215	Mus musculus miR-215 stem-loop	AGCUCUCAGCAUCAACGGUGUACAGGAGAAUGACCUAUGAUUUGACAGACCGUGCAGCUGUGUAUGUCUGUCAUUCUGUAGGCCAAUAUUCUGUAUGUCACUGCUACUUAAA	This mouse miRNA was predicted by computational methods using conservation with human and Fugu rubripes sequences [1].  Expression of the excised miR has been validated in zebrafish, and the 5' end mapped by PCR.  The 3' end was not experimentally determined.  The mature sequence differs from the human miR-215 at A12->U, and its expression has not been verified in mouse. 	6
15985	MI0000975	ath-MIR167d	Arabidopsis thaliana miR167d stem-loop	UGUUGGUUUUUAGAAGCUGAAGCUGCCAGCAUGAUCUGGUAAUCGCUACAUACGACAUACACACAUCACUAAACUUCUUUAUAAUUUAUGCACACACAUACAGCUCUUAAUGGCCACAACUCAAAGUUAUAAUUAGUGCAUGAUCUCUAGUUAUUUGACUGCUUUUAAUAUAUGUUUAUGGAUUCACGCAUGUGUGUGUAUGUACAUAAUUUACAUGCAUGCACUUUGUGUAUGGUACACAUCAAUUUGAACCCGUUCAAAAUUCUGUUUUUAUUAGUAUAUAUAUAGAUGUAUGUGGUGUGUGUGUCAGUGUGUGUGUGUGUUUAUAGAUAGUAGUACUAGGUCAUCCUGCAGCUUCAGUCACUAAAUCACCAACA	This sequence is a predicted paralogue of the previously identified miR167 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	1
15986	MI0000976	ath-MIR169b	Arabidopsis thaliana miR169b stem-loop	CCCAACGGAGUAGAAUUGCAUGAAGUGGAGUAGAGUAUAAUGCAGCCAAGGAUGACUUGCCGGAACGUUGUUAACCAUGCAUAUGAAUAAUGUGAUGAUUAAUUAUGUGAUGAACAUAUUUCUGGCAAGUUGUCCUUCGGCUACAUUUUGCUCUCUUCUUCUCAUGCAAACUUUCCUUGGG	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15987	MI0000977	ath-MIR169c	Arabidopsis thaliana miR169c stem-loop	UCGUCCAUUAUGAGUAUUAAUUAUGGUUAGGGAAUCUUACAGAAUGAAAAUGAAGGUGUGAAUGGAUUGUCUCAUCUAAAGCCUUGAAUGUGGGAAAAAGGCCAUUGUUGUUCAGCCAAGGAUGACUUGCCGGUAGCUUGUAUUAUGAUUACUCUAUAUUCGAUUUAUAUUAUGGAGAUGAUGGUUUAUAUAUAUUUACUUAUCUACAUAGUUUUAGUUGAUUUUUUUUCGUACGUAAUAUAAUACGAAAAAGUAUUUACUUAUUUAUAUAUGUGUGUUGGGGCAAGAAGUGUAACCAAGCUAGCCCGGCAAGUCAUCUAUGGCUAUGCAACUGUCUCUUCCUCUCAUUCUAGGCUUACGAUGACACGUAAAAAAUCCCAAAUAUCACUAAUAUGAUAUGAAUAUGGAUGA	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15988	MI0000978	ath-MIR169d	Arabidopsis thaliana miR169d stem-loop	GUAUCAUAGAGUCUUGCAUGGAAAAAUUAAAGAAUGAGAUUGAGCCAAGGAUGACUUGCCGAUGUUAUCAACAAAUCUUAACUGAUUUUGGUGUCCGGCAAGUUGACCUUGGCUCUGUUUCCUUCUUUUCUUUUCAAUGUCAAACUCUAGAUAU	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15989	MI0000979	ath-MIR169e	Arabidopsis thaliana miR169e stem-loop	UGAUGAUGAUGAUGAGUCACUAAUUAAUUGUAUCAUAGAGUCUUGCAUGGAAAAAUAGAAAAUGAGAUUGAGCCAAGGAUGACUUGCCGAUUUUCUCAACGAAUCUUACUGAUUAUGGUAUCCGGCAAGUUGACUUUGGCUCUGUUUCCUUCCCUUCUUUUCGAUGUCAAACUCUAGAUACCUAACCACAUAUCAUAUAUAUCAUCAUCAUUCAUCA	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15990	MI0000980	ath-MIR169f	Arabidopsis thaliana miR169f stem-loop	GGGUCUUGCAUGAAGGAAUAACGAAUGGAAUUGAGCCAAGGAUGACUUGCCGGUUUAAACCCAACCGGUUUAUGACCAUUGAUUUGGUCUCAUUCACAAUCUGUUGAUUCGUGUCUGGCAAGUUGACCUUGGCUCUGCUUCGUUCUCUAUUCUUCCAUGUUAGAUUC	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15991	MI0000981	ath-MIR169g	Arabidopsis thaliana miR169g stem-loop	UGCCUAUAAAUACCUUCAUCACGAGUAUGACAAGAUCACAAGACAAGAAAAGAAAGGUAGAGAAAACAUGAUAAUGAUGAUUACGAUGAUGAGAGUCUCUAGUUGUAUCAGAGGGUCUUGCAUGGAAGAAUAGAGAAUGAGGUUGAGCCAAGGAUGACUUGCCGGGUUUUUUUACCAAUGAAUCUAAUUAACUGAUUCUGGUGUCCGGCAAGUUGACCUUGGCUCUGUUUCCUUCUCUUCUUUUGGAUGUCAGACUCCAAGAUAUCUAUCAUCAUGAAUCGUGAUCAAACUUUGUAAUUUCAUUGAAAUGUGUUUUUCUUGAUGCGAAUUUUUUGGCUUACGGUUUUUCGAUUUGAAUGAUCAGAUUUUUGUUUUUGCA	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [3,4].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors.  Wang et al. report Northern blot evidence for the miR169* sequence from the opposite arm of the precursor [2]. 	1
15992	MI0000982	ath-MIR169h	Arabidopsis thaliana miR169h stem-loop	UCAUAUAAGAGAAAAUGGUGACAUGAAGAAUGAGAACUUGUGUGGUAGCCAAGGAUGACUUGCCUGCGUUUUAGACCAUAUAUAUCAAAGACUCACUCGAUCGAUAGUCUUAGAGUUGGUUGGUCGUCAGGCAGUCUCCUUGGCUAUUCAAACAAUUCUCAUUCUCUUCAUUCACAUUUCUCUUUUUUGG	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2,3].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15993	MI0000983	ath-MIR169i	Arabidopsis thaliana miR169i stem-loop	GAAGGAGAUGUCAAAGAUGAAUAGAAGAAUCAUAUUUGGUAGCCAAGGAUGACUUGCCUGACUCUUUGUGUAAAAUGUUUAGUGUCUUGUUUGAAGUCACUAUAAGUUGUAUCAAGCAAUGACCAUUUUGCUUAUAAAAAAGAUAUCAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUCUUUCAUCUCAGACAUUCACCUUC	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15994	MI0000984	ath-MIR169j	Arabidopsis thaliana miR169j stem-loop	GAGUAUAAUGAGGAAGAGAGGUCUAACAUGGCGAAAAGAGUCAUGUUUAGUAGCCAAGGAUGACUUGCCUGAUCUUUUUCACCUCCAUGAUUCAAUUUGUAAUUCAUGGGUUUUGGAUUAUUAUACAUUCAAAAGUAUAAUAAUUUGAAAUCAUGUUGAAUCUUGCGGGUUAGGUUUCAGGCAGUCUCCUUGGCUAUCUUGACAUGCUUUUUUCAUUCACG	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15995	MI0000985	ath-MIR169k	Arabidopsis thaliana miR169k stem-loop	UUAGAAGGAGAUGUCAAAGAUGAAUAGGAGAACAAUAUUUGGUAGCCAAGGAUGACUUGCCUGCUUCUCUGAACAAAAUGGUCGAUGUCAUGUUUUGAAGUGACUAUAAGUUAUACCAAGAAAUGACCAUUUUGUUUAUAAAUAGACAUCAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUUUCUCAACUCAGAUAUUUACCUUCAUCC	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15996	MI0000986	ath-MIR169l	Arabidopsis thaliana miR169l stem-loop	AUGAAGAAGAGAGGUCUAAUAUGGCGAAAAGAGUCAUGUUUAAUAGCCAAGGAUGACUUGCCUGAUCUUUUUCACCUCCAUGAUUCAAUUUUAAGUUCGUGGAUUUUGGAUUAUUAUGCGUUUAAAAGGUAUAAUAAUUUGAGAUCAUGUUGAAUCUUGCGGGUUAGGUUUCAGGCAGUCUCUUUGGCUAUCUUGACAUGCUUUCUUCAUC	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15997	MI0000987	ath-MIR169m	Arabidopsis thaliana miR169m stem-loop	UAGAAGGAGAAGUCAAAGAUGAAUAGAAGAAUCAUAUUUGGUAGCCAAGGAUGACUUGCCUGUUUCUUUGAGUAAAAUGGGUUAGUGUCAUGUUUGACAAGUGACUAUAAGUUAUAUCAAGCAAUGACCAUUUUACUCAUCAAAAGACAUCAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUCUCUCAUCUCAGACGUUUACCUUCAU	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15998	MI0000988	ath-MIR169n	Arabidopsis thaliana miR169n stem-loop	GAUGAAGAAGAGAGGUCUAACAUGGCGGAAAGCGUCAUGUUUAGUAGCCAAGGAUGACUUGCCUGAUCUUUUUCGCCUCCACGAUUCAAUUUCAAAUUCAUGCAUUUUGGAUUAUUAUACCUUUUAAAGUAUAAUAGGUCAAAUAUCAUGUUGAAUCUUGCGGGUUAGGUUUCAGGCAGUCUCUUUGGCUAUCUUGACAUGCUUUUUCCAUCCAU	This sequence is a predicted paralogue of the previously identified miR169 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	1
15999	MI0000989	ath-MIR171b	Arabidopsis thaliana miR171b stem-loop	UGCAAGGUAACGCGAGAUAUUAGUGCGGUUCAAUCAAAUAGUCGUCCUCUUAACUCAUGGAGAACGGUGUUGUUCGAUUGAGCCGUGCCAAUAUCACGCGGUAAACCAAAAAUGGCA	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors.  Its expression in Arabidopsis was confirmed by cloning and Northern blot [2,3].  The mature sequence reported in [3] is offset by 4 nts with respect to the sequence shown here. 	1
16000	MI0000990	ath-MIR171c	Arabidopsis thaliana miR171c stem-loop	UGAGCGCACUAUCGGACAUCAAAUACGAGAUAUUGGUGCGGUUCAAUCAGAAAACCGUACUCUUUUGUUUUAAAGAUCGGUUUAUUUGAUUGAGCCGUGCCAAUAUCACGCGUUUA	This sequence is a predicted paralogue of the previously identified miR171 family [1], later experimentally verified [2,3].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	1
16001	MI0000991	ath-MIR172c	Arabidopsis thaliana miR172c stem-loop	AGCUACUGUUCGCUGUUGGAGCAUCAUCAAGAUUCACAAAUCAUCAAGUAUUCGUGUAAAUAAACCCAUUUAUGAUUAGAUUUUUGAUGUAUGUAUGAGAAUCUUGAUGAUGCUGCAGCUGCAAUCAGUGGCU	This sequence is a predicted paralogue of the previously identified miR172 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	1
16002	MI0000992	ath-MIR172d	Arabidopsis thaliana miR172d stem-loop	AGUCAUUGUUUGCUAUUGCAACAUCUUCAAGAUUCAGAAAUCAGAUUCUCUUAUGGGUUUUCUUUUGAGCCUUUAUUUUUUGGUUUGAGAAUCUUGAUGAUGCUGCAGCGGCAAUUAAAUGGCU	This sequence is a predicted paralogue of the previously identified miR172 family [1], later experimentally verified [2].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	1
16003	MI0001000	ath-MIR390a	Arabidopsis thaliana miR390a stem-loop	GUAGAGAAGAAUCUGUAAAGCUCAGGAGGGAUAGCGCCAUGAUGAUCACAUUCGUUAUCUAUUUUUUGGCGCUAUCCAUCCUGAGUUUCAUUGGCUCUUCUUACUAC	miR390 was independently cloned by the ASRP project [1], and predicted by computational methods [2]. 	1
16004	MI0001001	ath-MIR390b	Arabidopsis thaliana miR390b stem-loop	GAGAAAUAGCUAUAAAGCUCAGGAGGGAUAGCGCCAUGGCUCACCAGUGCUGUAUGUUUUGUAUAUGCGUACAUGUAUAUCUGUUGGCGCUAUCCAUCCUGAGUUCCAUAGCUUCUUCUU	miR390 was independently cloned by the ASRP project [1], and predicted by computational methods [2]. 	1
16005	MI0001002	ath-MIR391	Arabidopsis thaliana miR391 stem-loop	UAGAGUGAUUACACAUACAAGUGGUCUUGCUUCUUCUAUGGUUUUAAAACUGCAAAUAAAGAUUUGCUUCGCAGGAGAGAUAGCGCCAUCACCUCUUCUAAGAAGUUAACUAGUGGUGACGGUAUCUCUCCUACGUAGCAAUCCUUAUAUAUGCAUCUUAAUACGGAGAGAUCAAGGUAUUUCAGUUGUUCAAUAAUCACCCUCUA		1
16006	MI0001003	ath-MIR393a	Arabidopsis thaliana miR393a stem-loop	AGAGGAAGGAUCCAAAGGGAUCGCAUUGAUCCUAAUUAAGGUGAAUUCUCCCCAUAUUUUCUUUAUAAUUGGCAAAUAAAUCACAAAAAUUUGCUUGGUUUUGGAUCAUGCUAUCUCUUUGGAUUCAUCCUUC	This sequence belongs to the miR393 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins and bHLH transcription factors [1]. 	1
16007	MI0001004	ath-MIR393b	Arabidopsis thaliana miR393b stem-loop	AGAGAAAGGAUCCAAAGGGAUCGCAUUGAUCCUAAUUAAGCUGAUUUAUUCCCCAAUAAUUGUUUUUUUUUUCCUUCUCAAUCGAAAGAUGGAAGAAAAACAAAUUCCAAACAUUUUGCUUACUUUUCCGGAUCAUGCGAUCUCUUUGGAUUCAUUCUUU	This sequence belongs to the miR393 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins and bHLH transcription factors [1]. 	1
16008	MI0001005	ath-MIR394a	Arabidopsis thaliana miR394a stem-loop	CUUACAGUCAUCUUUGGCAUUCUGUCCACCUCCUUCUAUACAUAUAUGCAUGUGUAUAUAUAUAUGCGUUUCGUGUGAAAGAAGGAGGUGGGUAUACUGCCAAUAGAGAUCUGUUAG	This sequence belongs to the miR394 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins [1]. 	1
16009	MI0001006	ath-MIR394b	Arabidopsis thaliana miR394b stem-loop	CUUACAGAGAUCUUUGGCAUUCUGUCCACCUCCUCUCUCUAUAUUUAUGUGUAAUAAGUGUACGUAUCUACGGUGUGUUUCGUAAGAGGAGGUGGGCAUACUGCCAAUAGAGAUCUGUUAG	This sequence belongs to the miR394 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins [1]. 	1
16010	MI0001007	ath-MIR395a	Arabidopsis thaliana miR395a stem-loop	AUGUCUCCUAGAGUUCCUCUGAGCACUUCAUUGGGGAUACAAUUUUUCUAAAUGAUUAUCCACUGAAGUGUUUGGGGGAACUCCCGGACCCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16011	MI0001008	ath-MIR395b	Arabidopsis thaliana miR395b stem-loop	AUGUCCCCAUGAGUUCCCUUUAACGCUUCAUUGUUAAAUACUCAAAGCCACAUUGGUUUGUAUACAACACUGAAGUGUUUGGGGGGACUCUUGGUGUCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16012	MI0001009	ath-MIR395c	Arabidopsis thaliana miR395c stem-loop	AUGUCCACAUGAGUUCCCUUUAACGCUUCAUUGUUGAAUACUCAAAGCCACAUUGGUUUGUAUAUAACACUGAAGUGUUUGGGGGGACUCUUGGUGUCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16013	MI0001010	ath-MIR395d	Arabidopsis thaliana miR395d stem-loop	AUGUCCUCUAGAGUUCUCCUGAACACUUCAUUGGAAAUUUGUUAUUCAGUAAGCUAACAGUUAAUUCCACUGAAGUGUUUGGGGGAACUCCCGAUGUCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16014	MI0001011	ath-MIR395e	Arabidopsis thaliana miR395e stem-loop	AUGUUUUCUAGAGUUCCUCUGAGCACUUCAUUGGAGAUACAAUUUUUUAUAAAAUAGUUUUCUACUGAAGUGUUUGGGGGAACUCCCGGGCUGAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16015	MI0001012	ath-MIR395f	Arabidopsis thaliana miR395f stem-loop	AUGUCCCCUUGAGUUCCCUUAAACGCUUCAUUGUUCAUACUUUGUUAUCAUCUAUCGAUCGAUCAAUCAAUCUGAUGAACACUGAAGUGUUUGGGGGGACUCUAGGUGACAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1]. 	1
16016	MI0001013	ath-MIR396a	Arabidopsis thaliana miR396a stem-loop	CUCUGUAUUCUUCCACAGCUUUCUUGAACUGCAAAACUUCUUCAGAUUUUUUUUUUUUUCUUUUGAUAUCUCUUACGCAUAAAAUAGUGAUUUUCUUCAUAUCUCUGCUCGAUUGAUUUGCGGUUCAAUAAAGCUGUGGGAAGAUACAGAC	This sequence belongs to the miR396 family of miRNAs, which are predicted to target mRNAs coding for Growth Regulating Factor (GRF) transcription factors, rhodenase-like proteins, and kinesin-like protein B [1]. 	1
16017	MI0001014	ath-MIR396b	Arabidopsis thaliana miR396b stem-loop	GGUCAUACUUUUCCACAGCUUUCUUGAACUUUCUUUUUCAUUUCCAUUGUUUUUUUCUUAAACAAAAGUAAGAAGAAAAAAAACUUUAAGAUUAAGCAUUUUGGAAGCUCAAGAAAGCUGUGGGAAAACAUGACA	This sequence belongs to the miR396 family of miRNAs, which are predicted to target mRNAs coding for Growth Regulating Factor (GRF) transcription factors, rhodenase-like proteins, and kinesin-like protein B [1].  The mature sequence reported in [2] is offset by 1 nt with respect to the sequence shown here. 	1
16018	MI0001015	ath-MIR397a	Arabidopsis thaliana miR397a stem-loop	UGAAUGAACAUCAUUGAGUGCAGCGUUGAUGUAAUUUCGUUUUGUUUUUCAUUGUUGAAUGGAUUAAAAGAAUUUAUACCAGCGUUGCGCUCAAUUAUGUUUUUCUA	This sequence belongs to the miR397 family of miRNAs, which are predicted to target mRNAs coding for laccases and beta-6 tubulin [1]. 	1
16019	MI0001016	ath-MIR397b	Arabidopsis thaliana miR397b stem-loop	UGAAUGAACAUCAUUGAGUGCAUCGUUGAUGUAAUUUUACUUAUUUUAUUCCAUUGUUGAAUUAAUUAAAGAAGUAUAUAUCAGCGUUGCAUUCAAUUAUGUUUUUCUA	This sequence belongs to the miR397 family of miRNAs, which are predicted to target mRNAs coding for laccases and beta-6 tubulin [1]. 	1
16020	MI0001017	ath-MIR398a	Arabidopsis thaliana miR398a stem-loop	UGAAAUUUCAAAGGAGUGGCAUGUGAACACAUAUCCUAUGGUUUCUUCAAAUUUCCAUUGAAACCAUUGAGUUUUGUGUUCUCAGGUCACCCCUUUGAAUCUCCC	This sequence belongs to the miR398 family of miRNAs, which are predicted to target mRNAs coding for copper superoxide dismutases and cytochrome C oxidase subunit V [1]. 	1
16021	MI0001018	ath-MIR398b	Arabidopsis thaliana miR398b stem-loop	UGGAUCUCGACAGGGUUGAUAUGAGAACACACGAGUAAUCAACGGCUGUAAUGACGCUACGUCAUUGUUACAGCUCUCGUUUUCAUGUGUUCUCAGGUCACCCCUGCUGAGCUCUU	This sequence belongs to the miR398 family of miRNAs, which are predicted to target mRNAs coding for copper superoxide dismutases and cytochrome C oxidase subunit V [1]. 	1
16022	MI0001019	ath-MIR398c	Arabidopsis thaliana miR398c stem-loop	UGGAUCUCGACAGGGUUGAUAUGAGAACACACGAGCAAUCAACGGCUAUAACGACGCUACGUCAUUGUUACAGCUCUCGUUUCAUGUGUUCUCAGGUCACCCCUGCUGAGCUCUU	This sequence belongs to the miR398 family of miRNAs, which are predicted to target mRNAs coding for copper superoxide dismutases and cytochrome C oxidase subunit V [1]. 	1
16023	MI0001020	ath-MIR399a	Arabidopsis thaliana miR399a stem-loop	AAAUGCAUUACAGGGUAAGAUCUCUAUUGGCAGGAAACCAUUACUUAGAUCUUUGCAUCUCUUUAUGCAUUGCUUUUAAUUAGUGAGUUAUCUGCCAAAGGAGAUUUGCCCUGUAAUUCUUCU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16024	MI0001021	ath-MIR399b	Arabidopsis thaliana miR399b stem-loop	UCACUAGUUUUAGGGCGCCUCUCCAUUGGCAGGUCCUUUACUUCCAAAUAUACACAUACAUAUAUGAAUAUCGAAAAUUUCCGAUGAUCGAUUUAUAAAUGACCUGCCAAAGGAGAGUUGCCCUGAAACUGGUUC	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16025	MI0001022	ath-MIR399c	Arabidopsis thaliana miR399c stem-loop	GGAGCAGUAAUAGGGCAUCUUUCUAUUGGCAGGCGACUUGGCUAUUUGUAUCUUUUGUGUUCUUGACUAUUGGCUAUGUCACUUGCCAAAGGAGAGUUGCCCUGUCACUGCUUC	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16026	MI0001023	ath-MIR399d	Arabidopsis thaliana miR399d stem-loop	GGUUGGAUUACUGGGCGAAUACUCCUAUGGCAGAUCGCAUUGGCUAGAUAUGCAAGUAAAAUGCUUCUCUGCCAAAGGAGAUUUGCCCCGCAAUUCAUCC	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16027	MI0001024	ath-MIR399e	Arabidopsis thaliana miR399e stem-loop	GAAAGCAUUACAGGGCGAAUCCUCUAUUGGCAGUGGAAGUUGAUGACCCUUAUAUGUUAUUUUCUCAUCAUUUUCCUCUGCCAAAGGAGAUUUGCCUCGCAAUGCUUCA	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16028	MI0001025	ath-MIR399f	Arabidopsis thaliana miR399f stem-loop	AUAUGCAUUACAGGGCAAGAUCACCAUUGGCAGAGAUCUAUUACUUCAUUCUUGCAUCAUAUGCAUAAAUGUUUGUGGUGAGCUCUCUGCCAAAGGAGAUUUGCCCGGUAAUUCUCUU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	1
16029	MI0001026	osa-MIR393	Oryza sativa miR393 stem-loop	UGGGGAAGCAUCCAAAGGGAUCGCAUUGAUCCUUCAUCGCUCUCGCUCGCUUCCAUGGCGGUCGUCGUCUACAAGCAGCUUGACGGAUCAUGCGAUCCUUUUGGAGGCUUCCUCU	This sequence belongs to the miR393 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins and bHLH transcription factors [1]. 	7
16030	MI0001027	osa-MIR394	Oryza sativa miR394 stem-loop	UACUGAGAGUUCUUUGGCAUUCUGUCCACCUCCUUGUCGAAUCCUCAGAGACAGAAAUCUCAUAUCUGUUGAUCUUGGAGGUGGGCAUACUGCCAAUGGAGCUGUGUAGG	This sequence belongs to the miR394 family of miRNAs, which are predicted to target mRNAs coding for F-box proteins [1]. 	7
16031	MI0001028	osa-MIR395b	Oryza sativa miR395b stem-loop	GAGUCCCUAGGAGUUCCUUUCAAGCACUUUACGACACACUGUAUUGAGAGUUGUCGUGAAGUGUUUGGGGGAACUCUUAGUGUCGC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16032	MI0001029	osa-MIR395d	Oryza sativa miR395d stem-loop	GUAUUGUCGUGAGUUCCCUUCAAGCACUUCACGUGGCACUAUCUCAAUGCCUACUAUGUGAAGUGUUUGGGGGAACUCUCGAUAUCAC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16033	MI0001030	osa-MIR395e	Oryza sativa miR395e stem-loop	GUAUUAUCGAGAGUUCCCUUCAACCACUUCACGUGGCACUGUUUCAAGGCCUAUUGUGUGAAGUGUUUGGGGGAACUCUCGAUAUCAC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16034	MI0001031	osa-MIR395g	Oryza sativa miR395g stem-loop	GUAUCACCGUGAGUUCCCUUCGAACACUUCACGUGGCACUAUUUCAAUGCCUAUUGUGAAGUGUUUGGGGGAACUCUCGAUGUCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16035	MI0001032	osa-MIR395h	Oryza sativa miR395h stem-loop	UUGUUACCUGGAGUUUCCUCAACACACUUCACAUCUGCUAGGCCCUAUUACAAUUGCGCAAUGUGGAGUCUGCAAUUGGUAGUGAAGUGUUUGGGGGAACUCUAGGUGGCAC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16036	MI0001033	osa-MIR395i	Oryza sativa miR395i stem-loop	GUUUUACCGGGAGUUCUCUUCAAGCACUUCACGUAGAGCUUUCUAUUGACAUGGAGCUUUAGAACAAUGUGAAGUGUUUGGGGGAACUCUUGGUACCAA	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16037	MI0001034	osa-MIR395j	Oryza sativa miR395j stem-loop	GUGUUCCCAAGAGUUCCUUGCAAGCACUUCACAUAGAACUUCUGUUACUCUCAUGUAACAUUGGGAACUUGAGAAGCUACUGUGAAGUGUUUGGGGGAACUCUAGGUGGCAC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16038	MI0001035	osa-MIR395k	Oryza sativa miR395k stem-loop	GUUUUAUCGGGAGUUUCCUUCAAGCACUUCACGUAGAGCUUUCUAUUGAUAUGGAGCUUUGGAACAAUGUGAAGUGUUUGGGGGAACUCUUGAUACCAA	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16039	MI0001036	osa-MIR395l	Oryza sativa miR395l stem-loop	GCGUUCCUUCCAAGCACUUCACACAGAGCUUUUAUUUCUCUCACAUCGAUUGAGAACUUAAUUAGAAGCUUUUGUGAAGUGUUUGGGGGAACUC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16040	MI0001037	osa-MIR395s	Oryza sativa miR395s stem-loop	GUAUCACCGUGAGUUCCCUUCAAGCACUUCACGUGGCACUAUUUCAAUGCCUAUUGUGAAGUGUUUGGGGGAACUCUCGAUGUUCC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16041	MI0001038	osa-MIR395t	Oryza sativa miR395t stem-loop	UUAUCCACUGGAGUUCUCCUCAAACCACUUCAGCAGAUAGCUAGCUAGGCCUCAUUGCAUUGCACCACUGUUGCAUAACUAUGAGCAUGGGGCCAAAAGUUAGCUGCUUAUAGUGAAGUGUUUGGGGAAACUCCGGUUGGCAA	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16042	MI0001041	osa-MIR395c	Oryza sativa miR395c stem-loop	GUAUUAUCAAGAGUUCUCUUUAAGCACUUCAUACGACACCAUUAUUUAUAGGGUUGUUGUGAAGUGUUUGGAGGAACUCUCGGUGUCAU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16043	MI0001042	osa-MIR395a	Oryza sativa miR395a stem-loop	UUGUCCACUGGAGUUCUCCUCAAUCCACUUCAGUAGAUAGCUAUGGCUAGGCCUCAUUGCAUUGCACUGUUACAUAACUGUGAUCAUGGGGCCAAAAGCUAGCUAUGUAUAGUGAAGUGCUUGGGGGAACUCCAGUUGACAC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16044	MI0001043	osa-MIR395f	Oryza sativa miR395f stem-loop	UUAUCGCGGGUUCCCUUCAAUCACUUCACAUGGUACUAUUUCAAGGCCUACUAUGUGAAUUGUUUGGGGGAACUCUCGAUGU	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16045	MI0001044	osa-MIR395u	Oryza sativa miR395u stem-loop	ACACUGCCAGGAAUUCCCUUCAAGCAAUUCAUGAAACAAUAUUUUGAGAGUUGUUGUGAAGCGUUUGGGGGAAAUCUCAGUGUCGC	This sequence belongs to the miR395 family of miRNAs, which are predicted to target mRNAs coding for ATP sulphurylases [1].  Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the genes have been renamed to reflect this arrangement [2]. 	7
16046	MI0001046	osa-MIR396a	Oryza sativa miR396a stem-loop	CUUUGUGAUCUUCCACAGCUUUCUUGAACUGCACGCAUGAUGAAUAAUCCCUUUGGUUAAUUGUGAUCUGGUCUCUGAGAGAUCGUAGUUAGACUCGAUCGGUUGCAUUGGCAUCAGAGAGAGCAGUUCAAUAAAGCUGUGGGAAAUUGCAGAG	This sequence belongs to the miR396 family of miRNAs, which are predicted to target mRNAs coding for Growth Regulating Factor (GRF) transcription factors, rhodenase-like proteins, and kinesin-like protein B [1]. 	7
16047	MI0001047	osa-MIR396b	Oryza sativa miR396b stem-loop	CUUUGUGGUCUUCCACAGCUUUCUUGAACUGCAUCUUUGAGAGAGAUUAGCAUCCCUAUGUGUGGAUUUUGCUUGCACGAGUGUGCAGUUCAAUAAAGCUGUGGGAAAUUACAGAG	This sequence belongs to the miR396 family of miRNAs, which are predicted to target mRNAs coding for Growth Regulating Factor (GRF) transcription factors, rhodenase-like proteins, and kinesin-like protein B [1]. 	7
16048	MI0001048	osa-MIR396c	Oryza sativa miR396c stem-loop	UGCCAUGCCUUUCCACAGCUUUCUUGAACUUCUCUUGUGCCUCACUCACUUUCAUUACUGGAGAGAUAUGCAUCAUCAGUGGAAGCUUAUAGGGAGAGGAGUGCAAGAAGAGGGUCAAGAAAGCUGUGGGAAGAAAUGGCA	This sequence belongs to the miR396 family of miRNAs, which are predicted to target mRNAs coding for Growth Regulating Factor (GRF) transcription factors, rhodenase-like proteins, and kinesin-like protein B [1]. 	7
16049	MI0001049	osa-MIR397a	Oryza sativa miR397a stem-loop	AUCAAAUGCAUCAUUGAGUGCAGCGUUGAUGAACAACGGUAACCGGUCCAUGUUGAUGCGCAUUUGGCCGGUGAUCUGAUCAUCAUCAGCGCUUCACUCAAUCAUGCGUUUGGC	This sequence belongs to the miR397 family of miRNAs, which are predicted to target mRNAs coding for laccases and beta-6 tubulin [1]. 	7
16050	MI0001050	osa-MIR397b	Oryza sativa miR397b stem-loop	AGGGAAGGCAUUAUUGAGUGCAGCGUUGAUGAACCUGCCGGCCGGCUAAAUUAAUUAGCAAGAAAGUCUGAAACUGGCUCAAAGGUUCACCAGCACUGCACCCAAUCACGCCUUUGCU	This sequence belongs to the miR397 family of miRNAs, which are predicted to target mRNAs coding for laccases and beta-6 tubulin [1]. 	7
16051	MI0001051	osa-MIR398a	Oryza sativa miR398a stem-loop	GCUGAACCCAGAGGAGUGGUACUGAGAACACAGGUGCCAAUACAAUGUAUGGUGAGCUACUGUAUAAUGGAGUAAUUCUGUAACUGUGUUCUCAGGUCACCCCUUUGGGUUUCUU	This sequence belongs to the miR398 family of miRNAs, which are predicted to target mRNAs coding for copper superoxide dismutases and cytochrome C oxidase subunit V [1]. 	7
16052	MI0001052	osa-MIR398b	Oryza sativa miR398b stem-loop	GGAGUUCCUACAGGGGCGAGCUGGGAACACACGGUGAUGAGGCGGUCUGGUCUUUCGUGUGUUCUCAGGUCGCCCCUGCCGGGACUCU	This sequence belongs to the miR398 family of miRNAs, which are predicted to target mRNAs coding for copper superoxide dismutases and cytochrome C oxidase subunit V [1]. 	7
16053	MI0001053	osa-MIR399a	Oryza sativa miR399a stem-loop	CUGUGAAUUACAGGGCAGUUCACCUUUGGCACAAGGGCAAGCAGUAGAAACCAUGCGUGCUUGCUAGAGCUGGAAAUGAUGCUGGUAGCAUUGCAUGGUUCAGGGAUCACAGAUCUCGUGCCAAAGGAGAAUUGCCCUGCGAUUUUGUC	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16054	MI0001054	osa-MIR399b	Oryza sativa miR399b stem-loop	GUGAGAAUCACAGUGCGAUUCUCCUCUGGCAUGGCAUGAGAGGCCUAAAAAAGAGACGCACUGCCGUGCCAAAGGAGAAUUGCCCUGCCAUUCAGAA	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16055	MI0001055	osa-MIR399c	Oryza sativa miR399c stem-loop	CGGCGAAUUACAGGGCGGUUUCUCCUUUGGCACGUACGGAGGCAAGGCAUGCGGUGAAAAAUCUCUAGCUAGCCAUGCGUGCCAAAGGAGAAUUGCCCUGCGAUUCACCA	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16056	MI0001056	osa-MIR399d	Oryza sativa miR399d stem-loop	AAGACAGUAGUAGGCAGCUCUCCUCUGGCAGGUGCAUUCUAGGUGAUUUUGUAAUUGUAUAUGCAUCCAAGGUAUAUACAGUCCGGCCAUGGUGCUACAUUGCAAUCAUCCAUAUGUGAUUGCAUUGUGUAUAUAUAUACAUGGUGGCCUUUGAUAGACCAUCAUAUAUCGGUUGGUUAUGUGCAUGUAUGUAUAUACCAGCUGCUACUAGCUUUGAUCGAUCGCCAUGUAGCGAUUGAAUUCACCAAAACGGCCUGCCAAAGGAGAGUUGCCCUGCGACUGUCUU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16057	MI0001057	osa-MIR399e	Oryza sativa miR399e stem-loop	ACAUGCAUUACCGGGUGAGUCUUCCUUGGCAGUGUUCGAAUCGGCAGUACCGGUCUGCAAGUGAUCGGUCAAUCACCAGUUCACCGCUGCCAAAGGAGAUUUGCCCAGCAAUGCAACU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16058	MI0001058	osa-MIR399f	Oryza sativa miR399f stem-loop	UGGUGGAUUACCGGGCCAUGUCUCCUUGGGCAGAGGUGAUCAGAUUGCACACUUCACUUCAACCUCUUGCUCUAGCUUGUUCUCUCUGCCAAAGGAGAUUUGCCCAGCAAUCCACAU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16059	MI0001059	osa-MIR399g	Oryza sativa miR399g stem-loop	AUGUGCAUUGCAGGGCAACUACUCCAUUGGCAGAGGGAUGGAUUGGAUAUGGAUAUGGCUGAUGCUUCCAUUUGAUCCCAUCCCUAUCUGCCAAAGGAGAUUUGCCCAGCGAUUCACUC	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16060	MI0001060	osa-MIR399h	Oryza sativa miR399h stem-loop	CCAUGCAUUACUGGGCAGGUCUCCCUUGGCAGUGGCCGAUCGAGCUGAUCAAACCACGCAAAAGCCACUGCCAAAGGAGACUUGCCCAGCAAUGCAGAU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16061	MI0001061	osa-MIR399i	Oryza sativa miR399i stem-loop	GUGAGAAUCACAGUGCAGUUCUCCUCUGGCAUGGAGGGCAAGAGGAGCUGAAUAGCUAAUGGAUGAUAAACUGCUAGCCUUUCCCUGCCAAAGGAGAGCUGCCCUGCCAUUCAGUG	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16062	MI0001062	osa-MIR399j	Oryza sativa miR399j stem-loop	AGUCCAGUUUCAGGGCUCCUCUCUCUUGGCAGGGAGCAUGUGAAGUCUUUUGUAGCUCACUCAUUUUCAGCCCUCUGCCAAAGGAGAGUUGCCCUAAAACUGGACU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16063	MI0001063	osa-MIR399k	Oryza sativa miR399k stem-loop	AGCUGCAUUGCUGGGCAAGUUGUCCUUUGGCAGAUGUUGCAGUUCAUCAUCGAUGCCUGGGGGUUACCAGACUACUGCCAAAGGAAAUUUGCCCCGGAAUUCAUCU	This sequence belongs to the miR399 family of miRNAs, which are predicted to target mRNAs coding for a phosphatase transporter [1]. 	7
16064	MI0001064	ebv-mir-BHRF1-1	Epstein Barr virus miR-BHRF1-1 stem-loop	UAUUAACCUGAUCAGCCCCGGAGUUGCCUGUUUCAUCACUAACCCCGGGCCUGAAGAGGUUGACAA	Pfeffer et al. cloned 5 miRNAs from a Burkitt's lymphoma cell line (BL41) infected with the B95-8 strain of Epstein-Barr virus [1].  They were all confirmed by Northern blot. 	9
16065	MI0001065	ebv-mir-BHRF1-2	Epstein Barr virus miR-BHRF1-2 stem-loop	CUUUUAAAUUCUGUUGCAGCAGAUAGCUGAUACCCAAUGUUAUCUUUUGCGGCAGAAAUUGAAAG	Pfeffer et al. cloned 5 miRNAs from a Burkitt's lymphoma cell line (BL41) infected with the B95-8 strain of Epstein-Barr virus [1].  They were all confirmed by Northern blot.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
16066	MI0001066	ebv-mir-BHRF1-3	Epstein Barr virus miR-BHRF1-3 stem-loop	UCUAACGGGAAGUGUGUAAGCACACACGUAAUUUGCAAGCGGUGCUUCACGCUCUUCGUUAAAAU	Pfeffer et al. cloned 5 miRNAs from a Burkitt's lymphoma cell line (BL41) infected with the B95-8 strain of Epstein-Barr virus [1].  They were all confirmed by Northern blot.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
16067	MI0001067	ebv-mir-BART1	Epstein Barr virus miR-BART1 stem-loop	GGGGGUCUUAGUGGAAGUGACGUGCUGUGAAUACAGGUCCAUAGCACCGCUAUCCACUAUGUCUCGCCCG	Pfeffer et al. cloned 5 miRNAs from a Burkitt's lymphoma cell line (BL41) infected with the B95-8 strain of Epstein-Barr virus [1].  They were all confirmed by Northern blot.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
16068	MI0001068	ebv-mir-BART2	Epstein Barr virus miR-BART2 stem-loop	ACUAUUUUCUGCAUUCGCCCUUGCGUGUCCAUUGUUGCAAGGAGCGAUUUGGAGAAAAUAAA	Pfeffer et al. cloned 5 miRNAs from a Burkitt's lymphoma cell line (BL41) infected with the B95-8 strain of Epstein-Barr virus [1].  They were all confirmed by Northern blot.  The mature miRNA names reflect cloning frequencies from Landgraf et al. [2], and may differ subtly from previous annotations. 	9
16069	MI0001069	ath-MIR400	Arabidopsis thaliana miR400 stem-loop	UGAGGAUUGUUUAUGAGAGUAUUAUAAGUCACUACAUUUGGUAAGCAAAGUGUUGUUUCUCAAACGAAGUGACUUAUGAUAAUCUCAUGAAUGGAUUUUGCA		1
16070	MI0001070	ath-MIR401	Arabidopsis thaliana miR401 stem-loop	UAUAUAGACCCUAAAAACGUCCAGGGACUAAUAAUGCAAAUAUGGAAAUCUUCUGGGGCAAACUUGAGCUUCUGAAAACUUGAAAGCGUUUAGGGUUUUUGCUGGGCCGAAACUGGUGUCGACCGACACCAAGAGUGUGUCGCUCGACACUCAUCGCUGAUUCCUGAACCAAAAUCGUUCUUAGUUUCCUUUUCCUUAGUUUUUGCUCCAAAAUGUCUCCUUAUCUCCAUUGUUGUCCCAUUGCAUAGAA		1
16071	MI0001071	ath-MIR402	Arabidopsis thaliana miR402 stem-loop	CGUGGUAGAUAAGUUUGAGUUGCAUAGUGGCAGUCUUCCUUUGUUUGUUAACCCAUAUUUUCAUGAUUCGAGGCCUAUUAAACCUCUGUUACAUCUGCUUUUUGAAAAGUUGUCAUUUUUCUGAAAUCUUCUUGCCUCAAUUUCCAACAGCAGAUUCAUCUUUCAUUGGAUGAUCCGUUAGUUUUUGAUAGAAAAAAUGAGGUGGGAAGAAAUUAAGACUGACUUCGAAAUAGCCUUUAAAAUAGGGGUUUAUAGACCUCGAAUCAUAUCAAACGAGUCUGCUACUAUGCUACUGAAAACUUUAUCAAA		1
16072	MI0001072	ath-MIR403	Arabidopsis thaliana miR403 stem-loop	UUGUCAUUAGAAGAGUCGUAUUACAUGUUUUGUGCUUGAAUCUAAUUCAACAGGCUUUAUGUAAGAGAUUCUUUAACAAUUCCUAUAAUCUUUGUUGUUGGAUUAGAUUCACGCACAAACUCGUAAUCUGUCUUU		1
16073	MI0001073	ath-MIR404	Arabidopsis thaliana miR404 stem-loop	UAGCAUGUUCGUUUCAUUAACGCUGGCGGUUGCGGCAGCGGCUGCGGUAGCGGUGGCGGCAAACACUACCGCAGGUUGUUGUUCGUUUUGUUGCCGCAGACGCUGCCGCAGCCGCUGCCGCAACCGCAGGUUUCUUUGUUCGUUUCGACG		1
16074	MI0001074	ath-MIR405a	Arabidopsis thaliana miR405a stem-loop	UCAAAAUGGGUAACCCAACCCAACCCAACUCAUAAUCAAAUGAGUUUAUGAUUAAAUGAGUUAUGGGUUGACCCAACUCAUUUUGUUAAAUGAGUUGGGUCUAACCCAUAACUCAUUUCAUUUGAUGGGUUGAGUUGUUAAAUGGGUUAACCAUUUA		1
16075	MI0001075	ath-MIR405b	Arabidopsis thaliana miR405b stem-loop	UUAACCCAUUUAACAAUUCAACCCAUCAAAUGAAAUGAGUUAUGGGUUAGACCCAACUCAUUUAACAAAAUGAGUUGGGUCUAACCCAUAACUCAUUUAAUUAUAAACUCAUUUGAUUAUGAGU		1
16076	MI0001077	ath-MIR405d	Arabidopsis thaliana miR405d stem-loop	ACCCAUCAAAUGAAAUGAGUUAUGGGUUGACCCAACUCAUUUUGUUAAAUGAGUUGGGUCUAACCCAUAACUCAUUUAAUCAUAAA		1
16077	MI0001078	ath-MIR406	Arabidopsis thaliana miR406 stem-loop	UAAAGUCUUAAUUUUUAGUUAUCACGAUUUAGCACAUAUCAAUCUAUAGAUUUGAUUUUUCUUUUAUUAGUUCUUAAAUUUUGAUUUGAGACAGUAACUAUUCAAAUAGAAUGCUAUUGUAAUCCAGAAUCCGAAAGAAACGAAUCAAAAAAAAAAAAAACGAGUCUUCAUAGUAAAAAUCGAUUAACUAAAAAGGAUGG		1
16078	MI0001079	ath-MIR407	Arabidopsis thaliana miR407 stem-loop	UGGGAAAAAUGUUAAAAAAAUCGCCAACUUUUAAAAAUGGGACAAAAAAAUCGCCAACUCCUGAAAUGUCAUUUAAAUCAUAUACUUUUGGUUGACUUUUCCAGAAAGAUAAUAAAGCAAAGAUUCGUAAUCAACAAAACUUUGCUCUGUUAUCUUUCUAAAGAACUCAAUCAAAAGUAUGUGAUUAAAACGACAUUUCAGGAGUUGGUGAUUUUUCAUCCCAUUUUUCAAAGUUGGCAAUUUUUUUGACAUUUUUUCCAAUG	MIR407a and MIR407b published by Sunkar and Zhu [1] map to the same locus on NC_003071.3. 	1
16079	MI0001080	ath-MIR408	Arabidopsis thaliana miR408 stem-loop	AAGGUUAGAUUGGUAUUGCAAUGAAAGAAGACAAAGCGGUAAUGAGAGAGAGACAGGGAACAAGCAGAGCAUGGAUUGAGUUUACUAAAACAUUAAACGACUCUGUUUUGUCUCUACCCAUGCACUGCCUCUUCCCUGGCUCCCUCUUUUUUUCUCUAUAUUUCUCUCUCUCCUUUCAUUUCACAGCUUUCAAUGGAAUUUUAUUGCUACUGCUAACG		1
16080	MI0001082	ath-MIR156g	Arabidopsis thaliana miR156g stem-loop	AUAACGAAGGCGACAGAAGAGAGUGAGCACACAUGGCUCUUUUUCUAGCAUGCUCAUGCUCGAAAGCUCUGCGUGCUUACUCUCUUCUUGUCUCCUGCUCUCU	This sequence is a predicted paralogue of the previously identified miR156 family [1], subsequently verified in [2].  It is predicted to target mRNAs coding for Squamosa-promoter Binding Protein (SBP)-like transcription factors. 	1
16081	MI0001083	ath-MIR156h	Arabidopsis thaliana miR156h stem-loop	AUGAAAAAUGUUGACAGAAGAAAGAGAGCACAACCUGGGAUUAGCAAAAAGAUAGUUUUGCCCUUGUCGGGAGUGUGCUCUCUUUCCUUCUGCCACCAUCAUUGCG	This sequence is a predicted paralogue of the previously identified miR156 family [1], subsequently verified in [2].  It is predicted to target mRNAs coding for Squamosa-promoter Binding Protein (SBP)-like transcription factors. 	1
16082	MI0001084	ath-MIR158b	Arabidopsis thaliana miR158b stem-loop	AUCUCUGUGCUUCUUUGUCUACACUUUUGGAAAAGGUGAUGAUAUCAUUGCUUUUCCCCAAAUGUAGACAAAGCAAUACCGUGAU		1
16083	MI0001085	ath-MIR159c	Arabidopsis thaliana miR159c stem-loop	GUGUAACAGAAGGAGCUCCCUUCCUCCAAAACGAAGAGGACAAGAUUUGAGGAACUAAAAUGCAGAAUCUAAGAGUUCAUGUCUUCCUCAUAGAGAGUGCGCGGUGUUAAAAGCUUGAAGAAAGCACACUUUAAGGGGAUUGCACGACCUCUUAGAUUCUCCCUCUUUCUCUACAUAUCAUUCUCUUCUCUUCGUUUGGAUUGAAGGGAGCUCCUUUUCUUCUUC	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	1
16084	MI0001086	ath-MIR319c	Arabidopsis thaliana miR319c stem-loop	UAGAUAUAGAAGGAGAUUCUUUCAGUCCAGUCAUGGAUAGAAAAAGAAGAGGGUAGAAAUAUCUGCCGACUCAUCCAUCCAAACACUCGUGGUAGAGAAACGAUAAAUUUAAACCGCAGUGACUGUGUGAAUGAUGCGGGAGAUAUUUUUGAUCCUUCUUUAUCUGUGUUUGGACUGAAGGGAGCUCCUUCUUUUUCUA	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1], subsequently verified in [2,3].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	1
16085	MI0001087	ath-MIR164c	Arabidopsis thaliana miR164c stem-loop	UAACACUUGAUGGAGAAGCAGGGCACGUGCGAACACAAAUGAAAUCGAUCGGUACUUGUUGAUCAUAUUUUCGCACGUGUUCUACUACUCCAACACGUGUCU	This sequence is a predicted paralogue of the previously identified miR164 family [1].  It is predicted to target mRNAs coding for NAC domain transcription factors. 	1
16086	MI0001088	ath-MIR167c	Arabidopsis thaliana miR167c stem-loop	CCAGUAGCAGUUAAGCUGCCAGCAUGAUCUUGUCUUCCUCUCUUAGGUUUCAUAUAUAGUUAAUAAAUAUUUUAUAUAUUUCUUGUUCUUACAAGAUUAUAUGAUCAUAGCUUAGAGAGAGAGAGAGACUAGGUCAUGCUGGUAGUUUCACCUGCUAAUG	This sequence is a predicted paralogue of the previously identified miR167 family [1], subsequently verified in [2].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	1
16087	MI0001089	ath-MIR172e	Arabidopsis thaliana miR172e stem-loop	GUAGUCGCAGAUGCAGCACCAUUAAGAUUCACAAGAGAUGUGGUUCCCUUUGCUUUCGCCUCUCGAUCCGCAGAAAAGGGUUCCUUAUCGAGUGGGAAUCUUGAUGAUGCUGCAUCAGCAAAUAC	This sequence is a predicted paralogue of the previously identified miR172 family [1].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	1
16088	MI0001090	osa-MIR156k	Oryza sativa miR156k stem-loop	UUGAGAGUGAUGACAGAAGAGAGAGAGCACAACCCGGCAGCAGCGACGACGGCGGUCGCUUCUGCCAGGGCCGUGUGCUCUCUGAUCUAUCUGUCAUUGCCGUCCA	This sequence is a predicted paralogue of the previously identified miR156 family [1].  It is predicted to target mRNAs coding for Squamosa-promoter Binding Protein (SBP)-like transcription factors. 	7
16089	MI0001091	osa-MIR156l	Oryza sativa miR156l stem-loop	GCUAGGGAGCCGACAGAAGAGAGUGAGCAUAUAUAGUUCUUUCCUUGCAUAUGUGGUCAUAUGUGUGUUGACUGAAGAGAUACAUAUAUAUAGAGAGAGAGAGUUCAUGUGCUUGAAGCUAUAUGUGCUCACUUCUCUUUCUGUCAGCAAAUUAUC	This sequence is a predicted paralogue of the previously identified miR156 family [1].  It is predicted to target mRNAs coding for Squamosa-promoter Binding Protein (SBP)-like transcription factors. 	7
16090	MI0001092	osa-MIR159a	Oryza sativa miR159a stem-loop	GUUGUGGACGUUGAGCUCCUUUCGGUCCAAAAAGGGGUGUUGCUGUGGGUCGAUUGAGCUGCUGGGUCAUGGAUCCCGUUAGCCUACUCCAUGUUCAUCAUUCAGCUCGAGAUCUGAAAGAAACUACUCCAAUUUAUACUAAUAGUAUGUGUGUAGAUAGGAAAAUGAUGGAGUACUCGUUGUUGGGAUAGGCUUAUGGCUUGCAUGCCCCAGGAGCUGCAUCAACCCUACAUGGACCCUCUUUGGAUUGAAGGGAGCUCUGCAUCUUUUGU	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16091	MI0001093	osa-MIR159b	Oryza sativa miR159b stem-loop	GGUUAUGAAGUGGAGCUCCUUUCGUUCCAAUGAAAGGUUUAUCUGAAGGGUGAUACAGCUGCUUGUUCAUGGUUCCCACUAUUCUAUCUCAUAGGAAAAGAGAUAGGCUUGUGGUUUGCAUGACCAAGGAGCCGAAUCAACUCCUUGCUGACCACUCUUUGGAUUGAAGGGAGCUCUGCAUCUUGAUC	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16092	MI0001094	osa-MIR159c	Oryza sativa miR159c stem-loop	GAGGAGGAAGAGGAGCUCCUUUCGAUCCAAUUCAGGAGAGGAAGUGGUAGGAUGCAGCUGCCGAUUCAUGGAUACCUCUGGAGUGCAUGGCAGCAAUGCUGUAGGCCUGCACUUGCAUGGGUUUGCAUGACCCGGGAGAUGAACCCACCAUUGUCUUCCUCUAUUGAUUGGAUUGAAGGGAGCUCCACAUCUCUCUC	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16093	MI0001095	osa-MIR159d	Oryza sativa miR159d stem-loop	UGAUGUGAGGAGGAGCUCCUUUCGAUCCAAUUCAGGAGAGGAAGUGGUGGGAUGCAGCUGCCGGUUCAUGGAUACCUCUGCAGUUCAUGCCGGUAGGCCUGCACUUGCAUGGGUUUGCAUGACCUGGGAGAUGAACCUGCCAUUGUGUUCCUCUAUUGAUUGGAUUGAAGGGAGCUCCGGCUACACCUA	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16094	MI0001096	osa-MIR159e	Oryza sativa miR159e stem-loop	GAUGAAGAAGAAGAGCUCCCUUUCGAUCCAAUUCAGGAGAGGAAGUGGUAGGAUGCAGCUGCCGGUUCAUGGAUACCUCUGGAGUGCAGGGCAAAUAGUCCUACCCUUUCAUGGGUUUGCAUGACUCGGGAGAUGAACCCGCCAUUGUCUUCCUCUAUUGAUUGGAUUGAAGGGAGCUCCUCUAGCUACAU	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16095	MI0001097	osa-MIR159f	Oryza sativa miR159f stem-loop	GAAGAAGAAGACGAGCUCCCUUCGAUCCAAUCCAGGAGAGGAAGUGGUAGGAUGCAGCUGCCGGUUCAUGGAUACCUCUGCAGUGCAUGUCGUAGGCUUGCACUUGCAUGGGUUUGCAUGACCCGGGAGAUGAACCCACCAUUGUCUUCCUCUUAUGCUUGGAUUGAAGGGAGCUCUACACCUCUCUC	This sequence is a predicted paralogue of the previously identified miR159/JAW family [1].  It is predicted to target mRNAs coding for MYB and TCP transcription factors. 	7
16096	MI0001098	osa-MIR319a	Oryza sativa miR319a stem-loop	UGUGUAAGAAGAGAGCUCUCUUCAGUCCACUCUCAGAUGGCUGUAGGGUUUUAUUAGCUGCCGAAUCAUCCAUUCACCUACCAAGAAAGUUGCAGGAGUGUAUCUCUUGGUAGCGGACUGGAUGACGCGGGAGCUAAAAUUUAGCUCUGCGCCGUUUGUGGUUGGACUGAAGGGUGCUCCCUUGCUCAAGC		7
16097	MI0001099	osa-MIR319b	Oryza sativa miR319b stem-loop	GAUGGAUGGAAGAGAGCGUCCUUCAGUCCACUCAUGGGCGGUGCUAGGGUCGAAUUAGCUGCCGACUCAUUCACCCACAUGCCAAGCAAGAAACGCUUGAGAUAGCGAAGCUUAGCAGAUGAGUGAAUGAAGCGGGAGGUAACGUUCCGAUCUCGCGCCGUCUUUGCUUGGACUGAAGGGUGCUCCCUCCUCCUCGA		7
16098	MI0001100	osa-MIR160e	Oryza sativa miR160e stem-loop	GUAGGGGAUAUGCCUGGCUCCCUGUAUGCCGCUCGCAUGGCUGCCAACCCAAUGAACUCGAUCUCGUUGUUGGCCGCUGCGUACGGCGUGCGAGGUGCCAAGCAUGGCCCUCUU	This sequence is a predicted paralogue of the previously identified miR160 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16099	MI0001101	osa-MIR160f	Oryza sativa miR160f stem-loop	GGAUUAACGCUGCCUGGCUCCCUGAAUGCCAUCCGAGAAGCGUGCCGCUGUGGCCGGCUGCUUCCUGGUUGGCAUUGAGGGAGUCAUGCAGGGUUUGCUC	This sequence is a predicted paralogue of the previously identified miR160 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16100	MI0001102	osa-MIR162b	Oryza sativa miR162b stem-loop	UGGGUGAUGCCUGGGCGCAGUGGUUUAUCGAUCUCUUCCCUGCCUUGUGCUGCUCCGAUCGAUGCCCGUGCUGAUUCUUGAUAAUAUACAACGCAGGAAUCGAUCGAUAAGCCUCUGCAUCCAGAUCUCACUUU	This sequence is a predicted paralogue of the previously identified miR162 family [1].  It is predicted to target mRNAs coding for DICER-LIKE 1 (DL1) proteins. 	7
16101	MI0001103	osa-MIR164c	Oryza sativa miR164c stem-loop	AGGUUCUUGUUGGAGAAGCAGGGUACGUGCAAAAUGCACACCGGUUGGUCGAGCUAAUUAACAAGCUCUGACGACCAUGGUGAUCGAAUGCACGUGCUCCCCUUCUCCACCAUGGCCUU	This sequence is a predicted paralogue of the previously identified miR164 family [1].  It is predicted to target mRNAs coding for NAC domain transcription factors. 	7
16102	MI0001104	osa-MIR164d	Oryza sativa miR164d stem-loop	CAAACCGUGCUGGAGAAGCAGGGCACGUGCUCGACGGCGGGGCUGGCUGGCCGGCCGGCUUGCAGCAUGUGCGCUCCUUCUCCAGCAUGGCUUC	This sequence is a predicted paralogue of the previously identified miR164 family [1].  It is predicted to target mRNAs coding for NAC domain transcription factors. 	7
16103	MI0001105	osa-MIR164e	Oryza sativa miR164e stem-loop	UUGUGCAGGGUGGAGAAGCAGGGCACGUGAGCGGCCAUCCAGUGUAGCUUCGCUGCGCGUCCAUGGCGGCGAACGCGCGUGAUCUGGAGUUUGGAUGGUCGUUCAUGUGUCCGUCUUCUCCACCGAGCACUG	This sequence is a predicted paralogue of the previously identified miR164 family [1].  It is predicted to target mRNAs coding for NAC domain transcription factors. 	7
16104	MI0001106	osa-MIR166j	Oryza sativa miR166j stem-loop	AGAUAGGUGUUUGGAAUGCAGUUUGAUCCAAGAUCUGCCUAUAUAUAUGGUGUGUAUAUCAUAUCUUGUGAUAUGGGGGAUAUGCAACAGGUGUGUGACAGGGGUAGGUAGAUCUCGGAUCAGGCUUCAUUCCUCACACC	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16105	MI0001107	osa-MIR166k	Oryza sativa miR166k stem-loop	AUUAGGUUAAGGGGUUUGUUGUCUGGCUCGAGGCAUCCGGGACUCCGGUUUCUCCUUUCCUACUGGAGGCGCCUAAUUUCCGGCGAGCUCGGAGCCUCGGACCAGGCUUCAAUCCCUUUAACCAUGC	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16106	MI0001108	osa-MIR166l	Oryza sativa miR166l stem-loop	GUUAGGUUAAGGGGAUUGUUGUCUGGUUCAAGGUCUCCACAUUGUGCAAAAUGUUCAUUCAUGGAGGCACAGGAUGCUUGGUGAUCUCGGACCAGGCUUCAAUCCCUUUAACCAGCA	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16107	MI0001109	osa-MIR167d	Oryza sativa miR167d stem-loop	CAUUAGGAGCUGAAGCUGCCAGCAUGAUCUGAUGAGUGCUUAUUAGGUGAGGGCAGAAUUGACUGCCAAAACAAAGAUCAGAUCAUGCUGUGCAGUUUCAUCUGCUUGUG	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16108	MI0001110	osa-MIR167e	Oryza sativa miR167e stem-loop	UGUGAGAGAAUGAAGCUGCCAGCAUGAUCUGGUUGUCAGGCAUGAGCCAAAUCUAUCCAUGGUGUUGGUGGUACUGAAAUUACCGCGUUUUCGAGGUUUUUCGUCGUGUCAACUUGCGAAGGGAAUUACGGGUUCUUGAUGAGCAUUGGUGAUAGGAGGUGUGGGCUUGGUUAGUAGAGGUAGAAUUAUGAUUGUUCUUGUGAGUUUCAGUAAGAGGUGGGAGUGAUUGGAAUUUGGCUCCAUCAGAUCAUGUUGCAGCUUCACUCUCUCACC	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16109	MI0001111	osa-MIR167f	Oryza sativa miR167f stem-loop	CACAAGUGGAUGAAGCUGCCAGCAUGAUCUGAUCACAGUAGUUCUCUAGCUGAUGAUGAUUUACAAAACCUAGAGACAUGCAUCAGAUCAUCUGGCAGUUUCAUCUUCUCAUG	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16110	MI0001112	osa-MIR167g	Oryza sativa miR167g stem-loop	CAUAAGCAGGUGAAGCUGCCAGCAUGAUCUGAAAGCAUCUCAAACCAGCGAUCAGAUCAUCCGGCAGCUUCAUCUUCUCAUG	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16111	MI0001113	osa-MIR167h	Oryza sativa miR167h stem-loop	CACAAGUUGGUGAAGCUGCCAGCAUGAUCUGAUGAUGAUGAUGAUCCACCUCUCUCAUCUGUGUUCUUGAUUAAUUACGGAUCAAUCGAUCAGGUCAUGCUGUAGUUUCAUCUGCUGGUU	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16112	MI0001114	osa-MIR167i	Oryza sativa miR167i stem-loop	UGUGAGAGGCUGAAGCUGCCAGCAUGAUCUGGUCCAUGAGUUGCACUGCUGAAUAUAUUGAAUUCAGCCAGGAGCUGCUACUGCAGUUCUGAUCUCGAUCUGCAUUCGUUGUUCUGAGCUAUGUAUGGAUUUGAUCGGUUUGAAGGCAUCCAUGUCUUUAAUUUCAUCGAUCAGAUCAUGUUGCAGCUUCACUCUCUCACU	This sequence is a predicted paralogue of the previously identified miR167 family [1].  It is predicted to target mRNAs coding for Auxin Response Factors (ARF transcription factors). 	7
16113	MI0001115	osa-MIR168a	Oryza sativa miR168a stem-loop	CGCCUCGGGCUCGCUUGGUGCAGAUCGGGACCCGCCGCCGCCGCUGCCGGGGCCGGAUCCCGCCUUGCACCAAGUGAAUCGGAGCCG	This sequence is a predicted paralogue of the previously identified miR168 family [1].  It is predicted to target mRNAs coding for the ARGONAUTE protein. 	7
16114	MI0001116	osa-MIR168b	Oryza sativa miR168b stem-loop	UGGUCUUGUGAGGCUUGGUGCAGCUCGGGAACUGUUCUUGAUGGACUGGCAGGAACUCCAUGUCCACCACUGCCACUCCUGUGUUGUGGCAUUCCUCCUUGCCGUU	This sequence is a predicted paralogue of the previously identified miR168 family [1].  It is predicted to target mRNAs coding for the ARGONAUTE protein. 	7
16115	MI0001117	osa-MIR169b	Oryza sativa miR169b stem-loop	GAACGGAAUGCAGCCAAGGAUGACUUGCCGGUACGUGUAUGCAUGUUUCAAGGUACUAUAUGUGCCCCCAACUGUUUUAGAUCCAUGCUGACAUUUUCCGGCAAGUUGUCCUUGGCUACGUCUUGUUC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16116	MI0001118	osa-MIR169c	Oryza sativa miR169c stem-loop	GAACGGGAUGCAGCCAAGGAUGACUUGCCGGCUCCUGGUAUUGGGGGAAUCUCAGCUUUGCUGAAGCGCCUUGGAGUUAGCCGGCAAGUCUGUCCUUGGCUACACCUAGCUC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16117	MI0001119	osa-MIR169d	Oryza sativa miR169d stem-loop	AUUUAUCGUGUAGCCAAGGAUGAAUUGCCGGCGUUUCACGCUGUUGAUGGUGCGUGCAUAUAUAAGUUGGCGCCGGCAAGUCAUUUCAGGCUACAUGUUUGCC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16118	MI0001120	osa-MIR169e	Oryza sativa miR169e stem-loop	GCUGGUUGUGUAGCCAAGGAUGACUUGCCGGCCUGGUUUGUGUUCAUCAGCAAUCCAGCAUAUGCUGUAUUGCCGUGUGUGAUCGAUCGAUGCAUGGACCGGCAAGUUAUUUUCUUUGGCUACAUUACAACC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16119	MI0001121	osa-MIR169f	Oryza sativa miR169f stem-loop	GCUGAUUCGGUAGCCAAGGAUGACUUGCCUAAUGCCUAUGUGCAUGUGUUUAUACGCUGCUCAUCUGCAUUUUGAUUAUCCCCUGAUCAGUCCUGUCGUCAAUUAUAUGUGUGUGUAGUACUCUGUACUCAUACAUAUAUAGGCAUGUCUUCCUUGGCUAUUCGGAGCGG	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16120	MI0001122	osa-MIR169g	Oryza sativa miR169g stem-loop	CUGCCUCUGGUAGCCAAGGAUGACUUGCCUAUUGUGCUCUUCUGAAUGAUGCAGUGCCAUGAUCAGUGUGGCCUGGCUGGUUCAGAUGAGCCGAGAUAGGCAGUCUCCUUGGCUAGCCUGAGUGGC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16121	MI0001123	osa-MIR169h	Oryza sativa miR169h stem-loop	UUAGCUCUGGUAGCCAAGGAUGACUUGCCUGUGUCCUUGUGUGUAAGGAUCAUUAAUUAUUAUUCAGAAAAUGAUCCUUUCAGCAGGUUUCAUGGGCAGUCUCCUUGGCUAGCCUGAGUGAU	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16122	MI0001124	osa-MIR169i	Oryza sativa miR169i stem-loop	GUAGCUCUGGUAGCCAAGGAUGACUUGCCUGUGUCCUUGUGUAGAGGAUCAUUCAGAAAAUGAGCCUUGAACUGGUUCAUAGGCAGUCUCCUUGGCUAGUCUGAGUCG	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16123	MI0001125	osa-MIR169j	Oryza sativa miR169j stem-loop	UCGCAUCUGGUAGCCAAGGAUGACUUGCCUGUGUCUCUGCUCAUGUGCAGUAGAAGAAGAUGCAUUUCUAGCUGCUUUCUGCAUAUGUGAUCUCACAGGCAGUCUCCUUGGCUAGCCUGAGCGGC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16124	MI0001126	osa-MIR169k	Oryza sativa miR169k stem-loop	UCUGUCUAGAUAGCCAAGGAUGACUUGCCUGUGGCCUCUUGGAGAGAGAGGUGUAGCUUAAUUAGCAGCAUGGUUUGAGCAUUGCUUGAUCGGUUGAUCGCUUCGCUUGCUCUGCAUGAGAUCUUACAGGCAGUCUCCUUGGCUAGUCUGGGCGGC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16125	MI0001127	osa-MIR169l	Oryza sativa miR169l stem-loop	UUAUCUCUGAUAGCCAAGGAUGACUUGCCUGUGUCCUCCCUGAAGGAUUAGCAAUUUAAUGAUCCUUUAAGCUGGUUCAUGGGCAGUCUCCUUGGCUAGCCUGAGUGG	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16126	MI0001128	osa-MIR169m	Oryza sativa miR169m stem-loop	UGAGUCCUGGUAGCCAAGGAUGACUUGCCUGUAUAUUUAUAUAUAUAUGUGUGUGUGAUCAAUGGAUGGAUUGAUCAAGCUGCUUGCAGGCUCAUGCAUAUAUAUGUACAGGCAGUCUCCUUGGCUAGCCCGGCUACC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16127	MI0001129	osa-MIR169n	Oryza sativa miR169n stem-loop	CUCCCUUUGGUAGCCAAGAAUGACUUGCCUAUGUGUUUUGCCUUGUGUUGGCUCAUCCAUCCAUCUAUCAGCCGUUGCAGAUUUGCAGUGGCAGAUUAAAGGGUUUCAGAAAGAAAUUCUUGUGAUGGAUGUGCAAUGUGGCUGCAUGGGCCGGUCUUCUUGGCUAGCCAGAGUGGC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16128	MI0001130	osa-MIR169o	Oryza sativa miR169o stem-loop	CUCCCUUUGGUAGCCAAGAAUGACUUGCCUACGCUUUUGCCCUCUGUUGGCUCAUCCAUCCGUCUAUCUAUCUGCCAUGGCAGAUGGCAGAUUAAGGGUUUCUGAAAGAAAUUCUUGUGAUAGGAUGUGCAAUGAGGCUGCAUGGGCCGGUCUUCUUGGCUAGCCAGAGUGGC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16129	MI0001131	osa-MIR169p	Oryza sativa miR169p stem-loop	GAGCAAGGUGUAGCCAAGGACAAACUUGCCGGAUCAACAGAGAAGGACUGCCAGUCUCCGGCCAAUUAAUUAACCUCGCCGUCGGCCAUCGCCGGCCGGCAAGUCAUCCUUGGCUGCAUCCUGCUC	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16130	MI0001132	osa-MIR169q	Oryza sativa miR169q stem-loop	CCACUCAGGCUAGCCAAGGAGACUGCCCAUGAACCAGCUUAAAGGAUCAUUAAAUUGCUAAUCCUUCAGGGAGGACACAGGCAAGUCAUCCUUGGCUAUCAGAGAUAA	This sequence is a predicted paralogue of the previously identified miR169 family [1].  It is predicted to target mRNAs coding for the CCAAT Binding Factor (CBF) and HAP2-like transcription factors. 	7
16131	MI0001133	osa-MIR171b	Oryza sativa miR171b stem-loop	GCGACGACGGGAUAUUGGGGCGGUUCAAUCAGAAAGCUUGUGCUCCGGAAGCGAGGAGCUCUACUCUUUUGAUUGAGCCGUGCCAAUAUCACGUCGCAUC	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16132	MI0001134	osa-MIR171c	Oryza sativa miR171c stem-loop	GUGGGAACGGGAUAUUGGUGCGGUUCAAUCAGAAAGCUUGUGCUCCGAAGGCGAGGGGCUCCACUCUUUGAUUGAGCCGUGCCAAUAUCACGUCGCCUU	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16133	MI0001135	osa-MIR171d	Oryza sativa miR171d stem-loop	UUGUAGCUAUGAUGUUGGCCCGGCUCACUCAGAUGGAUCAUCGGUGCAGAAGAGUGCAUGAAUCUGAUGCAGUCUCAGUGUAGUAUGCUCCAUGCUGGAACUUCUGAUUGAGCCGUGCCAAUAUCUCAGCACCAU	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16134	MI0001136	osa-MIR171e	Oryza sativa miR171e stem-loop	UGGUAGCUAUGAUGUUGGCUCGGCUCACUCAGACGGCAUUGGCGUGAUGCAAAGCAUGCAUGCGUGCUUGCUAGCUCACUUGUGUUUCUGAUUGAGCCGUGCCAAUAUCUUAGUGCUCU	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16135	MI0001137	osa-MIR171f	Oryza sativa miR171f stem-loop	GGGAGAGUGCGAUGUUGGCAUGGUUCAAUCAAACCGGGCAAACUUAUGCACUAGCUAAGCAAGAUGCAGGGAUAUGCAGUAUGGUUUUGUUUGGUCUGAUUGAGCCGUGCCAAUAUCACAAGCUUGC	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16136	MI0001138	osa-MIR171g	Oryza sativa miR171g stem-loop	GACAUGGCAUGGUAUUGACUUGGCUCAUCUCAGCAACAGCAAACUGCAUGCAGCGCUGGAGGUGAGCCGAGCCAAUAUCACUUCAUGUC	This sequence is a predicted paralogue of the previously identified miR171 family [1].  It is predicted to target mRNAs coding for SCARECROW-like transcription factors. 	7
16137	MI0001139	osa-MIR172a	Oryza sativa miR172a stem-loop	GUGUUUGCGGGCGUGGCAUCAUCAAGAUUCACAUCCAUGCAUAUAUCACAAGACGCACAUAUACAUCCGAUUUGGCUGAGAAUCUUGAUGAUGCUGCAUCCGCAGACAA	This sequence is a predicted paralogue of the previously identified miR172 family [1].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	7
16138	MI0001140	osa-MIR172b	Oryza sativa miR172b stem-loop	GUGAUUUCUGACGUGGCAUCAUCAAGAUUCACACAUUACAUUGCAUGCAUGCAUAUGUCUAUGCAUCUUUGAGCUUGUUGUUCUGAUCUCAACAACCUAGCUAGCUAAUAUUUCUCUCCUGGCCCUGACCUGCAUGAUGCAUGGUUGCACGCAUGGAGAGAGAAGAGAGAGAUCGAAGCUAAUUAAACGCAUGUGUAUAUAUGUGUGGGAAUCUUGAUGAUGCUGCAUCGGAAAUUAA	This sequence is a predicted paralogue of the previously identified miR172 family [1].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	7
16139	MI0001141	osa-MIR172c	Oryza sativa miR172c stem-loop	CUUGUUGCGGGUGCAGCGUCAUCAAGAUUCACGUGUGCCGCACGGCACACGUAUCGGUUUUCAAGUGUAGUCAUCGUGCGUGAAUCUUGAUGAUGCUGCACCAGCAAAGAG	This sequence is a predicted paralogue of the previously identified miR172 family [1].  It is predicted to target mRNAs coding for APETALA2-like transcription factors. 	7
16140	MI0001142	osa-MIR166g	Oryza sativa miR166g stem-loop	AGCAUGGUGUCUGGAAUGGAGGCUGAUCCAAGAUCAUUGCUUGGUGCAAAAUACUAGGGCAUUGUUGUAAGUGCCAUUAGUUCUUUUUUGUUUCCGAGUUUGUUAUCGAGGAUCUCGGACCAGGCUUCAUUCCUCACACCGUGCU	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16141	MI0001143	osa-MIR166h	Oryza sativa miR166h stem-loop	GGUGGCUUGUGGGGAAUGUUGGCUGGCUCGAGGUAUCCACAUCUUAAUUCCUCUCCGGCGAUCGAGCCGGCUCGGGCGUGUGGAAGCGUCGGACCAGGCUUCAUUCCUCGCAAGCCGAU	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16142	MI0001144	osa-MIR166i	Oryza sativa miR166i stem-loop	AGAUAGGUGUUUGGAAUGCAGUUUGAUCCAAGAUCUGCCUAUAUAUAUGGUGUGUAUAUCAUAUCUUGUGAUAUGGGGGAUAUGCAACAGGUGUGUGACAGGGGUAGGUAGAUCUCGGAUCAGGCUUCAUUCCUCACACCAAUAC	This sequence is a predicted paralogue of the previously identified miR166 family [1].  It is predicted to target mRNAs coding for HD-Zip transcription factors. 	7
16143	MI0001145	hsa-mir-384	Homo sapiens miR-384 stem-loop	UGUUAAAUCAGGAAUUUUAAACAAUUCCUAGACAAUAUGUAUAAUGUUCAUAAGUCAUUCCUAGAAAUUGUUCAUAAUGCCUGUAACA		5
16144	MI0001146	mmu-mir-384	Mus musculus miR-384 stem-loop	UGUUAAAUCAGGAAUUGUAAACAAUUCCUAGGCAAUGUGUAUAAUGUUGGUAAGUCAUUCCUAGAAAUUGUUCACAAUGCCUGUAACA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
16145	MI0001147	osa-MIR171h	Oryza sativa miR171h stem-loop	AGAAGAAGAGGACAUGGUUUGGUAUUGUUUCGGCUCAUGUCGUUCACACAGAUGUGAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCAGAGAACUUCU		7
16146	MI0001148	osa-MIR393b	Oryza sativa miR393b stem-loop	UCGGCCUGAGGAAACUAGUGGAGGACUCCAAAGGGAUCGCAUUGAUCUGGCUAGCUAUCUCGAUCGAUCGCCUCAUCGAUCGACGACGACGUGCGUGAUCGAUCAGUGCAAUCCCUUUGGAAUUUUCCUCUU		7
16147	MI0001149	osa-MIR408	Oryza sativa miR408 stem-loop	GGGAGUUCUGUGAUUGGAGAGGAGAGGAGACAGGGAUGAGGCAGAGCAUGGGAUGGGGCUAUCAACAGAUGUAGAUUAUUCCUUGCACAAGAGAUGAUGAUGAGCUGUGAAUGAGUUCUGAGAGAUGGCUGGUGUUGUUGUUGCUCCCUCCCCUGCACUGCCUCUUCCCUGGCUCCCCUGCACACCUCUCUCUCUCUCUCUCUCUCUCUGUGU		7
16148	MI0001150	hsa-mir-196b	Homo sapiens miR-196b stem-loop	ACUGGUCGGUGAUUUAGGUAGUUUCCUGUUGUUGGGAUCCACCUUUCUCUCGACAGCACGACACUGCCUUCAUUACUUCAGUUG	miR-196b is predicted based on sequence homology to miR-196a [1].  Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196. Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
16149	MI0001151	mmu-mir-196b	Mus musculus miR-196b stem-loop	AACUGGUCGGUGAUUUAGGUAGUUUCCUGUUGUUGGGAUCCACCUUUCUCUCGACAGCACGACACUGCCUUCAUUACUUCAGUUG	miR-196b is predicted based on sequence homology to miR-196a [1].  Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196. Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [1].  Landgraf et al. confirm expression of miR-196b in mouse by cloning [2]. 	6
16150	MI0001152	rno-mir-196b	Rattus norvegicus miR-196b stem-loop	AACUGGUCGGUGAUUUAGGUAGUUUCCUGUUGUUGGGAUCCACCUUUCUCUCGACAGCACGACACUGCCUUCAUUACUUCAGUUG	miR-196b is predicted based on sequence homology to miR-196a [1].  Yekta et al. report that miR-196 miRNAs are expressed from HOX gene clusters in mammals, and that HOX genes in these clusters are targets of miR-196. Indeed, HOXB8 mRNA was shown to be a natural target for miR-196-directed cleavage through a perfectly complementary miR-target site.  Other HOX genes have imperfect miR-196 complementary sites indicative of regulation by translational repression [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
16151	MI0001154	osa-MIR172d	Oryza sativa miR172d stem-loop	AAACAGUCGGUGCUUGCAGGUGCAGCACCAUCAAGAUUCACAUCGAGUUCAUCCCUAAACGAGAUCGAGGUUGGCUGACUAUAUGUGAUGAGAAUCUUGAUGAUGCUGCAUCAGCAAACGCUCGACUACU		7
16152	MI0001155	osa-MIR171i	Oryza sativa miR171i stem-loop	UAAAAAGAGGUAUUGGCGUGCCUCAAUCCGAAGGCAUGGCUGAUUACAGGCACCUCGACCGAUCUAGCGCAUGCAGCCAUGUUUCUUGGAUUGAGCCGCGUCAAUAUCUCUCCUUGCUUC		7
16153	MI0001156	osa-MIR167j	Oryza sativa miR167j stem-loop	UUGUGAUGUGUGCACCUUAAGCAGCUGAAGCUGCCAGCAUGAUCUGAUCUUUUGCGAUCUCUUUUUUUAUCUGAAUAAGUUGAUGGAAAUAUUGGGUUCCUAAGAUUCAGAUCGUGCUGCGCAGUUUCAUCUGCUAAUCGAUGCACUACACUGUGAAUUU		7
16154	MI0001157	osa-MIR166m	Oryza sativa miR166m stem-loop	CUCUGCUUUGGUGGUUGGCUGAUGUUCUCGGUUAAGGGGUUUGUUGUCUGGUUCAAGGCCUCCUGCUGUCCUACAUCACAUUUUUUUUUCUUUGUUCUGAAUUUCUGAUGGAUGUGUGUGUGCAUGAUGCAUGGCUGGUGGUGACCUCGGACCAGGCUUCAUUCCCUUUAACCAGCAUUUGCGUUAAUACCAUCAGGCAU		7
16155	MI0001158	osa-MIR166n	Oryza sativa miR166n stem-loop	UGAUCCAUGGCUGUUGAGAGGAAUGACGUCCGGUCUGAAGAUCGCCGUCCCCAGGCGGUGGCUUCGGACCAGGCUUCAUUCCCCAUGACUCAUGGAACCC		7
16156	MI0001159	osa-MIR164f	Oryza sativa miR164f stem-loop	UGAGGAUGGCGAGGCGCGCGAGGUGGAGAAGCAGGGCACGUGCAUUCCUAGAGCUUCCGUCCAGCUCCCCGGCGGGCUAGCUAGCUCACUCCGCCGCCGCCGCCGCCGCCGCCGGCGCGCGCACGGCUGGCUGGCUCCGGCCGGCUGAGAUGCAUGCACGGAUGCAUGUGCCCUUCUUCUCCACCGUGCACGCCUCGCCUGCAGCAAGGA		7
16157	MI0001160	mmu-mir-409	Mus musculus miR-409 stem-loop	UGGUACUCGGAGAGAGGUUACCCGAGCAACUUUGCAUCUGGAGGACGAAUGUUGCUCGGUGAACCCCUUUUCGGUAUCA	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse, including the miR-409-5p [1].  The 3' end of miR-409-5p was not determined and is predicted based on a miRNA length of 23 nts.  Landgraf et al. later confirm expression of mature miRNAs from both arms of the hairpin [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
16158	MI0001161	mmu-mir-410	Mus musculus miR-410 stem-loop	GGGUACUUGAGGAGAGGUUGUCUGUGAUGAGUUCGCUUUAUUAAUGACGAAUAUAACACAGAUGGCCUGUUUUCAAUACCA	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
16159	MI0001162	mmu-mir-376b	Mus musculus miR-376b stem-loop	UGGUAUUUAAAAGGUGGAUAUUCCUUCUAUGGUUACGUGCUUCCUGGAUAAUCAUAGAGGAACAUCCACUUUUUCAGUAUCA	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [1].  The mature miR-376b products have been shown to be modified by A to I edits [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
16160	MI0001163	mmu-mir-411	Mus musculus miR-411 stem-loop	UGGUACUUGGAGAGAUAGUAGACCGUAUAGCGUACGCUUUAUCUGUGACGUAUGUAACACGGUCCACUAACCCUCAGUAUCA	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse, including the mature sequence from the 3' arm of this hairpin [1].  Landgraf et al. later showed that the 5' product is the predominant one [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
16161	MI0001164	mmu-mir-412	Mus musculus miR-412 stem-loop	GGGUAUGGGACGGAUGGUCGACCAGCUGGAAAGUAAUUGUUUCUAAUGUACUUCACCUGGUCCACUAGCCGUCGGUGCCC	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
16162	MI0001165	mmu-mir-370	Mus musculus miR-370 stem-loop	AGACGGAGAGACCAGGUCACGUCUCUGCAGUUACACAGCUCAUGAGUGCCUGCUGGGGUGGAACCUGGUUUGUCUGUCU	Seitz et al. predicted a cluster of 40 miRNAs in the imprinted human 14q32 domain, and confirmed the expression of a subset by Northern blot or primer extension in mouse [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
16163	MI0001166	gga-mir-29a	Gallus gallus miR-29a stem-loop	ACCCCUUUAGAGGAUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAAUAUUUUCUAGCACCAUUUGAAAUCGGUUAUAGUGAUUGGGGA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16164	MI0001167	gga-mir-29b-1	Gallus gallus miR-29b-1 stem-loop	CCUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAACUAUUCAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGAGG		10
16165	MI0001168	gga-let-7i	MI0001168 Gallus gallus let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUA		10
16166	MI0001169	gga-mir-135a-2	Gallus gallus miR-135a-2 stem-loop	AGAUAAAUUCACUCUAGUGUUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16167	MI0001170	gga-mir-33	Gallus gallus miR-33 stem-loop	CUGUAGUGCAUUGUAGUUGCAUUGCAUGUGCUGGCAGUAACUGUGCAAUGUUCCUGCAGUGCAGUACAG		10
16168	MI0001171	gga-let-7a-3	Gallus gallus let-7a-3 stem-loop	GGGUGAGGUAGUAGGUUGUAUAGUUUUAGGGUUAUGCCCUGCCUGUCAGAUAACUAUACAAUCUACUGUCUUUCCU		10
16169	MI0001172	gga-let-7b	Gallus gallus let-7b stem-loop	CAGGAUGAGGUAGUAGGUUGUGUGGUUUCAGGGUAGUGAUUUUGCCCCAAUCAGGAGAUAACUAUACAACCUACUGCCUUCCCUG		10
16170	MI0001173	gga-mir-99a	Gallus gallus miR-99a stem-loop	CCAAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGUUGAAAUGCACUGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUAUG		10
16171	MI0001174	gga-let-7c	Gallus gallus let-7c stem-loop	GCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGC		10
16172	MI0001175	gga-mir-125b	Gallus gallus miR-125b stem-loop	AUCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUUUUGUAGCAACAAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA		10
16173	MI0001176	gga-mir-155	Gallus gallus miR-155 stem-loop	UGUUAAUGCUAAUCGUGAUAGGGGUUUUUACCUCUGAAUGACUCCUACAUGUUAGCAUUAACA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16174	MI0001177	gga-mir-222	MI0001177 Gallus gallus miR-222 stem-loop	UGUAGUUGCCCAUCAAUCGCUCAGUAGUCAGUGUAGAUUCUGUCUUUACAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGACAUCUCAUAUCU		10
16175	MI0001178	gga-mir-221	MI0001178 Gallus gallus miR-221 stem-loop	GACUGUCCAGGUUUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUUGUUAAGCAACAGCUACAUUGUCUGCUGGGUUUCCAGCUGCCUGGAA		10
16176	MI0001179	gga-mir-92	MI0001179 Gallus gallus miR-92 stem-loop	CUUUCUACACAGGUUGGGAUCAGUUGCAAUGCUGUGCGUUUCUGUGGUAUUGCACUUGUCCCGGCCUGUUGAGGUUGG		10
16177	MI0001180	gga-mir-19b	MI0001180 Gallus gallus miR-19b stem-loop	CACUGUUCUCUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUAUGAUACUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGCAGUG		10
16178	MI0001181	gga-mir-20a	MI0001181 Gallus gallus miR-20a stem-loop	UGACAGCUCUUGUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUCACUAAUCUACUGCAUUAUAAGCACUUAAAGUACUGCUAGCUGUAGAACUACA		10
16179	MI0001182	gga-mir-19a	MI0001182 Gallus gallus miR-19a stem-loop	GCAGUCUUCUGUUAGUUUUGCAUAGUUGCACUACAGGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUG		10
16180	MI0001183	gga-mir-18a	MI0001183 Gallus gallus miR-18a stem-loop	GUGCUUUUUGUACUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCAUAAGAAGUUAUGUC		10
16181	MI0001184	gga-mir-17	MI0001184 Gallus gallus miR-17 stem-loop	GUCAGAGUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUAUAGAACCUACUGCAGUGAAGGCACUUGUAGCAUUAUGUUGAC		10
16182	MI0001185	gga-mir-16-1	Gallus gallus miR-16-1 stem-loop	GUCUGUCAUACUCUAGCAGCACGUAAAUAUUGGUGUUAAAACUGUAAAUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGCU		10
16183	MI0001186	gga-mir-15a	MI0001186 Gallus gallus miR-15a stem-loop	CCUUGGCAUAACGUAGCAGCACAUAAUGGUUUGUGGGUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG		10
16184	MI0001187	gga-mir-26a	MI0001187 Gallus gallus miR-26a stem-loop	GUCACCUGGUUCAAGUAAUCCAGGAUAGGCUGUAUCCAUUCCUGCUGGCCUAUUCUUGGUUACUUGCACUGGGAGGC		10
16185	MI0001188	gga-mir-153	Gallus gallus miR-153 stem-loop	AGCGGUUGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16186	MI0001189	gga-mir-148a	Gallus gallus miR-148a stem-loop	GAAGCAAAGUUCUGUGACACUCAGACUCUGGUUACGAUAGCAGUCAGUGCACUACAGAACUUUGUCUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16187	MI0001190	gga-mir-196-2	Gallus gallus miR-196-2 stem-loop	AACUGCUCUGUGGUUUAGGUAGUUUCAUGUUGUUGGGGCUCCACCUUUCUCUCUACAGCACGAAACUGCCUUAAUUACUUCAGUUGAUAUCAUC		10
16188	MI0001191	gga-mir-138-1	Gallus gallus miR-138-1 stem-loop	CCCUGCCGGGUGCCGUGCAGCAGCUGGUGUUGUGAAUCAGGCCGUCACCAGUCGGAGAACGGCUACUUCACAACACCAGGGUGGCACUGCACCACA		10
16189	MI0001192	gga-mir-128-2	Gallus gallus miR-128-2 stem-loop	UGUCCAGCUGGAAGGGGGGCCGUUACACUGUAAGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUUCCUGCUGUGUC		10
16190	MI0001193	gga-mir-187	Gallus gallus miR-187 stem-loop	AAACUAUUGUGAGACCUCCGGCUACAACACAGGACAUGGGAGCUUUUCUGAACCCUCGUGUCUUGUGUUGCAGCCAGAGGGGCACA		10
16191	MI0001194	gga-mir-32	Gallus gallus miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAGUGCAAUUUAGUGUGUGCGAUACUUUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16192	MI0001195	gga-mir-133a-1	Gallus gallus miR-133a-1 stem-loop	CAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16193	MI0001196	gga-mir-1a-2	Gallus gallus miR-1a-2 stem-loop	ACCUGCUCAGAGCACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUGGCAGGC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16194	MI0001197	gga-mir-124a	Gallus gallus miR-124a stem-loop	AGGCUCUGCCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAUCCUCCAGGCGGCAUU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16195	MI0001198	gga-mir-30d	MI0001198 Gallus gallus miR-30d stem-loop	GUUGCUGUAAACAUCCCCGACUGGAAGCUGUAGCAGCUUGAGCUUUCAGUCAGAUGUUUGCUGC		10
16196	MI0001199	gga-mir-30b	MI0001199 Gallus gallus miR-30b stem-loop	CUAACUUUUAGUUCCUGUAAACAUCCUACACUCAGCUAUAACAAGUGGUAGGGCUGGGGGGUGGAUGUUUACUUCAACUGACUUGGA		10
16197	MI0001200	gga-mir-216	Gallus gallus miR-216 stem-loop	GAUGGCUGUGAAUUGGCUUAAUCUCAGCUGGCAACUGUGAGCAGUUAAUAAUUCUCACAGUGGUAUCUGGGAUUAUGCUAAACACAGCAAUUUCUUUGCUCUAAUG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16198	MI0001201	gga-mir-217	Gallus gallus miR-217 stem-loop	AAAGUCACUGCAGAGUUCUUGAUGUCGCAGAUACUGCAUCAGGAACUGAUUGGAUAAUAAUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAAG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16199	MI0001202	gga-mir-194	Gallus gallus miR-194 stem-loop	UGGUGCUCUCAUAUGUAACAGCAACUCCAUGUGGACUACACUGACUUCCAGUGGAGAUGCUGUUACUUUUGAUAG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16200	MI0001203	gga-mir-215	Gallus gallus miR-215 stem-loop	UCAGUAAGAACUGGUGUCCAGGAAAAUGACCUAUGAAUUGACAGACUGCUUUCAAAAUGUGCCUGUCAUUUCUAUAGGCCAAUAUUCUGUGCACUUUUCCUACUU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16201	MI0001204	gga-mir-30a	MI0001204 Gallus gallus miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCAGCAGAUGGGGCUUUCAGUCGGAUGUUUGCAGCUGC		10
16202	MI0001205	gga-mir-30c-2	Gallus gallus miR-30c-2 stem-loop	AGGUACUGUAAACAUCCUACACUCUCAGCUGUGGAAACUAAGAAAGCUGGGAGAAGGCUGUUUACUCUCCCU		10
16203	MI0001206	gga-mir-133b	Gallus gallus miR-133b stem-loop	CUCUGCUCUGGCUGGUCAAACGGAACCAAGCCCGUCUUCUUCGGAGGUUUGGUCCCCUUCAACCAGCUAUAGCAGUGUUGAAAA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16204	MI0001207	gga-mir-206	Gallus gallus miR-206 stem-loop	GAGAUGACAUGCUUCUUUAUAUCCCCAUAUGGAUUAGGCUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCAGGGAG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16205	MI0001208	gga-mir-223	Gallus gallus miR-223 stem-loop	CUGCAGUGCAGCACUGCGUGUAUUUGACAAGCUGAGUUUGACACUCAGUCUGGCAGAGUGUCAGUUUGUCAAAUACCCCAAGUGAGGCACUUGCUGAGCA		10
16206	MI0001209	gga-mir-18b	MI0001209 Gallus gallus miR-18b stem-loop	CGUGGUCCUUGUGUUAAGGUGCAUCUAGUGCAGUUAGUGACGUAGCGUAGAAUCUACUGCCCUAAAUGCUCCUUCUGGCACAAG		10
16207	MI0001210	gga-mir-106	MI0001210 Gallus gallus miR-106 stem-loop	CCUUGAGUUGUGCAAAAGUGCUUACAGUGCAGGUAGAGCUCAGCACCUACUGCAGUAUAAGCACUUCUGGCAUGACCGUGG		10
16208	MI0001211	gga-mir-302a	Gallus gallus miR-302a stem-loop	CCACAACUUAAAUGUGGAUGUGCUUGCUUUGUUCUGAAAAGAAAGUGCUUCCAUGUUUUAGUGAUGG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16209	MI0001212	gga-mir-218-1	Gallus gallus miR-218-1 stem-loop	UGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGUGAGGUAUGAGUAAAACAUGGUUCUGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		10
16210	MI0001213	gga-mir-103-2	Gallus gallus miR-103-2 stem-loop	UCUCUGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUUGCGUUCAUGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACAGAG		10
16211	MI0001214	gga-mir-203	Gallus gallus miR-203 stem-loop	CUCAGCCUCCUUGGUGCAGUGGUUCUUAACAGUUCAACAGUUCUCUAUCAUAAUUGUGAAAUGUUUAGGACCACUUGACCAGCGAGGCCCGGGCAUCG		10
16212	MI0001215	gga-mir-107	Gallus gallus miR-107 stem-loop	CUCUUUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCAUGGA		10
16213	MI0001216	gga-mir-10b	Gallus gallus miR-10b stem-loop	CAGAACGUUAUUACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGAUAUUCAUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA		10
16214	MI0001217	gga-mir-128-1	Gallus gallus miR-128-1 stem-loop	UGAGCUGUUGAAUUCGGGGCCGUAACACUGUCUGAGAGGUUUAUAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC		10
16215	MI0001218	gga-mir-181a-1	Gallus gallus miR-181a stem-loop	UGUAGUGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUUAAGUGAAAACCAUCGACCGUUGAUUGUACCCUCCAGCUAACCAUCCUCCUCCU		10
16216	MI0001219	gga-mir-181b-1	Gallus gallus miR-181b-1 stem-loop	AAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUUAACUAUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCACAU		10
16217	MI0001220	gga-mir-199-2	Gallus gallus miR-199-2 stem-loop	GAAGCGUCCGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCUGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAAAGCA	Chicken has two loci predicted to express miR-199.  mir-199-2 (MIR:MI0001220) is homologous to mir-199a-2 in human (MIR:MI0000281) and mouse (MIR:MI0000713).  mir-199-1 (MIR:MI0001245) is homologous to mir-199b in human (MIR:MI0000282) and mouse (MIR:MI0000714).  The expression of chicken miR-199 has been verified experimentally [2]. 	10
16218	MI0001221	gga-mir-137	Gallus gallus miR-137 stem-loop	UCUGACUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGGAGAGUACCGGCGGC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16219	MI0001222	gga-mir-16-2	MI0001222 Gallus gallus miR-16-2 stem-loop	CCUACUUGUUCCGCCCUAGCAGCACGUAAAUAUUGGUGUAGUAAAAUAAACCUUAAACCCCAAUAUUAUUGUGCUGCUUAAGCGUGGCAGAGAU		10
16220	MI0001223	gga-mir-15b	MI0001223 Gallus gallus miR-15b stem-loop	UGAGGCCUUAAAGUACUCUAGCAGCACAUCAUGGUUUGCAUGCUGUAGUGAAGAUGCGAAUCAUUAUUUGCUGCUUUAGAAAUUUAAGGAA		10
16221	MI0001224	gga-mir-190	Gallus gallus miR-190 stem-loop	UGCAGGACUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCCUGCC		10
16222	MI0001225	gga-mir-204-2	Gallus gallus miR-204-2 stem-loop	CUACUGAGACUGUGUGACCUGUGGGCUUCCCUUUGUCAUCCUAUGCCUGGAGAUCACAGUGAGGCAGGGACAGCAAAGGGAUGCUCAGCUGUCGUCUCUUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16223	MI0001226	gga-mir-7-2	Gallus gallus miR-7-2 stem-loop	GGACGGCCGCGGUGCCCUCUGGAAGACUAGUGAUUUUGUUGUUGUAUGGCUCAUCCCACCACAACAAGUCACAGUCUGCCUUAGGGCGCACGGCCCCGC		10
16224	MI0001227	gga-mir-184	Gallus gallus miR-184 stem-loop	CCGCUCUCACCCCCUUAUCACUUUUCCAGCCCAGCUUCUUCGCUCUGACUGUUGGACGGAGAACUGAUAAGGGU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16225	MI0001228	gga-mir-138-2	Gallus gallus miR-138-2 stem-loop	GUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACGGCAAGCGCUUCCUACUAUCCGGCUAUUUCACUACACCAGGGUUGCAUCA		10
16226	MI0001229	gga-mir-140	MI0001229 Gallus gallus miR-140 stem-loop	UGCGUCUCUCCGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACGGGAUGCCGGGGC		10
16227	MI0001230	gga-let-7g	Gallus gallus let-7g stem-loop	AGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCC		10
16228	MI0001231	gga-mir-135a-1	Gallus gallus miR-135a-1 stem-loop	GCCUCACUGUCCUGUAUGGCUUUUUAUUCCUAUGUGAUUAUACAUCCCGCUUCAUAUAGGGAUUGAAGCCGUGCAAGGCGCUGGGGUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16229	MI0001232	gga-let-7d	Gallus gallus let-7d stem-loop	AUUGGGCUCCUAGGAAGAGGUAGUGGGUUGCAUAGUUUUAGGGCAGGGAUUUUGCUCACAAGGAGGUAACUAUACAACCUGCUGCCUUUCUUAGGGCUUUAUU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16230	MI0001233	gga-let-7f	Gallus gallus let-7f stem-loop	UCAGAGUGAGGUAGUAGAUUGUAUAGUUGUAGGGUAGUUAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGA		10
16231	MI0001234	gga-let-7a-1	Gallus gallus let-7a-1 stem-loop	UGCACUGUGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCAUACCCGCAACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUAAAG		10
16232	MI0001235	gga-mir-146a	Gallus gallus miR-146a stem-loop	GUGUAUCCUCAGCUUUGAGAACUGAAUUCCAUGGGUUGUAAUUGAAUCCUUUGUCAGACCCAUGGGGCUCAGUUCUUCAGCUUGGAUAUUUCUGUCUUC		10
16233	MI0001236	gga-mir-103-1	Gallus gallus miR-103-1 stem-loop	UGCUGCCUUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCACUG		10
16234	MI0001237	gga-mir-218-2	Gallus gallus miR-218-2 stem-loop	GGGGUUUUCCUUUGUGCUUGAUCUAACCAUGUGGUAGAACAAUACAAAUUGAACAUGGUUCUGUCAAGCACCAUGGAAGGCUGCAUACUCCCUGC		10
16235	MI0001238	gga-mir-205b	Gallus gallus miR-205b stem-loop	AUACACUACUAGGGCCUUCCUGAUGCCCUUCAUUCCACCGGAAUCUGUCAGUGCAGAAACCAGAUUUCAGUGAAAUGAAGCCCAUCAGAGAGGCAGCU		10
16236	MI0001239	gga-mir-130b	Gallus gallus miR-130b stem-loop	GGGCGGGCUGCCCCUCUUUCCCUGUUGCACUACUGUCACGGUCGCAGCGAGCAGUGCAAUAAUGAAAGGGCGUCAGU		10
16237	MI0001240	gga-mir-301	MI0001240 Gallus gallus miR-301 stem-loop	UGGCUGCUGGUAUCGCUGGCUCUGACAAUGUUGCACUACUGUCUGCACAAAUAAAGCAGUGCAAUAAUAUUGUCAAAGCAUUUGGUUCCAGUC		10
16238	MI0001241	gga-mir-130a	MI0001241 Gallus gallus miR-130a stem-loop	UGCUGUUGUCCAGAGCCCUUUUUCUGUUGUACUACUGGCAAUUAUGAUGAGCAGUGCAAUAUUAAAAGGGCAUUGGCUGGCAG		10
16239	MI0001242	gga-mir-181b-2	MI0001242 Gallus gallus miR-181b-2 stem-loop	CUAAUGGCUGCAAUCAACAUUCAUUGCUGUCGGUGGGUUUUCAUUGCUAUCAACUCACUGAUCAAUGAAUGCAAACUGCGGACCA		10
16240	MI0001243	gga-mir-181a-2	MI0001243 Gallus gallus mir-181a-2 stem-loop	GCCAUCUUUGGAUAGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGAGAACUAAGAAAAACCAUCGACCGUUGACUGUACCUUGAGGU		10
16241	MI0001244	gga-mir-126	Gallus gallus miR-126 stem-loop	GCUGGUGACGGCCCAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGCUGUGGUCAGCA		10
16242	MI0001245	gga-mir-199-1	Gallus gallus miR-199-1 stem-loop	CUCCACUCCGUCUGCCCAGUGUUCAGACUACCUGUUCAGGACUACGAGAUUGUACAGUAGUCUGCACAUUGGUUAGGCUGUGCUGGGAUACACC	Chicken has two loci predicted to express miR-199.  mir-199-2 (MIR:MI0001220) is homologous to mir-199a-2 in human (MIR:MI0000281) and mouse (MIR:MI0000713).  mir-199-1 (MIR:MI0001245) is homologous to mir-199b in human (MIR:MI0000282) and mouse (MIR:MI0000714).  The expression of chicken miR-199 has been verified experimentally [2]. 	10
16243	MI0001246	gga-mir-219	Gallus gallus miR-219 stem-loop	CUCUGCUCCUGAUUGUCCAAACGCAAUUCUUGUGCGCUGGAGCCGUACGAACCAAGAAUUGUGUCUGGACAUCUGUAGCAGAGAU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16244	MI0001247	gga-mir-1a-1	Gallus gallus miR-1a-1 stem-loop	UGAGAGACAUACUUCUUUAUAUGCCCAUAUGAACCUGGCAAUCUAUGGAAUGUAAAGAAGUAUGUAUUUCA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16245	MI0001248	gga-mir-133a-2	Gallus gallus miR-133a-2 stem-loop	GUGAGGCCAAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCAACUGUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGUGCAUUGAU	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16246	MI0001249	gga-mir-200a	Gallus gallus miR-200a stem-loop	GGUCCUCUGUGGGCAUCUUACUAGACAGUGCUGGAUUUCUUGGAUCUAUUCUAACACUGUCUGGUAACGAUGUUUAAAGGGUGAACC		10
16247	MI0001250	gga-mir-200b	Gallus gallus miR-200b stem-loop	GCCAUUACCAUCUUACUGGGCAGCAUUGGAUGUUCUCUGUUUUUCUAAUACUGCCUGGUAAUGAUGAUUGUGGUGUUUCGUGCAC		10
16248	MI0001251	gga-mir-34a	MI0001251 Gallus gallus miR-34a stem-loop	GCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUACACAUUGUUGGGCC		10
16249	MI0001252	gga-mir-124b-1	Gallus gallus miR-124b-1 stem-loop	AGCCCCAGCGUUUUGUGUUCACUGCAGACCUUGAUUUAAUGUCACACGAUUAAGGCACGCAGUGAAUGCCAAAGUUUGGGGCAGCCUGGGCUG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16250	MI0001253	gga-mir-124b-2	Gallus gallus miR-124b-2 stem-loop	AGCCCCAGCGUUUUGUGUUCACUGCAGACCUUGAUUUAAUGUCACACGAUUAAGGCACGCAGUGAAUGCCAAAGUUUGGGGCAGCCUGGGCUG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16251	MI0001254	gga-mir-1b	Gallus gallus miR-1b stem-loop	ACAUACUUCUUCAUAUGCCCAUAUGGAGUCGGCCGGCGUUAUGGAAUGUUAAGAAGUAUGUAUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16252	MI0001255	gga-mir-133c	Gallus gallus miR-133c stem-loop	UGCCUUCCUGGGGCUGGUAAAAAGGAACCAGAUCAACUACAACUGGAUUUGGUCCCCUUCAACCAGCUGCAGUGGGGCA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16253	MI0001256	gga-mir-30e	Gallus gallus miR-30e stem-loop	CGGGGCAGUCAUCGCUGCUGUAAACAUCCUUGACUGGAAGCUGUGAGGUGUCAGCGGGGGCUUUCAGUCGGAUGUUUACAGCUGCAGGCUGCUGCA		10
16254	MI0001257	gga-mir-30c-1	MI0001257 Gallus gallus miR-30c-1 stem-loop	ACCAUGCUGUAGCACGUGUAAACAUCCUACACUCUCAGCUGUGAACUCGAGGUGGCUGGGAGAGGAUUGUUUACGCCUUCUGCCAUGGA		10
16255	MI0001258	gga-mir-100	Gallus gallus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUCAUAUUCCACACAAGCUUGUAUCUAUAGGUAUGUGUCUGUCUGG		10
16256	MI0001259	gga-let-7a-2	MI0001259 Gallus gallus let-7a-2 stem-loop	AGGUUGAGGUAGUAGGUUGUAUAGUUUAGAAUUACACCAAGGGAGAUAACUGUACAACCUCCUAGCUUUCCU		10
16257	MI0001260	gga-mir-34b	Gallus gallus miR-34b stem-loop	GUGCUUGGUUUGCAGGCAGUGUAGUUAGCUGAUUGUACCCAGCGCCCCACAAUCACUAAAUUCACUGCCAUCAAAACAAGGCAC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16258	MI0001261	gga-mir-34c	Gallus gallus miR-34c stem-loop	AGCCUGGUUACCAGGCAGUGUAGUUAGCUGAUUGCCACCAGGACCAAUCACUAACCACACAGCCAGGUAAAAAG	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16259	MI0001262	gga-let-7j	Gallus gallus let-7j stem-loop	GUGAGGUAGUAGGUUGUAUAGUUUGGUGGGAGGGAUUCUGUCCCAUUUCAGGUGAUAACUAUACAGUCUAUUGCCUUCCUUAA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16260	MI0001263	gga-let-7k	Gallus gallus let-7k stem-loop	GGCUGAGGUAGUAGAUUGAAUAGUUGUGGAGUCCUAUCCUCCCUUUGAGCUAACUAUACAAUCUACUGUCUUUCCUAAGGAGA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16261	MI0001264	gga-mir-135a-3	Gallus gallus miR-135a-3 stem-loop	CCCUCUGCUGUGGUCUAUGGCUUUUUAUUCCUAUGUGAUUGCUUUUCCUAACUCAUGUAGGGCGAAAAGCCAUGGGCUACUCAGGGGAGGGACUCC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16262	MI0001265	gga-mir-29c	Gallus gallus miR-29c stem-loop	UCUCUUACACAGGCUGACCGAUUUCUCUUGGUGUUCAGAGUCUCAGUUUCUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA		10
16263	MI0001266	gga-mir-29b-2	MI0001266 Gallus gallus miR-29b-2 stem-loop	CCUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUCCCACUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUCUAGGAG		10
16264	MI0001267	gga-mir-205a	Gallus gallus miR-205a stem-loop	GACAAUCCAUGGGUUCUGUUGUCCUUCAUUCCACCGGAGUCUGUCUCGUACCUAACCAGAUUUCAGUGGAGUGAAGCACAAGAGACAUGGAGAUGA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16265	MI0001268	gga-mir-196-1	Gallus gallus miR-196-1 stem-loop	UGAACUAGAACUGCUCUGUGAAUUAGGUAGUUUCAUGUUGUUGGGCUUUAAAUUUUAAACACAAGAACAUCAAACUACCUGAUUUACUCCAGUUA		10
16266	MI0001269	gga-mir-7-3	Gallus gallus miR-7-3 stem-loop	CUGUGGUCUGGCUCUGUGUGGAAGACUAGUGAUUUUGUUGUUAUGAUUUAUAAAGGUGACAACAAAUCAUAGCCUGCCAUACAGCACAGAUCUUC		10
16267	MI0001270	gga-mir-101	MI0001270 Gallus gallus miR-101 stem-loop	ACUAUCCUUUUUCGGUUAUCAUGGUACCGGUGCUGUAUACGUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGU		10
16268	MI0001271	gga-mir-204-1	Gallus gallus miR-204-1 stem-loop	GUCAACAGUGUCUGUUCAUGUGACCCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAAAAUAUAUGAAGGGGGCGGGGAAGGCAAAGGGACGUUCAACUGUCAUC	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16269	MI0001272	gga-mir-7-1	MI0001272 Gallus gallus miR-7-1 stem-loop	UGGAUGUUGGUCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAAUUAAAUUGACAACAAAUCACAGUCUGCCAUAUGGCACAGAUCAUGCCUCUACAG		10
16270	MI0001273	gga-mir-23b	MI0001273 Gallus gallus miR-23b stem-loop	UGUUGUGGCUGUUUGGGUUCCUGGCAUGAUGAUUUGUGAGUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACAUAGCCAUGACC		10
16271	MI0001274	gga-mir-27b	MI0001274 Gallus gallus miR-27b stem-loop	ACCUCUCUGGUGAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGUUUCCCUCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGUG		10
16272	MI0001275	gga-mir-24	MI0001275 Gallus gallus miR-24 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUGAUUUUACAUACUGGCUCAGUUCAGCAGGAACAGGAG		10
16273	MI0001276	gga-mir-31	Gallus gallus miR-31 stem-loop	UUCUUUCAUGCAGAGCUGGAGGGGAGGCAAGAUGUUGGCAUAGCUGUUAACCUAAAAACCUGCUAUGCCAACAUAUUGUCAUCUUUCCUGUCUG		10
16274	MI0001277	gga-mir-122-1	Gallus gallus miR-122-1 stem-loop	CAGAGCUGUGGAGUGUGACAAUGGUGUUUGUGUCCAAUCUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGGUAG		10
16275	MI0001278	gga-mir-183	Gallus gallus miR-183 stem-loop	ACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGCAACCCCGCGGUCAGUGAAUUACCAUAGGGCCAUAAACAAAGCAGAGAAAGACCCGCGA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16276	MI0001279	gga-mir-7b	Gallus gallus miR-7b stem-loop	UGGACAUUGGUCUAGUUCUGUGUGGAAGACUAGUGAUUUUUGUUGUUUUUAGAUAACUAAAUUGACAACAAAUCACAGUCUACCAUAUGGCACAGACUAUGCCUCUACAG		10
16277	MI0001280	gga-mir-122-2	Gallus gallus miR-122-2 stem-loop	CAGAGCUAUGGAGUGUGACAAUGGUGUUUGUGUCCAAUCUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGGUAG		10
16278	MI0001281	gga-mir-142	MI0001281 Gallus gallus miR-142 stem-loop	GACAGUGCAGUCACCCAUAAAGUAGAAAGCACUACUAAACAGCACUGCAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUG		10
16279	MI0001282	gga-mir-196-3	Gallus gallus miR-196-3 stem-loop	UUUCAUGCAGCUGAUCUGUGGUUUAGGUAGUUUCAUGUUGUUGGGAUUGGCUUUUAGCUCGGCAACAAGAAACUGCCUUAAUUACGUCAGUUAGUCUUCAUCAAGGGC		10
16280	MI0001283	gga-mir-9-2	Gallus gallus miR-9-2 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	This sequence is a predicted homologue of a verified miRNA from human, mouse or rat.  Its expression has not been validated in chicken. 	10
16281	MI0001284	gga-mir-218-3	Gallus gallus miR-218-3 stem-loop	UGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGUGAGGUAUGAGUAAAACAUGGUUCUGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		10
16282	MI0001287	dps-bantam	Drosophila pseudoobscura bantam stem-loop	AUUUGACUACGAAACCGGUUUUCGAUUUGGUUUGACUGUUUUUUAUACAAGUGAGAUCAUUUUGAAAGCUGAUUUUGUCAA		11
16283	MI0001288	dps-let-7	Drosophila pseudoobscura let-7 stem-loop	UCUGGCAAAUUGAGGUAGUAGGUUGUAUAGUAGUACUUCAGAUCGUACUAUACAAUGUGCUAGCUUUCUUUGCUUGA		11
16284	MI0001289	dps-mir-1	Drosophila pseudoobscura miR-1 stem-loop	GCCUUUGAGAGUUCCAUGCUUCCUUGCAUUCAAUAGUAUAACAUAAAGCAUAUGGAAUGUAAAGAAGUAUGGAGCGAAAUCUGGCAAG		11
16285	MI0001290	dps-mir-2a-1	Drosophila pseudoobscura miR-2a-1 stem-loop	GCUGGGCUCACAAAGUGGUUGUGAAAUGCAUUUUGCUUUGCCCGCAUAUCACAGCCAGCUUUGAUGAGCUCGGC		11
16286	MI0001291	dps-mir-2a-2	Drosophila pseudoobscura miR-2a-2 stem-loop	AUCUAAGCCUCAUCAAGUGGUUGUGAUAUGGAUACCCAACGCAUAUCACAGCCAGCUUUGAUGAGCUAGGAU		11
16287	MI0001292	dps-mir-2b-1	Drosophila pseudoobscura miR-2b-1 stem-loop	CUGCGACGCUCUUUAAAGUGGCGGUGACGUGUUGGUAAUAAUAUUCAUAUCACAGCCAGCUUUGAGGAGCGUUGCGG		11
16288	MI0001293	dps-mir-2b-2	Drosophila pseudoobscura miR-2b-2 stem-loop	UUGUGUCAUUCUUCAAAGUGGUUGUGAAAUGUUUGCCUUUUUAUGCCUAUUCAUAUCACAGCCAGCUUUGAGGAGCGACACGA		11
16289	MI0001294	dps-mir-2c	Drosophila pseudoobscura miR-2c stem-loop	UGGUAUCCUUACUUUCAGUGUCAUCAAAAAUGGCUGAAGAAAGAUAUAUUUGCAUUUGAAGCGUAUCACAGCCAGCUUUGAUGGGCAUUGCAAUGAGCAUCGA		11
16290	MI0001295	dps-mir-3	Drosophila pseudoobscura miR-3 stem-loop	GAUCCUGGGAUGCAUUUUGUGCAGUUAUGUCUACGUGAUCAUCCUCAUCACUGGGCAAAGUGUGUCUCAGGAU		11
16291	MI0001296	dps-mir-4	Drosophila pseudoobscura miR-4 stem-loop	UUGCAAUUAGUUUCUUUGGUCGUCCAGCCUUAGGUGAUUUCUCUGAUCAUAAAGCUAGACAACCAUUGAAGUUCGUUGUGG		11
16292	MI0001297	dps-mir-iab-4	Drosophila pseudoobscura miR-iab-4 stem-loop	UCGUAUACGUAUACUGAAUGUAUCCUGAGUGUAUCCUAUCCGGUAUACCUUCAGUAUACGUAACACGA		11
16293	MI0001298	dps-mir-5	Drosophila pseudoobscura miR-5 stem-loop	GCUAAAAGGAACGAUCGUUGUGAUAUGCGUUAAUUCACCGUUACAUAUCACAGUGAUUUUCCUUUAUAGCGC		11
16294	MI0001299	dps-mir-6-1	Drosophila pseudoobscura miR-6-1 stem-loop	UUUGAAGUAGAGAGAAUAGUUGCUGUGCUAUAUGUCCUUCGACUCUAUAUAUCACAGUGGCUGUUCUUUUUGUACCUAAA		11
16295	MI0001300	dps-mir-6-3	Drosophila pseudoobscura miR-6-3 stem-loop	CAAAAAGAAGGGAACGGUUGCUGCUGAUGUAGUUCAAGUUUUGCACAAUUUAUAUCACAGUGGCUGUUCUUUUUUGUUUG		11
16296	MI0001301	dps-mir-6-2	Drosophila pseudoobscura miR-6-2 stem-loop	CCAACCGCAGGGAACCGCUGCUGCUGAUAUAUUAUCCACCCAUCUUUGACAUUUCUAUAUCACAGUGGCUGUUCUUUUUGGUU		11
16297	MI0001302	dps-mir-7	Drosophila pseudoobscura miR-7 stem-loop	GAGUGUAUUCCGUAUGGAAGACUAGUGAUUUUGUUGUUUGGUCUCUGCUAAUAACAAUAAAUCCCUUGUCUUCUUACGGCGUGCAUCU		11
16298	MI0001303	dps-mir-8	Drosophila pseudoobscura miR-8 stem-loop	AAGGACAUCUGUUCACAUCUUACCGGGCAGCAUUAGAUCCUUUAGAUACCUCUAAUACUGUCAGGUAAAGAUGUCGUCCGUGUCCUU		11
16299	MI0001304	dps-mir-9a	Drosophila pseudoobscura miR-9a stem-loop	GCUAUGUUGUCUUUGGUUAUCUAGCUGUAUGAGUGAUAAAUAACGUCAUAAAGCUAGCUUACCGAAGUUAAUAUUAGC		11
16300	MI0001305	dps-mir-9b	Drosophila pseudoobscura miR-9b stem-loop	UGCACAUUAUUUGAUCUUUGGUGAUUUUAGCUGUAUGGUGUAUAUCAAAGAUCCAUAGAGCUUUAUCACCAAAACCCAAAUGGUUUUUGCA		11
16301	MI0001306	dps-mir-9c	Drosophila pseudoobscura miR-9c stem-loop	AUUUUUGCUGUUUCUUUGGUAUUCUAGCUGUAGAUUGUUUUUUGCACAUUGUAUAUCAUCUAAAGCUUUUAUACCAAAGCUCCAGCUUAAAU		11
16302	MI0001307	dps-mir-10	Drosophila pseudoobscura miR-10 stem-loop	CCACGUCUACCCUGUAGAUCCGAAUUUGUUUUACAUUAGCUUUAAGGACAAAUUCGGUUCUAGAGAGGUUUGUGUGG		11
16303	MI0001308	dps-mir-11	Drosophila pseudoobscura miR-11 stem-loop	CUCUUGUCAAGAACUUAUUCUGUGACCUGCGUGACAUUUAGCCACAUCACAGUCUGAGUUCUUGCUGAGCG		11
16304	MI0001309	dps-mir-12	Drosophila pseudoobscura miR-12 stem-loop	UACGGCUGAGUAUUACAUCAGGUACUGGUGUGCUUUAAAUCCAACAACCAGUACUUAUGUUAUACUACGCCGUG		11
16305	MI0001310	dps-mir-13a	Drosophila pseudoobscura miR-13a stem-loop	UACGUAACCCAUCAAACGGUUGUGAAAUGUUGCAUUUAUCAAAUCAUAUCACAGCCAUUUUGAUGAGUUUCGUG		11
16306	MI0001311	dps-mir-13b-1	Drosophila pseudoobscura miR-13b-1 stem-loop	CCAUGUCGUUAAAAUGUUUGUGACCUUAUGUACUCUUGAAUCAUAUCACAGCCAUUUUGACGAGUUUGG		11
16307	MI0001312	dps-mir-13b-2	Drosophila pseudoobscura miR-13b-2 stem-loop	AUUUACGCGUCAAAAUGACUGUGAGCUAUGUGUUUUUGAUCUCAUAUCACAGCCAUUUUGACGAGUUUG		11
16308	MI0001313	dps-mir-14	Drosophila pseudoobscura miR-14 stem-loop	UGUGGGAGCGAGACGGGGACUCACUGUGCUUUUGAAGUAGUCAGUCUUUUUCUCUCUCCUAUA		11
16309	MI0001314	dps-mir-31a	Drosophila pseudoobscura miR-31a stem-loop	UCUGUUGGUAAAUUGGCAAGAUGUCGGCAUAGCUGAAGUUGAAAAGCGAUCUUUGAGAACGCUAUGCUGCAUCUAGUCAGUUAUUCAAUGGA		11
16310	MI0001315	dps-mir-31b	Drosophila pseudoobscura miR-31b stem-loop	AAUUUGGCAAGAUGUCGGAAUAGCUGAGAGCAAAAAGAAGAUGAUUUGAAAUGCGGCUAUGCCUCAUCUAGUCAAUUGCAUUCAUUUGA		11
16311	MI0001316	dps-mir-33	Drosophila pseudoobscura miR-33 stem-loop	CCGGAGAUGACACGCAGGUGCAUUGUAGUCGCAUUGUCUGUCCAUCUUGAUUUCAGGCAAUACAACUGCAAUGCAAGCUCUGUGCAUUUCA		11
16312	MI0001317	dps-mir-34	Drosophila pseudoobscura miR-34 stem-loop	AAUUGGCUAUGCGCUUUGGCAGUGUGGUUAGCUGGUUGUGUAGCCAAAAUAUUGCCUUUGACCAUUCACAGCCACUAUCUUCACUGCCGCCGCGACAAGC		11
16313	MI0001318	dps-mir-79	Drosophila pseudoobscura miR-79 stem-loop	CUGCUCUGCUUCUGCUUUGGCGCUUUAGCUGUAUGAUAGAUUUAAAAUACUUCAUAAAGCUAGAUUACCAAAGCAUUGGCUCUG		11
16314	MI0001319	dps-mir-87	Drosophila pseudoobscura miR-87 stem-loop	CAUAUUUCAUUCGCGCCUGUAUCUUGCUGAACCGUAGCCAUAAUGGUCUUUCAUCCCGGUUGAGCAAAAUUUCAGGUGUGUGAGAAAUUUGUUAAGCA		11
16315	MI0001320	dps-mir-92a	Drosophila pseudoobscura miR-92a stem-loop	AUAGAGAUUGCCCGUAGGACGGGAAGGUGUCAACGUUUUAAAUUUUGAACAAACAUUGCACUUGUCCCGGCCUAUGGGCGGCUUGUCAUACACA		11
16316	MI0001321	dps-mir-92b	Drosophila pseudoobscura miR-92b stem-loop	UAAAACGUCACCUGAUGUAGGCCGUGCCCAGUGCUUAUUUGUCGUUGUUUGAAAAUACAAAUUGCACUAGUCCCGGCCUGCAGAGAGUGUCGCACACAAC		11
16317	MI0001322	dps-mir-100	Drosophila pseudoobscura miR-100 stem-loop	CCAUUAACAGAAACCCGUAAUUCCGAACUUGUGCUGUUUUAUAUCUGUUACAAGACCGGCAUUAUGGGAGUCUGUCAAUGCAAACAACUGGUUUUUGGCA		11
16318	MI0001323	dps-mir-124	Drosophila pseudoobscura miR-124 stem-loop	UCGUUUGGUACGUUUUUCUCCUGGUAUCCACUGUAGGCCUAUAUGUAUUUCGACCAUAAGGCACGCGGUGAAUGCCAAGAGCGGACGAAACUCUACUA		11
16319	MI0001324	dps-mir-125	Drosophila pseudoobscura miR-125 stem-loop	GACAUGUGCAAAUGUUUGUAUGGCUGAUUCCCUGAGACCCUAACUUGUGACUUUUAAUACCAGUUUCACAAGUUUUGAUCUCCGGUAUUGGACGCAAACUUGCUGAUGUU		11
16320	MI0001325	dps-mir-133	Drosophila pseudoobscura miR-133 stem-loop	UACAACGGCUGUAUGUAGCUGGUUGACAUCGGGUCAGAUCUAUUUUAUCAAGUAUUUGGUCCCCUUCAACCAGCUGUAUCAGUGGUUGAUUCCAAC		11
16321	MI0001326	dps-mir-184	Drosophila pseudoobscura miR-184 stem-loop	GGUCGACCGGUGCAUUCGUACCCUUAUCAUUCUCGCGCCCCGUGUGCAUUAAAAGACAACUGGACGGAGAACUGAUAAGGGCUCGUAUCACCAACUCAUC		11
16322	MI0001327	dps-mir-210	Drosophila pseudoobscura miR-210 stem-loop	GGUACUUAUUGCAGCUGCUGGCCACUGCACAAGAUUAGAUUUAAGACUCUUGUGCGUGUGACAGCGGCUAUUGUAAGAGGCCAUAUUAGCAUCA		11
16323	MI0001328	dps-mir-219	Drosophila pseudoobscura miR-219 stem-loop	UAAUUCGAUUUUUAGCUAUGAUUGUCCAAACGCAAUUCUUGUUGAUAUCCAAUACUCAAGGGUUGUGACUGGACAUCGCGGCUCGAAAUAAGAAUACAAC		11
16324	MI0001329	dps-mir-263a	Drosophila pseudoobscura miR-263a stem-loop	ACAUCCCGGCACAGUUAAUGGCACUGGAAGAAUUCACGGGGUUUUUCAAUACAACCCGUGAUCUCUUAGUGGCAUCUAUGGUGCGGGACUCA		11
16325	MI0001330	dps-mir-263b	Drosophila pseudoobscura miR-263b stem-loop	UUGCUGGCAUUGGCUCUUGGCACUGGGAGAAUUCACAGUUGGUUUCCAUAUAUUCUGUGGUUCUGCGGGUGCCAAAAUCGAAUGUUCGGCU		11
16326	MI0001331	dps-mir-274	Drosophila pseudoobscura miR-274 stem-loop	UCCCGUGCUGCAGUUUCAUUUUGUGACCGACACUAACGGGUAAUGGCUGGCCGCAGGACUACUCGUUUUUGCGAUCACAAUACUGAAAUUGCAGCAA		11
16327	MI0001332	dps-mir-275	Drosophila pseudoobscura miR-275 stem-loop	AAAGUCUCCUACCAUGCGCGCUAAUCAGAGACCGGGGCUGGUUUUUUCACUGCAGUCAGGUACCUGAAGUAGCGCGCGUGGUGCUAGACA		11
16328	MI0001333	dps-mir-276a	Drosophila pseudoobscura miR-276a stem-loop	CCUGGUUUUUGCCAUCAGCGAGGUAUAGAGUUCCUACGUUCAUAUUAUAAACUCGUAGGAACUUCAUACCGUGCUCUUGGAAGACCAAAAGACAACGAA		11
16329	MI0001334	dps-mir-276b	Drosophila pseudoobscura miR-276b stem-loop	AAAGCGAAGCCUCUUUACCAUCAGCGAGGUAUAGAGUUCCUACGUGCCGUAUCCAAAGUCGUAGGAACUUAAUACCGUGCUCUUGGAGGGCUGUCCAUC		11
16330	MI0001335	dps-mir-277	Drosophila pseudoobscura miR-277 stem-loop	UUGAAGGUUUUGGGUUGCGUGUCAGGAGUGCAUUUGCACUGAAACAUUCUGAAGCUUGUAAAUGCACUAUCUGGUACGACAUUCCAGAACGUACAAUCUU		11
16331	MI0001336	dps-mir-278	Drosophila pseudoobscura miR-278 stem-loop	GUAAUGGUACGGUGCGACCGGACGAUGGUUCACAACGACCGUGUCUCUUAAACUGGUCGGUGGGACUUUCGUCCGUUUGUAACGCCAUUUGUCAGCGA		11
16332	MI0001337	dps-mir-279	Drosophila pseudoobscura miR-279 stem-loop	UCAUACUACUGUUUUUAGUGAGUGAGGGUCCAGUGUUUCACAUUGAUUUUCUUAGUAUUUGUGACUAGAUCCACACUCAUUAAUAACGGUAGUUC		11
16333	MI0001338	dps-mir-280	Drosophila pseudoobscura miR-280 stem-loop	GGCUUUUAUGUAUUUACGUUGCAUAUGAAAUGAUAUUUAUAGUAAACAGAUUAUUUUAUAUGCAGGUAUGUGCAGCUGAAGAGCCUGUCCAUUG		11
16334	MI0001339	dps-mir-281-1	Drosophila pseudoobscura miR-281-1 stem-loop	CGAAUAGGUGAAUAAAGAGAGCUGUCCGUCGACAGUCAACGUACCAAUUUAAUACUGUCAUGGAAUUGCUCUCUUUGUAUAAUAUUCG		11
16335	MI0001340	dps-mir-281-2	Drosophila pseudoobscura miR-281-2 stem-loop	CGAAUAGUGAAAUAAAGAGAGCUAUCCGUCGACAGUCAAGUUAAUCAGAUUGUAAUACUGUCAUGGAAUUGCUCUCUUUGUAUAAUAUUCG		11
16336	MI0001341	dps-mir-282	Drosophila pseudoobscura miR-282 stem-loop	UGCCUUAUAAAUCUAGCCUCUACUAGGCUUUGUCUGUGCAUUUGAAAACCCGAUCAGACAUAGCCUAUAAGAGGUUAGGUGUACCAAGGAAGAA		11
16337	MI0001342	dps-mir-283	Drosophila pseudoobscura miR-283 stem-loop	CUCACGAUUCUCAAAGGUAAAUAUCAGCUGGUAAUUCUGGGAGCUAAGCAAGAUAUGAAACACUCGGAAUUUCAGUUGGUAUCGACUUUUUUGAAUU		11
16338	MI0001343	dps-mir-284	Drosophila pseudoobscura miR-284 stem-loop	GUUGCAGUUCCUGGAAUUAAGUUGACUGUGUAGCCUGGGAAGGCAAGGCUUGAGCACUGCUUCUGAAGUCAGCAACUUGAUUCCAGCAAUUGCGGCCCAA		11
16339	MI0001344	dps-mir-285	Drosophila pseudoobscura miR-285 stem-loop	UCGAAUCGAAGAACUGAGAUCGAUUGGUGCAUAGAUAUCAAGAGGACUCGCUAAUUUUCAACUCUAGCACCAUUCGAAAUCAGUGCUUUUGAUGAGAACC		11
16340	MI0001345	dps-mir-286	Drosophila pseudoobscura miR-286 stem-loop	UUAAAAUUAAAUGGCGAUUGUCGGUUUGGUCGCUUUUUACCAGGGUUCCGAUCAAGCGAAGUGACUAGACCGAACACUCGUGCUAUAAUUUUAGAAU		11
16341	MI0001346	dps-mir-287	Drosophila pseudoobscura miR-287 stem-loop	AUGUGUGAGUGUGGGGCCUGAAAUUUUGCACACAUUUACAAUAAUUGUAAAUGUGUUGAAAAUCGUUUGCACAACUGUGA		11
16342	MI0001347	dps-mir-288	Drosophila pseudoobscura miR-288 stem-loop	GGCCAUGUCGUAAUUAGCAGGGUACAGCGUUGCCGGCGAUAAUUAAUGACGUUGGUCACGUUGGUUUCAUGUCGAUUUCAUUUCAUGACACGGCCG		11
16343	MI0001348	dps-mir-289	Drosophila pseudoobscura miR-289 stem-loop	GAGUUUACAGUGAAAUAAAUAUUUAAGUGGAGCCUGCGACUGGGACUCCAGCUCUCCGACUGGGCUAACUCACUUGAGCGUUUGUUGGCACGUAAAAGAC		11
16344	MI0001349	dps-mir-304	Drosophila pseudoobscura miR-304 stem-loop	GCAGCAUUGAAUAAUCUCAAUUUGUAAAUGUGAGCGAUUUGAGGCAUUUGACACACUCACUUUGCAACUGGAGAUUGCUCGAAACUGC		11
16345	MI0001350	dps-mir-305	Drosophila pseudoobscura miR-305 stem-loop	CAUGUCUAUUGUACUUCAUCAGGUGCUCUGGUGUGUCCUGUAACCCGGCACAUGUUGAAGUACACUCAAUAUG		11
16346	MI0001351	dps-mir-306	Drosophila pseudoobscura miR-306 stem-loop	CACUUUGCCGGCUCAGGUACUUAGUGACUCUCAAUGCUUUCGACAUCUUGAGAGUCUCUCUGUGCCUGCACUGGCGGUGG		11
16347	MI0001352	dps-mir-307	Drosophila pseudoobscura miR-307 stem-loop	UGUCUUGCUUUGACUCACUCAACCUGGGUGUGAUGUUAUUUCGAUAUGGUAUCCAUCACAACCUCCUUGAGUGAGCGAUAGCAGGAUA		11
16348	MI0001353	dps-mir-308	Drosophila pseudoobscura miR-308 stem-loop	CUCGCAGUAUAUUUUUGUGUUUUGUUGUGUCUGAAACGCAAAUCACAGGAUUAUACUGUGAG		11
16349	MI0001354	dps-mir-309	Drosophila pseudoobscura miR-309 stem-loop	AUUAUACGAUAAACUUUGUUCAGUUUUGCCAACUUGCUUGCAGCACUGGGUGAAGUUUGUCUUAUAAU		11
16350	MI0001355	dps-mir-314	Drosophila pseudoobscura miR-314 stem-loop	UCGUAACUUGUGUGGCUUCGAAUGUACCUAGUUGAGGAAAACUCCGAAAUGGAUUUUGUUACCUCUGGUAUUCGAGCCAAUAAGUUCGG		11
16351	MI0001356	dps-mir-315	Drosophila pseudoobscura miR-315 stem-loop	CACUUAUCUAUUUUUGAUUGUUGCUCAGAAAGCCCUUAUAAUUAACCAGUUGGCUUUCGAGCAAUUAUCAAAGCCAAAUAAGUG		11
16352	MI0001357	dps-mir-316	Drosophila pseudoobscura miR-316 stem-loop	AAAUUCUAGUCGAUUUGUCUUUUUCCGCUUACUGGCGUUUUAUUCGAUCAACGACAGGAAAGGGAAAAAGGCGUAUUUACUAUGAGUUU		11
16353	MI0001358	dps-mir-317	Drosophila pseudoobscura miR-317 stem-loop	UGCAACUGCCGUUGGGAUACACCCUGUGCUCGCUUUGAAUAUGGUGCAAGCAAGUGAACACAGCUGGUGGUAUCCAAUGGCCGUUCUGCA		11
16354	MI0001359	dps-mir-318	Drosophila pseudoobscura miR-318 stem-loop	UUUAUGGGAUGCACCAAGUUCAGUUUUGUCACAUUUCGAGCAUCACUGGGCUUUGUUUAUCUCAUAAG		11
16355	MI0001360	dre-mir-7b	Danio rerio miR-7b stem-loop	UGAACGCUGGCUUGCUUCUGUGUGGAAGACUUGUGAUUUUGUUGUUGUUAGUUAGAUGAAGUGACAACAAAUCACGGUCUGCCCUACAGCACAGGCCCAGCAUC		12
16356	MI0001361	dre-mir-7a-1	Danio rerio miR-7a-1 stem-loop	UGUGGAAGACUAGUGAUUUUGUUGUUGUUUCUUCUGCUUUCUGACAACAAGUCACAGUCUACCUCAGCGAGCGGGCCCU		12
16357	MI0001362	dre-mir-7a-2	Danio rerio miR-7a-2 stem-loop	UUUUGGGCAUUAUGGAAGACUAGUGAUUUUGUUGUUGUGACGUCAUCAGUACUGACAACAAGUCACAGUCUGCCUCAGUGACCAGAAUCCACUCGUC		12
16358	MI0001363	dre-mir-10a	Danio rerio miR-10a stem-loop	UGUCUGUCAUCUAUAUAUACCCUGUAGAUCCGAAUUUGUGUGAAUAUACAGUCGCAAAUUCGUGUCUUGGGGAAUAUGUAGUUGACAUAAACACAACGC		12
16359	MI0001364	dre-mir-10b-1	Danio rerio miR-10b-1 stem-loop	GUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGAAAAAAUAACAUUCACAGAUUCGAUUCUAGGGGAGUAUAUGGUC	The miR-10b sequence described in [1] is offset by 2 nt with respect to that cloned in mouse (MIR:MI0000221). 	12
16360	MI0001365	dre-mir-34	Danio rerio miR-34 stem-loop	CUGCUGUGAGUGGUUCUCUGGCAGUGUCUUAGCUGGUUGUUGUGUGGAGUGAGAACGAAGCAAUCAGCAAGUAUACUGCCGCAGAAACUCGUCACCUU		12
16361	MI0001366	dre-mir-181b-1	Danio rerio miR-181b-1 stem-loop	CAUGUACGCACCUUCAGUUCUUCAAAGGUCAUAAUCAACAUUCAUUGCUGUCGGUGGGUUUAGUCUUGUAACAGCUCUCUGAACAAUGAAUGUAACUGUGGCCCAGAUU		12
16362	MI0001367	dre-mir-181b-2	Danio rerio miR-181b-2 stem-loop	CUAAUGACUGCAAUAAACAUUCAUUGCUGUCGGUGGGUUUCUAAUAGACACAACUCACUGAUCAAUGAAUGCAAACUGCGGUGCAA		12
16363	MI0001368	dre-mir-182	Danio rerio miR-182 stem-loop	GUAUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAGUCAGAUCCGGUGGUUCUAGACUUGCCAACUA		12
16364	MI0001369	dre-mir-183	Danio rerio miR-183 stem-loop	GACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAAAGCACACUAUCAGUGAAUUACCAAAGGGCCAUAAACAGAGCAGAGAAAGAACCACG		12
16365	MI0001370	dre-mir-187	Danio rerio miR-187 stem-loop	UGACCUGUGGCUGGGCCAGGGGCUGCAACACAGGACAUGGGAGCUGUCUCUCACUCCCGCUCGUGUCUUGUGUUGCAGCCAGUGGAACG		12
16366	MI0001371	dre-mir-192	Danio rerio miR-192 stem-loop	CUAGGACACAGGGUGAUGACCUAUGAAUUGACAGCCAGUGUUUGCAGUCCAGCUGCCUGUCAGUUCUGUAGGCCACUGCCCUGUU		12
16367	MI0001372	dre-mir-196a-1	Danio rerio miR-196a-1 stem-loop	CGCGCGGCUGGUGCGUGGUUUAGGUAGUUUCAUGUUGUUGGGAUUGGCUUCCUGGCUCGACAACAAGAAACUGCCUUGAUUACGUCAGUUCGUCUUCAUCAAGGGC		12
16368	MI0001373	dre-mir-199-1	Danio rerio miR-199-1 stem-loop	UCCUGCUCCGUCAUCCCAGUGUUCAGACUACCUGUUCAGGAUCAUACUGGUGUACAGUAGUCUGCACAUUGGUUAGACUGUGCAUGG		12
16369	MI0001374	dre-mir-199-2	Danio rerio miR-199-2 stem-loop	GGAGUUUUUGUGGACGCCCGUCCCGCCUGCCCAGUGUUCAGACUACCUGUUCAGGAAUUAGUGUUUGUACAGUAGUCUGCACAUUGGUUAGGCUGG		12
16370	MI0001375	dre-mir-199-3	Danio rerio miR-199-3 stem-loop	CCUCCCCCUCGCCUGCCCAGUGUUCAGACUACCUGUUCAUCAUGCUGCAGCUGAACAGUAGUCCGCACAUUGGUUAGGCUGGGCUGGGACACACACAC		12
16371	MI0001376	dre-mir-203a	Danio rerio miR-203a stem-loop	GUGUUUGGGUCUCUUCUGGUCCCUCUGGUGCAGUGGUUCUUAACAGUUCAACAGUUCUAUCUCAAAAUUGUGAAAUGUUUAGGACCACUUGACCAG		12
16372	MI0001377	dre-mir-204-1	Danio rerio miR-204-1 stem-loop	UCAUGUGACCUGUGGACUUCCCUUUGUCAUCCUAUGCCUGGAGUAAUAGAGGGGGCUGGGAAGUCAAAGGGACGCUCAGGCGUCAUCAUUCGC		12
16373	MI0001378	dre-mir-205	Danio rerio miR-205 stem-loop	AAACUACUGUGCAUUCUAUCCUUCAUUCCACCGGAGUCUGUGUAGUUGUUCAAUCAGAUUUCAGUGGUGUGAAGUGUAGGAAACACGGA		12
16374	MI0001379	dre-mir-210	Danio rerio miR-210 stem-loop	GCAGGUAAGCCACUGACUAACGCACAUUGCGCCUAUUCUCCACUCCACUGUGCGUGUGACAGCGGCUAACCAG	Lim et al. cloned this miRNA from D. rerio [1].  The 3' end of the mature sequence was not determined, but was later analysed in a study of many clones in mouse [2].  The most common cloned length is shown here. 	12
16375	MI0001380	dre-mir-181a-1	Danio rerio miR-181a-1 stem-loop	GUUUGCCUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGAGCUAAAUGGAAAAAAACCAUCGACCGUUGAUUGUACCCUGCGGC		12
16376	MI0001381	dre-mir-214	Danio rerio miR-214 stem-loop	UGACUGAGAGCGUUGUCUGUCUGCCUGUCUACACUUGCUGUGCAGAACUUCCUGCACCUGUACAGCAGGCACAGACAGGCAGACAGAUGGCAGCCCGCCU		12
16377	MI0001382	dre-mir-216a-1	Danio rerio miR-216a-1 stem-loop	GCUGAUUUUUGGCAUAAUCUCAGCUGGCAACUGUGAGUAGUGUUUUCAUCCCUCUCACAGGCGCUGCUGGGGUUCUGUCACACACAGCA		12
16378	MI0001383	dre-mir-217-1	Danio rerio miR-217-1 stem-loop	AUGAGAACUUUCUGAUGUUGGUGAUACUGCAUCAGGAACUGAUUGGAUGAUAUUCAGGAGCCAUCAGUUCCUGAUGCACUCCCAUCAGCAUCGAAAGA		12
16379	MI0001384	dre-mir-219-1	Danio rerio miR-219-1 stem-loop	AGGGUCCCAGAGAUUGAUUGUCCAAACGCAAUUCUUGUAACAUAUAAUAUAAAUCCAAGAAUUGUGCCUGGACAUCUGUUGCUGGAGAUUC		12
16380	MI0001385	dre-mir-219-2	Danio rerio miR-219-2 stem-loop	UGAUUGUCCAAACGCAAUUCUUGUGAAAUGUCGAGCGAUCAGUCGAGAAUUGUGCCUGGACAUCUGUUGCUGGAGGCUCC		12
16381	MI0001386	dre-mir-220	Danio rerio miR-220 stem-loop	GACAGUGUGGCGUUGUAGGGCUCCACAACCGUAUCGGACACUUUGGGAGACGGCACCACACUGAAGGUGUUCAUGAUGCGGUCCGGAAACUCCUCGCGGAUCUUACUGAUG		12
16382	MI0001387	dre-mir-221	Danio rerio miR-221 stem-loop	GUCGUGAACCUGGCAUACAAUGUAGAUUUCUGUGUGGUACUAUCUACAGCUACAUUGUCUGCUGGGUUUCAGGCCAGCAGAAUAAUUCUGCUC		12
16383	MI0001388	dre-mir-222	Danio rerio miR-222 stem-loop	GCCGGUGGCUUGUUCGGGUGCUCAUGAGAUGCUCAGUAGUCAGUGUAGAUCCUGUGUCACAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUUUUCUGCU		12
16384	MI0001389	dre-mir-223	Danio rerio miR-223 stem-loop	CUCUCCUCCUGAUCUAGACUCUUCUCUUAGAGUAUUUGACAGACUGUGGUUGACACUCGAUCUAAAGGGGUGUCAGUUUGUCAAAUACCCCAAGAGAGG		12
16385	MI0001390	cbr-mir-353	Caenorhabditis briggsae miR-353 stem-loop	GAAGAUAUGCAAAAUAAAAAGCAUGGGCACAAGUAUCAUGUGUUGGUAUCAUUGUUUCAAGUUAUUUGUUGCUAUGGUAUCGAUAAGCAUGCUACGUGUGAAGUGCGACAA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the confirmed elegans sequence at 3 positions. 	2
16386	MI0001392	cbr-mir-64	Caenorhabditis briggsae miR-64 stem-loop	UCAAGAAUCCUCGGCCUCGCCGACCAUGACACUGAAGCGUGUACGGAUGGAAAGUUGAAGCCUUCCGUUCCGCUAGUGUGCCAUGCAACGGCGAGUGCCUUGGCACUUUG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 3 positions. 	2
16387	MI0001394	cbr-mir-231	Caenorhabditis briggsae miR-231 stem-loop	CUAGCACCUCAAUGUUGUUCUGUCUGUUUCCAUAGCUUAUAUUGUAAGGUACUUAUAAGCUCGUGAACAACAGGCAGGACAACUGGAAGUGGUGUUUUUUUUCA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16388	MI0001395	cbr-mir-356	Caenorhabditis briggsae miR-356 stem-loop	CCUCAUCCAACCAAUGUGGAUGAGCAACGCGAACAAAUCCUCUUAUAAGAGAUUUGCCACGCCGCCGCUCACCACACUGGCUUUCAGAAGGUGCCAGGAAUCAGAAGACGAG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at the two terminal positions. 	2
16389	MI0001396	cbr-mir-83	Caenorhabditis briggsae miR-83 stem-loop	GCAGAAGGCACCACUCGAAAAAACUGAGUUUAUGUGUGUACUUGACGGCGAUCAGAGCAACGAUCUAGCACCAUAUAAAUUCAGUGUUUUCGUGGACAGAGAGCCAAGUUU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions at the 3' end. 	2
16390	MI0001397	cbr-mir-246	Caenorhabditis briggsae miR-246 stem-loop	GAAAAGUCCUAGUGAUAAAACAGCACCUGGCCAAUAUUAUGUAAUAUCAGAAGCAAAUUGAUUAUUACAUGUAUUGGGUAGGAGCUGUUCAAGCUAUGGUUAAAUGGGU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16391	MI0001398	cbr-mir-51	Caenorhabditis briggsae miR-51 stem-loop	CGUCAUCGAAUCUCAACGUCAAACGGAUCCGAAGACGUCCAUCUACCCGUAGCUCCUUGCCAUGUUACUGGUAAAAGUGAACAUGGAAGUUGGUCCGGGUACAUGGCCAGUAGGAGUUAUGAAGACGUGUUGAGGUUUCAAGAUU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16392	MI0001400	cbr-mir-357	Caenorhabditis briggsae miR-357 stem-loop	CUACAUCAGAAGAGACAGCGAAUCCCGGCAAUCACCGUGCAUUUUCAUCUACCAGAGGCACUAAUGAAAAUGCCAGUCAUUGACGGAAUUCGUUGAAUCUGGAAUUAAAGCAU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16393	MI0001401	cbr-mir-253	Caenorhabditis briggsae miR-253 stem-loop	AACAUUUUUCGAGUUUCAGUCCUUCUCACACACCUCACUAACACUAACUACAGAUUUCUAGAUGUUAGUAGGCGUUGUGGGAAGGGCGGAGAUGACGAAUACUUUGUGCA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16394	MI0001402	cbr-mir-70	Caenorhabditis briggsae miR-70 stem-loop	AAAACGGAUGUAUCUCUAGGAACAGCCAUCAUGUAAGACAUUUCUAACUGAAAGAUGUAAUACGUGAUUGGUGUUCCCAGAGUUUACCGUUUCCUUCUUUUAUUUUUCCAAA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16395	MI0001403	cbr-mir-358	Caenorhabditis briggsae miR-358 stem-loop	ACUCCCCAUUCGGAUUGAUACCCGACUUCCGGAUACCAAAUGUCAUAUCCAACUCGUUUCGUCAAUUGGUAUCCUUAGUCGUGGUCUCAAUCUGUACACGGCGAGAGUGUUGU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16396	MI0001404	cbr-mir-61	Caenorhabditis briggsae miR-61 stem-loop	UACUUGAUCGGUGUCUCGAGCCGAGUUAAGGCUAAUAGUCCUUCCGGUGUAUGGUAAUGACUAGAACCUUGACUCUGCUCGAGUUACUGAGCUCUUUGACCCCGCCC	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16397	MI0001405	cbr-mir-360	Caenorhabditis briggsae miR-360 stem-loop	UUCCAUAAAAAAGCGCCUAGGGUUUUGUGACCGUUGUUACGGUCAAUUCAUGUCUGACACAAUGACCGUAAUCCCGUUCACAACACCUUGUGUGGCUUGAAUAAUGAAAUU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae. 	2
16398	MI0001406	cbr-mir-239a	Caenorhabditis briggsae miR-239a stem-loop	GAGAAUGACGAUCCAAGUUUAUGCGAUUUUUGUACUACAAUUAGGUACUGGACACCAGCAGCGAGUGUAUCCAGAAUCUAUACUAGUACAAAAAUAGCUAACAGGAUUAAGAU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16399	MI0001407	cbr-mir-249	Caenorhabditis briggsae miR-249 stem-loop	AUUUGUUAUUUUGUGCGCCCUCAAUGCUACUAGCAACGCUCAAAAAUCACUGUACGACAAAUGACUAUAUUUUGUCACAGGAUUUUUGAGUGUUGCUAGUCGGAGAAGG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16400	MI0001408	cbr-mir-240	Caenorhabditis briggsae miR-240 stem-loop	CGCUGUCUUUAUUUUGAAACUGUUUUCAAAUCGAGAAUUUCGAGGCCUGAAUGCAAGAACCGUUUUGAGCAUACUGGCCUCCAAAUUUUCGCUUUGAAUUUUAGUUACGCGUG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 positions. 	2
16401	MI0001409	cbr-mir-254	Caenorhabditis briggsae miR-254 stem-loop	CUCCACUCUAUGCGGGUUGCCGUAUACAGAAGCAUCGAUUUUCACACGCCAUGAUGCGCCUGUGCAAAUCUUUUGCAACUGUAUACGGCGAUUUAGCAGACCAUAUUG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16402	MI0001410	cbr-mir-239b	Caenorhabditis briggsae miR-239b stem-loop	UAGGACAGACAUGCAAUUUUUGUACUGCACAAAAGUACUGACUAUUUCUCAGCGCUUUUGUCCAGUGCAAGAAUGGCAAGAGCUGGUCCAUUUUUUUAGGGAUUAAACAAUU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 1 position. 	2
16403	MI0001411	cbr-mir-62	Caenorhabditis briggsae miR-62 stem-loop	CCCUUGCAACUCGGCUAUUAUAAGGUGGGUUAGAUCCCAUAUCCUUCCGCUUGAUGGAAAUGAUAUGUAAUCUAGCUUACAGGUCUCUCAACAUCUCCAAGACGGUGCUA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae. 	2
16404	MI0001412	cbr-mir-55	Caenorhabditis briggsae miR-55 stem-loop	AAAAUUGAAUCGUCACAAAGGGGGACUCGGCGGAAAAUAUGGUGGUAUACUACACAGUGAAUAGAUAUACCCGUAUAUUUUUCUGCCGAGCCCCUCCACGACAUCAAUAAGG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 3 positions. 	2
16405	MI0001413	cbr-mir-84	Caenorhabditis briggsae miR-84 stem-loop	UUGCUAUAUAUUCAGCCGUACUGUCUGAAAAUAACAUCUGAGGUAGUUUGCAAUGCUGUCGACGUAACUGAAAAGUCAACAUCAUUCCAACUUCCUCGGCUGUUCAAAAGGCUA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16406	MI0001414	cbr-mir-354	Caenorhabditis briggsae miR-354 stem-loop	CCAGAGCCGACUAAGUGCCUUGGUGCGGCUACAGACGGGUAUCCGGCUCGAUGUUCAUACACCGCGACUCUUUCCUUUUACCUUGUUUGUUGCUGCUCCUUUUGGUUUU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae. 	2
16407	MI0001415	cbr-mir-35	Caenorhabditis briggsae miR-35 stem-loop	UAGUCCAGUUCUGGACAUUCGCGGGUUUUUUCCUUCGGUGAUAUUCGAAGAAUCGCUAUCACCGGGUGAAAACUUGCAAGUGUCUUGCUUCGACUGGUCAUUUUGCUUGUAU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16408	MI0001416	cbr-mir-36	Caenorhabditis briggsae miR-36 stem-loop	AUUCCAAUUGAAACCUUCGGACCAUUGUGAAUUUUUGCUGCGGUGUUACAACUAACAUCUGUAUCACCGGGUGAAAAUUCGCAAUGGUCCGAUGGGUAUUCAUGUGG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 2 teminal 3' end positions. 	2
16409	MI0001418	cbr-mir-38	Caenorhabditis briggsae miR-38 stem-loop	AUUCAUGUGGAGCCUGGACCUGUACCGGGUUCUCUUUGUGGUGAUAUGACAACUCAUAACCAUUCCUUAUCACCGGGAGACAACCUGGUAUAGGUCCAGCGACUCUGCUGGAUGG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 4 positions. 	2
16410	MI0001419	cbr-mir-39	Caenorhabditis briggsae miR-39 stem-loop	AUAUUCCAGAGAUGCAGGGAGCCCAACUGGUUCUCACUGCAGUGAUAAGCUAUGUUACAGUCUAUCACCGGGUGAAAAACGGUUAGGCUCUUUAAGCAUCUCUGUAUCCCCUG	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 5 positions at the 3' end. 	2
16411	MI0001420	cbr-mir-40	Caenorhabditis briggsae miR-40 stem-loop	CUCUGUAUCCCCUGCCCUCACCCCAGCGGGUUUUCAUCGCAGUGAUAUGACGCAUUCAAACCAUUUCUUAUCACCGGGUGUCAAUCAGCUAGGGUGUGGGCGCGGGUAUCCACAGA	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 3 positions. 	2
16412	MI0001421	cbr-mir-41	Caenorhabditis briggsae miR-41 stem-loop	UGAAAGCAGGUCCCAAAUGCCUUGGUGGUUUUUCGCCGUAGUGAUACAACAUCGAAGCCAUACGAUAUCACCGGGUGAAAAACUCCCAAGGUCGGGACAUUUUUAUUUGU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae.  The mature sequence differs from the elegans sequence at 3 positions. 	2
16413	MI0001422	cbr-mir-355	Caenorhabditis briggsae miR-355 stem-loop	CUACUGAUUAUGAUUAGUCAGCAAUCGGAUGGUUUGUUUUAGCCUGAGCUAUGUGUUAUUGCAUAUUCAUAGCUACUUGCUAAAACAUACCAAUCGAGUUGACUGACAU	This miRNA is the predicted homologue of a verified C. elegans miRNA [1]. Its expression has not been verified in C. briggsae. 	2
16414	MI0001423	rno-mir-421	Rattus norvegicus miR-421 stem-loop	CACACUGUAGGCCUCAUUAAAUGUUUGUUGAAUGAAAAAAUGAAUCAUCAACAGACAUUAAUUGGGCGCCUGCUCUGUG		8
16415	MI0001424	ath-MIR413	Arabidopsis thaliana miR413 stem-loop	GAUCCAUAGUUUCUCUUGUUCUGCACAUCCACUAACUUCAGGAACCAUGUCCCAGUUUCAGGUUAGAUCAAGUGGGAAAACAAAUGGAAGAUUGUGGCUAUGCAGAAACUGGAACUAUUCGUC	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16416	MI0001425	ath-MIR414	Arabidopsis thaliana miR414 stem-loop	UCAUCAUUAUCAUCAUCAUCAUAUUCAUCUUCAUCAUCAUCGUCAUCAUCAUCAUCAUCAUCGUAUGAGAAGAUAGAGAAGAGUGAGAGUAUGAGAUUUGAGUUGAGA	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16417	MI0001426	ath-MIR415	Arabidopsis thaliana miR415 stem-loop	AGAACAGAGCAGAAACAGAACAUAUAUUCUCUGUCUUUUUUUGUGGCAAAAGUAAAUGGCGAGAAGACAACUCUUUUACCAUCGAAUGUUCUUGGUUUUAGCUCUUCUCU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16418	MI0001427	ath-MIR416	Arabidopsis thaliana miR416 stem-loop	CGAAACUGAACCCGGUUUGUACGUAUGGACCGCGUCGUUGGAAUCCAAAAGAACCAGGUUCGUACGUACACUGUUCAUCG	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16419	MI0001428	ath-MIR417	Arabidopsis thaliana miR417 stem-loop	AAAUAUAUUCAAAAGUGGUCAAAACACGUCACUAUUUCCUUUAUGUUUUCCCCUUAUUGAUGGAAAUGGUUAAACAUGAAGGUAGUGAAUUUGUUCGAAUAAUAUGUUGAUAUAUUU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16420	MI0001429	ath-MIR418	Arabidopsis thaliana miR418 stem-loop	UUUAAAUUUAGAAUCUAGCGUAAAAAGAAAAUCCGAAUCAGGAACUCUAAUGUGAUGAUGAACUGACCUUAGA	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16421	MI0001430	ath-MIR419	Arabidopsis thaliana miR419 stem-loop	AAAUUAUGAAUGCUGAGGAUGUUGUUAUUACGAGCAAUGAGAUGUCUUUUUUUAAAAAAAAAAAUUUGGUUGCUUGCUUGCAAGAGGACAUCUUAGCAUCAAAUUU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16422	MI0001431	ath-MIR420	Arabidopsis thaliana miR420 stem-loop	UUCUAAACUAAUCACGGAAAUGCAAAAAUUGGAUACUACACUAUCAACUUUUUUCUUUUGUUCUCUUUAUCUCGUGAAUUUCCAUUUAAUGAGUUUAGUU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16423	MI0001433	osa-MIR413	Oryza sativa miR413 stem-loop	ACGGCUAGUUUCACUUGUUCUGCACAUGUGGAAAACAGUUAGCACUCUAUCUGAGUCGUAAUCCCAAGCAUUAUUACAGAAAAAUAAAAGUGCAUUACAAAGAAGUCAGACAU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16424	MI0001434	osa-MIR414	Oryza sativa miR414 stem-loop	GUUGCCGCUGCCGUCAUCCUCAUCAUCAUCGUCCUUGCAUGAAACCGCCAGCAAAUCCUUGCGCGGGGGGAGGGGGAAGGGGAGGGGGAGGGGUCGGAGGGGCGGC	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16425	MI0001435	osa-MIR415	Oryza sativa miR415 stem-loop	AGAGAGUUUUACAGAGCAGAAACAGAACAGAAGCAGAGCAGCUGUGUAUACACAACACUGCAACUAUCCCUAUCACUGAGGGACAAAGCAGAAACCAGCUGAGCUCUCCUUGGCUGUCUGUACAAGCAAAGCAAAAGCUUCAAG	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16426	MI0001436	osa-MIR416	Oryza sativa miR416 stem-loop	GAUGAGGAGUAUGAAUAGAAAGAAUUAGAAAAGCUACGGUGGUUGUUGAGCAGCGCCAAAAAAAACUCUGCUUUGCUCUGUUUCUGUGUUCGUCCGUACACUGUUCAUC	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16427	MI0001437	osa-MIR417	Oryza sativa miR417 stem-loop	UUUGGUACAAAUUUGAAUUCUUAAAUCUCUUAUAUUAUGAUAUGAAUGUAGUGAAUUUGUUCCAUG	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16428	MI0001438	osa-MIR418	Oryza sativa miR418 stem-loop	CGUUAGCUGUCUGCAAUCUGCCAUUCUUAUCAUCGCACAUUUAAUGUGAUGAUGAAAUGACGCAUUUCUGUCAAGUCUCACC	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16429	MI0001439	osa-MIR419	Oryza sativa miR419 stem-loop	UCUUCUCUGUUCUCUGUGAUGAAUGCUGACGAUGUUGUAGAUGUGAACUUUUUUUUUCUCUGUUGUCUAUGAUGAAUGCUUGUUGUCCUGGAGAUAUUGUAGA	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16430	MI0001440	osa-MIR420	Oryza sativa miR420 stem-loop	UUCCAACUAAAUUAAUCACGGAAAUGAUCUUUGAAUUGUUAAAAAUACUUCCAAUGCUCAAAUAAUUCCAAGAAAAAUCUUGAAAAUACUUGGACACUCAAAGUACUUAACAAAAUUAUAAUUAGACCAUUUAAUGAUUAAUUUAAUAUGUGGGU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16431	MI0001441	ath-MIR426	Arabidopsis thaliana miR426 stem-loop	GAGGGGGGACAAUUUUUGGAAAUUUGUCCUUACGGGUAGUACUAGAAUACUUGUCCACAUGACGAUUUGAAAUAACCGAAGGACAUAUGAGGAAAAAAUAAAAUUAAACUC	miR426 was predicted and validated using procedures described in [1], but the sequence itself was not reported (Takashi Soyano, pers. comm.). The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	1
16432	MI0001442	osa-MIR426	Oryza sativa miR426 stem-loop	UCGCAUUUUUGGAAGUUUGUCCUUACGAAAAGGCUAGCAAAAUUUAGUGAGGCAAUGAAUGAAAAGACAUCUAGCGAUACUAAAAUUAAAAUUUGAUAACCCUAAAAUGUGUCAAACUUUGGCAUUUCGUGAAAAUCCUUCAAUGCGA	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	7
16433	MI0001444	hsa-mir-422a	Homo sapiens miR-422a stem-loop	GAGAGAAGCACUGGACUUAGGGUCAGAAGGCCUGAGUCUCUCUGCUGCAGAUGGGCUCUCUGUCCCUGAGCCAAGCUUUGUCCUCCCUGG	miR-422a is an predicted paralogue of miR-422b (MIR:MI0001443), later verified in human [2]. 	5
16434	MI0001445	hsa-mir-423	Homo sapiens miR-423 stem-loop	AUAAAGGAAGUUAGGCUGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGUCUUGCUUCCUAACCCGCGC	miR-423 (renamed miR-423-3p here) is expressed in human promyelocytic leukemia (HL-60) cells [1].  The level of expression was shown to be up-regulated 48 hours after TPA-induction.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
16435	MI0001446	hsa-mir-424	Homo sapiens miR-424 stem-loop	CGAGGGGAUACAGCAGCAAUUCAUGUUUUGAAGUGUUCUAAAUGGUUCAAAACGUGAGGCGCUGCUAUACCCCCUCGUGGGGAAGGUAGAAGGUGGGG	This hairpin precursor expresses a 5' arm product, named miR-424, in human promyelocytic leukemia (HL-60) cells [1].  The level of expression of miR-424 was shown to be up-regulated 48 hours after TPA-induction.  The sequence is orthologous to the experimentally verified rat miR-322 locus (MIR:MI0000589), which expresses its mature product from the 3' arm of the hairpin.  The human miR-424 hairpin does not appear to contain the miR-322 sequence. 	5
16436	MI0001447	mmu-mir-425	Mus musculus miR-425 stem-loop	AAAGUGCUUUGGAAUGACACGAUCACUCCCGUUGAGUGGGCACCCAAGAAGCCAUCGGGAAUGUCGUGUCCGCCCAGUGCUCUUU	Poy et al. identified a mature miRNA from the 3' arm of this hairpin, and named it miR-425 [1].  Landgraf et al. later showed that the 5' product is the predominant one [2].  The 3' product is renamed miR-425* here. 	6
16437	MI0001448	hsa-mir-425	Homo sapiens miR-425 stem-loop	GAAAGCGCUUUGGAAUGACACGAUCACUCCCGUUGAGUGGGCACCCGAGAAGCCAUCGGGAAUGUCGUGUCCGCCCAGUGCUCUUUC	The mature sequences were previously named miR-425-5p and miR-425-3p in [2] and here.  Landgraf et al. show that the 5' product is the predominant one [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
16438	MI0001449	xla-mir-427	Xenopus laevis miR-427 stem-loop	AGCACCCAAAACGGGGCUCUCUCUUGUGACUGAAUUAUGAUGAGAAAGUGCUUUCUGUUUUGGGCGUU		13
16439	MI0001450	xla-mir-428	Xenopus laevis miR-428 stem-loop	CACGUCGGCCUAACUGGAGCCCUGUCUCAUUGCAGCUGUGAGUAAGUGCUCUCUAGUUCGGUUGCUGAGUG		13
16440	MI0001451	xla-mir-429	Xenopus laevis miR-429 stem-loop	UGGAUGUCUUACCAGACAUGGUUAGAUCUGGAUGCAUCUGUCUAAUACUGUCUGGUAAUGCCGUCCAU		13
16441	MI0001452	xla-mir-19b	Xenopus laevis miR-19b stem-loop	GCUCCUGUCAGUUUAGCUGGUUUGCAUCAGCUGGCUACUGUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGC		13
16442	MI0001453	xla-mir-20	Xenopus laevis miR-20 stem-loop	GCAGUUCCAAAGUGCUCAUAGUGCAGGUAGUUGUAUUCAUGUUCUACUGUAAUAUGGGCACUUACAGUACUGCU		13
16443	MI0001454	xla-mir-18	Xenopus laevis miR-18 stem-loop	CCUUGUGUUAAGGUGCAUCUAGUGCAGUUAGUGACAUAGCGUAGCAUCUACUGCCCUAAAUGCUCCUUUUGGCACAGGG		13
16444	MI0001455	xla-mir-133a	Xenopus laevis miR-133a stem-loop	CAGUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGGAUUGCAUUG		13
16445	MI0001456	zma-MIR156d	Zea mays miR156d stem-loop	AGGCUCUCGAGAGAUUGACAGAAGAGAGUGAGCACACGGCGCGACGAACGACAUAGCAUGUAUGCCGUCCUCGCCGCGUGCUCACUUCUCUUUCUGUCAGCCUCUUUCUCUCGAUGGCU		14
16446	MI0001457	zma-MIR156f	Zea mays miR156f stem-loop	UGGCUGCUAGAUGGUGUGGCUGACAGAAGAGAGUGAGCACGCAUCGGCCAGACUGCAUCUAUAUACGGCUGCCCCAAAGCGACGGAUCGAUGGAUGCCUAGCCUAGGCCUAGGCGCAGCUGCUGUUGCGUGCUCACUUCUCUUUCUGUCAGCUCUCUCUCUCAUCCU		14
16447	MI0001458	zma-MIR156g	Zea mays miR156g stem-loop	GGCUGACAGAAGAGAGUGAGCACGCAUCGGCCAGACUGCAUCUAUAUACGGCUGCUCCUGGCGAAUGGAUAGAUGCCAAGGCGCAGCUGCUGUUGCGUGCUCACUUCUCUUUCUGUCAGCU		14
16448	MI0001459	zma-MIR156b	Zea mays miR156b stem-loop	AGAUGAGUUUUUUGAAGGUUUGACAGAAGAGAGUGAGCACACACGGUGGUUUCUUACCAUGAGUGUCAUGCUAGGAGCUGUGCGUGCUCACCCUCUAUCUGUCAGUCACUCAUCAAGCCCAUCU		14
16449	MI0001460	zma-MIR156c	Zea mays miR156c stem-loop	GGUGGAGGAGAGGUGAAAGCUGACAGAAGAGAGUGAGCACACAUGGUGCCUUUCUUGCAUGAUGUAUGAUCGAGAGAGUUCAUGCUCGAAGCUAUGCGUGCUCACUUCUCUCUUUGUCAGCCAUUAGAACUCCUCUAUC		14
16450	MI0001461	zma-MIR156e	Zea mays miR156e stem-loop	CCGGCGGGCGCGCGCGCGGUGACAGAAGAGAGUGAGCACACGGCCGGUGUGACGGCACCGGCGCGGAUGUGCCGUCGCGGCCGCGUGCUCACUGCUCUCUCUGUCAUCCGCUGGCACACCCUCACG		14
16451	MI0001462	zma-MIR156a	Zea mays miR156a stem-loop	UUCGUUCCGUGGCUAACUGACAGAAGAGAGUGAGCACACAGCGGGCAGACUGCAUCGAUCGAUCUGCAUCCGAGACGGCGCACGUACGAAUGAUGAUGCAGCUGCUGCUGCGUGCUCACUUCUCUCUCUGUCAGUCCUCUAGCUGCUACGGC		14
16452	MI0001463	zma-MIR156h	Zea mays miR156h stem-loop	CGGGCUCGCGCGCGCGCGGUGACAGAAGAGAGUGAGCACACGGCCGGGCGUGACGGCACGUGCCGUCGCGGCCGCGUGCUCACUGCUCUUUCUGUCAUCCGCUGGUCCGGGCCUC		14
16453	MI0001464	zma-MIR156i	Zea mays miR156i stem-loop	CGCGGCGGGCGGUGACAGAAGAGAGUGAGCACACGGCCGGGCGGAACGGCACCGGCGGAUGGUGCCGUCGCGGACGCGUGCUCACUGCUCUAUCUGUCAUCCACUCUCUCCCCCGCU		14
16454	MI0001465	zma-MIR160a	Zea mays miR160a stem-loop	UUGUGUGCGUGCCUGGCUCCCUGUAUGCCACACAUGUAGCGCCCAACCCAGAUGYUAAGGUUGCCUGCUGUGGGUGGCGUGCAAGGGGCCAAGCAUGCAUCCAU		14
16455	MI0001466	zma-MIR160c	Zea mays miR160c stem-loop	AGGAUGUGCCUGGCUCCCUGUAUGCCACUCAUCUAGAGCAACGACAGCUUGGUAGGGUUGCCUAUAAGAUGGAUGGCGUGCAUGGUGCCAAGCAUAUCUC		14
16456	MI0001467	zma-MIR160d	Zea mays miR160d stem-loop	GGCCAGGGGCGGGAUCGAUAUGCCUGGCUCCCUGUAUGCCACUCGCAUGGCUGCCAACUCAUCAUGCAUACACUGCUAGCUAGUCGUUGGCUCCACUGCGGAUGGCGUGCGUGGAGCCAAGCAUGACCGAUCAUCUCCUCCU		14
16457	MI0001468	zma-MIR160b	Zea mays miR160b stem-loop	CGAUCGGCUCGUGUCGUGUGUGCCUGGCUCCCUGUAUGCCACACAUGUAGCCAACCCGUGGCGUGAUUGGAUGCUGUGGGUGGCGUGCAAGGAGCCAAGCAUGCAUAACAGGCCAUGAUCA		14
16458	MI0001469	zma-MIR164a	Zea mays miR164a stem-loop	CAGUGACAAGGACCACGCUGGAGAAGCAGGGCACGUGCAUGCGCAUACCAUAUAGCUAGACGAUGUUCUCUCUCGCUCCGCUCGACCAAGCUUCAUGUAUGGAUGGGUACGCACGCACGUGUUCUCCUUCUCCAUCGAGGUCUUUCUCACUU		14
16459	MI0001470	zma-MIR164d	Zea mays miR164d stem-loop	UGAGUGAGAAGGACCACGCUGGAGAAGCAGGGCACGUGCAUGCACAUACGCCAUUCUCGAUCUCUCCUCUCCACCACUACUGCAUCUAGCUAUCUCCAUGGAUGGAUGUACGUAGCUCGGACUGGAUCGAUCGGAGAAGCAAUAAGCUAGCGAGCUCAUGCAUGCUGGCUGUGCACGCACGUGGUCUCCUUCUCCAUCACGGUUCUUUCUCACUUC		14
16460	MI0001471	zma-MIR164b	Zea mays miR164b stem-loop	UAGACGGUGGCUGUGCGUGGUGGAGAAGCAGGGCACGUGCAUUACCAUCCAAUGCCGCCGGGUGGGUGGGUGGAAUGGAUGGAUGGUUCUUGAUGUGCCCAUCUUCUCCACCGAGCACGAACUGUCUU		14
16461	MI0001472	zma-MIR164c	Zea mays miR164c stem-loop	UGGCGAGGUGCGCGCGGUGGAGAAGCAGGGCACGUGCAUUCUUUCCGUCGCCGGCCGGCUUGGCAGCGGCCGGCGGCCCGGCUCUCGCAGUCACGCGUACGUCGCCUGAGCGGCGCGCGCGAGAGAGAGAGACACGGCAGGUCGUCGCCGGCGCGGCUAACUGGUGCAGGUGCAGCAGCUAGCUUCUGAAACCCAGCCAGCCAGCCAGCCGGCCGGCCGGCCGAUCGAUGCGUGCAUGUGCCCUUCUUCUCCAUCGGGCACGCCUCGCCU		14
16462	MI0001473	zma-MIR169a	Zea mays miR169a stem-loop	UAGGCUCGGGGACUAUGGUGCAGCCAAGGAUGACUUGCCGAUCGAUGUGACGCCUCUUGAUCUCGUCGUCGUCAGAUCGUCGCCGAUCAUCGGCAAGUUGUUCUUGGCUACACCGUGGCUCCUGCUCCUG		14
16463	MI0001474	zma-MIR169b	Zea mays miR169b stem-loop	UAGGCUCGGGGACUACGGUGCAGCCAAGGAUGACUUGCCGAUCUAUCGUCGAUCAACGAGCGACGCCUCUGAUGUCUGAUCUCGACAUCUAUCGUCGUCAGACCAUCAUCAUCUAUCGGCAAGUUGUUCUUGGCUACACCGUGGCUCCUGCUCCUG		14
16464	MI0001475	zma-MIR167a	Zea mays miR167a stem-loop	UGCUCUUGCGAAUGAGUGAAGCUGCCAGCAUGAUCUAGCUCUGAUUUGGUUGGCACCAUAUUAGCAGGCGUCCACGCACAGCUAGACUAGAGUGGCCUCGCGCGCUCUCGUCUGGUCUGUGUCUCGCUUUGUGCCUGCAAAUCGUUGUUAGAUCAUGCAUGACAGCCUCAUUCCUUCACAAUUCUGGGGC		14
16465	MI0001476	zma-MIR167b	Zea mays miR167b stem-loop	AGUGCCCAAGAUAAAGGGUGAAGCUGCCAGCAUGAUCUAACGACGGCAUUGCUCUGCUGCUGCAGUGAGGCUUGCGAGUGAUGGUUAGAUCAUGCUGUGACAGUUUCACUCUUUCCCUUUGGGCACA		14
16466	MI0001477	zma-MIR167d	Zea mays miR167d stem-loop	UGCCCAAGGGAACGAGUGAAGCUGCCAGCAUGAUCUAGCUCUGAGUGAUCACCCGAAAAAGAACAAUAGUUCUAGGUGGUCAUGCCUUGCUAGGUCAUGCUGCUGCAGCCUCACUUCUUCCCGUCGUUGGGCA		14
16467	MI0001478	zma-MIR167c	Zea mays miR167c stem-loop	UGCCCAAGGGAACGAGUGAAGCUGCCAGCAUGAUCUAGCUCGGAGUGAUCACGCGAGGAGAACAAUAGCUCGAGGUGGUCAUGCCUUGCUAGAUCAUGCUGUGGCAGCCUCACUUCUUCCCGUCCUUGGGCA		14
16468	MI0001479	zma-MIR160e	Zea mays miR160e stem-loop	AGGGAAUAUGCCUGGCUCCCUGUAUGCCACUCGCACGGCUACCACACCCCGGUGGCCGCUGCGGCUGGCGUGCGAGGUGCCAAGCAUGGCCCCC		14
16469	MI0001480	zma-MIR166a	Zea mays miR166a stem-loop	UGAGGGGAAUGUUGUCUGGCUCGGGGCCGCCGCCGCCGCUCCUUCCUUCUCUAGUCUCUCUUCUCUCCUAGCAGCUACUCUUCGCUUCCUACUCCUAUCUCGAUCCCUCUCUUCUUCUUCUUCUUCUUCUUCCUCUUCCCCCCUCUCUUGGAUCGAGACCGAGCGGACGGAGACGAGUGGUGUAGAUCUCGGACCAGGCUUCAUUCCCCCCAA		14
16470	MI0001481	zma-MIR162	Zea mays miR162 stem-loop	CUGGGCGCAGUGGUUUAUCGAUCUCUUCCUUGCCUUGUGCUGGUCCGGCCGGGAGUGGUGGUUCAAGCGUUUUAUUGUUGCAGCAGCUCGCAAACAACGCGGGAAUCGGUCGAUAAACCUCUGCAUCCAG		14
16471	MI0001482	zma-MIR166h	Zea mays miR166h stem-loop	GGGGAAUGACGUCCGGUCCGAACGAGCCACGGCUGCUGCUGCGCCGCCGCGGGCUUCGGACCAGGCUUCAUUCCCC		14
16472	MI0001483	zma-MIR166e	Zea mays miR166e stem-loop	GGGGAAUGUUGUCUGGCUCGAGGUGCAGAAACAUACAGAUCUCAUCGGUCUAGGUUCUUGUCGAUCUCGGACCAGGCUUCAUUCCCC		14
16473	MI0001485	zma-MIR166i	Zea mays miR166i stem-loop	GGGGAAUGUCGUCUGGCGCGAGACCGUACCAGACGACGUGCUCUCUCGGUCGUCGGACGGUCUCGGACCAGGCUUCAUUCCCC		14
16474	MI0001486	zma-MIR166f	Zea mays miR166f stem-loop	GGGGAAUGACGUCCGGUCCGAACAAGCCACGGCUGCUGCUGCGCUACCGCCGCGGCUUCGGACCAGGCUUCAUUCCCC		14
16475	MI0001487	zma-MIR166g	Zea mays miR166g stem-loop	GGGGAAUGUUGUCUGGUUGGAGACCUAACACCRCGAAUUAAUCAUCCAUGCCAUGGAAGCAGCAUAUGCCCGCCUGCAUCUAUCCAUGCAUGAUGGUGGAAGGUUUCGGACCAGGCUUCAUUCCCC		14
16476	MI0001488	zma-MIR166b	Zea mays miR166b stem-loop	GUGGAAUGUUGUCUGGUUCAAGGUCUUGCUWUCCGAUUUGAGGAUGAUCCAUGCUUGCAUGUGUAGUUUUUUUUGUUCCUCAGAUCUACAAGAUCUCGGACCAGGCUUCAUUCCCC		14
16477	MI0001489	zma-MIR166c	Zea mays miR166c stem-loop	GGGGAAUGUUGUCUGGCUCGAGGUGCAGAAACACGCAGAUCUCAUCGAGGUCGUCUUGGUUGUUGUUGAUCUCGGACCAGGCUUCAUUCCCC		14
16478	MI0001490	zma-MIR166d	Zea mays miR166d stem-loop	GUGGAAUGUUGUCUGGUUCAAGGUCUUUUGCUUUGUGAUCCAUCUGUGUAGAGCUUCUAAGUAUUCCUUGGAUCUGCAAGAUCUCGGACCAGGCUUCAUUCCCC		14
16479	MI0001491	zma-MIR171a	Zea mays miR171a stem-loop	GAUAUUGGCGAGGUUCAAUCAGAUGAUGUAUUUUUCUUAUAUAUAAAUUUGCAUGCAUGAAGGUGUGAAUCCAGUGUCUGAUUGAGCCGCGCCAAUAUC		14
16480	MI0001492	zma-MIR171b	Zea mays miR171b stem-loop	CGGGAUAUUGGCGCGGUUCAAUCAGAAAGCUUGCGCUCCAGGCCCGAGGGGCUCCACUCUUUGAUUGAGCCGUGCCAAUAUCACG		14
16481	MI0001493	zma-MIR172a	Zea mays miR172a stem-loop	GCGUGGCAUCAUCAAGAUUCACAACCCAUCAAUCCGAACCACUGAUUUGGAAUGCAUGYAUGAGAAUCUUGAUGAUGCUGCAU		14
16482	MI0001494	zma-MIR172d	Zea mays miR172d stem-loop	GUGCAGCACCAUCAAGAUUCACAUCCCCAGCUCGAUCUGUGCAUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAU		14
16483	MI0001495	zma-MIR172b	Zea mays miR172b stem-loop	GUGCAGCACCAUCAAGAUUCACAUCGUCCAACUCAUGCAUCAUGCAUAUAUGCAUCUUCAAUGAUGCGUGCCUCGCAUGUGUGUGUAUAUAUAUAUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAU		14
16484	MI0001496	zma-MIR172c	Zea mays miR172c stem-loop	GUGCAGCACCACCAAGAUUCACAUCCAACUCUCACGCAUCUUCAGUGAUGCAUGCAUGCUCUGUGAUGUCUCGCAGCAGCUAUAUGCAUAUGUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAU		14
16485	MI0001497	sbi-MIR166d	Sorghum bicolor miR166d stem-loop	GGGGAAUGUUGUCUGGCUCGAGGUGCAGGAACAUGCAGAUCUCAUCGGUCUAGAUUGUUGUUGAUCUCGGACCAGGCUUCAUUCCCC		15
16486	MI0001498	sbi-MIR166c	Sorghum bicolor miR166c stem-loop	GGGGAAUGUUGUCUGGUCGGAGACCUAACACCGCGAAUCAUCCAUGGAGCAGCAUGCAUGGUGGUGGAUGGUUUCGGACCAGGCUUCAUUCCCC		15
16487	MI0001499	sbi-MIR166b	Sorghum bicolor miR166b stem-loop	GGGGAAUGAUGUCCGGUCCGAAGACGCUGUGCGGCGAAAGCGGCGGCGGCUUCGGACCAGGCUUCAUUCCCC		15
16488	MI0001500	sbi-MIR166a	Sorghum bicolor miR166a stem-loop	GUGGAAUGUUGUCUGGUUCAAGGUCUCGCUUGUGAUUUAAGGAUGAUUUGUGCAUGCGUAAUUUUUAUUCCUUGAAUCUAUGAGAUCUCGGACCAGGCUUCAUUCCCC		15
16489	MI0001501	sbi-MIR172b	Sorghum bicolor miR172b stem-loop	GCGUGGCAUCAUCAAGAUUCACACACUGCUUGCAAAUGCAUACAUGCAUCUCUGCCGCCUUCUUUGCCUGCCAUUAAUAGCAGUUUUACUACAUGUUUUAGCUGCUGCUGCAUCAUAUAUGCCUCUGUGAAUAUAUAUGUGUAUGUGUGGGAAUCUUGAUGAUGCUGCAU		15
16490	MI0001502	sbi-MIR172c	Sorghum bicolor miR172c stem-loop	GUGCAGCACCAUCAAGAUUCACAUGGUCCAACUCAUGCAUCUUCAGUGAUGCUCAUGUGAUGGCUCGCAGUUGCUAUAUAUGCAUAUGUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAU		15
16491	MI0001503	sbi-MIR172a	Sorghum bicolor miR172a stem-loop	GUGCAGCAUCAUCAAGAUUCACAUCCAGCUCAUCCUCGGUGAUAUGCUAUAUACAUAAAUAUAUGCGUAUGUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAU		15
16492	MI0001504	sbi-MIR156a	Sorghum bicolor miR156a stem-loop	UGACAGAAGAGAGUGAGCACACGGCGCGACGAACGGCAUAAUAUGUAUGUCGUCCUCGCCGCGUGCUCACUUCUCUUUCUGUCA		15
16493	MI0001505	sbi-MIR156c	Sorghum bicolor miR156c stem-loop	UGACAGAAGAGAGUGAGCACACAUGGUGCCUUUCUUGCAUGAUGAAUGAGUGGAUUCAUGCUCGAAGCUAUGCGUGCUCACUUCUCUCUCUGUCA		15
16494	MI0001506	sbi-MIR156b	Sorghum bicolor miR156b stem-loop	UGACAGAAGAGAGUGAGCACACACGGUGGUUUCUUAGCAUGAGUGCCAUGUUGGGAGCUGUGCGUGCUCACUCUCUAUCUGUCA		15
16495	MI0001507	sbi-MIR160d	Sorghum bicolor miR160d stem-loop	UGCCUGGCUCCCUGUAUGCCACUCGCUUAGCUGCCAACAACUCAUACUACGUUGUUAACGACGUUGGCUCUACUGCGGAUGGCGUGCGAGGAGCCAAGCA		15
16496	MI0001508	sbi-MIR160a	Sorghum bicolor miR160a stem-loop	UGCCUGGCUCCCUGUAUGCCACACAUGUAGCCCAACCCAUAUGCUAAGGUUGCCUGCUGUGGGUGGCGUGCAAGGGGCCAAGCA		15
16497	MI0001509	sbi-MIR160c	Sorghum bicolor miR160c stem-loop	UGCCUGGCUCCCUGUAUGCCACUCAUCUAGAUCAACAACUACCUAUGGUUGCCUAUGAUGGUUGGCGUGCACGGUGCCAAGCA		15
16498	MI0001510	sbi-MIR160b	Sorghum bicolor miR160b stem-loop	UGCCUGGCUCCCUGUAUGCCACACAUGUAGCCCAACCCGUGGCGUGAUUGGAUGCUGUGGGUGGCGUGCAAGGAGCCAAGCA		15
16499	MI0001511	sbi-MIR160e	Sorghum bicolor miR160e stem-loop	UGCCUGGCUCCCUGUAUGCCACUCGCACGGCUACCACCCCAAGAUCAUCGAUCGAUCUCGGUGGCCGCUGCGGCUGGCGUGCGAGGUGCCAAGCA		15
16500	MI0001512	sbi-MIR164	Sorghum bicolor miR164 stem-loop	UGGAGAAGCAGGGCACGUGCAUUACCAUCCAAUGCCGCCAAGCUCGAUCCUCCUCUGAGCUUGCUAGCUCCAUCAGCUCGCCAGCCAUGGCUGGAUGGAUGGUUCUUCAUGUGCCCAUCUUCUCCA		15
16501	MI0001513	sbi-MIR167a	Sorghum bicolor miR167a stem-loop	UGAAGCUGCCAGCAUGAUCUAGCUCUGAGUGAUCACCCGAGAAGAACAAUAGUUCGAGGUGGUCUCGCCUUGCUAGGUCAUGCUGCGGCAGCCUCA		15
16502	MI0001514	sbi-MIR167b	Sorghum bicolor miR167b stem-loop	UGAAGCUGCCAGCAUGAUCUAACAACGGCAUUGCUCCUCCGUGUAGCGCCCUGUGCUUGCUUUUGCUUGUCUCCAUGGAGAAGACAGCGGCAAAGCUUAGCUUUGCUUCGCUUAGCUUGCUGGCUUUUCGUAUGGGCUGGCGGCGGGUUGCUGCGUGAAGCUUGCAAGUGAUGGUUAGAUCAUGCUGUGACAGUUUCA		15
16503	MI0001515	sbi-MIR169b	Sorghum bicolor miR169b stem-loop	CAGCCAAGGAUGACUUGCCGGAUAUGUGCAUGCAUAUGUUACAAGGCAGCAUAUGCACCCUGUUACAAGCCUGCCUGUUCUCCGGCAAGUUGUCCUUGGCUA		15
16504	MI0001516	sbi-MIR169a	Sorghum bicolor miR169a stem-loop	CAGCCAAGGAUGACUUGCCGAUCGAUCGAUGCAAACUCCUCUGAUGUCUGAUCUCAUCAGAUUAUCGUUGUCGGAAAGUUGUUCUUGGCUA		15
16505	MI0001517	gga-mir-20b	MI0001517 Gallus gallus miR-20b stem-loop	CUAGCAGUAUCAAAGUGCUCAUAGUGCAGGUAGCUUGGCAUUGGACCUACUGUAAUGUGGGCACUUACAGUACUGUUAGAUAAAG		10
16506	MI0001518	hsa-mir-18b	Homo sapiens miR-18b stem-loop	UGUGUUAAGGUGCAUCUAGUGCAGUUAGUGAAGCAGCUUAGAAUCUACUGCCCUAAAUGCCCCUUCUGGCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
16507	MI0001519	hsa-mir-20b	Homo sapiens miR-20b stem-loop	AGUACCAAAGUGCUCAUAGUGCAGGUAGUUUUGGCAUGACUCUACUGUAGUAUGGGCACUUCCAGUACU		5
16508	MI0001520	oar-mir-431	Ovis aries miR-431 stem-loop	CGUCCUGCGAGGUGUCUUGCAGGCCGUCAUGCAGGCCACACUGACGGAAACGUUGCAGGUCGUCUUGCAGGGCGUCUCGCAAGACGACACA		17
16509	MI0001521	oar-mir-127	Ovis aries miR-127 stem-loop	GCUUUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCCUCAUCUGCUUCCUUCGGGUU		17
16510	MI0001522	oar-mir-432	Ovis aries miR-432 stem-loop	GCAUGACUCCUCCAAGUCUUGGAGUAGGUCAUUGGGUGGAUCCUUUAUUUCCCUAUGUGGGCCACUGGAUGGCUCCUCCAUGUCUUGGCG		17
16511	MI0001523	oar-mir-136	Ovis aries miR-136 stem-loop	UCGGAUGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUACGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCUAUCAU		17
16512	MI0001524	mmu-mir-431	Mus musculus miR-431 stem-loop	CGUCCUGCGAGGUGUCUUGCAGGCCGUCAUGCAGGCCACACUGACGGUAACGUUGCAGGUCGUCUUGCAGGGCUUCUCGCAAGACGACAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
16513	MI0001525	mmu-mir-433	Mus musculus miR-433 stem-loop	UGCCCGGGGAGAAGUACGGUGAGCCUGUCAUUAUUCAGAGAGGCUAGAUCCUCUGUGUUGAGAAGGAUCAUGAUGGGCUCCUCGGUGUUCUCCAGGUAGCGGCACCACACCAUGAAGGCAGCCC	Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product is renames miR-433* here. 	6
16514	MI0001526	mmu-mir-434	Mus musculus miR-434 stem-loop	UCGACUCUGGGUUUGAACCAAAGCUCGACUCAUGGUUUGAACCAUUACUUAAUUCGUGGUUUGAACCAUCACUCGACUCCUGGUUCGAACCAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
16515	MI0001527	dre-mir-430a-1	Danio rerio miR-430a-1 stem-loop	CUGCUACUGUUGUCACUAUCGGUGCCCUCACAAAGGCACUGACUUGGAUGCUGCAUGUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUA		12
16516	MI0001528	dre-mir-430b-1	Danio rerio miR-430b-1 stem-loop	AUUGAUAGAAACCAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGC		12
16517	MI0001529	dre-mir-430c-1	Danio rerio miR-430c-1 stem-loop	UUCAAUCUAAAGCACAUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAG		12
16518	MI0001530	sbi-MIR393	Sorghum bicolor miR393 stem-loop	NACNAUGCCUGGAGGAAGCAUCCAAAGGGAUCGCAUUGAUCCGUCNCUCCUUCCAUUCUAUCNUGGGNGGNCGNCNUCUACNAGGACUUCNUUCCCGACGGAUCNUGCNAUCCUUUUGGAGGCUUCCNCUNNACUUACU		15
16519	MI0001531	sbi-MIR394a	Sorghum bicolor miR394a stem-loop	CUUUACAUACUGAGAGUUCCUUGGCAUUCUGUCCACCUCCUUGCCCAUCGUCAGAUAUAUGUGUUGCUUUUGGAGGUGGACAUACUGCCAAUGGAGCUGUGUAGGCCUCU		15
16520	MI0001532	sbi-MIR394b	Sorghum bicolor miR394b stem-loop	CUUUACAUACUGAGAGUUCCUUGGCAUUCUGUCCACCUCCUUGGCCCAUCGUCAGAUAUAUGUGUUGCUUUUGGAGGUGGANAUACUGNCAAUGGAGCUGUGUAGGCNUCU		15
16521	MI0001533	sbi-MIR395b	Sorghum bicolor miR395b stem-loop	GUUAGGUUUGGUGUCCCUAGGAGUUCUCUGCAAGCACUUCACGAGGCAUCGUUUUGAGAGCUUUUGUGAAGUGUUUGGGGGAACUCUUAGUGUCACAAAUCAUUU		15
16522	MI0001534	sbi-MIR395a	Sorghum bicolor miR395a stem-loop	GGUUGGUUGGUUGUCACCUGGAGUUCUCCACAAACUACUUCAGUAGCAACACACACCCCUAGUUUAAUGCACCGUGUUUGCAUGUUUGUGUGGAGCUGUGUGUGUACAUAGUGAAGUGUUUGGGGGAACUCUGGGUGGCAAUCAGCAAUU		15
16523	MI0001535	sbi-MIR395c	Sorghum bicolor miR395c stem-loop	GCACUAUUUUGAGAGCUUUUGUGAAGUGUUUGGGGGAACUCUUGAUGCCACUAACCAUUUGCUAGAGGUUGGCCAAGUGUGUGCUACAUGAGCCAAGUGUGUGCUACAUGAAAUGAUUUGAAGACAAAUCACAUUUGGAAAUUAUAUAUCAAGUUUGGUGUCCCCAGGAGUUCUCUGCAAACACUUCACAAAGCACUUUUUUAGAGCU		15
16524	MI0001536	sbi-MIR395d	Sorghum bicolor miR395d stem-loop	UCAAGUUUGGUGUCCCCCAGGAGUUCUCUGCAAACACUUCACAAAGCACUUUUUUAGAGCUUUUGUGAAGUGUUUGGGGGAACUCUUGGUGCCACUGAUCAUUU		15
16525	MI0001537	sbi-MIR395e	Sorghum bicolor miR395e stem-loop	AUUAGGUUUGGUGUCCCCGGGAGUUCUCUGCAAGCACUUCACGAGGCACUAUUUUGAGAGCUUUUGUGAAGUGUUUGGGGGAACUCUUGAUGCCACUAACCAUUU		15
16526	MI0001538	sbi-MIR396b	Sorghum bicolor miR396b stem-loop	AGAUGGCCUUCUUUGUGAUCUUCCACAGCUUUCUUGAACUGCAUCUCUAAGAGGAGCAGCUUGAACUCUCUACCUGCAUGAGCAGGUGCAGUUCAAUAAAGCUGUGGGAAACUGCAGAGAGAGGCCAA		15
16527	MI0001539	sbi-MIR396a	Sorghum bicolor miR396a stem-loop	ACAUGGCCCUCCUUGCCGUCUUCCACAGCUUUCUUGAACUGCAUGCUGGUAGUGCUGUGUGCAUCCGUUCCAAUAUUCCAAGAGGCAGUUCAAUAAAGCUGUGGGAAAUUGCAGAGAGAGACCAG		15
16528	MI0001540	sbi-MIR396c	Sorghum bicolor miR396c stem-loop	UUCAAGUCCAUGCCAUGCCUUUCCACAGCUUUCUUGAACUUCUCCUCCUCCUCCUCUCUCUUAGAAGGGUAGCUUUGAACAUCUCUCUCUCUCUCUCUCUCUCUCUCUCUCUCUCUCCAAAGAAGGUCAAGAAAGCUGUGGGAAGAAAUGACAUAACAAGGA		15
16529	MI0001541	sbi-MIR399a	Sorghum bicolor miR399a stem-loop	UACCGUCCGCCGGCGAAUUACGGGGCAGUUCGUCUUUGGCACAAAGGCACGUCCAGAACUACUCGAUGAGGGUCACUUGAGCUGAACUGAACAUGCGUGCCAAAGGAGAAUUGCCCUGCGAUUCGCCCGUGCAGAAG		15
16530	MI0001542	sbi-MIR399c	Sorghum bicolor miR399c stem-loop	CAUAUGCUGAGCAUGAAUUACAGGGUACAUCUCCUUUGGCACAGAUGCAUGCAGCAGAAUGCAUAUAUGCAUAUGCGAAACUGUCGAGCGUGCCAAAGGAGAAUUGCCCUGCGAUUCUAGGCUCUGCAAU		15
16531	MI0001543	sbi-MIR399d	Sorghum bicolor miR399d stem-loop	GUGCAGGCUGAAGACAGUUGUAGGCAGCUCUCCUCUGGCAGGCGGUCAUCGUCGUCGUCAUCGACGGCUGGUUCUGUGUUCAUCCGGAUCCAUCGUGCAGCCGUGCAUGCAUGCAGUAAUAUUCGGUUACAUGCAUGCAUUAUGCACGCACGUACGUCGUCGUCCUGCCAAAGGAGAGUUGCCCUGCGACUGUCUCCAGCUUCCU		15
16532	MI0001544	sbi-MIR399e	Sorghum bicolor miR399e stem-loop	ACAUGCGGGGCCAUGCAUUACCGGGUGGGUCUCCUCUGGCAGUAACUUGGCUGGUCGCCUGGUCCAUGAUACCUGCGUGCAGACACUGCCAAAGGAGAUUUGCCCAGCAAUGCAGUUUUGAGUCCC		15
16533	MI0001545	sbi-MIR399f	Sorghum bicolor miR399f stem-loop	CAUAUGCGAGUCGAGGAUUACCGGGCCAUUUCUCCUUGGGCAGAGUAAUUGAAUUUUACUUUGCUGGAUCCGGUUUGCUCUGCCAAAGGAGAUUUGCCCAGCAAUCCACAUUUGUAAUAU		15
16534	MI0001546	sbi-MIR399b	Sorghum bicolor miR399b stem-loop	UAGCUCAGGGGUGAGAAUCACAGUGCAGCUCUCCUUUUGGCAUGAAGGCUGAGAGAGUCAUGAGCAGUUUUCUGGCCUUUCCCUGCCAAAGGAGAGCUGCCCUGCCAUUCAUUAGCCCUGCAA		15
16535	MI0001547	sbi-MIR399g	Sorghum bicolor miR399g stem-loop	CCAGAUGUGCACUUGCAUUGCUGGGCAACUUCUCCUUUGGCAGAUGNGCAAUGNGCUCNGACCCUGGGGCUUCUUCCGCGCCUACUGCCAAAGGAAAUUUGCCCCGGAAUUCACCUGCACAGCCA		15
16536	MI0001548	sbi-MIR156d	Sorghum bicolor miR156d stem-loop	UGGACCUCUGGAGUGAGUGAUGACAGAAGAGAGAGAGCACAACCCAGCACCAGCGAGGAGAAGCCUCGCUUCUGCGAGGGCCGUGUGCUCUCUGCUCUCACUGUCAUCGCCGACAGGCCACCCAA		15
16537	MI0001549	sbi-MIR164b	Sorghum bicolor miR164b stem-loop	GAGGGGCGAGCAAACCGUGCUGGAGAAGCAGGGCACGUGCUCGUCGUCGCUGCAUGCGUGGUCGUCGUCGCAGCACGUGCGCUCCUUCUCCAACAUGGCUUCUCGCCCCCA		15
16538	MI0001550	sbi-MIR166e	Sorghum bicolor miR166e stem-loop	CAAGUUGAAGGUUAGGUUAAUGGGGUUGUUGUCUGGUUCAAGGUCGCCACAGCAGACAAAGCCCAUUUUGCUUAGCAUGCAGCAUGGGUUUAUCUCUAUUGAUGAUCGAUCUCGGACCAGGCUUCAAUCCCUUUAACUAGCAUCUGCAUAU		15
16539	MI0001551	sbi-MIR167d	Sorghum bicolor miR167d stem-loop	GUGGUGCAUCCUCUAGUAGCUGAAGCUGCCAGCAUGAUCUGAUGAGGUGAGGUUUAUUUGCUAGUUGGUCACAGGCUAACAGCAUGAUGGCCCAACAAAUCAACGAUCAGAUCAUGCUGUGCAGUUUCAUCUGCUCGUGGAUGCACAU		15
16540	MI0001552	sbi-MIR167f	Sorghum bicolor miR167f stem-loop	UCCGGUGCACUAGAGGUGGAUGAAGCUGCCAGCAUGAUCUGAGAAACUAGUGCUUGAUCCUUUUACUGAUUUCCAUCUAGCCUGCAUCUAUAUAUAUACCUUGAUGCAUGAAUCAUGGUCUGAUGAUAGUUAAGCGAGAUCAGAUCGUCUGGCAGUUUCAUCUUCUUAUGGCAGCACAA		15
16541	MI0001553	sbi-MIR167g	Sorghum bicolor miR167g stem-loop	AUUUGUGCACCUUAAGCAGCUGAAGCUGCCAGCAUGAUCUGAUCUUAAUUUCUUUUACUGGCAAACUUCGGAUGCCUAAGAUCAGAUCGUGCUGCGCAGUUUCACCUGCUAAUUGGAGCACAG		15
16542	MI0001554	sbi-MIR167e	Sorghum bicolor miR167e stem-loop	AGUGGUGCACCACAAGUUGGUGAAGCUGCCAGCAUGAUCUGAUGUCUUUAUAUAUAUUAAUUACCUCUGAUUUCUCCCUGACUGUUAUGGAUCGAUGAAUUCAGAUAUGAGGGGAAGGAAGAAAGAGGAAUAAUGAGCAUCAGGUCAUGCUGUAGUUUCAUCCGCUGGUGGGAGCACAU		15
16543	MI0001555	sbi-MIR167c	Sorghum bicolor miR167c stem-loop	NCUUUGNUGGUGUGAGAGGUUGAAGCUGCCAGCAUGAUCUGGUGGCCGGNCCGGCCGGCGUCUCUCAAGUGCGCUCGGAUCGGAGACGCGUCGCCAGAUCAUGUUGCAGCUUCACUCUCUCGCAACCACCAAA		15
16544	MI0001556	sbi-MIR168	Sorghum bicolor miR168 stem-loop	GCCGCCGCGCCGCCUCGGGCUCGCUUGGUGCAGAUCGGGACCUGCCGCCGUGCUCGGACGGGACAGAUCCCGCCUUGCACCAAGUGAAUCCGAGCCGGAGCAGCCG		15
16545	MI0001557	sbi-MIR169c	Sorghum bicolor miR169c stem-loop	UGGCGAGAGCCUGCCUUUGGUAGCCAAGGAUGACUUGCCUACACGGCCUUGCGAGUUCCGGUUGCAUGGCCAGUUCAGUUGGGUUUGUGGGCGGUCACCUUGGCUAGCCUGAGUGGCUCUUGCCUG		15
16546	MI0001558	sbi-MIR169d	Sorghum bicolor miR169d stem-loop	UGGCGAGAGCCUGCCUUUGGUAGCCAAGGAUGACUUGCCUACAUGGCAUUGCGAGUUCCGGUUGCAUGGCCAGUUCAGCUGAGUUUGUGGGCGGUCACCUUGGGACGGUAUCGAUAAGCUUGAUA		15
16547	MI0001559	sbi-MIR169e	Sorghum bicolor miR169e stem-loop	AGAGUGGUUGGUAGCUCUGGUAGCCAAGGAUGACUUGCCUGUGUGCCGGCCUCGAUCGAUCUCCCGGCCCUCUCAAGGAUCGAUCAUCGUGCGUGCGUGUCGAUCGAUCGUCGUCGUCGUCGUCACCUCUGGCAGAGAGCGAGACGAUGAUCGAUCGAUUAGCCGCGCGCCUUGGGUUGUUGGGGUGUGGUCGCGGUCUCACAGNCAGUCUCCUUGGCUAGCCCUGACUCACUCUUAUCA		15
16548	MI0001560	sbi-MIR169f	Sorghum bicolor miR169f stem-loop	CGAUGAGAGCACUGCUCUGGUAGCCAAGGAUGACUUGCCUGUGGCCUCCACUCCACCUGCGGCAGGAGGCUCUUCUUCUGCGCGCGCGUGUGUGUGUGGUUGUCGAUCGCAGGCAGUCUCCUUGGCUAGCCUCAGCGGCUCUCAUCCU		15
16549	MI0001561	sbi-MIR169g	Sorghum bicolor miR169g stem-loop	GCGAUAAGAGUCUGCCCAGAUAGCCAAGGAUGACUUGCCUGUGGCCUCUUGGCUUGGCUUGAGAGCUUAUUAACUCUGUGCACGUUUAAUUUGCUCUUCUUGUGGCCUCGAUCACAGGCAGUCUCCUUGGCUAGUCCGGGCGGCUCUUAUCU		15
16550	MI0001562	sbi-MIR169h	Sorghum bicolor miR169h stem-loop	GCGAUAAGAGUCUGCCCAGAUAGCCAAGGAUGACUUGCCUGUGGCCUCUUGGCUUGGCUUGAGAGCUUAUUAACUCUGUGCACGUUUAAUUUGGCUCUUCUUGGGGCCUCGAUCACAGGGCAGUCUCCCUUGGCUAGUCCGGGGCGGGCUCCUUA		15
16551	MI0001563	sbi-MIR169i	Sorghum bicolor miR169i stem-loop	GAUGGAGAGCCCCCUUUUGCUAGCCAAGAAUGACUUGCCUAUGCAUGCCCUCUGUUGGCAAUUCCUCCAGCCAUGGAGAUUGCACAAGGUGAAUUUUUGCGGCAUAGAUGAUGGAUGCAAUGUGGCUGCAUGGGCAGGUCUUCUUGGCUAGCCAGAGUGCUCUCAUCCA		15
16552	MI0001564	sbi-MIR171b	Sorghum bicolor miR171b stem-loop	AUGGCCGCCGCGCGCGACGGGGUAUUGGCGCGGUUCAAUUCGAGAGCUCGAGCCCUAGACUAGACGCCAGGGAGAGAGGGGGCUCUGCUCUCUGAUUGAGCCGUGCCAAUAUCACGUCCCGCUUGAAUGGCU		15
16553	MI0001565	sbi-MIR171d	Sorghum bicolor miR171d stem-loop	NAUAAUGGAAUAGUAGCUAUGAUGUUGGCUCGGCUCACUCAGACCACCUCUCCGAUCCUCAGCUCGUGUCCAUUGCGACAUCGAUCAUGUAUAUAUGUCGCUGGUCGUGGUUUCUGAUUGAGCCGUGCCAAUAUCUCAGUACUCUUCCAUAUAU		15
16554	MI0001566	sbi-MIR171a	Sorghum bicolor miR171a stem-loop	UUGGUUGGCUGAGAGAGUGCGAUGUUGGCAUGGUUCAAUCAAAUCAUCGCCCGGCAAGGUGACUUAAAUUUUGCGCUUUCGAUCGAUCGAGGUGCAGGGAGGUGUUUCCAGGCACCGUGUUUGAUUGAGCCGUGCCAAUAUCACAACCUUCUCUAGCCUAU		15
16555	MI0001567	sbi-MIR171c	Sorghum bicolor miR171c stem-loop	AGAACGAGACGACAUGGCAUGGUAUUGACUUGGCUCAUCUCUCAUCCACAGCAAACUUCACAAGUGCCUGAGGUGAGCCGAGCCAAUAUCACUUCAUGUCAUCUAGCGU		15
16556	MI0001568	sbi-MIR172e	Sorghum bicolor miR172e stem-loop	UCGGAGCCGACUCUCUGCAGGUGCAGCAGCAUCAAGGUUCGCCAGCAGCAAGCGAUCGAUCGAGGCGUGUGUGUGUGAAUCUUGAUGAUGCUGCACCAGCAAUGAGCCGGCCGGC		15
16557	MI0001569	sbi-MIR166f	Sorghum bicolor miR166f stem-loop	CCUUGGUCAUGGGGGUUUGUGGGGAAUGUUGGCUGGCUCGAGGCAUCCGCGUCCUGGCUUGCAGAUCGUUUUGCCUGCUACCGGAAAGAUCGAGAGGCGUCGGACCAGGCUUCAUUCCUCGCAAACCGGUGCAUCCAUG		15
16558	MI0001570	sbi-MIR171e	Sorghum bicolor miR171e stem-loop	AGGAGGAAGAAGACGACAUGGCGUGGUAUUGUUUCGGCUCAUGUCCUUCUUGCUUCGAGUCUGUCGUCGGAUUUUGGAUGUGAUGUGAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCUGA		15
16559	MI0001571	sbi-MIR172d	Sorghum bicolor miR172d stem-loop	AAACAGUCGGUGCUUGCAGGUGCAGCACCAUCAAGAUUCACAUCCCCAGCUCGAUCUGUGCAUGAUGAGAUGAGAAUCUUGAUGAUGCUGCAUCAGCAAACACUCACUUAC		15
16560	MI0001572	sbi-MIR159	Sorghum bicolor miR159 stem-loop	AGCGGAGCUCCUAUCAUUCCAAUGAAGGGCCCUUUUCAUGGGUGGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUAUGUGUGUAUGUACUCUAGAGGGCCCGAGAAGAGAUUCAUGUGGUCGUCAGUCUUUGAGAUAGGCUUGUGGUUUGCAUGACCGAGGAGCUGCACCGUCCCCUUGCUGGCCGCUCUUUGGAUUGAAGGGAGCUCUGCA		15
16561	MI0001573	sbi-MIR319	Sorghum bicolor miR319 stem-loop	CUGCCGCCAUGGUUGUGAUAUGGCCGGAUGGAAGAGAGCGUCCUUCAGUCCACUCAGGGGCGGUGCUAGGGUCGAAUUAGCUGCCGACUCAUUCACCCACAUGCCAAGCAAACGGCCAUGGAAACGAGCUAGCUUUGCAGAUGAGUGAAUGAAGCGGGAGGUAAAAGCUUCGAUCUCGCACCAUCUUUGCUUGGACUGAAGGGUGCUCCCUCCUCCCCUCCUUAAUUGUUUACUUUACCCAUGGCGCAG		15
16562	MI0001574	ame-bantam	Apis mellifera bantam stem-loop	UCGAAAACGAAACUGGUUUUCACAAUGAUUUGACAGAUAGAUUCGAUUCUGAGAUCAUUGUGAAAGCUGAUUUUGUUGAAAAGUCGA		18
16563	MI0001575	ame-mir-1	Apis mellifera miR-1 stem-loop	CCGGGCGAUGCUGUUCCGUGCUUCCUUACUUCCCAUAGUGGAUGCGACGUAUGGAAUGUAAAGAAGUAUGGAGCUGCGCCCGG		18
16564	MI0001576	ame-mir-12	Apis mellifera miR-12 stem-loop	AAGACAUGGGUGUGAGUAUUACAUCAGGUACUGGUGUGAUAUUCAGACAACCAGUACUUGUGUUAUACUUACGCUCAUGUCUU		18
16565	MI0001577	ame-mir-124	Apis mellifera miR-124 stem-loop	UGCUCCUUGCGUUCACUGCGGGCUUCCAUGUGCCAACUUUUCAAAAUUCAUAAGGCACGCGGUGAAUGCCAAGAGCG		18
16566	MI0001578	ame-mir-125	Apis mellifera miR-125 stem-loop	GUAAAGCCUGCCGCGUCGCCGGUCCCCUGAGACCCUAACUUGUGACGUCGCGACCGAUAUCUCACAGGCUAGAUUCUCUGGUAUUGGCGAUGAGUGCUGCCUUUUGC		18
16567	MI0001579	ame-mir-133	Apis mellifera miR-133 stem-loop	UAAUGUUAAGCUUAGCUGGUUGAACACGGGUCAAAUAUAUCGCACGAUUGACGCAUUUGGUCCCCUUCAACCAGCUGUAGUUGACAUUA		18
16568	MI0001580	ame-mir-184	Apis mellifera miR-184 stem-loop	UUCGUGCCCAAAGCCCCUUAUCAUUCUCCUGUCCGGUGUAGAAUUGUUAGACGACUGGACGGAGAACUGAUAAGGGCCCGAGGGUCACAGAA		18
16569	MI0001581	ame-mir-210	Apis mellifera miR-210 stem-loop	UGGACCCUAAUGCAGCUGCUGGCCACUGCACAAGAUUAGACAUAAGACUCUUGUGCGUGUGACAGCGGCUAUGAUGGGGUUUCCA		18
16570	MI0001582	ame-mir-219	Apis mellifera miR-219 stem-loop	AAUUGAAUGUCUCAGGCAAUGAUUGUCCAAACGCAAUUCUUGUCUAAACGGUACGAAAUCAAGAAUUGUGUGGGGACAUCAGCGCUCGAGGUGCGAUUCAAC		18
16571	MI0001583	ame-mir-263	Apis mellifera miR-263 stem-loop	AGCUUGGACUCUGUAAAUGGCACUGGAAGAAUUCACGGGGGAUUUAAGAAACGGGCCCGUGGAGCUCCCGUGUCAUACACAGCGUCCGGCU		18
16572	MI0001584	ame-mir-276	Apis mellifera miR-276 stem-loop	UGGUAGAGAUCCAGCAGCGAGGUAUAGAGUUCCUACGUAGUGUUCAGAAAGUAGGAACUUCAUACCGUGCUCUUGGACUUGCCG		18
16573	MI0001585	ame-mir-277	Apis mellifera miR-277 stem-loop	GGCAGUUGGGGCUCGUGCCAGAUGCGCGUUUACACGGGCCCUGAAUACUGUAAAUGCACUAUCUGGUACGACAUCUCUCCUGUC		18
16574	MI0001586	ame-mir-278	Apis mellifera miR-278 stem-loop	UCACGAGUAGUGUGUCCGGAUGAGGUCUUCAUCGACCGUGAUUUAAUUUCAUAAGGUCGGUGGGACUUUCGUCCGUUUGCAAGACUCGAGGA		18
16575	MI0001587	ame-mir-281	Apis mellifera miR-281 stem-loop	CGACGAAAGGCGCGCGCUAUAAAGAGAGCUAUCCAUCGACAGUAUGGUUAUAAUAGACACUGUCAUGGAGUUGCUCUCUUUGUAGACACUGCUAUGUUCAACG		18
16576	MI0001588	ame-mir-282	Apis mellifera miR-282 stem-loop	GGACAGAGUAACUUGAUUUAGCCUCUCCUAGGCUUUGUCUGUAUAUAAAGAACGGAGACAUAGCCUAGAAUAGGUUAGGUCAGGGCUCGUUC		18
16577	MI0001589	ame-mir-2-1	Apis mellifera miR-2-1 stem-loop	GGCGCGUGUGCACCGCUCACAAAGUGGUUGUGAUAUGCUGAUACGAGCGUUCAUAUCACAGCCAGCUUUGAUGAGCGUGGCGUCGCGUC		18
16578	MI0001590	ame-mir-2-2	Apis mellifera miR-2-2 stem-loop	UCGACUGUUCCUCCCAUCAGAGUGGUUGUGAUGUGGUAACUUGGACUCGUAUCACAGCCAGCUUUGAUGAGCGGAACGGUGCGA		18
16579	MI0001591	ame-mir-305	Apis mellifera miR-305 stem-loop	GGAGGCUGCAUGUUAAUUGUACUUCAUCAGGUGCUCUGGUGAACUCGAUACCCGGCACCUGUUGGAGCGCAAUUCAUAUGACUGUGCCCU		18
16580	MI0001592	ame-mir-315	Apis mellifera miR-315 stem-loop	GCUCUUUAUGCUUUUGAUUGUUGCUCAGAAAGCCUUGAUUAUGAUAUUGGCUUUCGGGCAAUAAUCAUAAUCACGAAAGGGU		18
16581	MI0001593	ame-mir-317	Apis mellifera miR-317 stem-loop	GCUCUCGGAGAACAGGGAGCCACUCUGCGUUCACUCGGUGGGUAAUGAAGCGGGUGAACACAGCUGGUGGUAUCUCAGUUUUCUGAGGGC		18
16582	MI0001594	ame-mir-7	Apis mellifera miR-7 stem-loop	CGAGCGCCGUUGCAUGGAAGACUAGUGAUUUUGUUGUUCUACUUUCGAUAUAACAAGGAAUCACUAAUCAUCCUACAAAGGCGCUCG		18
16583	MI0001595	ame-mir-8	Apis mellifera miR-8 stem-loop	GGAGUAUCUGUUCACAUCUUACCGGGCAGCAUUAGAUUGAAGUUGACCUUCUAAUACUGUCAGGUAAAGAUGUCGUCAGGAUUCC		18
16584	MI0001596	ame-mir-9a	Apis mellifera miR-9a stem-loop	UGGCGCGGACAUUUUCUUUGGUUAUCUAGCUGUAUGAGUAUUAUUCGACAUCAUAAAGCUAGGUUACCGGAGUUAAGCUCCUCGCCA		18
16585	MI0001597	ame-mir-9b	Apis mellifera miR-9b stem-loop	UAAUGCUAGUGCUCUUUGCUUUGGUAAUCUAGCUUUAUGAUCCUUAAUUAAAAUCAUAGAGCUAUAUUACCAAAGUAAAGGCAAAAGCUUUG		18
16586	MI0001598	ame-mir-iab-4	Apis mellifera miR-iab-4 stem-loop	GUGAAACCCCCUGUACGUAUACUGAAUGUAUCCUGAGUGUAUUUCUGUCCGGUAUACCUUCAGUAUACGUAACAGGAGGCUACAC		18
16587	MI0001599	aga-bantam	Anopheles gambiae bantam stem-loop	UGUGUGGAUGAAAUGUAAUCACAGAACCGGUUUUCAUUUUCGAUCUGACUUAUUUUUUUCACAAACAAGUGAGAUCACUUUGAAAGCUGAUUUUGUACAAUUAAUUCAACG		19
16588	MI0001600	aga-let-7	Anopheles gambiae let-7 stem-loop	GCCUACUCCCGUGUUGAGGUAGUUGGUUGUAUAGUACCGUGGUUCCAAUACUCGACUAUACAAUCCGCUAACUUACCUCGUGGGUAGAGU		19
16589	MI0001601	aga-mir-1	Anopheles gambiae miR-1 stem-loop	GAAGCAAAGCUGCGAAAGUUCCAUGCUUCCUUGCAUUCAAUAGUAUGUUUGUAAAACCCUAUGGAAUGUAAAGAAGUAUGGAGCGAUUGGGCUAGUUC		19
16590	MI0001602	aga-mir-10	Anopheles gambiae miR-10 stem-loop	GUCGAUUUAUGUUCUACAUCCACCCUGUAGAUCCGAAUUUGUUUGAAUUUAUAUUAAUAACAAAUUCGGUUCUAGAGAGGUUUGUGUGGGGCAUUUGUUAAC		19
16591	MI0001603	aga-mir-100	Anopheles gambiae miR-100 stem-loop	GCCCCGUCUGUGGAAACCCGUAGAUCCGAACUUGUGCUGCACUGUACAACUGGACACAAGAACGGAUAUAUGGGAUUCUGUCGACGGUUGGC		19
16592	MI0001604	aga-mir-124	Anopheles gambiae miR-124 stem-loop	CGUUUUUCUCCUGGUGUUCACUGUAGGCCUGUAUGUUCUAUUGCGGAUUUCAUAAGGCACGCGGUGAAUGCCAAGAGCGAACG		19
16593	MI0001605	aga-mir-125	Anopheles gambiae miR-125 stem-loop	UAUUGUUUCGUUUUUUUGUAUCUGCUGAUUCCCUGAGACCCUAACUUGUGACUAUCGUUGCAAAGUUUCACAAGUUUUGAUCUCCGGUAUUAGCGGUUGAGAUGCAACGGUA		19
16594	MI0001606	aga-mir-133	Anopheles gambiae miR-133 stem-loop	UGUUGACGCAAUAUUUUCCCUUUGCGAAUGCAUUUGGUCCCCUUCAACCAGCUGUAGCAGUGAUUGCAAUCAACAGU		19
16595	MI0001607	aga-mir-13b	Anopheles gambiae miR-13b stem-loop	UGCUCGUGGUCAGGUCGUAAAAAUGGUUGUGCCGUGUCGAUUUAAGAAAAGUUCAUAUCACAGCCAUUUUGACGAGUUUGACCACUCUUGAGCA		19
16596	MI0001608	aga-mir-14	Anopheles gambiae miR-14 stem-loop	GCCCGAUAAGCCUGUGGGAGCGAGAUUAAGGCUUGCUGGUUAUCACGUUAAACGUAGUCAGUCUUUUUCUCUCUCCUAUCGGUACUAACGGUGC		19
16597	MI0001609	aga-mir-184	Anopheles gambiae miR-184 stem-loop	GGUGCACUCGAACCCUUAUCAUUCUUUCGCCCCGUGUGCUUUCUAACAACUGGACGGAGAACUGAUAAGGGCCCGGGUCACC		19
16598	MI0001610	aga-mir-210	Anopheles gambiae miR-210 stem-loop	GAAAUUCAUUGCAGCUGCUGACCACUGCACAAGAUUAGAAUGCGACUCUUGUGCGUGUGACAACGGCUAUUAUGGGUUUU		19
16599	MI0001611	aga-mir-219	Anopheles gambiae miR-219 stem-loop	UUUCUAGCUCUGAUUGUCCAAACGCAAUUCUUGUCCUGUGCUGGUUUAGCUACUCAAGAGUUGUGACUGGACAUCCGUGGCUCGGAA		19
16600	MI0001612	aga-mir-263	Anopheles gambiae miR-263 stem-loop	CCCUGGUACAUGUAAUGGCACUGGAAGAAUUCACGGGAUUUUUUUCAACAUUCCCGUGUUCUCUUAGUGGCAUACCUAGUACAGGG		19
16601	MI0001613	aga-mir-275	Anopheles gambiae miR-275 stem-loop	UGAGCCGUCUAAUGACACGCGCUAAGCAGGAACCGGGACUUGGUACACAUUCGCUAGCAGUCAGGUACCUGAAGUAGCGCGCGUUAUUCGGCUCA		19
16602	MI0001614	aga-mir-276	Anopheles gambiae miR-276 stem-loop	GGUGACUGCCAUCAGCGAGGUAUAGAGUUCCUACGGUAAUCGAUUGAAACUUUGUAGGAACUUCAUACCGUGCUCUUGGAUAGCCGUUUACC		19
16603	MI0001615	aga-mir-277	Anopheles gambiae miR-277 stem-loop	GUUUUGGGGUACGUGUCAGAGGUGCAUUUACAUCGAACUAUUCCAGUUGAGGUAUUUGUAAAUGCACUAUCUGGUACGACAUUCCAGAAU		19
16604	MI0001616	aga-mir-278	Anopheles gambiae miR-278 stem-loop	GGUACGGUACGGACGGACGAUAGUCUUCAACGACCGUUCCGUUUGACACGAGGUCGGUGGGACUUUCGUCCGUUUGUAAGGCC		19
16605	MI0001617	aga-mir-279	Anopheles gambiae miR-279 stem-loop	UUCCUAUCAGUGUAAAUGGGUGUGAAUCUAGUGAUUUCACAUGAAUUUUCGAUUGUGACUAGAUCCACACUCAUUAAUGUUGUUUGGAA		19
16606	MI0001618	aga-mir-281	Anopheles gambiae miR-281 stem-loop	GCAAUCGAAUAUGAAAAUAAAGAGAGCUAUCCGUCGACAGUAGGGAUAUAAUUCACUGUCAUGGAAUUGCUCUCUUUAUGUACAAUUCGAUAUUCAACGUGC		19
16607	MI0001619	aga-mir-282	Anopheles gambiae miR-282 stem-loop	GUAACAGAGCUAAUCUAGCCUCUUCUAGGCUUUGUCUGUACAGUUUCUGCAAACCAGACAUAGCCUGUCAGAGGUUAGGUGAAAUCUGCUAGC		19
16608	MI0001620	aga-mir-283	Anopheles gambiae miR-283 stem-loop	UUCGACCGAAAGGUAAAUAUCAGCUGGUAAUUCUAGGCUAUCAAUCCAUCGUGCAUCCCGGGAUUUCAGCUGAUAUCCACUUUUCCGUCGAG		19
16609	MI0001621	aga-mir-2-1	Anopheles gambiae miR-2-1 stem-loop	GCGAAAGCGUCACACGGCCUAGCUCAUCAAAGCUGGCUGUGAUAUGAGAUAUCGGAUCGAAAGUGCACCAUUUCACAGCCACUUUGAGAGACAGGACAUGCGUUUGC		19
16610	MI0001622	aga-mir-2-2	Anopheles gambiae miR-2-2 stem-loop	GUGACGCAUUGCUCAUCAAAGCUGGCUGUGAUAGCAACUAUCAAAGCAAGCUACAACAACCAAGUUUGAUGACAAUGCAUGGC		19
16611	MI0001623	aga-mir-305	Anopheles gambiae miR-305 stem-loop	UUUGUCACAUGUCUAUUGUACUUCAUCAGGUGCUCUGGUGGAUUUGAGAAAACCCGGCACAUGUUGGAGUACACUCUAUGUGCUGACAAG		19
16612	MI0001624	aga-mir-307	Anopheles gambiae miR-307 stem-loop	UGGACUCAUUCUCUCGAUCACUCACUCAACCUGGGUGUGAUGCUUUUUUGAAUCAUCACAACCUCCUUGAGUGAGCGACCGCGGAUUGACUAAAACCA		19
16613	MI0001625	aga-mir-308	Anopheles gambiae miR-308 stem-loop	GCUUCUCGUGCGAUGUUUCGCAGUAUAUCCCUGUGAGUUUGCUACUUUUCAAUGGUCAAAUCACAGGAGUAUACUGUGAGAUGUUGCCGGUUACUUAGGC		19
16614	MI0001626	aga-mir-315	Anopheles gambiae miR-315 stem-loop	UAUAAAAUUUUGAUUGUUGCUCAGAAAGCCGUGUCGAUUAAGCAAUUCGCUUUCGGGCAGUAAUCAAAGUCAAAUA		19
16615	MI0001627	aga-mir-317	Anopheles gambiae miR-317 stem-loop	CGUCUCUGCCACUGGGAUACUCCUUGUGCUCGCUGUGCAUAUCGAUUCAAACUAGUGAACACAUCUGGUGGUAUCUCAGUGGCCGGGAUG		19
16616	MI0001628	aga-mir-7	Anopheles gambiae miR-7 stem-loop	GGCAAAACAUUGUAUGGAAGACUAGUGAUUUUGUUGUUUGGCUUAUGAUACUAACAAUAAAUCUCUCGUCUUUCUACAAAGUUUGCC		19
16617	MI0001629	aga-mir-79	Anopheles gambiae miR-79 stem-loop	GUGCCCUUUUGUCCGCGCUUUGGCGCUUUAGCUGUAUGAUAGAAUUUGAACUAUUUCAUAAAGCUAGAUUACCAAAGCAUAGACGAAUUGGGAC		19
16618	MI0001630	aga-mir-8	Anopheles gambiae miR-8 stem-loop	GGGUGUCUGUUCACAUCUUACCGGGCAGCAUUAGAUAUGUUAUCGGAUAUUUCUAAUACUGUCAGGUAAAGAUGUCGUCCGAGCCC		19
16619	MI0001631	aga-mir-9a	Anopheles gambiae miR-9a stem-loop	GUCAAUGUUCUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUUUAAACGUCAUAAAGCUAGCAUACCGAAGUUAAUAAUUGAC		19
16620	MI0001632	aga-mir-92a	Anopheles gambiae miR-92a stem-loop	UCAGGACUACGCGUCGGCCGGCUCAAGAGCAAAAUUGUGUUUCAUACUAAUAUUGCACUUGUCCCGGCCUAUGUGUGGUAAGGCCUGAA		19
16621	MI0001633	aga-mir-92b	Anopheles gambiae miR-92b stem-loop	GGGCUCCGGAUGUAGGACGUGACAGGUGCAUUAUUUGCUGAUUUUCAAUGUCAAAUUGCACUUGUCCCGGCCUGCAGCUUACCGCCC		19
16622	MI0001634	aga-mir-9b	Anopheles gambiae miR-9b stem-loop	UGCCACUUAUUGGGACUUUGGUGAUUUUAGCUGUAUGUUGAAUGCAUUCCUAACCACAUAUAGCUUUAUCACCAAAAACCUAAUGUGUGUGUA		19
16623	MI0001635	aga-mir-9c	Anopheles gambiae miR-9c stem-loop	UUUCCGGCUGUAUCUUUGGUAUUCUAGCUGUAGAAUGUUGUUUUCAUUGUAAUAUCUCUAAAGCUUUAGUACCAGAGGUCCAACUGGGAA		19
16624	MI0001636	aga-mir-iab-4	Anopheles gambiae miR-iab-4 stem-loop	GUGCCGCUUCAUGAACGUAUACUGAAUGUAUCCUGAGUGCUACUUAUCCGGUAUACCUUCAGUAUACGUAACAAGAGGCGACAC		19
16625	MI0001637	hsa-mir-448	Homo sapiens miR-448 stem-loop	GCCGGGAGGUUGAACAUCCUGCAUAGUGCUGCCAGGAAAUCCCUAUUUCAUAUAAGAGGGGGCUGGCUGGUUGCAUAUGUAGGAUGUCCCAUCUCCCAGCCCACUUCGUCA	Xie et al. [1] refer to this sequence by the internal identifier MIR64. The sequence is unrelated to C. elegans mir-64 (MIR:MI0000035). 	5
16626	MI0001638	mmu-mir-448	Mus musculus miR-448 stem-loop	ACGAGGAGGUUGAACAUCCUGCAUAGUGCUGCCAGGAAAUCCCUACUUCAUACUAAGAGGGGGCUGGCUGGUUGCAUAUGUAGGAUGUCCCAUCUCCUGGCCCACUUCGUCA	Xie et al. [1] refer to this sequence by the internal identifier MIR64. The sequence is unrelated to C. elegans mir-64 (MIR:MI0000035). 	6
16627	MI0001639	rno-mir-448	Rattus norvegicus miR-448 stem-loop	ACGGGGAGGUUGAACAUCCUGCAUAGUGCUGCCAGGAAAUCCCUACUUCAUACUAAGAGGGGGCUGGCUGGUUGCAUAUGUAGGAUGUCCCAUCUCCCGGCCCACUUCGUCA	Xie et al. [1] refer to this sequence by the internal identifier MIR64. The sequence is unrelated to C. elegans mir-64 (MIR:MI0000035). 	8
16628	MI0001640	cfa-mir-448	Canis familiaris miR-448 stem-loop	GCAGGGAGGUUGAACAUCCUGCAUAGUGCUGCCAGGAAAUCCCUAUUUUAUACUAAGGGGGCUGGCUGGUUGCAUAUGUAGGAUGUCCCAUCUCCCCGCCCACUUCAUCG	Xie et al. [1] refer to this sequence by the internal identifier MIR64. The sequence is unrelated to C. elegans mir-64 (MIR:MI0000035). 	20
16629	MI0001641	hsa-mir-429	Homo sapiens miR-429 stem-loop	CGCCGGCCGAUGGGCGUCUUACCAGACAUGGUUAGACCUGGCCCUCUGUCUAAUACUGUCUGGUAAAACCGUCCAUCCGCUGC	Xie et al. [1] refer to this sequence by the internal identifier MIR201. The sequence is unrelated to mouse mir-201 (MIR:MI0000244). 	5
16630	MI0001642	mmu-mir-429	Mus musculus miR-429 stem-loop	CCUGCUGAUGGAUGUCUUACCAGACAUGGUUAGAUCUGGAUGCAUCUGUCUAAUACUGUCUGGUAAUGCCGUCCAUCCACGGC	Xie et al. [1] refer to this sequence by the internal identifier MIR201. The sequence is unrelated to mouse mir-201 (MIR:MI0000244). 	6
16631	MI0001643	rno-mir-429	Rattus norvegicus miR-429 stem-loop	UGCCUGCUGAUGGAUGUCUUACCAGACAUGGUUAGAUCUGGAUGUAUCUGUCUAAUACUGUCUGGUAAUGCCGUCCAUCCAUGGC	Xie et al. [1] refer to this sequence by the internal identifier MIR201. The sequence is unrelated to mouse mir-201 (MIR:MI0000244). 	8
16632	MI0001644	cfa-mir-429	Canis familiaris miR-429 stem-loop	AGCCUGCUGAUGGGCGUCUUACCAGACACGGUUAGAUCUGGGUUCUGGUGUCUAAUACUGUCUGGUAAUGCCGUUCAUCCAUGGC	Xie et al. [1] refer to this sequence by the internal identifier MIR201. The sequence is unrelated to mouse mir-201 (MIR:MI0000244). 	20
16633	MI0001645	mmu-mir-365-2	Mus musculus miR-365-2 stem-loop	AGAGUGAUCAAGGACAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUCCUGACUCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCAGUGUGCAUCGGAG	Xie et al. [1] refer to this sequence by the internal identifier MIR190. The sequence is unrelated to mammalian mir-190 (MIR:MI0000486). 	6
16634	MI0001647	cfa-mir-365-2	Canis familiaris miR-365-2 stem-loop	AGAGUGUUCAAGGACAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUUCUGACUCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCAGUGUGCAUCGGG	Xie et al. [1] refer to this sequence by the internal identifier MIR190. The sequence is unrelated to mammalian mir-190 (MIR:MI0000486). 	20
16635	MI0001648	hsa-mir-449a	Homo sapiens miR-449a stem-loop	CUGUGUGUGAUGAGCUGGCAGUGUAUUGUUAGCUGGUUGAAUAUGUGAAUGGCAUCGGCUAACAUGCAACUGCUGUCUUAUUGCAUAUACA	Xie et al. [1] refer to this sequence by the internal identifier MIR54. The sequence is unrelated to C. elegans mir-54 (MIR:MI0000025). 	5
16636	MI0001649	mmu-mir-449a	Mus musculus miR-449a stem-loop	CUGUGUGUGAUGGCUUGGCAGUGUAUUGUUAGCUGGUUGAGUAUGUGAGCGGCACCAGCUAACAUGCGACUGCUCUCCUAUUGCACACACA	Xie et al. [1] refer to this sequence by the internal identifier MIR54. The sequence is unrelated to C. elegans mir-54 (MIR:MI0000025). 	6
16637	MI0001650	rno-mir-449a	Rattus norvegicus miR-449a stem-loop	CUGUGUGCGAUGGGUUGGCAGUGUAUUGUUAGCUGGUUGAGUAUGUAAAAGGCACCAGCUAACAUGCAACUGCUCUCCUAUUGCACAUACA		8
16638	MI0001651	cfa-mir-449	Canis familiaris miR-449 stem-loop	CCGUGUGUGAUGGGUUGGCAGUGUAUUGUUAGCUGGUUGAAUAUAUGAAUGGCAUCAGCUAACAUGCAACUGCUAUCUUAUUGCAUAUACA	Xie et al. [1] refer to this sequence by the internal identifier MIR54. The sequence is unrelated to C. elegans mir-54 (MIR:MI0000025). 	20
16639	MI0001652	hsa-mir-450a-1	Homo sapiens miR-450a-1 stem-loop	AAACGAUACUAAACUGUUUUUGCGAUGUGUUCCUAAUAUGCACUAUAAAUAUAUUGGGAACAUUUUGCAUGUAUAGUUUUGUAUCAAUAUA	Xie et al. [1] refer to this sequence by the internal identifier MIR238. The sequence is unrelated to C. elegans mir-238 (MIR:MI0000313).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
16640	MI0001653	mmu-mir-450a-1	Mus musculus miR-450a-1 stem-loop	GAGAGAUACUGAGCUGUUUUUGCGAUGUGUUCCUAAUAUGUGCUAUAAUUAUAUUGGGAACAUUUUGCAUAAAUAGCUUUGUGUCAAUACA	Xie et al. [1] refer to this sequence by the internal identifier MIR238. The sequence is unrelated to C. elegans mir-238 (MIR:MI0000313).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
16641	MI0001654	rno-mir-450a	Rattus norvegicus miR-450a stem-loop	GAGAGAUGCGGAGCUGUUUUUGCGAUGUGUUCCUAAUGUGUGCUACAAUUAUAUUGGGAACAUUUUGCAUAAAUAGUUUUACAUCGACACA	Xie et al. [1] refer to this sequence by the internal identifier MIR238. The sequence is unrelated to C. elegans mir-238 (MIR:MI0000313). 	8
16642	MI0001655	cfa-mir-450a	Canis familiaris miR-450 stem-loop	GAAAGAUGCUGAACUGUUUUUGCGAUGUGUUCCUAAUAUGCAGUAUGAACAUAUUGGGAGCAUUUUGCAUGCAUGGUUUUGUAUCAAUAUA	Xie et al. [1] refer to this sequence by the internal identifier MIR238. The sequence is unrelated to C. elegans mir-238 (MIR:MI0000313). 	20
16643	MI0001656	rno-mir-365	Rattus norvegicus miR-365 stem-loop	ACAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUCCUGACUCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCA	Xie et al. [1] refer to this sequence by the internal identifier MIR245. The sequence is unrelated to C. elegans mir-245 (MIR:MI0000321). 	8
16644	MI0001657	cfa-mir-365-1	Canis familiaris miR-365-1 stem-loop	ACCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUCCACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA	Xie et al. [1] refer to this sequence by the internal identifier MIR245. The sequence is unrelated to C. elegans mir-245 (MIR:MI0000321). 	20
16645	MI0001669	mghv-mir-M1-1	Mouse gammaherpesvirus 68 miR-M1-1 stem-loop	UGGUCGAGGAAGUGGGUCCAACUUUAUCCCUAUAGUGUGAUAGAAAUGGCCGUACUUCCUUUAUA		21
16646	MI0001670	mghv-mir-M1-2	Mouse gammaherpesvirus 68 miR-M1-2 stem-loop	GAGAGGGGGAGUGUGUGGUCUGUAGAGAGACAUGAGUUGAUCGGCAGACCCCCUCUCCCCCUCUUU		21
16647	MI0001671	mghv-mir-M1-3	Mouse gammaherpesvirus 68 miR-M1-3 stem-loop	GAAGUAGCGAACCUCUGCUCACUGCCCGGGCCCUCCGGGAGGUGAGCAGGAGUUGCGCUUU		21
16648	MI0001672	mghv-mir-M1-4	Mouse gammaherpesvirus 68 miR-M1-4 stem-loop	CGAGCCCUGACCAUCGAGGAGCACGUGUUAUUCUAGACCUCUCUUCCAGCUAAGAUAGCAUGUGCCGUCCUCUUUGUUUCCCAAGUCAGUAUUC		21
16649	MI0001673	mghv-mir-M1-5	Mouse gammaherpesvirus 68 miR-M1-5 stem-loop	CAGAGUUGAGAUCGGGUCGUCUCCCCCUGGCGGAAGGAGGCAAACCCGAGCUCCUCCUUC		21
16650	MI0001674	mghv-mir-M1-6	Mouse gammaherpesvirus 68 miR-M1-6 stem-loop	AACCACCUCCCACAAUUUCAGAGUCUUAGCCAGAUUAUCUGAAACUGUGUGAGGUGGUUUUU		21
16651	MI0001675	mghv-mir-M1-7	Mouse gammaherpesvirus 68 miR-M1-7 stem-loop	AAAGGUGGAGGUGCGGUAACCUCCUAAGAUUACUGUUGGGAUAUCGCGCCCACCUUUAUU		21
16652	MI0001676	mghv-mir-M1-8	Mouse gammaherpesvirus 68 miR-M1-8 stem-loop	UUUACCAGCACUCACUGGGGGUUUGGUCAGGAGAUCAAGUAGAUCUGACCAACCCUAAGUGAGUUUUUCUU		21
16653	MI0001677	mghv-mir-M1-9	Mouse gammaherpesvirus 68 miR-M1-9 stem-loop	UGAGGUUCCCGGCAAAUGUUGGAUAGAUAGGUAACUUCUCACAUUUGCCUGGACCUUUUU		21
16654	MI0001678	hcmv-mir-UL22A	Human cytomegalovirus miR-UL22A stem-loop	CCUGUCUAACUAGCCUUCCCGUGAGAGUUUAUGAACAUGUAUCUCACCAGAAUGCUAGUUUGUAGAGG		22
16655	MI0001679	hcmv-mir-UL36	Human cytomegalovirus miR-UL36 stem-loop	CCACGUCGUUGAAGACACCUGGAAAGAGGACGUUCGCUCGGGCACGUUCUUUCCAGGUGUUUUCAACGUGCGUGG		22
16656	MI0001680	hcmv-mir-UL112	Human cytomegalovirus miR-UL112 stem-loop	GACAGCCUCCGGAUCACAUGGUUACUCAGCGUCUGCCAGCCUAAGUGACGGUGAGAUCCAGGCUGUC		22
16657	MI0001681	hcmv-mir-UL148D	Human cytomegalovirus miR-UL148D stem-loop	AGCAGGUGAGGUUGGGGCGGACAACGUGUUGCGGAUUGUGGCGAGAACGUCGUCCUCCCCUUCUUCACCGCC		22
16658	MI0001682	hcmv-mir-US5-1	Human cytomegalovirus miR-US5-1 stem-loop	UGAACGCUUUCGUCGUGUUUUUCAUGCAGCUUUUACAGACCAUGACAAGCCUGACGAGAGCGUUCA		22
16659	MI0001683	hcmv-mir-US5-2	Human cytomegalovirus miR-US5-2 stem-loop	GGAGGCUUUCGCCACACCUAUCCUGAAAGCGUUGCAUUCUUUAUGAUAGGUGUGACGAUGUCUUU		22
16660	MI0001684	hcmv-mir-US25-1	Human cytomegalovirus miR-US25-1 stem-loop	UGUGAACCGCUCAGUGGCUCGGACCGCCGGCUGUUUCUGCGCACCGGUCCGAACGCUAGGUCGGUUCUCA		22
16661	MI0001685	hcmv-mir-US25-2	Human cytomegalovirus miR-US25-2 stem-loop	CGGUUAGCGGUCUGUUCAGGUGGAUGAGGGCUCUUCACGGUCGGGCACUCGGCUGUGCCUGUCAUCCACUUGGAGAGCUCCCGCGGUCCG		22
16662	MI0001686	hcmv-mir-US33	Human cytomegalovirus miR-US33 stem-loop	CACGGUUGAUUGUGCCCGGACCGUGGGCGCGACGAAACCCACCGUCACGGUCCGAGCACAUCCAAACGUG	The mature miRNA names reflect cloning frequencies from Landgraf et al. [2], and may differ subtly from previous annotations. 	22
16663	MI0001687	osa-MIR435	Oryza sativa miR435 stem-loop	UUCCACCUUCCCAAAAACUCCCCAGCAGACCUGGAGCGAAAAUUGCCUUGAAUUAGCUUCAGACCUAUAGUGUCGUUGAUAGUUUAGGGACAUGUUUUAUCCGGUAUUGGAGUUGAGGGAUGAAAAUUGGAC		7
16664	MI0001688	osa-MIR437	Oryza sativa miR437 stem-loop	CCCUCUGUUUCAUAUUGUAUUGUGUUUUAGUUUUGUUGUAAGUCAAAAUUCUUUUACUUUGACCAAGUUUGUAGUAAAAUAAUUAACAUCUAAAAUACCAAAUAAAUACACUAUUGAGACAUAUUUCUUGGUUGAUUUUUCUAUAAACUUGGUCAAAGUUAGAGAAGUUUGACUUAGGACAAAACUAAACACCUUAUGAUAUGGAACAGAGGG		7
16665	MI0001689	osa-MIR438	Oryza sativa miR438 stem-loop	AACGUGUUUUGGGCAAACUUGUUUUCCCACGCGUUAUAGUGAAAACUUUUGGAAUAUGUUUGUUAUGGGAGUAUAUAUUAUUGAUAUUGGAUCUAGAAGCAUAAUUUUAUAUAACGUGUGUUACGGGUGGACAUGGUUUCAAAAGUUUUCACUUUAACGCGUGGGAUAUCAUCUACUUCCUCCGUU		7
16666	MI0001690	osa-MIR390	Oryza sativa miR390 stem-loop	GGUAUGGAACAAUCCUUGAAGCUCAGGAGGGAUAGCGCCUCGAAAUCAAACUAGGCGCUAUCUAUCCUGAGCUCCAUGGUUUGUUCUUACC		7
16667	MI0001691	osa-MIR439a	Oryza sativa miR439a stem-loop	UACCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUG		7
16668	MI0001692	osa-MIR439b	Oryza sativa miR439b stem-loop	UUCCUGUCGAAUUGUGGUUGUUCGAUAGGUACCCCUGUCGAACCGCGGUUGUUCGACAGG		7
16669	MI0001693	osa-MIR439c	Oryza sativa miR439c stem-loop	UACCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUG		7
16670	MI0001694	osa-MIR439d	Oryza sativa miR439d stem-loop	CCACCUACCCUGUCGAACUCACGUAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGAUAGGGUG		7
16671	MI0001695	osa-MIR439e	Oryza sativa miR439e stem-loop	CCACCUACCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUG		7
16672	MI0001696	osa-MIR439f	Oryza sativa miR439f stem-loop	ACCUACCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUG		7
16673	MI0001697	osa-MIR439g	Oryza sativa miR439g stem-loop	UCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGG		7
16674	MI0001698	osa-MIR439h	Oryza sativa miR439h stem-loop	ACCACCUACCCUGUCGAACUCACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUG		7
16675	MI0001699	osa-MIR439i	Oryza sativa miR439i stem-loop	CACCUACCCUGUCGAACUGACGCAGUUCGACAUGUACCUGUCGAACUGUGGUUGUUCGAUAGGUAUCCCUGUCGAACCGCGGUUGUUCGACAGGGUGCUAAAC		7
16676	MI0001700	osa-MIR439j	Oryza sativa miR439j stem-loop	GCAGGGACAUAUCCAACGGGCAGUGUUCGAUAGGGGCGUGGCUACAGUGACACUACAAUGUUUUUUUCUAUUUUUAAAAUUAUUUAAUCACAUGUCGAACCGCGGUUGUUCGAUAGGUACCCUGU		7
16677	MI0001701	osa-MIR440	Oryza sativa miR440 stem-loop	AUUGCUAUUGUUGGUGCUGGGCUCGUCCUGAUCACUAGGAGACUCUGAUCAAGCUAGGCCUAAACUUAUGUAUUAGUGUCUCCUGAUGAUCGGGACAAGGCUAACACCGAUGAGAGCGAU		7
16678	MI0001702	osa-MIR396d	Oryza sativa miR396d stem-loop	AAAGAUGUGCGGGCAUGCUUUCCACAGGCUUUCUUGAACUGUGAACUCGUGGGGGUGUAUGUGCUCAUGUUGGGAUUGUGGUCGGUGGCCUCCAAUUCUCUGAAAAGAAAGCUGAAUUGUCGAGCUCCCCGUUCUGUCUUUG		7
16679	MI0001703	osa-MIR396e	Oryza sativa miR396e stem-loop	GCGGGCAUGCUUUCCACAGGCUUUCUUGAACUGUGAACUCGUGGGGGUGUAUGUGCUCAUGUUGGGAUUGUGGUCGGUGGCCUCCAAUUCUCUGAAAAGAAAGCUGAAUUGUCGAGCUCCCCGUUCUGUCUUUGGUCGUCUCUACCUGUUGAUGGUUCAAGAAAGCCCAUGGAAACCAUGCCGC		7
16680	MI0001704	osa-MIR441a	Oryza sativa miR441a stem-loop	AAAAUAUAUUAAUUGGUACUUUCUCUAUUUAACAAUGUAAGUCAUUUUAGCAUUUCACACAUUCAUAUUGAUCUAGAUUCAUUACCAUCAAUAUAAAUGUGGGAAAUGCUAAAAUGACUUACAUUGUGAAACGGAGGGAGUAGUAAUUCAAAA		7
16681	MI0001705	osa-MIR441b	Oryza sativa miR441b stem-loop	UUAUCACCACUGACAUACUUCCUCCGUUUCACAAUGUAAGUCAUUUUAGUAAUUUUCAUAUUCAUAUUGAUGUUAAUGAAUCUAGACUCAUGUACCAUCAAUAUAAAUGUGGGAAAUGGUAGAAUGACUUACAUUAUGAAACAUAGGGAGCA		7
16682	MI0001706	osa-MIR441c	Oryza sativa miR441c stem-loop	UACUUCCUCUGUUUCAUAAUGUAAGUCAUUUUAGCAUUUUUCAUAUUUAUAUUGAUGGUAAUGAAUCUAGAUAGAUAUAUAUGUCUAGAUUCAUUACCAUCAAUAUAAAUGUGGGAAAUGCUAGAAUAACUUACAUUGUGAAACGGAGGAAGUA		7
16683	MI0001707	osa-MIR442	Oryza sativa miR442 stem-loop	CACAUAUAUGGAGUAUUAAAUAUAAAUGAAAAAAAUAACUAAUUAUACAGAUGACGUGUAAAUUGCGAGACGAAUCUUUUAAGCCUAAUUGCUCCAUGAUCUGACAAUGUGGUGCUACAGUAAACAUUUGCUAAUGACGGAUUAAUUAGGCUUAAUAAAUUCGUCUCGCAGUUUACAGACGGAUUCUGUAAUUUGUUUUGUUAUUAGUCUACGUUAAAUACUUCAAAUGUGUG		7
16684	MI0001708	osa-MIR443	Oryza sativa miR443 stem-loop	CGUCCCAUAAAAACAAACCCAAAACUAGAUGUGAUAUAUCACAAUACAAUAAAUCUGGAUAGGAGUCUAUCCAGAUACUUCUAUCUAGAUUUAUUGUACUGGGAUAUGUCACAUAUAUUCAGUUUUAUAUUUGUUUUUUUUUUGGACG		7
16685	MI0001709	osa-MIR445a	Oryza sativa miR445a stem-loop	UCACAUUGAAUGUUUGACACUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUGUAGCAUCACAUUGUCAAAUCAUGGUGUAAUUAGACUCAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUGUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGA		7
16686	MI0001710	osa-MIR445b	Oryza sativa miR445b stem-loop	GUCCGUGUCACAUCGAAUGUUUGACGCUAAUUUAGAGUAUUAAACAUAGACUAAUAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAACUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAGACUCAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAAUGUAUGUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGAC		7
16687	MI0001711	osa-MIR445c	Oryza sativa miR445c stem-loop	CCGUGUCACAUCGAAUGUUUGACGCUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAGGCUUAAAAGAUUCGUCUCGUGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUAUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAUA		7
16688	MI0001712	osa-MIR445d	Oryza sativa miR445d stem-loop	UGGCCAAAAUUUAGUCCCUGUCACAUCAGAUGUUAUGACACUAAUUAAAAGUAUUAAACAUAGACUAAUGACAAACCCCAUUCCAUAACCCUGGAUUAAUUCGCGAGAUGAAUCUAUUGAGUCUAAUUAAUCAAUGAUUAGCCUAUGUGAUGCUACACUAAACAUGUGUUAAUUAUGGAUUAAUUAGGCUUAAAAAUUUUGUCUCACGAAUUAGCUCUCAUUUAUGCAAUUAUUAGUUUUGUAAGUAGUUUAUGUUUAAUAUCUAAAUUAGUGUAUAAACAUCCGAUGUGAUAGGGACUAAAGUUGGAUCCA		7
16689	MI0001713	osa-MIR445e	Oryza sativa miR445e stem-loop	GUCCGUGUCACAUCGAAUGUUUGACGCUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAGACUCAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUGUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGAC		7
16690	MI0001714	osa-MIR445f	Oryza sativa miR445f stem-loop	AGAUGGGGCUAAAACUUUUUAGUCCGUGUCACAUCGAAUGUUUGACGCUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGGGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAGACUCAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUGUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGACUUAAAAUAAGUCCCUGUUU		7
16691	MI0001715	osa-MIR445g	Oryza sativa miR445g stem-loop	UUUUAGUCCGUGUCACAUCGAAUGUUUGACGCUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAAACUCAAAAGAUUCGUCUUGCGAAUUAGUCCAAGGUUAUAGAAUAUGUUUUAUAAUUAGUGUAUGUUUAAUAUUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGACUUAAA		7
16692	MI0001716	osa-MIR445h	Oryza sativa miR445h stem-loop	UUUUUAGUCCGUGUCACAUUGAAUGUUUGACACUAAUUUGGAGUAUUAAACAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGCGAGACGAAUUUUUUAAGCCUAAUUAAUCCAUAAUUAUGAAAAGUUUACUAAUCAUGGUGUAAUUAGACUCAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUGUUUAAUACUCUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGACUUAAAA		7
16693	MI0001717	osa-MIR445i	Oryza sativa miR445i stem-loop	ACUUUUUAGUCCGUGUCACAUCGAAUGUUUGACGCUAAUUUAGAGUAUUAAAUAUAGACUAAUAAAAAAACUAAUUUCAUAAAUGAAAGCUAAUCUGUGAGAUGAAUUUUUAAGCCUAAUUAAUCCAUAAUUAAAAGAUUCGUCUCGCGAAUUAGUCCAAGGUUAUAGAAUAGGUUUUAUAAUUAGUGUAUGUUUAAUACUUUAAAUUAGUGUAUAAACAUCCGAUGUGACAGGGACUUUAAGU		7
16694	MI0001718	osa-MIR446	Oryza sativa miR446 stem-loop	AAAUAUGUACUUCCUUUGUUUCACAGUGUAAGUCAUUAUAAAAUUUCCCACAUUUAUAUUGAUGUUAAUGAAUCUAUAUAGAUAUAUAUGUCUAGAUUUAUUAACAUCAAUAUGAAUAUGGGAAAUGGUAGAAUAACUUACAUUGUGAAACGGAGGGAGUAUAUAGAACUUGAAC		7
16695	MI0001719	osa-MIR444a	Oryza sativa miR444a stem-loop	AUGCAAUUGGGGGCAGCAAGCUAGAGGUGGCAACUGCAUAAUUUGCAAGAAAUUGUUGGCUGAAGAUCAUACCGAUGAUAUUCUUGCAAGUUAUGCAGUUGCUGCCUCAAGCUUGCUGCCUCCUGUUGCCA		7
16696	MI0001720	dre-mir-429	Danio rerio miR-429 stem-loop	CUUGUUGAUGGACGUCUUACCAGACAUGGUUAGAUGUAAUAACUUGUGUCUAAUACUGUCUGGUAAUGCCGUCCAUCACAUG		12
16697	MI0001721	hsa-mir-431	Homo sapiens miR-431 stem-loop	UCCUGCUUGUCCUGCGAGGUGUCUUGCAGGCCGUCAUGCAGGCCACACUGACGGUAACGUUGCAGGUCGUCUUGCAGGGCUUCUCGCAAGACGACAUCCUCAUCACCAACGACG		5
16698	MI0001722	rno-mir-431	Rattus norvegicus miR-431 stem-loop	UCCUGCGCGUCCUGCGAGGUGUCUUGCAGGCCGUCAUGCAGGCCACACUGACGGUAACGUUGCAGGUCGUCUUGCAGGGCUUCUCGCAAGACGACAUCUUCAUCGCCAACGACG		8
16699	MI0001723	hsa-mir-433	Homo sapiens miR-433 stem-loop	CCGGGGAGAAGUACGGUGAGCCUGUCAUUAUUCAGAGAGGCUAGAUCCUCUGUGUUGAGAAGGAUCAUGAUGGGCUCCUCGGUGUUCUCCAGG		5
16700	MI0001724	rno-mir-433	Rattus norvegicus miR-433 stem-loop	CCGGGGAGAAGUACGGUGAGCCUGUCAUUAUUCAGAGAGGCUAGAUCCUCUGUGUUGAGAAGGAUCAUGAUGGGCUCCUCGGUGUUCUCCAGG		8
16701	MI0001725	hsa-mir-329-1	Homo sapiens miR-329-1 stem-loop	GGUACCUGAAGAGAGGUUUUCUGGGUUUCUGUUUCUUUAAUGAGGACGAAACACACCUGGUUAACCUCUUUUCCAGUAUC		5
16702	MI0001726	hsa-mir-329-2	Homo sapiens miR-329-2 stem-loop	GUGGUACCUGAAGAGAGGUUUUCUGGGUUUCUGUUUCUUUAUUGAGGACGAAACACACCUGGUUAACCUCUUUUCCAGUAUCAA		5
16703	MI0001727	hsa-mir-453	Homo sapiens miR-453 stem-loop	GCAGGAAUGCUGCGAGCAGUGCCACCUCAUGGUACUCGGAGGGAGGUUGUCCGUGGUGAGUUCGCAUUAUUUAAUGAUGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
16704	MI0001729	hsa-mir-451	Homo sapiens miR-451 stem-loop	CUUGGGAAUGGCAAGGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAAUGGUUCUCUUGCUAUACCCAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
16705	MI0001730	mmu-mir-451	Mus musculus miR-451 stem-loop	CUUGGGAAUGGCGAGGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAACGGUUCUCUUGCUGCUCCCACA		6
16706	MI0001731	rno-mir-451	Rattus norvegicus miR-451 stem-loop	UUUGGGAAUGGCGAGGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAAUGGUUCUCUUGCUGCUCCCACA		8
16707	MI0001732	dre-mir-451	Danio rerio miR-451 stem-loop	AGAGGCGGCGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAAGGGUUCUGCUGCCUUU		12
16708	MI0001733	hsa-mir-452	Homo sapiens miR-452 stem-loop	GCUAAGCACUUACAACUGUUUGCAGAGGAAACUGAGACUUUGUAACUAUGUCUCAGUCUCAUCUGCAAAGAAGUAAGUGCUUUGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
16709	MI0001734	mmu-mir-452	Mus musculus miR-452 stem-loop	GCUAAGCAGUUACAACUGUUUGCAGAGGAAACUGAGACUUUAUAACUAUGUCUCAGUCUCAUCUGCAAAGAGGUAAGUGCUUUGC		6
16710	MI0001735	hsa-mir-409	Homo sapiens miR-409 stem-loop	UGGUACUCGGGGAGAGGUUACCCGAGCAACUUUGCAUCUGGACGACGAAUGUUGCUCGGUGAACCCCUUUUCGGUAUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
16711	MI0001738	mtr-MIR162	Medicago truncatula miR162 stem-loop	AGAUGAGGUGAAGUUCGUCACUGGAUGCAGCGGUUCAUCGAUCUGUUCCUGAAUUUUGUUUGUCUCGUAAAACAAACAUGAAUCGGUCGAUAAACCUCUGCAUCCAGCGCUCACUUUCCCCUCU		23
16712	MI0001739	mtr-MIR160	Medicago truncatula miR160 stem-loop	AGAUAUAUAUACUAAUUGCGUGCCUGGCUCCCUGUAUGCCAUUUGUAGAGUUCAUCAAGAUGUUGAUGACUUUAAUGAAUGGCGUGCGAGGAGCCAUGCAUGUUGUGUAUAUUUUCUAU		23
16713	MI0001740	mtr-MIR166	Medicago truncatula miR166 stem-loop	CAGACAUACGAAGGAGUUCAGGGGAAUGGUGUCUGAUUCGAGACCAUUCGUCACAAGUAAACAGUAGCCUUGAGAAUGAUCUCGGACCAGGCUUCAUUCCCCCUAGCUCAUAGUAUCAUGC		23
16714	MI0001741	mtr-MIR169a	Medicago truncatula miR169a stem-loop	AAGAGGCAGAGAGAGUAAUGCAGCCAAGGAUGACUUGCCGACAACAUUGGCGAAUGUUCAUGUGAUUUCUGCCUCAUUGUGCCGGCAAGUUGUCCUUGGCUAUGUUAGUCUCUCAUCUUCU		23
16715	MI0001742	mtr-MIR169b	Medicago truncatula miR169b stem-loop	AAGAGGCAGAGAGAGUAAUGCAGCCAAGGAUGACUUGCCGACAACGUUGGCGAAUGUUCAUGUGAUUUCUGCCUCAUUGUGCCGGCCAGUUGUCCUUGGCUAUGUUAGUCUCUCAUCUUCU		23
16716	MI0001743	mtr-MIR399b	Medicago truncatula miR399b stem-loop	UCAUAGGGCAUGUCUCUAUUGGUAGGUGAUAUGGUGAUAUUUCAUUUGAAUUAGAGGCUUCAGAAAUUCACUUGCCAAAGGAGAGCUGCCCUGUGAGUGUUUAGCUUAAACA		23
16717	MI0001744	mtr-MIR399d	Medicago truncatula miR399d stem-loop	UAAAGUAAGCAAAUCAGUCAUAGGGCAUGUCUCUAUUGGCAGGUGAUAUGGUGAUAUUUCAUUUGACUUUAAGGCUCUAAAAAUUCACUUGCCAAAGGAGAGCUGCCCUACGAGUGUUUAGCUUAAACA		23
16718	MI0001745	mtr-MIR393	Medicago truncatula miR393 stem-loop	AACUGCAACUUGAGGAGGCAUCCAAAGGGAUCGCAUUGAUCCUAUAAUAUUUCAACUUUAGUCACUUUAAUUUUCUCUCAUAUAAUACUUAAUUGGGAUCAUGCCAUCCCUUUGGAUUUCUCCUUUAGUAGCUAC		23
16719	MI0001746	mtr-MIR395a	Medicago truncatula miR395a stem-loop	UUUUUGUUGAUUGUUUCUUAGAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUGUAUUUGGUCUAAUAUCCAUUAGAAAAGAUAGUUCUUCAUCAAUGAAGUGUUUGGGGGAACUCUUGGGUUCAACCAGCACCA		23
16720	MI0001747	mtr-MIR395b	Medicago truncatula miR395b stem-loop	UACUUGUUGAUUUUCUCUUGGAGUUCCUCUGAAUGCUUCAAACAUGAGACAAUCUUGAUAGAAAUUAUGGAUAGUUCUUGUUCAAUGAAGUAUUUGGGGGAACUCUUGGAAUUGAAUCAACAUA		23
16721	MI0001748	mtr-MIR399c	Medicago truncatula miR399c stem-loop	GUUCUGCUGUUGAGGAAUGAUAGGGAAAAUCUCUUUUGGCAGAGAGGAGUAAAAAUCUUAAACAGGAAUGUUUCUGGUUUGCCAAAGGAGAUUUGCCCUGCCAUUUUUGACAGCUAUUG		23
16722	MI0001749	mtr-MIR399a	Medicago truncatula miR399a stem-loop	UCCAAGUUGCAGUUGAAUUACAGGGUGAGUUCUCCAUUGGCAGGUAGCUAGUCACUAUAUGAUAUGCAUUGCAAUCAUUUCUUAGUGUGCAAUCUGCCAAAGGAGAUUUGCCCAGCGAUUCUCCUGCAACUCUA		23
16723	MI0001750	mtr-MIR399e	Medicago truncatula miR399e stem-loop	UCCAAGUUGCAGUUGAAUUACAGGGUGAGUUCUCCAUUGGCAGGUAGCUAGCCACUAUAUGAUAUGCAUUGCAAUCAUCACUUAGUGUGUAAUCUGCCAAAGGAGAUUUGCCCAGCGAUUCUCAUGCAACUCUA		23
16724	MI0001751	mtr-MIR319	Medicago truncatula miR319 stem-loop	UAUUAAGAAAAAUAGUUCAAGAGAGCUCUCUUCAGUCCACUCAUGGAUAGGAAAAGGUUUUGAAUUAGCUGCUGACUCAUUCAUUCAAACACAAUAAGAAGAAGCAUGAUGAAUAUGCUAUAUUGUGAAUGUGUGAAUGAUGCGGGAGCUAAAUUUCAUCUUUCUCUUGUCUUUGCUUGGACUGAAGGGAGCUCCCUUUUGCUGUUUAUAUAUCA		23
16725	MI0001752	mtr-MIR156	Medicago truncatula miR156 stem-loop	AGCCAUGAAUCAGUCCGAGAUGACAGAAGAGAGAGAGCACACCCACCUGAUUACAAGUAACAAAAAACUACCAACUAUCAACAUUUUGUCUACUAUGAAGAAAAUCACAUGUCUAGACUAUAGUUACGAAUGGAAGAUACAUUCAAUGAUGUUUAUGAAAAUUUGAGACGGUCGAGGACUAUAGUUACUCUAUCGCAUACAUUUAAUGACAAAAAAAAUUGUGUACUCUUAUUUAUUUUCAAUACAUCUUCAUUCAAUUUCUAUGCAAGAAUCAAAAUGCAGUAUAAAAAAUUGCAUUCAAUAUCAUGGUAAAAAAAUUGUUCAAAAAAAGUAAAUAUCAUGGUAAAAAAAUCAUUAGAUUUUGCAAUAAGUAAGAGUCAAGUUUUACCUUGUGAGGAAUUCCUCCCAACAGAAUCAUGGGAGCUCUUUCUUCUUCUCUCAUUGUGCCCUGCCAGUCUCC		23
16726	MI0001753	mtr-MIR171	Medicago truncatula miR171 stem-loop	UGAAUUCCCCUCCGCUUUUUGAUGUUGGCUUGUCUCAAUCAAAUCAAAGUUCUUGAAAUUUGAGUUCUUUAGUCUGAUUGAGUCGUGCCAAUAUCAUAUUAAGCGAUAAAAGUC		23
16727	MI0001754	sof-MIR156	Saccharum officinarum miR156 stem-loop	GGUGGAGAAGAGGUGGAGGCUGACAGAAGAGAGUGAGCACACAUGGUGCCUUUCUUGCAUGAUGAACGAUCGAGAGGUUCAUGCUCGAAGCUAUGCGUGCUCACUUCUCUCUCUGUCAGCCGUUAGAACUCUCUCUC		24
16728	MI0001755	sof-MIR396	Saccharum officinarum miR396 stem-loop	AGAUGGCCUUCUUUGUGAUCUUCCACAGCUUUCUUGAACUGCAUCUCUAAGAGGAGCAGCUCGAAGCCUCGAACUCUACCUGCAUGAGCAGGUGCAGUUCAAUAAAGCUGUGGGAAACUGCAGAGAGAGGCCAA		24
16729	MI0001756	sof-MIR159a	Saccharum officinarum miR159a stem-loop	CCUGAUGCUUGGAUUUGAAGCGGAGCUCCUAUCAUUCCAAUGAAGGGCCGUUCUGAAGGGUUGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUAUGUGUGUAUGUAUUUUCGAGAGGGAGGAGAGGAGCUAGACUCUCAUGGUGGUCGUCUUUGAGAUAGGCUUGUGGUUUGCAUGACCGAGGAGCUGCACCGUCCCCUUGCUGGCCGCUCUUUGGAUUGAAGGGAGCUCUGCAUCCUGAUCCAUCCAUCC		24
16730	MI0001757	sof-MIR159b	Saccharum officinarum miR159b stem-loop	CCUGAUGCUUGGAUUUGAAGCGGAGCUCCUAUCAUUCCAAUGAAGGGCCGUUCUGAAGGGUGGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUAUGUGUGUAUGUAUUUUCGGAGAGGGAGGAGAGGAGCUAGACUCUCACGGUGGUCGUCUUUGAGAUAGGCUUGUGGUUUGCAUGACCGAGGAGCUGCACCGUCCCCUUGCUGGCCGCUCUUUGGAUUGAAGGGAGCUCUGCAUCCUGAACCAUCCAUCC		24
16731	MI0001758	sof-MIR159d	Saccharum officinarum miR159d stem-loop	CCUGAUGCUUGGAUUUGAAGCGGAGCUCCUAUCAUUCCAAUGAAGGGCCGUUCUGAAGGGUUGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUAUGUGUGUAUGUAUUUUCGAGAGGGAGGAGAGGAGCUAGACUCUCAUGGGGGUCGUCUAUGAGAUACGCUUGUGGUUUGCAUGACCGAUGAGCUGCACCGUCCCCUUGCUGGCCGCUCUUUGGAUUGAAGGGAGCUCUGCAUCCUGAUCCAUCCAUCC		24
16732	MI0001759	sof-MIR159e	Saccharum officinarum miR159e stem-loop	CUGAUGCUUGGAUUUGAAGCGGAGCUCCUAUCAUUCCAAUGAAGGGCCGUUCUGAAGGGUGGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUAUGUGUGUAUGUAUUUUCGAGAGGGAGGAGAGGAGCUAGACUCUCACGGUGGUCGUCUUUGAGAUAGGCUUGUGGUUUGCAUGACCGAAGAGCUGCACCGUCCCCUUGCUGGCCGCUCUUUGGAUUGAAAGGAGCUCUUGCAUCUGAUCCAUCCAUCC		24
16733	MI0001760	sof-MIR159c	Saccharum officinarum miR159c stem-loop	UGAAGACGACGACGAAGAAGAAGAUGGCGAAGAAAAGUGAUCGAAGAGCUCCCUUCGAUCCAAUCCAGGAGGGGAAGUGGUCGGUUGCAGCUGCCGGUUCAUGGAUGCCUCUCUGGUGCAGCAAUGACUAAUGCUCACCUGCACUUGCAUGGGUGUGCAUGACCCGGGAGAUGAACCCACCAUCAUCUUUCCCUCGUGCUUGGAUUGAAGGGAGCUCCUCUCUCUUUCCUCUCUCUCU		24
16734	MI0001761	sof-MIR167a	Saccharum officinarum miR167a stem-loop	AGUGGUGCACCACAAGUUGGUGAAGCUGCCAGCAUGAUCUGAUGGUGGUAUAUAUGAAUAUAUGAUGUCUUUACCUCUGAUCUCUCCCUGACUGUCACCGAUCCAUGAAUCCAGGAUGAGGGGAGGGAAGAAAGAGGGAUAAUGAGCAUCAGGUCAUGCUGUAGUUUCAUCUGCUGGUGGGAGCACAU		24
16735	MI0001762	sof-MIR167b	Saccharum officinarum miR167b stem-loop	AGUGGUGCACCACAAGUUGGUGAAGCUGCCAGCAUGAUCUGAUGGUGGUAUAUAUGAAUAUAUGAUGUCUUUACCUCUGAUCUCUCCCUGACUGUCACGGAUCCAUGAAUCCAGGAUGAGGGGAGGGAAGAAAGAGGGAUAAUGAGCAUCAGGUCAUGCUGUAGUUUCAUCUGCUGGUGGGAGCACAU		24
16736	MI0001763	sof-MIR168a	Saccharum officinarum miR168a stem-loop	GCCGCCGCGCCGCCUCGGGCUCGCUUGGUGCAGAUCGGGACCCGCCGCCCGGCCGACGGGACGGAUCCCGCCUUGCACCAAGUGAAUCGGAGCCGGCGCAGCCA		24
16737	MI0001764	sof-MIR168b	Saccharum officinarum miR168b stem-loop	CCGCCCCGCGCCGUCUGGGCUCGCUUGGGCAGAUCGGGACCCGCCGCCCGGCCGACGGGACGGAUCCCGCCUUGCACCAAGUGAAUCGGAGCCGGCGCAGCCA		24
16738	MI0001765	sof-MIR408a	Saccharum officinarum miR408a stem-loop	AGAAGAUGGGUAUGGUUGGAGACAGGGAUGAGGCAGAGCAUGGGAUGAGGCCAUCAACAAAAUUUCCAAUUUCUGUCCUCCGCUAGGCCGCUACUGCAUUUCUGUUUGCUUGCUCACAAAACGGAGGGAUUUGUGAGAGUUAUCAGGCAGAAAGAACAAAGAAGGUGCCUCCCUGGUGAAGUGGUGAUGGCCUGACCUGAGACGGCUGAGAGCUCAGCUGGUGUCCUGUUGUUGCUUCCUCCCCUGCACUGCCUCUUCCCUGGCUCCCCACCGUUGCCCUUGC		24
16739	MI0001766	sof-MIR408b	Saccharum officinarum miR408b stem-loop	AGAAGAUGGGUAUGGUUGGAGACAGGGAUGAGGCAGAGCAUGGGAUGGGGCCAUCAACAAAAUUUCCAAUUUCUGUCCUCCGCUAGGCCGCUACUGCAUUUAUGUUUGCUUGCUCACAAAACGGAGGGAUUUGUGAGAGUUAUCAGGCAGAAAGAACAAAGAAGGUGCCUCCCUGGUGAAGUGGUGAUGGCCUGACCUGAGAGGGCUGAGAGCUCAGCUGGUGUCCUGGUGUUGUUGCUUCCUCCCCUGCACUGCCUCUUCCCUGGCUCCCCACCGUUGCCCUUGC		24
16740	MI0001767	sof-MIR408c	Saccharum officinarum miR408c stem-loop	AGAAGAUGGGUAUGGUUGGAGACAGGGAUGAGGCAGAGCAUGGGAUGGGGCCAUCAACAAAAUUUCCAAUUUCUGUCCUCCGCUAGGCCGCUACUGCAUUUCUGUUUGCUUGCUCACAAAACGGAGGGAUUUGUGAGAGUUAUCAGGCAGAAAGAACAAAGAAGGUGCCUCCCUGGUGAAGUGGUGAUGGCCUGACCUGAGAGGGCUGAGAGCUCAGCUGGUGUCCUGGUGUUGUUGCUUCCUCCCCUGCACUGCCUCUUCCCUGGCUCCCCACCGUUGCCCUUGC		24
16741	MI0001768	sof-MIR408d	Saccharum officinarum miR408d stem-loop	GGAAGGUAUGUUUGAUUGGAGACAGGGACGAGGCAGAGCAUGGGAUGGGGCCAUCAACAAAAUUUCCAAUUUCCGUUUGCUUGCUCACAAAACGAAGGUGCCUGCCUCCCUGGUGAUGGCCUGACCUGAGAGGGCUGAGAGCUCAGCUGGUGUCCUGGUGUUGUUGCUUCCACCCCUGCACUGCCUCUUCCCUGGCUCCCCACCGUUGCCCUUGC		24
16742	MI0001769	sof-MIR408e	Saccharum officinarum miR408e stem-loop	AGAAGAUGGGUAUGGUUGGAGACAGGGAUGAGGCAGAGCAUGGGAUGAGGCCAUCAACAAAAUUUCCAAUUUCUGUCCUCCGCUAGGCCGCUACUGCAUUUAUGUUUGCUUGCUCACAAAACGGAGGGAUUUGUGAGAGUUAUCAGGCAGAAAGAACAAAGAAGGUGCCUCCCUGGUGAAGUGGUGAUGGCCUGACCUGAGACGGAUGAGAGCUCAGCUGGUGUCCUGUUGUUGCUUACUUCCCUGCACUGACUCUUCCCUGGCUCCCCACCGUUGCCCUUGC		24
16743	MI0001770	gma-MIR156d	Glycine max miR156d stem-loop	CUACUUGGUAAUUAAGGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAUAUGCAUAUUAUAUAAUAUAUAGCAGGGAACUCAUGAUGAAUUGUGCAUCUUACUCCUUUGUGCUCUCUAUACUUCUGUCAUCACCUUCAGCCUCCAUUUC		25
16744	MI0001771	gma-MIR156e	Glycine max miR156e stem-loop	AGGAGGUGUUGGUGAUGCUGUUGACAGAAGAUAGAGAGCACUGAUGAUGAAAUGCAUGAAAGGGAAUGGCAUCUCACUCCUUUGUGCUCUCUAGUCUUCUGUCAUCAUCCUUCUCCCUCCCCUC		25
16745	MI0001772	gma-MIR156c	Glycine max miR156c stem-loop	ACUUGACCACUAGGCUUAUCUCUUUCCGUUUCUGAGCAUGCAUACUCAUUCACAGCAUCAAAAUGCACAGAUCCUGAUGGAGAUUGCACAGGGCAGGUGAUGCUAGAUUGCACCAUACUCAAAUCUGGACUUUGUGAUUGAAGUGUUGACAGAAGAUAGAGAGCACAACCUGAGUCAAAGGAUCC		25
16746	MI0001773	gma-MIR159	Glycine max miR159 stem-loop	AAUUAAAGGGGAUUAUGAAGUGGAGCUCCUUGAAGUCCAAUUGAGGAUCUUACUGGGUGAAUUGAGCUGCUUAGCUAUGGAUCCCACAGUUCUACCCAUCAAUAAGUGCUUUUGUGGUAGUCUUGUGGCUUCCAUAUCUGGGGAGCUUCAUUUGCCUUUAUAGUAUUAACCUUCUUUGGAUUGAAGGGAGCUCUACACCCUUCUCUUCUUUUCU		25
16747	MI0001774	gma-MIR160	Glycine max miR160 stem-loop	CAUGCAUACAUAUGUGUAUGUGCCUGGCUCCCUGUAUGCCAUUUGUAGAGCUCAUCGAAGCAUCAAUGACCUUUGUGGAUGGCGUAUGAGGAGCCAAGCAUAUUUCAUAUACAUACAUG		25
16748	MI0001775	gma-MIR166a	Glycine max miR166a stem-loop	ACGGAAGCUUUGUCUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACCCUUCUUCAUCUUGAUCUUGUGUAGACUACUAUGCUUGUGGUCAAGGAAUACAUAGUGUUGUCGGACCAGGCUUCAUUCCCCCCAAUUAUAUGCUUCCAAA		25
16749	MI0001776	gma-MIR166b	Glycine max miR166b stem-loop	GCUUGCAAAGGUGAGGUUGAGAGGAAUGUUGUCUGGCUCGAGGUCAUGGAGGAGGAGGAGGAGUAGAGUACUGAGAUCAGUGAAAGUUUCCAAUGGAAAUUUACCCUCUUACACAAAAAAAUGAUUCUCGGACCAGGCUUCAUUCCCCCCACCCAACUUUUGCUUUU		25
16750	MI0001777	gma-MIR167a	Glycine max miR167a stem-loop	GAAGUUCGCAAAGGAAAAAGUGAAGCUGCCAGCAUGAUCUACCUUUGGUUAGAGAGCUCAAGAGUGCUAACCCUGACUAGGUCAUGCUGUGACAGCCUCACUCCUUCCUAUUUGGGGAC		25
16751	MI0001778	gma-MIR167b	Glycine max miR167b stem-loop	AAGGGUCACAAAGGAAAAAGUGAAGCUGCCAGCAUGAUCUAGCUUUGGUUAGUGGGAGCGAGAUAGUGCUAACCCUCACUAGGUCAUGCUGUGCUAGCCUCACUCCUUCCUAUUUGGAGAC		25
16752	MI0001779	gma-MIR168	Glycine max miR168 stem-loop	GGCACGAGGCGGUCUCUAAUUCGCUUGGUGCAGGUCGGGAACCGGUUUUCGCGCGGAAUGGAGGAGCGGUCGCCGGCGCCGAAUUGGAUCCCGCCUUGCAUCAACUGAAUCGGAGGCCGCGGUGAAC		25
16753	MI0001780	gma-MIR172a	Glycine max miR172a stem-loop	UUAACAGUCGUUAUUUGCGGAUGUAGCAUCAUCAAGAUUCACAUGCAAGCGCAGGUGGUGGGUGGGACUUGAUGCAAUCUAAGUGCUGUGCCAGCCAAGCCAUAGGUCUUUUGGAACUGAGAAUCUUGAUGAUGCUGCAUCAGCCAUAAACGACUUCAC		25
16754	MI0001781	gma-MIR172b	Glycine max miR172b stem-loop	UUGACAGUCGUUGUUUGCGGAUGUAGCAUCAUCAAGAUUCACAUGCAAAUGAAGGUGGGUGGGACUAUGAUGCAAUCCAAGUGCUCUGCCAAUCCAUCGGUCUUUUUGAUGUGAGAAUCUUGAUGAUGCUGCAUCAGCCAUAAACGGCUUUAA		25
16755	MI0001782	gma-MIR319a	Glycine max miR319a stem-loop	CGUUGAAGACCCUAAGGUAAGAGAGCUUUCUUCAGUCCACUCAUGGGUGACAGUAAGAUUCAAUUAGCUGCCGACUCAUUCAUCCAAAUGUUGAGUGUAAGCGAAUAAAUAUACUCAGCAGAUGAGUGAAUGAUGCGGGAGACAAAUUGAAUCUUAAGUUUCCUGUACUUGGACUGAAGGGAGCUCCCUUUUCCUUUUGUCUCUUAC		25
16756	MI0001783	gma-MIR319b	Glycine max miR319b stem-loop	UAAGUCCUAAGCGACGGUAAGAGAGCUUUCUUCAGUCCACUUAUGGGUGACAAUAAGAUUUCAAUUAGCUGCCGACUCAUUCAUCCAAAUGCUGAGUGAAAGCGAAGAAAGAUACUCAGCAAAUGAGUGAAUGAUGCGGGAGACAAAUUGAUUCUUAAGUGUCCUGUACUUGGACUGAAGGGAGCUCCCUUUUUCUUUUGAAUCUUCU		25
16757	MI0001784	gma-MIR156a	Glycine max miR156a stem-loop	CACACCAGAUUGAGAGAGGCUGACAGAAGAGAGUGAGCACAUGCUAGUGGUAUUUGUAUGAGGGCAUACAAUUGCGGGUGCGUGCUCACUUCUCUAUCUGUCAGCUUCCCAUUCUUUUUUAC		25
16758	MI0001785	gma-MIR396a	Glycine max miR396a stem-loop	UCAUGGCUCUCUUUGUAUUCUUCCACAGCUUUCUUGAACUGCAUCCAAAGAGUUCCUUUGCAUGCAUGCCAUGGCACUCUUACUCCCAAAUCUUGUUUUGCGGUUCAAUAAAGCUGUGGGAAGAUACAGAUAGGGUCAAC		25
16759	MI0001786	gma-MIR396b	Glycine max miR396b stem-loop	CUCAAGUCCUGGUCAUGCUUUUCCACAGCUUUCUUGAACUUCUUAUGCAUCUUAUAUCUCUCCACCUCCAGGAUUUUAAGCCCUAGAAGCUCAAGAAAGCUGUGGGAGAAUAUGGCAAUUCAGGCU		25
16760	MI0001787	gma-MIR398a	Glycine max miR398a stem-loop	CUCGGAGGAGUGAAUCUGAGAACACAAGGCUGGUUUGCACUGCUAUAUCAUCUAUUGGUAUAAGGUGAAUUUACUUUGUGUUCUCAGGUCACCCCUUUGAGCCAACCUGUUGACAU		25
16761	MI0001788	gma-MIR398b	Glycine max miR398b stem-loop	AGUCCAAAUGGUUUAUCUCAGAGGAGUGGAUCUGAGAACACAAGGCUGGUUUGCACUGCUAUAUUAUGAUCGAUUGGUAUAAGGUGAAUUUACUUUGUGUUCUCAGGUCACCCCUUUGAGCCAACCUGUUGACAU		25
16762	MI0001789	gma-MIR319c	Glycine max miR319c stem-loop	UUGGGAGGGAAAGAGAGUGAAGGAGCUUCCCUCAGCCCAUUCAUGGAGAUAACGAAAGAUUGGGUUGCUGAAUUAACUGCUAGCUCACACAUUCAUUCAUACAAUAGUAUUCAAUUAGGGUAAUAUUGUGUGAAUGAAGCGGGAGUAUAUAGUAUCUAUAUUGCAACCCUCUUUCUCUGUGCUUGGACUGAAAGGAGCUCCUUCUUUUUCUGCUCCCUCCA		25
16763	MI0001790	gma-MIR156b	Glycine max miR156b stem-loop	UGAUGUGAGAUAUCUCAUGUUGACAGAAGAGAGAGAGCACAACCCGGGAAUGGCUAAAGGAGUCUUUGCCUUUGUUGGGAGUGUGCCCUCUCUUCCUCUGUCAUCAUCACAUUCACAUGC		25
16764	MI0001791	gma-MIR169	Glycine max miR169 stem-loop	AAGAGGAAGAGAGAGUGAUGCAGCCAAGGAUGACUUGCCGGCGUUAUUAUUUGCUCAUGUUCAUGCUCACCGGUUUCCUUGCCGGCAAGUUGUGUUUGGCUAUGUUUUGCUCUCUUCUUCU		25
16765	MI0001792	zma-MIR171d	Zea mays miR171d stem-loop	AGAAAUGGAAGUGUAACUAUGGUGUUGGCUCGGCUCACUCAGAAGUUGAAGCCGAAUCCAAAUGGUAGCUGCCGGCGUUUCUGAUUGAGCCGUGCCAAUAUCUCAGUACUCUUUCAUGCUG		14
16766	MI0001793	zma-MIR171f	Zea mays miR171f stem-loop	UUGGUUGUUGGCUGAGAGAGUGCGAUGUUGGCAUGGCUCAAUCAACUCGCCGGCCGCGGGUGGCUUAUAGCUUAAUUCUGCGCAUUCGAUCGAGGUGCGGGCGCAGUGUUUAAUUGAUUGAGCCGUGCCAAUAUCACAACCUUCUCUAGCCUAUA		14
16767	MI0001794	zma-MIR394a	Zea mays miR394a stem-loop	GGCGCUUACUGAAGAGUUCCUUGGCAUUCUGUCCACCUCCUCUCGCCGAUCUUGCAGAAAGUUUACCAGUUCUGUUGCAUUUUUUUUGGAGGUGGGCAUACUGCCAAUGGAGCUGUGUAGGCCUCC		14
16768	MI0001795	zma-MIR394b	Zea mays miR394b stem-loop	UGGCGCUUACUGAGAGUUCCUUGGCAUUCUGUCCACCUCCCUUCUUGACGAUCUUGCAGAAAGUUUGCUUUUUUUGUUUGUUUGGAGGUGGGCAUACUGCCAAUGGAGCUGCGUAGGCCUCC		14
16769	MI0001796	zma-MIR395b	Zea mays miR395b stem-loop	GCAACGUUUUGUGUUACUAGGAGUUCCCUACAAGCACUUCACAAUACCUUGGCUCAAUAAAUUAAAGGCCAGUUGUGAAGUGUUUGGGGGAACUCUUGGUAUCAUGAAGCAUUU		14
16770	MI0001798	zma-MIR395c	Zea mays miR395c stem-loop	UCUUGGUUGGUUCUCCCUUGGAGUUCCCUGCAAACACUUCACCAGCUAGGCCAUAGUGCCGGCCCUUGCACAAUGUUGUAUCUGAUCACCUAGCUAGUGUGAAGUGUUUGGAGGAACUCUAGGUGUUAUCCAGCAAUG		14
16771	MI0001799	zma-MIR395a	Zea mays miR395a stem-loop	UAUUGGUUGGUUGUCACCUGGAGUUCUCCUCAAACCACUUCAGUUGCUGCACCUAGCUAGUUUAAUGGCACUGUGCUUGCGUGCAAGCGGCCGGAGCUGUGUGUAGCUAGUGAAGUGUUUGGGGGAACUCUGGGUGUCAAUCAGCAAUU		14
16772	MI0001800	zma-MIR396b	Zea mays miR396b stem-loop	AGAUGGCCUUCUUUGUGAUCUUCCACAGCUUUCUUGAACUGCAUCUCUCAGAGGAGCGGCAGCUUCAACUCCUCCACCCGCAUCAGCAGGUGCAUGCAGUUCAAUAAAGCUGUGGGAAACUGCAGAGAGAGGCCAG		14
16773	MI0001801	zma-MIR396a	Zea mays miR396a stem-loop	ACAUGGCCCUCCUUGCCGUCUUCCACAGCUUUCUUGAACUGCAUGCCGCCGGCUGGUGGAUGCUGCGCGCUUGAAUUCCGGUCGAUCCCAAGAGGCGCAGUUCAAUAAAGCUGUGGGAAACUGCAGAGAGAGGCCAC		14
16774	MI0001802	zma-MIR399a	Zea mays miR399a stem-loop	UGUGAAGAGGGUGAGAAUCACAGUGCGGUUCUCCUCUGGCACGAAGGCUGGCCAGAGCAGCUUAUAUUGCCACCACCCUUCCUUGCCAAAGGAGAAUUGCCCUGCCAUUCACAACCCUGCAAU		14
16775	MI0001803	zma-MIR399c	Zea mays miR399c stem-loop	UGCUUGCUGAGCAUGAAUUACAGGGUACGUCUCCUUUGGCACAGCAGAAUGCACACAUCAUCAGUCGAGAGAGUAAGCUCGCUGCGUGCUCGCCGGCCUGGGAGCGGAAGUCGCAGGCCAAAUGGCGGCGGUGCAGAUGCAUGAACAGCAGCUGCCGUAUAUAUGCGUGCCAAAGGAGAAUUGCCCUGCGAUUCUAGGCUCAGCGAU		14
16776	MI0001804	zma-MIR399b	Zea mays miR399b stem-loop	GUAGCUCAGGGUGCGAAUCACAGUGCAGCUCUCCUCUGGCAUGAAGGCUGUGAGAGAGGCAUGACAAUUUCUGGCCUUGCCCUGCCAAAGGAGAGCUGUCCUGCCAUUCAUUAGCCCUGCAA		14
16777	MI0001805	zma-MIR399d	Zea mays miR399d stem-loop	UCAAGGUGAGAAUCACAGUGUGGCUCUCCUCUGGCAUGAAGGCGCGGCUGAGAGGCACGAACAGUUUCUGGCCUUCCCCUGCCAAUGCCAAAGGAGAGCUGCCCUGCCAUUCGUUAGCCCUGCAA		14
16778	MI0001806	zma-MIR399e	Zea mays miR399e stem-loop	AUGCCUAAGCUGUCCAGUUUCAGGGCUUCUCUUUCUUGGCAGGGAAGCAUGAGAUGCCAUAGCUCUCUGCUCUCUUCAACCCUCUGCCAAAGGAGAGUUGCCCUGUAACAGGACUCAGCUUAUG		14
16779	MI0001807	zma-MIR399f	Zea mays miR399f stem-loop	CAGGAUGUGCACCUGCAUUUCUGGGCAACUUCUCCUUUGGCAGAUGCGCGAGAAUGUGCCACUGCUGCCAAAGGAAAUUUGCCCCGGAAUUCAUCUGCACAAGCA		14
16780	MI0001808	zma-MIR156j	Zea mays miR156j stem-loop	CGAGUGGACCUCGGGAGCGAUGACAGAAGAGAGAGAGCACAACCCAGCACCAGCGAGGAAAAGCCUCGCUUCUGCGAGGGCCGUGUGCUCUCUGCUCUCACUGUCAUCGCCCACAGGCCACCGAA		14
16781	MI0001809	zma-MIR159a	Zea mays miR159a stem-loop	UCGAUGCUUUGGGUUUGAAGCGGAGCUCCUAUCAUUCCAAUGAAGGGUCGUUCCGAAGGGCUGGUUCCGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCAUCAUGUGUAUAUAUGUAAUCCAUGGGGGAGGGUUUCUCUCGUCUUUGAGAUAGGCUUGUGGUUUGCAUGACCGAGGAGCUGCACCGCCCCCUUGCUGGCCGCUCUUUGGAUUGAAGGGAGCUCUGCAUCCUGAUCCACCCCUCC		14
16782	MI0001810	zma-MIR159b	Zea mays miR159b stem-loop	UAGACGGUCUGGUCUUAAGGCGGUGCUCCCUUCAAACCAAUAAACGGUCGAUCUGAUGGGUGGUACAGCUGCUCGUUCAUGGUUCCCACUGUCCCAUCUCAUCAGAGAGAGAGAGAGAUGCUUGAGAUGGGCUUGUGGUUUGCAUGACCGAGGAGCUGCACGUCCCCUUCGUUGACCGCUGUUUGGAUUGAAGGGAGCUCUGCAUCUUGGUCCCAAGACUU		14
16783	MI0001811	zma-MIR159c	Zea mays miR159c stem-loop	AUGAUUAAGAAAGGCGAUCGAAGAGCUCCCUUCGAUCCAAUCCAGGAGGGGAAGUGGUCGGUUGCAGCUGCCGGUUCAUGGAUACCUCUCUGGUGCAGCAAUGGCCGCUGCUCACCUCUGCACUUGCAUGGGUGUGCAUGACCCGGGAGAUGAGCCCGCCAUCAUCUUUCCCUCGUGCUUGGAUUGAAGGGAGCUCCUCUCUGUCUGUCUGUCUGUC		14
16784	MI0001812	zma-MIR159d	Zea mays miR159d stem-loop	AAGAAGAUGCCGAUCGAUCGAAGAGCUCCCUUCGAUCCAAUCCAGGAGGGAAAGUGGUCGGCUGCAGCUGCCGGUUCAUGGAUACCUCUCUGGUGCAGCAAUGGCCGAGAUGCUCACCUGCACUUGCAUGGGUGUGCAUGACCCGGGAGACGAACCGACCAUCAUCUUUCCCUCGUGCUUGGAUUGAAGGGAGCUCCUCUCUCUCUCUCUCUCUUAU		14
16785	MI0001813	zma-MIR319a	Zea mays miR319a stem-loop	GGUUCAUGUUUUCUCUGGAAGAGAGCUCUCUUCAGUCCACUCUGAAAUGGCUGUAGGGUUUCAUUAGCUGCCGACUCAUCCAUUCACCUGCCAAGAACCAUGGACAGGUCUGGUCUUGGUAGCCGAGUGGGUGGCGCGGGAGCUAAAAUCAAGCUCUACGCUGUUUGUGGUUGGACUGAAGGGUGCUCCCUUUUGUUUGCUCAAACGCU		14
16786	MI0001814	zma-MIR319c	Zea mays miR319c stem-loop	GGUUUAUGGCUUCUGUGGAAGAGAGCUCUCUUCAGUCCACUCUAAAAUGGCUGUAGGGUUUCAUUAGCUGCCGACUCAUCCAUUCACCUGCCAAGAACCAUGGGCAAGCGGUAGGUCUGGUCUUGGUAGCCGAGUGGGUGGCGCGGGAGCUAAAAUCAAACUCUACGCUGUUUACGGUUGGACUGAAGGGUGCUCCCUUCAAUUUGCCCAAACACU		14
16787	MI0001815	zma-MIR319b	Zea mays miR319b stem-loop	GACGACGAUGGCUGGAUGGAAGAGAGCGUCCUUCAGUCCACUCAGGGGCGGUGCUAGGGUCGAAUUAGCUGCCGACUCAUUCACCCACAUGCCAAGCAAACGGCCAUGGAAACCAGCUUUGCAGAUGAGUGAAUGAAGCGGGAGGUAAAAGCUUCGAUCUCGCACCGUCUUUGCUUGGACUGAAGGGUGCUCCCUCCUCCCUCGCUCCUUGUU		14
16788	MI0001816	zma-MIR319d	Zea mays miR319d stem-loop	UGGUCGCCGGCCGGAUGGAAGAGAGCGUCCUUCAGUCCACUCAGGGGCGGUGCUAGGGUCGGAUUAGCUGCCGACUCAUUCACCCACAUGCCAAGCAAACGGCCAUGGAAACGAGCUUCGCAGAUGAGUGAAUGAAGCGGGAGGUAAAAGCUUCGAUCUCGCACCGUCUUUGCUUGGACUGAAGGGUGCUCCCUCCGAUCCUUUCCUUGUUU		14
16789	MI0001817	zma-MIR166k	Zea mays miR166k stem-loop	GCAUGCUCGGGUUAGGUCAGGGGGAUUGUUGUCUGGCUCGGGGUCUCCGGUCGAGAUCGAUUCAUAACAUAUACGUACGUGCUUCUAGCCUUGCCGGCGGAGCUAGUCGUUGUCGUCGACCGGAGAUUUCGGACCAGGCUUCAAUCCCUUUGACCAUGCGGCAUUAGG		14
16790	MI0001818	zma-MIR166j	Zea mays miR166j stem-loop	CAAGUUGAAGAUUAGGUUAAGGGGUUUGUUUGUCUGGUUCAAGGUCGCCACACAGCAGGGAAAACCCAUUUCGCCUUGAAGCAUGCACCAUGAUGGGUGUACCUGUUGGUGAUCUCGGACCAGGCUUCAAUCCCUUUAACUAGCGUCUGCAUAU		14
16791	MI0001819	zma-MIR167e	Zea mays miR167e stem-loop	UUGGUGUGUCCUCUAGUAGCUGAAGCUGCCAGCAUGAUCUGAGGUGUCCACAGCAUAUAUAUGGAAGCAGCUAGCGAUCAGAUCAUGCUGUGCAGUUUCAUCUGCUCGUGGACGCACAC		14
16792	MI0001820	zma-MIR167f	Zea mays miR167f stem-loop	CGUGCACCUUAUUAAGCAGCUGAAGCUGCCAGCAUGAUCUGAUCUUUCGUUUACUGGCAACUUUGGAUACCUAAGAUCCAGAUCGUGCUGCGCAGUUUCACCUGCUAAUUGGAGCACAG		14
16793	MI0001821	zma-MIR167g	Zea mays miR167g stem-loop	AGUGGUGCACCACGAGUUGGUGAAGCUGCCAGCAUGAUCUGGUUAUGAUGGUGGUGGUAUAUGUAAGAUGGAUGUAAUCUAUACUACUACCGGCCCCUGUCACUCUCUCUCUCUCCCCCGUCCCUGACUGUCAUAUAUGGAUCGACGAAUCCAAGAUGAGAGGGGAAGGGAGAGAGAGAGAGGGUAAUUAAUGAGCACCAGGACCAGGUCAUGCUGUAGUUUCAUCUGCUGGUGGCCGCACAU		14
16794	MI0001822	zma-MIR167h	Zea mays miR167h stem-loop	ACUUUGCUGCUGUGAGAGGUUGAAGCUGCCAGCAUGAUCUGGCUGCUCAGACGCCGGCGGGCGUCUCGAGUGCUCGCUCGAUCGUCGGUGACGCUUGGAUUCACCAGAUCAUGUUGCAGCUUCACUCUCUCGCAGCCAGCAAA		14
16795	MI0001823	zma-MIR167i	Zea mays miR167i stem-loop	ACUUCGCUGGUGUGAGAGCUUGAAGCUGCCAGCAUGAUCUGGCUACUCAAACGCCGCCGGCCUCCCAAGUGCUCGAUCGGUGGCGCUUCACCAGAUCAUGUUGCAGCUUCACUCUCUCGCAACCAGCGAA		14
16796	MI0001824	zma-MIR168a	Zea mays miR168a stem-loop	GAAGCCGCGCCGCCUCGGGCUCGCUUGGUGCAGAUCGGGACCCGCCGCCCGGCCGACGGGACGGAUCCCGCCUUGCACCAAGUGAAUCGGAGCCGGCGGAGCGA		14
16797	MI0001825	zma-MIR168b	Zea mays miR168b stem-loop	UCCGCCGCGCCGUCUCGGGCUCGCUUGGUGCAGAUCGGGACCCGCCGCCCGGCCGACGGGACGGAUCCCGCCUUGCAUCAAGUGAAUCGGAGCCGGCGCAGCGA		14
16798	MI0001826	zma-MIR169c	Zea mays miR169c stem-loop	AUGAGGUAGAGAACGGGAUGCAGCCAAGGAUGACUUGCCGGCUCCUGGAACCUGGAGGCGUCUCAGCUUGCUGUGCUGUGGCUUAGAACUUAGUCGGCAAGUCUGUCCUUGGCUACACCUAGUUCUCUUCCUCU		14
16799	MI0001827	zma-MIR169f	Zea mays miR169f stem-loop	ACCAGAGCUGAUUCGUUCAGUAGCCAAGGAUGACUUGCCUAGGUAUAUAUGCAUGGGCUAUGGCUACAUGCCUGAGAGCCAGUCUCUUGUGACGCUGAGCAUGUAUAGUGUAGGCAUGUCUUCCUUGGCUACUCGGAGCGGCUCUAGUCA		14
16800	MI0001828	zma-MIR169g	Zea mays miR169g stem-loop	CAGAGCUAGCCUGCCUCUGGUAGCCAAGGAUGACUUGCCUACAUGGUCUCGCUAGUUCCGGUUGUUGCAUGCAUGCCACUAUGCCAGUCCUGCUGGGUUUGUGGGCGGUCUCCUUGGCUAGCCUGAGUGGCUCUUGCCUG		14
16801	MI0001829	zma-MIR169h	Zea mays miR169h stem-loop	CAAUAAGGGCCUGCCUCUGAUAGCCAAGGAUGACUUGCCUAUGUCCUUUGUUUACAAAGGAUCAGAAUUGUGGACCUUUGUGUUGGUUCGUAGGCAGUCUCCUUGGCUAGCCUGAGUGGCCCCUAUUG		14
16802	MI0001830	zma-MIR169i	Zea mays miR169i stem-loop	GAUGAGAGUGGUAGCUCUGGUAGCCAAGGAUGACUUGCCUGUGUGCUGGCCACGCUCCCCUCAUGCAAGGACCAUCUCGUGUCGACCGACGAGCGAGCGAGCGAUCGAUCGAUGAGAGGAUGACGAAGCUUGGGGUGUACGUUGGUCUCUCACGGGCAGUCUCCUUGGCUAGCCCUGACUCACUCUUACCG		14
16803	MI0001831	zma-MIR169k	Zea mays miR169k stem-loop	CGAUGAGAGCACUGCUCUGGUAGCCAAGGAUGACUUGCCUGUGGCCUCCAUCAGUCGCAGAGGACGCUGUUCUUCUGCUUGUGGUUGUCGAUCGCAGGCAGUCUCCUUGGCUAGCCCGAGCGGCUCUCAUCCA		14
16804	MI0001832	zma-MIR169j	Zea mays miR169j stem-loop	GCGAUAAGAGUCUGUCCAGAUAGCCAAGGAUGACUUGCCUGUGGCUUCUUGGCUUGGCUUGGCUCGGGCAAAACCUUGUGCACGUUUUAUUGCUCGCCUCGUGGCCUCGAUCACAGGCAGUCUCCUUGGCUAGUCCGGGCGGGCCCCUUAU		14
16805	MI0001833	zma-MIR169d	Zea mays miR169d stem-loop	GCAAUAGGGGCCACUCAGGCUAGCCAAGGAGACUGCCUAUGAACCUCUCAAUGGUCCACACAUUCAGGUCCUUUGUAAACAAAGGACAUAGGCAAGUCAUCCUUGGCUAUCAGAGGUAGGCCCUUAUU		14
16806	MI0001834	zma-MIR169e	Zea mays miR169e stem-loop	GCAAUAGGGGCCACUCAGGCUAGCCAAGGAGACUGCCUACGAACCAACACAAAGGUCCACAAUUCUGAUCCUUUGUAAACAAAGGACAUAGGCAAGUCAUCCUUGGCUAUCAGAGGCAGGCCCUUAUU		14
16807	MI0001835	zma-MIR171c	Zea mays miR171c stem-loop	GGGGAAUCGAAAACCUACGGGAUAUUGGUGCGGUUCAAUCAGAAAGCUUGCGCUCCAAAGCCCAGGGGCUCCACUCUUUGACUGAGCCGUGCCAAUAUCACGUCCUCGCUUUGCUUGC		14
16808	MI0001836	zma-MIR171j	Zea mays miR171j stem-loop	AAUGGCCGCGAGCUAGACGGGGUAUUGACGCGGUUCAAUUCGAGAGCUCGAGCCCUAGCAGAGGCCAGGGGGGGUGGGGCUCUGCUCUCUGAUUGAGCCGUGCCAAUAUCACGUCCCACUCGCCCUCGC		14
16809	MI0001837	zma-MIR171e	Zea mays miR171e stem-loop	AGAAAUGGAAUAGUAGCUAUGAUGUUGGCUCGGCUCACUCAGACGACGUACGCGCGCGAGAUCAUGUGCUAUGCCGCUGCUGUUUCUGAUUGAGCCGUGCCAAUAUCUUAGUACUCUUCCAUGCAU		14
16810	MI0001838	zma-MIR171i	Zea mays miR171i stem-loop	CUGGUUGGCUGAGAGAGUGCGAUGUUGGCACGGUUCAAUCAAAUCGCCGGCCGGGUUGACUUGUUGAUUGAGCCGUGCCAAUAUCACAACCUUCUCUAGCCUAG		14
16811	MI0001839	zma-MIR171g	Zea mays miR171g stem-loop	AGAACGAGGCGACAUGGCAUGGUAUUGACUUGGCUCAUCUCUCGCCCACACCAGAAUCCACAAGUGCCGGAGGAGGUGAGCCGAGCCAAUAUCACUUCAUGUCAUCUAGCGU		14
16812	MI0001840	zma-MIR172e	Zea mays miR172e stem-loop	CAGCCAGCCGGUGAUUUCUGGAGUGGCAUCAUCAAGAUUCACACACUGCAUGCCAACAUAAUGCGCGUGUUCAUGCAUCCAUCGCCGCCGCUGCAUCAUGCAUCAUAUAUAAUAUAUAUAUAUGUGUAUGUGUGGGAAUCUUGAUGAUGCUGCAUUGGAUAUCAAGGGCUAUAU		14
16813	MI0001841	zma-MIR166l	Zea mays miR166l stem-loop	AAAGAACGGGAGGAGGGUUUCUGGAAUGGAGGCUGGUCCAAGAUCCUUAGGUGUUAAAGCAUUAUAUUGCCUUGUUUCUGGUUUUGUGUUUGAGAUCUCGGACCAGGCUUCAUUCCUCAAACCCACGCUCCCGACAC		14
16814	MI0001842	zma-MIR166m	Zea mays miR166m stem-loop	UCCUUGGUCUGGGGGUUUGUGGGGAAUGUUGGCUGGCUCGAGGCAUCCGCGUCCUGGCUCGCAGUCGCAGCGCAGAUCGUGUUUUGCCUGCUACCGGCCGGACAGAUCGAGAGGCGUCGGACCAGGCUUCAUUCCUCGCAAACCGGUGCAUCCCCA		14
16815	MI0001843	zma-MIR171k	Zea mays miR171k stem-loop	GGGAGGAAGAAGACGACAUGGCGUGGUAUUGUUUCGGCUCAUGUCCUUCUUGACUGGAUGUGAUGUGAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCUGA		14
16816	MI0001844	zma-MIR171h	Zea mays miR171h stem-loop	GGGAGGAAGGAGACGACAUGGCGUGGUAUUGUUUCGGCUCAUGUCCUUCUUCGAUCGAGUCUUGCCGUUGGAUUUGGAUGUGAUGUGAGCCGAACCAAUAUCACUCAUGUACUCUUCAUUCCCA		14
16817	MI0001845	zma-MIR393	Zea mays miR393 stem-loop	CCAGGAAGCUGGUGGAGGACUCCAAAGGGAUCGCAUUGAUCUAUUCUCACCUGCCGCCUGCUGCAUGCGAUGCGAGUCGACGACAAGAUCAGUGCAAUCCCUUUGGAAUUUUCCACUCGCGCCUUC		14
16818	MI0001846	zma-MIR408	Zea mays miR408 stem-loop	GGGGUUGGUUUUGAUUUGGAGACAGGGAUGAGACAGAGCAUGGGAUGGGGCCAUCAACAAAGUGGAGGGACUAGCUUGCGAGGCAGAAAGAAGGUGCCAGUGCCGGUGCCUCCCCGGUGAAACGAUGAUGGGAGUGUUGUUGCUCCCUCCCCUGCACUGCCUCUUCCCUGGCUCCGAUCCCCCACCGUUGC		14
16819	MI0001847	zma-MIR156k	Zea mays miR156k stem-loop	GGCUUAGGCCCCGAAGAGAUUGACAGAAGAGAGCGAGCACCUGGCGCGGCGACCGGCAUGGAACGCAUGCCGUCCCCGCCGCGUGCUCGCUUCUCUUUCUGUCAGCCUCUCCCUCGUCCUGAG		14
16820	MI0001848	zma-MIR160f	Zea mays miR160f stem-loop	GAGGUGAAAGAUAGGGAAUAUGCCUGGCUCCCUGUAUGCCGCUCGCAUGGCUACCACCGCCUGUGGUCGUUGCGGCUGGCGUGCGAGGUGCCAGGCAUGUUUUAAUAAUUAUCUCC		14
16821	MI0001849	sbi-MIR399h	Sorghum bicolor miR399h stem-loop	AGUGUUCAGGGUAAGAAUCACAGUGCGGUUCUCCUCUGGCAUGGAGGCCAACAUAGCAGGCAUUGGAGAAUGCACAGCGCUAUCGCCAUCCCUGCCAAAGGAGAAUUGCCCUGCCAUUCGGUAUAACCCUGG		15
16822	MI0001850	sbi-MIR399i	Sorghum bicolor miR399i stem-loop	AUGCCUAAGCUGUCCAGUUUCAGGGCUUCUCUUUCUUGGCAGGGAGCAUGAGAAGCCAUAGCUCUGCUCUGUUCUGCCCUCUGCCAAAGGAGAGUUGCCCUGUAACAGGACUCAGCUUAUG		15
16823	MI0001851	sbi-MIR159b	Sorghum bicolor miR159b stem-loop	UGAAUGAAGAUAUGAAGAAGAAGACGACGACGAUGAAGAAGGCGAAGAAAAGCGAACAAAGAGCUCCCUUCGAUCCAAUCCAGGAGGGGAAGUGGUCGGUUGCAGCUGCCGGUUCAUGGAUGCCUCUCUGGUGCAGCAAUGACUGAUGCUCACCUGCACUUGCAUGGGUGUGCAUGACCCGGGAGAUGAACCCACCAUCAUCUUUCCCUCGUGCUUGGAUUGAAGGGAGCUCCUCUCUCUUUCUCUCUUUCUC		15
16824	MI0001852	sbi-MIR164c	Sorghum bicolor miR164c stem-loop	UAUGGUGUGUUUGUGCAGGGUGGAGAAGCAGGACACGUGAGCGACCAUCCAGUUUCCAUCGCUGGCUCUCCGCUGCGGGCGCUGCCGUGCGUUGGAUCGUCGUUGGGUGGUCGCUCAUGUGUCCGUCCUCUCCACCGAGCACCGGUACAUCCG		15
16825	MI0001853	sbi-MIR166g	Sorghum bicolor miR166g stem-loop	UCAUGCUCGGAUUAGGUUAGGGGGAUUGUUGUCUGGCUCGGGGUCUCCGGUCGAGAAUCCUUGGCCUUGCCGGAGUUGUCGUUGACCGGAGAUUUCGGACCAGGCUUCAAUCCCUUUAACCAUGCGGCAUUUAG		15
16826	MI0001854	sbi-MIR171f	Sorghum bicolor miR171f stem-loop	UGAGAGAAUAAGACGACAUGGCGUGAUGUUGUUUCGGCUCAUGCAUAUCCUUCUUGAGUGUAUCAUCAGGAAAGAGGCGAUGAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCAUA		15
16827	MI0001855	sbi-MIR395f	Sorghum bicolor miR395f stem-loop	ACAAUGUUUGGUGUUACCACGAGUUCCCUUCAAGCACUUCAUGAGGCACCAUUAAAUAACUCUAUUUAAGAUUAGGUGUAAUAUGAAGUGUUUGGGGGAACUCUUGGUGAUACUCAACAUCG		15
16828	MI0001856	sbi-MIR156e	Sorghum bicolor miR156e stem-loop	CGAUUAGGCCCUGAAGAGAUUGACAGAAGAGAGCGAGCACCCGGCGCGGCGGCCGGCAUGGAGCGCAUGCCGUCCCCGCCGCGUGCUCGCUUCUCUUUCUGUCAGCCUCUCUCUCGUCCUGGG		15
16829	MI0001857	dre-let-7a-1	Danio rerio let-7a-1 stem-loop	GACGGUGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACACUGGGAGAUAACUAUACAACCUACUGUCUUUCUCAAAGUC		12
16830	MI0001858	dre-let-7a-2	Danio rerio let-7a-2 stem-loop	GCCCCCAGGCUGAGGUAGUAGGUUGUAUAGUUUAGAAUAACAUCACUGGAGAUAACUGUACAACCUCCUAGCUUUCCCUGAGAU		12
16831	MI0001860	dre-let-7a-3	Danio rerio let-7a-3 stem-loop	GAGACUGUCGUUUGGGGUGAGGUAGUAGGUUGUAUAGUUUGAGGGUUUAACCCUUGCUGUCAGAUAACUAUACAACUUACUGUCUUUCCCGAAGUGGCCGUAGUGUC		12
16832	MI0001861	dre-let-7a-4	Danio rerio let-7a-4 stem-loop	GCGAUGUCUCGGGAUGAGGUAGUAGGUUGUAUAGUUUAGAGUUACAACACGGGAGAUAACUGUACAGCCUCCUAGCUUUCCUCGAGCAGACGC		12
16833	MI0001862	dre-let-7a-5	Danio rerio let-7a-5 stem-loop	GUACGUGUUUUUGGUGUCUGGACAAGGUGAGGUAGUAGGUUGUAUAGUUUGGUGGGAGGGAUCAAACCCUGUUCAGGUGAUAACUAUACAGUCUAUUGCCUUCCUUGUGUCACCUAAGGUCUGC		12
16834	MI0001863	dre-let-7a-6	Danio rerio let-7a-6 stem-loop	CACAGUGAACCUGUGUGUUUCUUCAAGGUGAGGUAGUAGGUUGUAUAGUUUGUGGGAAGGAUCACAUCCUAUUCAGGUGAUAACUAUACAGUCUAUUGCCUUCCCUGAGAGACACAAUGACCACGAGUG		12
16835	MI0001865	dre-let-7b	Danio rerio let-7b stem-loop	UCGGACAGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGUUGUGUUUUUGCCCCAUCAGGAGUUAACUAUACAACCUACUGCCUUCCCUGAAGGG		12
16836	MI0001866	dre-let-7c-1	Danio rerio let-7c-1 stem-loop	CUGAGAGUGUGUGCAUCCAGGCUGAGGUAGUAGGUUGUAUGGUUUAGAAUUUUGCCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGCUCACAAGCCAG		12
16837	MI0001867	dre-let-7c-2	Danio rerio let-7c-2 stem-loop	GUGUGCAUCCAGGCUGAGGUAGUAGGUUGUAUGGUUUCGAAUGACACCAUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGUACAC		12
16838	MI0001868	dre-let-7d-1	Danio rerio let-7d-1 stem-loop	UGUGCGUUGCGGUGUGAGGUAGUUGGUUGUAUGGUUUUGCAUAAUAAACAGCCCGGAGUUAACUGUACAACCUUCUAGCUUUCCCUGCGGCUGCACG		12
16839	MI0001870	dre-let-7d-2	Danio rerio let-7d-2 stem-loop	CGCUGCAGGCUGAGGUAGUUGGUUGUAUGGUUUUGCAUCAUAAUCAGCCUGGAGUUAACUGUACAACCUUCUAGCUUUCCCUGCGGUG		12
16840	MI0001871	dre-let-7e	Danio rerio let-7e stem-loop	GCUGUUCUUGGGGCUGAGGUAGUAGAUUGAAUAGUUGUGGAGCCCUGCGCUCUCUCUCUGAGAUAACUAUACAAUCUACUGUCUUUCCUAAGGCGACAGC		12
16841	MI0001872	dre-let-7f	Danio rerio let-7f stem-loop	UGGUAAUGCUUGUGCAGUGUGAGGUAGUAGAUUGUAUAGUUGUAGGGUAGUGAUUUUAUCCUGUGUAGAAGAUAACUAUACAAUCUAUUGCCUUCCCUGAGGGGCAGAAAUACACA		12
16842	MI0001873	dre-let-7g-1	Danio rerio let-7g-1 stem-loop	GGGGGCUGUGGAAUGAGGUAGUAGUUUGUAUAGUUUGGGAUCACACCAGAUCUGGGAGAUAACUAUACAGCCUACUGUCUUUCUCACAGCUGCUCC		12
16843	MI0001874	dre-let-7g-2	Danio rerio let-7g-2 stem-loop	GUGGACUGUGGGAUGAGGUAGUAGUUUGUAUAGUUUUAGGAUCACACCAGAUCUGGGAGAUAACUAUACAGUCUACUGUCUUUCCCACGGUUACCGC		12
16844	MI0001875	dre-let-7h	Danio rerio let-7h stem-loop	GAGUUGGCUGUGUUGUGGUGAGGUAGUAAGUUGUGUUGUUGUUGGGGAUCAGUAUAGUAUGGCCCUUGAAGGAGAUAACUAUACAAUUUACUGCCUUCCAUAAUGCAGACUCUC		12
16845	MI0001876	dre-let-7i	Danio rerio let-7i stem-loop	GUGUACUGGCUGAGGUAGUAGUUUGUGCUGUUGGUUGGGAUGUGACAUUGCCCGUUAUGGAGAUGACUGCGCAAGCUACUCCCUUGCCAGUGCUG		12
16846	MI0001877	dre-mir-1-2	Danio rerio miR-1-2 stem-loop	GCCUACUUGGUGUACAUACUUCUUUAUGUGCCCAUAUGAACAUAUAAAAGCUAUGGAAUGUAAAGAAGUAUGUAUUCUUGGUCAGGU		12
16847	MI0001878	dre-mir-1-1	Danio rerio miR-1-1 stem-loop	GCCCAUAUAUCCCGCUUGGUAGACAUACUUCUUUAUAUGCCCAUAUGAACAAGAGCAGCUAUGGAAUGUAAAGAAGUAUGUAUCCCAGGUGAGAGAAAAACGGGGC		12
16848	MI0001879	dre-mir-7a-3	Danio rerio miR-7a-3 stem-loop	UGUGUGUGUGUUCUGCCCUCUGCGGAGUGGAAGACUAGUGAUUUUGUUGUGAAAAUGAACAAAAACCAACAACAAACCGCAGUCGUCCUCUCAGCACGGGGCCCACACCUGCAGAGCACA		12
16849	MI0001880	dre-mir-9-1	Danio rerio miR-9-1 stem-loop	GGGGUUGGCUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUAUUCAUUCUUCAUAAAGCUAGAUAACCGAAAGUAACAAGAAUCCC		12
16850	MI0001881	dre-mir-9-2	Danio rerio miR-9-2 stem-loop	GCUCUCCUCUGGUGACUUUUGCACUUGGAGGCGUGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUGCUGGCCGUCAUAAAGCUAGAUAACCGAAAGUAAGAGCCGCUUCUAUCAGCAACGUAUGGAGCAUUGC		12
16851	MI0001882	dre-mir-9-4	Danio rerio miR-9-4 stem-loop	UGGGUUAGUUUUUCUCUUUGGUUAUCUAGCUGUAUGAGUUUAUGUGAUAUCAUAAAGCUAGAGAACCGAAUGUAUAAACUAAUUCCA		12
16852	MI0001883	dre-mir-9-3	Danio rerio miR-9-3 stem-loop	UCAGGGGGUUGGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUUAUAACACUGUCAUAAAGCUAGAUAACCGAAAGUAGAAAUAAUUCCCAAAAUCUUUGG		12
16853	MI0001884	dre-mir-9-5	Danio rerio miR-9-5 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUAUUUUGCACUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUGCCUCC		12
16854	MI0001885	dre-mir-9-6	Danio rerio miR-9-6 stem-loop	GGAGGUAGUUGCUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUUAUCUGCCUUCAUAAAGCUAGAUAACCGAAAGUAGAAACGUCCUCC		12
16855	MI0001886	dre-mir-9-7	Danio rerio miR-9-7 stem-loop	GGGUUAGUUUUUCUCUUUGGUUAUCUAGCUGUAUGAGUUAUGAAAUAUCAUAAAGCUAGAGAACCGAAAGUAGAAACUAUACCU		12
16856	MI0001887	dre-mir-10b-2	Danio rerio miR-10b-2 stem-loop	GUAGUCGUCUAUAUGUACCCUGUAGAACCGAAUUUGUGUCCAAAACAUCAAAAUCGCAAAUACGUCUCUACAGGAAUACAUGGGCGACGUAA		12
16857	MI0001888	dre-mir-10c	Danio rerio miR-10c stem-loop	CCUGUCAUCUAUAUAUACCCUGUAGAUCCGGAUUUGUGUAAACAGACGCACAGUCACAAAUUCGUAUCUAGGGGAGUAUGUAGUUGAUGUAUAGG		12
16858	MI0001889	dre-mir-10d-1	Danio rerio miR-10d-1 stem-loop	UGGAAGCUUUGUUCCGUCGUCUAUAUAUACCCUGUAGAACCGAAUGUGUGUUUACACAGCAAAUUCACAGAUUCGGUUUUAGGGGAGUAUAUGGACGAUGCAAAAACGUCUGCUUUCA		12
16859	MI0001890	dre-mir-10d-2	Danio rerio miR-10d-2 stem-loop	UGGAAGCUUUGUUCCGUCGUCUAUAUAUACCCUGUAGAACCGAAUGUGUGUUUACACAGCAAAUUCACAGAUUCGGUUUUAGGGGAGUAUAUGGACGAUGCAAAAACGUCUGCUUUCA		12
16860	MI0001891	dre-mir-15a-1	Danio rerio miR-15a-1 stem-loop	CCUGUCGGUACUGUAGCAGCACAGAAUGGUUUGUGAGUUAUAACGGGGGUGCAGGCCGUACUGUGCUGCGGCAACAACGACAGG		12
16861	MI0001892	dre-mir-15a-2	Danio rerio miR-15a-2 stem-loop	GCCGAGGCUCUCUAGGUGAUGGUGUAGCAGCACAGAAUGGUUUGUGGUGAUACAGAGAUGCAGGCCAUGAUGUGCUGCAGCAUCAAUUCCUGGGACCUACGC		12
16862	MI0001893	dre-mir-15b	Danio rerio miR-15b stem-loop	GUCUGUCGUCAUCUUUUUAUUUAGCCCUGAGUGCCCUGUAGCAGCACAUCAUGGUUUGUAAGUUAUAAGGGCAAAUUCCGAAUCAUGAUGUGCUGUCACUGGGAGCCUGGGAGUUUCUCCAUUAACAUGACAGC		12
16863	MI0001894	dre-mir-16a	Danio rerio miR-16a stem-loop	CCUUCCUCGCUUUAGCAGCACGUAAAUAUUGGUGUGUUAUAGUCAAGGCCAACCCCAAUAUUAUGUGUGCUGCUUCAGUAAGGCAGG		12
16864	MI0001895	dre-mir-16b	Danio rerio miR-16b stem-loop	CCUGAACUUGGCCGUGUGACAGACUGGCUGCCUGGCUGUAGCAGCACGUAAAUAUUGGAGUCAAAGCACUUGCGAAUCCUCCAGUAUUGACCGUGCUGCUGGAGUUAGGCGGGCCGUUUACCGUCUGCGGGGGCCUCGGG		12
16865	MI0001896	dre-mir-16c	Danio rerio miR-16c stem-loop	GAGGUUGUGUGUGUGUGCGUGUGUUGUCUUGCUUUAGCAGCAUGUAAAUAUUGGAGUUACUCCUUGGCCAAUGCCUCCAAUAUUGCUCGUGCUGCUGAAGCAAGAAGUCACCAAGCAGCACAUGCACGUCAUCCUU		12
16866	MI0001897	dre-mir-17a-1	Danio rerio miR-17a-1 stem-loop	GGACUUUCUUGAGUGGACUUGGUUGGUGUCAAUGUAUUGUCAAAGUGCUUACAGUGCAGGUAGUAUUAUGGAAUAUCUACUGCAGUGGAGGCACUUCUAGCAAUACACUUGACCAUUUUAACCUUCCUCCAGGCAUCC		12
16867	MI0001898	dre-mir-17a-2	Danio rerio miR-17a-2 stem-loop	GUCACUGUAGUGUCAAAGUGCUUACAGUGCAGGUAGUUCAAUAUAAUCUACUGCAGUGGAGGCACUUCAAGCUUUACCGUGAC		12
16868	MI0001899	dre-mir-20b	Danio rerio miR-20b stem-loop	GAGUUUGUCCUGGCAGUUCCAAAGUGCUCACAGUGCAGGUAGUGCCAGUGGAUCUACUGCAAUGUCUGCACUUCAAGUAUUGCCGGACGCCUUC		12
16869	MI0001900	dre-mir-18a	Danio rerio miR-18a stem-loop	GGCUUUGUGCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGACUAGCACCUACUGCCCUAAGUGCUCCUUCUGGCACGAGGGU		12
16870	MI0001901	dre-mir-18b	Danio rerio miR-18b stem-loop	UACUGCUUAUGCUAAGGUGCAUUUAGUGCAGAUAGUGAAAUAGACUAGCACCUACUGCCCUAAGUGCCCCUUCUGGCAUAAGGGGCU		12
16871	MI0001902	dre-mir-18c	Danio rerio miR-18c stem-loop	GCCUUCCUGCUAAGGUGCAUCUUGUGUAGUUAGUGAAGUAGUCUAGUAUCUACUGCGCUAGAUGUUCCUUUUGGCAGGAGUAGCU		12
16872	MI0001903	dre-mir-19a	Danio rerio miR-19a stem-loop	UGGUGCAGUUCUCUGCUAGUUUUGCAUAGUUGCACUACAAGAAAACGGGAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGCUGC		12
16873	MI0001904	dre-mir-19b	Danio rerio miR-19b stem-loop	GCUGGACCCCCGGUCAGUUUUGCUGGUUUGCAUUCAGCUUUUAAGACUGUGCGCUGUGCAAAUCCAUGCAAAACUGAUUGUGGCAGC		12
16874	MI0001905	dre-mir-19c	Danio rerio miR-19c stem-loop	UGGAAAAGCCCUGUUAUCUGGGGUGAGUUUUGCAGGAUUGCAUCCGGCUUUAUUACAACAUGCUGUGCAAAUCCAUGCAAAACUCGCUGCGCCAGGGACAAACCA		12
16875	MI0001906	dre-mir-19d	Danio rerio miR-19d stem-loop	GUUGUGUGGCGGUCAGCUUUGCGGGGUGGGCAGUCAGCCUCCGUGUGGCCGCUGUGCAAACCCAUGCAAAACUGAGCGCUGCGCUAC		12
16876	MI0001907	dre-mir-20a	Danio rerio miR-20a stem-loop	UCUUAAAUAAAUCUCCUAAUGUUGCAGUUGUGUUAGAGUUUCAGCAGUGCUAAAGUGCUUAUAGUGCAGGUAGUAUUUCUGUCAUCUACUGCAGUGUGAGCACUUGAAGUACUUCUAGCUUAAUGCGUCUGGGAUCCGAAGAUUUCUGCUAGA		12
16877	MI0001908	dre-mir-21-1	Danio rerio miR-21-1 stem-loop	UUAUGUGUCUUUAUUGGCGUGGAUAUAAGUCUUUCCCAGUGUGUCAGAUAGCUUAUCAGACUGGUGUUGGCUGUUACAUUCGCCCGGCGACAACAGUCUGUAGGCUGUCUGACAUUUUGGGCAUUUUCUUCUCCGAUUAAAAAUAUGA		12
16878	MI0001909	dre-mir-21-2	Danio rerio miR-21-2 stem-loop	AGACAGACAGUAAAAGUGUCCCUUUCUGUCAUGUAGCUUAUCAGACUGGUGUUGGCUUUGAGUUUUUGGCAACAGCAGUCUAAUAGGCUGUCUGACAUUUUGGGCUUAUUCGACGUACGGUUUGUUU		12
16879	MI0001910	dre-mir-22a-1	Danio rerio miR-22a-1 stem-loop	GCUGACCUGCAGCAGUUCUUCACUGGCAAGCUUUAUGUCCUUGUGUACCAGCUAAAGCUGCCAGCUGAAGAACUGUUGUGGUUGGC		12
16880	MI0001911	dre-mir-22a-2	Danio rerio miR-22a-2 stem-loop	GCUGACCUGCAGCAGUUCUUCACUGGCAAGCUUUAUGUCCUUGUGUACCAGCUAAAGCUGCCAGCUGAAGAACUGUUGUGGUUGGC		12
16881	MI0001912	dre-mir-22b	Danio rerio miR-22b stem-loop	GUUACUUCACAGUCGUUCUUCACUGGCUAGCUUUAUGUGGCAGCACCUUAAAGCUGCCAGUUGAAGAGCUGUUGUGGGUAAC		12
16882	MI0001913	dre-mir-23a-1	Danio rerio miR-23a-1 stem-loop	GCUGUGGCGGGGAGGGUUCCUGGCACCGUGAUUUGGUGGAUAAACAGAAAUGAAAAUCACAUUGCCAGGGAUUUCCACUCCUGCACGGU		12
16883	MI0001915	dre-mir-23a-2	Danio rerio miR-23a-2 stem-loop	CUCUUCUGCCGGCCAGGGGAAUUCCUGGCAGAGUGAUUUUUAAACCUAAUGACUGAAUCACAUUGCCAGGGAUUUCCAAUGGCUCGUGUGACUCAGAG		12
16884	MI0001916	dre-mir-23a-3	Danio rerio miR-23a-3 stem-loop	CCAGCUGGAGGGAUUCCUGGCAGAGUGAUUUGGGAUUAUAUCAUAAAAUCACAUUGCCAGGGAUUUCCAACCAGCUGU		12
16885	MI0001917	dre-mir-23b	Danio rerio miR-23b stem-loop	GUGGCUGUGUGGGUUCUUGGCAUGCUGAUUUGUGACUGUAGUAAAAAAAAAUCACAUUGCCAGGGAUUACCACACUACCAC		12
16886	MI0001918	dre-mir-24-4	Danio rerio miR-24-4 stem-loop	GAGGGCUGUUCCCACUUGUGCCUGCUAAACUGGUAUCAGUAUGUUGAUUUAGUGCUGGCUCAGUUCAGCAGGAACAGGUGUGAAGUCCUC		12
16887	MI0001919	dre-mir-24-2	Danio rerio miR-24-2 stem-loop	GGGCUGGUCUCCUGUGCCUGCUGUGCUGAUAAUCAGUGGACGGCUGUGACUGGCUCAGUUCAGCAGGAACAGGGGCCUGGUC		12
16888	MI0001920	dre-mir-24-3	Danio rerio miR-24-3 stem-loop	GCUGAACGGGAGUCAUAUGAGAGAUAGAUGGAGCUGGCCUCCCGUGCCUACUGAGCUGAUUACAGUACUGUGCAAACACUGGCUCAGUUCAGCAGGAACAGGAGUCUGGUCCACAAACUCCACCAAACACUGCUGCUUCAGC		12
16889	MI0001921	dre-mir-24-1	Danio rerio miR-24-1 stem-loop	ACCUGAGCUCCGGUGCCUUCUGAGCUGAUAUCAGUUGUAGUAAAUCACUGGCUCAGUUCAGCAGGAACAGGAGUGUGGCC		12
16890	MI0001922	dre-mir-25	Danio rerio miR-25 stem-loop	GCCGGCGCUGAGAGGCGGAGACUUGGGCAGCUGCCGUCAUUCCCAGAAGGCAUUGCACUUGUCUCGGUCUGACAGUGGCGGC		12
16891	MI0001923	dre-mir-26a-1	Danio rerio miR-26a-1 stem-loop	UUUGGCCUGGUUCAAGUAAUCCAGGAUAGGCUUGUGAUGUCCGGAAAGCCUAUUCGGGAUGACUUGGUUCAGGAAUGA		12
16892	MI0001925	dre-mir-26a-2	Danio rerio miR-26a-2 stem-loop	GUGUGGACUUGAGUGCUGGAAGUGGUUGUUCCCUUGUUCAAGUAAUCCAGGAUAGGCUGUCUGUCCUGGAGGCCUAUUCAUGAUUACUUGCACUAGGUGGCAGCCGUUGCCCUUCAUGGAACUCAUGC		12
16893	MI0001926	dre-mir-26a-3	Danio rerio miR-26a-3 stem-loop	CUAAGCUGAUACUGAGUCAGUGUGUGGCUGCAACCUGGUUCAAGUAAUCCAGGAUAGGCUUUGUGGACUAGGGUUGGCCUGUUCUUGGUUACUUGCACUGGGUUGCAGCUACUAAACAACUAAGAAGAUCAGAAGAG		12
16894	MI0001927	dre-mir-26b	Danio rerio miR-26b stem-loop	GCAUUUGGCCUUUGCCUGGUUCAAGUAAUCCAGGAUAGGUUAGUUCCCACUAGUACGGCCUAUUCUUGGUUACUUGUUUCAGGAGGAGGCUACGAGC		12
16895	MI0001928	dre-mir-27a	Danio rerio miR-27a stem-loop	UCUGGAUAUGAUGUCUGCUGAAGUUUCGUGAGGUGCAGGACUUAGCUCACUCUGUGAACAGAUCUCGGAUAUCCUAUGUUCACAGUGGCUAAGUUCCGCUCCUCUGAGGCCCACACUCGAAAUCAGCCAGG		12
16896	MI0001929	dre-mir-27b	Danio rerio miR-27b stem-loop	UCUUUUCUAGCAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGAACUCUUUGUUCACAGUGGCUAAGUUCUGCAUCUGAGGAGAGGA		12
16897	MI0001930	dre-mir-27c	Danio rerio miR-27c stem-loop	GGUUGUGUGGUGUCAGGACUUAACCCACUUGUGAACAAUGCAUCGAACUUCAAUGUUCACAGUGGUUAAGUUCUGCCGCCCCUAGACC		12
16898	MI0001931	dre-mir-27d	Danio rerio miR-27d stem-loop	UUCUGAGCGGGUGCAGAGCUUGGCUGAUUGGUGAACGUGCAUGGCUUGUGUUUUUGUUCACAGUGGCUAAGUUCUUCACCCGAAAAGAA		12
16899	MI0001932	dre-mir-27e	Danio rerio miR-27e stem-loop	GUCAUCACUCGCUCACGGCGCAGAGCUUAGCUAAUCGGUGAGCAUUGAUCCCUUAAGAAAACUGUUCACAGUGGCUAAGUUCAGUGUCUGGAGUGAACGGGAUGAC		12
16900	MI0001933	dre-mir-29b-1	Danio rerio miR-29b-1 stem-loop	CUGCUCCUGGAAGCUGAAUUCAGAUGGUGCCAUAGAGUAUUUUAUGGCAUCUAGCACCAUUUGAAAUCAGUGUUCCUGGGCCG		12
16901	MI0001934	dre-mir-29b-2	Danio rerio miR-29b-2 stem-loop	UCUCCUCCUGGAAGCUGGUUUCAAGUGGUGUUUUAGAGUGCUGAUCAAAUGAAUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGUGAGA		12
16902	MI0001936	dre-mir-29b-3	Danio rerio miR-29b-3 stem-loop	UCUUCCUCCAGAUGCUGGUUUCACAUGGUGGUUUAGAUGUGUUCUACCAAAGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGAGGG		12
16903	MI0001938	dre-mir-29a-1	Danio rerio miR-29a-1 stem-loop	UGAAGACCCUCAUCUCUCUCUCUCUCUCCCCACCAAACGAUGACUGAUUUCCUUUGGUGCUUAGAGUCCCAUCUGUCAUCUAGCACCAUUUGAAAUCGGUUAUAAUGACUGGGGAUCAAUUCUUCA		12
16904	MI0001940	dre-mir-30a	Danio rerio miR-30a stem-loop	GGCUCCUUGCAGUUGUAAACAUUCCCGACUGGAAGUUGUAAUGCAGAAAAUCUCAGCUUUCAGUCUGAUGUUUGCUGCUACUGGUGGCC		12
16905	MI0001941	dre-mir-30b	Danio rerio miR-30b stem-loop	UUCCAGUGUAGUCGCUGUAAACAUCCUACACUCAGCUGUGAGCUGCAGACGAGGCUGGGCGGAGGGUGUUUGCUGUGACUGUCUGGAG		12
16906	MI0001944	dre-mir-30c	Danio rerio miR-30c stem-loop	CUUCAGGGAGUGUAAACAUCCUACACUCUCAGCUGGAGCGCAGCCGAGGCCGGGAGUGGGAUGUUUGCGCUCUCUGGCU		12
16907	MI0001946	dre-mir-30d	Danio rerio miR-30d stem-loop	GUGCUGUAUAUGGGUAUAACUGGUUGUUCAUGCCUGUAAACAUCCCCGACUGGAAGCUGUGCUACGCGGAAAACGAGCUUUCAGUUGGAUGUUUGCUGUCAUCGUCCAGUUCUGUCGCCUUGUAUUAC		12
16908	MI0001950	dre-mir-30e-2	Danio rerio miR-30e-2 stem-loop	UACGGGCUACUGUAAACAUCCUUGACUGGAAGCUGGUGCACAUGAUGGAGCUUUCAGUCGGAUGUUUGCAGCAGCCAACU		12
16909	MI0001951	dre-mir-92a-1	Danio rerio miR-92a-1 stem-loop	UGGUCCCUUUCUGCGCAGGUUGGGAUUGGUAGCAAUGCUGUGUGUUUUGAAGGUAUUGCACUUGUCCCGGCCUGUAAAGGAUUGU		12
16910	MI0001952	dre-mir-92a-2	Danio rerio miR-92a-2 stem-loop	ACAGCAUCCCUUUCUUUGCAGGUUGGGAUCGGCCGCAAUGCUCUGUGCUGGAAGUAUUGCACUUGUCCCGGCCUGUGAAGAGCAUGGGAAAUUGU		12
16911	MI0001953	dre-mir-92b	Danio rerio miR-92b stem-loop	UCCUACGGGCAGGGAGGUGUGGGAUGUUGUGCAGUGUUGUUCAAUCUCCCGCCAAUAUUGCACUCGUCCCGGCCUCCCUGAC		12
16912	MI0001954	dre-mir-93	Danio rerio miR-93 stem-loop	GUGUGUGUUAAAAGUGCUGUUUGUGCAGGUAGUGUGUUUCCUCUACUGUAGGAGCAGCACUUCACAACACACAC		12
16913	MI0001955	dre-mir-96	Danio rerio miR-96 stem-loop	GCUGGGCGCUCUUCUUUGCCUGUUUUGGCACUAGCACAUUUUUGCUUUUUUAUAUAUACCUUGAGCAAUUAUGUGUAGUGCCAAUAUGGGACAAGACAGACAUGCUACUUAAAAAAAAAAUCAGC		12
16914	MI0001956	dre-mir-99-1	Danio rerio miR-99-1 stem-loop	GCCACUUGUCAUUAACCCGUAGAUCCGAUCUUGUGAUAAGUUUGAUGGCACAAGCUCGAUUCUAUGGGUCUCUGUCUCUGUGGU		12
16915	MI0001957	dre-mir-99-2	Danio rerio miR-99-2 stem-loop	CACUUGUCACAAACCCGUAGAUCCGAUCUUGUGGCGUAAUCGGCAACCCAAGCUCGAUUCUGUGGGUCUCUGUCACUGUG		12
16916	MI0001958	dre-mir-100-1	Danio rerio miR-100-1 stem-loop	GAAGAGACCUGCCUGCUGACACAAACCCGUAGAUCCGAACUUGUGGUGACUGUCCACACAAGCUUGUAUCUAUAGGUAUCUGUCUGUGUGGCCUUC		12
16917	MI0001959	dre-mir-100-2	Danio rerio miR-100-2 stem-loop	AGCUGCCACAAACCCGUAGAUCCGAACUUGUGGUGUCUCUGUGCACAAGCUCGUGUCUAUAGGUAUGUGUCUGCG		12
16918	MI0001960	dre-mir-101a	Danio rerio miR-101a stem-loop	GGCUGCCCUGGUUCAGUUAUCACAGUGCUGAUGCUGUCCAUCUUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCUGCC		12
16919	MI0001961	dre-mir-101b	Danio rerio miR-101b stem-loop	GCUCCUCCGUCAUGAAUUGUCCAUUUUCAGUUAUCAUGGUACCGGUGCUGUGUGCCUGUCAAGUACAGUACUAUGAUAACUGAAGAUUGACAAUGCCAAACAUCAGUGGAGU		12
16920	MI0001962	dre-mir-103	Danio rerio miR-103 stem-loop	UUGCCCUGGUCUGUCAGCCUCUUUACGGUGCUGCCUUGUGGAAUCUGGAUCAAGCAGCAUUGUACAGGGCUAUGAGAGACCCGGGCCC		12
16921	MI0001963	dre-mir-107	Danio rerio miR-107 stem-loop	UCUGUGUGCUCUGAGCUUCUUUACAGUGUUGUCUUGUGGCAUGGAGAUCAAGCAGCAUUGUACAGGGCUAUCACAGCACACUGAACAGC		12
16922	MI0001965	dre-mir-122	Danio rerio miR-122 stem-loop	UCCAGAGCUGUGGAGUGUGACAAUGGUGUUUGUAUCAUCUGUCGUCAAACGCCAUUAUCACACUAAAUAGCCACGG		12
16923	MI0001966	dre-mir-124-1	Danio rerio miR-124-1 stem-loop	GGCUCUCGCUGUACGUGUUCACAGUGGACCUUGAUUUAUUGUAUUUCAAUUAAGGCACGCGGUGAAUGCCAACAGCACAGCC		12
16924	MI0001967	dre-mir-124-2	Danio rerio miR-124-2 stem-loop	CCUGCUUUUCUUCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGAUGGC		12
16925	MI0001968	dre-mir-124-3	Danio rerio miR-124-3 stem-loop	GGCUCUGUGGGAUUUCAGACUCUGGCUUUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCUUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUUUUAACAUCAGCAGGCC		12
16926	MI0001969	dre-mir-124-4	Danio rerio miR-124-4 stem-loop	GGUUUUUGCUCUUUGUGUUCACAGUGGACCUUGAUUUAAUUUCAAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGAAGCC		12
16927	MI0001970	dre-mir-124-5	Danio rerio miR-124-5 stem-loop	GGGUUUUGCUCGUGCGUUCUUUUUGAGUUCUCGCUCUGCGUGUUCACAGCGGACCUUGAUUUAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAAGAAUCUCUCCAGCAACGAGUUUGCGC		12
16928	MI0001971	dre-mir-124-6	Danio rerio miR-124-6 stem-loop	GGGUGGUGACACAGGCCCGCCACUCUGCGUGUUCACGGCGGACCUUGAUUUAAUAUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGGGGUCUUAAAACGACAAACCC		12
16929	MI0001972	dre-mir-125a-1	Danio rerio miR-125a-1 stem-loop	GUAUGUCUCUUUGUCCCUGAGACCCUUAACCUGUGAGGUCAAACUAGGUCACAGGUGAGGUCCUCAGGAACAGGGCUGCAUGC		12
16930	MI0001973	dre-mir-125a-2	Danio rerio miR-125a-2 stem-loop	GAUCAGUCCAAAUCGAUGUAUGUCUGUGUCCCUGAGACCCUUAACCUGUGAUGUCUUCCAAGGUCACAGGUGAGGUCCUUGGGAACACGGCUGUAUAUGAUGACGUC		12
16931	MI0001975	dre-mir-125b-1	Danio rerio miR-125b-1 stem-loop	UUCUGUUGCAGGUUGGCGGUUGGUCUGCAAAUGUGCCUCUCACAAUCCCUGAGACCCUAACUUGUGACGUUUUCCUGUUAUGUGCACGGGUUAGGUUCUUGGGAGCUGAGAGGGGUGCUCUGUCAUCAGCCCGCCGGCGUCGGAA		12
16932	MI0001976	dre-mir-125b-2	Danio rerio miR-125b-2 stem-loop	GUGCCCCUCUCCUUCCCUGAGACCCUAACUUGUGACGUUCUGCUUCGAUGUCCACGGGUUGGGUUCUCGGGAGCUGUGAGAGGCAC		12
16933	MI0001977	dre-mir-125b-3	Danio rerio miR-125b-3 stem-loop	CCCGUGCGGCCACCGCUGCACUCCUCCUGGUCCCUGAGACCCUAACUUGUGAGCUUUGUGUGCUAAAAAUCACAGGUUAAGCUCUUGGGACCUGGGCAGAGGGCAAAAGCACUGG		12
16934	MI0001978	dre-mir-125c	Danio rerio miR-125c stem-loop	GCUCUCCUCCUGUUCCCUGAGACCCUAACUCGUGAGGUCUUUUUCCAAAAUCACGGGUCAGGAGCUUGGGAGACAGGUGGAGGGC		12
16935	MI0001979	dre-mir-126	Danio rerio miR-126 stem-loop	GAGCCAUUUUAACUGCUUCACAGUCCAUUAUUACUUUUGGUACGCGCUAGGCCAGACUCAAACUCGUACCGUGAGUAAUAAUGCACUGUGGCAGUGGGUUU		12
16936	MI0001980	dre-mir-128-1	Danio rerio miR-128-1 stem-loop	UGGAGGAGGAGUGCUGGGAGACGGGGCCGUGGCACUGUAUGAGAUUCAUGUAGGCUUUCUCACAGUGAACCGGUCUCUUUUUCCAGCCCUCACUGACA		12
16937	MI0001981	dre-mir-128-2	Danio rerio miR-128-2 stem-loop	UCUGCUCAUGGGUCUGUCAGUAGUAGGACAGGGGGCCGUUUCUACUGUCAGAGAUGCUGCCACUCGUCUCACAGUGAACCGGUCUCUUUUCCUGCUAUUCACUUCUGCAAUAAUAUGAGCAGA		12
16938	MI0001982	dre-mir-129-2	Danio rerio miR-129-2 stem-loop	GUCUUUCACGAAUCUUUUUGCGGUCUGGGCUUGCUGUUCUCAACUAUCAAUGGGAAGCCCUUACCCCAAAAAGCAUUUGCGGAGGGC		12
16939	MI0001983	dre-mir-129-1	Danio rerio miR-129-1 stem-loop	GUCCUUUUCAGGUCUUUUUGCGGUCUGGGCUUGCUGUUCCUUGAACCAGUAGCCAGGAAGCCCUUACCCCAAAAAGUAUCUGCAGAGGAC		12
16940	MI0001984	dre-mir-130a-1	Danio rerio miR-130a-1 stem-loop	UGUCUGUCCAGUGCCCCUUUUAUAUUGUACUACUGAUAACCCAGUUAUUAAAGCAGUGCAAUGUUAAAAGGGCAUUGGCCAGGGA		12
16941	MI0001985	dre-mir-130a-2	Danio rerio miR-130a-2 stem-loop	UGUCUGUCCAGUGCCCCUUUUAUAUUGUACUACUGAUAACCCAGUUAUUAAAGCAGUGCAAUGUUAAAAGGGCAUUGGCCAGGGA		12
16942	MI0001986	dre-mir-130b	Danio rerio miR-130b stem-loop	CUGUUGCCUGACACUCUUUCCCUGUUGCACUACUGUGGGAGCUGCAGCAAAGCAGUGCAAUAAUGAAAGGGCAUCAGUCCACUG		12
16943	MI0001987	dre-mir-130c-1	Danio rerio miR-130c-1 stem-loop	GGGAGAGGUCUGUACGGUGAUAUUGACCAUGUUUUGUCCAUUGCCCUUUUUCUGUUGUACUACUGGCCAAUCAGAAGAGCAGUGCAAUAUUAAAAGGGCAUUGGCUGAUAGAACAGAGUCCUUCACCUCUCACCCUCUCCU		12
16944	MI0001988	dre-mir-130c-2	Danio rerio miR-130c-2 stem-loop	UUGUUGACCAGGGCCCUUUUUCUGUUGUACUACUGUGCAGUCAGAUGAGCAGUGCAAUAUUAAAAGGGCAUUGGCUGACAA		12
16945	MI0001989	dre-mir-132-1	Danio rerio miR-132-1 stem-loop	GUCUCCAUGGCGACCGUGGCAUUAGAUUGUUACUGUAGGAACAGAAUUUUUGGUAACAGUCUACAGCCAUGGUCGCUAGUGGGCA		12
16946	MI0001991	dre-mir-132-2	Danio rerio miR-132-2 stem-loop	UCCCUUCCUCUGCUGUCUCCAUGCUGACCGUGGCUUUAGAUUGUUACUGUAGCGUUGGCACGUGGUAACAGUCUACAGCCAUGGUCGCCAAGGGGCAGGUGUUACAGCGACUACUGGGA		12
16947	MI0001992	dre-mir-133a-2	Danio rerio miR-133a-2 stem-loop	AAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCAACUGUUUUAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGUGCAUU		12
16948	MI0001993	dre-mir-133a-1	Danio rerio miR-133a-1 stem-loop	CAUCAAACCACAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCUUUGAUG		12
16949	MI0001994	dre-mir-133b	Danio rerio miR-133b stem-loop	CACGCCUUGCUGUGGCUGGUCAAAUGGAACCAAGUCAGGUGUUUCUGCGAGGUUUGGUCCCCUUCAACCAGCUACUGCGUCGUG		12
16950	MI0001995	dre-mir-133c	Danio rerio miR-133c stem-loop	GAAACACGGCUUAGUUGCUGGUAAAACGGAACCAAGUCGGGUGUUUGCGAGAGGUUUGGUCCCUUUCAACCAGCUACUGCGCCGUGAAUUC		12
16951	MI0001996	dre-mir-135c-1	Danio rerio miR-135c-1 stem-loop	UGCUGUGUUUUAUGGCUUUCUAUUCCUAUGUGAUUUUCUUCUGCCGUGUCACAUAGGGUUCAAAGCCAUUGGGUACAGAG		12
16952	MI0001997	dre-mir-135c-2	Danio rerio miR-135c-2 stem-loop	UGCUGUGUUUUAUGGCUUUCUAUUCCUAUGUGAUUUUCUUCUGCCGUGUCACAUAGGGUUCAAAGCCAUUGGGUACAGAG		12
16953	MI0001998	dre-mir-135c-3	Danio rerio miR-135c-3 stem-loop	UGCAGUCUAAAGCAACUCAAAACACUACUGUGCUUUAUGGCUUUCUAUUCCUAUGUGAUUUUGAUAUGAUGUAUCAUGUAGGGUUCAAAGCCAUUAGGUACAGAGUGGCUUAUCAGCAGUGGAUGUA		12
16954	MI0002000	dre-mir-137-1	Danio rerio miR-137-1 stem-loop	GGCUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGCUCUCGUUGUUAUUGCUUAAGAAUACGCGUAGUUGAGGAGAGUC		12
16955	MI0002001	dre-mir-137-2	Danio rerio miR-137-2 stem-loop	GUUCUGUUGUUUCCCUCUAUAAAGGACUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGCUCUCGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGGAGAGUCAUGUCGGCGGCGAGAGAGC		12
16956	MI0002002	dre-mir-138	Danio rerio miR-138 stem-loop	UGUGUGCUGCAGCUGGUGUUGUGAAUCAGGCCGAUGUCACACGUCAGCGAUAACCCGGCUAUUUCACAACACCAGGGUGGCACCACA		12
16957	MI0002003	dre-mir-140	Danio rerio miR-140 stem-loop	GUGUUUGUCUCCUGUGUCCCGUCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACGGGAUGUCUGGAGGUGUCUGC		12
16958	MI0002004	dre-mir-141	Danio rerio miR-141 stem-loop	GUCUCUAGGGUACAUCUUACCUGACAGUGCUUGGCUGUUCACUGAUGUUCUAACACUGUCUGGUAACGAUGCACUCUGGUGAC		12
16959	MI0002005	dre-mir-142a	Danio rerio miR-142a stem-loop	CGUACAGUGCAGUCAUCCAUAAAGUAGAAAGCACUACUAAACCCCUCGCCACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUUG		12
16960	MI0002006	dre-mir-142b	Danio rerio miR-142b stem-loop	ACAGUGCAGUCACUCAUAAAGUAGACAGCACUACUAAACUUCUCUACACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGU		12
16961	MI0002007	dre-mir-143-1	Danio rerio miR-143-1 stem-loop	GAUCUACAGUCGUCUGGCCCGCGGUGCAGUGCUGCAUCUCUGGUCAACUGGGAGUCUGAGAUGAAGCACUGUAGCUCGGGAGGACAACACUGUCAGCUC	The cloned mature miR-143 sequence always appears to be 22nt in length, modified by the addition of a 3' U residue not found in the genomic sequence [1]. 	12
16962	MI0002008	dre-mir-143-2	Danio rerio miR-143-2 stem-loop	GAUCUACAGUCGUCUGGCCCGCGGUGCAGUGCUGCAUCUCUGGUCAACUGGGAGUCUGAGAUGAAGCACUGUAGCUCGGGAGGACAACACUGUCAGCUC	The cloned mature miR-143 sequence always appears to be 22nt in length, modified by the addition of a 3' U residue not found in the genomic sequence [1]. 	12
16963	MI0002009	dre-mir-144	Danio rerio miR-144 stem-loop	GCUCUCUAGACAGGAUAUCAUCGUAUACUGUAAGUUCAUUAUUGAGACACUACAGUAUAGAUGAUGUACUAUCCAGGGGGUCAACGAGC		12
16964	MI0002010	dre-mir-145	Danio rerio miR-145 stem-loop	UCAGUCUUCAUCAUUUCCUCAUCCCCGGGGUCCAGUUUUCCCAGGAAUCCCUUGGGCAAUCGAAAGGGGGAUUCCUGGAAAUACUGUUCUUGGGGUUGGGGGUGGACUACUGA		12
16965	MI0002012	dre-mir-146a	Danio rerio miR-146a stem-loop	GAGUUUGUUUUGAGCACUUUUCCCUGAGAACUGAAUUCCAUAGAUGGUGUUCAUGAAAAGUUCAUCUAUGGGCUCAGUUCUUCUGGCAAUCUGUUUAAUGUCUGCUACAAAUUC		12
16966	MI0002013	dre-mir-146b-1	Danio rerio miR-146b-1 stem-loop	GCUCUUGGCUUUGAGAACUGAAUUCCAAGGGUGUCUGCUUUAUAUUCAGCCCACGGAGUUCAGUUCUUAAGUUUGGAUGC		12
16967	MI0002014	dre-mir-146b-2	Danio rerio miR-146b-2 stem-loop	GCUCUUGGCUUUGAGAACUGAAUUCCAAGGGUGUCUGCUUUAUAUUCAGCCCACGGAGUUCAGUUCUUAAGUUUGGAUGC		12
16968	MI0002015	dre-mir-148	Danio rerio miR-148 stem-loop	CUUUCCAAGUAAAGUUCUGUGAUACACUCCGACUCUGAAUGUUUGCAGUCAGUGCAUUACAGAACUUUGUUUUGGGAGU		12
16969	MI0002016	dre-mir-150	Danio rerio miR-150 stem-loop	CAUCUCCGUCUCUCCCAAUCCUUGUACCAGUGUCUGAUUUACAGAUGACGCUGGACGGGGUUUGGGGGGGGCUGAGGGA		12
16970	MI0002017	dre-mir-152	Danio rerio miR-152 stem-loop	CUGUUCACCUGGCUCAAGUUCUGUGAUACACUCAGACUUUGAAUCAGUGGUAGUCAGUGCAUGACAGAACUUUGGCCCGG		12
16971	MI0002019	dre-mir-153b	Danio rerio miR-153b stem-loop	GAGCGAUGGAGCGCGGUAGCGAGGUAUUGCACAGCUGUCUGUGUCAUUUUUGUGGUUUGCAGCUAGUAGUCUGGUUCCAGUUGCAUAGUCACAAAAAUGAGCACAGACAGAUGUGACUGCAGCAACGCUGAUGAAACGCUCCAUCGCC		12
16972	MI0002021	dre-mir-153a	Danio rerio miR-153a stem-loop	GGUUGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUUAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACU		12
16973	MI0002022	dre-mir-153c	Danio rerio miR-153c stem-loop	GAUGGAGAUCAGUAGGUCCCUGGACGUAGCACACCUCCCAGUGUCAUUUUUGUGAUUUGCAGCUAGUAGUCUGGGUCCAGUUGCAUAGUCACAAAAAUGAUCAUUGGUAGGUGUGAGUGCAGCAGGAGUGAGGCUUACCGGAUCCUCCAUC		12
16974	MI0002023	dre-mir-155	Danio rerio miR-155 stem-loop	UGGUGCAGGUUUAAUGCUAAUCGUGAUAGGGGUUUAGUGCUGAUGAACACCUAUGCUGUUAGCAUUAAUCUUGCGCUA		12
16975	MI0002024	dre-mir-181c	Danio rerio miR-181c stem-loop	GGGUCCUGAUUCACAUUCAUUGCUGUCGGUGGGUUUUAUCUCUUCGACUCGCCGGACAAUGAAUGAGAACUACGGCUC		12
16976	MI0002026	dre-mir-184	Danio rerio miR-184 stem-loop	GUCGAACACGUCUCCUUAUCACUUUUCCAGCCCAGCUAUCCAUUUAGUAUUCGUUGGACGGAGAACUGAUAAGGGCAUGUGCCCGAU		12
16977	MI0002027	dre-mir-190	Danio rerio miR-190 stem-loop	UCUGGAGGUGAGGUAGACCUGGAAGCCUUUCUGCAGGCCUCUGUUUGAUAUGUUUGAUAUAUUAGGUUGUUAUUCUGUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCCUGCUCUGUCUCCAG		12
16978	MI0002028	dre-mir-462	Danio rerio miR-462 stem-loop	GUCUGGAUGGUAACGGAACCCAUAAUGCAGCUGUUUGGUUGAUUGAUUGACAGCUGUCUGUGGAUUCCGUGCCCCUCCUUUCUUGCAGGAGCUCAUUGAGAU		12
16979	MI0002029	dre-mir-193a-1	Danio rerio miR-193a-1 stem-loop	GACAUUAAUGUGUUAGAGGUUGGGUCUUUGCGGGCAAGGUGAGUAGUUAAAUUUACUCUCAACUGGCCUACAAAGUCCCAGUUUCUGGCUCAUGUUAUC		12
16980	MI0002030	dre-mir-193a-2	Danio rerio miR-193a-2 stem-loop	GAAAGUGUGUCAGAGGCUGGGUCUUUGCGGGCAAGGUGAGUUUUCCUUUUAUUCAACUGGCCUACAAAGUCCCAGUUUUCGGCCCAUGUGACCAUCUC		12
16981	MI0002031	dre-mir-193a-3	Danio rerio miR-193a-3 stem-loop	GAAAGUGUGUCAGAGGCUGGGUCUUUGCGGGCAAGGUGAGUUUUCCUUUUAUUCAACUGGCCUACAAAGUCCCAGUUUUCGGCCCAUGUGACCAUCUC		12
16982	MI0002032	dre-mir-193b	Danio rerio miR-193b stem-loop	GUGAUUUCAGUGACGGGACUUUGGGGGCGAGAUGAGUAUUGAUCUCUAUCCAACUGGCCCGCAAAGUCCCGCUUCUGGGACUCAC		12
16983	MI0002033	dre-mir-194a	Danio rerio miR-194a stem-loop	UGGUGCUGACUGCUUGUAACAGCAACUCCAUGUGGAAGGUUUGUGUCUUCCAGUGGAGCUGCUGUUGCGUGCAGAUAGUCACCA		12
16984	MI0002034	dre-mir-194b	Danio rerio miR-194b stem-loop	GCUCGCUGGGUGUAACAGCCGCUCCAUGUGGAAAAUGCAUUCAAGUGCCCAUGGAGAAGCUGUUACCUGCAGAGAGU		12
16985	MI0002035	dre-mir-196a-2	Danio rerio miR-196a-2 stem-loop	UCGAGUGGUUUAGGUAGUUUCAUGUUGUUGGGAUUACAUUCAAACUCUGCAACGUGAAACUGUCUUAAUUGCCCCA		12
16986	MI0002036	dre-mir-196b	Danio rerio miR-196b stem-loop	GUCUGUGAUUUAGGUAGUUUCAAGUUGUUGGGCUGGACGUUUAAUUUCACAGGAACCUGAAACUGCCUGAAUUGCUCCA		12
16987	MI0002037	dre-mir-200a	Danio rerio miR-200a stem-loop	GGCACUUAGCAGCCAUCUUACCGGACAGUGCUGGACUGUAUAACUGUUUUCUAACACUGUCUGGUAACGAUGUUUGUUGGGUGACC		12
16988	MI0002038	dre-mir-200b	Danio rerio miR-200b stem-loop	GGUAGUCGUCUCCAUCUUACGAGGCAGCAUUGGAUUUCAUUACUUUUUCUAAUACUGCCUGGUAAUGAUGAUGAUUGCUGCC		12
16989	MI0002039	dre-mir-200c	Danio rerio miR-200c stem-loop	UGGAUGCCUGGCUCCAUCUUACAAGGCAGUUUUGGAUGUUAUAUCUUCUCUAAUACUGCCUGGUAAUGAUGCAGAUGGUCAUCUA		12
16990	MI0002040	dre-mir-202	Danio rerio miR-202 stem-loop	CUGUUCCUUUUUCCUAUGCAUAUACCUCUUUGACAUGCUGCUUUAAAGAGGCAUAGGGCAUGGGAAAAUGGGGCGG		12
16991	MI0002041	dre-mir-203b	Danio rerio miR-203b stem-loop	UCCUCUUUGGCCGAGUGGUUCUCAACAGUUCAACAGUUCUUUUGAUGAUUGUGAAAUGUUCAGGACCACUUGAUCAGACGAAGGA		12
16992	MI0002042	dre-mir-204-2	Danio rerio miR-204-2 stem-loop	GUGUUGCUCUAGUGACCAGUUUGUGACCUCCUGGGUUUCCCUUUGUCAUCCUAUGCCUGCAGUUCCUGAUGAGGCUGGGACAGCAAAGGGAGGUUCAGAUGUCGACCUGUACUACAGUCAAUAC		12
16993	MI0002043	dre-mir-204-3	Danio rerio miR-204-3 stem-loop	GUGUUGCUCUAGUGACCAGUUUGUGACCUCCUGGGUUUCCCUUUGUCAUCCUAUGCCUGCAGUUCCUGAUGAGGCUGGGACAGCAAAGGGAGGUUCAGAUGUCGACCUGUACUACAGUCAAUAC		12
16994	MI0002045	dre-mir-206-1	Danio rerio miR-206-1 stem-loop	GAAUGUUGCCUCUUGUGAAGACAUGCUUCCUUAUAUGCCCAUAUUAAUGCUCAAGUUAUGGAAUGUAAGGAAGUGUGUGGUUUCAGGGGGAAAUUUGUC		12
16995	MI0002046	dre-mir-206-2	Danio rerio miR-206-2 stem-loop	GAGUUGGCUGUUGCUUAUUGAGACGACAUACUUCCUUAUAUCCCCAUAUUCAGAAUUAAUCUAUGGAAUGUAAGGAAGUGUGUGGCUUCAGUGAGAUCUCAUCAUCAUC		12
16996	MI0002047	dre-mir-216a-2	Danio rerio miR-216a-2 stem-loop	GCUGAUUUUUGGCAUAAUCUCAGCUGGCAACUGUGAGUAGUGUUUUCAUCCCUCUCACAGGCGCUGCUGGGGUUCUGUCACACACAGCA		12
16997	MI0002048	dre-mir-216b-1	Danio rerio miR-216b-1 stem-loop	ACUGACUGGGUAAUCUCUGCAGGCAACUGUGAUGUGAUUACAGUCUCACAUUGACCUGAAGAGGUUGAGCAGUCUGU		12
16998	MI0002049	dre-mir-216b-2	Danio rerio miR-216b-2 stem-loop	CUGACUGGGUAAUCUCUGCAGGCAACUGUGAUGUGAUUACAGUCUCACAUUGACCUGAAGAGGUUGUGCAGUCUGU		12
16999	MI0002050	dre-mir-217-2	Danio rerio miR-217-2 stem-loop	AUGAGAACUUUCUGAUGUUGGUGAUACUGCAUCAGGAACUGAUUGGAUGAUAUUCAGGAGCCAUCAGUUCCUGAUGCACUCCCAUCAGCAUCGAAAGA		12
17000	MI0002051	dre-mir-218a-1	Danio rerio miR-218a-1 stem-loop	CAGCUGUCUCUUGUGCUUGAUCUAACCAUGUGCCGCCGCCUACACAAGCCUCACAUGGUUCCGUCAAGCACCAGGGACCGCUG		12
17001	MI0002052	dre-mir-218a-2	Danio rerio miR-218a-2 stem-loop	GCGGGGUUUUCCUUUGUGCUUGAUCUAACCAUGUGGUUGCAGACUCAGACUAAUACAUGGUUCUGUCAAGCACCAUGGAAGGUCUUGC		12
17002	MI0002053	dre-mir-218b	Danio rerio miR-218b stem-loop	CAGGACACCAUUGUGCUUGAUCUAACCAUGCAGUUCCCUUUCUGUCCAUGGUUGUGCCAAGCACUUUGGAGACUUG		12
17003	MI0002054	dre-mir-219-3	Danio rerio miR-219-3 stem-loop	CUUCUCUUUUAAGUUCAUCUGUCUGGUUUGAUACUGACGGUCAGGUGCUGAUUGUCCAAACGCAAUUCUUGUGCUUGUGUGAAACAGGAGUUGUGGAUGGACAUCACGCUCCUGUCUGGUCCUCACAUCUACAGGAUGGGCCAAGUAAAG		12
17004	MI0002059	dre-mir-301a-1	Danio rerio miR-301a-1 stem-loop	GCUGUUAACAGGUGCUCUGACUUCAUUGCACUACUGUAUUGGACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCGUCUGAGAGCAGC		12
17005	MI0002060	dre-mir-301a-2	Danio rerio miR-301a-2 stem-loop	GCUGUUAACAGGUGCUCUGACUUCAUUGCACUACUGUAUUGGACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCGUCUGAGAGCAGC		12
17006	MI0002061	dre-mir-301b	Danio rerio miR-301b stem-loop	AAGGUCUGUUGCUUUGACGAUGUUGCACUACUGAACCAUCUAAUCAAGCAGUGCAAUAGUAUUGUCAUUGCAUUCGGCUUU		12
17007	MI0002062	dre-mir-301c	Danio rerio miR-301c stem-loop	UGAGGUCAGCUGCUCUGACGAUGUUGCACUACUGUACCAUCCAUUCUAGCAGUGCAAUAGUAUUGUCAUAGCAUUUAGCCUCU		12
17008	MI0002063	dre-mir-338-1	Danio rerio miR-338-1 stem-loop	GGUUUCUCCCUGCAACAAUCUCCUGAUGCUGCCUGAGUGUUUUUCUUCCACUCCAGCAUCAGUGAUUUUGUUGCCGGAGGUCACC		12
17009	MI0002064	dre-mir-338-2	Danio rerio miR-338-2 stem-loop	GGUUUCUCCCUGCAACAAUCUCCUGAUGCUGCCUGAGUGUUUUUCUUCCACUCCAGCAUCAGUGAUUUUGUUGCCGGAGGUCACC		12
17010	MI0002065	dre-mir-338-3	Danio rerio miR-338-3 stem-loop	GUGUGUGUGUGUGUUUCUGGUGCCUGCUGAGAACAAUAUCCUGAUGCUGAAUGAGUGUGUUGAAGGAAACUCCAGCAUCAGUGAUUUUGUUGCCAGAGGAGCACUUUGGGCAUCCUGUGUAUAU		12
17011	MI0002066	dre-mir-338-4	Danio rerio miR-338-4 stem-loop	GUGUGUGUGUGUGUUUCUGGUGCCUGCUGAGAACAAUAUCCUGAUGCUGAAUGAGUGUGUUGAAGGAAACUCCAGCAUCAGUGAUUUUGUUGCCAGAGGAGCACUUUGGGCAUCCUGUGUAUAU		12
17012	MI0002067	dre-mir-363	Danio rerio miR-363 stem-loop	UAAAUGCAAAUAUUUGUCUUGCUGUUUUCGGGUGGAUGACUCUGCAAUUUUAUUAGUGAUGGAAAAACUUCAAUAAAAAUUGCACGGUAUCCAUCUGUAAUCCGCUGGAUUCCAUUACCUGCGUUUG		12
17013	MI0002068	dre-mir-365-1	Danio rerio miR-365-1 stem-loop	CCGCAGGGAGAAUGAGGGGCUUUUGGGGGCACUUGUGUUUCAGUUUCACCAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCACUG		12
17014	MI0002069	dre-mir-365-2	Danio rerio miR-365-2 stem-loop	AGGCAGCAAGAAAAAUGAGGGACUUUUAGGGGCAGCUGUGUUUUAUUAACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAAUUUUCAGC		12
17015	MI0002070	dre-mir-365-3	Danio rerio miR-365-3 stem-loop	AAGUCAGCAAGAAAAGUGAGGGACUUUUAGGGGCAGCUGUGUUAUACUGACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAGUGCUCAAC		12
17016	MI0002071	dre-mir-365-4	Danio rerio miR-365-4 stem-loop	AAGUCAGCAAGAAAAGUGAGGGACUUUUAGGGGCAGCUGUGUUAUACUGACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAGUGCUCAAC		12
17017	MI0002072	dre-mir-375-1	Danio rerio miR-375-1 stem-loop	UGCACUUGCUUUACGUUGAGCCACACGCACAAUACAUGUGGAUUCAGUUUUGUUCGUUCGGCUCGCGUUAAGCAAGUGCA		12
17018	MI0002073	dre-mir-375-2	Danio rerio miR-375-2 stem-loop	UGUACUUGUCUCACGUUGAGCCACACGCACAAUGCCUGCAGAUGAAAGGGUUUUGUUCGUUCGGCUCGCGUUACGCAGAUGCA		12
17019	MI0002074	dre-mir-454a	Danio rerio miR-454a stem-loop	UUGCAGGUCGUUUAAGAAUUAAUCCUAAUUCUUGGGACCCUAUCAGUAUUGCCUCUGCUGUCCACUGUGUUCAGAGUAGUGCAAUAUUGCUAAUAGGGUUUUAGGUUUUAGGUUGUACCUUCAG		12
17020	MI0002076	dre-mir-454b	Danio rerio miR-454b stem-loop	GAUAAAUGCAUCUUGCAGGCGAGACCCUAUCAAUAUUGCCUCUGCUUUUCUCACUGUUUAUGGAGUAGUGCAAUAUUGCUUAUAGGGUCUUGACUUUAAGGCUAAUCUGCAAUAUC		12
17021	MI0002077	dre-mir-455	Danio rerio miR-455 stem-loop	UCCCUGGUGUGAGGGUAUGUGCCCUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGCCUAGAUCUUC	The mir-455 precursor was predicted computationally and a mature product verified in human by Northern blot [2].  The precise sequence termini of the mature form were derived by cloning from human and rat samples (Landgraf and Tuschl, unpublished). 	12
17022	MI0002079	dre-mir-430c-2	Danio rerio miR-430c-2 stem-loop	CACAUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAG		12
17023	MI0002080	dre-mir-430c-3	Danio rerio miR-430c-3 stem-loop	CACAUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAG		12
17024	MI0002081	dre-mir-430c-4	Danio rerio miR-430c-4 stem-loop	CACAUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAG		12
17025	MI0002082	dre-mir-430c-5	Danio rerio miR-430c-5 stem-loop	CACAUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAG		12
17026	MI0002083	dre-mir-430c-6	Danio rerio miR-430c-6 stem-loop	AUUAAGAUCACUACAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17027	MI0002087	dre-mir-430c-7	Danio rerio miR-430c-7 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAU		12
17028	MI0002088	dre-mir-430c-8	Danio rerio miR-430c-8 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17029	MI0002089	dre-mir-430c-9	Danio rerio miR-430c-9 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17030	MI0002090	dre-mir-430c-10	Danio rerio miR-430c-10 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17031	MI0002091	dre-mir-430c-11	Danio rerio miR-430c-11 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17032	MI0002092	dre-mir-430c-12	Danio rerio miR-430c-12 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17033	MI0002093	dre-mir-430c-13	Danio rerio miR-430c-13 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17034	MI0002094	dre-mir-430c-14	Danio rerio miR-430c-14 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17035	MI0002095	dre-mir-430c-15	Danio rerio miR-430c-15 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17036	MI0002096	dre-mir-430c-16	Danio rerio miR-430c-16 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17037	MI0002097	dre-mir-430c-17	Danio rerio miR-430c-17 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17038	MI0002098	dre-mir-430c-18	Danio rerio miR-430c-18 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17039	MI0002099	dre-mir-430c-19	Danio rerio miR-430c-19 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17040	MI0002100	dre-mir-430c-20	Danio rerio miR-430c-20 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17041	MI0002101	dre-mir-430c-21	Danio rerio miR-430c-21 stem-loop	AUUAAGAUCACUUCAAACAGGAGCAUUGAUUUGUCCUUUGUUCAUAAGUGCUUCUCUUUGGGGUAGUUUUAAUAAGGACAAG		12
17042	MI0002111	dre-mir-430a-2	Danio rerio miR-430a-2 stem-loop	GUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17043	MI0002112	dre-mir-430a-3	Danio rerio miR-430a-3 stem-loop	GUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17044	MI0002113	dre-mir-430a-4	Danio rerio miR-430a-4 stem-loop	CUAUCGGUACCCUCACAAAAACACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGA		12
17045	MI0002114	dre-mir-430a-5	Danio rerio miR-430a-5 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17046	MI0002115	dre-mir-430a-6	Danio rerio miR-430a-6 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17047	MI0002116	dre-mir-430a-7	Danio rerio miR-430a-7 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17048	MI0002117	dre-mir-430a-8	Danio rerio miR-430a-8 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17049	MI0002118	dre-mir-430a-9	Danio rerio miR-430a-9 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17050	MI0002119	dre-mir-430a-10	Danio rerio miR-430a-10 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17051	MI0002120	dre-mir-430a-11	Danio rerio miR-430a-11 stem-loop	GGACAAGGUUUUAAUCUGCUACUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17052	MI0002121	dre-mir-430a-12	Danio rerio miR-430a-12 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17053	MI0002122	dre-mir-430a-13	Danio rerio miR-430a-13 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17054	MI0002123	dre-mir-430a-14	Danio rerio miR-430a-14 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17055	MI0002124	dre-mir-430a-15	Danio rerio miR-430a-15 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17056	MI0002125	dre-mir-430a-16	Danio rerio miR-430a-16 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17057	MI0002126	dre-mir-430a-17	Danio rerio miR-430a-17 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGAC		12
17058	MI0002131	dre-mir-430a-18	Danio rerio miR-430a-18 stem-loop	CACCAUUGUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUUAAGUGACAUGUG		12
17059	MI0002132	dre-mir-430a-19	Danio rerio miR-430a-19 stem-loop	CACCAUUGUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGGGUAGUUUUAAGUGACAUGUG		12
17060	MI0002133	dre-mir-430a-20	Danio rerio miR-430a-20 stem-loop	GGACAAGGUUUUAAUCUGCUGCUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17061	MI0002134	dre-mir-430a-21	Danio rerio miR-430a-21 stem-loop	GGACAAGGUUUUAAUCUGCUGCUAUUGUCACUAUCGGUACCCUCACAAAGGCACUGACUUGGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUCU		12
17062	MI0002135	dre-mir-430a-22	Danio rerio miR-430a-22 stem-loop	GACAAGAUUUUAGUCUGCCACCAUUGUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAAUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGACCUGUGCUACAAGAGAAUGUUGUC		12
17063	MI0002138	dre-mir-430a-23	Danio rerio miR-430a-23 stem-loop	UUUAAAUAAACUAUUACCGUCAGGCUUUCACAAGCCAGCCUCAAAGUUUGUUCUCAAACUUUAAGAAUCUAGUUGGUAAGUGCUAUUUGUUGGGGUAGUUUCAAGUGA		12
17064	MI0002139	dre-mir-430i-1	Danio rerio miR-430i-1 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGCGUAGUUUCAAGUGAC		12
17065	MI0002140	dre-mir-430i-2	Danio rerio miR-430i-2 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGCGUAGUUUCAAGUGAC		12
17066	MI0002141	dre-mir-430i-3	Danio rerio miR-430i-3 stem-loop	GUCUCUAUCGGUACCCUCACAAAAGCACUGACUUUGAUGCUGUAUUUGGUAAGUGCUAUUUGUUGGCGUAGUUUCAAGUGAC		12
17067	MI0002142	dre-mir-430b-2	Danio rerio miR-430b-2 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17068	MI0002143	dre-mir-430b-3	Danio rerio miR-430b-3 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17069	MI0002144	dre-mir-430b-4	Danio rerio miR-430b-4 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17070	MI0002146	dre-mir-430b-6	Danio rerio miR-430b-6 stem-loop	CAGUUGACGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAGAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17071	MI0002147	dre-mir-430b-7	Danio rerio miR-430b-7 stem-loop	CAGUUGACGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAGAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17072	MI0002148	dre-mir-430b-8	Danio rerio miR-430b-8 stem-loop	CAGUUGACGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAGAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17073	MI0002149	dre-mir-430b-9	Danio rerio miR-430b-9 stem-loop	CAGUUGACGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAGAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17074	MI0002150	dre-mir-430b-10	Danio rerio miR-430b-10 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17075	MI0002151	dre-mir-430b-11	Danio rerio miR-430b-11 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17076	MI0002152	dre-mir-430b-12	Danio rerio miR-430b-12 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17077	MI0002153	dre-mir-430b-13	Danio rerio miR-430b-13 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17078	MI0002154	dre-mir-430b-14	Danio rerio miR-430b-14 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17079	MI0002155	dre-mir-430b-15	Danio rerio miR-430b-15 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17080	MI0002156	dre-mir-430b-16	Danio rerio miR-430b-16 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17081	MI0002157	dre-mir-430b-17	Danio rerio miR-430b-17 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17082	MI0002158	dre-mir-430b-18	Danio rerio miR-430b-18 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17083	MI0002166	dre-mir-430b-5	Danio rerio miR-430b-5 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAAAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17084	MI0002170	dre-mir-430b-19	Danio rerio miR-430b-19 stem-loop	CAGUUGACAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAGAGCAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGCUG		12
17085	MI0002171	dre-mir-430b-20	Danio rerio miR-430b-20 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAUAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUACUG		12
17086	MI0002172	dre-mir-430b-21	Danio rerio miR-430b-21 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAUAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUACUG		12
17087	MI0002173	dre-mir-430b-22	Danio rerio miR-430b-22 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGUUG		12
17088	MI0002174	dre-mir-430b-23	Danio rerio miR-430b-23 stem-loop	CAGUUGAGGUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAGUUGGGGUAGAUGUUUGUUG		12
17089	MI0002175	dre-mir-430j	Danio rerio miR-430j stem-loop	CAGUUGAGAUCAACUCUAACUUUAGCAUCUUUCUUUUAAGCAAAGUAGAAAGUGCUAUCAAAUUGGGGUAGAUGUUUGCUG		12
17090	MI0002176	dre-mir-456	Danio rerio miR-456 stem-loop	GCUGGUUGUGUGUGCAGGCAUCUUUCCAGUCUACAUGUGGAUCCAGGAGUCUGCAGGCUGGUUAGAUGGUUGUCACGUACCCAGC		12
17091	MI0002177	dre-mir-457a	Danio rerio miR-457a stem-loop	UGCCUGACAGAAGCAGCACAUCAAUAUUGGCAGCUGCCCUCUCUCUGGGUUGCCAGUAUGGUUUGUGCUGCUCCCGUCAGACA		12
17092	MI0002178	dre-mir-457b	Danio rerio miR-457b stem-loop	GAAUGUACUAAAGCAGCACAUAAAUACUGGAGGUGAUUGUGGUGUUAUCCAGUAUUGCUGUUCUGCUGUAGUAAGACC		12
17093	MI0002179	dre-mir-458	Danio rerio miR-458 stem-loop	GUGCAGAUAGCAGCGCCAUUUACAGAGCUAUAAGCAUCAUAGUUGUCAUAGCUCUUUGAAUGGUACUGCCAUAUGCAC		12
17094	MI0002180	dre-mir-459	Danio rerio miR-459 stem-loop	CCUCUUGCUCUCAGUAACAAGGAUUCAUCCUGUUGUGGUACUCAAAUCCAACAGGGAAUCUCUGUUACUGGGGUUAAGGUU		12
17095	MI0002181	dre-mir-460	Danio rerio miR-460 stem-loop	CUCCUCGGCUCCUGCAUUGUACACACUGUGCGGAAAACAUGGACAUGCACAGCGCAUACAAUGUGGAUGCUGUGGAG		12
17096	MI0002183	dre-mir-461	Danio rerio miR-461 stem-loop	AUUUUGAAAAUCAGGAAUGGGCUAAAUGCCAAUCAAAAUAAAGCAAGUCUUUGGUCCAGACCAGGUAAUACAAAAUAAG		12
17097	MI0002184	ptc-MIR156a	Populus trichocarpa miR156a stem-loop	AAAGAAAGACUGACAGAAGAGAGUGAGCACACACGAAAGUAUAUGGUAUGAAGGCAUUCCAUUGCAGGGUGUGUGCUCACAUCUCUUCUGUCAGCUUCCAC		26
17098	MI0002185	ptc-MIR156b	Populus trichocarpa miR156b stem-loop	GUAAGGGAGGUGACAGAAGAGAGUGAGCACACAGGGUACUUUCUUGCAUGACAUCCAUGCUUGAAACUUUGCGUGCUCACUCUCUAUCUGUCACCCCACCA		26
17099	MI0002186	ptc-MIR156c	Populus trichocarpa miR156c stem-loop	CAUUAGAAACUGACAGAAGAGAGUGAGCACACAGAGGCAUAUUUGUAUAAAUCUAUACCAUUGCUUUUGCGUGCUCACUUCUCAUUCUGUCAGCUUCCAG		26
17100	MI0002187	ptc-MIR156d	Populus trichocarpa miR156d stem-loop	GUAAGUGAGUUGACAGAAGAGAGUGAGCACACAGGGUACUUUCUUGCAUGACGUUCAUGCUUGAAGCUUUGCGUGCCCACCCUCUAUCUGUCACCCCAUCA		26
17101	MI0002188	ptc-MIR156e	Populus trichocarpa miR156e stem-loop	CAUUAGAAAUUGACAGAAGAGAGUGAGCACACAGAGGCAUAUUUGUAUAAAAUUAUACCAUUGCUUUUGCGUGCUCAUUUCUCUUUCUGUCACUUCCAGA		26
17102	MI0002189	ptc-MIR156f	Populus trichocarpa miR156f stem-loop	AGAGAAAGACUGACAGAAGAGAGUGAGCACACACGAAAGCUAAUUGUAUGAAAGCAUACCAUUGCAGGGUGUGUGCUCACUUCUCUUCUGUCAGCUUACAU		26
17103	MI0002190	ptc-MIR156g	Populus trichocarpa miR156g stem-loop	GGUGAUGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAAAUGCAUGGAGCUUAAUUGCAUCUCACUCCUUUGUGCUCUCUAGUCUUCUGUCAUCACCUUCA		26
17104	MI0002191	ptc-MIR156h	Populus trichocarpa miR156h stem-loop	GGUGAUGCUGUUGACAGAAGAUAGAGAGCACUGACGAUGAAAUGCAUGGAGCUUAAUUGCAUCUCACUCCUUUGUGCUCUCUAGUCUUCUGUCAUCACCUUCA		26
17105	MI0002192	ptc-MIR156i	Populus trichocarpa miR156i stem-loop	UGUGAUGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGUUUUGCAGUAGACUCUGGAUCUCACUCCUUUGUGCUCUCUAUGCUUCUGCCAUCACCUUC		26
17106	MI0002193	ptc-MIR156j	Populus trichocarpa miR156j stem-loop	GGUGAUGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAUAUGCAAUGGACUCUGCAUCCCACUCCUUUGUGCUCUCUAUGCUUCUGUCAUCACUUUCA		26
17107	MI0002194	ptc-MIR156k	Populus trichocarpa miR156k stem-loop	UUAUGCAUGCUGACAGAAGAGAGGGAGCACAACCCUGUAAUAGCUAAAGAGAGUCUUUGCUUUUGUUGGACUGUGCUUUCUCUUCUUCUGUCACCAACCAA		26
17108	MI0002195	ptc-MIR159a	Populus trichocarpa miR159a stem-loop	GAUUAGGGAGUGGAGCUCCUUGAAGUCCAAUAGAGGUUCUUGCUGGGUAGAUUAAGCUGCUAAGCUAUGGAUCCACAGUCCUAUCUAUCAACUGAAGGAUAGGUUUGCGGCUUGCAUAUCUCAGGAGCUUUAUUGCCUAAUGUUAGAUCCCUUUUUGGAUUGAAGGGAGCUCUAAACCCAUAA		26
17109	MI0002196	ptc-MIR159b	Populus trichocarpa miR159b stem-loop	GAUUAUGGAGUGGAGCUCCUUGAAGUCCAAUAGAAGCUCCUGCUGGGUAGAUCGAGCUGCUGAGCUAUGAAUCCCACAGCCCUAUCACCAUCAGUCAUUUUGAUGGGCCUGCGGCUUGCAUAUCUCAGGAGCUUUAUUACCUAAUGUUAGAUCUUUUUUUGGAUUGAAGGGAGCUCUAAACCUUUGA		26
17110	MI0002197	ptc-MIR159c	Populus trichocarpa miR159c stem-loop	GAUUAGGGAGUGGAGCUCCUUGAAGUCCAAUAGAGGUUCUUGCUGGGUAGAUUAAGCUGCUAAGCUAUGGAUCCACAGUCCUAUCUAUCAACCGAAGGAUAGGUUUGCGGCUUGCAUAUCUCAGGAGCUUUAUUGCCUAAUGUUAGAUCCCUUUUUGGAUUGAAGGGAGCUCUAAACCCAUAA		26
17111	MI0002198	ptc-MIR159d	Populus trichocarpa miR159d stem-loop	UUGUAAAUUUGGGAGCUUUCUUUGGUUCAAAAUGAGGAAAGAAAGUGGGUAUACUCGUCUGCUUGUUCAUGGAUACCUCUGGGUUGCGCAGGAUAUAUUAGUUAGGGCUACAGCUUAAGGGUUUGCAUGGCCAAGGAGACGUUGCCUGCCUUCUCCUUUCGUUUCUUGGAUUGAAGGGAGCUCCUACAUGUAUC		26
17112	MI0002199	ptc-MIR159e	Populus trichocarpa miR159e stem-loop	ACCAUUAAAUAGGAGCUUGCUCACUCCAGAUCUGAAAGGAGGUGAUAGGAAACCACUUCUGCUACUUCAUGAAUACCCGUGGGUGUGCGCGUAGCCAUGGUGAGCUGCGCAGGCUAAGGGUCUGCAUGUGCUAGGAGAUGUGGUUGCCUUGAUCUUUUUGGUCUUGGGGUGAAGGGAGCUCCUAUAGUCCCA		26
17113	MI0002200	ptc-MIR159f	Populus trichocarpa miR159f stem-loop	GAGGCUCAAUGGAGCUCUCCCCACUCCAUGCCUGAAAGGAGUUCGAUGGUAGACCAUGGCUGCUAGUUCAUGAAUACCCUUGGGUGCGCAGAAUUAGCAACGGUGCAGGCGAAGUUGCGCAGGCUAAGGGUCUGCAUGACCUAGGAGACGUGGUUACCCUGACCCUUUUUGUAUUGGAGUGAAGGGAGCUCGAUGGUCUUU		26
17114	MI0002201	ptc-MIR160a	Populus trichocarpa miR160a stem-loop	ACAUGGGUUAUGCCUGGCUCCCUGUAUGCCACAAGCAAAGACCAAUCUUUUGUUUUAGAUUGGCUGUUGCCGGUGGCGUGCGAGGAGCCAAGCAUACUCUCU		26
17115	MI0002202	ptc-MIR160b	Populus trichocarpa miR160b stem-loop	AUAUUAUAUGUGCCUGGCUCCCUGUAUGCCAUUUGCAGAGCCCAACGGAUCCUCGAUGGCCUCCGUGGAUGGCGUAUGAGGAGCCAUGCAUAUUCGCA		26
17116	MI0002203	ptc-MIR160c	Populus trichocarpa miR160c stem-loop	AUAUUAUAUGUGCCUGGCUCCCUGUAUGCCAUUUGCAGAGCCCACCGGUUCUUCGAUGGCCUCCGUGGAUGGCGUAUGAGGAGCCAUGCAUAUUCACA		26
17117	MI0002204	ptc-MIR160d	Populus trichocarpa miR160d stem-loop	AAAUGGGUUAUGCCUGGCUCCCUGUAUGCCACAGCAAAGACCAAUCUCUUCUGUCUUAGAUUGGCUGCUGCCGGUGGCGUGCGAGGAGCCAAGCAUACUCUCU		26
17118	MI0002205	ptc-MIR160e	Populus trichocarpa miR160e stem-loop	AAGAAUGGCCUGCCUGGCUCCCUGAAUGCCAUCUAGGAAGCUUGUCAAAGAGUGUUGGCAACCUUUCUAUUUGGCAUGAGGGGAGUCGAGCAGGCCAAUU		26
17119	MI0002206	ptc-MIR160f	Populus trichocarpa miR160f stem-loop	AAGAAUGGUCUGCCUGGCUCCCUGAAUGCCAUCUAGGAAGCUUGUCAAAGAGUGUUGGCAACCUCUCUAACUGGCAUGAGGGGAGUCACGCAGGCCCAAC		26
17120	MI0002207	ptc-MIR160g	Populus trichocarpa miR160g stem-loop	GGGAUCAAUCUGCCUGGCUCCCUGGAUGCCAACUAAGAAAUUUGUCGAGUGGUCUUGACUCUUCAUAGUUGGCAUCAGAGGAGUCAUGCAGGUCCAAC		26
17121	MI0002208	ptc-MIR160h	Populus trichocarpa miR160h stem-loop	GAUCCCUGUGUGCCUGGCUCCCUGCAUGCCAUUUGCAUAGCUCAUCAGAACGUCGGUGGCCUUGGUGGAUGGCGUGCAACGAGUCAUGCAUGCUGUGA		26
17122	MI0002209	ptc-MIR162a	Populus trichocarpa miR162a stem-loop	UGGGAAGACACUGGAGGCAGCGGUUCAUCGAUCUCUUCCUGGCCAAUUUUUUGUUUAGCACGAAAAACAUGAACCGAUCGAUAAACCUCUGCAUCCAGCGCUUCCUU		26
17123	MI0002210	ptc-MIR162b	Populus trichocarpa miR162b stem-loop	UGAGAAGACACUGGAGGCAGCGGUUCAUCGAUCUUUUCCUGAAGAUUUUUUUGUUUUACACGAACAACACGAACCGAUCGAUAAACCUCUGCAUCCAGUGCUUCCCU		26
17124	MI0002211	ptc-MIR162c	Populus trichocarpa miR162c stem-loop	UGAGAAGACACUGGAGGCAGCGGUUCAUCGAUCUUUUCCUGAAGAUUUUUUUGUUUUACACGAACAACACGAACCGAUCGAUAAACCUCUGCAUCCAGUGCUUCCCU		26
17125	MI0002212	ptc-MIR164a	Populus trichocarpa miR164a stem-loop	GGUUCCUUGCUGGAGAAGCAGGGCACGUGCAAAAUCCUGAUGAAGUGCUUACACUUUGCACGCGCUCUUCUUCUCCAACACGGGC		26
17126	MI0002213	ptc-MIR164b	Populus trichocarpa miR164b stem-loop	GUGAGCAAGAUGGAGAAGCAGGGCACGUGCACUACUAACUCAUGCACACAGAGAGGGAGACGCAUUUCUUGCUGGAGUUACGAGUUACGACUCUUACCUACUAUUGAUUUUGUUAGCUCCAGUGAGUUAGUUAUUCAUGUGCCUGUCUUCCUCAUCAUGAUC		26
17127	MI0002214	ptc-MIR164c	Populus trichocarpa miR164c stem-loop	UAGCUCUUGCUGGAGAAGCAGGGCACGUGCAAGCUCUCUCCUCAAGCUUUCCUUGCACGUGCUCCCCUUCUCCAACAUGGGU		26
17128	MI0002215	ptc-MIR164d	Populus trichocarpa miR164d stem-loop	UGGCUCACGCUGGAGAAGCAGGGCACGUGCAAAAUCCUUCUCGGCUUCCAGAUGCUGAUGAAGCACUCUUUGCACGUGCUCCCCUCCUCCAACAUGAGU		26
17129	MI0002216	ptc-MIR164e	Populus trichocarpa miR164e stem-loop	GUGAGCAAGAUGGAGAAGCAGGGCACGUGCAUUACUAACUCAUGCACACAGAGUGAGAGAGACAUUUCUUGCUGGAGUUAUGACUCUUACCUACUAUAGAUUGUGUUGGCUUCAGCGAGUUAGUUCUUCAUGUGCCUGUCUUCCCCAUCAUGAUC		26
17130	MI0002217	ptc-MIR164f	Populus trichocarpa miR164f stem-loop	UGAGCCAUGCUGGAGAAGCAGGGCACAUGCUAAAUCUAUCAGCUUGAAAGUCUGAUAGUUUUGCAUGUGCUCUAUCUCUCCAGCUUGGAC		26
17131	MI0002218	ptc-MIR166a	Populus trichocarpa miR166a stem-loop	UUUCUUUUGAGGGGAAUGUUGUCUGGCUCGAGGUCACUAAUGGGAUCUAUGAUUUUAUCUCAAUUGAUUGAUUUUCUUUUAAAUUCUAGUAAAUUGAAUUGAGAGAUAUCAUGAUCAACUUAUAUUUAAUGAUGUCGGACCAGGCUUCAUUCCCCCCAAUUGUU		26
17132	MI0002219	ptc-MIR166b	Populus trichocarpa miR166b stem-loop	UAACUGUUGAGGGGAUUGCUGUCUGGUUCGAUGUCAUUCAUGUGAAGCUUUAACAUUAAUGUAGUAUUGAGUGAUUUCGGACCAGGCUUCAUUCCCCCCAACUAUA		26
17133	MI0002220	ptc-MIR166c	Populus trichocarpa miR166c stem-loop	CUUUUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACUCUUUCUUGAUCAGUCUGAUCAAGUGUUCUAUCUUUAGAUCUAAUAUCUUAGAUCAUGUGUUAGGGUCGUCGGACCAGGCUUCAUUCCCCCCAAUUAUU		26
17134	MI0002221	ptc-MIR166d	Populus trichocarpa miR166d stem-loop	CGUGAGUUGAGGGGAAUGUUGGCUGGCUCGAAGCUUAAGCAAAGAGUUUUCUCUCAAGAAACAACUGUUAAGGCUUCGGACCAGGCUUCAUUCCCCUCAACCAAU		26
17135	MI0002222	ptc-MIR166e	Populus trichocarpa miR166e stem-loop	UAACUGUUGAGGGGAUUGUCGUCUGGUUCGAUGUCAUUCAUGAGAAGCUCAAACAUAAACGUAAUAUUGAAUGAUUUCGGACCAGGCUUCAUUCCCCCCAACAAUG		26
17136	MI0002223	ptc-MIR166f	Populus trichocarpa miR166f stem-loop	GGUGUGUUGAGGGGAAUGUUGGCUGGCUCGAAGCUUAAGCAAAGAGUUUCCUAACAUGAAACAACUGUUAAGGCUUCGGACCAGGCUUCAUUCCCCUCAAACAUA		26
17137	MI0002224	ptc-MIR166g	Populus trichocarpa miR166g stem-loop	ACACAGUUGAGGGGAAUGCUGUCUGGUUCGAGACCAUUCACCUGAAGAGCACGCAUUCAUCUUUUGAGUGAUCUCGGACCAGGCUUCAUUCCCCCCAACUCAA		26
17138	MI0002225	ptc-MIR166h	Populus trichocarpa miR166h stem-loop	ACACAGUUGAGGGGAAUGCUGUCUGAUUCGAGACCAUUCACUUUAAGCACACAUUCAUCUUUCGAAUGAUCUCGGACCAGGCUUCAUUCCCCCCAACUCAA		26
17139	MI0002226	ptc-MIR166i	Populus trichocarpa miR166i stem-loop	UGUCUUUUGAGGGGAAUGUUGUUUGGUUCAAGGCCUGGCCACCCCAUGUCUUGGAAUUUAAAAUAUCAUGUCCUCGGACCAGGCUUCAUUCCCCUCAAUUACU		26
17140	MI0002227	ptc-MIR166j	Populus trichocarpa miR166j stem-loop	UCUUUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACUUUUUGUUCAUCAAUCUAAUCGAACUUUCUACCUGUAGAUCUAGUAUCUUAUUUAAGAUUGAUCACGUAUUAGGGUUGUCGGACCAGGCUUCAUUCCCCCCAAUCAUU		26
17141	MI0002228	ptc-MIR166k	Populus trichocarpa miR166k stem-loop	UCUUUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACUUUUUGUUCAUCAAUCUAAUCGAACUUUCUACCUGUAGAUCUAGUAUCUUAUUUAAGAUUGAUCACGUAUUAGGGUUGUCGGACCAGGCUUCAUUCCCCCCAAUCAUU		26
17142	MI0002229	ptc-MIR166l	Populus trichocarpa miR166l stem-loop	UAACUUUUGUGGUGAAUGUUGUCUGGUUCAAGGCAUGGCCACCACAUCUCUUGGUGAAUAUAUGUCCUCGGACCAGGCUUCAUUCCCCUCAAUUAAU		26
17143	MI0002230	ptc-MIR166m	Populus trichocarpa miR166m stem-loop	UGAGGAUGUGGGGGAAUGUCGUCUGACUCGAGACAACAGGUAAACUGAAGGAAUGGCCGGAGUUUAAGAGUUCUCUCGGACCAGGCUUCAUUCCCCUCAUCCACA		26
17144	MI0002231	ptc-MIR166n	Populus trichocarpa miR166n stem-loop	AAGGGGUGUUUGGAAUGAAGUUUGAUCCAAGAUCCUUGUCUCUCCCGUUAACUUAGUCUCUGUUACUGUUAGGUUUUCAUUACUGAGUGUAUUUGCAGCCCCCUUGUCUGAUUUUAGCAUCAUGAGAGUAGGAAGUGCUGGUGAUCAUAGGGUUUGGUUCAAGAUCCAUUUGACUCUUCUCUUUAUAUCUCUCCUGUGUCCUAGCUGGUAAUCUGUAGUAGUCUUAAUUAUCCCUUACUUCUUGUUAAUUUUUAGGUUUGAUCUUGCAAGUAAUUAUAUUUGGAAAAUAUCAUAAAAUGAUCUCGGACCAGGCUUCAUUCCUUACACCUUG		26
17145	MI0002232	ptc-MIR166o	Populus trichocarpa miR166o stem-loop	AAGGGGUGUUUGGAAUGAAGUUUGAUCCAAGAUCCUUGUCUCUCCCGUUCAUUUAGUAAUGUUACUGCUAGGUUUCGCUAUGUAUUGAUCAGUGUAUACACAGCAGCUACGAGCUAGGCCUUGUGUUUCAGAUUUUAGCUUCAAUAUAGAGUGAGCACUAGUGAUAGAGUUUGAUUCAAGAUCCAUCUCAUGUGUGCUAGCUAGCUUUUAAAUUUUUAAUCAGAUCCCUACUUCCUGUUAAUUCUUAGGUUUUAUCUUGCAAGUUAUUAUAUUUAGUAAACAUCAUGAACUGAUCUCGGACCAGGCUUCAUUCCUUACACCGAA		26
17146	MI0002233	ptc-MIR166p	Populus trichocarpa miR166p stem-loop	UAAGGUUGAGAGGAACGCUGUCUGGGUCGAGGUCAUGGAGGCCAUGAUUAUACAUAAAUGGCAUUAUCUGAUGACAGCCCAGAUAAUCGAUGCACCUGUCUUGAACCUAAAUGAUUCUCGGACCAGGCUCCAUUCCUUCCAACCAU		26
17147	MI0002234	ptc-MIR166q	Populus trichocarpa miR166q stem-loop	UUAGGUUGAGAGGAAUGUUGUCUGGCUCGAGGUCAUUGAGGCCAUGAUUAUACAGACAUGGCAUUACCUGAUGACAGCCGAGAAAAUUCAAAGUCUGUGUGUAUCUUGUACCUCGAUGAUUCUCGGACCAGGCUUCAUUCCUUCCAACAAA		26
17148	MI0002235	ptc-MIR167a	Populus trichocarpa miR167a stem-loop	CACUAGCAGUUGAAGCUGCCAGCAUGAUCUAACUUCCUUGCUUCUUUAUCAAGGAUGGAUUUAGAUCAUGUGGUGGUUUCACCUGUUGA		26
17149	MI0002236	ptc-MIR167b	Populus trichocarpa miR167b stem-loop	AGGGAAAAAGUGAAGCUGCCAGCAUGAUCUAUCUUUGGUUAGAGAAAGAAAGGACUAACCCUAGCUAGGUCAUGCUGUGACAGCCUCACUCCUUCC		26
17150	MI0002237	ptc-MIR167c	Populus trichocarpa miR167c stem-loop	CACUAGCAGUUGAAGCUGCCAGCAUGAUCUAAAUUAACCUCCUUCUUUAUCAAGGAUGGAUUAGAUCAUGUGGUAGUUUCACCUGCUGA		26
17151	MI0002238	ptc-MIR167d	Populus trichocarpa miR167d stem-loop	AGGGAAAAGGUGAAGCUGCCAGCAUGAUCUAUCUUUGGUUAGAGAAGGAUAGAAGCGAAAGAACUAACCCUAGCUAGGUCAUGCUCUGACAGCCUCACUCCUUCC		26
17152	MI0002239	ptc-MIR167e	Populus trichocarpa miR167e stem-loop	CACUAGUAGUUGAAGCUGCCAGCAUGAUCUGAACUUUCCUUAAUUUUCCUAUACGGGAAAGACUAGAUCAUGUGGUAGUUUCAUCUAUUGA		26
17153	MI0002240	ptc-MIR167f	Populus trichocarpa miR167f stem-loop	CUCUAUCAGUUGAAGCUGCCAGCAUGAUCUUAGCCUUCCUCCUUUGUUGAGGAAAGAAACAGAUCAUGUGGCAGUUUCACCUGUUGU		26
17154	MI0002241	ptc-MIR167g	Populus trichocarpa miR167g stem-loop	CACUAUCAGUUGAAGCUGCCAGCAUGAUCUUAACCUCCCUCCUUUGUCGAGGAAAGAACAGAUCAUGUGGCAGUUUCACCUGAAGU		26
17155	MI0002242	ptc-MIR167h	Populus trichocarpa miR167h stem-loop	CGCUAUUAGUUGAAGCUGCCAACAUGAUCUGAGCUUUCCUUAAUUUUCCUAUACAGGAAAGACUAGAUCAUGUGGCAGUUUCACCUAUUGA		26
17156	MI0002243	ptc-MIR168a	Populus trichocarpa miR168a stem-loop	GGUCUCUGAUUCGCUUGGUGCAGGUCGGGAACUGAUUCGGCGAUUUGAUUGCCAGAUGGCUCGACAUGACUGGUUGUUGUGGAAAAAGAAAAGGAAGGAAACAGGAAAAAAAACAAAGAAUAGCGAAUUGGAUCCCGCCUUGCAUCAACUGAAUCGGAGG		26
17157	MI0002244	ptc-MIR168b	Populus trichocarpa miR168b stem-loop	GGUCUCUAAUUCGCUUGGUGCAGGUCGGGAACUGAUUCGGCGAUUUGAUUGCCAGAUGGCUAAACACGAUUGGCUGUGAGGCAAAUUAUAAAAAGAAAGAGAAUUGGAUCCCGCCUUGCAUCAACUGAAUCGGAGA		26
17158	MI0002245	ptc-MIR169a	Populus trichocarpa miR169a stem-loop	AAGUGGUAUGCAGCCAAGGAUGACUUGCCGACUUAACUGAUCUGUAUAAAUUAAUGCAUGUGUAGUCAAAAUUACUACUACUAUAUAUUAAUCUGAUCUGUGACCACAAAUUAACUAACUACUAGCUAGUAAUUAGUUGGCAAGUUGUCCAUGGCUACAUGCUGC		26
17159	MI0002246	ptc-MIR169aa	Populus trichocarpa miR169aa stem-loop	GUAGAGAUCGAGCCAAGAAUGACUUGUCGGCAGGCUAGCAAUUGCUACGUAUAGAGCAAUAUGUAUGCUAGAAUGAGUAUUCCGCCAGGUCGUUCUUGGCUCAACUUUG		26
17160	MI0002247	ptc-MIR169ab	Populus trichocarpa miR169ab stem-loop	CUUGUUUGGUAGCCAAGGACGACUUGCCCACCACCAUCUCAGUUGGGUCCAAUAUAUUACUGGGCACCUUCCAUUUGGUUUUGGGCAAGCACCUUGGCUAGCUGACA		26
17161	MI0002248	ptc-MIR169ac	Populus trichocarpa miR169ac stem-loop	UCUUGUUUGUAGCCAAGGACGACUUGCCCACAAUAUGUAUCGUGAGCGUUUCCAAUUUGCAACCUCAUACUUGGUUUGUUUUGGGCAGUCUCCUUGGCUAUGCAGAU		26
17162	MI0002249	ptc-MIR169ad	Populus trichocarpa miR169ad stem-loop	GAUGUUCGGUAGCCAAGGACGACUUGCCCACACUAUGAGACAAGUGGUUAGAAUUAGCAACUUCUUAAUUGGUUAUGGGAAGUCUCCUUGGCUAUGCUGAC		26
17163	MI0002250	ptc-MIR169ae	Populus trichocarpa miR169ae stem-loop	CUUGUUUGGUAGCCAAGGACGACUUGCCCACCACCAUCUUAGUUGGGUCCAAUAUAUUACUGGGCACCUUCCAUUUGGUUUUGGGCAAGCACCUUGGCUAGCUGACA		26
17164	MI0002251	ptc-MIR169af	Populus trichocarpa miR169af stem-loop	CCUGUUUGGUAGCCAAGGACGACUUGCCCACCACCAUCUUAGUUGGGUCCAGUAUAUUACUGGGCACCUUCCAUUUGGUUUUGGGCAAGCACCUUGGCUAGCUGACA		26
17165	MI0002252	ptc-MIR169b	Populus trichocarpa miR169b stem-loop	AAGAUUGAUGCAGCCAAGGAUGACUUGCCGACGACUCGUUUUUGCUUUCAUCAAUAUACGCAUAAUUAAGAAGAGAUGAAUCCGUUGGCAGGUUGUUCUUGGCUACAUUUUUC		26
17166	MI0002253	ptc-MIR169c	Populus trichocarpa miR169c stem-loop	AAGUUUGAUGCAGCCAAGGAUGACUUGCCGACGACUCAAUUUUUGCUUCCAUAUGGUAGAAGAGAUGAAUAGGUUGGCAGGUUUUCCUUGGCUACAUUUUCC		26
17167	MI0002254	ptc-MIR169d	Populus trichocarpa miR169d stem-loop	GAGUCGAAUGCAGCCAAGGAUGACUUGCCGGCAUUUCCUCCUAAGUAGCGAGCCCGGCAAGGCUUCUAUUUGGCACGCCCGGCCGGCGGGUUGUCCUUGGCUAUAUUUGGU		26
17168	MI0002255	ptc-MIR169e	Populus trichocarpa miR169e stem-loop	UAUCGUGGCGCAGCCAAGGAUGACUUGCCGGCAAGCUCCUCACACGUAUUUUGUUUCGAGUUUCAUUGAUGGCAUUGCUAGAUAGAUAUAUAUGAUUUCGUAAUUCAAACUUUUGGGCCAUUGUCUGGUUGAAAUGAUCGGCAAGCUGUCCUUGGCUAUGUCUCUA		26
17169	MI0002256	ptc-MIR169f	Populus trichocarpa miR169f stem-loop	UUAUGUGGUGCAGCCAAGGAUGACUUGCCGGAAUAAGCUAUGAUCAAUAGCUAUAGCUAUGGUAUUUUUCAUCCUAGGUUUGGCUAUAUAUAUAUAUAUAUAUAGCCAGUUAAUUGCUAUAAAUCUCAGCACAUUUAUGUUUUAUAUGUCUGCACACAGACACACACAUCAUUGAAUGUUGAUGUUCCACCUCCUAUGAUCAGUAGUCAAUCGGCAAGUCAUCUCUGGCUACUCAACUC		26
17170	MI0002257	ptc-MIR169g	Populus trichocarpa miR169g stem-loop	GAGUAGAAUGCAGCCAAGGAUGACUUGCCGGCAUUUCCUCCUAGGUAGCUAGCAAGCCUUCUAUUUGGCAUGCCUGUCCGGCAGGUUGUCCUUGGCUAAAUUUUGU		26
17171	MI0002258	ptc-MIR169h	Populus trichocarpa miR169h stem-loop	GAGUGUAAUUCAGCCAAGGAUGACUUGCCGGCAGCACGGGAUCUCAGAGCUUAAUAACUAGAAGAUCAAGGCUGUCAUUACUUUUCCGGCCGGCAAGUUGCCCUUGGCUACAUUGUAC		26
17172	MI0002259	ptc-MIR169i	Populus trichocarpa miR169i stem-loop	UCUUGUUUGGUAGCCAAGGAUGACUUGCCUGCUCCAUUGUAGGAGGUUUCCGAAAAAAUGCAGACAUGUAUAAUUUCGAAACCCCUGUUUCGUUUCAGGCAGUCUCCUUGGCUAACUUGACUG		26
17173	MI0002260	ptc-MIR169j	Populus trichocarpa miR169j stem-loop	UCUUGUUUGAUAGCCAAGGAUGACUUGCCUGCUACUUGCAAGAGUUUCUGCAAAGAGAUCAGAACCAAAUAUGCAUGGAAUUAUAUGUAAUGAAACUCUUGUUUGAUUGCCAGGCAGUCUCCUUGGCUAGCCUGACA		26
17174	MI0002261	ptc-MIR169k	Populus trichocarpa miR169k stem-loop	UCUUGUUUGGUAGCCAAGGAUGACUUGCCUGUAGCCUCCCUCGGAUUCAUGAACACGAGCAUUUAUGUGGUGCUCAAAAGAAAAGGAGAGAAUGAUCCCAGCUGGCAGCGACAAGGUCAAUCCAUUGAAGUAGCGAGAAGCAGGUGAUUUAUAGCUAGAAUCCACAAGAGGUUCCCAGCAAGUGUCCUUGGCUAACGAGACGG		26
17175	MI0002262	ptc-MIR169l	Populus trichocarpa miR169l stem-loop	UCUUGUUUGAUAGCCAAGGAUGACUUGCCUGCUACAUACAAGAGAUCAUUAUGCAUAAAUAGAACGAAAUAUGUACAUGGUAUUAAUUAAUGCAGUGAAAACUCUUGUUUGGUUGCCAGGCAGUCUCCUUGGCUAAGCUGACA		26
17176	MI0002263	ptc-MIR169m	Populus trichocarpa miR169m stem-loop	UCUUGUUUGGUAGCCAAGGAUGACUUGCCUGCUCCCUUCAAGGAGGUUUCAUGAAAUGCAGACAUGAUCUCUCGAAACCCCUGUUGGGUUUCAGGCGGUCUCCUUGGCUAACUUGACAG		26
17177	MI0002264	ptc-MIR169n	Populus trichocarpa miR169n stem-loop	AGAGUGGAUUUGAGCCAAGGAUGACUUGCCGCAGAUGCAUGGUCCUUGCUGCUGAUCACAUACCAAGGGGGGUUUUGGGUGGCAAGCAUCCUUGGUUCUCCUUCGCU		26
17178	MI0002265	ptc-MIR169o	Populus trichocarpa miR169o stem-loop	CCUUGCGUGGAAGCCAAGGAUGACUUGCCUGAGAAUUUUAGGAAGGUUUCUAUAUGAAAGCUUUUUAUUAGUUUUGCAGGAAGUCAACCUUGGCUUUCCUAUAG		26
17179	MI0002266	ptc-MIR169p	Populus trichocarpa miR169p stem-loop	CCUUGCGUGGAAGCCAAGGAUGACUUGCCUGAGAAUUUUAGGAAGGUUUCUAUAUGAAAGCUUUUUAUUAGUUUUGCAGGAAGUCAACCUUGGCUUUCCUAUAG		26
17180	MI0002267	ptc-MIR169q	Populus trichocarpa miR169q stem-loop	UCUUGUUAGUUAGCCAAGGACGACUUGCCUGUUCCUAGCAAUUUGGGAUUUGCCCUGGACUAAGAGGCAGGACCCUCAUUCCGGGUUUCAGGCAGUCUCCUUGGCUAGGUUGACA		26
17181	MI0002268	ptc-MIR169r	Populus trichocarpa miR169r stem-loop	GAGGGUUUGGUAGCCAAGGAUGACUUGCCUAUUUCCUCCAUAAGGCUUUAAAAAGCAUGAAAUGUGGUUUAGAGCUCAAUUGAAGGGUUCAUAGGCAGUCUACUUUGGUUAUCCUAGCU		26
17182	MI0002269	ptc-MIR169s	Populus trichocarpa miR169s stem-loop	AGAGUGUGAUUCAGCCAAGGAUGACUUGCCGGCAGCAGGUAAGAGCAAAGCUCCGUUUUUGGAAGUUCAAGGAUAUCUUAACUUUUCCGGCCGGCAAGCUGUCCUUGGCUACAUUGUACU		26
17183	MI0002270	ptc-MIR169t	Populus trichocarpa miR169t stem-loop	CUAGAGUCCGAGCCAAGAAUGACUUGCCGGCAGGCUAGCAUUUGCUAGCUACAGGGCAAGAUGUAUGCUAAAGUGACAUUCCGCCAGGUUGUUCUUGGCUCUACUUUG		26
17184	MI0002271	ptc-MIR169u	Populus trichocarpa miR169u stem-loop	GAGGGUUGGGUAGCCAAGGACGACUUGCCUAUUUCCUCCAUGGGGUCCUGAAAAGAAUGAAAUACUGUCGUUCAGAGCUCAUUGGUAGGGUUCAUAGGCAGUCUCCUUUGGCUAUCCUAACU		26
17185	MI0002272	ptc-MIR169v	Populus trichocarpa miR169v stem-loop	CGUGUUUGGUAGCCAAGGAUGACUUGCCCACUCCAUUGAAAGAGUUUUUCAAGCAUAUGGUAGUGUAGAACUUUUCUUUGGUUCUGGGCAGUCAUCUUGGCUAUGCUGAC		26
17186	MI0002273	ptc-MIR169w	Populus trichocarpa miR169w stem-loop	CGUGUUUGGUAGCCAAGGAUGACUUGCCCACUCUAUGGAAAGAGUUCUCAAGCACACGGCAGAGAGGACCCUUACUUCGGCUCUGGGCAGUCACCUUGGCUAUGCUGAC		26
17187	MI0002274	ptc-MIR169x	Populus trichocarpa miR169x stem-loop	UGCUGUUUUCUAGCCAAGGAUGACUUGCUCGUUAGCCCUUGAAAGAUGUUUCAAAUUUAGGCUGCAUAUGCUCAGAACCUUUUUCUGGCUUCAGGCAAUCAUCUUGGCUAAAUGACAG		26
17188	MI0002275	ptc-MIR169y	Populus trichocarpa miR169y stem-loop	UCUUGUUUAGUAGCCAUGGAUGAAUUGCCUGCUUCCAAAAUGAGGUGUCAAGCCGAGAUAAACAUACAAGUUUGAUCCCUCAUUGGGGUUCCCAGGCAGUCAUCAGCUUGGCUAACUUGACAG		26
17189	MI0002276	ptc-MIR169z	Populus trichocarpa miR169z stem-loop	UAGUAGAAUGCAGCCAAGAAUGAUUUGCCGGCGCCGGCCAGCACUUGUUGCAAAGCAACUAAGCAAGGGCUUCAAAUGUUUUUGGCACCCCGGCAAGUUGUUCUUGGCUACAUUUGGA		26
17190	MI0002277	ptc-MIR171a	Populus trichocarpa miR171a stem-loop	UCAGAGAAAACGGGAUAUUGGUACGGUUCAAUCAGAAAGUAAUGCUCCCAAAAGUAUAGAGUACUAUUGUUUGAUUGAGCCGUGCCAAUAUCACGUACACUCAU		26
17191	MI0002278	ptc-MIR171b	Populus trichocarpa miR171b stem-loop	UUAUAUAUAACGAGAUAUUGGUGCGGUUCAAUCAGAUAGUAAUGCUCCAUAAGCAUAGAGCUCUAUUGUUUGAUUGAGCCGUGCCAAUAUCACGUAUAUGUUG		26
17192	MI0002279	ptc-MIR171c	Populus trichocarpa miR171c stem-loop	AAAAGAAAGCGAUGUUGGUGAGGUUCAAUCCGAAGACGGAUUUACACGUGAAAGUAAUUGUAAAAUACGAUCUCAGAUUGAGCCGCGCCAAUAUCACUUUCUCA		26
17193	MI0002280	ptc-MIR171d	Populus trichocarpa miR171d stem-loop	AAAAGAAAGCGAUGUUGGUGAGGUUCAAUCCGAAGACAGAUUUACACGAGUGAAAGUAAAAUCCGAUCUCAGAUUGAGCCGCGCCAAUAUCACUUUUCAG		26
17194	MI0002281	ptc-MIR171e	Populus trichocarpa miR171e stem-loop	GUGGAAAUUUGAUGUUGGCAGAGCUCAAUCAAAUCAAAGCACUCAAUGGUUGGGUUCUUUCAUCUGAUUGAGCCGUGCCAAUAUCGCAUUAAAU		26
17195	MI0002282	ptc-MIR171f	Populus trichocarpa miR171f stem-loop	GUGUCAUUGCGAUGUUGGCCCGGUUCACUCAGAGAAAAGACACCAUUUUUUUUCAAGAAGAUCAUCAAAGCUUGAAAGAAUAAUGGUGGUCGGUCGUCUCUGAUUGAGCCGUGCCAAUAUCUUAGUGCUC		26
17196	MI0002283	ptc-MIR171g	Populus trichocarpa miR171g stem-loop	GAAAGUGGGGGAUGUUGGGAUGGCUCAAUCAUGUCAAAUCUCCCAAAUUAUGAUGUUGGGUCUUUUAAUCUGAUUGAGCCGUGCCAAUAUCACACUUCUU		26
17197	MI0002284	ptc-MIR171h	Populus trichocarpa miR171h stem-loop	GAAAGUGGGGGAUGUUGGGAUGGCUCAAUCAUAUCAAAUCUCCCAAACUAUGAUGUUGGGUCGUUUAAUCUGAUUGAGCCGUGCCAAUAUCACACUAACU		26
17198	MI0002285	ptc-MIR171i	Populus trichocarpa miR171i stem-loop	GAGUGACUAUGAUAUUGGCCUGGUUCACUCAGAUCACGACUUCAGAGCAAAGUGUCUUUCUUCUUCUUCUUCUUCUUCUUGUUUUAUGUUCGUUUGAUUUGAUUGAGCCGUGCCAAUAUCUCAGUACUC		26
17199	MI0002286	ptc-MIR171j	Populus trichocarpa miR171j stem-loop	CUAACUCAAGAUAUUGGCACAGUUCAUCCUCACAGUGGCCUUGAUGAAUGAUUCAAAUCUAUGGUUGGAUUGAGCCGCGCCAAUACUGUGUGCCA		26
17200	MI0002287	ptc-MIR172a	Populus trichocarpa miR172a stem-loop	UUGUUUGCAGGUGCAGCAUCAUCAAGAUUCACAUUCAAAUAGAUGUACCGAAGCUAUACAGCUAUGUAGCUAGCUAGCAAUGUAUAAUCAUUGUAGGUGAGAAUCUUGAUGAUGCUGCAUCAGCCAUAA		26
17201	MI0002288	ptc-MIR172b	Populus trichocarpa miR172b stem-loop	UUGUUUGCGGGUGGAGCAUCAUCAAGAUUCACAUGCAAAUGCACGGCCGGUGAUGUUAAGAGUUAAAUCUUUCUUUGUUUCUGUUCAUCUGCCAAAGUUCUUUGGAAGUGAGAAUCUUGAUGAUGCUGCAUCGGCAAUAA		26
17202	MI0002289	ptc-MIR172c	Populus trichocarpa miR172c stem-loop	UUGUUUGCAGGUGCAGCAUCAUCAAGAUUCACAUUCAAACAGAUGUACGGCAGCUAGCUAGCUAGAUAGAUAGACAGCAAUGUAUUUCUUUGAAGGUGAGAAUCUUGAUGAUGCUGCAUCAGCCAUAA		26
17203	MI0002290	ptc-MIR172d	Populus trichocarpa miR172d stem-loop	GCAUUGGCGGAUGCGGCAUCAUCAAGAUUCACAAGCUUUAAGGCUUGAGUGAGAGGGGUGGCAUACGGUCACCUCCUUUAGCAAGCUUUAAGGCUUGAGUGAGAGGGGUGGCAUACGGUCACCUCCUUUAGUCCAAAGGGUCCUUUUUUAUGGGAAUCUUGAUGAUGCUGCAUCGGCAAAUA		26
17204	MI0002291	ptc-MIR172e	Populus trichocarpa miR172e stem-loop	AUAUUGGCCGAUGCGGCAGCAUCAAGAUUCACAAACUUUAAGGCUUGAGUUGGGGUGGUACACGGUCACCUCCUUUACUCGAAAGGUUCCUUAAUUUCUGAUGGGAAUCUUGAUGAUGCUGCAUCGGCAAAUA		26
17205	MI0002292	ptc-MIR172f	Populus trichocarpa miR172f stem-loop	UUGUUUGCGGGUGCUGCAUCACCAAGAUUCACAUGCAAAUGCAUGGCCGAUGAUAUAUGUUAGAAAUUUUUUUUAUAUAAAAAAGAUAUCUUUCUUUCUUUCUGAUCAUCUGCCAAAGUUCUUUGGAAGUGAGAAUCUUGAUGAUGCUGCAUCGGCAAUAA		26
17206	MI0002293	ptc-MIR172g	Populus trichocarpa miR172g stem-loop	CUGUUUGCCUAUGGAGCAUCAUCAAGAUUCACAAGCUUUAUUAGGGCUAGUGUGUGGUGAUGAUGGUGGCUUUUGGUGGUCCCUUUUUUUCAAUCCAAUAGCCCUUUGAAUUGGGAAUCUUGAUGAUGCUGCAGCGGCAAUAA		26
17207	MI0002294	ptc-MIR172h	Populus trichocarpa miR172h stem-loop	CUGUUUGCCGAUGGAGCACCAUCAAGAUUCACAAACUUUAUUAGGGCUAAUAAGUGGUGAUGAUGGUGGCUUUUGGUGGUCCCUUCGUUUCAACCCAAUAGCCAUUUGAAUUGGGAAUCUUGAUGAUGCUGCAGCGGCAAUAA		26
17208	MI0002295	ptc-MIR172i	Populus trichocarpa miR172i stem-loop	AUGUGGUGAAGGCAGCAAGUCGCGGGUUGUUGUUGGCGAAAUGGUUCUGUUGGUUGAAUGGAAGAGUAGCUGAAGGAACAGUUUUGGUCGAAGAAGAGAAUCCUGAUGAUGCUGCAACACAGAGC		26
17209	MI0002296	ptc-MIR319a	Populus trichocarpa miR319a stem-loop	UAAUAGCUAAGAGAGCUUUCUUCAGUCCACUCAUGGGUGGUAGUAGGAUUUAAUUAGCUGCCGACUCAUUCAUCCAAAUACUGAGUUAAAGGACAAGGAGAUUACCCAGUAAAUGAGUGAAUGAUGCGGGAGACAAAUUGAAUCCUAAGCUUCCUGUACUUGGACUGAAGGGAGCUCCCUUUCCUUUU		26
17210	MI0002297	ptc-MIR319b	Populus trichocarpa miR319b stem-loop	UAAUAGAUAAGAGAGCUUUUUUCGGUCCACUUAUAGAUAGUAAUAUGAUUUAAUUAGUUACCGACUCAUUCAUCCAAAUACUGAGUUAUGAGCUAAGAUUACCCAGUAAAUGAAUGAGUGAUGCGGGAGACAAAUUAAAUCUUAAACUUCCUAUCAUUGGACUGAAGGGAGCUCCCUUUACUGUU		26
17211	MI0002298	ptc-MIR319c	Populus trichocarpa miR319c stem-loop	AAUGGUUUAAGAGAGCUUUCUUCAGUCCACUCAUGGACGGGCGAAGGGUUUGGAUUAGCUGCCGACUCAUUCAUUCAAACACAGUAGAAAUUAAGGGAGCAGUAUGGCUGCUAUUGUGAAUGUGUGAAUGAUGCGGGAGAUAAAUUUCAUCCUUUUCUUCUCUGUGCUUGGACUGAAGGGAGCUCCCUUUAAUCGU		26
17212	MI0002299	ptc-MIR319d	Populus trichocarpa miR319d stem-loop	AAUGGUUUAACAGAGCUUCCUUCAGUCCACUCAUGGACGGGCGAAGGGUUUGGAUUAGCUGCCGACUCAUUCAUUCAAACACAGUAGACAAGGAGUGGCAGCGGCUGCUAUUGUGAAUGUGUGAAUGACGCGGGAGAUUAAUUUCAUCCUUUUCUUCUCUGUGCUUGGACUGAAGGGAGCUCCCUUUAAUUGU		26
17213	MI0002300	ptc-MIR319e	Populus trichocarpa miR319e stem-loop	GGAGGGGCUGAGGUGCUCCUUUUAGUCCAAUACGGAGGGCUGAGAAGCGGCUAGAGCUGCCAUCUCAUGCAUUUAGGCAAUGCUUAACAUUUGACGAAGAGAGGUUAAGCUUGGCCACUUGCAUGGUGUGGGAGCAACUCCUUCCGCAUGCUUUGCUCGCCCAUUGGACUGAAGGGAGCUCCUGGUUUUACC		26
17214	MI0002301	ptc-MIR319f	Populus trichocarpa miR319f stem-loop	UAAUGGUGGGAGAGAGCUUCCUUCAGCCCACUCAUGGAUAGGAGAAAGGGGUUGAAUUAGCUGCCGACUCAUUCAUUCAAGCACCAGUAGAAAAAGGGGAAUGGAUAUUCUUUUGCUACUGUGAUUGUGUGAAUGAUGCGGGAGAUAAUUUUACAUCCCCUCUUUUUCUGUGCUUGGACUGAAGGGAGCUCCUUCCUUCUAU		26
17215	MI0002302	ptc-MIR319g	Populus trichocarpa miR319g stem-loop	UAAUCGUGGGAGAGAGCUUCUUUCAGCCCACUCGUGGAUAGGACAAAGGGGUUGAACUAGCUGCCGACUCAUUCAUUCAAGCACUAGUAGAAAAAAAGGCGAACGGUGUUUCUUUUGCUACUGUGAUUGUGUGAAUGAUGCGGGAGAUAAUUUUCCAUCCUCUCCUUUUCUGUGCUUGGACUGAAGGGAGCUCCUUCCUUCUCU		26
17216	MI0002303	ptc-MIR319h	Populus trichocarpa miR319h stem-loop	UUGUAGGGGCUAAAGUGCUCCUUUUAGUCCAAUAAGGAGGGCUGAGAAGCGGCUAGAGCUGCCAUCUCAUGCAUUUAGGCAAUGCUUAACAUUUGGCAAAGAGGUUUAAGCUUGGCCAGGUGCAUGGUGUGGGAGCAACUCCUUCCGCAUGCUUUGUUCGCCCAUUGGACUGAAGGGAGCUCCUGGUUUUACCAC		26
17217	MI0002304	ptc-MIR319i	Populus trichocarpa miR319i stem-loop	GUGCAGAAAUGGAGGUUCCUUCCAGCCUCAAGCAUCUUUAAGAUGGUGGCGAUGUCUAUUUUGGGCUGAAGGGAGCUCCCAAUUCUUCU		26
17218	MI0002305	ptc-MIR390a	Populus trichocarpa miR390a stem-loop	AGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGAGCAUGACAAAGUCUAUGUUUGAGUUAAUCUCAACAAAAUCAAUCCAGUCAUCAGUGGCGCUAUCUAUCCUGAGUUCUAUGGGUU		26
17219	MI0002306	ptc-MIR390b	Populus trichocarpa miR390b stem-loop	AGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCCUAAGGAUAAUCAUGGGCUCUUUUUAUGUGGUUUUUGAUUCUCAGUGGCGCUAUCCAUCCUGAGUUUCAUUGCUU		26
17220	MI0002307	ptc-MIR390c	Populus trichocarpa miR390c stem-loop	AGGAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGAGCUGAUGAUAAGUUGAUGUUUGAUGGGUUAAUCUCAACAUAAUCAAUCUAGUCAUUAGUGGCGCUAUCUAUCCUGAGUUCUAUAGGUU		26
17221	MI0002308	ptc-MIR390d	Populus trichocarpa miR390d stem-loop	AGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCCUAAGGAUAACCAUGGGCUCUUUUUAUUUGGUUUUUGACUAUCAGUGGCGCUAUCCAUCCUGAGUUUUACUGGUU		26
17222	MI0002309	ptc-MIR393a	Populus trichocarpa miR393a stem-loop	AGAGGAGGCAUCCAAAGGGAUCGCAUUGAUCCCAAGUGUCUGUCCCCCAUAAUUUUGGAUCAUGCUAUCCCUUUGGAUUCCUCCU		26
17223	MI0002310	ptc-MIR393b	Populus trichocarpa miR393b stem-loop	AGAGGAGGCAUCCAAAGGGAUCGCAUUGAUCCCGAGUGUCCCUGGCCAUAAUUUUGGAUCAUGCUAUCCCUUUGGAUUCCUCCU		26
17224	MI0002311	ptc-MIR393c	Populus trichocarpa miR393c stem-loop	GCUGGAGUGUUCCAAAGGGAUCGCAUUGAUCUAAUGACUCUCGAUGUCUAAAUCAUAUUAAUGUUUAGUUUUUUCGUUGGAUCAUGCGAUCCCUUAGGAAUUUUCCA		26
17225	MI0002312	ptc-MIR393d	Populus trichocarpa miR393d stem-loop	GUUGGAGUGUUCCAAAGGGAUCGCAUUGAUCUAAUGACUUUUGAUGUCUAUAUGAUGUUAAUGUUUAGUCAUUUCAUUGGAUCAUGCGAUCCCUUAGGAAUUUUCCA		26
17226	MI0002313	ptc-MIR394a	Populus trichocarpa miR394a stem-loop	ACAGAGUUUUUUGGCAUUCUGUCCACCUCCAUCUGUAGAAACUACAAGUUGUUCUACUUUCUGGAGGUGGGCAUACUGCCAACUGAGCUC		26
17227	MI0002314	ptc-MIR394b	Populus trichocarpa miR394b stem-loop	ACAGAGUUUAUUGGCAUUCUGUCCACCUCCUAUCUUUAGAAAUUAGAAUAUCUCUUUCAUAUGGAGGUGGGCAUACUGCCAACCGAGCUC		26
17228	MI0002315	ptc-MIR395a	Populus trichocarpa miR395a stem-loop	GGUCACCCUGAGUUCCUCCUAGCUUCUUCAGUACCCGUGGAAAGCUAAUGCUACAAUUAUCUUGAGCUGGUAAGACUGGCAGGUGUCAGAUGUGGAUGUGUUAAAGGUAAUAUUAUUGAUUAUUUACGGCGCCAUUCAAGUAUUUGUUCUACUGUUAGAGGAUUUAAUCAAGUAUAUGUGGUAUUACUCCUGAUUUGCUGAAGGGUUUGGAGGAACUCUAGGUGCU		26
17229	MI0002316	ptc-MIR395b	Populus trichocarpa miR395b stem-loop	GUGUCCCCUAGAGUUCCCUUGAGCACUUCACUGGGACCCUUCAGACCGAAAGAGUAUUAUCUUUCCCACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17230	MI0002317	ptc-MIR395c	Populus trichocarpa miR395c stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCAUUGGGAAUCUUCGAUUAAAUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17231	MI0002318	ptc-MIR395d	Populus trichocarpa miR395d stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCACUGGGAAUUUCCGAUCAAAUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17232	MI0002319	ptc-MIR395e	Populus trichocarpa miR395e stem-loop	CUGUCCCCCGGAGUUUCCCUGACCACUUCACUGGGGCUAUAAUUCUACUCUUCGUGUUUAAGGGUAGAGGCAACCCUUCCUCACUGAAGUGUUUGGGGGAACUCUGGGUGGCA		26
17233	MI0002320	ptc-MIR395f	Populus trichocarpa miR395f stem-loop	CUGUCCCCCGGAGUUUCCCUGACCACUUCACUGGGGCUAUAAUUCUACUCCUCGUGUUUAAGGGUAGAGGCAACCCUUCCUCACUGAAGUGUUUGGGGGAACUCUGGGAGGCA		26
17234	MI0002321	ptc-MIR395g	Populus trichocarpa miR395g stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCAUUGGGGAUCUUCCAUCGACCUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17235	MI0002322	ptc-MIR395h	Populus trichocarpa miR395h stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCAUUGGGGAUCUUCCAUCGACCUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17236	MI0002323	ptc-MIR395i	Populus trichocarpa miR395i stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCAAUGGGGAUCUUCCAUCGACCUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17237	MI0002324	ptc-MIR395j	Populus trichocarpa miR395j stem-loop	GUGUCCCCUAGAGUUCCUCUGAGCACUUCAAUGGGGAUCUUCCAUCGACCUGAAAGAGUAUUAUCAUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCA		26
17238	MI0002325	ptc-MIR396a	Populus trichocarpa miR396a stem-loop	CUUGGUAUUCUUCCACAGCUUUCUUGAACUGCACCUAUUUGAAUAUUGUUGUUGAUGUUGCCGUGCAUGUACAUAUGACAUUGUAUUUUUGUUGCGGUUCAAUAAAGCUGUGGGAAGAUACAA		26
17239	MI0002326	ptc-MIR396b	Populus trichocarpa miR396b stem-loop	CUUUGUAUUCUUCCACAGCUUUCUUGAACUGCACCUAUUAGAUUAAUGUUGAUGUUGUUGUGCGAUAUGCCAUGACCAUAUGACAUUGUAUUCAUUUUUGCUGCGGUUCAAUAAAGCUGUGGGAAGAUACAA		26
17240	MI0002327	ptc-MIR396c	Populus trichocarpa miR396c stem-loop	UGCCAUGUUUUUCCACAGCUUUCUUGAACUUCCUAGAGCCUAGAGGUGCUGCUAGCUAUACAUAUAACUUAAGAAGUUCAAGAAAGCCGUGGAAUAGCAUGA		26
17241	MI0002328	ptc-MIR396d	Populus trichocarpa miR396d stem-loop	GGUCAUGCUUUUCCACAGCUUUCUUGAACUUCCUUGCCAUGCUUAACUUGUGUGUGUGUGUGUGUGUGUGUGUAGAUCACUAUAUAUCUGUAUAGUUAUACACAUUUAGCUAGCUAGCACCAUGGAAGCUCAAGAAAGCCGUGGGAGAACAUGG		26
17242	MI0002329	ptc-MIR396e	Populus trichocarpa miR396e stem-loop	GGUCAUGCUUUUCCACAGCUUUCUUGAACUUCUUUGCCUUGCUUAAUCUGUGUAUAUAUAGAUCACUACAUGUACAGCUCCUAUAUAUAUAAAUAUAUGUAUGUAUAGCGCCAUGGAAGCUCAAGAAAGCUGUGGGAGAACAUGG		26
17243	MI0002330	ptc-MIR396f	Populus trichocarpa miR396f stem-loop	CUUGGUGAUUUUCCACGGCUUUCUUGAACUGUAUAUAUUAUCAAUGGCUUUUUACAAGACUGGAAGAUGGUUUCCAUGGAGAAGAAUUGUCACAAAAACAGUUCAAGAAAGCCCUGAAAAAUUAUUU		26
17244	MI0002331	ptc-MIR396g	Populus trichocarpa miR396g stem-loop	UUGCAUGCUUUUCCACGGCUUUCUUGAACUUGGCACUCAAGAGACAUGAGAGUAAAGGGCUAGGCUUUCUUUUCUAUUCCUUUCGUUCUUUGAAAUUUUCCUGUUCAAAGAAUCCAUACAUAUCAGUCUCUUUAGUACAAAGCUCAAGAAAGCCGUGGGAAAAUAUGA		26
17245	MI0002332	ptc-MIR397a	Populus trichocarpa miR397a stem-loop	UGGAGAACCAUCAUUGAGUGCAGCGUUGAUGAAAUCCUCCAUUUUGUGCUAUUAAACUGUUACCAACCCUUUAUGGGGCAUGGCAUCAUUUCACCAGCGCUGCAUUCAAUCAUGUUUUUC		26
17246	MI0002333	ptc-MIR397b	Populus trichocarpa miR397b stem-loop	UAAUUAUACACCAUUGAGUGCAGCGUUGAUGAAAUUCUCUUGUUAGCUUACUUAGCUAUUUUCUCACGAUGGCGUGGAAUCAUUUCACCAGCGCUGCAUUCAACCAUGUUUUUC		26
17247	MI0002334	ptc-MIR397c	Populus trichocarpa miR397c stem-loop	CAAGUUUAGUUCAUUGAGUGGAGCUUUGAUGACAAUUUGUUUUAAAAGCUCUACUGUAUUCGAACAAUAUG		26
17248	MI0002335	ptc-MIR398a	Populus trichocarpa miR398a stem-loop	GUACACCCCAGAGGAGUGGCUCCAGAGAACACAGGGGGUUGGUUUUCUAGCUGUAAGCUACAAGAUGGACAAAGCACUCUGUGUUCUCAGGUCACCCCUUUGGGGCACC		26
17249	MI0002336	ptc-MIR398b	Populus trichocarpa miR398b stem-loop	AGGGUUCCGACAGGAGCGGCCUUGGGUCACAUGUGGCGGCAUCCAAUGUACUUCAUGUGUUCUCAGGUCGCCCCUGCCGGGCUUC		26
17250	MI0002337	ptc-MIR398c	Populus trichocarpa miR398c stem-loop	AGGAUUCCUACAGGAGCGACCUGAAAUCACAUGUGGGCUGCACCCUCCUGGGUUAUCUUGAGCAACAUGUGUUCUCAGGUCGCCCCUGCCGGGCUUU		26
17251	MI0002338	ptc-MIR399a	Populus trichocarpa miR399a stem-loop	GCAAUAAUUACCGGGCAAUUACUCCUUUGGCAGCUGGCCACUCAACGGCGGCAGGUGAUCAAAUUCACCAAUGCAAACAAGUAAGCUCGCUGCCAAAGGAGAUUUGCCCCGCAAUUCAUC		26
17252	MI0002339	ptc-MIR399b	Populus trichocarpa miR399b stem-loop	GGUGCAGUUGCAUUACAGGGCAAGCUUCCAUUGGCAUGCAGCCACUAAGACACGCAAUAUCUAACACUUGAUGCAUUCCUGUAGAGUGCGGCGCCAUGCCAAAGGAGAUUUGCCCGGCAAUUCUUC		26
17253	MI0002340	ptc-MIR399c	Populus trichocarpa miR399c stem-loop	GGUGCAGUUGCAUUACAGGGCAAGCUUCCAUUGGCAUGCAGCCACUAAGACACGCAAUAUCUAACACUUGAUGCAUUCCUGUAGAGUGCGGCGCCAUGCCAAAGGAGAUUUGCCCGGCAAUUCUUC		26
17254	MI0002341	ptc-MIR399d	Populus trichocarpa miR399d stem-loop	GGAUGCAUUACUGGGCAAUUCUUCUGUUGGCAGCUGGUGACUCAUACUGCACUAGCUGAGAUUAAGCAGCAAGAGUUUGCUCACUGCCAAAGAAGAUUUGCCCCGCAAUUCCUU		26
17255	MI0002342	ptc-MIR399e	Populus trichocarpa miR399e stem-loop	GGAUGCAUUACUGGGCAAUUCUUCUGUUGGCAGUUGGUGACUCAUACUGCACUAGCUGAGAUUAAGCAGCAAGAGUUUGCUCACUGCCAAAGAAGAUUUGCCCCGCAAUUCAUU		26
17256	MI0002343	ptc-MIR399f	Populus trichocarpa miR399f stem-loop	UAAAGAAUAACAGGGCUUUAUCCUCCUUUGGCAAACAGAACAUGGAAAUAAAUGCCUGCAUAUUUCUGUUUUGCCAAAGGAGAAUUGCCCUGCCAUUCGAU		26
17257	MI0002344	ptc-MIR399g	Populus trichocarpa miR399g stem-loop	UGAUGAAUAACUGUGCAAUUCUCCUUUGGCAGACGUAUAUGGCGUUCGGACACCAACUUUGGACUGCCAAAGGAGAAUUGCCCUGCCAUUCAAC		26
17258	MI0002345	ptc-MIR399h	Populus trichocarpa miR399h stem-loop	AAACCAGUUGCAGGGCACCUCUCUUCCUUGGCAGACAGUACUAAUGGUGCCUAUAGCUUCAAGCUGAGAGGGUAUGCGAGAAUCUUGAUCCCAAUAUAGGCUUGCCAAAGGAGAGUUUCCCUGUGACCGUUU		26
17259	MI0002346	ptc-MIR399i	Populus trichocarpa miR399i stem-loop	AAACCAGUUGUAGGGUACCUCUUACUUGGCAAGCAAUGGUGAUUGUUGCAAACAUUGCAGAAUUUGAUCUCGGUGUCUUGCCAAAGGAGAGUUGCCCUAUGACUGUUU		26
17260	MI0002347	ptc-MIR399j	Populus trichocarpa miR399j stem-loop	UGCAUUACAGGGCAAGACCUCCAUUGGCAGGCAGCCACUAAAGCAUGCAUUUAAAUUAUGCGUUCUUUUAAGUGUGCCCUCUGCCAAAGGAGAUUUGUCCGGCAAAUCUUCU		26
17261	MI0002348	ptc-MIR399k	Populus trichocarpa miR399k stem-loop	GGAGCAUUGCUGAGCAAAUUUCCUUUGGCAGAUACCAUAAGUAACAAGAGCUUAUGUUGUUCAUUUGCCAAAGGAGAUUUGCUCACCAAUUCCA		26
17262	MI0002349	ptc-MIR399l	Populus trichocarpa miR399l stem-loop	AACUAGUUAAAUGGCUUCUCUUCUUUGGCAGGUGAUGGUAUAGAUUACAACUUAUAGCUUUAAUCUAGUAUUCAGUUACCCGCCAAAGGAGAGUUGCCCUCUAACUUCC		26
17263	MI0002350	ptc-MIR403a	Populus trichocarpa miR403a stem-loop	AGGCAUAUUUCAGGUUUGUGCAUGAAUCUAAUAUAGCUAAAAAAAUCCCAUCAAACACAAAUUAAAAUACUAGAUAGCAAUCAGCACUAGUUUAGUAUAGUAUUAGAUUCACGCACAAACUCGUAAUCUGUC		26
17264	MI0002351	ptc-MIR403b	Populus trichocarpa miR403b stem-loop	ACUCAUAUCUCUAGUUUGUUCGUGGAUCUGACGCCAUCACAACCGUUCAUUUCACGACCAUCCAAUGGCGUUAGAUUCACGCACAAACUCGCGAUCUGUC		26
17265	MI0002352	ptc-MIR408	Populus trichocarpa miR408 stem-loop	AGAGACAGAUGAAGACGGGGAACAGGCAGAGCAUGGAUGGAGCUACUAACAGAAGUACUUGUUUUGGCUCUACCCAUGCACUGCCUCUUCCCUGGCUUGUGGCUC		26
17266	MI0002354	ptc-MIR472a	Populus trichocarpa miR472a stem-loop	UUAUCGGGUGGGUGAGCGGGGAAGAUAACUUUGGUUUUUGAGAUAGUACUUGUUAUUUUCCCUACUCCACCCAUCCCAUAG		26
17267	MI0002355	ptc-MIR472b	Populus trichocarpa miR472b stem-loop	UUACUGGAUGGGUGAGUGGGGAAGAUAACUAAGCUCUGUUUGUUAUUUUCCCAACUCCACCCAUCCCAUAG		26
17268	MI0002356	ptc-MIR473a	Populus trichocarpa miR473a stem-loop	AUUGUUCACUCUCCCUCAAGGCUUCCAACGCAAUAACCAGCUACGUACAUGUAACUGUGUUACGGCUGCAGGCUUGAGGCCUUUGGGGGAGAGUGGUCAA		26
17269	MI0002357	ptc-MIR473b	Populus trichocarpa miR473b stem-loop	UGCUCGCUCUCCCUCAGGGCUUCCAACGCAGUAAGCAGGUACGUGCAUGUCAGCAUAUUCUCGCUGCAGGCUCGAGGUCUUUGGUGAGAGUAGUGAUCAA		26
17270	MI0002358	ptc-MIR474a	Populus trichocarpa miR474a stem-loop	UCCAAAAGUUGCUGGGUUUGGCUGGGCAGGCGGACCCAAUGCUAUUGGGUUCAGCAGGACCCAACACUUCUUUCCUUCUCUUCUAUCACCAGCACCCUUUGAAA		26
17271	MI0002359	ptc-MIR474b	Populus trichocarpa miR474b stem-loop	UUCAAAAGUUGUUGGGUUUGGCUGGGCAGCCAGAUCCAGUGCUAUUGGGUCCUGUUAGACAACGCUAUUUGGUCUUGUCAAGCUAGAUCCAACAUUACUUUUUGACU		26
17272	MI0002360	ptc-MIR474c	Populus trichocarpa miR474c stem-loop	GACAGUAAAGCUACAUCCAAUAGUCCUGGAUUCUGGUCAAUAAGUGCAAAAGCUGUUGGGUUUGGCUGGGCAGCU		26
17273	MI0002361	ptc-MIR475a	Populus trichocarpa miR475a stem-loop	CAUCUUGAUCAAUGGCCAUUGUAAGAGUAGAAGGAUCCAUGAAGCAAUAACUCUCUUUGCUAAAAUGUGUGAUAAAACAUUGACUCCUGGUAUUUCACUCUUACAGUGCCCAUUGAUUAAGAUG		26
17274	MI0002362	ptc-MIR475b	Populus trichocarpa miR475b stem-loop	AUCUUGAUCAAUGGCCAUUGUAAGAGUAGAAGGAUCCAUGAAGCAAUAACUCUCUUUGCUGAAAUGUGCGACCAAAUAGACUCUUGAUAUUUCAUUCUUACAGUGCCCAUUGAUUAAGAU		26
17275	MI0002363	ptc-MIR475c	Populus trichocarpa miR475c stem-loop	UAACAUCUUGAACAAUGGCCAUUGUAAGAGUAAGUGGUCCAUGAGUCAAUAACUCUCUUUGCAGAAAUGCAUGACAAAGCAUUGACUCCUAUUUCACCCUUACAAUGUCCAUUGAUUAAGAGGUU		26
17276	MI0002364	ptc-MIR475d	Populus trichocarpa miR475d stem-loop	AUAACAUCCUGAUCAAUGGCCAUUGUAAGAGUAGAAGGAUCCAUGAAGCAAAACAUUGACUCCUGAUAUUCCACUCUUACAGAGUCCAUUGAUUAAGAUGUUA		26
17277	MI0002365	ptc-MIR476a	Populus trichocarpa miR476a stem-loop	UUAAGCUAGUAAUCCUUCUUUGCAAAGUCAUUUAUUAUUUUUCCUUCAAUUACUAUAAUCAAUGACUUUGCAAAGAUAGAUUUACUAGCUAAAUCU		26
17278	MI0002366	ptc-MIR476b	Populus trichocarpa miR476b stem-loop	GCUAGUAAUUCUUCUUUGCAAAAUCAUUAAUUAUCCUAGCUCUAAUUACUAUAAUUAAUGGCUUUGCAAAGAUAGAUUUACUAGCUAAAUCUU		26
17279	MI0002367	ptc-MIR476c	Populus trichocarpa miR476c stem-loop	GCUAGUAAUUCUUCUUUGCAAAAUCAUUAAUUAUCCUAGCUCUAAUUACUAUAAUUAAUGGCUUUGCAAAGAUAGAUUUACUAGCUAAAUCUU		26
17280	MI0002368	ptc-MIR477a	Populus trichocarpa miR477a stem-loop	CAAUCUCCCUCAGAGGCUUCCAAUAUCUCAGUUUAUAGUAAUUGCUUCAAAUAACGAGAAUGUUGGAUGCCUUUGGGGGAGAUUG		26
17281	MI0002369	ptc-MIR477b	Populus trichocarpa miR477b stem-loop	CAAUCUCCCUCAGAGGCUUCCAAUAUCUCAGUUUAUAGUAAUUGCUUCAAAUAAUGAGAAUGUUGGAUGCCUUUGGGUGAGAUUG		26
17282	MI0002370	ptc-MIR478a	Populus trichocarpa miR478a stem-loop	CUCCCUUUUAGGGUUAAAACGUCAACAUUUUAGACGAGUCUCUUAUUUUUAGGGACUGGUGUUAUUUUUUGACGUGUCUUCUAUUUUUAGGGACUG		26
17283	MI0002371	ptc-MIR478b	Populus trichocarpa miR478b stem-loop	UCUCCCUUUUAGGGUUAAAACGUCAACAUUUUAGACGAGUCUCCUAUUUUUAGGGACUGGUGUUAUUUUUUGACGUGUCUUCUAUUUUUAGGGACC		26
17284	MI0002372	ptc-MIR478c	Populus trichocarpa miR478c stem-loop	UCUCCUUUUUAGGGUUAAAUGUCAAUAUUUUAGACGAGUUUUCUAUUUUUAGGGUCUGGUGUUAUUUUUUGACGUGUCUUCUAUUUUUAGGGACC		26
17285	MI0002373	ptc-MIR478d	Populus trichocarpa miR478d stem-loop	AUCCUAAUCUAUAAGUCUCCUAUUUUUAGAGAUGGACGUUAACUUUUUUGUGAAUAGCCUAGUUGACGUGUCUUCUAUUUUUAGGAACCAAGAAUG		26
17286	MI0002374	ptc-MIR478e	Populus trichocarpa miR478e stem-loop	GAGUCUUCUAUCUUUAAGAACGGACAUCAUAUUUCUCGUGAAUGGUCUAAUUGACGAGUCUUCUAUUUUUAGGGAUAGACACUAG		26
17287	MI0002375	ptc-MIR478f	Populus trichocarpa miR478f stem-loop	AAGUAUCUUAUUUUUAGGAGCCGAUGUCAUUUUUUUGACAUGUCUUCUAUUUUUAGGGACCGA		26
17288	MI0002376	ptc-MIR478h	Populus trichocarpa miR478h stem-loop	UCUCCUUUUUAGGGACAAACGUCAAUAUUUUAGACGAGUCUCCUAAUUUUUAGGGACUGGUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17289	MI0002377	ptc-MIR478i	Populus trichocarpa miR478i stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17290	MI0002378	ptc-MIR478j	Populus trichocarpa miR478j stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17291	MI0002379	ptc-MIR478k	Populus trichocarpa miR478k stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17292	MI0002380	ptc-MIR478l	Populus trichocarpa miR478l stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17293	MI0002381	ptc-MIR478m	Populus trichocarpa miR478m stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17294	MI0002382	ptc-MIR478n	Populus trichocarpa miR478n stem-loop	AGUCUCCUAAUUUUUAGGGACUGAUGUUAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17295	MI0002383	ptc-MIR478o	Populus trichocarpa miR478o stem-loop	UCUCCUUUUUAGGAAUAAACGUUAAUAUUUUAGACGAGUCUCCUAAAUUUUAGGGACUGAUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17296	MI0002384	ptc-MIR478p	Populus trichocarpa miR478p stem-loop	UCUCCUUUUUUGGGACAAACGUUAAUAUUUUAGACGAGUCUCCUAAUUUUUAGGGACUAAUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17297	MI0002385	ptc-MIR478q	Populus trichocarpa miR478q stem-loop	UCUCCUUUUUAGGGAUAAACGUUAAUGUUUUAGACGAGUCUCCUAAAUUUUAGGGACUAAUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17298	MI0002386	ptc-MIR478r	Populus trichocarpa miR478r stem-loop	AGUCUCCUAGUUUGAGGGACUGAUAUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17299	MI0002387	ptc-MIR478s	Populus trichocarpa miR478s stem-loop	UCUCAUUUUUAGGGAUAAACGUUAAUGUUUUAGACGAGUCUCCUAAAUUUUAGGGACUAAUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17300	MI0002388	ptc-MIR478u	Populus trichocarpa miR478u stem-loop	UCUCCUUUUUAGGGAUAAACGUUAAUAUUUUAGACGAGUCUCCUAAUUUUUAGGGACUGAUGUCAUUUUUAACGUGUCUCCUAUUUUUAGGGACC		26
17301	MI0002389	ptc-MIR479	Populus trichocarpa miR479 stem-loop	GGUGUGAUAUUGGUCCGGCUCAUCUUCUGUGCAUAAGCAUCUGAAGUUCUUCACUCAUGAAGACGAGCCGAAUCAAUAUCACUCU		26
17302	MI0002390	ptc-MIR480a	Populus trichocarpa miR480a stem-loop	UAAUAUGUUUGGGGUUGAUCCUUGUUUAGUUAUAAUAGACCCACACCUGACUGCUUAGAAUUAUUUGUUAUCGCAUAUCCGACUACAUUAUUGACGUUGAAAAACAGAGAACUACUACAUCAUUGACGUUGAACCAUAAA		26
17303	MI0002391	ptc-MIR480b	Populus trichocarpa miR480b stem-loop	UAAUAUGUUUGGGGUUGAUCCUUGUUUAGUUAUAAUAGACCCACACCUGACUGCUUAGAAUUAUUUGUUAUCGCCUAUCCGACUACAUUAUUGACGUUGAAAAACAGAGAACUACUACAUCAUUGAUGUUGAACCAUAAA		26
17304	MI0002392	ptc-MIR481a	Populus trichocarpa miR481a stem-loop	GAAGGUUAAGUGUGUUGGGGUAGUGGAGAUGGUCAAAGAUGUUAGAGAAUAAUAUAAAUCAUAUCCUAGGACCUCACUUAACAGCUUAAGCUA		26
17305	MI0002393	ptc-MIR481b	Populus trichocarpa miR481b stem-loop	AUCCUAGGACCUCACUUAACAGCUUAAGCUAUUGGGUUGAGAUGGUUCUUUGACAUGAUAUCAGAGCCUUGAUAACCAAGUGGUCUCGAGUUUGAAUCUCAUCAUCCUCAUUUAUUUGAUAAAAAAUACUUAAAGGGGUGUGUUAGAGAAUAAUAUAAAUCAUAUUCUGGAACCUCACCUAACAGCUUAAGCUAUUGGGUUGAAAUGAUUCUUUGACAUU		26
17306	MI0002394	ptc-MIR481c	Populus trichocarpa miR481c stem-loop	AUCCUAGGACCUCACUUAACAGCUUAAGCUUUUGGGUUGAGAUGAUUCUUUGACAUGAUAUCAGAGCUUUGAUGACCAAGCGGUCACGAGUUCGAAUCUCACCAUCCCCAUUUAUUUGAUAAAAUUAAGCACAAGGUAAUGUGAGUCUGUGCAAGUUUCAAGCCCAAAGAGCUUUCACUUGAGGGGGUGUGUUAG		26
17307	MI0002395	ptc-MIR481d	Populus trichocarpa miR481d stem-loop	GGCAGUCAAAGAGGGGGCAAGGAAAGGGGAGAAUUAUGUUACUGUCACUUGGCUGUUAUUCGUAGAACUAGAAUGACAUUGAGGGUGUUAGAGAAUAAUAUAAAUCAUAUUCUAAGACCUCACCUAACAGCUUAAGCUAUU		26
17308	MI0002396	ptc-MIR481e	Populus trichocarpa miR481e stem-loop	AUCCUAGGACCUCACCUAACAGCUUAAGCUAUUGGGUUGAGAUGAUUCUUUGACAUGGUAUCAGAGCCUUGAUGACCAAGUGGUCACGAGUUCGAAUCUCACCACUCCUAUUUAUUUGAUAAAAAUCAAGCACAAGGUAAUGUGGGCCUAUGCAAGUUUCAAGCCCAAAGAGCUUUCACUUGAGGGGGUGUAUUAG		26
17309	MI0002397	ptc-MIR482	Populus trichocarpa miR482 stem-loop	UCUUUGGAGAUGGGAGAGUAUGCAAGAAGGAAAAAUUCAUGAUUUAAUAUUCUUUCUUGCCUACUCCUCCCAUUCCAUCUG		26
17310	MI0002398	mmu-mir-463	Mus musculus miR-463 stem-loop	CUUUACCUAAUUUGUUGUCCAUCAUGUAAAACAUAAAUGAUGAUAGACACCAUAUAAGGUAGAGGAAGGUUCACU	Yu et al. cloned a product from the 5' arm of this precursor, and named it miR-463 [1].  Landgraf et al. later show that the 3' product is the predominant one [2].  The 5' miRNA is renamed miR-463* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
17311	MI0002399	mmu-mir-464	Mus musculus miR-464 stem-loop	ACCUUGUUAUGGGGGUCUGGGGUAAGGAGUGGUCAUCAGGGGGUACUACCAAGUUUAUUCUGUGAGAUAGA		6
17312	MI0002400	mmu-mir-465a	Mus musculus miR-465a stem-loop	GCCCUAUUUAGAAUGGCACUGAUGUGAUAAAAUAAAAAAUUGAUCAGGGCCUUUCUAAGUAGAGUAAGGCUUAC	Yu et al. identified a mature miRNA product from the 5' arm of this precursor, renamed miR-465a-5p here [1].  Watanabe et al. later reported a 3' miRNA product [2]. 	6
17313	MI0002401	mmu-mir-466a	Mus musculus miR-466a stem-loop	UAUAUGUGUUUAUGUGUGUGUACAUGUACAUAUGUGAAUAUGAUAUCCAUAUACAUACACGCACACAUAAGAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	6
17314	MI0002402	mmu-mir-467a	Mus musculus miR-467a stem-loop	CUGUGUGCGUAAGUGCCUGCAUGUAUAUGCGUGUAUAUUUUAUGCAUAUACAUACACACACCUACACACACAU	The sequence of miR-467 is of low complexity.  The sequence maps exactly to several genomic positions, and many more with 1 or 2 substitutions. Confidence in this miRNA might therefore be reduced.  Landgraf et al. show that the 5' mature miRNA is the predominant one, in contrast with previous annotations [3].  The 3' miRNA is renamed miR-467* here. 	6
17315	MI0002403	mmu-mir-468	Mus musculus miR-468 stem-loop	AUAAGAAACUUGGCGUGUCGUGACUGAUGUACUGAUAAGAAACUCAGUGUGAUAUGACUGAUGUGCGUGUGUCUGUCU		6
17316	MI0002404	mmu-mir-469	Mus musculus miR-469 stem-loop	CGCGGUGCCUCUUUCAUUGAUCUUGGUGUCCUCAAAUUGAAAGCCAAGGAAGAGGUGGGGGGCGUGGUAGCCUU		6
17317	MI0002405	mmu-mir-470	Mus musculus miR-470 stem-loop	CAGUGCUCUUCUUGGACUGGCACUGGUGAGUUAAACUAAAUACAACCAGUACCUUUCUGAGAAGAGUAAAGCUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
17318	MI0002406	mmu-mir-471	Mus musculus miR-471 stem-loop	GUGCUUUACGUAGUAUAGUGCUUUUCACAUUAAACAAAAAGUGAAAGGUGCCAUACUAUGUAUAGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
17319	MI0002407	ath-MIR447a	Arabidopsis thaliana miR447a stem-loop	CAUUCUUAAUAUAUAAUACUACUUUUUCAUCCAUUAAACCCCUUACAAUGUCGAGUAAACGAAGCAUCUGUCCCCUGGUAUUGUCUUCGAGCUUGGUGUUUUUUUCUAGCCAACUCCAAGUUCUCGAGUUGAUCAUUGUUUGUAUUCUUGAGACAUUAUUUGGGGACGAGAUGUUUUGUUGACUCGAUAUAAGAAGGGGCUUUAUGGAAGAAAUUGUAGUAUUAUAUAUCGAGAGUG		1
17320	MI0002408	ath-MIR447b	Arabidopsis thaliana miR447b stem-loop	CAUUCUUAAUAUACAAUACUACUUUUUCAUCCAUUAAUCCCCUUACAAUGUCGAGUAAACGAAGCAUCUGUCCCCUGGUAUUGUCUUCGAGCUUGGUGUGUUUUUCUAGCCAGCCCCAAGUUCUCGAGUUGAUCAUUGUUUGUAUUCUGACACAUUAUUUGGGGACGAGAUGUUUUGUUGACUCGAUAUAAGAAGGGGCUUUAUGGAAGAAAUUGUAGUAUUAUAUAUUGAGAAUG		1
17321	MI0002409	ath-MIR447c	Arabidopsis thaliana miR447c stem-loop	CAUUCUUAAUAUACAAUACUUCUUUUUCAUGCAUUAAGCCCCUUACAAUGUCGAGUAAACAAAGCAUGUGUCCGCUAAUAUUGUCUUCGAGCUUGGUAUUUUUGUAUUCUGAUACGGUAUUUGGGGACGACAUCUUUUGUUGACUCGAUAUAAGAAGGGGGUUUGUGGAAGAAAUUGUAGUAUUAUAUAUCAAGAAUG		1
17322	MI0002410	ssc-mir-105-1	Sus scrofa miR-105-1 stem-loop	UGUGCAUCGUAGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA		27
17323	MI0002411	ssc-mir-105-2	Sus scrofa miR-105-2 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUUGGUGGCUGCUUAUGCACCACGGAUGUUUGAGCAUGUGCUAUGGUGUCUA		27
17324	MI0002412	ssc-mir-106a	Sus scrofa miR-106a stem-loop	CCUUGGCCGUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG		27
17325	MI0002413	ssc-mir-122	Sus scrofa miR-122 stem-loop	CCUUAGCAGAGCUGUGGAGUGUGACAAUGGUGUUUGUGUCCAAACUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGUUAGGC		27
17326	MI0002414	ssc-mir-125b	Sus scrofa miR-125b stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA		27
17327	MI0002415	ssc-mir-135-1	Sus scrofa miR-135-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCAUUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACA		27
17328	MI0002416	ssc-mir-135-2	Sus scrofa miR-135-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA		27
17329	MI0002417	ssc-mir-145	Sus scrofa miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUGAGAUGGGGAUUCCUGUAAAUACUGUUCUUGAGGUCAUGG		27
17330	MI0002418	ssc-mir-148a	Sus scrofa miR-148a stem-loop	GAGGCAAAGUUCUGAGACACUCCGACUCUGAAUAUGAUAGAAGUCAGUGCACUACAGAACUUUGUCUC		27
17331	MI0002419	ssc-mir-15b	Sus scrofa miR-15b stem-loop	UUGAGGCCUUAAAGUACUGCCGCAGCACAUCAUGGUUUACAUACUACAAUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU		27
17332	MI0002420	ssc-mir-181b	Sus scrofa miR-181b stem-loop	AUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGAGUCUGAAUCAACUCACUGAUCAAUGAAUGCAAACUGCGGACCAAACA		27
17333	MI0002421	ssc-mir-184	Sus scrofa miR-184 stem-loop	CCAGUCACAUCCCCUUAUCACUUUUCCAGCCAGCUUUGUGACUCUAAAUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA		27
17334	MI0002422	ssc-mir-19a	Sus scrofa miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC		27
17335	MI0002423	ssc-mir-20	Sus scrofa miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC		27
17336	MI0002424	ssc-mir-216	Sus scrofa miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCCCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUUGCCCU		27
17337	MI0002425	ssc-mir-217	Sus scrofa miR-217 stem-loop	AUAAUUAUUACAGAGUUUUUGAUGUCGCAGAUACUGCAUCAGGAACUGAUUGGAUAAGAAUUGGUCACCAUCAGUUCUUAAUGCAUUGCCUUCAGCAUCUAAACAAG		27
17338	MI0002426	ssc-mir-224	Sus scrofa miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAAGGUUUUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC		27
17339	MI0002427	ssc-mir-23a	Sus scrofa miR-23a stem-loop	CGGCUGGGGUUCCUGGGGAUGGGAUUUGCUGCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAAUCGACC		27
17340	MI0002428	ssc-mir-24	Sus scrofa miR-24 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGAUUUGUGCAGACUGGCUCAGUUCAGCAGGAACAGG		27
17341	MI0002429	ssc-mir-26a	Sus scrofa miR-26a stem-loop	GGCUGUGGCUGGAUUCAAGUAAUCCAGGAUAGGCUGUUUCCAUCUGUGAGGCCUAUUCUUGAUUACUUGUUUCUGGAGGCAGCU		27
17342	MI0002430	ssc-mir-28	Sus scrofa miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACACUCUAUUGAGUUGCCUUUCUGUCUUCCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU		27
17343	MI0002431	ssc-mir-29b	Sus scrofa miR-29b stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAAAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG		27
17344	MI0002432	ssc-mir-301	Sus scrofa miR-301 stem-loop	GCUAACAAAUGCUCUGACUUUAUUGCACUACUGUACUUUACAGCUACCAGUCCAAUAGUAUUGUCAAAGCAUCUGAGAGCAG		27
17345	MI0002433	ssc-mir-323	Sus scrofa miR-323 stem-loop	UUGGUACUUGGAGAGAGGUGGUCCGUGGCGCGUUCGCUUUAUUUAUGGCGCACAUUACACGGUCGACCUCUUUGCGGUAUCUAAUC		27
17346	MI0002434	ssc-mir-326	Sus scrofa miR-326 stem-loop	UCUGUCUGUUGGGCUGGAGGCAGGGCCUUUGUGCAGGCGGGUUGUGCUCAGAUCGCCUCUGGGCCCUUCCUCCAGCCCAGAGGCGGAUUCA		27
17347	MI0002435	ssc-mir-7	Sus scrofa miR-7 stem-loop	UGGAUGUUGGUCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG		27
17348	MI0002436	ssc-mir-95	Sus scrofa miR-95 stem-loop	AACACAGUGGGCGCUCAAUAAAUGUUUGUUGAAUUGAGAUGCGUUAAAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG		27
17349	MI0002437	ssc-mir-140	Sus scrofa miR-140 stem-loop	CCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGG		27
17350	MI0002438	ssc-mir-181c	Sus scrofa miR-181c stem-loop	CAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCCGAGGCCUGGA		27
17351	MI0002439	ssc-mir-183	Sus scrofa miR-183 stem-loop	CUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAACAG		27
17352	MI0002440	ssc-mir-205	Sus scrofa miR-205 stem-loop	CUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGCUCAGGAG		27
17353	MI0002441	ssc-mir-214	Sus scrofa miR-214 stem-loop	GGCCUGGCUGGACGGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU		27
17354	MI0002442	ssc-mir-27a	Sus scrofa miR-27a stem-loop	UGGCCUGGGGAGCAGGGCUUAGCUGCUUGUGAGCAGGUCCACAGCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCUGGA		27
17355	MI0002443	ssc-mir-32	Sus scrofa miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAGUGCAAUUUAGUGUGUGUGAUAUUUUC		27
17356	MI0002444	ssc-mir-325	Sus scrofa miR-325 stem-loop	AGUGCUUGGUUCCUAGUAGGUGUUCAGUAAGUGUUUGUGACAUAAUUCGUUUAUUGAGCACCUCCUAUCAAUCAAGCACUGUGCUAGGUUCUGG		27
17357	MI0002445	ssc-let-7c	Sus scrofa let-7c stem-loop	UGUGUGCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCGUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGCACACU		27
17358	MI0002446	ssc-let-7f	Sus scrofa let-7f stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		27
17359	MI0002447	ssc-let-7i	Sus scrofa let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUAG		27
17360	MI0002448	ssc-mir-103	Sus scrofa miR-103 stem-loop	CUUACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCACUGAG		27
17361	MI0002449	ssc-mir-107	Sus scrofa miR-107 stem-loop	UUCUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGAGAGC		27
17362	MI0002450	ssc-mir-124a	Sus scrofa miR-124a stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAGUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG		27
17363	MI0002451	ssc-mir-128	Sus scrofa miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC		27
17364	MI0002452	ssc-mir-136	Sus scrofa miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUACGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU		27
17365	MI0002453	ssc-mir-139	Sus scrofa miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCAGGCCAUGUUGGAGUAAC		27
17366	MI0002454	ssc-mir-153	Sus scrofa miR-153 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG		27
17367	MI0002455	ssc-mir-18	Sus scrofa miR-18 stem-loop	GUGCUUUUUGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCAUAAGAAGUUAUGU		27
17368	MI0002456	ssc-mir-186	Sus scrofa miR-186 stem-loop	UGCUUAUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUAUGAUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUG		27
17369	MI0002457	ssc-mir-196	Sus scrofa miR-196 stem-loop	UUGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUAUCGUCGAGGGC		27
17370	MI0002458	ssc-mir-204	Sus scrofa miR-204 stem-loop	GGCUACAGUCCUUCUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC		27
17371	MI0002459	ssc-mir-21	Sus scrofa miR-21 stem-loop	UGUACCACCUUGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUCUGACAUUUUGGUAUC		27
17372	MI0002460	ssc-mir-29c	Sus scrofa miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUANGGGGA		27
17373	MI0002461	ssc-mir-30c	Sus scrofa miR-30c stem-loop	GACAGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUCUCUGCCUU		27
17374	MI0002462	ssc-mir-9-1	Sus scrofa miR-9-1 stem-loop	CGGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA		27
17375	MI0002463	ssc-mir-9-2	Sus scrofa miR-9-2 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA		27
17376	MI0002464	hsa-mir-412	Homo sapiens miR-412 stem-loop	CUGGGGUACGGGGAUGGAUGGUCGACCAGUUGGAAAGUAAUUGUUUCUAAUGUACUUCACCUGGUCCACUAGCCGUCCGUAUCCGCUGCAG		5
17377	MI0002465	hsa-mir-410	Homo sapiens miR-410 stem-loop	GGUACCUGAGAAGAGGUUGUCUGUGAUGAGUUCGCUUUUAUUAAUGACGAAUAUAACACAGAUGGCCUGUUUUCAGUACC		5
17378	MI0002466	hsa-mir-376b	Homo sapiens miR-376b stem-loop	CAGUCCUUCUUUGGUAUUUAAAACGUGGAUAUUCCUUCUAUGUUUACGUGAUUCCUGGUUAAUCAUAGAGGAAAAUCCAUGUUUUCAGUAUCAAAUGCUG	The mature miR-376b products have been shown to be modified by A to I edits [2]. 	5
17379	MI0002467	hsa-mir-483	Homo sapiens miR-483 stem-loop	GAGGGGGAAGACGGGAGGAAAGAAGGGAGUGGUUCCAUCACGCCUCCUCACUCCUCUCCUCCCGUCUUCUCCUCUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
17380	MI0002468	hsa-mir-484	Homo sapiens miR-484 stem-loop	AGCCUCGUCAGGCUCAGUCCCCUCCCGAUAAACCCCUAAAUAGGGACUUUCCCGGGGGGUGACCCUGGCUUUUUUGGCG		5
17381	MI0002469	hsa-mir-485	Homo sapiens miR-485 stem-loop	ACUUGGAGAGAGGCUGGCCGUGAUGAAUUCGAUUCAUCAAAGCGAGUCAUACACGGCUCUCCUCUCUUUUAGU		5
17382	MI0002470	hsa-mir-486	Homo sapiens miR-486 stem-loop	GCAUCCUGUACUGAGCUGCCCCGAGGCCCUUCAUGCUGCCCAGCUCGGGGCAGCUCAGUACAGGAUAC		5
17383	MI0002471	hsa-mir-487a	Homo sapiens miR-487a stem-loop	GGUACUUGAAGAGUGGUUAUCCCUGCUGUGUUCGCUUAAUUUAUGACGAAUCAUACAGGGACAUCCAGUUUUUCAGUAUC		5
17384	MI0002472	kshv-mir-K12-10a	Kaposi sarcoma-associated herpesvirus miR-K12-10a stem-loop	CUGGAGGCUUGGGGCGAUACCACCACUCGUUUGUCUGUUGGCGAUUAGUGUUGUCCCCCCGAGUGGCCAG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17385	MI0002473	kshv-mir-K12-10b	Kaposi sarcoma-associated herpesvirus miR-K12-10b stem-loop	CUGGAGGCUUGGGGCGAUACCACCACUCGUUUGUCUGUUGGCGAUUGGUGUUGUCCCCCCGAGUGGCCAG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [3]. 	16
17386	MI0002474	kshv-mir-K12-11	Kaposi sarcoma-associated herpesvirus miR-K12-11 stem-loop	CGCUUUGGUCACAGCUUAAACAUUUCUAGGGCGGUGUUAUGAUCCUUAAUGCUUAGCCUGUGUCCGAUGCG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Pfeffer et al. [1].  The names were corrected in release 7.0.  In addition, Samols et al. incorrectly named this sequence miR-6 [2].  Cai et al. define the likely miRNA primary transcripts [3]. 	16
17387	MI0002475	kshv-mir-K12-1	Kaposi sarcoma-associated herpesvirus miR-K12-1 stem-loop	CGAUUACAGGAAACUGGGUGUAAGCUGUACAUAAUCCCCGGCAGCACCUGUUUCCUGCAACCCUCGU	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17388	MI0002476	kshv-miR-K12-2	Kaposi sarcoma-associated herpesvirus miR-K12-2 stem-loop	GGGUCUACUUCGCUAACUGUAGUCCGGGUCGAUCUGAGCCAUUGAAGCAAGCUUCCAGAUCUUCCAGGGCUAGAGCUGCCGCGGUGACACC	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. [1].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [2]. 	16
17389	MI0002477	kshv-mir-K12-9	Kaposi sarcoma-associated herpesvirus miR-K12-9 stem-loop	GGGUCUACCCAGCUGCGUAAACCCCGCUGCGUAAACACAGCUGGGUAUACGCAGCUGCGUAAACCC	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17390	MI0002478	kshv-mir-K12-8	Kaposi sarcoma-associated herpesvirus miR-K12-8 stem-loop	CGCGCACUCCCUCACUAACGCCCCGCUUUUGUCUGUUGGAAGCAGCUAGGCGCGACUGAGAGAGCACGCG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17391	MI0002479	kshv-mir-K12-7	Kaposi sarcoma-associated herpesvirus miR-K12-7 stem-loop	GCGUUGAGCGCCACCGGACGGGGAUUUAUGCUGUAUCUUACUACCAUGAUCCCAUGUUGCUGGCGCUCACGG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17392	MI0002480	kshv-mir-K12-6	Kaposi sarcoma-associated herpesvirus miR-K12-6 stem-loop	CUUGUCCAGCAGCACCUAAUCCAUCGGCGGUCGGGCUGAUGGUUUUCGGGCUGUUGAGCGAG	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  In addition, Samols et al. incorrectly named this sequence miR-5 [3].  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17393	MI0002481	kshv-mir-K12-5	Kaposi sarcoma-associated herpesvirus miR-K12-5 stem-loop	UGACCUAGGUAGUCCCUGGUGCCCUAAGGGUCUACAUCAAGCACUUAGGAUGCCUGGAACUUGCCGGUCA	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  In addition, Samols et al. incorrectly named this sequence miR-4 [3].  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17394	MI0002482	kshv-mir-K12-4	Kaposi sarcoma-associated herpesvirus miR-K12-4 stem-loop	AUAACUAGCUAAACCGCAGUACUCUAGGGCAUUCAUUUGUUACAUAGAAUACUGAGGCCUAGCUGAUUAU	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  In addition, Samols et al. incorrectly named this sequence miR-3 [3].  Cai et al. define the likely miRNA primary transcripts [4]. 	16
17395	MI0002483	kshv-mir-K12-3	Kaposi sarcoma-associated herpesvirus miR-K12-3 stem-loop	GGCUAUCACAUUCUGAGGACGGCAGCGACGUGUGUCUAACGUCAACGUCGCGGUCACAGAAUGUGACACC	Please note that the names of KSHV miRNAs in release 6.0 did not correctly relate to those published in Cai et al. and Pfeffer et al. [1,2].  The names were corrected in release 7.0.  In addition, Samols et al. incorrectly named this sequence miR-2 [3].  Cai et al. define the likely miRNA primary transcripts [4].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5].  The ends of the miRNA may be offset with respect to previous annotations. 	16
17396	MI0002484	mml-mir-200c	Macaca mulatta miR-200c stem-loop	CCCUCGUCUUACCCAGCAGUGUUUGGGUGCGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17397	MI0002485	mml-mir-141	Macaca mulatta miR-141 stem-loop	UGGCCGGCCCUGGGUCCAUCUUCCAGUACAGUGUUGGAUGGUCUAAUUGUGAAGCUCCUAACACUGUCUGGUAAAGAUGGCCCCCGGGUCGGUUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17398	MI0002486	ggo-mir-200c	Gorilla gorilla miR-200c stem-loop	CCUCGUCUUACCCAGCAGUGUUUGGGUGCGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17399	MI0002487	ggo-mir-141	Gorilla gorilla miR-141 stem-loop	CGGCCGGCCCUGGGUCCAUCUUCCAGUACAGUGUUGGAUGGUCUAAUUGUGAAGCUCCUAACACUGUCUGGUAAAGAUGGCCCCCGGGUGGGUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17400	MI0002488	ppy-mir-200c	Pongo pygmaeus miR-200c stem-loop	CCCUCGUCUUACCCAGCAGUGUUUGGGUGCGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17401	MI0002489	ppy-mir-141	Pongo pygmaeus miR-141 stem-loop	UGGCCGGCCCUGGGUUCAUCUUCCAGUACAGUGUUGGAUGGUCUAAUUGUGAAGCUCCUAACACUGUCUGGUAAAGAUGGCCCCCGGGUGGGUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17402	MI0002490	ppa-mir-141	Pan paniscus miR-141 stem-loop	UGGCCGGCCCUGGGUCCAUCUUCCAGUACAGUGUUGGAUGGUCUAAUUGUGAAGCUCCUAACACUGUCUGGUAAAGAUGCCCCCGGGGUGGGUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17403	MI0002491	ggo-mir-15b	Gorilla gorilla miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUGCUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17404	MI0002492	age-mir-15b	Ateles geoffroyi miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17405	MI0002493	ppa-mir-15b	Pan paniscus miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUGCUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17406	MI0002494	ppy-mir-15b	Pongo pygmaeus miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUGCUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17407	MI0002495	ptr-mir-15b	Pan troglodytes miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUGCUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17408	MI0002496	mml-mir-15b	Macaca mulatta miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17409	MI0002497	lla-mir-15b	Lagothrix lagotricha miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17410	MI0002498	mne-mir-15b	Macaca nemestrina miR-15b stem-loop	UUGAGGCCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17411	MI0002499	ptr-mir-23b	Pan troglodytes miR-23b stem-loop	CUCAGGUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCACGACCUUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17412	MI0002500	ppy-mir-23b	Pongo pygmaeus miR-23b stem-loop	CUCAGGUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCACGACCUUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17413	MI0002501	ppa-mir-23b	Pan paniscus miR-23b stem-loop	CUCAGGUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCACGACCUUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17414	MI0002502	mml-mir-30b	Macaca mulatta miR-30b stem-loop	ACCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17415	MI0002503	ptr-mir-30b	Pan troglodytes miR-30b stem-loop	ACCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17416	MI0002504	ggo-mir-30b	Gorilla gorilla miR-30b stem-loop	ACCAAGUUCCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17417	MI0002505	lla-mir-30b	Lagothrix lagotricha miR-30b stem-loop	ACCGAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGAGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17418	MI0002506	mne-mir-30b	Macaca nemestrina miR-30b stem-loop	ACCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17419	MI0002507	age-mir-30b	Ateles geoffroyi miR-30b stem-loop	ACCGAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGAGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17420	MI0002508	ppa-mir-30b	Pan paniscus miR-30b stem-loop	ACCAAGUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAAUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17421	MI0002509	ggo-mir-125b-1	Gorilla gorilla miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17422	MI0002510	age-mir-125b-1	Ateles geoffroyi miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17423	MI0002511	ppa-mir-125b	Pan paniscus miR-125b stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUAACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUAAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17424	MI0002512	ppy-mir-125b-1	Pongo pygmaeus miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17425	MI0002513	ptr-mir-125b-1	Pan troglodytes miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17426	MI0002514	mml-mir-125b-1	Macaca mulatta miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17427	MI0002515	sla-mir-125b	Saguinus labiatus miR-125b stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17428	MI0002516	lla-mir-125b-1	Lagothrix lagotricha miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17429	MI0002517	mne-mir-125b-1	Macaca nemestrina miR-125b-1 stem-loop	UGCGCUCCUCUCAGUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGUGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17430	MI0002518	mml-mir-128a	Macaca mulatta miR-128a stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17431	MI0002519	ptr-mir-128	Pan troglodytes miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17432	MI0002520	ppy-mir-128	Pongo pygmaeus miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17433	MI0002521	sla-mir-128	Saguinus labiatus miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17434	MI0002522	age-mir-128	Ateles geoffroyi miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17435	MI0002523	ppa-mir-128	Pan paniscus miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17436	MI0002524	mml-mir-130a	Macaca mulatta miR-130a stem-loop	UGCUGCUGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUGUCACUAGCAGUGCAAUGUUAAAAGGGCAUUGGCCCCCCAGUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17437	MI0002525	ggo-mir-130a	Gorilla gorilla miR-130a stem-loop	UGCUGCUGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUGUCACUAGCAGUGCAAUGUUAAAAGGGCAUUGGCCGUGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17438	MI0002526	mne-mir-130a	Macaca nemestrina miR-130a stem-loop	UGCUGCUGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUGUCACUAGCAGUGCAAUGUUAAAAGGGCAUUGGCCGUGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17439	MI0002527	ppa-mir-130a	Pan paniscus miR-130a stem-loop	UGCUGCUGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUGUCACUAGCAGUGCAAUGUUAAAAGGGCAUUGGCCGUGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17440	MI0002528	ggo-mir-133a	Gorilla gorilla miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17441	MI0002529	age-mir-133a	Ateles geoffroyi miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17442	MI0002530	ppa-mir-133a	Pan paniscus miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17443	MI0002531	ppy-mir-133a	Pongo pygmaeus miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17444	MI0002532	ptr-mir-133a	Pan troglodytes miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17445	MI0002533	mml-mir-133a	Macaca mulatta miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17446	MI0002534	sla-mir-133a	Saguinus labiatus miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17447	MI0002535	lla-mir-133a	Lagothrix lagotricha miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17448	MI0002536	mne-mir-133a	Macaca nemestrina miR-133a stem-loop	ACAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGCCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17449	MI0002537	lla-mir-135-1	Lagothrix lagotricha miR-135-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCACUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17450	MI0002538	age-mir-135-1	Ateles geoffroyi miR-135-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCACUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17451	MI0002539	ppa-mir-135-1	Pan paniscus miR-135-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCACUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17452	MI0002540	mml-mir-135a-2	Macaca mulatta miR-135a-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17453	MI0002541	ptr-mir-135	Pan troglodytes miR-135 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17454	MI0002542	ggo-mir-135	Gorilla gorilla miR-135 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17455	MI0002543	ppy-mir-135	Pongo pygmaeus miR-135 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17456	MI0002544	lla-mir-135-2	Lagothrix lagotricha miR-135-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGCACCACAUAAUGUAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17457	MI0002545	age-mir-135-2	Ateles geoffroyi miR-135-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17458	MI0002546	ppa-mir-135-2	Pan paniscus miR-135-2 stem-loop	AGAUAAAUUCACUCUAGUGCUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAAUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17459	MI0002547	ptr-mir-140	Pan troglodytes miR-140 stem-loop	UGUGUCUCUCUCUGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACCGGGGCACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17460	MI0002548	mne-mir-140	Macaca nemestrina miR-140 stem-loop	UGUGUCUCUCUCUGUGUCCUGCCAGUGGUUCUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACCGGGGCACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17461	MI0002549	ptr-mir-143	Pan troglodytes miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUUUUCUGCAGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17462	MI0002550	ggo-mir-143	Gorilla gorilla miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUGUUCUGCAGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17463	MI0002551	ppy-mir-143	Pongo pygmaeus miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUGUUCUGCAGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17464	MI0002552	lla-mir-143	Lagothrix lagotricha miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUGUUCUGCAGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17465	MI0002553	ppa-mir-143	Pan paniscus miR-143 stem-loop	GCGCAGCGCCCUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUUUUCUGCAGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17466	MI0002554	ptr-mir-144	Pan troglodytes miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGCGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCCGGGCACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17467	MI0002555	ppy-mir-144	Pongo pygmaeus miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGCGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCUGGGCACCCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17468	MI0002556	mne-mir-144	Macaca nemestrina miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGUGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCCGGGCACCCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17469	MI0002557	ppa-mir-144	Pan paniscus miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGCGAUGAGACACUACAGUAUAGAUGAUGUACUACUCCGGGCACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17470	MI0002558	mml-mir-145	Macaca mulatta miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAAAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17471	MI0002559	ptr-mir-145	Pan troglodytes miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17472	MI0002560	ggo-mir-145	Gorilla gorilla miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17473	MI0002561	ppy-mir-145	Pongo pygmaeus miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17474	MI0002562	mne-mir-145	Macaca nemestrina miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAAAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17475	MI0002563	mml-mir-153-1	Macaca mulatta miR-153-1 stem-loop	CUCACAGCUGCCAGUGUCAUUUUUGUGAUCUGCAGCUAGUAUUCUCACUCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGCAGGUGUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17476	MI0002564	ppy-mir-153	Pongo pygmaeus miR-153 stem-loop	CUCACAGCUGCCAGUGUCAUUUUUGUGAUCUGCAGCUAGUAUUCUCACUCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGCAGGUGUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17477	MI0002565	mne-mir-153-1	Macaca nemestrina miR-153-1 stem-loop	CUCACAGCUGCCAGUGUCAUUUUUGUGAUCUGCAGCUAGUAUUCUCACUCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGCAGGUGUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17478	MI0002566	mml-mir-153-2	Macaca mulatta miR-153-2 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17479	MI0002567	ggo-mir-153	Gorilla gorilla miR-153 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17480	MI0002568	mne-mir-153-2	Macaca nemestrina miR-153-2 stem-loop	AGCGGUGGCCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGGAAACUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17481	MI0002569	ptr-mir-9	Pan troglodytes miR-9 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17482	MI0002570	ggo-mir-9	Gorilla gorilla miR-9 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17483	MI0002571	lla-mir-9	Lagothrix lagotricha miR-9 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17484	MI0002572	mne-mir-9	Macaca nemestrina miR-9 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17485	MI0002573	age-mir-9	Ateles geoffroyi miR-9 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17486	MI0002574	ggo-mir-125b-2	Gorilla gorilla miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17487	MI0002575	age-mir-125b-2	Ateles geoffroyi miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17488	MI0002576	lca-mir-125b	Lemur catta miR-125b stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17489	MI0002577	ppy-mir-125b-2	Pongo pygmaeus miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17490	MI0002578	ptr-mir-125b-2	Pan troglodytes miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17491	MI0002579	mml-mir-125b-2	Macaca mulatta miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17492	MI0002580	lla-mir-125b-2	Lagothrix lagotricha miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17493	MI0002581	mne-mir-125b-2	Macaca nemestrina miR-125b-2 stem-loop	ACCAGACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17494	MI0002582	mml-mir-127	Macaca mulatta miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCCUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17495	MI0002583	ptr-mir-127	Pan troglodytes miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17496	MI0002584	ppy-mir-127	Pongo pygmaeus miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17497	MI0002585	sla-mir-127	Saguinus labiatus miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17498	MI0002586	lla-mir-127	Lagothrix lagotricha miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17499	MI0002587	mne-mir-127	Macaca nemestrina miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCCUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17500	MI0002588	age-mir-127	Ateles geoffroyi miR-127 stem-loop	UGUGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCAUCAUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17501	MI0002589	ggo-mir-134	Gorilla gorilla miR-134 stem-loop	UAGGGUGUGUGACUGGUUGACCAGAGGGGCAUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17502	MI0002590	ppy-mir-134	Pongo pygmaeus miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCAUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17503	MI0002591	mne-mir-134	Macaca nemestrina miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCAUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17504	MI0002592	ppa-mir-134	Pan paniscus miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCAUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17505	MI0002593	ptr-mir-136	Pan troglodytes miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17506	MI0002594	ggo-mir-136	Gorilla gorilla miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17507	MI0002595	ppy-mir-136	Pongo pygmaeus miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17508	MI0002596	ppa-mir-136	Pan paniscus miR-136 stem-loop	UGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17509	MI0002597	ptr-mir-154	Pan troglodytes miR-154 stem-loop	GUGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17510	MI0002598	ggo-mir-154	Gorilla gorilla miR-154 stem-loop	GUGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17511	MI0002599	ppy-mir-154	Pongo pygmaeus miR-154 stem-loop	GUGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17512	MI0002600	mne-mir-154	Macaca nemestrina miR-154 stem-loop	GAGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17513	MI0002601	ppa-mir-154	Pan paniscus miR-154 stem-loop	GUGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17514	MI0002602	ptr-mir-184	Pan troglodytes miR-184 stem-loop	CCAGUCACGUCCCCUUAUCACUUUUCCAGCCCAGCUUUGUGACUGUAAGUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17515	MI0002603	ppy-mir-184	Pongo pygmaeus miR-184 stem-loop	CCAGUCACGUCCCCUUAUCACUUUUCCAGCCCAGCUUUGUGACUGUAAGUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17516	MI0002604	mne-mir-184	Macaca nemestrina miR-184 stem-loop	UCAGUCACGUCCCCUUAUCACUUUUCCAGCCCAGCUUUAUGACUGUAAGUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17517	MI0002605	ptr-mir-186	Pan troglodytes miR-186 stem-loop	UGCUUGUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGGUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17518	MI0002606	ggo-mir-186	Gorilla gorilla miR-186 stem-loop	UGCUUGUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGGUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17519	MI0002607	ppa-mir-186	Pan paniscus miR-186 stem-loop	UGCUUGUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGGUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17520	MI0002608	mml-mir-188	Macaca mulatta miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUUUAUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGUGAGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17521	MI0002609	ptr-mir-188	Pan troglodytes miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAACUUUCUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGCGAGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17522	MI0002610	ppy-mir-188	Pongo pygmaeus miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUUUCUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGCGAGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17523	MI0002611	mne-mir-188	Macaca nemestrina miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUUUAUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGUGAGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17524	MI0002612	ppa-mir-188	Pan paniscus miR-188 stem-loop	UGCUCCCUCUCUCACAUCCCUUGCAUGGUGGAGGGUGAGCUUUCUGAAAACCCCUCCCACAUGCAGGGUUUGCAGGAUGGCGAGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17525	MI0002613	mml-mir-190a	Macaca mulatta miR-190a stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCUUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17526	MI0002614	ptr-mir-190	Pan troglodytes miR-190 stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCUUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17527	MI0002615	ggo-mir-190	Gorilla gorilla miR-190 stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCUUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17528	MI0002616	ppa-mir-190	Pan paniscus miR-190 stem-loop	UGCAGGCCUCUGUGUGAUAUGUUUGAUAUAUUAGGUUGUUAUUUAAUCCAACUAUAUAUCAAACAUAUUCCUACAGUGUCUUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17529	MI0002617	ggo-mir-195	Gorilla gorilla miR-195 stem-loop	AGCUUCCUGGGCUCUAGCAGCACAGAAAUAUUGGCACAGGGAAGCGAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17530	MI0002618	ppa-mir-195	Pan paniscus miR-195 stem-loop	AGCUUCCCUGGCUCUAGCAGCACAGAAAUAUUGGCACAGGGAAGCGAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17531	MI0002619	ppy-mir-206	Pongo pygmaeus miR-206 stem-loop	UGCUUCCCGAGGCCACAUGCUUCUUUAUAUCCCCAUAUGGAUUACUUUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCGGCAAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17532	MI0002620	mne-mir-206	Macaca nemestrina miR-206 stem-loop	UGCUUCCCGAGGCCACAUGCUUCUUUAUAUCCCCAUAUGGAUUACUUUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCGGCAAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17533	MI0002621	mml-mir-21	Macaca mulatta miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17534	MI0002622	ptr-mir-21	Pan troglodytes miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17535	MI0002623	ggo-mir-21	Gorilla gorilla miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17536	MI0002624	ppy-mir-21	Pongo pygmaeus miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17537	MI0002625	mne-mir-21	Macaca nemestrina miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17538	MI0002626	age-mir-21	Ateles geoffroyi miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17539	MI0002627	ppa-mir-21	Pan paniscus miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACACCAGUCGAUGGGCUGUCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17540	MI0002628	age-mir-22	Ateles geoffroyi miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17541	MI0002629	ppa-mir-22	Pan paniscus miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17542	MI0002630	lca-mir-22	Lemur catta miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17543	MI0002631	mml-mir-22	Macaca mulatta miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17544	MI0002632	ppy-mir-22	Pongo pygmaeus miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17545	MI0002633	ptr-mir-22	Pan troglodytes miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17546	MI0002634	sla-mir-22	Saguinus labiatus miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCCGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17547	MI0002635	lla-mir-22	Lagothrix lagotricha miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17548	MI0002636	mne-mir-22	Macaca nemestrina miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17549	MI0002637	mml-mir-24-1	Macaca mulatta miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUUACACACUGGCUCAGUUCAGCAGGAACAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17550	MI0002638	ppy-mir-24-1	Pongo pygmaeus miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUUACACACUGGCUCAGUUCAGCAGGAACAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17551	MI0002639	mne-mir-24-1	Macaca nemestrina miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUUACACACUGGCUCAGUUCAGCAGGAACAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17552	MI0002640	ppa-mir-24-1	Pan paniscus miR-24/miR-189 stem-loop	CUCCGGUGCCUACUGAGCUGAUAUCAGUUCUCAUUUUACACACUGGCUCAGUUCAGCAGGAACAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17553	MI0002641	ptr-mir-26a	Pan troglodytes miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17554	MI0002642	ggo-mir-26a	Gorilla gorilla miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17555	MI0002643	ppy-mir-26a	Pongo pygmaeus miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17556	MI0002644	lla-mir-26a	Lagothrix lagotricha miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17557	MI0002645	mne-mir-26a	Macaca nemestrina miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGAUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17558	MI0002646	mml-mir-26a-1	Macaca mulatta miR-26a-1 stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17559	MI0002647	ppa-mir-26a	Pan paniscus miR-26a stem-loop	GUGGCCUCGUUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACGGGGACGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17560	MI0002648	age-mir-28	Ateles geoffroyi miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUGCCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17561	MI0002649	mml-mir-28	Macaca mulatta miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUUCCUUUGUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17562	MI0002650	ptr-mir-28	Pan troglodytes miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUACCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17563	MI0002651	ggo-mir-28	Gorilla gorilla miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUACCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17564	MI0002652	ppy-mir-28	Pongo pygmaeus miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUACCUUUCUGAUUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17565	MI0002653	mne-mir-28	Macaca nemestrina miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUUCCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17566	MI0002654	sla-mir-28	Saguinus labiatus miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUGCCUUUCUAACUUUCCCACUAGAUUGUAAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17567	MI0002655	lla-mir-28	Lagothrix lagotricha miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUGCCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17568	MI0002656	ppa-mir-28	Pan paniscus miR-28 stem-loop	GGUCCUUGCCCUCAAGGAGCUCACAGUCUAUUGAGUUACCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGAGGGCAGGCACU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17569	MI0002657	ggo-mir-29a	Gorilla gorilla miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17570	MI0002658	age-mir-29a	Ateles geoffroyi miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17571	MI0002659	ppa-mir-29a	Pan paniscus miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17572	MI0002660	ppy-mir-29a	Pongo pygmaeus miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17573	MI0002661	ptr-mir-29a	Pan troglodytes miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17574	MI0002662	mml-mir-29a	Macaca mulatta miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17575	MI0002663	sla-mir-29a	Saguinus labiatus miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17576	MI0002664	lla-mir-29a	Lagothrix lagotricha miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17577	MI0002665	mne-mir-29a	Macaca nemestrina miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17578	MI0002666	mml-mir-30a	Macaca mulatta miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCAUAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17579	MI0002667	ptr-mir-30a	Pan troglodytes miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17580	MI0002668	ggo-mir-30a	Gorilla gorilla miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17581	MI0002669	ppy-mir-30a	Pongo pygmaeus miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17582	MI0002670	ppa-mir-30a	Pan paniscus miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17583	MI0002671	mml-mir-31	Macaca mulatta miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17584	MI0002672	ptr-mir-31	Pan troglodytes miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17585	MI0002673	ggo-mir-31	Gorilla gorilla miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17586	MI0002674	ppy-mir-31	Pongo pygmaeus miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17587	MI0002675	mne-mir-31	Macaca nemestrina miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17588	MI0002676	ppa-mir-31	Pan paniscus miR-31 stem-loop	GGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGGGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17589	MI0002677	mml-mir-32	Macaca mulatta miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17590	MI0002678	ptr-mir-32	Pan troglodytes miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17591	MI0002679	ggo-mir-32	Gorilla gorilla miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17592	MI0002680	ppy-mir-32	Pongo pygmaeus miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17593	MI0002681	sla-mir-32	Saguinus labiatus miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17594	MI0002682	mne-mir-32	Macaca nemestrina miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17595	MI0002683	ppa-mir-32	Pan paniscus miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUUUUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17596	MI0002684	mml-mir-33a	Macaca mulatta miR-33a stem-loop	CUGCGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17597	MI0002685	ptr-mir-33	Pan troglodytes miR-33 stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUCACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17598	MI0002686	ggo-mir-33	Gorilla gorilla miR-33 stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUCACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17599	MI0002687	ppy-mir-33	Pongo pygmaeus miR-33 stem-loop	CUGCGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUCACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17600	MI0002688	mne-mir-33	Macaca nemestrina miR-33 stem-loop	CUGCGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17601	MI0002689	ppa-mir-33	Pan paniscus miR-33 stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUUCUGGUGGUACCCAUGCAAUGUUUCCACAGUGCAUCACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17602	MI0002690	ptr-mir-95	Pan troglodytes miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17603	MI0002691	ggo-mir-95	Gorilla gorilla miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17604	MI0002692	ppy-mir-95	Pongo pygmaeus miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17605	MI0002693	sla-mir-95	Saguinus labiatus miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17606	MI0002694	lla-mir-95	Lagothrix lagotricha miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17607	MI0002695	ppa-mir-95	Pan paniscus miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCAUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17608	MI0002696	mml-mir-98	Macaca mulatta miR-98 stem-loop	GUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17609	MI0002697	ptr-mir-98	Pan troglodytes miR-98 stem-loop	AGGAUUCUGCUCAUGCCAGGGUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCCCUGGUGUGUGGCAUAUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17610	MI0002698	ggo-mir-98	Gorilla gorilla miR-98 stem-loop	GUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17611	MI0002699	ppy-mir-98	Pongo pygmaeus miR-98 stem-loop	GUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17612	MI0002700	age-mir-98	Ateles geoffroyi miR-98 stem-loop	GUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17613	MI0002701	ppa-mir-98	Pan paniscus miR-98 stem-loop	GUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUAUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17614	MI0002702	mml-mir-99a	Macaca mulatta miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17615	MI0002703	ptr-mir-99a	Pan troglodytes miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17616	MI0002704	ggo-mir-99a	Gorilla gorilla miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17617	MI0002705	ppy-mir-99a	Pongo pygmaeus miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUAAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17618	MI0002706	lla-mir-99a	Lagothrix lagotricha miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17619	MI0002707	mne-mir-99a	Macaca nemestrina miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17620	MI0002708	ppa-mir-99a	Pan paniscus miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17621	MI0002709	ggo-mir-100	Gorilla gorilla miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUAUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17622	MI0002710	age-mir-100	Ateles geoffroyi miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUGUUAGUCUGCACAAGCUUGUGUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17623	MI0002711	ppa-mir-100	Pan paniscus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUAUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17624	MI0002712	ppy-mir-100	Pongo pygmaeus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUAUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17625	MI0002713	ptr-mir-100	Pan troglodytes miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUAUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17626	MI0002714	mml-mir-100	Macaca mulatta miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUAUUAGUCCGCACAAGCUUGUGUCUAUAGGUAUGUGUCUUUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17627	MI0002715	sla-mir-100	Saguinus labiatus miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUGUUAAUGUGCACAAGCUUGUGUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17628	MI0002716	lla-mir-100	Lagothrix lagotricha miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUGUUAGUCUGCACAAGCUUGUGUCUAUAGGUAUGUGUCUGUUAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17629	MI0002717	ggo-mir-101	Gorilla gorilla miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17630	MI0002718	sla-mir-101	Saguinus labiatus miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17631	MI0002719	age-mir-101	Ateles geoffroyi miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCUAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17632	MI0002720	ppa-mir-101	Pan paniscus miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17633	MI0002721	ppy-mir-101	Pongo pygmaeus miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCUAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17634	MI0002722	ptr-mir-101	Pan troglodytes miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17635	MI0002723	mml-mir-101-1	Macaca mulatta miR-101-1 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17636	MI0002724	lla-mir-101	Lagothrix lagotricha miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17637	MI0002725	mne-mir-101	Macaca nemestrina miR-101 stem-loop	UGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17638	MI0002726	ppy-mir-29b-1	Pongo pygmaeus miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17639	MI0002727	ptr-mir-29b-1	Pan troglodytes miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17640	MI0002728	ggo-mir-29b-1	Gorilla gorilla miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17641	MI0002729	lla-mir-29b	Lagothrix lagotricha miR-29b stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17642	MI0002730	age-mir-29b	Ateles geoffroyi miR-29b stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17643	MI0002731	ppa-mir-29b-1	Pan paniscus miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17644	MI0002732	ptr-mir-29b-2	Pan troglodytes miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17645	MI0002733	ggo-mir-29b-2	Gorilla gorilla miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17646	MI0002734	ppy-mir-29b-2	Pongo pygmaeus miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17647	MI0002735	sla-mir-29b	Saguinus labiatus miR-29b stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17648	MI0002736	mne-mir-29b	Macaca nemestrina miR-29b stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17649	MI0002737	ppa-mir-29b-2	Pan paniscus miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17650	MI0002738	age-mir-103	Ateles geoffroyi miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17651	MI0002739	ggo-mir-103	Gorilla gorilla miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17652	MI0002740	ppa-mir-103	Pan paniscus miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17653	MI0002741	ppy-mir-103	Pongo pygmaeus miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17654	MI0002742	ptr-mir-103	Pan troglodytes miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17655	MI0002743	mml-mir-103-1	Macaca mulatta miR-103-1 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17656	MI0002744	lla-mir-103	Lagothrix lagotricha miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17657	MI0002745	mne-mir-103	Macaca nemestrina miR-103 stem-loop	UACUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGCAUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17658	MI0002746	ppy-mir-105	Pongo pygmaeus miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17659	MI0002747	ggo-mir-105	Gorilla gorilla miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17660	MI0002748	ppa-mir-105	Pan paniscus miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17661	MI0002749	ptr-mir-105	Pan troglodytes miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUUAUGCACCACGGAUGUUUGAGCAUGUGCUAUGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17662	MI0002750	mml-mir-105-1	Macaca mulatta miR-105-1 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17663	MI0002751	sla-mir-105	Saguinus labiatus miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17664	MI0002752	lla-mir-105	Lagothrix lagotricha miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17665	MI0002753	mne-mir-105	Macaca nemestrina miR-105 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUCAUGCACCACGGAUGUUUGAGCAUGUGCUACGGUGUCUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17666	MI0002754	mml-mir-107	Macaca mulatta miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17667	MI0002755	ptr-mir-107	Pan troglodytes miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17668	MI0002756	ggo-mir-107	Gorilla gorilla miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17669	MI0002757	ppy-mir-107	Pongo pygmaeus miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17670	MI0002758	lla-mir-107	Lagothrix lagotricha miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17671	MI0002759	mne-mir-107	Macaca nemestrina miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17672	MI0002760	ppa-mir-107	Pan paniscus miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17673	MI0002761	ggo-mir-124a	Gorilla gorilla miR-124a stem-loop	AUCAAGAUUAGAGGCUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17674	MI0002762	age-mir-124a	Ateles geoffroyi miR-124a stem-loop	AUCAAGAUCAGAGGCUCUGCCCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17675	MI0002763	ppa-mir-124a	Pan paniscus miR-124a stem-loop	AUCAAGAUUAGAGGCUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17676	MI0002764	ppy-mir-124a	Pongo pygmaeus miR-124a stem-loop	AUCAAGAUUAGAGGCUCUGCCCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17677	MI0002765	ptr-mir-124a	Pan troglodytes miR-124a stem-loop	AUCAAGAUUAGAGGCUCUGCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17678	MI0002766	mml-mir-124a-1	Macaca mulatta miR-124a-1 stem-loop	AUCAAGAUCAGAGGCUCUGCCCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGGCUGCACUUGAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17679	MI0002767	lla-mir-124a	Lagothrix lagotricha miR-124a stem-loop	AUCAAGAUCAGAGGCUCUGCCCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUACGACUGCACUUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17680	MI0002768	lla-mir-139	Lagothrix lagotricha miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17681	MI0002769	ppa-mir-139	Pan paniscus miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17682	MI0002770	ptr-mir-147	Pan troglodytes miR-147 stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUGGAAGCCAGUGUGUGGAAAUGCUUCUGCUAGAUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17683	MI0002771	ppy-mir-147	Pongo pygmaeus miR-147 stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUGGAAGCCAGUGUGUGGAAAUGCUUCUGCUAGAUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17684	MI0002772	sla-mir-147	Saguinus labiatus miR-147 stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUUGAAGCCAGUGUGUGGAAAUGCUUCUGCCACAUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17685	MI0002773	mne-mir-147	Macaca nemestrina miR-147 stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUUGAAGCCAGUGUGUGGAAAUGCUUCUGCUACAUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17686	MI0002774	ppa-mir-147	Pan paniscus miR-147 stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUGGAAGCCAGUGUGUGGAAAUGCUUCUGCUAGAUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17687	MI0002775	ggo-mir-7-1	Gorilla gorilla miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17688	MI0002776	ppy-mir-7-1	Pongo pygmaeus miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17689	MI0002777	sla-mir-7	Saguinus labiatus miR-7 stem-loop	UUGGAUAUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAAUUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17690	MI0002778	lla-mir-7	Lagothrix lagotricha miR-7 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17691	MI0002779	mne-mir-7-1	Macaca nemestrina miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUUGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17692	MI0002780	ppa-mir-7-1	Pan paniscus miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17693	MI0002781	ggo-mir-7-2	Gorilla gorilla miR-7-2 stem-loop	CUGCAUACAGAGUGGACCGGCUGGCCCCAUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACAAAUCCCAGUCUGCCUAAUGGUGCCAGCCAUCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17694	MI0002782	ppy-mir-7-2	Pongo pygmaeus miR-7-2 stem-loop	CUGGAUACAGAGUGGACCGGCUGGCCCCGUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACAAAUCCCAGUCUGCCUAAUGGUGCCAGCCAUCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17695	MI0002783	mne-mir-7-2	Macaca nemestrina miR-7-2 stem-loop	CUGGAUACAGAGUGAAGUGGCUGGCCCCGUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACGAAUCCCAGUCUGCCGAAUGGUGCCAGCCAUUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17696	MI0002784	ppa-mir-7-2	Pan paniscus miR-7-2 stem-loop	CUGGAUACAGAGCGGACCAGCUGGCCCCAUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACAAAUCCCAGUCUACCUAAUGGUGCCAGCCAUCACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17697	MI0002785	ptr-mir-7	Pan troglodytes miR-7 stem-loop	AGAUUAGAGUGGCUGUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUACUACGACAACAAGUCACAGCCGGCCUCAUAGCGCAGACUCCCUUCGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17698	MI0002786	ggo-mir-7-3	Gorilla gorilla miR-7-3 stem-loop	AGACUGGAGUGGCUGUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUACUACGACAACAAGUCACAGCCGGCCUCACAGCGCAGACUCCCUUCGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17699	MI0002787	ppa-mir-7-3	Pan paniscus miR-7-3 stem-loop	AGAUUAGAGUGGCUGUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUACUACGACAACAAGUCACAGCCGGCCUCAUAGCGCAGACUCCCUUCGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17700	MI0002788	ggo-mir-10a	Gorilla gorilla miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17701	MI0002789	ppy-mir-10a	Pongo pygmaeus miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCCGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUUUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17702	MI0002790	sla-mir-10a	Saguinus labiatus miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17703	MI0002791	age-mir-10a	Ateles geoffroyi miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17704	MI0002792	ppa-mir-10a	Pan paniscus miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACACAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUACACACUCCGCUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17705	MI0002793	ggo-mir-10b	Gorilla gorilla miR-10b stem-loop	CCAGACAUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCAUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17706	MI0002794	mne-mir-10b	Macaca nemestrina miR-10b stem-loop	CAGAGGUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCAUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17707	MI0002795	ppa-mir-10b	Pan paniscus miR-10b stem-loop	CCAGAGGUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCGUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17708	MI0002796	ggo-mir-34a	Gorilla gorilla miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17709	MI0002797	age-mir-34a	Ateles geoffroyi miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGUGCAAUAGUGAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17710	MI0002798	ppa-mir-34a	Pan paniscus miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGCCCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17711	MI0002799	ppy-mir-34a	Pongo pygmaeus miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17712	MI0002800	ptr-mir-34a	Pan troglodytes miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17713	MI0002801	mml-mir-34a	Macaca mulatta miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUACACAUUGUGGGGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17714	MI0002802	sla-mir-34a	Saguinus labiatus miR-34a stem-loop	GGCCGGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUGAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17715	MI0002803	lla-mir-34a	Lagothrix lagotricha miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUGAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGGGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17716	MI0002804	mne-mir-34a	Macaca nemestrina miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGCAAUAGUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUACACAUUGUGGGGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17717	MI0002805	ggo-mir-181a-2	Gorilla gorilla mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGGCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUUGGGGUCCUUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17718	MI0002806	ppa-mir-181a-2	Pan paniscus mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGCCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUUGGGGUCCUUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17719	MI0002807	ptr-mir-181a-2	Pan troglodytes mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGCCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUUGGGGUCCUUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17720	MI0002808	mml-mir-181a-2	Macaca mulatta mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGCCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUCGGGGUCCUUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17721	MI0002809	sla-mir-181a-2	Saguinus labiatus mir-181a-2 stem-loop	AGAAGGGCUACCAGGCCAACCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGACUUGAAAAAAAACCACUGACCGUUGACUGUACCUUGGGGUCCUUA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17722	MI0002810	mne-mir-181a-2	Macaca nemestrina mir-181a-2 stem-loop	AGAAGGGCUAUCAGGCCAGCCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACUGACCGUUGACUGUACCUCGGGGUCCCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17723	MI0002811	mml-mir-181c	Macaca mulatta miR-181c stem-loop	CGGAGAAUUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCUGAGACCUGGACUUGCCAUCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17724	MI0002812	ptr-mir-181c	Pan troglodytes miR-181c stem-loop	CGGAAAAUUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCUGAGGCCUGGAAUUGCCAUCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17725	MI0002813	ggo-mir-181c	Gorilla gorilla miR-181c stem-loop	CGGAAAAUUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCUGAGGCCUGGAAUUGCCAUCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17726	MI0002814	ppa-mir-181c	Pan paniscus miR-181c stem-loop	CGGAAAAUUUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCUGAGGCCUGGAAUUGCCAUCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17727	MI0002815	mml-mir-182	Macaca mulatta miR-182 stem-loop	CACAGCUGCUUGCCUCCCCCUGUUUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAAUGGGAUCCGGUGGUUCUAGACUUGCCAACUACGGGGCGAGGGCUCAGCCGGCAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17728	MI0002816	ppy-mir-182	Pongo pygmaeus miR-182 stem-loop	CACAGCUGCUUGCCUUCCCCCGUUUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAACAGGAUCCGGUGGUUCUAGACUUGCCAACUAUGGGGCGAGGACUCAGCCGGCAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17729	MI0002817	ggo-mir-187	Gorilla gorilla miR-187 stem-loop	GGUCGGGCUCACCAUGACACAGUGUGAGACCUCGGGCUACAACACAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17730	MI0002818	ppy-mir-187	Pongo pygmaeus miR-187 stem-loop	GGUUGGGCUCACCAUGACACAGUGUGAGACCUCGGGCUACAACAUAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17731	MI0002819	mne-mir-187	Macaca nemestrina miR-187 stem-loop	GGUCAGGCUCACUAUGACACAGUGUGAGACCUCGGGCUACAACACAGGACCCGGGUGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17732	MI0002820	ppa-mir-187	Pan paniscus miR-187 stem-loop	GGUCGGGCUCACCAUGACACAGUGUGAGACCUCGGGCUACAACACAGGACCCGGGCGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17733	MI0002821	mml-mir-196a-1	Macaca mulatta miR-196a-1 stem-loop	GUGAAUUAGGUAGUUUCAUGUUGUUGGGCCUGGGUUUCUGAACACAACAACAUUAAACCACCCGAUUCAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17734	MI0002822	ggo-mir-196-1	Gorilla gorilla miR-196-1 stem-loop	GUGAAUUAGGUAGUUUCAUGUUGUUGGGCCUGGGUUUCUGAACACAACAACAUUAAACCACCCGAUUCAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17735	MI0002823	ppy-mir-196-1	Pongo pygmaeus miR-196-1 stem-loop	GUGAAUUAGGUAGUUUCAUGUUGUUGGGCCUGGGUUUCUGAACACAACAACAUUAAACCACCCGAUUCAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17736	MI0002824	ptr-mir-196	Pan troglodytes miR-196 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17737	MI0002825	ggo-mir-196-2	Gorilla gorilla miR-196-2 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17738	MI0002826	ppy-mir-196-2	Pongo pygmaeus miR-196-2 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17739	MI0002827	lla-mir-196	Lagothrix lagotricha miR-196 stem-loop	UGCUUGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17740	MI0002828	age-mir-196	Ateles geoffroyi miR-196 stem-loop	UGCUUGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17741	MI0002829	ppa-mir-196	Pan paniscus miR-196 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17742	MI0002830	ggo-mir-199a	Gorilla gorilla miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17743	MI0002831	ppa-mir-199a	Pan paniscus miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17744	MI0002832	ppy-mir-199a	Pongo pygmaeus miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17745	MI0002833	ptr-mir-199a	Pan troglodytes miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17746	MI0002834	mml-mir-199a-1	Macaca mulatta miR-199a-1 stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17747	MI0002835	sla-mir-199a	Saguinus labiatus miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17748	MI0002836	lla-mir-199a	Lagothrix lagotricha miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17749	MI0002837	mne-mir-199a	Macaca nemestrina miR-199a stem-loop	AGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGGAGAGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17750	MI0002838	ptr-mir-204	Pan troglodytes miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17751	MI0002839	ggo-mir-204	Gorilla gorilla miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17752	MI0002840	ppy-mir-204	Pongo pygmaeus miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17753	MI0002841	sla-mir-204	Saguinus labiatus miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17754	MI0002842	mne-mir-204	Macaca nemestrina miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17755	MI0002843	ppa-mir-204	Pan paniscus miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17756	MI0002844	ggo-mir-205	Gorilla gorilla miR-205 stem-loop	AAAGAUCCUCAGACAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17757	MI0002845	age-mir-205	Ateles geoffroyi miR-205 stem-loop	AAAGAUCCUCGGGCAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUCAGGAGGCAUGGAGCUGACG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17758	MI0002846	ppa-mir-205	Pan paniscus miR-205 stem-loop	AAAGAUCCUCAGACAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17759	MI0002847	ptr-mir-205	Pan troglodytes miR-205 stem-loop	AAAGAUCCUCAGACAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17760	MI0002848	lla-mir-205	Lagothrix lagotricha miR-205 stem-loop	AAAGAUCCUCGGGCAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17761	MI0002849	mne-mir-205	Macaca nemestrina miR-205 stem-loop	AAAGAUCCUCAGGCAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17762	MI0002850	mml-mir-211	Macaca mulatta miR-211 stem-loop	UCACUGGCCAUGUGACUUGUGGGCUUCCCUUUGUCAUCCUUUGCCUAGGGCUCUGAGCAGGGCAGGGACAGCAAAGGGGUGCUCAGUUGUCACUUCCCACAGCACAGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17763	MI0002851	ppy-mir-211	Pongo pygmaeus miR-211 stem-loop	UCACCCAGCCAUGUGACUUGUGGACUUCCCUUUGUCAUCCUUCGCCUAGGGCUCUGAGCAGGGCAGGGACAGCAAAGGGGUGCUCAGUUGUCACUUCCCACAGCACGGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17764	MI0002852	mne-mir-211	Macaca nemestrina miR-211 stem-loop	UCACUGGCCAUGUGACUUGUGGGCUUCCCUUUGUCAUCCUUCGCCUAGGGCUCUGAGCAGGGCAGGGACAGCAAAGGGGUGCUCAGUUGUCACUUCCCACAGCACAGAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17765	MI0002853	ggo-mir-214	Gorilla gorilla miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17766	MI0002854	age-mir-214	Ateles geoffroyi miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17767	MI0002855	ppa-mir-214	Pan paniscus miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17768	MI0002856	ppy-mir-214	Pongo pygmaeus miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17769	MI0002857	ptr-mir-214	Pan troglodytes miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17770	MI0002858	mml-mir-214	Macaca mulatta miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17771	MI0002859	sla-mir-214	Saguinus labiatus miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17772	MI0002860	mne-mir-214	Macaca nemestrina miR-214 stem-loop	GGCCUGGCUGGACAGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17773	MI0002861	lca-mir-216	Lemur catta miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUAGCCCUCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17774	MI0002862	ptr-mir-216	Pan troglodytes miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAAACUAAACAGAGCAAUUUCCUAGCCCUCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17775	MI0002863	ggo-mir-216	Gorilla gorilla miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUAGCCCUCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17776	MI0002864	ppy-mir-216	Pongo pygmaeus miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUUGCCCUCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17777	MI0002865	ppa-mir-216	Pan paniscus miR-216 stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUCCUAGCCCUCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17778	MI0002866	ggo-mir-217	Gorilla gorilla miR-217 stem-loop	AGUAUAAUUAUUACAUAGUUUUUGAUGUCGCAGAUACUGCAUCAGGAACUGAUUGGAUAAGAAUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17779	MI0002867	ppa-mir-217	Pan paniscus miR-217 stem-loop	AGUAUAAUUAUUACAUAGUUUUUGAUGUCGCAGAUACUGCAUCAGGAACUGAUUGGAUAAGAAUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17780	MI0002868	ggo-mir-218	Gorilla gorilla miR-218 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17781	MI0002869	age-mir-218	Ateles geoffroyi miR-218 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17782	MI0002870	ppa-mir-218-1	Pan paniscus miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17783	MI0002871	lca-mir-218	Lemur catta miR-218 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCCAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17784	MI0002872	ppy-mir-218-1	Pongo pygmaeus miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17785	MI0002873	ptr-mir-218-1	Pan troglodytes miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17786	MI0002874	sla-mir-218-1	Saguinus labiatus miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17787	MI0002875	lla-mir-218-1	Lagothrix lagotricha miR-218-1 stem-loop	GUGAUAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17788	MI0002876	mne-mir-218-1	Macaca nemestrina miR-218-1 stem-loop	GUGACAAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17789	MI0002877	ppa-mir-218-2	Pan paniscus miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17790	MI0002878	ppy-mir-218-2	Pongo pygmaeus miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17791	MI0002879	ptr-mir-218-2	Pan troglodytes miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17792	MI0002880	mml-mir-218-2	Macaca mulatta miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17793	MI0002881	sla-mir-218-2	Saguinus labiatus miR-218-2 stem-loop	GACCAGUCGCUGCGGAGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17794	MI0002882	lla-mir-218-2	Lagothrix lagotricha miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17795	MI0002883	mne-mir-218-2	Macaca nemestrina miR-218-2 stem-loop	GACCAGUCGCUGCGGGGCUUUCCUUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCGGAAAGCACCGUGCUCUCCUGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17796	MI0002884	mml-mir-219-1	Macaca mulatta miR-219-1 stem-loop	CCGCCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUAUGGCUCUGGCCGAGAGUUGAGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGGGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17797	MI0002885	ggo-mir-219	Gorilla gorilla miR-219 stem-loop	CCGCCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUAUGGCUCCGGCCGAGAGUUGAGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGCGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17798	MI0002886	ppy-mir-219	Pongo pygmaeus miR-219 stem-loop	CCGCCCCGGGCCGCGGCUCCUGAUUGUCCAAACGCAAUUCUCGAGUCUAUGGCCCCGGCCGAGAGUUGAGUCUGGACGUCCCGAGCCGCCGCCCCCAAACCUCGAGCGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17799	MI0002887	mml-mir-220a	Macaca mulatta miR-220a stem-loop	GACAGCGUGGCAUUGUAGGGCUCCACCACCAUGUCUGACACUUUGGGUGAGAGCACCACGCUGAAGGUGUUCAUAAUGUGGUCUGGGAACUCCUUGUGGAUCUUACUGAUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17800	MI0002888	ptr-mir-220	Pan troglodytes miR-220 stem-loop	GACAGCAUGGCAUUGUAGGGCUCCACACCGUAUCUGACACUUUGGGCGAGGGCACCAUGCUGAAGGUGUUCAUGAUGCAGUCUGGGAACUCCUCACGGAUCUUACUGAUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17801	MI0002889	ggo-mir-220	Gorilla gorilla miR-220 stem-loop	GACAGCGUGGCAUUGUAGGGCUCCACACCGUGUCUGACACUUUGGGCGAGGGCACCAUGCUGAAGGUGUUCAUGAUGUGAUCUGGGAACUCCUCACGGAUCUUACUGAUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17802	MI0002890	mne-mir-220	Macaca nemestrina miR-220 stem-loop	GACAGCGUGGCAUUGUAGGCUCCACCACCAUGUCUGACACUUUGGGUGAGAGCACCACGCUGAAGGUGUUCAUAAUGUGGUCUGGGAACUCCUUGUGGAUCUUACUGAUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17803	MI0002891	ppa-mir-220	Pan paniscus miR-220 stem-loop	GACAGCAUGGCAUUGUAGGGCUCCACACCGUAUCUGACACUUUGGGCGAGGGCACCAUGCUGAAGGUGUUCAUGAUGCAGUCUGGGAACUCCUCACGGAUCUUACUGAUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17804	MI0002892	mml-mir-221	Macaca mulatta miR-221 stem-loop	UGAACAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUCGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACAUGUUCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17805	MI0002893	ggo-mir-221	Gorilla gorilla miR-221 stem-loop	UGAACAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUCGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACAUGUUCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17806	MI0002894	ppy-mir-221	Pongo pygmaeus miR-221 stem-loop	UGAACAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUCGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACAUGUUCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17807	MI0002895	ppa-mir-221	Pan paniscus miR-221 stem-loop	UGAACAUCCAGGUCUGGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUCGUUAGGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACAUGUUCUC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17808	MI0002896	age-mir-222	Ateles geoffroyi miR-222 stem-loop	UCUGCCGGAAGGUGUGGGUACCCUCAGUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUUGUAAUCAGUAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCUUUUAGCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17809	MI0002897	mml-mir-223	Macaca mulatta miR-223 stem-loop	CCCGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCGUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCAUAUGCUUACCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17810	MI0002898	ptr-mir-223	Pan troglodytes miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCAUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCACAUGCUUACCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17811	MI0002899	ggo-mir-223	Gorilla gorilla miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCAUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCACAUGCUUACCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17812	MI0002900	ppy-mir-223	Pongo pygmaeus miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUAGACACUCCGUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCACAUGCUUACCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17813	MI0002901	sla-mir-223	Saguinus labiatus miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCGUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGACACAUGCUUAGCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17814	MI0002902	ppa-mir-223	Pan paniscus miR-223 stem-loop	CCUGGCCUCCUGCAGUGCCACGCUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCAUGUGGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGCGGCACAUGCUUACCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17815	MI0002903	mml-mir-224	Macaca mulatta miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17816	MI0002904	ptr-mir-224	Pan troglodytes miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17817	MI0002905	ggo-mir-224	Gorilla gorilla miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17818	MI0002906	ppy-mir-224	Pongo pygmaeus miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17819	MI0002907	mne-mir-224	Macaca nemestrina miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17820	MI0002908	ppa-mir-224	Pan paniscus miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUGUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17821	MI0002909	ptr-mir-197	Pan troglodytes miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17822	MI0002910	ppy-mir-197	Pongo pygmaeus miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17823	MI0002911	mne-mir-197	Macaca nemestrina miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCGGCAUGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17824	MI0002912	age-mir-197	Ateles geoffroyi miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17825	MI0002913	ppa-mir-197	Pan paniscus miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17826	MI0002914	ggo-mir-198	Gorilla gorilla miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUAUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17827	MI0002915	age-mir-198	Ateles geoffroyi miR-198 stem-loop	UCACUGGUCCAGAGGGGAGCUAGGUACCUGUGAUUUUUCCUUCUUUUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17828	MI0002916	ppa-mir-198	Pan paniscus miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17829	MI0002917	ppy-mir-198	Pongo pygmaeus miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17830	MI0002918	ptr-mir-198	Pan troglodytes miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17831	MI0002919	mml-mir-198	Macaca mulatta miR-198 stem-loop	UCAUUGGUCCAGAGGGGAAAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17832	MI0002920	sla-mir-198	Saguinus labiatus miR-198 stem-loop	UCAUUGGUCCAGAGGGGAGCUCGAUACCUGUGAUUUUUCCUUCUUUUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17833	MI0002921	lla-mir-198	Lagothrix lagotricha miR-198 stem-loop	UCACUGGUCCAGAAGGGAGCUAGGUACUUGUGAUUUUUCCUUCUUUUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17834	MI0002922	mne-mir-198	Macaca nemestrina miR-198 stem-loop	UCAUUGGUCCAGAGGGGAAAUAGGUUCCUGUGAUUUUUCCUUCUUCUCUGUAGAAUAAAUGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17835	MI0002923	ptr-mir-30c	Pan troglodytes miR-30c stem-loop	AGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17836	MI0002924	lla-mir-30c	Lagothrix lagotricha miR-30c stem-loop	AGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17837	MI0002925	mne-mir-30c	Macaca nemestrina miR-30c stem-loop	AGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUUUCU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17838	MI0002926	ptr-mir-30d	Pan troglodytes miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17839	MI0002927	ggo-mir-30d	Gorilla gorilla miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17840	MI0002928	mne-mir-30d	Macaca nemestrina miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17841	MI0002929	ppa-mir-30d	Pan paniscus miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17842	MI0002930	ppa-mir-1	Pan paniscus miR-1 stem-loop	ACCUACUCAGAGUACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUGGUAGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17843	MI0002931	mml-mir-181a-1	Macaca mulatta miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17844	MI0002932	mml-mir-181b-1	Macaca mulatta miR-181b-1 stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUAGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17845	MI0002933	ptr-mir-181a-1	Pan troglodytes miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17846	MI0002934	ptr-mir-181b	Pan troglodytes miR-181b stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17847	MI0002935	ppy-mir-181a-1	Pongo pygmaeus miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17848	MI0002936	ppy-mir-181b	Pongo pygmaeus miR-181b stem-loop	CCUGUGCAGAGAUUAUUGUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17849	MI0002937	ggo-mir-181a-1	Gorilla gorilla miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUUCUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17850	MI0002938	ggo-mir-181b	Gorilla gorilla miR-181b stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17851	MI0002939	lla-mir-181a-1	Lagothrix lagotricha miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17852	MI0002940	lla-mir-181b	Lagothrix lagotricha miR-181b stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17853	MI0002941	mne-mir-181a-1	Macaca nemestrina miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17854	MI0002942	mne-mir-181b	Macaca nemestrina miR-181b stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUAGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17855	MI0002943	ppa-mir-181a-1	Pan paniscus miR-181a-1 stem-loop	UGAGUUUUGAGGUUGCUUCAGUGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACCCUAUGGCUAACCAUCAUCUACUCCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17856	MI0002944	ppa-mir-181b	Pan paniscus miR-181b stem-loop	CCUGUGCAGAGAUUAUUUUUUAAAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCGCUU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17857	MI0002945	age-mir-15a	Ateles geoffroyi miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17858	MI0002946	age-mir-16	Ateles geoffroyi miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17859	MI0002947	ggo-mir-15a	Gorilla gorilla miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17860	MI0002948	ggo-mir-16	Gorilla gorilla miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17861	MI0002949	mne-mir-15a	Macaca nemestrina miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17862	MI0002950	mne-mir-16	Macaca nemestrina miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17863	MI0002951	sla-mir-15a	Saguinus labiatus miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17864	MI0002952	sla-mir-16	Saguinus labiatus miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17865	MI0002953	ppa-mir-15a	Pan paniscus miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17866	MI0002954	ppa-mir-16	Pan paniscus miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17867	MI0002955	lca-mir-15a	Lemur catta miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17868	MI0002956	lca-mir-16	Lemur catta miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGUGUUAAGAUUCUAAAAUUAUCUCUAAGUAUUAACUGUGCCG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17869	MI0002957	mml-mir-15a	Macaca mulatta miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17870	MI0002958	mml-mir-16-1	Macaca mulatta miR-16-1 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17871	MI0002959	ppy-mir-15a	Pongo pygmaeus miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17872	MI0002960	ppy-mir-16	Pongo pygmaeus miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17873	MI0002961	ptr-mir-15a	Pan troglodytes miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17874	MI0002962	ptr-mir-16	Pan troglodytes miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17875	MI0002963	lla-mir-15a	Lagothrix lagotricha miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17876	MI0002964	lla-mir-16	Lagothrix lagotricha miR-16 stem-loop	GUCAGCAGUGCCUUAGCAGCACGUAAAUAUUGGCGCUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17877	MI0002965	ggo-mir-17	Gorilla gorilla miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17878	MI0002966	ggo-mir-18	Gorilla gorilla miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17879	MI0002967	ggo-mir-19a	Gorilla gorilla miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17880	MI0002968	ggo-mir-20	Gorilla gorilla miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17881	MI0002969	ggo-mir-19b-1	Gorilla gorilla miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17882	MI0002970	ggo-mir-92-1	Gorilla gorilla miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17883	MI0002971	lca-mir-17	Lemur catta miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17884	MI0002972	lca-mir-18	Lemur catta miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17885	MI0002973	lca-mir-19a	Lemur catta miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17886	MI0002974	lca-mir-20	Lemur catta miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUCAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17887	MI0002975	lca-mir-19b-1	Lemur catta miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUAAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17888	MI0002976	lca-mir-92-1	Lemur catta miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17889	MI0002977	age-mir-17	Ateles geoffroyi miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17890	MI0002978	age-mir-18	Ateles geoffroyi miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17891	MI0002979	age-mir-19a	Ateles geoffroyi miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGCAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17892	MI0002980	age-mir-20	Ateles geoffroyi miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17893	MI0002981	age-mir-19b-1	Ateles geoffroyi miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17894	MI0002982	age-mir-92-1	Ateles geoffroyi miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17895	MI0002983	ppa-mir-17	Pan paniscus miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17896	MI0002984	ppa-mir-18	Pan paniscus miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17897	MI0002985	ppa-mir-19a	Pan paniscus miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17898	MI0002986	ppa-mir-20	Pan paniscus miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17899	MI0002987	ppa-mir-19b-1	Pan paniscus miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17900	MI0002988	ppa-mir-92-1	Pan paniscus miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17901	MI0002989	ppy-mir-17	Pongo pygmaeus miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUACGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17902	MI0002990	ppy-mir-18	Pongo pygmaeus miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17903	MI0002991	ppy-mir-19a	Pongo pygmaeus miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17904	MI0002992	ppy-mir-20	Pongo pygmaeus miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17905	MI0002993	ppy-mir-19b-1	Pongo pygmaeus miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17906	MI0002994	ppy-mir-92-1	Pongo pygmaeus miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17907	MI0002995	ptr-mir-17	Pan troglodytes miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17908	MI0002996	ptr-mir-18	Pan troglodytes miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17909	MI0002997	ptr-mir-19a	Pan troglodytes miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17910	MI0002998	ptr-mir-20	Pan troglodytes miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17911	MI0002999	ptr-mir-19b-1	Pan troglodytes miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17912	MI0003000	ptr-mir-92-1	Pan troglodytes miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17913	MI0003001	mml-mir-17	Macaca mulatta miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17914	MI0003002	mml-mir-18	Macaca mulatta miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17915	MI0003003	mml-mir-19a	Macaca mulatta miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17916	MI0003004	mml-mir-20a	Macaca mulatta miR-20a stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17917	MI0003005	mml-mir-19b-1	Macaca mulatta miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17918	MI0003006	mml-mir-92a-1	Macaca mulatta miR-92a-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [2].  The expression of this mature miRNA was validated by Miska et al [1]. 	32
17919	MI0003007	sla-mir-17	Saguinus labiatus miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17920	MI0003008	sla-mir-18	Saguinus labiatus miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17921	MI0003009	sla-mir-19a	Saguinus labiatus miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17922	MI0003010	sla-mir-20	Saguinus labiatus miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17923	MI0003011	sla-mir-19b-1	Saguinus labiatus miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17924	MI0003012	sla-mir-92-1	Saguinus labiatus miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17925	MI0003013	lla-mir-17	Lagothrix lagotricha miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17926	MI0003014	lla-mir-18	Lagothrix lagotricha miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17927	MI0003015	lla-mir-19a	Lagothrix lagotricha miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGCAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17928	MI0003016	lla-mir-20	Lagothrix lagotricha miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17929	MI0003017	lla-mir-19b-1	Lagothrix lagotricha miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17930	MI0003018	lla-mir-92-1	Lagothrix lagotricha miR-92-1 stem-loop	CUUUCUACACAGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17931	MI0003019	mne-mir-17	Macaca nemestrina miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17932	MI0003020	mne-mir-18	Macaca nemestrina miR-18 stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17933	MI0003021	mne-mir-19a	Macaca nemestrina miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAGGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17934	MI0003022	mne-mir-20	Macaca nemestrina miR-20 stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17935	MI0003023	mne-mir-19b-1	Macaca nemestrina miR-19b-1 stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17936	MI0003024	mml-mir-194-1	Macaca mulatta miR-194-1 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17937	MI0003025	mml-mir-215	Macaca mulatta miR-215 stem-loop	AUCAUUAAGAAAUGGUAUACAGGAAAAUGACCUAUGAAUUGACAGACACUAUAGCUGAGUUUGUCUGUCAUUUCUUUAGGCCAAUAUUCUGUAUGACUGUGCUACUUCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17938	MI0003026	ptr-mir-194	Pan troglodytes miR-194 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17939	MI0003027	ptr-mir-215	Pan troglodytes miR-215 stem-loop	AUCAUUCAGAAAUGGUAUACGGGAAAAUGACCUAUGAAUUGACAGACAAUAUAGCUGAGUUUGUCUGUCAUUUCUUUAGGCCAAUAUUCUGUAUGACUGUGCUACUUCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17940	MI0003028	ppy-mir-194	Pongo pygmaeus miR-194 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGUUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17941	MI0003029	ppy-mir-215	Pongo pygmaeus miR-215 stem-loop	AUCAUUCAGAAAUGGUAUACAGGAAAAUGACCUAUGAAUUGACAGACAAUACAGCUGAGUUUGUCUGUCAUUUCUUUAGGCCAAUAUUCUGUACAACUGUGCUACUUCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17942	MI0003030	ggo-mir-194	Gorilla gorilla miR-194 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17943	MI0003031	ggo-mir-215	Gorilla gorilla miR-215 stem-loop	AUCAUUCAGAAAUGGUAUACGGGAAAAUGACCUAUGAAUUGACAGACAAUAUAGCUGAGUUUGUCUGUCAUUUCUUUAGACCAAUAUUCUGUAUGACUGUGCUACUUCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17944	MI0003032	mne-mir-194	Macaca nemestrina miR-194 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17945	MI0003033	mne-mir-215	Macaca nemestrina miR-215 stem-loop	AUCAUUAAGAAAUGGUAUACAGGAAAAUGACCUAUGAAUUGACAGACACUAUAGCUGAGUUUGUCUGUCAUUUCUUUAGGCCAAUAUUCUGUAUGACUGUGCUACUUCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17946	MI0003034	age-mir-194	Ateles geoffroyi miR-194 stem-loop	AUGGUGUUAUCAAGUGUAACAGCAACUCCAUGUGGACUGUGUACCAAUUUCCAGUGGAGAUGCUGUUACUUUUGAUGGUUACCAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17947	MI0003035	ggo-mir-23a	Gorilla gorilla miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17948	MI0003036	ggo-mir-27a	Gorilla gorilla miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17949	MI0003037	ggo-mir-24	Gorilla gorilla miR-24 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGUACACUGGCUCAGUUCAGCAGGAACAGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17950	MI0003038	age-mir-23a	Ateles geoffroyi miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUGCCUAUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17951	MI0003039	age-mir-27a	Ateles geoffroyi miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUUCACUCCAAGUCAUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17952	MI0003040	ppa-mir-23a	Pan paniscus miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17953	MI0003041	ppa-mir-27a	Pan paniscus miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17954	MI0003042	ppa-mir-24-2	Pan paniscus miR-24-2 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGUACACUGGCUCAGUUCAGCAGGAACAGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17955	MI0003043	lca-mir-23a	Lemur catta miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUACCUAUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17956	MI0003044	lca-mir-27a	Lemur catta miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAAUCAUGUUCACAGUGGCUAAGUUCCGCCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
17957	MI0003045	ppy-mir-23a	Pongo pygmaeus miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17958	MI0003046	ppy-mir-27a	Pongo pygmaeus miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUUGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17959	MI0003047	ppy-mir-24-2	Pongo pygmaeus miR-24-2 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGUACACUGGCUCAGUUCAGCAGGAACAGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17960	MI0003048	ptr-mir-23a	Pan troglodytes miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17961	MI0003049	ptr-mir-27a	Pan troglodytes miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17962	MI0003050	ptr-mir-24	Pan troglodytes miR-24 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGUACACUGGCUCAGUUCAGCAGGAACAGGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17963	MI0003051	mml-mir-23a	Macaca mulatta miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17964	MI0003052	mml-mir-27a	Macaca mulatta miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17965	MI0003053	mml-mir-24-2	Macaca mulatta miR-24-2 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGCACACUGGCUCAGUUCAGCAGGAACAGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17966	MI0003054	sla-mir-23a	Saguinus labiatus miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUGCCUAUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17967	MI0003055	sla-mir-27a	Saguinus labiatus miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUUCACUCCAAGUCAUGUUCACAGUGGCUAAGUUCCGCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17968	MI0003056	mne-mir-23a	Macaca nemestrina miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUUCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17969	MI0003057	mne-mir-27a	Macaca nemestrina miR-27a stem-loop	CUGAGGAGCAGGGCUUAGCUGCUUGUGAGCAGGGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCGCCCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17970	MI0003058	mne-mir-24-2	Macaca nemestrina miR-24-2 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGGUUUGUGCACACUGGCUCAGUUCAGCAGGAACAGGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17971	MI0003059	ggo-mir-106b	Gorilla gorilla miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17972	MI0003060	ggo-mir-93	Gorilla gorilla miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17973	MI0003061	ggo-mir-25	Gorilla gorilla miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
17974	MI0003062	age-mir-106b	Ateles geoffroyi miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17975	MI0003063	age-mir-93	Ateles geoffroyi miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCUGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
17976	MI0003064	ppa-mir-106b	Pan paniscus miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17977	MI0003065	ppa-mir-93	Pan paniscus miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17978	MI0003066	ppa-mir-25	Pan paniscus miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
17979	MI0003067	ppy-mir-106b	Pongo pygmaeus miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17980	MI0003068	ppy-mir-93	Pongo pygmaeus miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17981	MI0003069	ppy-mir-25	Pongo pygmaeus miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
17982	MI0003070	ptr-mir-106b	Pan troglodytes miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17983	MI0003071	ptr-mir-93	Pan troglodytes miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17984	MI0003072	ptr-mir-25	Pan troglodytes miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGCUGAGACGCGCCCGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated.  The assembled chimp genome sequence forces a single deletion in the 3' region of the chimp mature miRNA with respect to the human and rodent sequences. 	37
17985	MI0003073	mml-mir-106b	Macaca mulatta miR-106b stem-loop	CCUGCUGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17986	MI0003074	mml-mir-93	Macaca mulatta miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUAACCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17987	MI0003075	mml-mir-25	Macaca mulatta miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17988	MI0003076	sla-mir-106b	Saguinus labiatus miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17989	MI0003077	sla-mir-93	Saguinus labiatus miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCCAACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
17990	MI0003078	lla-mir-106b	Lagothrix lagotricha miR-106b stem-loop	CCUGCCGGGGCUAAAGUGCUGACAGUGCAGAUAGUGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17991	MI0003079	lla-mir-93	Lagothrix lagotricha miR-93 stem-loop	CUCGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCUGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17992	MI0003080	lla-mir-25	Lagothrix lagotricha miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
17993	MI0003081	mne-mir-106b	Macaca nemestrina miR-106b stem-loop	CCUGCUGGGGCUAAAGUGCUGACAGUGCAGAUAGUGGUCCUCUCCGUGCUACCGCACUGUGGGUACUUGCUGCUCCAGCAGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17994	MI0003082	mne-mir-93	Macaca nemestrina miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUUAACCGACCUACUGCUGAGCUAGCACUUCCCGAGCCCCCAG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17995	MI0003083	mne-mir-25	Macaca nemestrina miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
17996	MI0003084	mml-mir-183	Macaca mulatta miR-183 stem-loop	CCGCAGAACGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17997	MI0003085	mml-mir-96	Macaca mulatta miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
17998	MI0003086	ptr-mir-183	Pan troglodytes miR-183 stem-loop	CCGCAGAGUGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCAGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
17999	MI0003087	ptr-mir-96	Pan troglodytes miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
18000	MI0003088	ggo-mir-183	Gorilla gorilla miR-183 stem-loop	CCGCAGAGUGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCAGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
18001	MI0003089	ggo-mir-96	Gorilla gorilla miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
18002	MI0003090	sla-mir-183	Saguinus labiatus miR-183 stem-loop	CCGCAGAACGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCUCGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
18003	MI0003091	sla-mir-96	Saguinus labiatus miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
18004	MI0003092	mne-mir-183	Macaca nemestrina miR-183 stem-loop	CCGCAGAACGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
18005	MI0003093	mne-mir-96	Macaca nemestrina miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
18006	MI0003094	ppa-mir-183	Pan paniscus miR-183 stem-loop	CCGCAGAGUGUGACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCAGUCAGUGAAUUACCGAAGGGCCAUAAACAGAGCAGAGACAGAUCCACGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
18007	MI0003095	ppa-mir-96	Pan paniscus miR-96 stem-loop	UGGCCGAUUUUGGCACUAGCACAUUUUUGCUUGUGUCUCUCCGCUCUGAGCAAUCAUGUGCAGUGCCAAUAUGGGAAA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
18008	MI0003096	ggo-mir-106a	Gorilla gorilla miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
18009	MI0003097	ggo-mir-19b-2	Gorilla gorilla miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
18010	MI0003098	ggo-mir-92-2	Gorilla gorilla miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	29
18011	MI0003099	age-mir-106a	Ateles geoffroyi miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
18012	MI0003100	age-mir-19b-2	Ateles geoffroyi miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUACAUGUAUAUAUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUCAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
18013	MI0003101	age-mir-92-2	Ateles geoffroyi miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	28
18014	MI0003102	ppa-mir-106a	Pan paniscus miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
18015	MI0003103	ppa-mir-19b-2	Pan paniscus miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
18016	MI0003104	ppa-mir-92-2	Pan paniscus miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	34
18017	MI0003105	lca-mir-19b-2	Lemur catta miR-19b-2 stem-loop	AUACUGCUACUCACGAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUACAUAAGGCUGUGCAAAUCCAUGCAAAACUGAUCGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
18018	MI0003106	lca-mir-92-2	Lemur catta miR-92-2 stem-loop	UCAUCCGUGGGUGGGGAUUUGUUGCAUUACUUGUGUUAUAUGUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	31
18019	MI0003107	mml-mir-106a	Macaca mulatta miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
18020	MI0003108	mml-mir-19b-2	Macaca mulatta miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	32
18021	MI0003109	ppy-mir-106a	Pongo pygmaeus miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
18022	MI0003110	ppy-mir-19b-2	Pongo pygmaeus miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
18023	MI0003111	ppy-mir-92-2	Pongo pygmaeus miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	35
18024	MI0003112	ptr-mir-106a	Pan troglodytes miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
18025	MI0003113	ptr-mir-19b-2	Pan troglodytes miR-19b-2 stem-loop	GACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
18026	MI0003114	ptr-mir-92-2	Pan troglodytes miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCCACAAAAGUAUUGCACUUGUCCCGGCCUGUGAGAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	37
18027	MI0003115	sla-mir-106a	Saguinus labiatus miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
18028	MI0003116	sla-mir-19b-2	Saguinus labiatus miR-19b-2 stem-loop	ACAUUGCUACUUACAGUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUACAUGUAUAUAUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
18029	MI0003117	sla-mir-92-2	Saguinus labiatus miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	36
18030	MI0003118	lla-mir-19b-2	Lagothrix lagotricha miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUACAUGUAUAUAUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUCAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
18031	MI0003119	lla-mir-92-2	Lagothrix lagotricha miR-92-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	30
18032	MI0003120	mne-mir-106a	Macaca nemestrina miR-106a stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
18033	MI0003121	mne-mir-19b-2	Macaca nemestrina miR-19b-2 stem-loop	ACAUUGCUACUUACAAUUAGUUUUGCAGGUUUGCAUUUCAGCGUAUAUAUGUAUAUGUGGCUGUGCAAAUCCAUGCAAAACUGAUUGUGAUAAUGU	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
18034	MI0003122	mne-mir-92	Macaca nemestrina miR-92 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA	Berezikov et al. used primers designed from human miRNA gene flanking sequence to amplify miRNA precursor regions in primates [1].  The expression of the mature miRNA was not validated. 	33
18035	MI0003123	hsa-mir-488	Homo sapiens miR-488 stem-loop	GAGAAUCAUCUCUCCCAGAUAAUGGCACUCUCAAACAAGUUUCCAAAUUGUUUGAAAGGCUAUUUCUUGGUCAGAUGACUCUC	Bentwich et al. identified a product from the 5' arm of this precursor, and named it miR-488 [1].  Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product is therefore renamed miR-488*. miR-488 cloned in [2] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
18036	MI0003124	hsa-mir-489	Homo sapiens miR-489 stem-loop	GUGGCAGCUUGGUGGUCGUAUGUGUGACGCCAUUUACUUGAACCUUUAGGAGUGACAUCACAUAUACGGCAGCUAAACUGCUAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18037	MI0003125	hsa-mir-490	Homo sapiens miR-490 stem-loop	UGGAGGCCUUGCUGGUUUGGAAAGUUCAUUGUUCGACACCAUGGAUCUCCAGGUGGGUCAAGUUUAGAGAUGCACCAACCUGGAGGACUCCAUGCUGUUGAGCUGUUCACAAGCAGCGGACACUUCCA		5
18038	MI0003126	hsa-mir-491	Homo sapiens miR-491 stem-loop	UUGACUUAGCUGGGUAGUGGGGAACCCUUCCAUGAGGAGUAGAACACUCCUUAUGCAAGAUUCCCUUCUACCUGGCUGGGUUGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18039	MI0003127	hsa-mir-511-1	Homo sapiens miR-511-1 stem-loop	CAAUAGACACCCAUCGUGUCUUUUGCUCUGCAGUCAGUAAAUAUUUUUUUGUGAAUGUGUAGCAAAAGACAGAAUGGUGGUCCAUUG		5
18040	MI0003128	hsa-mir-511-2	Homo sapiens miR-511-2 stem-loop	CAAUAGACACCCAUCGUGUCUUUUGCUCUGCAGUCAGUAAAUAUUUUUUUGUGAAUGUGUAGCAAAAGACAGAAUGGUGGUCCAUUG		5
18041	MI0003129	hsa-mir-146b	Homo sapiens miR-146b stem-loop	CCUGGCACUGAGAACUGAAUUCCAUAGGCUGUGAGCUCUAGCAAUGCCCUGUGGACUCAGUUCUGGUGCCCGG		5
18042	MI0003130	hsa-mir-202	Homo sapiens miR-202 stem-loop	CGCCUCAGAGCCGCCCGCCGUUCCUUUUUCCUAUGCAUAUACUUCUUUGAGGAUCUGGCCUAAAGAGGUAUAGGGCAUGGGAAAACGGGGCGGUCGGGUCCUCCCCAGCG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18043	MI0003131	hsa-mir-492	Homo sapiens miR-492 stem-loop	CAACUACAGCCACUACUACAGGACCAUCGAGGACCUGCGGGACAAGAUUCUUGGUGCCACCAUUGAGAACGCCAGGAUUGUCCUGCAGAUCAACAAUGCUCAACUGGCUGCAGAUG		5
18044	MI0003132	hsa-mir-493	Homo sapiens miR-493 stem-loop	CUGGCCUCCAGGGCUUUGUACAUGGUAGGCUUUCAUUCAUUCGUUUGCACAUUCGGUGAAGGUCUACUGUGUGCCAGGCCCUGUGCCAG	The mature miRNA sequences were named miR-493-5p and miR-493-3p in [1,2] and here.  Landgraf et al. showed that the 3' product is the predominant one [3].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
18045	MI0003133	hsa-mir-432	Homo sapiens miR-432 stem-loop	UGACUCCUCCAGGUCUUGGAGUAGGUCAUUGGGUGGAUCCUCUAUUUCCUUACGUGGGCCACUGGAUGGCUCCUCCAUGUCUUGGAGUAGAUCA		5
18046	MI0003134	hsa-mir-494	Homo sapiens miR-494 stem-loop	GAUACUCGAAGGAGAGGUUGUCCGUGUUGUCUUCUCUUUAUUUAUGAUGAAACAUACACGGGAAACCUCUUUUUUAGUAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
18047	MI0003135	hsa-mir-495	Homo sapiens miR-495 stem-loop	UGGUACCUGAAAAGAAGUUGCCCAUGUUAUUUUCGCUUUAUAUGUGACGAAACAAACAUGGUGCACUUCUUUUUCGGUAUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18048	MI0003136	hsa-mir-496	Homo sapiens miR-496 stem-loop	CCCAAGUCAGGUACUCGAAUGGAGGUUGUCCAUGGUGUGUUCAUUUUAUUUAUGAUGAGUAUUACAUGGCCAAUCUCCUUUCGGUACUCAAUUCUUCUUGGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations.  miR-496 cloned in [2] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
18049	MI0003137	hsa-mir-193b	Homo sapiens miR-193b stem-loop	GUGGUCUCAGAAUCGGGGUUUUGAGGGCGAGAUGAGUUUAUGUUUUAUCCAACUGGCCCUCAAAGUCCCGCUUUUGGGGUCAU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	5
18050	MI0003138	hsa-mir-497	Homo sapiens miR-497 stem-loop	CCACCCCGGUCCUGCUCCCGCCCCAGCAGCACACUGUGGUUUGUACGGCACUGUGGCCACGUCCAAACCACACUGUGGUGUUAGAGCGAGGGUGGGGGAGGCACCGCCGAGG		5
18051	MI0003139	hsa-mir-181d	Homo sapiens miR-181d stem-loop	GUCCCCUCCCCUAGGCCACAGCCGAGGUCACAAUCAACAUUCAUUGUUGUCGGUGGGUUGUGAGGACUGAGGCCAGACCCACCGGGGGAUGAAUGUCACUGUGGCUGGGCCAGACACGGCUUAAGGGGAAUGGGGAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18052	MI0003140	hsa-mir-512-1	Homo sapiens miR-512-1 stem-loop	UCUCAGUCUGUGGCACUCAGCCUUGAGGGCACUUUCUGGUGCCAGAAUGAAAGUGCUGUCAUAGCUGAGGUCCAAUGACUGAGG		5
18053	MI0003141	hsa-mir-512-2	Homo sapiens miR-512-2 stem-loop	GGUACUUCUCAGUCUGUGGCACUCAGCCUUGAGGGCACUUUCUGGUGCCAGAAUGAAAGUGCUGUCAUAGCUGAGGUCCAAUGACUGAGGCGAGCACC		5
18054	MI0003142	hsa-mir-498	Homo sapiens miR-498 stem-loop	AACCCUCCUUGGGAAGUGAAGCUCAGGCUGUGAUUUCAAGCCAGGGGGCGUUUUUCUAUAACUGGAUGAAAAGCACCUCCAGAGCUUGAAGCUCACAGUUUGAGAGCAAUCGUCUAAGGAAGUU		5
18055	MI0003143	hsa-mir-520e	Homo sapiens miR-520e stem-loop	UCUCCUGCUGUGACCCUCAAGAUGGAAGCAGUUUCUGUUGUCUGAAAGGAAAGAAAGUGCUUCCUUUUUGAGGGUUACUGUUUGAGA		5
18056	MI0003144	hsa-mir-515-1	Homo sapiens miR-515-1 stem-loop	UCUCAUGCAGUCAUUCUCCAAAAGAAAGCACUUUCUGUUGUCUGAAAGCAGAGUGCCUUCUUUUGGAGCGUUACUGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18057	MI0003145	hsa-mir-519e	Homo sapiens miR-519e stem-loop	UCUCAUGCAGUCAUUCUCCAAAAGGGAGCACUUUCUGUUUGAAAGAAAACAAAGUGCCUCCUUUUAGAGUGUUACUGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18058	MI0003146	hsa-mir-520f	Homo sapiens miR-520f stem-loop	UCUCAGGCUGUGACCCUCUAAAGGGAAGCGCUUUCUGUGGUCAGAAAGAAAAGCAAGUGCUUCCUUUUAGAGGGUUACCGUUUGGGA		5
18059	MI0003147	hsa-mir-515-2	Homo sapiens miR-515-2 stem-loop	UCUCAUGCAGUCAUUCUCCAAAAGAAAGCACUUUCUGUUGUCUGAAAGCAGAGUGCCUUCUUUUGGAGCGUUACUGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18060	MI0003148	hsa-mir-519c	Homo sapiens miR-519c stem-loop	UCUCAGCCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAAAGUGCAUCUUUUUAGAGGAUUACAGUUUGAGA	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here).  Landgraf et al. confirm mature miRNA expression from both arms of the precursor [2], leading to the -5p, -3p designations.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18061	MI0003149	hsa-mir-520a	Homo sapiens miR-520a stem-loop	CUCAGGCUGUGACCCUCCAGAGGGAAGUACUUUCUGUUGUCUGAGAGAAAAGAAAGUGCUUCCCUUUGGACUGUUUCGGUUUGAG		5
18062	MI0003150	hsa-mir-526b	Homo sapiens miR-526b stem-loop	UCAGGCUGUGACCCUCUUGAGGGAAGCACUUUCUGUUGUCUGAAAGAAGAGAAAGUGCUUCCUUUUAGAGGCUUACUGUCUGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18063	MI0003151	hsa-mir-519b	Homo sapiens miR-519b stem-loop	CAUGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAAAGUGCAUCCUUUUAGAGGUUUACUGUUUG	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here).  Landgraf et al. confirm mature miRNA expression from both arms of the precursor [2], leading to the -5p, -3p designations.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18064	MI0003152	hsa-mir-525	Homo sapiens miR-525 stem-loop	CUCAAGCUGUGACUCUCCAGAGGGAUGCACUUUCUCUUAUGUGAAAAAAAAGAAGGCGCUUCCCUUUAGAGCGUUACGGUUUGGG	The mature products were previously named miR-525 and miR-525* in [1] and here.  Landgraf et al. show that both products are significantly expressed, prompting a renaming to miR-525-5p and miR-525-3p [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18065	MI0003153	hsa-mir-523	Homo sapiens miR-523 stem-loop	UCUCAUGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAACGCGCUUCCCUAUAGAGGGUUACCCUUUGAGA	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here and in [1]).  Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product is renamed miR-523* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18066	MI0003154	hsa-mir-518f	Homo sapiens miR-518f stem-loop	UCUCAUGCUGUGACCCUCUAGAGGGAAGCACUUUCUCUUGUCUAAAAGAAAAGAAAGCGCUUCUCUUUAGAGGAUUACUCUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18067	MI0003155	hsa-mir-520b	Homo sapiens miR-520b stem-loop	CCCUCUACAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGG		5
18068	MI0003156	hsa-mir-518b	Homo sapiens miR-518b stem-loop	UCAUGCUGUGGCCCUCCAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAACAAAGCGCUCCCCUUUAGAGGUUUACGGUUUGA		5
18069	MI0003157	hsa-mir-526a-1	Homo sapiens miR-526a-1 stem-loop	CUCAGGCUGUGACCCUCUAGAGGGAAGCACUUUCUGUUGCUUGAAAGAAGAGAAAGCGCUUCCUUUUAGAGGAUUACUCUUUGAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18070	MI0003158	hsa-mir-520c	Homo sapiens miR-520c stem-loop	UCUCAGGCUGUCGUCCUCUAGAGGGAAGCACUUUCUGUUGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGGUUACCGUUUGAGA	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here).  Landgraf et al. confirm mature miRNA expression from both arms of the precursor [2], leading to the -5p, -3p designations.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18071	MI0003159	hsa-mir-518c	Homo sapiens miR-518c stem-loop	GCGAGAAGAUCUCAUGCUGUGACUCUCUGGAGGGAAGCACUUUCUGUUGUCUGAAAGAAAACAAAGCGCUUCUCUUUAGAGUGUUACGGUUUGAGAAAAGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18072	MI0003160	hsa-mir-524	Homo sapiens miR-524 stem-loop	UCUCAUGCUGUGACCCUACAAAGGGAAGCACUUUCUCUUGUCCAAAGGAAAAGAAGGCGCUUCCCUUUGGAGUGUUACGGUUUGAGA		5
18073	MI0003161	hsa-mir-517a	Homo sapiens miR-517a stem-loop	UCUCAGGCAGUGACCCUCUAGAUGGAAGCACUGUCUGUUGUAUAAAAGAAAAGAUCGUGCAUCCCUUUAGAGUGUUACUGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18074	MI0003162	hsa-mir-519d	Homo sapiens miR-519d stem-loop	UCCCAUGCUGUGACCCUCCAAAGGGAAGCGCUUUCUGUUUGUUUUCUCUUAAACAAAGUGCCUCCCUUUAGAGUGUUACCGUUUGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18075	MI0003163	hsa-mir-521-2	Homo sapiens miR-521-2 stem-loop	UCUCGGGCUGUGACUCUCCAAAGGGAAGAAUUUUCUCUUGUCUAAAAGAAAAGAACGCACUUCCCUUUAGAGUGUUACCGUGUGAGA		5
18076	MI0003164	hsa-mir-520d	Homo sapiens miR-520d stem-loop	UCUCAAGCUGUGAGUCUACAAAGGGAAGCCCUUUCUGUUGUCUAAAAGAAAAGAAAGUGCUUCUCUUUGGUGGGUUACGGUUUGAGA	The mature products were previously named miR-520d and miR-520d* here and in [1].  Landgraf et al. show that both products may be significantly expressed [2].  They are therefore renamed miR-520d-5p and miR-520d-3p. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18077	MI0003165	hsa-mir-517b	Homo sapiens miR-517b stem-loop	GUGACCCUCUAGAUGGAAGCACUGUCUGUUGUCUAAGAAAAGAUCGUGCAUCCCUUUAGAGUGUUAC		5
18078	MI0003166	hsa-mir-520g	Homo sapiens miR-520g stem-loop	UCCCAUGCUGUGACCCUCUAGAGGAAGCACUUUCUGUUUGUUGUCUGAGAAAAAACAAAGUGCUUCCCUUUAGAGUGUUACCGUUUGGGA		5
18079	MI0003167	hsa-mir-516b-2	Homo sapiens miR-516b-2 stem-loop	UCUCAUGAUGUGACCAUCUGGAGGUAAGAAGCACUUUGUGUUUUGUGAAAGAAAGUGCUUCCUUUCAGAGGGUUACUCUUUGAGA		5
18080	MI0003168	hsa-mir-526a-2	Homo sapiens miR-526a-2 stem-loop	GUGACCCUCUAGAGGGAAGCACUUUCUGUUGAAAGAAAAGAACAUGCAUCCUUUCAGAGGGUUAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18081	MI0003169	hsa-mir-518e	Homo sapiens miR-518e stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUUGGCUAAAAGAAAAGAAAGCGCUUCCCUUCAGAGUGUUAACGCUUUGAGA	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here and in [1]).  Landgraf et al. show that the 3' product is the predominant one [2], so the 5' product is renamed miR-518e*.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18082	MI0003170	hsa-mir-518a-1	Homo sapiens miR-518a stem-loop	UCUCAAGCUGUGACUGCAAAGGGAAGCCCUUUCUGUUGUCUGAAAGAAGAGAAAGCGCUUCCCUUUGCUGGAUUACGGUUUGAGA	The 5' mature product was previously named miR-527 in [1] and here. Landgraf et al. showed that products from both arms are approximately equally expressed [2].  miR-527 is renamed miR-518a-5p here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations.  miR-518a-5p cloned in [2] has a 1 nt 3' extension (A), which is incompatible with the genome sequence. 	5
18083	MI0003171	hsa-mir-518d	Homo sapiens miR-518d stem-loop	UCCCAUGCUGUGACCCUCUAGAGGGAAGCACUUUCUGUUGUCUGAAAGAAACCAAAGCGCUUCCCUUUGGAGCGUUACGGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18084	MI0003172	hsa-mir-516b-1	Homo sapiens miR-516b-1 stem-loop	UCUCAGGCUGUGACCAUCUGGAGGUAAGAAGCACUUUCUGUUUUGUGAAAGAAAAGAAAGUGCUUCCUUUCAGAGGGUUACUCUUUGAGA		5
18085	MI0003173	hsa-mir-518a-2	Homo sapiens miR-518a-2 stem-loop	UCUCAAGCUGUGGGUCUGCAAAGGGAAGCCCUUUCUGUUGUCUAAAAGAAGAGAAAGCGCUUCCCUUUGCUGGAUUACGGUUUGAGA	The 5' mature product was previously named miR-527 in [1] and here. Landgraf et al. showed that products from both arms are approximately equally expressed [2].  miR-527 is renamed miR-518a-5p here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations.  miR-518a-5p cloned in [2] has a 1 nt 3' extension (A), which is incompatible with the genome sequence. 	5
18086	MI0003174	hsa-mir-517c	Homo sapiens miR-517c stem-loop	GAAGAUCUCAGGCAGUGACCCUCUAGAUGGAAGCACUGUCUGUUGUCUAAGAAAAGAUCGUGCAUCCUUUUAGAGUGUUACUGUUUGAGAAAAUC		5
18087	MI0003175	hsa-mir-520h	Homo sapiens miR-520h stem-loop	UCCCAUGCUGUGACCCUCUAGAGGAAGCACUUUCUGUUUGUUGUCUGAGAAAAAACAAAGUGCUUCCCUUUAGAGUUACUGUUUGGGA		5
18088	MI0003176	hsa-mir-521-1	Homo sapiens miR-521-1 stem-loop	UCUCAGGCUGUGACCCUCCAAAGGGAAGAACUUUCUGUUGUCUAAAAGAAAAGAACGCACUUCCCUUUAGAGUGUUACCGUGUGAGA		5
18089	MI0003177	hsa-mir-522	Homo sapiens miR-522 stem-loop	UCUCAGGCUGUGUCCCUCUAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAAAAUGGUUCCCUUUAGAGUGUUACGCUUUGAGA	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here and in [1]).  Landgraf et al. show that the 3' product is the predominant one [2], so the 5' product is renamed miR-522*.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18090	MI0003178	hsa-mir-519a-1	Homo sapiens miR-519a stem-loop	CUCAGGCUGUGACACUCUAGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAGGAAAGUGCAUCCUUUUAGAGUGUUACUGUUUGAG	The 5' arm of this precursor expresses a product related to miR-526 (previously named miR-526c here and in [1]).  Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product is renamed miR-519a* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18091	MI0003179	hsa-mir-527	Homo sapiens miR-527 stem-loop	UCUCAAGCUGUGACUGCAAAGGGAAGCCCUUUCUGUUGUCUAAAAGAAAAGAAAGUGCUUCCCUUUGGUGAAUUACGGUUUGAGA	miR-527 cloned in [2] has a 1 nt 3' extension (A), which is incompatible with the genome sequence. 	5
18092	MI0003180	hsa-mir-516a-1	Homo sapiens miR-516a-1 stem-loop	UCUCAGGCUGUGACCUUCUCGAGGAAAGAAGCACUUUCUGUUGUCUGAAAGAAAAGAAAGUGCUUCCUUUCAGAGGGUUACGGUUUGAGA		5
18093	MI0003181	hsa-mir-516a-2	Homo sapiens miR-516a-2 stem-loop	UCUCAGGUUGUGACCUUCUCGAGGAAAGAAGCACUUUCUGUUGUCUGAAAGAAAAGAAAGUGCUUCCUUUCAGAGGGUUACGGUUUGAGA		5
18094	MI0003182	hsa-mir-519a-2	Homo sapiens miR-519a-2 stem-loop	UCUCAGGCUGUGUCCCUCUACAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAGGAAAGUGCAUCCUUUUAGAGUGUUACUGUUUGAGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18095	MI0003183	hsa-mir-499	Homo sapiens miR-499 stem-loop	GCCCUGUCCCCUGUGCCUUGGGCGGGCGGCUGUUAAGACUUGCAGUGAUGUUUAACUCCUCUCCACGUGAACAUCACAGCAAGUCUGUGCUGCUUCCCGUCCCUACGCUGCCUGGGCAGGGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18096	MI0003184	hsa-mir-500	Homo sapiens miR-500 stem-loop	GCUCCCCCUCUCUAAUCCUUGCUACCUGGGUGAGAGUGCUGUCUGAAUGCAAUGCACCUGGGCAAGGAUUCUGAGAGCGAGAGC	Bentwich et al. identified a mature product from the 3' arm of this precursor, and named it miR-500 [1].  Landgraf et al. later showed that the 5' product was the predominant one [2].  The 3' product is therefore renamed miR-500*. 	5
18097	MI0003185	hsa-mir-501	Homo sapiens miR-501 stem-loop	GCUCUUCCUCUCUAAUCCUUUGUCCCUGGGUGAGAGUGCUUUCUGAAUGCAAUGCACCCGGGCAAGGAUUCUGAGAGGGUGAGC		5
18098	MI0003186	hsa-mir-502	Homo sapiens miR-502 stem-loop	UGCUCCCCCUCUCUAAUCCUUGCUAUCUGGGUGCUAGUGCUGGCUCAAUGCAAUGCACCUGGGCAAGGAUUCAGAGAGGGGGAGCU	Extensive cloning studies suggest that the 3' product may be the predominant one [2]. 	5
18099	MI0003187	hsa-mir-450a-2	Homo sapiens miR-450a-2 stem-loop	CCAAAGAAAGAUGCUAAACUAUUUUUGCGAUGUGUUCCUAAUAUGUAAUAUAAAUGUAUUGGGGACAUUUUGCAUUCAUAGUUUUGUAUCAAUAAUAUGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18100	MI0003188	hsa-mir-503	Homo sapiens miR-503 stem-loop	UGCCCUAGCAGCGGGAACAGUUCUGCAGUGAGCGAUCGGUGCUCUGGGGUAUUGUUUCCGCUGCCAGGGUA		5
18101	MI0003189	hsa-mir-504	Homo sapiens miR-504 stem-loop	GCUGCUGUUGGGAGACCCUGGUCUGCACUCUAUCUGUAUUCUUACUGAAGGGAGUGCAGGGCAGGGUUUCCCAUACAGAGGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18102	MI0003190	hsa-mir-505	Homo sapiens miR-505 stem-loop	GAUGCACCCAGUGGGGGAGCCAGGAAGUAUUGAUGUUUCUGCCAGUUUAGCGUCAACACUUGCUGGUUUCCUCUCUGGAGCAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18103	MI0003191	hsa-mir-513a-1	Homo sapiens miR-513a-1 stem-loop	GGGAUGCCACAUUCAGCCAUUCAGCGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGGGUAAUGUACAGCAUGCACUGCAUAUGUGGUGUCCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18104	MI0003192	hsa-mir-513a-2	Homo sapiens miR-513a-2 stem-loop	GGAUGCCACAUUCAGCCAUUCAGUGUGCAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGGGUAAUGUACAGCAUGCACUGCAUAUGUGGUGUCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18105	MI0003193	hsa-mir-506	Homo sapiens miR-506 stem-loop	GCCACCACCAUCAGCCAUACUAUGUGUAGUGCCUUAUUCAGGAAGGUGUUACUUAAUAGAUUAAUAUUUGUAAGGCACCCUUCUGAGUAGAGUAAUGUGCAACAUGGACAACAUUUGUGGUGGC		5
18106	MI0003194	hsa-mir-507	Homo sapiens miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAGAAGUGCCAUGCAUGUGUCUAGAAAUAUGUUUUGCACCUUUUGGAGUGAAAUAAUGCACAACAGAUAC		5
18107	MI0003195	hsa-mir-508	Homo sapiens miR-508 stem-loop	CCACCUUCAGCUGAGUGUAGUGCCCUACUCCAGAGGGCGUCACUCAUGUAAACUAAAACAUGAUUGUAGCCUUUUGGAGUAGAGUAAUACACAUCACGUAACGCAUAUUUGGUGG		5
18108	MI0003196	hsa-mir-509-1	Homo sapiens miR-509-1 stem-loop	CAUGCUGUGUGUGGUACCCUACUGCAGACAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGGUAGAGUACUGCAUGACACAUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The cloned miR-509-5p sequence from [3] includes a 1 nt extension at the 3' end (A), which is incompatible with the genome sequence. 	5
18109	MI0003197	hsa-mir-510	Homo sapiens miR-510 stem-loop	GUGGUGUCCUACUCAGGAGAGUGGCAAUCACAUGUAAUUAGGUGUGAUUGAAACCUCUAAGAGUGGAGUAACAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18110	MI0003198	hsa-mir-514-1	Homo sapiens miR-514-1 stem-loop	AACAUGUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACACGUACG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18111	MI0003199	hsa-mir-514-2	Homo sapiens miR-514-2 stem-loop	GUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAACUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18112	MI0003200	hsa-mir-514-3	Homo sapiens miR-514-3 stem-loop	GUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAACUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18113	MI0003201	osa-MIR528	Oryza sativa miR528 stem-loop	AGUGGAAGGGGCAUGCAGAGGAGCAGGAGAUUCAGUUUGAAGCUGGACUUCACUUUUGCCUCUCUCUCCUGUGCUUGCCUCUUCCAUU		7
18114	MI0003202	osa-MIR529a	Oryza sativa miR529a stem-loop	GAAGAAGAGAGAGAGUACAGCCUUAGUUCAGAUCACAUAUGACUAUCUUUUGCGAGUCUGAUCGAUACUCUGAUGAAGGCUGUACCCUCUCUCUUCUUC		7
18115	MI0003203	osa-MIR530	Oryza sativa miR530 stem-loop	UGCAUUUGCACCUGCACCUACAGAGAGGAAGAUGAAGCAGCAAGCUAGCAAUACGUGCUUGAUCGCUAUACGCUAGCUUCUUGCACACAAUGUUGUUCCUGGUCUCUUCCUGAUCCCUAGGUGCAGAGGCAGAUGCAACUAUGUCAUAGA		7
18116	MI0003204	osa-MIR531	Oryza sativa miR531 stem-loop	GGCGCCGCCGAGCCUUGCUCGCCGGGGCUGCGUGCCGCCAUAGCUGGCGCGCAUCCCCGUCGAGCGUUGCUCGACGGUGCC		7
18117	MI0003205	hsa-mir-532	Homo sapiens miR-532 stem-loop	CGACUUGCUUUCUCUCCUCCAUGCCUUGAGUGUAGGACCGUUGGCAUCUUAAUUACCCUCCCACACCCAAGGCUUGCAAAAAAGCGAGCCU		5
18118	MI0003206	mmu-mir-532	Mus musculus miR-532 stem-loop	CAGAUUUGCUUUUUCUCUUCCAUGCCUUGAGUGUAGGACCGUUGACAUCUUAAUUACCCUCCCACACCCAAGGCUUGCAGGAGAGCAAGCCUUCUC		6
18119	MI0003207	fru-let-7h	Fugu rubripes let-7h stem-loop	UGUGGUGAGGUAGUAAGUUGUGUUGUUGUAGGGGAAGAUUGUGCACCCUGUUCAGGAGAUAACUAUACAACUUACUGCCUUCCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18120	MI0003208	tni-let-7h	Tetraodon nigroviridis let-7h stem-loop	AAUUGGCUUUGCUGUGGUGAGGUAGUAAGUUGUGUUGUUGUUGGGGAUCAAGAUUGUGCACCCUGUCAAGGAGAUAACUAUACAACUUACUGCCUUCCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18121	MI0003209	fru-mir-223	Fugu rubripes miR-223 stem-loop	CACUUAGUGUAUUUGACAAGCUGUUCUUGACACUCUUUAUACGCGAGUGUCAGUUUGUCAAAUACCCCAAGUGAGGUGUCACUUGUCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18122	MI0003210	tni-mir-223	Tetraodon nigroviridis miR-223 stem-loop	CAGGCCCUUCACUUAGUGUAUUUGACAAGCUGUGUUUGACACUCUGUAUCUGCGAGUGUCAGUUUGUCAAAUACCCCAAGUGAGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18123	MI0003211	fru-mir-124-3	Fugu rubripes miR-124-3 stem-loop	GGUUUGAGCUCUUUGUGUUCACAGUGGACCUUGAUUUAAUUUCAAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGAAGCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18124	MI0003212	tni-mir-124-3	Tetraodon nigroviridis miR-124-3 stem-loop	GGUUUGAGCUCUUUGUGUUCACAGUGGACCUUGAUUUAAUUUCAAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAGAA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18125	MI0003213	fru-let-7e	Fugu rubripes let-7e stem-loop	GCUGUCCUUGGGGUUGAGGUAGUAGAUUGAAUAGUUGUGGGGUUGUGUGACCUCUUAGUGAGAUAACUAUACAAUCUACUGUCUUUCCUAAGGAGACAGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18126	MI0003214	tni-let-7e	Tetraodon nigroviridis let-7e stem-loop	GCUGUCCUUGGGGCUGAGGUAGUAGAUUGAAUAGUUGUGGGGUUGUGUGACCUCUAUGUGAGAUAACUAUACAAUCUACUGUCUUUCCCAAGGAGACAGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18127	MI0003215	fru-mir-219-2	Fugu rubripes miR-219-2 stem-loop	UCGGAGCUGAUUGUCCAAACGCAAUUCUUGCGUCUGCCUUUGUGAAACCAGGAGUUGUGGAUGGACAUCACGCCCCUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18128	MI0003216	tni-mir-219-2	Tetraodon nigroviridis miR-219-2 stem-loop	UCGGAGCUGAUUGUCCAAACGCAAUUCUUGCGUCUGCCUUUGUGAAACCAGGAGUUGUGGAUGGACAUCACGCCCCUGAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18129	MI0003217	fru-mir-101a	Fugu rubripes miR-101a stem-loop	UGCCCUGGUUCAGUUAUCACAGUGCUGAUGCUGUCCCCAUCGAAGGUACAGUACUGUGAUAACUGAAGGAUGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18130	MI0003218	tni-mir-101a	Tetraodon nigroviridis miR-101a stem-loop	UGCCCUGGUUCAGUUAUCACAGUGCUGAUGCUGUCCCCAUCGAAGGUACAGUACUGUGAUAACUGAAGGAUGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18131	MI0003219	fru-mir-222	Fugu rubripes miR-222 stem-loop	UCAGUUGCUCAGUAGGCAGUGUAGAUCCUGUGUAGCAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18132	MI0003220	tni-mir-222	Tetraodon nigroviridis miR-222 stem-loop	CAGUUGCUCAGUAGGCAGUGUAGAUCCUGUGUAGCAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18133	MI0003221	fru-mir-221	Fugu rubripes miR-221 stem-loop	CCUGAACCUGGCAUACAAUGUAGAUUUCUGUGUGCUUGGAUUCUACAGCUACAUUGUCUGCUGGGUUUCCGGAUAGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18134	MI0003222	tni-mir-221	Tetraodon nigroviridis miR-221 stem-loop	CCUGAACCUGGCAUACAAUGUAGAUUUCUGUGUGCUUGGAUUCUACAGCUACAUUGUCUGCUGGGUUUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18135	MI0003223	fru-mir-142a	Fugu rubripes miR-142a stem-loop	ACAGUGCAGUCAUCCAUAAAGUAGAAAGCACUACUAAACUCUUUGCCACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18136	MI0003224	tni-mir-142a	Tetraodon nigroviridis miR-142a stem-loop	GUACAGUGCAGUCAUCCAUAAAGUAGAAAGCACUACUAAACUCUUCGCCACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18137	MI0003225	fru-mir-9-1	Fugu rubripes miR-9-1 stem-loop	GGGGUUGUCUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGACGUACAAUCUUCAUAAAGCUAGAUAACCGAAAGUAACAAGAAUCCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18138	MI0003226	tni-mir-9-1	Tetraodon nigroviridis miR-9-1 stem-loop	CAGAGGGGUUGUCUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGACGUACAAUCUUCAUAAAGCUAGAUAACCGAAAGUAACAAGAAUCCCAUUA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18139	MI0003227	fru-mir-23a-2	Fugu rubripes miR-23a-2 stem-loop	AGCUGGAGGGAUUCCUGGCAGAGUGAUUUGGCUGUGAUGUAAUGUAAAUCACAUUGCCAGGGAUUUCCAACCAGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18140	MI0003228	tni-mir-23a-2	Tetraodon nigroviridis miR-23a-2 stem-loop	AGCUGGAGGGAUUCCUGGCAGAGUGAUUUGGCUGUGAUGUAAUGUAAAUCACAUUGCCAGGGAUUUCCAACCAGCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18141	MI0003229	fru-mir-25	Fugu rubripes miR-25 stem-loop	GCUGGUGUUGAGAGGCGGAGACUUGGGCAAUUGCCGGCCAUCACAGAGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18142	MI0003230	tni-mir-25	Tetraodon nigroviridis miR-25 stem-loop	GCUGGUGUUGAGAGGCGGAGACUUGGGCAAUUGCCGGCCAUCACAGAGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18143	MI0003231	fru-mir-17-1	Fugu rubripes miR-17-1 stem-loop	GUCUGUGUAUUGCCAAAGUGCUUACAGUGCAGGUAGUUCUAUGUGACACCUACUGCAAUGGAGGCACUUACAGCAGUACUCUUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18144	MI0003232	tni-mir-17-1	Tetraodon nigroviridis miR-17-1 stem-loop	GUCUGUGUAUUGCCAAAGUGCUUACAGUGCAGGUAGUACUAUGUAACACCUACUGCAAUGGAGGCACUUACAGCAGUACUCUUGAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18145	MI0003233	fru-mir-18	Fugu rubripes miR-18 stem-loop	UUGUGCUAAGGUGCAUCUAGUGCAGAUAGUGAAAUAGACUAGCACCUACUGCCCUAAGUGCUCCUUCUGGCAUAAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18146	MI0003234	tni-mir-18	Tetraodon nigroviridis miR-18 stem-loop	UUGUGCUAAGGUGCAUCUAGUGCAGAUAGUGAAAUAGACUAGCACCUACUGCCCUAAGUGCUCCUUCUGGCAUAAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18147	MI0003235	fru-mir-19a	Fugu rubripes miR-19a stem-loop	GCAGUUCUCUGCUAGUUUUGCAUAGUUGCACUACAAGAAUAGAGGAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18148	MI0003236	tni-mir-19a	Tetraodon nigroviridis miR-19a stem-loop	GCAGUUCUCUGCUAGUUUUGCAUAGUUGCACUACAAGAAUAGAGGAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18149	MI0003237	fru-mir-19b	Fugu rubripes miR-19b stem-loop	GUCAGUUUUGCUGGUUUGCAUCCAGCUUUGUUACCGCGCUGUGCAAAUCCAUGCAAAACUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18150	MI0003238	tni-mir-19b	Tetraodon nigroviridis miR-19b stem-loop	CAAUCAUCGUUUGGUCAGUUUUGCUGGUUUGCAUUCAGCUUUGUUGCUGUGCUGUGCAAAUCCAUGCAAAACUGACU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18151	MI0003239	fru-mir-92-2	Fugu rubripes miR-92-2 stem-loop	CAGGUGGGGAUCAGUAGCAAUGCUGUGCACUGGAAGGUAUUGCACUUGUCCCGGCCUGUGUAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18152	MI0003240	tni-mir-92-2	Tetraodon nigroviridis miR-92-2 stem-loop	CUUCCCAUACAGGUGGGGAUGAGUAGCAAUGCUGUGUACUAGGAGGUAUUGCACUUGUCCCGGCCUGUGUAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18153	MI0003241	fru-mir-184	Fugu rubripes miR-184 stem-loop	CGCUCACAUCUCCUUAUCACUUUUCCAGCCCAGCUAUAGGUUUUGAAUCCGUUGGACGGAGAACUGAUAAGGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18154	MI0003242	tni-mir-184	Tetraodon nigroviridis miR-184 stem-loop	CGCUCACAUCUCCUUAUCACUUUUCCAGCCCAGCUAUAGCUUCUGAAUCCGUUGGACGGAGAACUGAUAAGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18155	MI0003243	dre-mir-184-2	Danio rerio miR-184-2 stem-loop	CACAUCUCCUUAUCACUUUUCCAGCCCAGCUAACGAUGGUGAAUCCGUUGGACGGAGAACUGAUAAGGGCAUGUGGCUG	This zebrafish miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	12
18156	MI0003244	fru-let-7a-3	Fugu rubripes let-7a-3 stem-loop	CAAGGUGAGGUAGUAGGUUGUAUAGUUUGUGGGAUGGCUUGGAUCCUACUCAGAUGAUAACUAUACAGUCUAUUACCUUCCUUGAGAGGUACAAUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18157	MI0003245	tni-let-7a-3	Tetraodon nigroviridis let-7a-3 stem-loop	CAAGGUGAGGUAGUAGGUUGUAUAGUUUGUGGGAUGGCUUGGAUCCUACUCAGAUUAUAACUAUACAGUCUAUUACCUUCCUUGAGAGGUACAAUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18158	MI0003246	fru-mir-187	Fugu rubripes miR-187 stem-loop	GUGGCCAUUUGGCCGGGCCAGGGGCUGCAACACAGGACAUGGGUCAUGCCUCUGCCCACCGCUCGUGUCUUGUGUUGCAGCCAGUGGAGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18159	MI0003247	tni-mir-187	Tetraodon nigroviridis miR-187 stem-loop	GGCUGCAACACAGGACAUGGGUCUUGCCUCUGCCCGCCGCUCGUGUCUUGUGUUGCAGCCAGUGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18160	MI0003248	fru-mir-137	Fugu rubripes miR-137 stem-loop	CUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUCACGUUGUUAUUGCUUAAGAAUACGCGUAGUUGAGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18161	MI0003249	tni-mir-137	Tetraodon nigroviridis miR-137 stem-loop	UCGACCACGGGUAUUCUUGGGUUGAUAAUACAGAUGUGGAUGUUAUUGCUUGAGAAUACGCGUAGUCGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18162	MI0003251	tni-mir-204b	Tetraodon nigroviridis miR-204b stem-loop	AUGUGACCUAUGGACUUCCCUUUGUUAUCCUAUGCCUGGACUCAAAAAAGGGGCUGGGAGGGCAAAGGGUUGCCCAGUUGUCAUAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18163	MI0003252	fru-mir-458	Fugu rubripes miR-458 stem-loop	UGCAGACAGCAGCGCCAUUUUCAGAGCUAUCAGUCAACGUGGUCAUAGCUCUUUAAAUGGUACUGCUGUAGGCAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18164	MI0003253	tni-mir-458	Tetraodon nigroviridis miR-458 stem-loop	GUGCAGACGGCAGCGCCAUUUUCAGAGCUAUCAGUGCCAGCGGGUCAUAGCUCUUUAAAUGGUUCUGCUGUAGGCAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18165	MI0003254	fru-mir-489	Fugu rubripes miR-489 stem-loop	CUUCUGAUACUGGUGGUGGCUUGGUGGUCGUAUGCAUGACGUCAUUUACUUCGAUGAUUGGAGUGACAUCAUAUGUACGGCUGCUAAACUGCUACAAGAGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18166	MI0003255	tni-mir-489	Tetraodon nigroviridis miR-489 stem-loop	UGGUGGUGGCCUGGUGGUCGUAUGCAUGACGUCAUUUACUUCGAUGAUUGGAGUGACAUCAUAUGUACGGCUGCUAAACCGCUACAAGAGAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18167	MI0003256	dre-mir-489	Danio rerio miR-489 stem-loop	ACUGACUUGAGUGGUGGCCUGGUGGUCGUAUGUAUGACGUCAUUUACUUCAAAGUUUGGAGUGACAUCAUAUGUACGGCUGCUAAACUGCUACAUGGCUCAUCA	miR-489 was predicted in zebrafish based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication), and later verified experimentally [1]. 	12
18168	MI0003257	fru-mir-192	Fugu rubripes miR-192 stem-loop	UGGGACGUGAGGUGAUGACCUAUGAAUUGACAGCCAGUAACUGGAGCCUCUGCCUGUCAGUUCUGUAGGCCACUGCUACGUU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18169	MI0003258	tni-mir-192	Tetraodon nigroviridis miR-192 stem-loop	CACGAGGUGAUGACCUAUGAAUUGACAGCCAGUAACUGGAGCCUCUGCCUGUCAGUUCUGUAGGCCACUGCUGCGUCCGUCCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18170	MI0003259	fru-mir-194	Fugu rubripes miR-194 stem-loop	CGCUGGAUGUAACAGCAACUCCAUGUGGAAGCUGUAUGUGAGUUCCAGUGGAAGUGCUGUUACCUGCAGAGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18171	MI0003260	tni-mir-194	Tetraodon nigroviridis miR-194 stem-loop	GCGCGCUGGAUGUAACAGCAACUCCAUGUGGAAGCUGUAUGUGUGUUCCAGUGGAAGUGCUGUUACCUGCAGAGAUCCACC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18172	MI0003261	fru-mir-142b	Fugu rubripes miR-142b stem-loop	ACAGUGCUGUCACCCAUAAAGUAGAAAGCACUACUAAACUAUUCUACACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGCACUGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18173	MI0003262	tni-mir-142b	Tetraodon nigroviridis miR-142b stem-loop	ACAGUGCUGUCACCCAUAAAGUAGAAAGCACUACUAAACGUCUUUACACAGUGUAGUGUUUCCUACUUUAUGGAUGAGUGCACUGU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18174	MI0003263	fru-mir-30b	Fugu rubripes miR-30b stem-loop	UUCCGGCUCAGUUGGUGUAAACAUCCUACACUCAGCUGUGAUCCUUUGCGGCAGAGGCUGAGAGAAGGUUGUUUACUUGAACUGGCUGGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18175	MI0003264	tni-mir-30b	Tetraodon nigroviridis miR-30b stem-loop	AGAUGGUGUAAACAUCCUACACUCAGCUGUGAUCUUUUGCCGCAGAGGCUGAGAGAAGGUUGUUUACUUGAACUGGCUGGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18176	MI0003265	fru-mir-30d	Fugu rubripes miR-30d stem-loop	UGCACAUGGCAGUUUGAGGCUGUAAACAUCCCCGACUGGAAGCUGUCACUCAGAAGAGCUUUCAGUCUGAUGUUUACCACCUCCGACCGCCUCCUGCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18177	MI0003266	tni-mir-30d	Tetraodon nigroviridis miR-30d stem-loop	UGGCAGUUUGAGGCUGUAAACAUCCCCGACUGGAAGCUGUCACUCAGCAGAGCUUUCAGUCUGAUGUUUACCCCCUCCGACCGCCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18178	MI0003267	fru-mir-27b	Fugu rubripes miR-27b stem-loop	AGGCACAGAGCUUAGCUGAUUGGUGAACAGUGAUUGAUUUCCUCUUUGUUCACAGUGGCUAAGUUCUGCACCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18179	MI0003268	tni-mir-27b	Tetraodon nigroviridis miR-27b stem-loop	AGGCACAGAGCUUAGCUGAUUGGUGAACAGUGAUUGAUUUCCUCUUUGUUCACAGUGGCUAAGUUCUGCACCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18180	MI0003269	fru-mir-23b	Fugu rubripes miR-23b stem-loop	GGCUGUGAGGGUUCCUGGCGUGCUGAUUUGUGACUUAUGAUAAAAUCACAUUGCCAGGGAUUACCACACAGCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18181	MI0003270	tni-mir-23b	Tetraodon nigroviridis miR-23b stem-loop	GGCUGUGAGGGUUCCUGGCGUGCUGAUUUGUGACCUAUGAUAAAAUCACAUUGCCAGGGAUUACCACACCGCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18182	MI0003271	fru-mir-196a-2	Fugu rubripes miR-196a-2 stem-loop	UCGAGUGGUUUAGGUAGUUUCAUGUUGUUGGGGUCCAUUUCAAACUCUGCAACAUGAAACUGUCUUAAUUGCCCCA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18183	MI0003272	tni-mir-196a-2	Tetraodon nigroviridis miR-196a-2 stem-loop	UCGAGUGGUUUAGGUAGUUUCAUGUUGUUGGGGUCCAUUUCAAACUCUGCAACAUGAAACUGUCUUAAUUGCCCCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18184	MI0003273	fru-mir-126	Fugu rubripes miR-126 stem-loop	CGGCCCAUUAUUACUUUUGGUACGCGCUAUGCCACUCUCAACUCGUACCGUGAGUAAUAAUGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18185	MI0003274	tni-mir-126	Tetraodon nigroviridis miR-126 stem-loop	CGGCCCAUUAUUACUUUUGGUACGCGCUAUGCCACUCUCAACUCGUACCGUGAGUAAUAAUGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18186	MI0003275	fru-mir-199-3	Fugu rubripes miR-199-3 stem-loop	CUCCCCGUCCUGCCUGCCCAGUGUUCAGACUACCUGUUCAUCAGACUAAAGCUGAACAGUAGUCUGCACAUUGGUUAAGCUGGGUUGGGACACACACGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18187	MI0003276	tni-mir-199-3	Tetraodon nigroviridis miR-199-3 stem-loop	CCCCACCCUGCCUGCCCAGUGUUCAGACUACCUGUUCAUCAGACUCAAGCUGAACAGUAGUCUGCACAUUGGUUAUGCAGAGUUGGGACACACAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18188	MI0003277	fru-mir-148	Fugu rubripes miR-148 stem-loop	CUUUCCAAAUAAAGUUCUGUGAUACACUUAGACUCUAGUUCCUCGCAGUCAGUGCAUUACAGAACUUUGUUUUGGGAGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18189	MI0003278	tni-mir-148	Tetraodon nigroviridis miR-148 stem-loop	AAAUAAAGUUCUGUGAUACACUUCGACUCUGAUUCCUCGCAGUCAGUGCAUUACAGAACUUUGUUU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18190	MI0003279	fru-mir-10b-1	Fugu rubripes miR-10b-1 stem-loop	AUAUAUACCCUGUAGAACCGAAUUUGUGUGAUGGCGUCAAAGUCACAGAUUCGAUUCUAGGGGAGUAUAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18191	MI0003280	tni-mir-10b-2	Tetraodon nigroviridis miR-10b-2 stem-loop	AUAUAUACCCUGUAGAACCGAAUUUGUGUGAUCAAGUCACAGUCACAGAUUCGAUUCUAGGGGAGUAUAU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18192	MI0003281	fru-mir-205	Fugu rubripes miR-205 stem-loop	UGUGUUCUAUCCUUCAUUCCACCGGAGUCUGUAUGUGUAUUUAACCAGAUUUCAGUGGUGUGAAGUGUAAGAGACAUGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18193	MI0003282	tni-mir-205	Tetraodon nigroviridis miR-205 stem-loop	UAUCCUUCAUUCCACCGGAGUCUGUAACUGUUUUUAACCAGAUUUCAGUGGUGUGAAGUGUAAGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18194	MI0003283	fru-mir-365	Fugu rubripes miR-365 stem-loop	CAGCAAGAAAAGUGAGGGACUUUUAGGGGCAGCUGUGUUUUAUUAACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAAUUGUCAAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18195	MI0003284	tni-mir-365	Tetraodon nigroviridis miR-365 stem-loop	CAGCAAGAAAAGUGAGGGACUUUUAGGGGCAGCUGUGUUUUAUUAACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAAUUGUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18196	MI0003285	fru-mir-193	Fugu rubripes miR-193 stem-loop	UGUGUCAGAAGCUGGGUCUUUGCGGGCAAGGUGAGUCCUCAGUUUGUUCAACUGGCCUACAAAGUCCCAGUCUCUGGCUCACGUAACC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18197	MI0003286	tni-mir-193	Tetraodon nigroviridis miR-193 stem-loop	CAGAAGCUGGGUCUUUGCGGGCAAGGUGAGUCCUCAGUUUGUUCAACUGGCCUACAAAGUCCCAGUGUCUGGCUCACGUGACC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18198	MI0003287	fru-mir-124-1	Fugu rubripes miR-124-1 stem-loop	GGUUGUGUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCUUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18199	MI0003288	tni-mir-124-1	Tetraodon nigroviridis miR-124-1 stem-loop	CUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCUUACAAUUAAGGCACGCGGUGAAUGCCAAGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18200	MI0003289	fru-mir-217	Fugu rubripes miR-217 stem-loop	AUGAAGAGCCUUCUUGAUGCGGAUGAUACUGCAUCAGGAACUGAUUGGCUGAUGCUUUUUACCCAACAGUACCUGAUGCAUUGCCUUCAGCAUUGAAAGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18201	MI0003290	tni-mir-217	Tetraodon nigroviridis miR-217 stem-loop	UCUUGAUGUGGAUGAUACUGCAUCAGGAACUGAUUGGCUGAUGCUUAGUACCCAACAGUACCUGAUGCAUUGCCUUCAGCAUUGAAAGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18202	MI0003291	fru-mir-216a	Fugu rubripes miR-216a stem-loop	UUGGUAAAAUCUCAGCUGGCAACUGUGAGUCGUUCACUAGCUGCUCUCACAAUGGCCUCUGGGAUUAUGCUAA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18203	MI0003292	tni-mir-216a	Tetraodon nigroviridis miR-216a stem-loop	UUGGUGAAAUCUCAGCUGGCAACUGUGAGUCGUUCACUAGCUGCUCUCACAAUGGCCUCUGGGAUUAUGCUAA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18204	MI0003293	fru-mir-216b	Fugu rubripes miR-216b stem-loop	UGACUGUUUAAUCUCUGCAGGCAACUGUGAUGGUGUUUUAUAUUCUCACAAUCACCUGGAGAGAUUCUGCAGUUUAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18205	MI0003294	tni-mir-216b	Tetraodon nigroviridis miR-216b stem-loop	UGACUGUUUAAUCUCUGCAGGCAACUGUGAUGGUGAUUUUUAUUCUCACAAUCACCUGGAGAGAUUCUGCAGUUUAU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18206	MI0003295	fru-let-7i	Fugu rubripes let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUUGGGUUGUGACACUGCCCGCUAUGGAGAUGACUGCGCAAGCUACUGCCUUGCUA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18207	MI0003296	tni-let-7i	Tetraodon nigroviridis let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUUGGGUUGUGACACUGCCCGCUAUGGAGAUGACUGCGCAAGCUACUGCCUUGCUA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18208	MI0003297	fru-mir-10b-2	Fugu rubripes miR-10b-2 stem-loop	GUUGUCUAUAUGUACCCUGUAGAACCGAAUUUGUGUGAGUUCCAGACAGUCGCAAGUACGUCUCUACAGGAAUACAUGGGCAAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18209	MI0003298	tni-mir-10b-1	Tetraodon nigroviridis miR-10b-1 stem-loop	GUUGUCUAUAUGUACCCUGUAGAACCGAAUUUGUGUGAGUUCAGACAGUCACAAGUACGUCUCUACAGGAAUACAUGGGCAAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18210	MI0003299	fru-mir-196a-1	Fugu rubripes miR-196a-1 stem-loop	AGCUGGAGCGUGGUUUAGGUAGUUUCAUGUUGUUGGGGAUGGCUUCCUGGCUCGGCAACAAGAAACUGCCUUGAUUACGUCAGUU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18211	MI0003300	tni-mir-196a-1	Tetraodon nigroviridis miR-196a-1 stem-loop	AGCUGGAGCGUGGUUUAGGUAGUUUCAUGUUGUUGGGGAUGGCUUCCUGGCUCGGCAACAAGAAACUGCCUUGAUUACGUCAGUUCGUCUUCAUCAAGGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18212	MI0003301	fru-mir-429	Fugu rubripes miR-429 stem-loop	CCUGUUGAUAGGCGUCUUACCAGACAUGGUUAGAUGUAAUUAUUGUUGUCUAAUACUGUCUGGUAAUGCCGUCCAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18213	MI0003302	tni-mir-429	Tetraodon nigroviridis miR-429 stem-loop	AGCCUGUUGAUAGGCGUCUUACCAGACAUGGUUAGAUGUAAUUAUUGUUGUCUAAUACUGUCUGGUAAUGCCGUCCAUUAAAUGGCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18214	MI0003303	fru-mir-200a	Fugu rubripes miR-200a stem-loop	UCUCAGGAUCCAUCUUACCCGACAGUGCUGGAUUGUACUACUGUUGUUCUAACACUGUCUGGUAACGAUGUUUUCUGGGUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18215	MI0003304	tni-mir-200a	Tetraodon nigroviridis miR-200a stem-loop	CAUCUUACCUGACAGUGCUGGAUUAUACUACUGUUGUUCUAACACUGUCUGGUAACGAUGUU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18216	MI0003305	fru-mir-200b	Fugu rubripes miR-200b stem-loop	GGUGAUUAUCUCCAUCUUACGAGGCAGCAUUGGAUAUCAUCACUUUCUCUAAUACUGCCUGGUAAUGAUGAUGAUCG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18217	MI0003306	tni-mir-200b	Tetraodon nigroviridis miR-200b stem-loop	CCAUCUUACGAGGCAGCAUUGGAUAGCAUCACUUUUUCUAAUACUGCCUGGUAAUGAUGAUGAUCGUCGUCUGCAGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18218	MI0003307	fru-mir-218b	Fugu rubripes miR-218b stem-loop	CAGGACCCCAUUGUGCUUGAUCUAACCAUGCAGUGCAUCGUGUGUCCAUGGUUGUGCCAAGCACCUUGGAGGCUUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18219	MI0003308	tni-mir-218b	Tetraodon nigroviridis miR-218b stem-loop	CAGGACCCCAUUGUGCUUGAUCUAACCAUGCAGUGCGUCCUGUGUCCAUGGUUGUGCCAAGCACCUUGGAGGCUUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18220	MI0003309	fru-mir-301	Fugu rubripes miR-301 stem-loop	CAGCUGCUUUGACAAUGUUGCACUACUGUACCAUCCAUUCUAGCAGUGCAAUAGUAUUGUCAUAGCAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18221	MI0003310	tni-mir-301	Tetraodon nigroviridis miR-301 stem-loop	AGGUCAGCUGCUCUGACAAUGUUGCACUACUGUACCAUCCAUUCUAGCAGUGCAAUAGUAUUGUCAUAGCAUUUGGCCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18222	MI0003311	fru-mir-130	Fugu rubripes miR-130 stem-loop	UGUUGUUGUCCUCUGCCCUUUUUCUGUUGCACCACUGGACACUGAGAUGAGCAGUGCAAUAUUAAAAGGGCAUUGGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18223	MI0003312	tni-mir-130	Tetraodon nigroviridis miR-130 stem-loop	UGUUGUCCUCUGCCCUUUUUCUGUUGCACCACUGGACACUGAGAUGAGCAGUGCAAUAUUAAAAGGGCAUUGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18224	MI0003313	fru-let-7a-2	Fugu rubripes let-7a-2 stem-loop	GGGUGAGGUAGUAGGUUGUAUAGUUUUAGGGUUAUACCCUUCCUGUCAGAUAACUAUACAACUUACUGUCUUUCCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18225	MI0003314	tni-let-7a-2	Tetraodon nigroviridis let-7a-2 stem-loop	GUCCUUUGGGGUGAGGUAGUAGGUUGUAUAGUUUUAGGGUUAUACCCUUCCUGUCAGAUAACUAUACAACUUACUGUCUUUCCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18226	MI0003315	fru-mir-122	Fugu rubripes miR-122 stem-loop	AGCUAUGGAGUGUGACAAUGGUGUUUGUUUCCUUUCUUUCAAACGCCAUUAUCACACUAAAUAGCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18227	MI0003316	tni-mir-122	Tetraodon nigroviridis miR-122 stem-loop	AGCUGUGGAGUGUGACAAUGGUGUUUGUGUCCUUUCUUUCAAACGCCAUUAUCACACUAAAUAGCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18228	MI0003317	fru-mir-218a-1	Fugu rubripes miR-218a-1 stem-loop	CGGCUGUCUCUUGUGCUUGAUCUAACCAUGUGGCCCCGCCUAUUGUGACAUCACAUGGUUCCGUCAAGCGCCAGGGACCGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18229	MI0003318	tni-mir-218a-1	Tetraodon nigroviridis miR-218a-1 stem-loop	CGGCUGUCUCUUGUGCUUGAUCUAACCAUGUGGCCCCGCCUAUUGUGAAAUCACAUGGUUCCGUCAAGCGCCAGGGACCGCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18230	MI0003319	fru-let-7d	Fugu rubripes let-7d stem-loop	UGUGCUCUGCAGUGUGAGGUAGUUGGUUGUAUGGUUUCGCAUAAUAAACAGCACGGAGAUAACUGUACAACCUUCUAGCUUUCCCUGCGGAGUCAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18231	MI0003320	tni-let-7d	Tetraodon nigroviridis let-7d stem-loop	UGUGCUCUGCAGUGUGAGGUAGUUGGUUGUAUGGUUUCGCAUAAUAAACAGCACGGAGAUAACUGUACAACCUUCUAGCUUUCCCUGCGGAGUCAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18232	MI0003321	fru-mir-9-2	Fugu rubripes miR-9-2 stem-loop	GUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUCUGCUCGUCAUAAAGCUAGAUAACCGAAAGUAAAAAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18233	MI0003322	tni-mir-9-2	Tetraodon nigroviridis miR-9-2 stem-loop	GUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUCUGCUCGUCAUAAAGCUAGAUAACCGAAAGUAAAAAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18234	MI0003323	fru-mir-460	Fugu rubripes miR-460 stem-loop	CAGUUCCUGCAUUGUACACACUGUGCAAAUCAUUUCUGGAAGCACAGCGCAUACAAUGUGGAUGCUGUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18235	MI0003324	tni-mir-460	Tetraodon nigroviridis miR-460 stem-loop	CAGUUCCUGCAUUGUACACACUGUGCAAAUCAAUUCUGGAAGCACAGCGCAUACAAUGUGGAUGCUGUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18236	MI0003325	fru-mir-21	Fugu rubripes miR-21 stem-loop	UGUCAAAUAGCUUAUCAGACUGGUGUUGGCUGUUAAGAUUGCAAGGCGACAACAGUCUGUAGGCUGUCUGACA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18237	MI0003326	tni-mir-21	Tetraodon nigroviridis miR-21 stem-loop	AUUGUCGUCUUUACAUCUGUCACUCUCGGCCUGUCAAAUAGCUUAUCAGACUGGUGUUGGCUGUUAAGAUUGCAAGGCGACAACAGUCUGAAGGCUGUCUGACAUUUCGGGCUCUUUCAUCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18238	MI0003327	fru-mir-153b	Fugu rubripes miR-153b stem-loop	CAUCUCCCAGUGUCAUUUUUGUGGUUUGCAGCUAGUACUCUGGCUCCAGUUGCAUAGUCACAAAAAUGAGCAUUGGCAGGUGUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18239	MI0003328	tni-mir-153b	Tetraodon nigroviridis miR-153b stem-loop	CAUCUCCCAGUGUCAUUUUUGUGGUUUGCAGCUAGUACUCUGGCUCCAGUUGCAUAGUCACAAAAAUGAGCAUUGGCAGGUGUGAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18240	MI0003329	fru-mir-199-2	Fugu rubripes miR-199-2 stem-loop	CCGCCUGCCCAGUGUUCAGACUACCUGUUCAGGAAGUAGUGGUUGUACAGUAGUCUGCACAUUGGUUAGGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18241	MI0003330	tni-mir-199-2	Tetraodon nigroviridis miR-199-2 stem-loop	CCGCCUGCCCAGUGUUCAGACUACCUGUUCAGGAAGUAGUGGUUGUACAGUAGUCUGCACAUUGGUUAGGCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18242	MI0003331	fru-mir-181b-1	Fugu rubripes miR-181b-1 stem-loop	AAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUUAACUGUAUGGAAGAGCUCACUGAACGAUGAAUGCAACUGUGUCCCAGAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18243	MI0003332	tni-mir-181b-1	Tetraodon nigroviridis miR-181b-1 stem-loop	AAAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUUAACUGUAUGGAAGAGCUCACUGAACGAUGAAUGCAACUGUGUCCCAGAU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18244	MI0003333	fru-mir-181a-1	Fugu rubripes miR-181a-1 stem-loop	GCUCGCCCCGGUGAACAUUCAACGCUGUCGGUGAGUUUGAGCUAAAUUGGAAAAACCAUCGACCGUUGAUUGUACCCCGUGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18245	MI0003334	tni-mir-181a-1	Tetraodon nigroviridis miR-213 stem-loop	GCUCGCCCCGGUGAACAUUCAACGCUGUCGGUGAGUUUGAGCCAAAUUGGAAAAACCAUCGACCGUUGAUUGUACCCCGUGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18246	MI0003335	fru-mir-338	Fugu rubripes miR-338 stem-loop	GGAUUCUCCCUGCAACAACAUCCUGGUGCUGCCUGAGUCACUUUCACAAACUCCAGCAUCAGUGAUUUUGUUGCGGGGGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18247	MI0003336	tni-mir-338	Tetraodon nigroviridis miR-338 stem-loop	GGAUUCUCCCUGCAACAACAUCCUGGUGCUGCCUGAGUCACUUUCACAAACUCCAGCAUCAGUGAUUUUGUUGCGGGGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18248	MI0003337	fru-mir-7	Fugu rubripes miR-7 stem-loop	CCCUGUCUGCUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGUUAGAUCAACUGACAACAAAUCACAGUCUGCCAAACAGCACAGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18249	MI0003338	tni-mir-7	Tetraodon nigroviridis miR-7 stem-loop	UGGAAGACUAGUGAUUUUGUUGUUUGGUGUCAAAAUUGACAACAAAUCAUUGUCUUCCUCACUGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18250	MI0003339	fru-mir-153a	Fugu rubripes miR-153a stem-loop	CCAGUGUCAUUUUUGUGAUGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUCAUUGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18251	MI0003340	tni-mir-153a	Tetraodon nigroviridis miR-153a stem-loop	CCAGUGUCAUUUUUUGUGAUGUUGCAGCUAGUAAUAUAAGCCAAGUUGCAUAGUCACAAAAGUGAUCAUUGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18252	MI0003341	fru-let-7j	Fugu rubripes let-7j stem-loop	GUCUGAGGUAGUUUUUUGUACAGUUUGAGGGUCUGUGAUUCUGCCCCAUACAGGAGCUAACUGUACAAGUGACUGCCUUGCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18253	MI0003342	tni-let-7j	Tetraodon nigroviridis let-7j stem-loop	GUCUGAGGUAGUUUUUUGUACAGUUUGAGGGUCUGUGAUUCUGCCCCAUACAGGAGCUAACUGUACAAGUGACUGCCUUGCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18254	MI0003343	dre-let-7j	Danio rerio let-7j stem-loop	GGUUGAGGUAGUUGUUUGUACAGUUUUUAGGGUCUGUUAUUCUGCCCUGUUAAGGAGCUAACUGUACAGACUACUGCCUUGCC	This zebrafish miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	12
18255	MI0003344	fru-let-7b	Fugu rubripes let-7b stem-loop	CAGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGUUGUGAUUUUGCCCCAUCAGGAGCUAACUAUACAACCUACUGCCUUCCCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18256	MI0003345	tni-let-7b	Tetraodon nigroviridis let-7b stem-loop	CAGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGUUGUGAUUUUGCCCCAUCAGGAGCUAACUAUACAACCUACUGCCUUCCCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18257	MI0003346	fru-mir-128-2	Fugu rubripes miR-128-2 stem-loop	GAAGAGGGGGCCGUUACACUGUCAGAGAUGUAGUCUGAGGGUCUCACAGUGAACCGGUCUCUUUUCCUGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18258	MI0003347	tni-mir-128-2	Tetraodon nigroviridis miR-128-2 stem-loop	GAGGAGGGGGCCGUUACACUGUCAGAGAUGUAGUCUGAGGGUCUCACAGUGAACCGGUCUCUUUUCCUGCUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18259	MI0003348	fru-mir-144	Fugu rubripes miR-144 stem-loop	CCUGGACAGGAUAUCAUCUAAUACUGUAAGUUUAUUAAAGAGACACUACAGUAUAGAUGAUGUACUAUCCAGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18260	MI0003349	tni-mir-144	Tetraodon nigroviridis miR-144 stem-loop	CCCUGGACAGGAUAUCAUCUUAUACUGUAAGUUUAAUAAAGUGACACUACAGUAUAGAUGAUGUACUAUCCAGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18261	MI0003350	fru-mir-30c	Fugu rubripes miR-30c stem-loop	UCAGGAAGUGUAAACAUCCUACACUCUCGGCGUCCGCCCCCUGGUGGCCGGGGGUGGGACUGUUUGCACUGCCUGACU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18262	MI0003351	tni-mir-30c	Tetraodon nigroviridis miR-30c stem-loop	UUCAGGGAGUGUAAACAUCCUACACUCUCGGCGUCCGCCCCCUGGUGGCCGGGGGUGGGACUGUUUGCACUGCCUGGCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18263	MI0003352	fru-mir-140	Fugu rubripes miR-140 stem-loop	GUCAGUGGUUUUACCCUAUGGUAGGUGACAUCAUGCUGUUCUACCACAGGGUAGAACCACGGACGGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18264	MI0003353	tni-mir-140	Tetraodon nigroviridis miR-140 stem-loop	GUCAGUGGUUUUACCCUAUGGUAGGUGACAUCAUGCUGUUCUACCACAGGGUAGAACCACGGACGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18265	MI0003354	fru-mir-124-2	Fugu rubripes miR-124-2 stem-loop	CUGGUCUCUCCUCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18266	MI0003355	tni-mir-124-2	Tetraodon nigroviridis miR-124-2 stem-loop	GCCUCUCCUCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18267	MI0003356	fru-mir-214	Fugu rubripes miR-214 stem-loop	CAGGAUGAGACUGUUGUGGUGUGUCUGCCUGUCUACACUUGCUGUGCAGACCUUCUGCUCCUGUACAGCAGGCACAGACAGGCAGACAGAUGGCAGCCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18268	MI0003357	tni-mir-214	Tetraodon nigroviridis miR-214 stem-loop	GUGGUGUGUCUGCCUGUCUACACUUGCUGUGCAGACCUUCUGCUCCUGUACAGCAGGCACAGACAGGCAGACAGAUGGCAGCCCCACU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18269	MI0003358	fru-mir-199-1	Fugu rubripes miR-199-1 stem-loop	UCCUGCUCCGUCAUCCCAGUGUUCAGACUACCUGUUCAGGAUUUUACUGGUGUACAGUAGUCUGCACAUUGGUUAGACAGUGCAUGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18270	MI0003359	tni-mir-199-1	Tetraodon nigroviridis miR-199-1 stem-loop	CCGGCUCCGUCCACCCAGUGUUCAGACUACCUGUUCAUUGUCAUACUGGUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCACGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18271	MI0003360	fru-mir-455	Fugu rubripes miR-455 stem-loop	CCCUGGUGUGAGGGUAUGUGCCCUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAUGG		38
18272	MI0003361	tni-mir-455	Tetraodon nigroviridis miR-455 stem-loop	CCCUGAUGUGAGGGUAUGUGCCCUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUUCCUCAAGG		39
18273	MI0003362	fru-mir-135b	Fugu rubripes miR-135b stem-loop	AUGCCCAGUGCACUGUAUGGCUUUUUAUUCCUAUCUGACUGUACUGAUAGUUCAUAUAGGGAUGGAAGCCAUGCACUGCGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18274	MI0003363	tni-mir-135b	Tetraodon nigroviridis miR-135b stem-loop	GCCCAGUGCGCUGUAUGGCUUUUUAUUCCUAUCUGACUGUACUGAGAGUUCAUAUAGGGAUGGAAGCCAUGCACCGCGCUGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18275	MI0003364	dre-mir-135b	Danio rerio miR-135b stem-loop	CUCUUUGCCCCGUAUGGCUUUUUAUUCCUAUCUGAGAAUUGCUCAGGACUCAUAUAGGGAUGGAAGCCAUGCAGGGCUGGGG	This zebrafish miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	12
18276	MI0003365	fru-mir-196b	Fugu rubripes miR-196b stem-loop	UGUGAUAUAGGUAGUUUCAAGUUGUUGGGCUGAACUCUUGUGAUCACAGGAACCUGAAACUGCCUGAGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18277	MI0003366	tni-mir-196b	Tetraodon nigroviridis miR-196b stem-loop	UGUGAUGUAGGUAGUUUCAAGUUGUUGGGCUAAACUUUGGUGAUCACAGGAACCUGAAACUGCCCGAUU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18278	MI0003367	fru-mir-129-1	Fugu rubripes miR-129-1 stem-loop	GUCCUUCACGAAUCUUUUUGCGGUCUGGGCUUGCUGUUCUUUACUGGUAAUCUGGGAAGCCCUUACCCCAAAAAGCAUUUGCGGAGGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18279	MI0003368	tni-mir-129-1	Tetraodon nigroviridis miR-129-1 stem-loop	GUCCUUCACGAAUCUUUUUGCGGUCUGGGCUUGCUGUUCUCUGCUCACCCGGAAGCCCUUACCCCAAAAAGCAUUUGCGGGGGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18280	MI0003369	fru-mir-26	Fugu rubripes miR-26 stem-loop	AGGCCUCGGCCUGGUUCAAGUAAUCCAGGAUAGGCUGGUUAACCCUGCACGGCCUAUUCUUGAUUACUUGUGUCAGGAAGUGGCCGUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18281	MI0003370	tni-mir-26	Tetraodon nigroviridis miR-26 stem-loop	GCGUUAGGCCUCGGCCUGGUUCAAGUAAUCCAGGAUAGGCUGGUUAACCCUGCACGGCCUAUUCUUGAUUACUUGUGUCAGGAAGUGGCCGCCAGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18282	MI0003371	fru-mir-101b	Fugu rubripes miR-101b stem-loop	UGAACUGUCCAUUUUCAGUUAUCAUGGUACCGCUGCUGUGUCCCUCUCAAGUACAGUACUAUGAUAACUGAAGAUUGGCAGUGCCAUC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18283	MI0003372	tni-mir-101b	Tetraodon nigroviridis miR-101b stem-loop	UGAACUGUCCAUUUUCGGUUAUCAUGGUACCGCUGCUGUGUCCCUCUCAAGUACAGUACUAUGAUAACUGAAGAUUGGCAGUGCCAUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18284	MI0003373	fru-mir-9-4	Fugu rubripes miR-9-4 stem-loop	GGGUUAGUUUUUAUCUUUGGUUAUCUAGCUGUAUGAGUUUAUGUAAUAUCAUAAAGCUAGAGAACCGAAUGUAUAAACUAAUUCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18285	MI0003374	tni-mir-9-4	Tetraodon nigroviridis miR-9-4 stem-loop	GGGUUAGUUUUUAUCUUUGGUUAUCUAGCUGUAUGAGUUUAUGUAAUAUCAUAAAGCUAGAGAACCGAAUGUACAAACUAAUUCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18286	MI0003375	fru-mir-181b-2	Fugu rubripes miR-181b-2 stem-loop	GCUCGCAAUAAACAUUCAUUGCUGUCGGUGGGUUUCUAUGGCAAUAGCUCACUGACCAAUGAAUGAAGACUGCGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18287	MI0003376	tni-mir-181b-2	Tetraodon nigroviridis miR-181b-2 stem-loop	GCUCGCAAUAAACAUUCAUUGCUGUCGGUGGGUUUCCAUGGCAAUAGCUCGCUGACCAAUGAAUGAAGACUGCGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18288	MI0003377	fru-mir-103	Fugu rubripes miR-103 stem-loop	CUCUCCGCUUUUAGCCUCUUUACAGUGCUGCCUUGUCUAAUCAUGUUCAAGCAGCAUUGUACAGGGCUAUGACAGCGUAGAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18289	MI0003378	tni-mir-103	Tetraodon nigroviridis miR-103 stem-loop	UUGCUCUACGCUUUUAGCCUCUUUACAGUGCUGCCUUGCUCUACUCAUGUUCAAGCAGCAUUGUACAGGGCUAUGACAGCGUAGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18290	MI0003379	fru-mir-107	Fugu rubripes miR-107 stem-loop	UUCUGUCUGCUGUGAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGCGAUCAAGCAGCAUUGUACAGGGCUAUCACCGCACACAGAGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18291	MI0003380	tni-mir-107	Tetraodon nigroviridis miR-107 stem-loop	UCUGUCUGCUGUGAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGCGAUCAAGCAGCAUUGUACAGGGCUAUCACCGCACACAGAGCUGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18292	MI0003381	fru-mir-22b	Fugu rubripes miR-22b stem-loop	GUUGCCUCACAGUCGUUCUUCACUGGCUAGCUUUAUGUCCUCUGACCCAUGCUAAAGCUGCCAGUUGAAGAGCUGUUGUGUGUAAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18293	MI0003382	tni-mir-22b	Tetraodon nigroviridis miR-22b stem-loop	GUUGCCUCACAGUCGUUCUUCACUGGCUAGCUUUAUGUCCUCCGACCCCACGCUAAAGCUGCCAGUUGAAGAGCUGUUGUGUGUAAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18294	MI0003383	fru-mir-212	Fugu rubripes miR-212 stem-loop	GGUCAGCGCAUCAACACCUUGGCUCUAGACUGCUUACUGCUAAAACCGCUCAUAAGUACAGUAACAGUCUACAGUCAUGGCUACUGACGCCUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18295	MI0003384	tni-mir-212	Tetraodon nigroviridis miR-212 stem-loop	GGUCAGCGCAUCAACACCUUGGCUCUAGACUGCUUACUGCUAACACCGCUCUGAAGUACAGUAACAGUCUACAGUCAUGGCUACUGACGCCUGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18296	MI0003385	dre-mir-212	Danio rerio miR-212 stem-loop	GUCAGUGCAUCAAUACCUUGGCUCUAGACUGCUUACUGCUAAAUGUGUCUGAAAGUACAGUAACAGUCUACAGUCAUGGCUACUGACGUCUGGC	This miRNA was predicted by computational methods using conservation between human, mouse and Fugu rubripes sequences [1].  Expression of the excised miR was validated in zebrafish, and the 5' end mapped by PCR.  The 3' end was not experimentally determined. 	12
18297	MI0003386	tni-mir-181a-2	Tetraodon nigroviridis mir-181a-2 stem-loop	CAGUUUUUUCAGGUCUUUGGGGAACAUUCAACGCUGUCGGUGAGUUUGGUGACUCAGAAAAAAACCAUCGAGCGUUGAGUGUACCUUUAGG	This Tetraodon miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	39
18298	MI0003387	dre-mir-181a-2	Danio rerio mir-181a-2 stem-loop	UUGGUGAACAUUCAACGCUGUCGGUGAGUUUUGCGCUUCUGUAACAAACCAUCGACCGUUGACUGUACCCUGAGGGUGG	This zebrafish miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	12
18299	MI0003388	fru-mir-135a	Fugu rubripes miR-135a stem-loop	UGCUGUGUUUUAUGGCUUUCUAUUCCUAUGUGAUUUUCUCUAGCAUGUCACAUAGGGUCUAAAGCCAUUGGGUACAGAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18300	MI0003389	tni-mir-135a	Tetraodon nigroviridis miR-135a stem-loop	UGCUGUGUUUUAUGGCUUUCUAUUCCUAUGUGAUUUUCUCUAGCAUGUCACAUAGGGUCUAAAGCCAUUGGGUACAGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18301	MI0003390	fru-mir-218a-2	Fugu rubripes miR-218a-2 stem-loop	GGUUGUUCCUUUGUGCUUGAUCUAACCAUGUGGCUGCCGGGUUCUUAUAGUGGAACAUGGUUCUGUCAAGCACCAUGGAACGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18302	MI0003391	tni-mir-218a-2	Tetraodon nigroviridis miR-218a-2 stem-loop	GGUUGUUCCUUUGUGCUUGAUCUAACCAUGUGGCUGCCAGGUUCUUAUCGUGGAACAUGGUUCUGUCAAGCACCAUGGAACGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18303	MI0003392	fru-mir-29a-1	Fugu rubripes miR-29a-1 stem-loop	AGGUUGACUGAUUUCUUUUGGUGUUCAGAGUCCAAUUCUGUUUCUAGCACCAUUUGAAAUCGGUUACAGUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18304	MI0003393	tni-mir-29a-1	Tetraodon nigroviridis miR-29a-1 stem-loop	AGGUUGACCGAUUUCUUUUGGUGUUCAGAGUCCAAUUCUGUUUCUAGCACCAUUUGAAAUCGGUUACAGUGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18305	MI0003394	dre-mir-29a-2	Danio rerio miR-29a-2 stem-loop	AGGUUGACCGAUUUCUUUUGGUGUUCAGAGUCUUUUGGGGUUUCUAGCACCAUUUGAAAUCGGUUACAAUG	This zebrafish miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	12
18306	MI0003395	fru-mir-29b-2	Fugu rubripes miR-29b-2 stem-loop	UGGAAGCUGGUUUCAGGUGGUGGCUUAGAGUAUUGUCAUCUAUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18307	MI0003396	tni-mir-29b-2	Tetraodon nigroviridis miR-29b-2 stem-loop	CUCUUGGAAGCUGGUUUCAGGUGGUGGCUUAGAGUAUUGUCAUCUAUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18308	MI0003397	fru-mir-133	Fugu rubripes miR-133 stem-loop	AAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUGUUGAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGCGCAUUGAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18309	MI0003398	tni-mir-133	Tetraodon nigroviridis miR-133 stem-loop	UGACUCCACAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUCUUGAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18310	MI0003399	fru-mir-132	Fugu rubripes miR-132 stem-loop	GUCUCCAUGGUUACCGUGGCAUUAGAUUGUUACUGUAGCAACUGCACCAGUGGUAACAGUCUACAGCCAUGGUCGCUAGGGGGCA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18311	MI0003400	tni-mir-132	Tetraodon nigroviridis miR-132 stem-loop	GUCUCCAUGGUUACCGUGGCAUUAGAUUGUUACUGUAGCAACUGCACCAGCGGUAACAGUCUACAGCCAUGGUCGCUAGGGGGCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18312	MI0003401	fru-mir-125b	Fugu rubripes miR-125b stem-loop	CUCUCAUUCCCUGAGACCCUAACUUGUGACGUUGUGCUGUGAUGUGCACGGGUUGGGUUCUUGGGAGCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18313	MI0003402	tni-mir-125b	Tetraodon nigroviridis miR-125b stem-loop	GUACCUCUCUCAUUCCCUGAGACCCUAACUUGUGACGUUGUGCUGUGAUGUGCACGGGUUGGGUUCUUGGGAGCUGCGAGGGGCGCUCACACAUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18314	MI0003403	fru-mir-29a-2	Fugu rubripes miR-29a-2 stem-loop	GAAGACAGUCUUGGACUCCCUUCCCCGUCCUCCACCAAAAGAUGACUGAUUUCUUCUGGUGCUGAGAGUCGGCUGCAGCCUUCUAGCACCAUUUGAAAUCGGUUAUAAAACAGUGGGUCGAUACAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18315	MI0003404	tni-mir-29a-2	Tetraodon nigroviridis miR-29a-2 stem-loop	UGUUUCUCCACCAAAAGAUGACUGAUUUCCUCUGGUGCUUAGAGCCGCCUGCAGCCUUCUAGCACCAUUUGAAAUCGGUUAUAAAACUGUGGAUCAGUGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18316	MI0003405	fru-mir-29b-1	Fugu rubripes miR-29b-1 stem-loop	UCCAGAAGCUGGUUUCAUGUGGUGGUUUAGAUGUGUCUUCCCUCUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18317	MI0003406	tni-mir-29b-1	Tetraodon nigroviridis miR-29b-1 stem-loop	CUCCAGAAGCUGGUUUCACGUGGUGGUUUAGAUGUGUCUCCUCAUCGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18318	MI0003407	fru-let-7a-1	Fugu rubripes let-7a-1 stem-loop	CAGGUUGAGGUAGUAGGUUGUAUAGUUGAGAGUGACACCACAGGAGAUGACUGUACAGCCUCCUAGCUUUCCCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18319	MI0003408	tni-let-7a-1	Tetraodon nigroviridis let-7a-1 stem-loop	CAGGGUGAGGUAGUAGGUUGUAUAGUUGAGAGUGACACCACAGGAGAUAACUGUACAGCCUCCUAGCUUUCCCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18320	MI0003409	fru-mir-100	Fugu rubripes miR-100 stem-loop	CACAAACCCGUAGAUCCGAACUUGUGGUGACUGGCCGCACAAGCUCGUAUCUAUAGGUAUGUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18321	MI0003410	tni-mir-100	Tetraodon nigroviridis miR-100 stem-loop	CACAAACCCGUAGAUCCGAACUUGUGGUGACUGGCCGCACAAGCUCGUAUCUAUAGGUAUGUG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18322	MI0003411	fru-mir-219-1	Fugu rubripes miR-219-1 stem-loop	UGAUUGUCCAAACGCAAUUCUUGUGAAAAUUCAAAUCCUACCCGAGAAUUGUGCCUGGACAUCUGUUGCUGGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18323	MI0003412	tni-mir-219-1	Tetraodon nigroviridis miR-219-1 stem-loop	UCUGAGCACUAGCAGCUGAUUGUCCAAACGCAAUUCUUGUGAAAAUCCAAAGCCUACCCGAGAAUUGUGCCUGGACAUCUGUUGCUGGACGCUCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18324	MI0003413	fru-mir-24-1	Fugu rubripes miR-24-1 stem-loop	GGGUUGUGCCCUCCUGUGCCUACUGAACUGGUAUCAGUGUCAUACUGGAAAACUGGCUCAGUUCAGCAGGAACAGGAGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18325	MI0003414	tni-mir-24-1	Tetraodon nigroviridis miR-24-1 stem-loop	CUUCCUGUGCCUACUGAGCUGAUAUGCAGUUGUACAGAACCACUGGCUCAGUUCAGCAGGAACAGGAGUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18326	MI0003415	fru-mir-23a-1	Fugu rubripes miR-23a-1 stem-loop	GCUGUGGCGGGGAGGGUUCCUGGCACCGUGAUUUGAUGCACAAAGACAAACAAAAAUCACAUUGCCAGGGAUUUCCACCCUUUCACAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18327	MI0003416	tni-mir-23a-1	Tetraodon nigroviridis miR-23a-1 stem-loop	GCUGUGGCGGGGAGGGUUCCUGGCACCGUGAUUUGAUGCACAAAGACAAACAAAAAUCACAUUGCCAGGGAUUUCCACCCUUUCACAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18328	MI0003417	fru-mir-27e	Fugu rubripes miR-27e stem-loop	CACUUGCUAAAGGCACCGAGCUUAGCUAAUUGGUGAGCAUUGAUCCCUGCUAUGUGUUGUUCACAGUGGCUAAGUUCAGUGCCUGAGGUGAAAUAGUUGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18329	MI0003418	tni-mir-27e	Tetraodon nigroviridis miR-27e stem-loop	CUCUUGCUGAAGGCACAGAGCUUAGCUAAUUGGUGAGCAUUGAUCCCUGCUAUGUGUUGUUCACAGUGGCUAAGUUCAGUGCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18330	MI0003419	fru-mir-375	Fugu rubripes miR-375 stem-loop	UGUACUUGCUUCACGUUGAGCCUCACGCACAAUACCUGAAGAUGAAGUUUUGUUCGUUCGGCUCGCGUUAUGCAGGU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18331	MI0003420	tni-mir-375	Tetraodon nigroviridis miR-375 stem-loop	UGUACUUGCUUCACGUUGAGCCUCACGCACAAUACCUGAAGAUGAAGUUUUGUUCGUUCGGCUCGCGUUAUGCAGGU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18332	MI0003421	fru-mir-128-1	Fugu rubripes miR-128-1 stem-loop	GAGAGCCUGGGUACGGGGCCGGGACGCUGUUUGAGAGUCCUCUAUGAAUCUCACAGUGAACCGGUCUCUUUUCCAGCCCCUCACU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18333	MI0003422	tni-mir-128-1	Tetraodon nigroviridis miR-128-1 stem-loop	GCUGCAUACGGGGCCGGGACGCUGUUUGAGAGUCCACUAUGAAUCUCACAGUGAACCGGUCUCUUUUGCAGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18334	MI0003423	fru-mir-1	Fugu rubripes miR-1 stem-loop	CUUAGUGUACAUACUUCUUUAUGUACCCAUAUGGACAUAUGAUAACUAUGGAAUGUAAAGAAGUAUGUAUUCUUGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18335	MI0003424	tni-mir-1	Tetraodon nigroviridis miR-1 stem-loop	AUUACCUCCUUAGUGUACAUACUUCUUUAUGUACCCAUAUGAACAUAUGAUAACUAUGGAAUGUAAAGAAGUAUGUAUUCUUGGUGAGGUGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18336	MI0003425	fru-mir-202	Fugu rubripes miR-202 stem-loop	UCCUUUUUCCUAUGCAUAUACCUUUUUCAGAUGUAACUUUAAAGAGGCAUAGGGCAUGGGAAAAUGGGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18337	MI0003426	tni-mir-202	Tetraodon nigroviridis miR-202 stem-loop	UCCUUUUUCCUAUGCAUAUACCUUUUUCAGAUGUAACUUUAAAGAGGCAUAGGGCAUGGGAAAAUGGGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18338	MI0003427	fru-mir-203	Fugu rubripes miR-203 stem-loop	CUGAUUAAGUGGUUCUCAACAGUUCAACAGUUCUAUGAGAAAAUUGUGAAAUGUUUAGGACCACUUGACCAGUC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18339	MI0003428	tni-mir-203	Tetraodon nigroviridis miR-203 stem-loop	CUGAUUAAGUGGUUCUCAACAGUUCAACAGUUCUUUGAGAAAAUUGUGAAAUGUUUAGGACCACUUGACCAGUC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18340	MI0003429	fru-mir-23a-3	Fugu rubripes miR-23a-3 stem-loop	UCUGUUGGCCAGGGGGAUUCCUGGCAGAGUGAUUUUUAGACUACAGGACUGAAUCACAUUGCCAGGGAUUUCCAAUGGCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18341	MI0003430	tni-mir-23a-3	Tetraodon nigroviridis miR-23a-3 stem-loop	UCUGUUGGCCAGGGGAAUUCCUGGCAGAGUGAUUUUUGAGACUACAGGACUGAAUCACAUUGCCAGGGAUUUCCAAUGGCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18342	MI0003431	fru-mir-27c	Fugu rubripes miR-27c stem-loop	GGCUGUGUGGCGGCAGGACUUAACCCACAUGUGAGCAGUGAGUGUGUGCCAUGUUCACAGUGGUUAAGUUCUGCCGCC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18343	MI0003432	tni-mir-27c	Tetraodon nigroviridis miR-27c stem-loop	GGCUGUGCGGCGGCAGGACUUAACCCACAUGUGAACAGUGAGUGUGCCGUGUUCACAGUGGUUAAGUUCUGCCGCC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18344	MI0003433	fru-mir-24-2	Fugu rubripes miR-24-2 stem-loop	GGGUCAGUCUCCUGUGCCUGCUGUGCUGAUAAUCAGUGUGUGACGUUGGCUGGCUCAGUUCAGCAGGAACAGGGGACUGGUC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18345	MI0003434	tni-mir-24-2	Tetraodon nigroviridis miR-24-2 stem-loop	GGGUCAGUCUCCUGUGCCUGCUGUGCUGAUAAUCAGUGUGUGACGUUGGCUGGCUCAGUUCAGCAGGAACAGGGGACUGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18346	MI0003435	fru-mir-138	Fugu rubripes miR-138 stem-loop	GCUGCAGCUGGUGUUGUGAAUCAGGCCGAUGACAGACACCUCCUAUAAGCCGGCUAUUUCACAACACCAGGGUGGCACC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18347	MI0003436	tni-mir-138	Tetraodon nigroviridis miR-138 stem-loop	GCUGCAGCUGGUGUUGUGAAUCAGGCCGAUGACAGACACCUCCUAGAAGCCGGCUAUUUCACAACACCAGGGUGGCACC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18348	MI0003437	fru-mir-129-2	Fugu rubripes miR-129-2 stem-loop	UGGGUCUUUUUGCGGUCUGGGCUUGCUGUUCCUAAGGCAGUAGCCAGGAAGCCCUUACCCCAAAAAGUAUCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18349	MI0003438	tni-mir-129-2	Tetraodon nigroviridis miR-129-2 stem-loop	GGGUCUUUUUGCGGUCUGGGCUUGCUGUUCCUAAGGCAGUAGCCAGGAAGCCCUUACCCCAAAAAGUAUCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18350	MI0003439	fru-mir-125a	Fugu rubripes miR-125a stem-loop	CUUCAGUGUCCCUGAGACCCUUAACCUGUGAUGAUAUGAAAGGUCACAGGUGAGGUCCUUGGGAAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18351	MI0003440	tni-mir-125a	Tetraodon nigroviridis miR-125a stem-loop	CAGUGUCCCUGAGACCCUUAACCUGUGAUAACGUGAAAGGUCACAGGUGAGGUCCUUGGGAAC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18352	MI0003441	fru-mir-17-2	Fugu rubripes miR-17-2 stem-loop	GUCAAAGUAGUGUCAAAGUGCUUACAGUGCAGGUAGUUUGAUGACAUCUACUGCAGUGAAGGCACUUUCAGCGCUAUUCUGA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18353	MI0003442	tni-mir-17-2	Tetraodon nigroviridis miR-17-2 stem-loop	GUCACCGUAGUGUCAAAGUGCUUACAGUGCAGGUAGUUAAAAGAAAUCUACUGCAGUGAAGGCACUUUCAGCACUAUUCUGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18354	MI0003443	fru-mir-20	Fugu rubripes miR-20 stem-loop	AGCAGUAUUAAAGUGCUUAUAGUGCAGGUAGUUACUGAUGGUCUACUGCAGUGUGAGCACUUCUAGUACUUCUAGAUGCA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18355	MI0003444	tni-mir-20	Tetraodon nigroviridis miR-20 stem-loop	GCAGUAUUAAAGUGCUUAUAGUGCAGGUAGUUUUCUCAGGGUCUACUGCAGUAUGAGCACUUCUAGUACUUCU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18356	MI0003445	fru-mir-92-1	Fugu rubripes miR-92-1 stem-loop	CUUUCCUGUGCAGGUUGGGAGAGGUAGCAAUGCUCAGAGAUUAUGCGGUAUUGCACUUGUCCCGGCCUGUGGAGGAAGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18357	MI0003446	tni-mir-92-1	Tetraodon nigroviridis miR-92-1 stem-loop	CUUUCCUGUACAGGUUGGGAGAGGUAGCAAUGCUCGGAGUUCAUGUGGUAUUGCACUUGUCCCGGCCUGUGGAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18358	MI0003447	fru-mir-15b	Fugu rubripes miR-15b stem-loop	UGAGUCCCUUAGACUGCUAUAGCAGCGCAUCAUGGUUUGUAACGAUGUAGAAAAGGGUGCAAGCCAUAAUCUGCUGCUUUAGAAUUUUAAGGAAA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18359	MI0003448	tni-mir-15b	Tetraodon nigroviridis miR-15b stem-loop	GCCCUUAGACUGCUUUAGCAGCGCAUCAUGGUUUGUAAUGAUGUGGAAAAAAGGUGCAAACCAUAAUUUGCUGCUUUAGAAUUUUAAGGAA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18360	MI0003449	fru-mir-10c	Fugu rubripes miR-10c stem-loop	CUGUCUUCUAUAUCUACCCUGUAGAUCCGGAUUUGUGUAAAAAUCAUUAAAGCAAUCACAAAUUCGCUUCUAGGGGAGUAUAUAGUGGAUUUAUACACGACG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18361	MI0003450	tni-mir-10c	Tetraodon nigroviridis miR-10c stem-loop	GAGCCGCUGUCUUCUAUAUCUACCCUGUAGAUCCGGAUUUGUGUAACGAUCAUUAAAGCAAUCACAAAUUCGCUUCUAGGGGAGUAUAUAGUGGAUUUAUACACGACG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18362	MI0003451	fru-mir-9-3	Fugu rubripes miR-9-3 stem-loop	GGAGCUGUGUUUCUGUCUUUGGUUAUCUAGCUGUAUGAGUGUUAAAUACCUGUCAUAAAGCUAGAUAACCGAAAGUAGAAAU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18363	MI0003452	tni-mir-9-3	Tetraodon nigroviridis miR-9-3 stem-loop	GGAGCUGUGUUUCUGUCUUUGGUUAUCUAGCUGUAUGAGUGUUAAAUACCUGUCAUAAAGCUAGAUAACCGAAAGUAGAAAU	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18364	MI0003453	fru-mir-183	Fugu rubripes miR-183 stem-loop	CUGUGUAUGGCACUGGUAGAAUUCACUGUGAGAGCUCACUAUCAGUGAAUUACCAUAGGGCCAUAAACAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18365	MI0003454	tni-mir-183	Tetraodon nigroviridis miR-183 stem-loop	CUGUGUAUGGCACUGGUAGAAUUCACUGUGAGAGCUCACUAUCAGUGAAUUACCAUAGGGCCAUAAACAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18366	MI0003455	fru-mir-96	Fugu rubripes miR-96 stem-loop	CUCUUCUUCGCCCAUUUUGGCACUAGCACAUUUUUGCUUCUGUAUGUAUACUUUGAGCAAUUAUGUGUAGUGCCAAUAUAGGAGAAGACAGACUUUCAACCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18367	MI0003456	tni-mir-96	Tetraodon nigroviridis miR-96 stem-loop	UUGCCCAUUUUGGCACUAGCACAUUUUUGCUUCUGUAUAUAUACUUUGAGCAAUUAUGUGUAGUGCCAAUAUAGGAGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18368	MI0003457	fru-mir-182	Fugu rubripes miR-182 stem-loop	UGUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAGAUGGAUCCGGUGGUUCUAGACUUGCCAACUACUGCU	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18369	MI0003458	tni-mir-182	Tetraodon nigroviridis miR-182 stem-loop	UGUUUGGCAAUGGUAGAACUCACACUGGUGAGGUAGAUGGAUCCGGUGGUUCUAGACUUGCCAACUA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18370	MI0003459	fru-mir-210	Fugu rubripes miR-210 stem-loop	UCUAAAAGCAGGUGAGCCACUGACUAACGCACAUUGCGCCAGUUGACAGUUCCACUGUGCGUGUGACAGCGGCUAACCUGGUUUUGGGAACGCUUCUG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18371	MI0003460	tni-mir-210	Tetraodon nigroviridis miR-210 stem-loop	CAGGUGAGCCACUGACUAACGCACAUUGUGCCAGUUGACAGUUCCACUGUGCGUGUGACAGCGGCUAACCUGGUUUUGGGGA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18372	MI0003461	fru-let-7g	Fugu rubripes let-7g stem-loop	UGGGAUGAGGUAGUAGUUUGUAUAGUUUUAGGAUCACACCAGAUCUGGGAGAUAACUAUACAGUCUACUGUCUUUCCCA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18373	MI0003462	tni-let-7g	Tetraodon nigroviridis let-7g stem-loop	UGGGAUGAGGUAGUAGUUUGUAUAGUUUUAGGAUCACACCAGAUCUGGGAGAUAACUAUACAGUCUACUGUCUUUCCCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18374	MI0003463	fru-mir-22a	Fugu rubripes miR-22a stem-loop	GCCGACCUACAGCAGUUCUUCACUGGCAAGCUUUAUGUCCUCGUGCAACAGCUAAAGCUGCCAGCUGAAGAACUGUUGUGGUUGGC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18375	MI0003464	tni-mir-22a	Tetraodon nigroviridis miR-22a stem-loop	GCCGACCUACAGCAGUUCUUCACUGGCAAGCUUUAUGUCCUCGUGCAACCGCUAAAGCUGCCAGCUGAAGAACUGUUGUGGUCGGC	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18376	MI0003465	fru-mir-204	Fugu rubripes miR-204 stem-loop	UGUGACCUGUGGGCUUCCCUUUGUCAUCCUAUGCCUGGAGCUCGGAUAAGGCAGGGACAGCAAAGGGAUGCUCAGCUGUCACCACUGACAUC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18377	MI0003466	tni-mir-204a	Tetraodon nigroviridis miR-204a stem-loop	UGUGACCUGUGGGCUUCCCUUUGUCAUCCUAUGCCUGGAGCUCGGAUAAGGCAGGGACAGCAAAGGGAUGCUCAGCCGUCACCACUGACUUCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18378	MI0003467	fru-mir-152	Fugu rubripes miR-152 stem-loop	GGCUAAGUUCUGUGAUACACUCUGACUGUGAAUGUCUAUGCUAGUCAGUGCAUAACAGAACUUUGUCCCGG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18379	MI0003468	tni-mir-152	Tetraodon nigroviridis miR-152 stem-loop	CUGCUCAAACUCUGGGCUAAGUUCUGUGAUACACUCUGACUGUGAAUGGCUAUGCUAGUCAGUGCAUAACAGAACUUUGUCCCGG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18380	MI0003469	fru-mir-15a	Fugu rubripes miR-15a stem-loop	CUGGUGAUGCUGUAGCAGCACGGAAUGGUUUGUGGGUUACACUGAGAUACAGGCCAUACUGUGCUGCCGCA	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18381	MI0003470	tni-mir-15a	Tetraodon nigroviridis miR-15a stem-loop	CUGGUGAUGCUGUAGCAGCACGGAAUGGUUUGUGAGUUACACUGAGAUACAAGCCAUGCUGUGCUGCCGCA	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18382	MI0003471	fru-mir-16	Fugu rubripes miR-16 stem-loop	GCCACUGUGCUGUAGCAGCACGUAAAUAUUGGAGUUAAGGCUCUCUGUGAUACCUCCAGUAUUGAUCGUGCUGCUGAAGCAAAGAUGAC	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18383	MI0003472	tni-mir-16	Tetraodon nigroviridis miR-16 stem-loop	UAGCAGCACGUAAAUAUUGGAGUUAAGGCUCUCUGUGAUACCUCCAGUAUUGAUCGUGCUGCUGAAGCAAAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18384	MI0003473	fru-mir-190	Fugu rubripes miR-190 stem-loop	CUGUCUGAUAUGUUUGAUAUAUUAGGUUGUUAUUCAGUCCAACUAUAUAUCAAACAUAUUCCUACAG	This Fugu miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	38
18385	MI0003474	tni-mir-190	Tetraodon nigroviridis miR-190 stem-loop	CUGUCUGAUAUGUUUGAUAUAUUAGGUUGUUAUUCAGUCCAACUAUAUAUCAAACAUAUUCCUACAG	This Tetraodon miRNA sequence is predicted based on homology with a verified zebrafish sequence (Mihaela Zavolan, personal communication). 	39
18386	MI0003475	fru-mir-181a-2	Fugu rubripes mir-181a-2 stem-loop	GACUUUGUCAAGUCUUUGGGGAACAUUCAACGCUGUCGGUGAGUUUUGUCUCCGAAAAACCAUCGACUGUUGAGUGUACCCUGACACUUGAGCUCCC	This Fugu miRNA sequence is predicted based on homology with a verified mammalian sequence (Mihaela Zavolan, personal communication). 	38
18387	MI0003476	mmu-mir-489	Mus musculus miR-489 stem-loop	ACUGCUGCAGUGGCAGCUUGGUUGUCAUAUGUGUGAUGACACUUUCUAAAGUCUUCCAGAAUGACACCACAUAUAUGGCAGCUAAACUGUUACAUGGAACAACAAGU		6
18388	MI0003477	rno-mir-489	Rattus norvegicus miR-489 stem-loop	ACUGCUACAGUGGCAGCUUGGUUGUCGUAUGCGUGAUGACACGUUCUCGUGUAUUCCAGAAUGACAUCACAUAUAUGGCAGCUAAACUGUUACAGGAACAACAAGU		8
18389	MI0003478	rno-mir-383	Rattus norvegicus miR-383 stem-loop	UCCUCAGAUCAGAAGGUGACUGUGGCUUUGGGUGGAUAUUAAUCAGCCACAGCACUGCCUGGUCAGAAAGAGCA		8
18390	MI0003479	rno-mir-207	Rattus norvegicus miR-207 stem-loop	AGGCAGGGGUGAGGGGCUGCGGGAGGAGCGGGGCGGAGGCUGCGGCUUGCGCUUCUCCUGGCUCUCCUCCCUUUCUUU		8
18391	MI0003480	rno-mir-501	Rattus norvegicus miR-501 stem-loop	GCUCGUCCUCUCUAAUCCUUUGUCCCUGGGUGAAAAUGCUAUUUGUAUGCAAUGCACCCGGGCAAGGAUUUGGGGAAGGUAAGC		8
18392	MI0003481	rno-mir-361	Rattus norvegicus miR-361 stem-loop	GAAGCUUAUCAGAAUCUCCAGGGGUACUUAUUAUUUGAAAAGUCCCCCAGGUGUGAUUCUGAUUCGUUUC		8
18393	MI0003482	rno-mir-215	Rattus norvegicus miR-215 stem-loop	GGUGUACAGGACAAUGACCUAUGAUUUGACAGACAGUGUGGCUGCGUGUGUCUGUCAUUCUGUAGGCCAAUAUUCUGUAUGUCUCUCCUCCUUACAA		8
18394	MI0003483	rno-mir-224	Rattus norvegicus miR-224 stem-loop	GGGCUUUCAAGUCACUAGUGGUUCCGUUUAGUAGAUGGUUUUUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUACAAAGCCC		8
18395	MI0003484	mmu-mir-483	Mus musculus miR-483 stem-loop	GAGGGGGAAGACGGGAGAAGAGAAGGGAGUGGUUUUUGGGUGCCUCACUCCUCCCCUCCCGUCUUGUUCUCUC		6
18396	MI0003485	rno-mir-483	Rattus norvegicus miR-483 stem-loop	GAGGGGGAAGACGGGAGAAGAGAAGGGAGUGGUUUUUGGGUGCCUCACUCCUCCCCUCCCGUCUUGUUCUCUC		8
18397	MI0003486	rno-mir-370	Rattus norvegicus miR-370 stem-loop	AGACAGAGAGACCAGGUCACGUCUCUGCAGUUACACAGCUCAUGAGUGCCUGCUGGGGUGGAACCUGGUUUGUCUGUCU		8
18398	MI0003487	rno-mir-377	Rattus norvegicus miR-377 stem-loop	CUUGAGCAGAGGUUGCCCUUGGUGAAUUCGCUUUAUUGAUGUUGAAUCACACAAAGGCAACUUUUGGUUGAG		8
18399	MI0003488	rno-mir-412	Rattus norvegicus miR-412 stem-loop	GGGACGGAUGGUCGACCAGCUGGAAAGUAAUUGUUUCUAAUGUACUUCACCUGGUCCACUAGCCGUCGGU		8
18400	MI0003489	rno-mir-1	Rattus norvegicus miR-1 stem-loop	UGCCUACUCAGAGCACAUACUUCUUUAUGUACCCAUAUGAACAUAGAAUGCUAUGGAAUGUAAAGAAGUGUGUAUUUUGGGUAGGUA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18401	MI0003490	rno-mir-133b	Rattus norvegicus miR-133b stem-loop	CCCUGCUCUGGCUGGUCAAACGGAACCAAGUCCGUCUUCCUGAGAGGUUUGGUCCCCUUCAACCAGCUACAGCAGGGCUGGCAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18402	MI0003491	mmu-mir-484	Mus musculus miR-484 stem-loop	CUCGUCAGGCUCAGUCCCCUCCCGAUAAACCUCAAAAUAGGGUCUUACCUAGGGGGCUGGCGGCGUA		6
18403	MI0003492	mmu-mir-485	Mus musculus miR-485 stem-loop	ACUUGGAGAGAGGCUGGCCGUGAUGAAUUCGAUUCAUCUAAACGAGUCAUACACGGCUCUCCUCUCUUCUAGU	miR-485-3p was predicted by Sewer et al [1], and its expression later verified experimentally by Mineno et al using MPSS technology [2].  The MPSS protocol used provides 22nt sequences, but the true extents of the mature miRNA are not reliably obtained.  Landgraf et al. show that the 5' product is the predominant one [3]. 	6
18404	MI0003493	mmu-mir-486	Mus musculus miR-486 stem-loop	CAGCCAGCUCUGAUCUCGCCCUCCCUGAGGGGUCCUGUACUGAGCUGCCCCGAGGUCCUUCACUGUGCUCAGCUCGGGGCAGCUCAGUACAGGAUGCGUCAGGGUGGGAGACAACGGGGAACAAGCCA		6
18405	MI0003494	ppt-MIR390a	Physcomitrella patens miR390a stem-loop	CAUGAUACAAUUACGAAGCUCAGGAGGGAUAGCGCCAUUCUCUGUUCUUCUCUAUCGACACUUGGUAAACCAGCUUGUGCUAGCUAUGGGCAGAGAUAUGGCGUUAUCCAUUCUGAGCUUUGCAAGUGUCUCGUGCU		40
18406	MI0003495	ppt-MIR390b	Physcomitrella patens miR390b stem-loop	AUCAAGCUGCUGGGAGAUACAAUUACGAAGCUCAGGAGGGAUAGCGCCCAGCCCUGCUUUUACUGUUCAAUCAGUUAGAGUGCUUCUGAUAGUAAGAUGCAGAUGCAUGACGCUAUCCAUUCUGAGCUUUGCAACUGUGUCCCCCUAAUUUGGGCAACCGGAUCGGUUAGCUGGU		40
18407	MI0003496	ppt-MIR319a	Physcomitrella patens miR319a stem-loop	GUGGAGCUCCGUUUCGGUCCAAUAGUGGCUGCGACGGAAGGUGGUCCCGCUGCCGAAUCACACGUCCGGGUUGCUUAUCGGGGCAGGGCCCCGAUACGGUAUCCGAACGUUUGUCCCGGGAACUGGUCGACCUUCCGCCCGGCGUCUCUUGGACUGAAGGGAGCUCCAC		40
18408	MI0003497	ppt-MIR319b	Physcomitrella patens miR319b stem-loop	GAGCUCUUUUCAGUCCAGUAGCAGCUAAUGUCGAAGGUUGUACCGCUGCCGACUCAAACUUCCGGCUUCCAUAUCACGACGCGUGAUAUGGAAUCCGAAGGUCUGAUCCGGGAGCUGAUCGAUCUCCAGGUUAGCAUCUCUUGGACUGAAGGGAGCUCCU		40
18409	MI0003498	ppt-MIR319c	Physcomitrella patens miR319c stem-loop	UAACCUCACUGGCUGUGGGAGCUUCCUUCGGUUCAAUAGUGGCUGAUAUGAGGUUGCACUGCUGCCGACUCAAACUUCCGGCUUCCCUCUCUUAGAAUGGCAGGGAAUCCGAAUGUCUGAUGCGGGAGCUGAGCGGUCUUCAACUCAGCUUCUCUUGGACUGAAGGGAGCUCCCAUGUCUUUGUGGUUA		40
18410	MI0003499	ppt-MIR319d	Physcomitrella patens miR319d stem-loop	CAGCGUGGAGCUUUCUUCGGUCCAAUAGUGGCUGAGUCGAAGGUUGUGCUGCUGCCGACUCAAACUUCCGGCUUCCCUAUCCAACCCCUGGUAUGGAAUCCGAAUGUCUGAUACGGGAGCUGUUCAAUCUCCGGCUUAGCAUCUCUUGGACUGAAGGGAGCUCCCCGCUG		40
18411	MI0003500	ppt-MIR533a	Physcomitrella patens miR533a stem-loop	AUGGGGAGCUGGCCAGGCUGUGAGGGACGGAGCAGAGUUGGCUUGUGGCUCCUUGUGGCCCCCUCCAGCAGCUUCCUCCUCACAGUCUGCACAGCUCUCCGU	Arazi et al. identified a mature miRNA from the 5' arm of this precursor, and called it miR533 [1].  Axtell et al. show by deep sequencing that the 3' product is the predominant one [3].  The 5' miRNA is renamed miR533* here. 	40
18412	MI0003501	ppt-MIR534a	Physcomitrella patens miR534a stem-loop	AUAUGCAUGCAACUUGUGUGGACAGACUGACUAGUCUAGUGGUGUAGUGGAAAGUAUUAGUUGGUUGAUGCACGAUGUUGUUUUGCAACAAGUGACUCGUCGCUGCAAUACUGAACCCACAAGUUUUGGAAGUUGUUUUGAUUGGGGCCACCCACAUUGCUCGACUAGAUUCAGUAUGUCCAUUGCAGUUGCAUACAUAU		40
18413	MI0003502	ppt-MIR535a	Physcomitrella patens miR535a stem-loop	GGAGGUGAAACGGUGGAGAACCUAGGUGACAACGAGAGAGAGCACGCUGGAAUGCUUUUCAUGCAAUACGCUUGGAUGUGUUCUAGCGUGCCCUCUACCGUUGUCGCCAAACAUCUUCUCCAUGACUUCUCCUCU		40
18414	MI0003503	ppt-MIR535b	Physcomitrella patens miR535b stem-loop	GUGACAACGAGAGAGAGCACGCUGGAAUGCACUCUUGUAAGAAGCAUGGGUAUGUUCUUGUGUGCCCUCUCCCGCUGUCGC		40
18415	MI0003504	ppt-MIR535c	Physcomitrella patens miR535c stem-loop	GUGACAACGAGAGAGAGCACGCUGGAAUGCUUUCACGCAAUAAGCCUGGAUGUGUUCUUGCGUGCCCUUUCCCGUUGUCGC		40
18416	MI0003505	osa-MIR535	Oryza sativa miR535 stem-loop	GGCGGUGACAACGAGAGAGAGCACGCCGGUGCGGCGGUCACGGUGAGCCGGCCCGCGGCGGCGUACCUGCGUGCUUUCUCCCGUUGUCACUGCC		7
18417	MI0003506	ppt-MIR156a	Physcomitrella patens miR156a stem-loop	GGCGGUGGAGGAUGUGGGAGUGACAGAAGAGAGUGAGCACAGCUGAGCAUGUACAUGAGGAAGUACUUGCCCAUGUGUGCUCACUCUCUUCCUGUCGCACCUCUCCUUUGACGCU		40
18418	MI0003507	ppt-MIR536a	Physcomitrella patens miR536a stem-loop	UGAUUCCACCCCUUGGAUGUCACUGCUUGGCACAAUCCUCUUAUUGUGAAUUUCAUGUCCUCUUUCGUGGUUAGUCGAUAGAGUUGUACUACCUUUAUUCAUCCAGUGUUAUAAAUGUUUGUCCAGUGCUAGCUCUUCACUUGGGGAUUGCACAACAGGGGGUUCGUGCCAAGCUGUGUGCAACCUAAGGGUGGUUUUA		40
18419	MI0003508	ppt-MIR537a	Physcomitrella patens miR537a stem-loop	GUUGUCGUCAUAUAUGGACUGUAGAAACACCUGAAGCGAGUGAGGACCAUCCGAUUCUAGCCAUGGAAACAGAUAAGAGCUCAUGUCUGGGUUCCUGUUUCUGUGAUGCUUUUGAGGUUUGCGCAUGAGAUAGCAUCGGUUAGGCUUCAAACUCUUGAGGUGUUUCUACAGGCUACAUAUGAUUGAUAGC		40
18420	MI0003509	ppt-MIR537b	Physcomitrella patens miR537b stem-loop	UCAUAUCUGGACUGUAGAAACACCUGAAGUGACUGAAGUUAGUCCGGUUUAGGUAUGAGAAUGAUUGGAGCACCUCUCCAGAUGUUCCAGAUGUAAUGAAACCGGUGCAAGCUUCAAGCUCUUGAGGUGUUUCUACAGGCUACAUAUGA		40
18421	MI0003510	ppt-MIR538a	Physcomitrella patens miR538a stem-loop	UUACAAUGAGUUUGUGAGUCUCCAUGCUGCUCUAACAUUGCAUGGAGUCUAUGUCUGGAGUAUUGUCCUUCAUUCCCGUGCAAAUGCUGAAGUAAUGCAAGAAUGUGAACAUUGGGACUAUUCCAGACGUAGCCUUCAUGCAUGUUAGAGUGAUGUGGAAACCCGUGAACUACUUGUAA		40
18422	MI0003511	ppt-MIR538b	Physcomitrella patens miR538b stem-loop	CCAUGCUUCUCUAACGUUGCAUGGAGUCUAUGUCUGGACCUCCUCCAUUUGCUCUUUCAAGAGAAUGUGAGAAUUUCGAGAUUCGGACAUAGCCUUCAUGCAUGCUAGAGUAGAAUGG		40
18423	MI0003512	ppt-MIR538c	Physcomitrella patens miR538c stem-loop	UUACAAAGAGUUCUUGAGUCUCCAUGCUUCUCUGACGUUGCAUGGAGUCUAUGUCUGGACCUUCUCCAUUUCCUCUUUCAAGAGAAUGUGAGCAUUGAAGGAUUCGGACAUAGCCUUCAUGCAUGCUAGAGUAUCAUGGAGGCCCGUGAACUACUUGUAA		40
18424	MI0003513	hsa-mir-455	Homo sapiens miR-455 stem-loop	UCCCUGGCGUGAGGGUAUGUGCCUUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGCCUAUGUCAUC	The mir-455 precursor was predicted computationally and a 5' mature product verified in human by Northern blot [1].  The precise sequence termini of the mature forms were derived by cloning from human and rat samples [2]. 	5
18425	MI0003514	hsa-mir-539	Homo sapiens miR-539 stem-loop	AUACUUGAGGAGAAAUUAUCCUUGGUGUGUUCGCUUUAUUUAUGAUGAAUCAUACAAGGACAAUUUCUUUUUGAGUAU		5
18426	MI0003515	hsa-mir-544	Homo sapiens miR-544 stem-loop	AUUUUCAUCACCUAGGGAUCUUGUUAAAAAGCAGAUUCUGAUUCAGGGACCAAGAUUCUGCAUUUUUAGCAAGUUCUCAAGUGAUGCUAAU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18427	MI0003516	hsa-mir-545	Homo sapiens miR-545 stem-loop	CCCAGCCUGGCACAUUAGUAGGCCUCAGUAAAUGUUUAUUAGAUGAAUAAAUGAAUGACUCAUCAGCAAACAUUUAUUGUGUGCCUGCUAAAGUGAGCUCCACAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18428	MI0003517	mmu-mir-546	Mus musculus miR-546 stem-loop	CCUCUCUUCCCAAAACUAAACAGGAUCUAUCAUGGUGGCACGGAGUCAGCUAGAUGUUGUCUCUUGCUAUCCCUGUGCUAGUUCCAUGUUUUAGAAGCAAAGUGAUACUGGGGAGGAGAGG		6
18429	MI0003518	mmu-mir-540	Mus musculus miR-540 stem-loop	UGGGCCAAGGGUCACCCUCUGACUCUGUGGCCAAGGGUAGACAGGUCAGAGGUCGAUCCUGGGCCUA		6
18430	MI0003519	mmu-mir-543	Mus musculus miR-543 stem-loop	UGCUUAAUGAGAAGUUGCCCGCGUGUUUUUCGCUUUAUAUGUGACGAAACAUUCGCGGUGCACUUCUUUUUCAGCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
18431	MI0003520	mmu-mir-539	Mus musculus miR-539 stem-loop	UACUUGAGGAGAAAUUAUCCUUGGUGUGUUGGCUCUUUUGGAUGAAUCAUACAAGGAUAAUUUCUUUUUGAGUA		6
18432	MI0003521	mmu-mir-541	Mus musculus miR-541 stem-loop	GCCAAAAUCAGAGAAGGGAUUCUGAUGUUGGUCACACUCCAAGAGUUUUAAAAUGAGUGGCGAACACAGAAUCCAUACUCUGCUUAUGGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18433	MI0003522	mmu-mir-542	Mus musculus miR-542 stem-loop	GGAUCUCAGACGUCUCGGGGAUCAUCAUGUCACGAGAUACCACUGUGCCCUUGUGACAGAUUGAUAACUGAAAGGUCUGGGAGCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
18434	MI0003523	mmu-mir-547	Mus musculus miR-547 stem-loop	GUGUGAUGUAUCACUUGAGGAUGUACCACCCAUUUAACAGGAAACAUGCUUGGUACAUCUUUGAGUGAGAUAACACAC	The predominant miRNA cloned by Langraf et al. has a 3' terminal U residue, which is incompatible with the genome sequence [2]. 	6
18435	MI0003524	rno-mir-540	Rattus norvegicus miR-540 stem-loop	CCCUGGGGCUGGGCCAAGGGUCACCCUCUGACUCUGUGGCCAAGGGUAGACAGGUCAGAGGUCGAUCCUGGGCCUACUCUGGGG		8
18436	MI0003525	rno-mir-543	Rattus norvegicus miR-543 stem-loop	GGUGCUUAAUGAGAAGUUGCCCGCGUGUUUUUCGCUUUAUAUGUGACGAAACAUUCGCGGUGCACUUCUUUUUCAGCAUC		8
18437	MI0003526	rno-mir-539	Rattus norvegicus miR-539 stem-loop	AUACUUGAGGAGAAAUUAUCCUUGGUGUGUUUGCUCUUUUGGAUGAAUCAUACAAGGGUAAUUUCUUUUCGAGUAU		8
18438	MI0003527	rno-mir-541	Rattus norvegicus miR-541 stem-loop	GCCAAAAUCAGAGAAGGGAUUCUGAUGUUGGUCACACUCCAAGAAUUUUAAAAUGAGUGGCGAACACAGAAUCCAUACUCUGCUUAUGGC		8
18439	MI0003528	rno-mir-542	Rattus norvegicus miR-542 stem-loop	UCUCAGACGUCUCGGGGAUCAUCAUGUCACGAGAUACCACUGCGCACUUGUGACAGAUUGAUAACUGAAAGGUCUGGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18440	MI0003529	hsa-mir-376a-2	Homo sapiens miR-376a-2 stem-loop	GGUAUUUAAAAGGUAGAUUUUCCUUCUAUGGUUACGUGUUUGAUGGUUAAUCAUAGAGGAAAAUCCACGUUUUCAGUAUC	The mature miR-376a products have been shown to be modified by A to I edits [2]. 	5
18441	MI0003530	hsa-mir-487b	Homo sapiens miR-487b stem-loop	UUGGUACUUGGAGAGUGGUUAUCCCUGUCCUGUUCGUUUUGCUCAUGUCGAAUCGUACAGGGUCAUCCACUUUUUCAGUAUCAA		5
18442	MI0003531	mmu-mir-367	Mus musculus miR-367 stem-loop	AGGCCGUCACUGUUGCUAACAUGCAACUCUGUUGAAUAGAAAUUGGAAUUGCACUUUAGCAAUGGUGAUGGACCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18443	MI0003532	mmu-mir-494	Mus musculus miR-494 stem-loop	UUGAUACUUGAAGGAGAGGUUGUCCGUGUUGUCUUCUCUUUAUUUAUGAUGAAACAUACACGGGAAACCUCUUUUUUAGUAUCAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18444	MI0003533	mmu-mir-376c	Mus musculus miR-376c stem-loop	UUUGGUAUUUAAAAGGUGGAUAUUCCUUCUAUGUUUAUGCUUUUUGUGAUUAAACAUAGAGGAAAUUUCACGUUUUCAGUGUCAAA	The mature miR-376c products have been shown to be modified by A to I edits [2]. 	6
18445	MI0003534	mmu-mir-487b	Mus musculus miR-487b stem-loop	UGGUACUUGGAGAGUGGUUAUCCCUGUCCUCUUCGCUUCACUCAUGCCGAAUCGUACAGGGUCAUCCACUUUUUCAGUAUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
18446	MI0003535	mmu-mir-369	Mus musculus miR-369 stem-loop	GGUACUUGAAGGGAGAUCGACCGUGUUAUAUUCGCUUGGCUGACUUCGAAUAAUACAUGGUUGAUCUUUUCUCAGUAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
18447	MI0003536	mmu-mir-20b	Mus musculus miR-20b stem-loop	CCUAGUAGUGCCAAAGUGCUCAUAGUGCAGGUAGUUUUUAUACCACUCUACUGCAGUGUGAGCACUUCUAGUACUCCUGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [4]. 	6
18448	MI0003537	mmu-mir-450a-2	Mus musculus miR-450a-2 stem-loop	GAACUAUUUUUGCGAUGUGUUCCUAAUAUGUACUAUGAGUAUAUUGGGGAUGCUUUGCAUUCAUGGUUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18449	MI0003538	mmu-mir-503	Mus musculus miR-503 stem-loop	UGCCCUAGCAGCGGGAACAGUACUGCAGUGAGUGUUUGGUGCCCUGGAGUAUUGUUUCCACUGCCUGGGUA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [5]. 	6
18450	MI0003539	mmu-mir-291b	Mus musculus miR-291b stem-loop	ACAUACAGUGUCGAUCAAAGUGGAGGCCCUCUCCGCGGCUUGGCGGGAAAGUGCAUCCAUUUUGUUUGUCUCUGUGUGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
18451	MI0003540	rno-mir-493	Rattus norvegicus miR-493 stem-loop	GGCCUCCAGGGCCUUGUACAUGGUAGGCUUUCAUUCAUUGUUUGCACAUUCGGUGAAGGUCUACUGUGUGCCAGGCCCUGUGCC		8
18452	MI0003541	rno-mir-379	Rattus norvegicus miR-379 stem-loop	UGGUUCCUGCAGAGGUGGUAGACUAUGGAACGUAGGCGUUAUGUUUCUGACCUAUGUAACAUGGUCCACUAACUCUCAGUAUCCA		8
18453	MI0003542	rno-mir-494	Rattus norvegicus miR-494 stem-loop	UGAUACUUGAAGGAGAGGUUGUCCGUGUUGUCUUCUCUUUAUUUAUGAUGAAACAUACACGGGAAACCUCUUUUUUAGUAUCA		8
18454	MI0003543	rno-mir-376c	Rattus norvegicus miR-376c stem-loop	UUGGUAUUUAAAAGGUGGAUAUUCCUUCUAUGUUUAUGGUAUUUAUGAUUAAACAUAGAGGAAAUUUCACGUUUUCAGUGUCAA		8
18455	MI0003544	rno-mir-376b	Rattus norvegicus miR-376b stem-loop	UUUGGUAUUUAAAAGGUGGAUAUUCCUUCUAUGGUUACGUGCUUCCUGGAUAAUCAUAGAGGAACAUCCACUUUUUCAGUAUCAAA		8
18456	MI0003545	rno-mir-376a	Rattus norvegicus miR-376a stem-loop	UGAUAUUUAAAAGGUAGAUUCUCCUUCUAUGAGUACAAUAUUAAUGACUAAUCGUAGAGGAAAAUCCACGUUUUCAGUAUCA		8
18457	MI0003546	rno-mir-381	Rattus norvegicus miR-381 stem-loop	AGCGAGGUUGCCCUUUGUAUAUUCGGUUUAUUGACAUGGGAUAUACAAGGGCAAGCUCUCU		8
18458	MI0003547	rno-mir-487b	Rattus norvegicus miR-487b stem-loop	UGGUACUUGGAGAGUGGUUAUCCCUGUCCUCUUCGCUUCACUUAUGCCGAAUCGUACAGGGUCAUCCACUUUUUCAGUAUCA		8
18459	MI0003548	rno-mir-382	Rattus norvegicus miR-382 stem-loop	GGUACUUGAAGAGAAGUUGUUCGUGGUGGAUUCGCUUUACUUGUGACGAAUCAUUCACGGACAACACUUUUUUCAGUACC		8
18460	MI0003549	rno-mir-485	Rattus norvegicus miR-485 stem-loop	GAUACUUGGAGAGAGGCUGGCCGUGAUGAAUUCGAUUCAUCUAAACGAGUCAUACACGGCUCUCCUCUCUUCUAGUGUC		8
18461	MI0003550	rno-mir-409	Rattus norvegicus miR-409 stem-loop	GGUACUCGGAGAGAGGUUACCCGAGCAACUUUGCAUCUGGAGGACGAAUGUUGCUCGGUGAACCCCUUUUCGGUAUC		8
18462	MI0003551	rno-mir-369	Rattus norvegicus miR-369 stem-loop	GGUACUUGAAGGGAGAUCGACCGUGUUAUAUUCGCUUAGCUGACUUCGAAUAAUACAUGGUUGAUCUUUUCUCAGUAUC		8
18463	MI0003552	rno-mir-374	Rattus norvegicus miR-374 stem-loop	CUCGGAUGGAUAUAAUACAACCUGCUAAGUGUUCUAGCACUUAGCACGUUGUAUUAUUAUUGUCCGAG		8
18464	MI0003553	rno-mir-363	Rattus norvegicus miR-363 stem-loop	UUUUGCUGUUAUCGGGUGGAUCACGAUGCAAUUUUGAUUAGAGUAAUGGGAGAGAAAUUGCACGGUAUCCAUCUGUAAACCGCAGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18465	MI0003554	rno-mir-20b	Rattus norvegicus miR-20b stem-loop	GUAGUGCCAAAGUGCUCAUAGUGCAGGUAGGUUUUGCUGCACUCUACUGCAGUGUGAGCACUUCUGGUACUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18466	MI0003555	rno-mir-503	Rattus norvegicus miR-503 stem-loop	UGCCCUAGCAGCGGGAACAGUACUGCAGUGAGUGUUUGGUGCCCUGGAGUAUUGUUUCCGCUGCCUGGGUA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18467	MI0003556	hsa-mir-551a	Homo sapiens miR-551a stem-loop	GGGGACUGCCGGGUGACCCUGGAAAUCCAGAGUGGGUGGGGCCAGUCUGACCGUUUCUAGGCGACCCACUCUUGGUUUCCAGGGUUGCCCUGGAAA		5
18468	MI0003557	hsa-mir-552	Homo sapiens miR-552 stem-loop	AACCAUUCAAAUAUACCACAGUUUGUUUAACCUUUUGCCUGUUGGUUGAAGAUGCCUUUCAACAGGUGACUGGUUAGACAAACUGUGGUAUAUACA		5
18469	MI0003558	hsa-mir-553	Homo sapiens miR-553 stem-loop	CUUCAAUUUUAUUUUAAAACGGUGAGAUUUUGUUUUGUCUGAGAAAAUCUCGCUGUUUUAGACUGAGG		5
18470	MI0003559	hsa-mir-554	Homo sapiens miR-554 stem-loop	ACCUGAGUAACCUUUGCUAGUCCUGACUCAGCCAGUACUGGUCUUAGACUGGUGAUGGGUCAGGGUUCAUAUUUUGGCAUCUCUCUCUGGGCAUCU		5
18471	MI0003560	hsa-mir-92b	Homo sapiens miR-92b stem-loop	CGGGCCCCGGGCGGGCGGGAGGGACGGGACGCGGUGCAGUGUUGUUUUUUCCCCCGCCAAUAUUGCACUCGUCCCGGCCUCCGGCCCCCCCGGCCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18472	MI0003561	hsa-mir-555	Homo sapiens miR-555 stem-loop	GGAGUGAACUCAGAUGUGGAGCACUACCUUUGUGAGCAGUGUGACCCAAGGCCUGUGGACAGGGUAAGCUGAACCUCUGAUAAAACUCUGAUCUAU		5
18473	MI0003562	hsa-mir-556	Homo sapiens miR-556 stem-loop	GAUAGUAAUAAGAAAGAUGAGCUCAUUGUAAUAUGAGCUUCAUUUAUACAUUUCAUAUUACCAUUAGCUCAUCUUUUUUAUUACUACCUUCAACA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18474	MI0003563	hsa-mir-557	Homo sapiens miR-557 stem-loop	AGAAUGGGCAAAUGAACAGUAAAUUUGGAGGCCUGGGGCCCUCCCUGCUGCUGGAGAAGUGUUUGCACGGGUGGGCCUUGUCUUUGAAAGGAGGUGGA		5
18475	MI0003564	hsa-mir-558	Homo sapiens miR-558 stem-loop	GUGUGUGUGUGUGUGUGUGGUUAUUUUGGUAUAGUAGCUCUAGACUCUAUUAUAGUUUCCUGAGCUGCUGUACCAAAAUACCACAAACGGGCUG		5
18476	MI0003565	hsa-mir-559	Homo sapiens miR-559 stem-loop	GCUCCAGUAACAUCUUAAAGUAAAUAUGCACCAAAAUUACUUUUGGUAAAUACAGUUUUGGUGCAUAUUUACUUUAGGAUGUUACUGGAGCUCCCA		5
18477	MI0003567	hsa-mir-561	Homo sapiens miR-561 stem-loop	CUUCAUCCACCAGUCCUCCAGGAACAUCAAGGAUCUUAAACUUUGCCAGAGCUACAAAGGCAAAGUUUAAGAUCCUUGAAGUUCCUGGGGGAACCAU		5
18478	MI0003568	hsa-mir-562	Homo sapiens miR-562 stem-loop	AGUGAAAUUGCUAGGUCAUAUGGUCAGUCUACUUUUAGAGUAAUUGUGAAACUGUUUUUCAAAGUAGCUGUACCAUUUGCACUCCCUGUGGCAAU		5
18479	MI0003569	hsa-mir-563	Homo sapiens miR-563 stem-loop	AGCAAAGAAGUGUGUUGCCCUCUAGGAAAUGUGUGUUGCUCUGAUGUAAUUAGGUUGACAUACGUUUCCCUGGUAGCCA		5
18480	MI0003570	hsa-mir-564	Homo sapiens miR-564 stem-loop	CGGGCAGCGGGUGCCAGGCACGGUGUCAGCAGGCAACAUGGCCGAGAGGCCGGGGCCUCCGGGCGGCGCCGUGUCCGCGACCGCGUACCCUGAC		5
18481	MI0003572	hsa-mir-566	Homo sapiens miR-566 stem-loop	GCUAGGCGUGGUGGCGGGCGCCUGUGAUCCCAACUACUCAGGAGGCUGGGGCAGCAGAAUCGCUUGAACCCGGGAGGCGAAGGUUGCAGUGAGC		5
18482	MI0003573	hsa-mir-567	Homo sapiens miR-567 stem-loop	GGAUUCUUAUAGGACAGUAUGUUCUUCCAGGACAGAACAUUCUUUGCUAUUUUGUACUGGAAGAACAUGCAAAACUAAAAAAAAAAAAAGUUAUUGCU		5
18483	MI0003574	hsa-mir-568	Homo sapiens miR-568 stem-loop	GAUAUACACUAUAUUAUGUAUAAAUGUAUACACACUUCCUAUAUGUAUCCACAUAUAUAUAGUGUAUAUAUUAUACAUGUAUAGGUGUGUAUAUG		5
18484	MI0003575	hsa-mir-551b	Homo sapiens miR-551b stem-loop	AGAUGUGCUCUCCUGGCCCAUGAAAUCAAGCGUGGGUGAGACCUGGUGCAGAACGGGAAGGCGACCCAUACUUGGUUUCAGAGGCUGUGAGAAUAA		5
18485	MI0003576	hsa-mir-569	Homo sapiens miR-569 stem-loop	GGUAUUGUUAGAUUAAUUUUGUGGGACAUUAACAACAGCAUCAGAAGCAACAUCAGCUUUAGUUAAUGAAUCCUGGAAAGUUAAGUGACUUUAUUU		5
18486	MI0003577	hsa-mir-570	Homo sapiens miR-570 stem-loop	CUAGAUAAGUUAUUAGGUGGGUGCAAAGGUAAUUGCAGUUUUUCCCAUUAUUUUAAUUGCGAAAACAGCAAUUACCUUUGCACCAACCUGAUGGAGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18487	MI0003578	hsa-mir-571	Homo sapiens miR-571 stem-loop	CCUCAGUAAGACCAAGCUCAGUGUGCCAUUUCCUUGUCUGUAGCCAUGUCUAUGGGCUCUUGAGUUGGCCAUCUGAGUGAGGGCCUGCUUAUUCUA		5
18488	MI0003579	hsa-mir-572	Homo sapiens miR-572 stem-loop	GUCGAGGCCGUGGCCCGGAAGUGGUCGGGGCCGCUGCGGGCGGAAGGGCGCCUGUGCUUCGUCCGCUCGGCGGUGGCCCAGCCAGGCCCGCGGGA		5
18489	MI0003580	hsa-mir-573	Homo sapiens miR-573 stem-loop	UUUAGCGGUUUCUCCCUGAAGUGAUGUGUAACUGAUCAGGAUCUACUCAUGUCGUCUUUGGUAAAGUUAUGUCGCUUGUCAGGGUGAGGAGAGUUUUUG		5
18490	MI0003581	hsa-mir-574	Homo sapiens miR-574 stem-loop	GGGACCUGCGUGGGUGCGGGCGUGUGAGUGUGUGUGUGUGAGUGUGUGUCGCUCCGGGUCCACGCUCAUGCACACACCCACACGCCCACACUCAGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18491	MI0003582	hsa-mir-575	Homo sapiens miR-575 stem-loop	AAUUCAGCCCUGCCACUGGCUUAUGUCAUGACCUUGGGCUACUCAGGCUGUCUGCACAAUGAGCCAGUUGGACAGGAGCAGUGCCACUCAACUC		5
18492	MI0003583	hsa-mir-576	Homo sapiens miR-576 stem-loop	UACAAUCCAACGAGGAUUCUAAUUUCUCCACGUCUUUGGUAAUAAGGUUUGGCAAAGAUGUGGAAAAAUUGGAAUCCUCAUUCGAUUGGUUAUAACCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18493	MI0003584	hsa-mir-577	Homo sapiens miR-577 stem-loop	UGGGGGAGUGAAGAGUAGAUAAAAUAUUGGUACCUGAUGAAUCUGAGGCCAGGUUUCAAUACUUUAUCUGCUCUUCAUUUCCCCAUAUCUACUUAC		5
18494	MI0003585	hsa-mir-578	Homo sapiens miR-578 stem-loop	AGAUAAAUCUAUAGACAAAAUACAAUCCCGGACAACAAGAAGCUCCUAUAGCUCCUGUAGCUUCUUGUGCUCUAGGAUUGUAUUUUGUUUAUAUAU		5
18495	MI0003586	hsa-mir-579	Homo sapiens miR-579 stem-loop	CAUAUUAGGUUAAUGCAAAAGUAAUCGCGGUUUGUGCCAGAUGACGAUUUGAAUUAAUAAAUUCAUUUGGUAUAAACCGCGAUUAUUUUUGCAUCAAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18496	MI0003587	hsa-mir-580	Homo sapiens miR-580 stem-loop	AUAAAAUUUCCAAUUGGAACCUAAUGAUUCAUCAGACUCAGAUAUUUAAGUUAACAGUAUUUGAGAAUGAUGAAUCAUUAGGUUCCGGUCAGAAAUU		5
18497	MI0003588	hsa-mir-581	Homo sapiens miR-581 stem-loop	GUUAUGUGAAGGUAUUCUUGUGUUCUCUAGAUCAGUGCUUUUAGAAAAUUUGUGUGAUCUAAAGAACACAAAGAAUACCUACACAGAACCACCUGC		5
18498	MI0003589	hsa-mir-582	Homo sapiens miR-582 stem-loop	AUCUGUGCUCUUUGAUUACAGUUGUUCAACCAGUUACUAAUCUAACUAAUUGUAACUGGUUGAACAACUGAACCCAAAGGGUGCAAAGUAGAAACAUU		5
18499	MI0003590	hsa-mir-583	Homo sapiens miR-583 stem-loop	AACUCACACAUUAACCAAAGAGGAAGGUCCCAUUACUGCAGGGAUCUUAGCAGUACUGGGACCUACCUCUUUGGU		5
18500	MI0003591	hsa-mir-584	Homo sapiens miR-584 stem-loop	UAGGGUGACCAGCCAUUAUGGUUUGCCUGGGACUGAGGAAUUUGCUGGGAUAUGUCAGUUCCAGGCCAACCAGGCUGGUUGGUCUCCCUGAAGCAAC		5
18501	MI0003592	hsa-mir-585	Homo sapiens miR-585 stem-loop	UGGGGUGUCUGUGCUAUGGCAGCCCUAGCACACAGAUACGCCCAGAGAAAGCCUGAACGUUGGGCGUAUCUGUAUGCUAGGGCUGCUGUAACAA		5
18502	MI0003593	hsa-mir-548a-1	Homo sapiens miR-548a-1 stem-loop	UGCAGGGAGGUAUUAAGUUGGUGCAAAAGUAAUUGUGAUUUUUGCCAUUAAAAGUAACGACAAAACUGGCAAUUACUUUUGCACCAAACCUGGUAUU		5
18503	MI0003594	hsa-mir-586	Homo sapiens miR-586 stem-loop	AUGGGGUAAAACCAUUAUGCAUUGUAUUUUUAGGUCCCAAUACAUGUGGGCCCUAAAAAUACAAUGCAUAAUGGUUUUUCACUCUUUAUCUUCUUAU		5
18504	MI0003595	hsa-mir-587	Homo sapiens miR-587 stem-loop	CUCCUAUGCACCCUCUUUCCAUAGGUGAUGAGUCACAGGGCUCAGGGAAUGUGUCUGCACCUGUGACUCAUCACCAGUGGAAAGCCCAUCCCAUAU		5
18505	MI0003596	hsa-mir-548b	Homo sapiens miR-548b stem-loop	CAGACUAUAUAUUUAGGUUGGCGCAAAAGUAAUUGUGGUUUUGGCCUUUAUUUUCAAUGGCAAGAACCUCAGUUGCUUUUGUGCCAACCUAAUACUU		5
18506	MI0003597	hsa-mir-588	Homo sapiens miR-588 stem-loop	AGCUUAGGUACCAAUUUGGCCACAAUGGGUUAGAACACUAUUCCAUUGUGUUCUUACCCACCAUGGCCAAAAUUGGGCCUAAG		5
18507	MI0003598	hsa-mir-548a-2	Homo sapiens miR-548a-2 stem-loop	UGUGAUGUGUAUUAGGUUUGUGCAAAAGUAAUUGGGGUUUUUUGCCGUUAAAAGUAAUGGCAAAACUGGCAAUUACUUUUGCACCAAACUAAUAUAA		5
18508	MI0003599	hsa-mir-589	Homo sapiens miR-589 stem-loop	UCCAGCCUGUGCCCAGCAGCCCCUGAGAACCACGUCUGCUCUGAGCUGGGUACUGCCUGUUCAGAACAAAUGCCGGUUCCCAGACGCUGCCAGCUGGCC	Cummins et al. identified a mature product from the 3' arm of this precursor, and named it miR-589 [1].  Landgraf et al. show that the 5' product is the predominant one [2].  The 3' mature sequence is therefore renamed miR-589*. 	5
18509	MI0003600	hsa-mir-550-1	Homo sapiens miR-550-1 stem-loop	UGAUGCUUUGCUGGCUGGUGCAGUGCCUGAGGGAGUAAGAGCCCUGUUGUUGUAAGAUAGUGUCUUACUCCCUCAGGCACAUCUCCAACAAGUCUCU	Cummins et al. identified a mature product from the 3' arm of this precursor, and named it miR-550 [1].  Landgraf et al. show that the 5' product is the predominant one [2].  The 3' miRNA is therefore renamed miR-550*. 	5
18510	MI0003601	hsa-mir-550-2	Homo sapiens miR-550-2 stem-loop	UGAUGCUUUGCUGGCUGGUGCAGUGCCUGAGGGAGUAAGAGCCCUGUUGUUGUCAGAUAGUGUCUUACUCCCUCAGGCACAUCUCCAGCGAGUCUCU	Cummins et al. identified a mature product from the 3' arm of this precursor, and named it miR-550 [1].  Landgraf et al. show that the 5' product is the predominant one [2].  The 3' miRNA is therefore renamed miR-550*. 	5
18511	MI0003602	hsa-mir-590	Homo sapiens miR-590 stem-loop	UAGCCAGUCAGAAAUGAGCUUAUUCAUAAAAGUGCAGUAUGGUGAAGUCAAUCUGUAAUUUUAUGUAUAAGCUAGUCUCUGAUUGAAACAUGCAGCA		5
18512	MI0003603	hsa-mir-591	Homo sapiens miR-591 stem-loop	UCUUAUCAAUGAGGUAGACCAUGGGUUCUCAUUGUAAUAGUGUAGAAUGUUGGUUAACUGUGGACUCCCUGGCUCUGUCUCAAAUCUACUGAUUC		5
18513	MI0003604	hsa-mir-592	Homo sapiens miR-592 stem-loop	UAUUAUGCCAUGACAUUGUGUCAAUAUGCGAUGAUGUGUUGUGAUGGCACAGCGUCAUCACGUGGUGACGCAACAUCAUGACGUAAGACGUCACAAC		5
18514	MI0003605	hsa-mir-593	Homo sapiens miR-593 stem-loop	CCCCCAGAAUCUGUCAGGCACCAGCCAGGCAUUGCUCAGCCCGUUUCCCUCUGGGGGAGCAAGGAGUGGUGCUGGGUUUGUCUCUGCUGGGGUUUCUCCU	Cummins et al. identified a mature miRNA from the 5' arm of this precursor, and named it miR-593 [1].  Landgraf et al. show that the 3' product is the predominant one [2].  The 5' product is therefore renamed miR-593*. 	5
18515	MI0003607	hsa-mir-595	Homo sapiens miR-595 stem-loop	ACGGAAGCCUGCACGCAUUUAACACCAGCACGCUCAAUGUAGUCUUGUAAGGAACAGGUUGAAGUGUGCCGUGGUGUGUCUGGAGGAAGCGCCUGU		5
18516	MI0003608	hsa-mir-596	Homo sapiens miR-596 stem-loop	AGCACGGCCUCUCCGAAGCCUGCCCGGCUCCUCGGGAACCUGCCUCCCGCAUGGCAGCUGCUGCCCUUCGGAGGCCG		5
18517	MI0003609	hsa-mir-597	Homo sapiens miR-597 stem-loop	UACUUACUCUACGUGUGUGUCACUCGAUGACCACUGUGAAGACAGUAAAAUGUACAGUGGUUCUCUUGUGGCUCAAGCGUAAUGUAGAGUACUGGUC		5
18518	MI0003610	hsa-mir-598	Homo sapiens miR-598 stem-loop	GCUUGAUGAUGCUGCUGAUGCUGGCGGUGAUCCCGAUGGUGUGAGCUGGAAAUGGGGUGCUACGUCAUCGUUGUCAUCGUCAUCAUCAUCAUCCGAG		5
18519	MI0003611	hsa-mir-599	Homo sapiens miR-599 stem-loop	AAAGACAUGCUGUCCACAGUGUGUUUGAUAAGCUGACAUGGGACAGGGAUUCUUUUCACUGUUGUGUCAGUUUAUCAAACCCAUACUUGGAUGAC		5
18520	MI0003612	hsa-mir-548a-3	Homo sapiens miR-548a-3 stem-loop	CCUAGAAUGUUAUUAGGUCGGUGCAAAAGUAAUUGCGAGUUUUACCAUUACUUUCAAUGGCAAAACUGGCAAUUACUUUUGCACCAACGUAAUACUU		5
18521	MI0003613	hsa-mir-600	Homo sapiens miR-600 stem-loop	AAGUCACGUGCUGUGGCUCCAGCUUCAUAGGAAGGCUCUUGUCUGUCAGGCAGUGGAGUUACUUACAGACAAGAGCCUUGCUCAGGCCAGCCCUGCCC		5
18522	MI0003614	hsa-mir-601	Homo sapiens miR-601 stem-loop	UGCAUGAGUUCGUCUUGGUCUAGGAUUGUUGGAGGAGUCAGAAAAACUACCCCAGGGAUCCUGAAGUCCUUUGGGUGGA		5
18523	MI0003615	hsa-mir-602	Homo sapiens miR-602 stem-loop	UUCUCACCCCCGCCUGACACGGGCGACAGCUGCGGCCCGCUGUGUUCACUCGGGCCGAGUGCGUCUCCUGUCAGGCAAGGGAGAGCAGAGCCCCCCUG		5
18524	MI0003616	hsa-mir-603	Homo sapiens miR-603 stem-loop	GAUUGAUGCUGUUGGUUUGGUGCAAAAGUAAUUGCAGUGCUUCCCAUUUAAAAGUAAUGGCACACACUGCAAUUACUUUUGCUCCAACUUAAUACUU		5
18525	MI0003617	hsa-mir-604	Homo sapiens miR-604 stem-loop	AGAGCAUCGUGCUUGACCUUCCACGCUCUCGUGUCCACUAGCAGGCAGGUUUUCUGACACAGGCUGCGGAAUUCAGGACAGUGCAUCAUGGAGA		5
18526	MI0003618	hsa-mir-605	Homo sapiens miR-605 stem-loop	GCCCUAGCUUGGUUCUAAAUCCCAUGGUGCCUUCUCCUUGGGAAAAACAGAGAAGGCACUAUGAGAUUUAGAAUCAAGUUAGG		5
18527	MI0003619	hsa-mir-606	Homo sapiens miR-606 stem-loop	UGUAUCCUUGGUUUUUAGUAGUUUUACUAUGAUGAGGUGUGCCAUCCACCCCAUCAUAGUAAACUACUGAAAAUCAAAGAUACAAGUGCCUGACCA		5
18528	MI0003620	hsa-mir-607	Homo sapiens miR-607 stem-loop	UUGCCUAAAGUCACACAGGUUAUAGAUCUGGAUUGGAACCCAGGGAGCCAGACUGCCUGGGUUCAAAUCCAGAUCUAUAACUUGUGUGACUUUGGG		5
18529	MI0003621	hsa-mir-608	Homo sapiens miR-608 stem-loop	GGGCCAAGGUGGGCCAGGGGUGGUGUUGGGACAGCUCCGUUUAAAAAGGCAUCUCCAAGAGCUUCCAUCAAAGGCUGCCUCUUGGUGCAGCACAGGUAGA		5
18530	MI0003622	hsa-mir-609	Homo sapiens miR-609 stem-loop	UGCUCGGCUGUUCCUAGGGUGUUUCUCUCAUCUCUGGUCUAUAAUGGGUUAAAUAGUAGAGAUGAGGGCAACACCCUAGGAACAGCAGAGGAACC		5
18531	MI0003623	hsa-mir-610	Homo sapiens miR-610 stem-loop	UCUAUUUGUCUUAGGUGAGCUAAAUGUGUGCUGGGACACAUUUGAGCCAAAUGUCCCAGCACACAUUUAGCUCACAUAAGAAAAAUGGACUCUAGU		5
18532	MI0003624	hsa-mir-611	Homo sapiens miR-611 stem-loop	AAAAUGGUGAGAGCGUUGAGGGGAGUUCCAGACGGAGAUGCGAGGACCCCUCGGGGUCUGACCCACA		5
18533	MI0003625	hsa-mir-612	Homo sapiens miR-612 stem-loop	UCCCAUCUGGACCCUGCUGGGCAGGGCUUCUGAGCUCCUUAGCACUAGCAGGAGGGGCUCCAGGGGCCCUCCCUCCAUGGCAGCCAGGACAGGACUCUCA		5
18534	MI0003626	hsa-mir-613	Homo sapiens miR-613 stem-loop	GGUGAGUGCGUUUCCAAGUGUGAAGGGACCCUUCCUGUAGUGUCUUAUAUACAAUACAGUAGGAAUGUUCCUUCUUUGCCACUCAUACACCUUUA		5
18535	MI0003627	hsa-mir-614	Homo sapiens miR-614 stem-loop	UCUAAGAAACGCAGUGGUCUCUGAAGCCUGCAGGGGCAGGCCAGCCCUGCACUGAACGCCUGUUCUUGCCAGGUGGCAGAAGGUUGCUGC		5
18536	MI0003628	hsa-mir-615	Homo sapiens miR-615 stem-loop	CUCGGGAGGGGCGGGAGGGGGGUCCCCGGUGCUCGGAUCUCGAGGGUGCUUAUUGUUCGGUCCGAGCCUGGGUCUCCCUCUUCCCCCCAACCCCCC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18537	MI0003629	hsa-mir-616	Homo sapiens miR-616 stem-loop	UUAGGUAAUUCCUCCACUCAAAACCCUUCAGUGACUUCCAUGACAUGAAAUAGGAAGUCAUUGGAGGGUUUGAGCAGAGGAAUGACCUGUUUUAAAA	Cummins et al. identified a mature product from the 5' arm of this precursor, and named it miR-616 [1].  Landgraf et al. show that the 3' product is the predominant one [2].  The 5' miRNA is therefore renamed miR-616*. 	5
18538	MI0003630	hsa-mir-548c	Homo sapiens miR-548c stem-loop	CAUUGGCAUCUAUUAGGUUGGUGCAAAAGUAAUUGCGGUUUUUGCCAUUACUUUCAGUAGCAAAAAUCUCAAUUACUUUUGCACCAACUUAAUACUU	Extensive cloning studies suggest that the 5' miRNA may be the predominant one [2]. 	5
18539	MI0003631	hsa-mir-617	Homo sapiens miR-617 stem-loop	CAUCAUAAGGAGCCUAGACUUCCCAUUUGAAGGUGGCCAUUUCCUACCACCUUCAAAUGGUAAGUCCAGGCUCCUUCUGAUUCAAUAAAUGAGGAGC		5
18540	MI0003632	hsa-mir-618	Homo sapiens miR-618 stem-loop	CUCUUGUUCACAGCCAAACUCUACUUGUCCUUCUGAGUGUAAUUACGUACAUGCAGUAGCUCAGGAGACAAGCAGGUUUACCCUGUGGAUGAGUCUGA		5
18541	MI0003633	hsa-mir-619	Homo sapiens miR-619 stem-loop	CGCCCACCUCAGCCUCCCAAAAUGCUGGGAUUACAGGCAUGAGCCACUGCGGUCGACCAUGACCUGGACAUGUUUGUGCCCAGUACUGUCAGUUUGCAG		5
18542	MI0003634	hsa-mir-620	Homo sapiens miR-620 stem-loop	AUAUAUAUCUAUAUCUAGCUCCGUAUAUAUAUAUAUAUAUAUAUAGAUAUCUCCAUAUAUAUGGAGAUAGAUAUAGAAAUAAAACAAGCAAAGAA		5
18543	MI0003635	hsa-mir-621	Homo sapiens miR-621 stem-loop	UAGAUUGAGGAAGGGGCUGAGUGGUAGGCGGUGCUGCUGUGCUCUGAUGAAGACCCAUGUGGCUAGCAACAGCGCUUACCUUUUGUCUCUGGGUCC		5
18544	MI0003636	hsa-mir-622	Homo sapiens miR-622 stem-loop	AGAGAAGCUGGACAAGUACUGGUCUCAGCAGAUUGAGGAGAGCACCACAGUGGUCAUCACACAGUCUGCUGAGGUUGGAGCUGCUGAGAUGACACU		5
18545	MI0003637	hsa-mir-623	Homo sapiens miR-623 stem-loop	GUACACAGUAGAAGCAUCCCUUGCAGGGGCUGUUGGGUUGCAUCCUAAGCUGUGCUGGAGCUUCCCGAUGUACUCUGUAGAUGUCUUUGCACCUUCUG		5
18546	MI0003638	hsa-mir-624	Homo sapiens miR-624 stem-loop	AAUGCUGUUUCAAGGUAGUACCAGUACCUUGUGUUCAGUGGAACCAAGGUAAACACAAGGUAUUGGUAUUACCUUGAGAUAGCAUUACACCUAAGUG	Cummins et al. identified a mature miRNA from the 5' arm of this precursor, and named it miR-624 [1].  Landgraf et al. later showed that the 3' product is the predominant one [2].  The 5' product is therefore renamed miR-624*. 	5
18547	MI0003639	hsa-mir-625	Homo sapiens miR-625 stem-loop	AGGGUAGAGGGAUGAGGGGGAAAGUUCUAUAGUCCUGUAAUUAGAUCUCAGGACUAUAGAACUUUCCCCCUCAUCCCUCUGCCCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18548	MI0003640	hsa-mir-626	Homo sapiens miR-626 stem-loop	ACUGAUAUAUUUGUCUUAUUUGAGAGCUGAGGAGUAUUUUUAUGCAAUCUGAAUGAUCUCAGCUGUCUGAAAAUGUCUUCAAUUUUAAAGGCUU		5
18549	MI0003641	hsa-mir-627	Homo sapiens miR-627 stem-loop	UACUUAUUACUGGUAGUGAGUCUCUAAGAAAAGAGGAGGUGGUUGUUUUCCUCCUCUUUUCUUUGAGACUCACUACCAAUAAUAAGAAAUACUACUA		5
18550	MI0003642	hsa-mir-628	Homo sapiens miR-628 stem-loop	AUAGCUGUUGUGUCACUUCCUCAUGCUGACAUAUUUACUAGAGGGUAAAAUUAAUAACCUUCUAGUAAGAGUGGCAGUCGAAGGGAAGGGCUCAU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18551	MI0003643	hsa-mir-629	Homo sapiens miR-629 stem-loop	UCCCUUUCCCAGGGGAGGGGCUGGGUUUACGUUGGGAGAACUUUUACGGUGAACCAGGAGGUUCUCCCAACGUAAGCCCAGCCCCUCCCCUCUGCCU	Cummins et al. identified a product from the 3' arm of this precursor, and named it miR-629 [1].  Landgraf et al. later showed that the 3' product is the predominant one [2].  The 3' product is renamed miR-629*. 	5
18552	MI0003644	hsa-mir-630	Homo sapiens miR-630 stem-loop	AACUUAACAUCAUGCUACCUCUUUGUAUCAUAUUUUGUUAUUCUGGUCACAGAAUGACCUAGUAUUCUGUACCAGGGAAGGUAGUUCUUAACUAUAU		5
18553	MI0003645	hsa-mir-631	Homo sapiens miR-631 stem-loop	GUGGGGAGCCUGGUUAGACCUGGCCCAGACCUCAGCUACACAAGCUGAUGGACUGAGUCAGGGGCCACACUCUCC		5
18554	MI0003646	hsa-mir-33b	Homo sapiens miR-33b stem-loop	GCGGGCGGCCCCGCGGUGCAUUGCUGUUGCAUUGCACGUGUGUGAGGCGGGUGCAGUGCCUCGGCAGUGCAGCCCGGAGCCGGCCCCUGGCACCAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18555	MI0003647	hsa-mir-632	Homo sapiens miR-632 stem-loop	CGCCUCCUACCGCAGUGCUUGACGGGAGGCGGAGCGGGGAACGAGGCCGUCGGCCAUUUUGUGUCUGCUUCCUGUGGGACGUGGUGGUAGCCGU		5
18556	MI0003648	hsa-mir-633	Homo sapiens miR-633 stem-loop	AACCUCUCUUAGCCUCUGUUUCUUUAUUGCGGUAGAUACUAUUAACCUAAAAUGAGAAGGCUAAUAGUAUCUACCACAAUAAAAUUGUUGUGAGGAUA		5
18557	MI0003649	hsa-mir-634	Homo sapiens miR-634 stem-loop	AAACCCACACCACUGCAUUUUGGCCAUCGAGGGUUGGGGCUUGGUGUCAUGCCCCAAGAUAACCAGCACCCCAACUUUGGACAGCAUGGAUUAGUCU		5
18558	MI0003650	hsa-mir-635	Homo sapiens miR-635 stem-loop	CAGAGAGGAGCUGCCACUUGGGCACUGAAACAAUGUCCAUUAGGCUUUGUUAUGGAAACUUCUCCUGAUCAUUGUUUUGUGUCCAUUGAGCUUCCAAU		5
18559	MI0003651	hsa-mir-636	Homo sapiens miR-636 stem-loop	UGGCGGCCUGGGCGGGAGCGCGCGGGCGGGGCCGGCCCCGCUGCCUGGAAUUAACCCCGCUGUGCUUGCUCGUCCCGCCCGCAGCCCUAGGCGGCGUCG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18560	MI0003652	hsa-mir-637	Homo sapiens miR-637 stem-loop	UGGCUAAGGUGUUGGCUCGGGCUCCCCACUGCAGUUACCCUCCCCUCGGCGUUACUGAGCACUGGGGGCUUUCGGGCUCUGCGUCUGCACAGAUACUUC		5
18561	MI0003653	hsa-mir-638	Homo sapiens miR-638 stem-loop	GUGAGCGGGCGCGGCAGGGAUCGCGGGCGGGUGGCGGCCUAGGGCGCGGAGGGCGGACCGGGAAUGGCGCGCCGUGCGCCGCCGGCGUAACUGCGGCGCU		5
18562	MI0003654	hsa-mir-639	Homo sapiens miR-639 stem-loop	UGGCCGACGGGGCGCGCGCGGCCUGGAGGGGCGGGGCGGACGCAGAGCCGCGUUUAGUCUAUCGCUGCGGUUGCGAGCGCUGUAGGGAGCCUGUGCUG		5
18563	MI0003655	hsa-mir-640	Homo sapiens miR-640 stem-loop	GUGACCCUGGGCAAGUUCCUGAAGAUCAGACACAUCAGAUCCCUUAUCUGUAAAAUGGGCAUGAUCCAGGAACCUGCCUCUACGGUUGCCUUGGGG		5
18564	MI0003656	hsa-mir-641	Homo sapiens miR-641 stem-loop	UGGGUGAAAGGAAGGAAAGACAUAGGAUAGAGUCACCUCUGUCCUCUGUCCUCUACCUAUAGAGGUGACUGUCCUAUGUCUUUCCUUCCUCUUACCCCU		5
18565	MI0003657	hsa-mir-642	Homo sapiens miR-642 stem-loop	AUCUGAGUUGGGAGGGUCCCUCUCCAAAUGUGUCUUGGGGUGGGGGAUCAAGACACAUUUGGAGAGGGAACCUCCCAACUCGGCCUCUGCCAUCAUU		5
18566	MI0003658	hsa-mir-643	Homo sapiens miR-643 stem-loop	ACCAAGUGAUAUUCAUUGUCUACCUGAGCUAGAAUACAAGUAGUUGGCGUCUUCAGAGACACUUGUAUGCUAGCUCAGGUAGAUAUUGAAUGAAAAA		5
18567	MI0003659	hsa-mir-644	Homo sapiens miR-644 stem-loop	UUUUUUUUUAGUAUUUUUCCAUCAGUGUUCAUAAGGAAUGUUGCUCUGUAGUUUUCUUAUAGUGUGGCUUUCUUAGAGCAAAGAUGGUUCCCUA		5
18568	MI0003660	hsa-mir-645	Homo sapiens miR-645 stem-loop	CAGUUCCUAACAGGCCUCAGACCAGUACCGGUCUGUGGCCUGGGGGUUGAGGACCCCUGCUCUAGGCUGGUACUGCUGAUGCUUAAAAAGAGAG		5
18569	MI0003661	hsa-mir-646	Homo sapiens miR-646 stem-loop	GAUCAGGAGUCUGCCAGUGGAGUCAGCACACCUGCUUUUCACCUGUGAUCCCAGGAGAGGAAGCAGCUGCCUCUGAGGCCUCAGGCUCAGUGGC		5
18570	MI0003662	hsa-mir-647	Homo sapiens miR-647 stem-loop	AGGAAGUGUUGGCCUGUGGCUGCACUCACUUCCUUCAGCCCCAGGAAGCCUUGGUCGGGGGCAGGAGGGAGGGUCAGGCAGGGCUGGGGGCCUGAC		5
18571	MI0003663	hsa-mir-648	Homo sapiens miR-648 stem-loop	AUCACAGACACCUCCAAGUGUGCAGGGCACUGGUGGGGGCCGGGGCAGGCCCAGCGAAAGUGCAGGACCUGGCACUUAGUCGGAAGUGAGGGUG		5
18572	MI0003664	hsa-mir-649	Homo sapiens miR-649 stem-loop	GGCCUAGCCAAAUACUGUAUUUUUGAUCGACAUUUGGUUGAAAAAUAUCUAUGUAUUAGUAAACCUGUGUUGUUCAAGAGUCCACUGUGUUUUGCUG		5
18573	MI0003665	hsa-mir-650	Homo sapiens miR-650 stem-loop	CAGUGCUGGGGUCUCAGGAGGCAGCGCUCUCAGGACGUCACCACCAUGGCCUGGGCUCUGCUCCUCCUCACCCUCCUCACUCAGGGCACAGGUGAU		5
18574	MI0003666	hsa-mir-651	Homo sapiens miR-651 stem-loop	AAUCUAUCACUGCUUUUUAGGAUAAGCUUGACUUUUGUUCAAAUAAAAAUGCAAAAGGAAAGUGUAUCCUAAAAGGCAAUGACAGUUUAAUGUGUUU		5
18575	MI0003667	hsa-mir-652	Homo sapiens miR-652 stem-loop	ACGAAUGGCUAUGCACUGCACAACCCUAGGAGAGGGUGCCAUUCACAUAGACUAUAAUUGAAUGGCGCCACUAGGGUUGUGCAGUGCACAACCUACAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 3' end of the miRNA is offset with respect to previous annotations.  miR-652 cloned in [2] has a 1 nt 3' extension (U), which is incompatible with the genome sequence. 	5
18576	MI0003668	hsa-mir-548d-1	Homo sapiens miR-548d-1 stem-loop	AAACAAGUUAUAUUAGGUUGGUGCAAAAGUAAUUGUGGUUUUUGCCUGUAAAAGUAAUGGCAAAAACCACAGUUUCUUUUGCACCAGACUAAUAAAG		5
18577	MI0003669	hsa-mir-661	Homo sapiens miR-661 stem-loop	GGAGAGGCUGUGCUGUGGGGCAGGCGCAGGCCUGAGCCCUGGUUUCGGGCUGCCUGGGUCUCUGGCCUGCGCGUGACUUUGGGGUGGCU		5
18578	MI0003670	hsa-mir-662	Homo sapiens miR-662 stem-loop	GCUGUUGAGGCUGCGCAGCCAGGCCCUGACGGUGGGGUGGCUGCGGGCCUUCUGAAGGUCUCCCACGUUGUGGCCCAGCAGCGCAGUCACGUUGC		5
18579	MI0003671	hsa-mir-548d-2	Homo sapiens miR-548d-2 stem-loop	GAGAGGGAAGAUUUAGGUUGGUGCAAAAGUAAUUGUGGUUUUUGCCAUUGAAAGUAAUGGCAAAAACCACAGUUUCUUUUGCACCAACCUAAUAAAA		5
18580	MI0003672	hsa-mir-663	Homo sapiens miR-663 stem-loop	CCUUCCGGCGUCCCAGGCGGGGCGCCGCGGGACCGCCCUCGUGUCUGUGGCGGUGGGAUCCCGCGGCCGUGUUUUCCUGGUGGCCCGGCCAUG		5
18581	MI0003673	hsa-mir-449b	Homo sapiens miR-449b stem-loop	UGACCUGAAUCAGGUAGGCAGUGUAUUGUUAGCUGGCUGCUUGGGUCAAGUCAGCAGCCACAACUACCCUGCCACUUGCUUCUGGAUAAAUUCUUCU		5
18582	MI0003674	hsa-mir-653	Homo sapiens miR-653 stem-loop	UUCAUUCCUUCAGUGUUGAAACAAUCUCUACUGAACCAGCUUCAAACAAGUUCACUGGAGUUUGUUUCAAUAUUGCAAGAAUGAUAAGAUGGAAGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	5
18583	MI0003675	hsa-mir-411	Homo sapiens miR-411 stem-loop	UGGUACUUGGAGAGAUAGUAGACCGUAUAGCGUACGCUUUAUCUGUGACGUAUGUAACACGGUCCACUAACCCUCAGUAUCAAAUCCAUCCCCGAG		5
18584	MI0003676	hsa-mir-654	Homo sapiens miR-654 stem-loop	GGGUAAGUGGAAAGAUGGUGGGCCGCAGAACAUGUGCUGAGUUCGUGCCAUAUGUCUGCUGACCAUCACCUUUAGAAGCCC		5
18585	MI0003677	hsa-mir-655	Homo sapiens miR-655 stem-loop	AACUAUGCAAGGAUAUUUGAGGAGAGGUUAUCCGUGUUAUGUUCGCUUCAUUCAUCAUGAAUAAUACAUGGUUAACCUCUUUUUGAAUAUCAGACUC		5
18586	MI0003678	hsa-mir-656	Homo sapiens miR-656 stem-loop	CUGAAAUAGGUUGCCUGUGAGGUGUUCACUUUCUAUAUGAUGAAUAUUAUACAGUCAACCUCUUUCCGAUAUCGAAUC		5
18587	MI0003679	hsa-mir-549	Homo sapiens miR-549 stem-loop	AGACAUGCAACUCAAGAAUAUAUUGAGAGCUCAUCCAUAGUUGUCACUGUCUCAAAUCAGUGACAACUAUGGAUGAGCUCUUAAUAUAUCCCAGGC	Cummins et al report two mature isoforms that map to the same precursor locus, referred to as miR-549a (shown here) and miR-549b (two nt longer at the 3' end - GACAACUAUGGAUGAGCUCUCA) [1]. 	5
18588	MI0003681	hsa-mir-657	Homo sapiens miR-657 stem-loop	GUGUAGUAGAGCUAGGAGGAGAGGGUCCUGGAGAAGCGUGGACCGGUCCGGGUGGGUUCCGGCAGGUUCUCACCCUCUCUAGGCCCCAUUCUCCUCUG		5
18589	MI0003682	hsa-mir-658	Homo sapiens miR-658 stem-loop	GCUCGGUUGCCGUGGUUGCGGGCCCUGCCCGCCCGCCAGCUCGCUGACAGCACGACUCAGGGCGGAGGGAAGUAGGUCCGUUGGUCGGUCGGGAACGAGG		5
18590	MI0003683	hsa-mir-659	Homo sapiens miR-659 stem-loop	UACCGACCCUCGAUUUGGUUCAGGACCUUCCCUGAACCAAGGAAGAGUCACAGUCUCUUCCUUGGUUCAGGGAGGGUCCCCAACAAUGUCCUCAUGG		5
18591	MI0003684	hsa-mir-660	Homo sapiens miR-660 stem-loop	CUGCUCCUUCUCCCAUACCCAUUGCAUAUCGGAGUUGUGAAUUCUCAAAACACCUCCUGUGUGCAUGGAUUACAGGAGGGUGAGCCUUGUCAUCGUG		5
18592	MI0003685	hsa-mir-421	Homo sapiens miR-421 stem-loop	GCACAUUGUAGGCCUCAUUAAAUGUUUGUUGAAUGAAAAAAUGAAUCAUCAACAGACAUUAAUUGGGCGCCUGCUCUGUGAUCUC		5
18593	MI0003686	hsa-mir-542	Homo sapiens miR-542 stem-loop	CAGAUCUCAGACAUCUCGGGGAUCAUCAUGUCACGAGAUACCAGUGUGCACUUGUGACAGAUUGAUAACUGAAAGGUCUGGGAGCCACUCAUCUUCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18594	MI0003687	hcmv-mir-US4	Human cytomegalovirus miR-US4 stem-loop	CGUGUCGCGACAUGGACGUGCAGGGGGAUGUCUGUCGCGAUAGAGUUGAUGUGACAGCCCGCUACACCUCUCUGUCGCGACAUG		22
18595	MI0003688	hcmv-mir-UL70	Human cytomegalovirus miR-UL70 stem-loop	GGUUGCGUCUCGGCCUCGUCCAGACUGGCGAUGAGCGCCGAGAGGGGGAUGGGCUGGCGCGCGGCC		22
18596	MI0003689	sv40-mir-S1	Simian virus 40 miR-S1 stem-loop	UGAACAGACUGUGAGGGCUGAGGGGCCUGAAAUGAGCCUUGAGACUGUGAAUCAAUGCCUGUUUCAUGCCCUGAGUCUUCCAUGUUCU		41
18597	MI0003690	dre-mir-34b	Danio rerio miR-34b stem-loop	GGGGUUGGUCUGUAGGCAGUGUUGUUAGCUGAUUGUUUCAUAUGAACUAUAAUCACUAACCAUACUGCCAACACAACAACCUACA		12
18598	MI0003691	dre-mir-31	Danio rerio miR-31 stem-loop	GAAGAGAUGGCAAGAUGUUGGCAUAGCUGUUAAUGUUUAUGGGCCUGCUAUGCCUCCAUAUUGCCAUUUCUG		12
18599	MI0003692	dre-mir-135a	Danio rerio miR-135a stem-loop	ACAGCUGUCGUGUCUUAUGGCUUUUUAUUCCUAUGUGAAGGUGAACAAGGCUCAUGUAGGGAUACAAGCCACUAAACACGCAGUCAGAAAUCAGCUUU		12
18600	MI0003693	dre-mir-139	Danio rerio miR-139 stem-loop	CUGUAUUCUACAGUGCAUGUGUCUCCAGUGUUUCUAUGGCGACUGGGGAGGCAGCGCUGUUGGAAUAAC		12
18601	MI0003694	gga-mir-9-1	Gallus gallus miR-9-1 stem-loop	UUGGGUUGGUUUUUCUCUUUGGUUAUCUAGCUGUAUGAGUGUAUGUGAUAUCAUAAAGCUAGAGAACCGAAUGUAAAAACCCGCUCGC		10
18602	MI0003695	gga-mir-146b	MI0003695 Gallus gallus miR-146b stem-loop	GGACUGGCUGCUUGGCUUUGAGAACUGAAUUCCAUAGGCGUUAAAGCAUCCAAAAAUGCCCUAUGGAUUCAGUUCUGCAGUUGGGCAGCAAAUAAACCUCCAGCC		10
18603	MI0003696	gga-mir-147-1	Gallus gallus miR-147-1 stem-loop	AAUCUAGUGGAAUCACUUCUGCACAAACUUGACUACUGAAAUCAGUGUGCGGAAAUGCUUCUGCUACAUU		10
18604	MI0003697	gga-mir-147-2	Gallus gallus miR-147-2 stem-loop	AAUCUAGUGGAAUCACUUCUGCACAAACUUGACUACUGAAAUCAGUGUGCGGAAAUGCUUCUGCUACAUU		10
18605	MI0003698	gga-mir-193b	Gallus gallus miR-193b stem-loop	GUGGUUCCAGAGUCGGGGUUUUGGGGGCGAGAUGAGCUUAUGUUUUAUCCAACUGGCCCACAAAGUCCCGCUUUUGGUGGUCA		10
18606	MI0003699	gga-mir-202	Gallus gallus miR-202 stem-loop	GCUCGUUGUUCCUUUUUCCUAUGCAUAUACUUCUUUGAGAGUUUGAUCUAAAGAGGCAUAGAGCAUGGGAAAAUGGGGCGACUGAGGUA		10
18607	MI0003700	gga-mir-302b	Gallus gallus miR-302b stem-loop	CCCUUUUACUUUAACAUGGAGGUGCUUUCUGUGAUUUUACAAAAGUAAGUGCUUCCAUGUUUUAGUAGAGGU		10
18608	MI0003701	gga-mir-302c	Gallus gallus miR-302c stem-loop	CCUCCGCUUUAACAUGGAGGUACCUGCUGCCUACAAAAGUAAGUGCUUCCAUGUUUCAGUGGUGG		10
18609	MI0003702	gga-mir-302d	Gallus gallus miR-302d stem-loop	CCUCAACUUUAACAUGGAGGUACUUGCUGGACACCUGAAAAAGUAAGUGCUUCCAUGUUUUAGUUGUGG		10
18610	MI0003703	gga-mir-365-1	Gallus gallus miR-365-1 stem-loop	CGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUACACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA		10
18611	MI0003704	gga-mir-365-2	Gallus gallus miR-365-2 stem-loop	GGCAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUUACUAACCCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCAAUGGUCAA		10
18612	MI0003705	gga-mir-375	Gallus gallus miR-375 stem-loop	CCUGGCGUCGAGCCCCACGUGCAAGACCUGACCUGAACGUUUUGUUCGUUCGGCUCGCGUUAGGC		10
18613	MI0003706	gga-mir-383	Gallus gallus miR-383 stem-loop	CUCCUCAGAUCAGAAGGUGAUUGUGGCUUUGGGUAAAUAUUGAGCAGCCACAGCACUGCCUGGUCAGAAAGAG		10
18614	MI0003707	gga-mir-455	Gallus gallus miR-455 stem-loop	UCCCUGGUGUGAGGGUAUGUGCCCUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGU		10
18615	MI0003708	gga-mir-489	Gallus gallus miR-489 stem-loop	GUGGUGGCUUGGUGGUCGUAUGUAUGACGUCAUUUACUUGGACUUUUAGGAGUGACAUCAUAUGUACGGCUGCUAAACUGCUGC		10
18616	MI0003709	gga-mir-490	Gallus gallus miR-490 stem-loop	AAGUUCAUGGUUCGACACCAUGGAUCUCCAGGUGGGUCAAGAUUAUAGAGAUACACCAACCUGGAGGACUCCAUGCUGUUGAGCUGUUCACAA		10
18617	MI0003710	gga-mir-499	Gallus gallus miR-499 stem-loop	UUUGAGGGAGCGGCAGUUAAGACUUGUAGUGAUGUUUAGAUAAUGUAUUACAUGAACAUCACUUUAAGUCUGUGCUACUUCUCUCCUCAUU		10
18618	MI0003711	gga-mir-211	Gallus gallus miR-211 stem-loop	CCUGUGAGCUUCCCUUUGUCAUCCUAUGCCUGAGCGAUGCCUGGAGGCUGGGACGGUGAAGGGAGGCCCACGGG		10
18619	MI0003712	gga-mir-367	Gallus gallus miR-367 stem-loop	AGGCUAAUACUGUUGCUAACAUGCAACUCUGUUGUAUAAAAAUUGGAAUUGCACUUUAGCAAUGGUGAUGGAC		10
18620	MI0003713	gga-mir-466	Gallus gallus miR-466 stem-loop	AGUUUUCUGAGUGUACAUAUAUGUAUGUAUGUAUAUAUAUAUAUAUAUAUAUACACACACACAUAAGAC		10
18621	MI0003714	gga-mir-429	Gallus gallus miR-429 stem-loop	GCCUGCUGAUUGCUGUCUUACCAGGCAAAGUUAGAUCUAGCUAUUUCUGUCUAAUACUGUCUGGUAAUGCCGUCAAUCGCAUGG		10
18622	MI0003715	gga-mir-449	Gallus gallus miR-449 stem-loop	CUGUGUGCGGUGGGGUGGCAGUGUAUGUUAGCUGGUUGAAACUCUUGACAUCAGCUAACACGCAGUUGCUAACCUGCUCCACAUAC		10
18623	MI0003716	mmu-mir-302b	Mus musculus miR-302b stem-loop	GUUCCCUUCAACUUUAACAUGGGAAUGCUUUCUGUCUCAUCGAAGAGUAAGUGCUUCCAUGUUUUAGUAGAAGU	Mouse miR-302b was verified experimentally by Mineno et al using MPSS technology [1].  The MPSS protocol used provides 22nt sequences, but the true extents of the mature miRNA are not reliably obtained.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18624	MI0003717	mmu-mir-302c	Mus musculus miR-302c stem-loop	CCUCUGCUUUAACAUGGGGUUACCUGCUGUGUUAAACAAAAGCAAGUGCUUCCAUGUUUCAGUGGGGG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [1].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18625	MI0003718	mmu-mir-302d	Mus musculus miR-302d stem-loop	CCUUUACUUUAACAUGGAGGCACUUGCUGUGCAUUUAAAAAUAAGUGCUUCCAUGUUUGAGUGUGG	Mouse miR-302d was verified experimentally by Mineno et al using MPSS technology [1].  The MPSS protocol used provides 22nt sequences, but the true extents of the mature miRNA are not reliably obtained.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18626	MI0003719	rno-mir-378	Rattus norvegicus miR-378/miR-422b stem-loop	GGGCUCCUGACUCCAGGUCCUGUGUGUUACCUCGAAAUAGCACUGGACUUGGAGUCAGAAGGCCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	8
18627	MI0003720	rno-mir-505	Rattus norvegicus miR-505 stem-loop	AGUGGGGGAGCCAGGAAGUAUUGAUGUUUCUGCCAGGUUAGCGUCAACACUUGCUGGUUUCCUCUCU		8
18628	MI0003721	rno-mir-499	Rattus norvegicus miR-499 stem-loop	GCUGUUAAGACUUGCAGUGAUGUUUAGCUCCUCUCCAUGUGAACAUCACAGCAAGUCUGUGCUGC		8
18629	MI0003722	rno-mir-664-1	Rattus norvegicus miR-664-1 stem-loop	CUGGCUGGGGAAAAAGAUUGGAUAGAAAACAUUAUUCUAUUCAUUUACUCCCCAGCCUA		8
18630	MI0003723	rno-mir-664-2	Rattus norvegicus miR-664-2 stem-loop	CUGGCUGGGGAAAAUGAUUGGAUAGAAAACAUUAUUCUAUUCAUUUACUCCCCAGCCUA		8
18631	MI0003724	rno-mir-497	Rattus norvegicus miR-497 stem-loop	CCAGCAGCACACUGUGGUUUGUACGGCACUGUGGCCACGUCCAAACCACACUGUGGUGUUAGAGCGAGG		8
18632	MI0003725	ebv-mir-BART3	Epstein Barr virus miR-BART3 stem-loop	CCUUUGGUGGAACCUAGUGUUAGUGUUGUGCUGUAAAUAAGUGUCCAGCGCACCACUAGUCACCAGGUGUCACCGGAGG	mir-BART3 was discovered independently by two groups.  Cai et al identified mature miRNA products from both arms of the hairpin precursor and mapped the ends of the mature sequences by cloning [1].  Grundhoff et al confirmed that the 5' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  The mature miRNA names reflect cloning frequencies from Landgraf et al. [3], and may differ subtly from previous annotations.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18633	MI0003726	ebv-mir-BART4	Epstein Barr virus miR-BART4 stem-loop	UUUGGUGGGACCUGAUGCUGCUGGUGUGCUGUAAAUAAGUGCCUAGCACAUCACGUAGGCACCAGGUGUCACCAGG	mir-BART4 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 5' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2]. 	9
18634	MI0003727	ebv-mir-BART5	Epstein Barr virus miR-BART5 stem-loop	GCUCUGUGGCACCUCAAGGUGAAUAUAGCUGCCCAUCGACGUAUCGCUGGAAACCGGUGGGCCGCUGUUCACCUAAAGUGACGCAAGGU	mir-BART5 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 5' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence was misnamed miR-BART6 in [2]. 	9
18635	MI0003728	ebv-mir-BART6	Epstein Barr virus miR-BART6 stem-loop	UGACCUUGUUGGUACUUUAAGGUUGGUCCAAUCCAUAGGCUUUUUUUGUGAAAACCCGGGGAUCGGACUAGCCUUAGAGUAACUCAAGGCCA	mir-BART6 was discovered independently by two groups.  Cai et al identified a mature miRNA product from the 3' arm of the hairpin precursor and mapped the ends of the mature sequence by cloning [1].  Grundhoff et al report that the 5' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence was misnamed miR-BART9 in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18636	MI0003729	ebv-mir-BART7	Epstein Barr virus miR-BART7 stem-loop	UCCAGUGUCCUGAUCCUGGACCUUGACUAUGAAACAAUUCUAAAAAAAUGCAUCAUAGUCCAGUGUCCAGGGACAGUGCACUCGGA	mir-BART7 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence is misnamed miR-BART11 in [2]. 	9
18637	MI0003730	ebv-mir-BART8	Epstein Barr virus miR-BART8 stem-loop	UGGGUUCACUGAUUACGGUUUCCUAGAUUGUACAGAUGAACUAGAACUGUCACAAUCUAUGGGGUCGUAGACAGUGUGCUUA	mir-BART8 was discovered independently by two groups.  Cai et al identified a mature miRNA product from the 5' arm of the hairpin precursor and mapped the ends of the mature sequence by cloning [1].  Grundhoff et al report that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  The ends of ebv-miR-BART8-3p are therefore predicted, not experimentally determined. This sequence was misnamed miR-BART12 in [2].  The mature miRNA names reflect cloning frequencies from Landgraf et al. [3], and may differ subtly from previous annotations.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18638	MI0003731	ebv-mir-BART9	Epstein Barr virus miR-BART9 stem-loop	CAGCUGUUGUUUGUACUGGACCCUGAAUUGGAAACAGUAACUUGGAUUCUGUAACACUUCAUGGGUCCCGUAGUGACAACUAUGCUG	mir-BART9 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence was misnamed miR-BART13 in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18639	MI0003732	ebv-mir-BART10	Epstein Barr virus miR-BART10 stem-loop	CAGAGGAGUGUCCCGGGGCCACCUCUUUGGUUCUGUACAUAUUUUGUUAUUGUACAUAACCAUGGAGUUGGCUGUGGUGCACUCCAUCUG	mir-BART10 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence was misnamed miR-BART14 in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18640	MI0003733	ebv-mir-BART11	Epstein Barr virus miR-BART11 stem-loop	GGCUUCUGUUGGGUCAGACAGUUUGGUGCGCUAGUUGUGUGCUUAGCAGCAACGCACACCAGGCUGACUGCCUUAGCAGUGUGGCC	mir-BART11 was discovered independently by two groups.  Cai et al identified a mature miRNA product from the 3' arm of the hairpin precursor and mapped the ends of the mature sequence by cloning [1].  Grundhoff et al report that the 5' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence was misnamed miR-BART15 in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18641	MI0003734	ebv-mir-BART12	Epstein Barr virus miR-BART12 stem-loop	CUGGUGACCUAACACCCGCCCAUCACCACCGGACAGAUUCUGAACUUGUCCUGUGGUGUUUGGUGUGGUUUUGGGGUACGCAG	mir-BART12 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence is misnamed miR-BART16 in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	9
18642	MI0003735	ebv-mir-BART13	Epstein Barr virus miR-BART13 stem-loop	UUGGGCACCUCGAUAACCGGCUCGUGGCUCGUACAGACGAUUGUUUGGCUCUGUAACUUGCCAGGGACGGCUGACGAUGUGUUUAG	mir-BART13 was discovered independently by two groups.  Cai et al mapped the ends of the mature sequence by cloning [1].  Grundhoff et al confirmed that the 3' arm gives rise to a mature miRNA product, but didnot experimentally determine the extents of that product [2].  This sequence is misnamed miR-BART19 in [2]. 	9
18643	MI0003736	ebv-mir-BART14	Epstein Barr virus miR-BART14 stem-loop	CAGGGGUGGCCGGUACCCUACGCUGCCGAUUUACAUAAUAUAAAUUGUAAAUGCUGCAGUAGUAGGGAUCUGGACGCGCGACCUG	mir-BART14 was discovered independently by two groups.  Cai et al identified a mature miRNA products from the 5' arm of the hairpin precursor and mapped the ends of the mature sequence by cloning [1]. Grundhoff et al report that both arms give rise to a mature miRNA products, but didnot experimentally determine the extents of those products [2].  The ends of ebv-miR-BART14-3p are therefore predicted, not experimentally determined.  This sequence is nisnamed miR-BART20 in [2]. The mature miRNA names reflect cloning frequencies from Landgraf et al. [3], and may differ subtly from previous annotations. 	9
18644	MI0003737	rlcv-mir-rL1-1	Rhesus lymphocryptovirus miR-rL1-1 stem-loop	GGCCGGCUCCUUAUUAACCUGAUCAGCCCCGGGGUUGCCUGUCUUAGCACUAACUCCGGGCCUGAAGAGGUUGACAAGAAGGGUC		42
18645	MI0003738	rlcv-mir-rL1-2	Rhesus lymphocryptovirus miR-rL1-2 stem-loop	GCCCCCACUUUUAAAUUCUGCCACAGAAGAUAGCUGAUACUCGAUGUUAUCUUUUGCGGGGGAAUUUCCAAGUGUUGGC		42
18646	MI0003739	rlcv-mir-rL1-3	Rhesus lymphocryptovirus miR-rL1-3 stem-loop	CUGGGUCCUCGGGGGGCGGUGGAGACCGCGGGUGCGGUGAUUGCUUGACCCUCGCACCUCGCCGUCUCUACUGCUCGCCGGGUACGUCUGG		42
18647	MI0003740	rlcv-mir-rL1-4	Rhesus lymphocryptovirus miR-rL1-4 stem-loop	GAGAUGCUUUAACCUUGGGGGGACCUAGUAAUUGUGCGGUGUUGUGAGUGUUAGAAACACCACACGAUCCACUAGGUCUCACCUGGGCUCCUUGCCUC		42
18648	MI0003741	rlcv-mir-rL1-5	Rhesus lymphocryptovirus miR-rL1-5 stem-loop	CUUCGGUGGAACCUAGUGCCGGUGAUGUGCUGUGGAUAGGCAGCUAGCGCACCACUUUUCACUAGGUGUCACCGGGG		42
18649	MI0003742	rlcv-mir-rL1-6	Rhesus lymphocryptovirus miR-rL1-6 stem-loop	CCCUUGGUGGGUUUUAGUGGAAGUGACGUGCUGUGAUUAGGUACCCAUAGCACCGCUAUCCACUAUGUCUCACCAGGG	The mature miRNA names reflect cloning frequencies from Landgraf et al. [2], and may differ subtly from previous annotations. 	42
18650	MI0003743	rlcv-mir-rL1-7	Rhesus lymphocryptovirus miR-rL1-7 stem-loop	CCGUGUGCCGCUUCGAGGUAAACAUCGGCUUACUGAAGUCUCUUAGUAAGGUCAGUGGGCCUGUUUCCCUCACAGAGACACAUGG		42
18651	MI0003744	rlcv-mir-rL1-8	Rhesus lymphocryptovirus miR-rL1-8 stem-loop	UUGCUGCGGCACCGUAAGGUGAAUAUAGCUGCCCAUUGAUGUCUGUUUAGAACCCGGUGGGCCGCAGUUCACCUACAGUGACGCAGUGA	The predominant mature miRNA form cloned by Landgraf et al. has an additional 3' terminal U residue, which is incompatible with the genome sequence and hairpin shown here [2]. 	42
18652	MI0003745	rlcv-mir-rL1-9	Rhesus lymphocryptovirus miR-rL1-9 stem-loop	GCCUGCGGAACCCUAAGAGGGGGGCCUGCACGCCGAGGUUAUUUCCCAGCCCUUCGAUGCAUGGUCCCCCCUUAGUGGACUGCAGGC		42
18653	MI0003746	rlcv-mir-rL1-10	Rhesus lymphocryptovirus miR-rL1-10 stem-loop	GUGGUCCUCUGACAUCGGGUUUCCGCUGUACUUGCAUAAUGAGAACUUUGUAGUGCGCCGGUGACCUGAUAGCAGCGGUCUCAC		42
18654	MI0003747	rlcv-mir-rL1-11	Rhesus lymphocryptovirus miR-rL1-11 stem-loop	GGGGCCUUGCCUCCGUAUCCUAUCAAGUGUGACGUGGCUUUGUUCGUGACACUCGAUAGGAUACGGGGGUAAAGGCGCCU		42
18655	MI0003748	rlcv-mir-rL1-12	Rhesus lymphocryptovirus miR-rL1-12 stem-loop	UCAGGGUACGCUCAGACCAGACCAUGCACAGUGGGCGAUUAAGACAUUGCUCUAACGGUGCAUGGACUGGCUAGAGUGUUCCUGG		42
18656	MI0003749	rlcv-mir-rL1-13	Rhesus lymphocryptovirus miR-rL1-13 stem-loop	CCCGUGUCUUGAUCCUGGGCAUGGGCUAUGAAACAGUUCUAACAAUUGGAUCAUAGCCAGUGUCCAGGGACGGUGCACCGGG		42
18657	MI0003750	rlcv-mir-rL1-14	Rhesus lymphocryptovirus miR-rL1-14 stem-loop	GCCCUCCGGCUGGGUCGGACGGUCUGGUGCGCUUGAUGUGUUUUCGGUACCAUCGCACAUCAGGCUGAACGACUCAGAGGAGUGGC		42
18658	MI0003751	rlcv-mir-rL1-15	Rhesus lymphocryptovirus miR-rL1-15 stem-loop	UUCCUGGAGCCGGUGACCUGAGACCCACCCUUCUCGACGGGGCAGGUGUUAUAAGUGUCCUGUAGAGUAUGGGUGUGGUUUUAGUGCACGCGGGAG		42
18659	MI0003752	rlcv-mir-rL1-16	Rhesus lymphocryptovirus miR-rL1-16 stem-loop	GAGGGCCAGUUGAAGCAGGCAUGUCUUCAUUCCUGAUUUCCUGAUGGCAUGAAACACAUGGCCUGUUCCUAUUGGCACCUU		42
18660	MI0003757	hsa-mir-758	Homo sapiens miR-758 stem-loop	GCCUGGAUACAUGAGAUGGUUGACCAGAGAGCACACGCUUUAUUUGUGCCGUUUGUGACCUGGUCCACUAACCCUCAGUAUCUAAUGC		5
18661	MI0003758	hsa-mir-1264	Homo sapiens miR-1264 stem-loop	AGGUCCUCAAUAAGUAUUUGUUGAAAGAAUAAAUAAACCAACAAGUCUUAUUUGAGCACCUGUUAUGUG		5
18662	MI0003760	hsa-mir-671	Homo sapiens miR-671 stem-loop	GCAGGUGAACUGGCAGGCCAGGAAGAGGAGGAAGCCCUGGAGGGGCUGGAGGUGAUGGAUGUUUUCCUCCGGUUCUCAGGGCUCCACCUCUUUCGGGCCGUAGAGCCAGGGCUGGUGC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18663	MI0003761	hsa-mir-668	Homo sapiens miR-668 stem-loop	GGUAAGUGCGCCUCGGGUGAGCAUGCACUUAAUGUGGGUGUAUGUCACUCGGCUCGGCCCACUACC		5
18664	MI0003763	hsa-mir-767	Homo sapiens miR-767 stem-loop	GCUUUUAUAUUGUAGGUUUUUGCUCAUGCACCAUGGUUGUCUGAGCAUGCAGCAUGCUUGUCUGCUCAUACCCCAUGGUUUCUGAGCAGGAACCUUCAUUGUCUACUGC		5
18665	MI0003764	hsa-mir-1224	Homo sapiens mir-1224 stem-loop	GUGAGGACUCGGGAGGUGGAGGGUGGUGCCGCCGGGGCCGGGCGCUGUUUCAGCUCGCUUCUCCCCCCACCUCCUCUCUCCUCAG	This sequence was identified as a miRNA candidate by Berezikov et al [1], and confirmed later by more extensive cloning [2]. 	5
18666	MI0003776	hsa-mir-320b-1	Homo sapiens mir-320b-1 stem-loop	AAUUAAUCCCUCUCUUUCUAGUUCUUCCUAGAGUGAGGAAAAGCUGGGUUGAGAGGGCAAACAAAUUAACUAAUUAAUU		5
18667	MI0003778	hsa-mir-320c-1	Homo sapiens mir-320c-1 stem-loop	UUUGCAUUAAAAAUGAGGCCUUCUCUUCCCAGUUCUUCCCAGAGUCAGGAAAAGCUGGGUUGAGAGGGUAGAAAAAAAAUGAUGUAGG	This sequence was identified as a candidate by RAKE analysis [1], and later confirmed by Solexa sequencing [2]. 	5
18668	MI0003780	hsa-mir-1296	Homo sapiens miR-1296 stem-loop	ACCUACCUAACUGGGUUAGGGCCCUGGCUCCAUCUCCUUUAGGAAAACCUUCUGUGGGGAGUGGGGCUUCGACCCUAACCCAGGUGGGCUGU		5
18669	MI0003786	hsa-mir-1323	Homo sapiens miR-1323 stem-loop	ACUGAGGUCCUCAAAACUGAGGGGCAUUUUCUGUGGUUUGAAAGGAAAGUGCACCCAGUUUUGGGGAUGUCAA	This sequence was identified as a miRNA candidate by Berezikov et al [1], and confirmed later by cloning [2].  Afanasyeva et al. refer to this sequence using the internal identifier MYCNAMP_NB2_61 [2]. 	5
18670	MI0003814	hsa-mir-1271	Homo sapiens miR-1271 stem-loop	CACCCAGAUCAGUGCUUGGCACCUAGCAAGCACUCAGUAAAUAUUUGUUGAGUGCCUGCUAUGUGCCAGGCAUUGUGCUGAGGGCU		5
18671	MI0003815	hsa-mir-1301	Homo sapiens miR-1301 stem-loop	GGAUUGUGGGGGGUCGCUCUAGGCACCGCAGCACUGUGCUGGGGAUGUUGCAGCUGCCUGGGAGUGACUUCACACAGUCCUC		5
18672	MI0003820	hsa-mir-454	Homo sapiens miR-454 stem-loop	UCUGUUUAUCACCAGAUCCUAGAACCCUAUCAAUAUUGUCUCUGCUGUGUAAAUAGUUCUGAGUAGUGCAAUAUUGCUUAUAGGGUUUUGGUGUUUGGAAAGAACAAUGGGCAGG	The mature miRNA sequences were named miR-454-5p and miR-454-3p in [1] and here.  Landgraf et al. showed that the 3' product is the predominant one [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	5
18673	MI0003821	hsa-mir-1185-2	Homo sapiens miR-1185-2 stem-loop	UUUGGUACUUAAAGAGAGGAUACCCUUUGUAUGUUCACUUGAUUAAUGGCGAAUAUACAGGGGGAGACUCUCAUUUGCGUAUCAAA	This sequence was proposed as a miRNA candidate by Berezikov et al by RAKE analysis [1], and validated by cloning independently by Subramanian et al [2]. 	5
18674	MI0003832	hsa-mir-1283-1	Homo sapiens miR-1283-1 stem-loop	CUCAAGCUAUGAGUCUACAAAGGAAAGCGCUUUCUGUUGUCAGAAAGAAGAGAAAGCGCUUCCCUUUUGAGGGUUACGGUUUGAGAA		5
18675	MI0003834	hsa-mir-769	Homo sapiens miR-769 stem-loop	GCCUUGGUGCUGAUUCCUGGGCUCUGACCUGAGACCUCUGGGUUCUGAGCUGUGAUGUUGCUCUCGAGCUGGGAUCUCCGGGGUCUUGGUUCAGGGCCGGGGCCUCUGGGUUCCAAGC		5
18676	MI0003836	hsa-mir-766	Homo sapiens miR-766 stem-loop	GCAUCCUCAGGACCUGGGCUUGGGUGGUAGGAGGAAUUGGUGCUGGUCUUUCAUUUUGGAUUUGACUCCAGCCCCACAGCCUCAGCCACCCCAGCCAAUUGUCAUAGGAGC		5
18677	MI0003839	hsa-mir-320b-2	Homo sapiens miR-320b-2 stem-loop	UGUUAUUUUUUGUCUUCUACCUAAGAAUUCUGUCUCUUAGGCUUUCUCUUCCCAGAUUUCCCAAAGUUGGGAAAAGCUGGGUUGAGAGGGCAAAAGGAAAAAAAAAGAAUUCUGUCUCUGACAUAAUUAGAUAGGGAA	This sequence was identified as a candidate by RAKE analysis [1], and later confirmed by Solexa sequencing [2,3].  The sequence was named mir-1242 in [2]. 	5
18678	MI0003844	hsa-mir-1185-1	Homo sapiens miR-1185-1 stem-loop	UUUGGUACUUGAAGAGAGGAUACCCUUUGUAUGUUCACUUGAUUAAUGGCGAAUAUACAGGGGGAGACUCUUAUUUGCGUAUCAAA	This sequence was proposed as a miRNA candidate by Berezikov et al by RAKE analysis [1], and validated by cloning independently by Subramanian et al [2]. 	5
18679	MI0003906	hsa-mir-802	Homo sapiens mir-802 stem-loop	GUUCUGUUAUUUGCAGUCAGUAACAAAGAUUCAUCCUUGUGUCCAUCAUGCAACAAGGAGAAUCUUUGUCACUUAGUGUAAUUAAUAGCUGGAC		5
18680	MI0003938	hsa-mir-1298	Homo sapiens miR-1298 stem-loop	AGACGAGGAGUUAAGAGUUCAUUCGGCUGUCCAGAUGUAUCCAAGUACCCUGUGUUAUUUGGCAAUAAAUACAUCUGGGCAACUGACUGAACUUUUCACUUUUCAUGACUCA		5
18681	MI0004118	mmu-mir-1224	Mus musculus mir-1224 stem-loop	GUGAGGACUGGGGAGGUGGAGGGUAGCAUCAUUAGAGCCAGAGCUCUGUCUCAGCUCCCUCUCCCCCCACCUCUUCUCUCCUCAG	This sequence was identified as a miRNA candidate by Berezikov et al [1], and confirmed later by more extensive cloning [2]. 	6
18682	MI0004122	mmu-mir-301b	Mus musculus mir-301b stem-loop	UUUCCUGCUGGCUGCGGGUGCUCUGACUAGGUUGCACUACUGUGCUGUGAGAAGCAGUGCAAUGGUAUUGUCAAAGCAUCUGGGACCAGCCUCGAAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
18683	MI0004123	mmu-mir-675	Mus musculus mir-675 stem-loop	UGCGGCCCAGGGACUGGUGCGGAAAGGGCCCACAGUGGACUUGGUACACUGUAUGCCCUAACCGCUCAGUCCCUGGGUCUGGCA		6
18684	MI0004124	mmu-mir-744	Mus musculus mir-744 stem-loop	GGCUGGGCAAGGUGCGGGGCUAGGGCUAACAGCAGUCUUACUGACGGUUUCCUGGAAACCACACACAUGCUGUUGCCACUAACCUCAACCUUACUCGGUC	mir-744 was also named mir-803 in Takada et al., supplementary information [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18685	MI0004125	mmu-mir-374	Mus musculus mir-374 stem-loop	GAAGAAAUCCUACUCGGGUGGAUAUAAUACAACCUGCUAAGUGUUCUAGCACUUAGCAGGUUGUAUUAUCAUUGUCCGAGGUUAUGGCUCUCGUC		6
18686	MI0004126	mmu-mir-216b	Mus musculus mir-216b stem-loop	UUGGCAGACUGGGAAAUCUCUGCAGGCAAAUGUGAUGUCACUGAAGAAACCACACACUUACCUGUAGAGAUUCUUCAGUCUGACAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18687	MI0004127	mmu-mir-592	Mus musculus mir-592 stem-loop	UGAUAUUAUGCCAUGACAUUGUGUCAAUAUGCGAUGAUGUGUUGUGAUGGCACAGCGUCAUCACGUGGUGACGCAACAUCAUGACGUAAGACAUCA		6
18688	MI0004129	mmu-mir-758	Mus musculus miR-758 stem-loop	UGGGUGCGUGAGGUGGUUGACCAGAGAGCACACGCUAUAUUUGUGCCGUUUGUGACCUGGUCCACUAACCCUCAGUAUCUA		6
18689	MI0004131	mmu-mir-551b	Mus musculus mir-551b stem-loop	GUGCUCUUGUGGCCCAUGAAAUCAAGCUUGGGUGAGACCUGGUGCAGAACAGGAAGGCGACCCAUACUUGGUUUCAGUGGCUGCAAGAAUGACUGCAU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18690	MI0004133	mmu-mir-671	Mus musculus mir-671 stem-loop	UGGCAGGCCAGGAAGAGGAGGAAGCCCUGGAGGGGCUGGAGGUGAUGGAUGUUUUCCUCCGGUUCUCAGGGCUCCACCUCUUUCGAGCCGUAGAGCCA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18691	MI0004134	mmu-mir-668	Mus musculus mir-668 stem-loop	GGUAAGUGUGCCUCGGGUGAGCAUGCACUUAAUGUAGGUGUAUGUCACUCGGCUCGGCCCACUACC		6
18692	MI0004171	mmu-mir-665	Mus musculus mir-665 stem-loop	AGAACAGGGUCUCCUUGAGGGGCCUCUGCCUCUAUCCAGGAUUAUGUUUUUAUGACCAGGAGGCUGAGGUCCCUUACAGGCGGCCUCUUACUCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18693	MI0004196	mmu-mir-667	Mus musculus mir-667 stem-loop	GUGGGUACUGGCCUCGGUGCUGGUGGAGCAGUGAGCACGCCAUACAUUAUAUCUGUGACACCUGCCACCCAGCCCAAGGCCCCUAGGCCCAC		6
18694	MI0004203	mmu-mir-770	Mus musculus miR-770 stem-loop	GCCACCUUCUGUGCCCCCAGCACCACGUGUCUGGGCCACGUGAGCAACGCCACGUGGGCCUGACGUGGAGCUGGGGCCGCAGGGGUCUGAUGGC		6
18695	MI0004215	mmu-mir-762	Mus musculus miR-762 stem-loop	GCCCGGCUCCGGGUCUCGGCCCGCACGGUCCGGCCGGCCAUGCUGGCGGGGCUGGGGCCGGGACAGAGCCCGUGGC		6
18696	MI0004249	mmu-mir-802	Mus musculus mir-802 stem-loop	GGUCCUAUUAUUUGCAAUCAGUAACAAAGAUUCAUCCUUGUGUCAAUCAUACAACACGGAGAGUCUUUGUCACUCAGUGUAAUUAAUAGCCUUCACC		6
18697	MI0004258	mmu-mir-672	Mus musculus mir-672 stem-loop	GAUGGUGAUCUAGCCCUUUAGUUUUGAGGUUGGUGUACUGUGUGUGAGUAUACAUAUUUAUCACACACAGUCACUAUCUUCGAAAGUGAGGGUGCACAUC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3]. 	6
18698	MI0004295	mmu-mir-670	Mus musculus mir-670 stem-loop	GGUUUGGAGGUGGGCCUGACAUCCCUGAGUGUAUGUGGUGAACCUGAACUUGCCCUGGGUUUCCUCAUAUCCAUUCAGGAGUGUCAGCUGCCUCUUCGCU		6
18699	MI0004306	mmu-mir-761	Mus musculus miR-761 stem-loop	UGGCAAGUGGAGGAGCAGCAGGGUGAAACUGACACAGUGCUGGUGAGUUUCACUUUGCUGCUCCUCCUGACUCCCA		6
18700	MI0004310	mmu-mir-764	Mus musculus miR-764 stem-loop	UCAACACAAUCUGAAUCUUGGAGGCAGGUGCUCACAUGUCCUCCUCCAUGCUUAUAAAUACAUGGAGGAGGCCAUAGUGGCAACUGUCACCAUGAUUGAUUUCGUUGG		6
18701	MI0004516	mmu-mir-763	Mus musculus miR-763 stem-loop	AAUGAUGGAGGUGCAGGCGUUUCCUGGGGAUUAAUGACCAGCUGGGAAGAACCAGUGGCCCUCGGCUCUGCCUCCCAGCCAGCCAUUAACUCCAAGGAAAUGUCUUUUGCUGAGGUCGUU		6
18702	MI0004523	mmu-mir-669a-1	Mus musculus mir-669a-1 stem-loop	UGUAUGUGCAUGUGUGUAUAGUUGUGUGUGCAUGUUCAUGUCUAUAUUUGAAUAUACAUAACAUACACACACACGUAUAAACGCAAGCACACAUACA	The sequence of miR-669a-1 is of low complexity.  The sequence maps exactly to several genomic positions, and many more with 1 or 2 substitutions. Confidence in this miRNA might therefore be reduced. 	6
18703	MI0004553	mmu-mir-666	Mus musculus mir-666 stem-loop	CUGAUUCUGCCUGCGUGGAGCGGGCACAGCUGUGAGAGCCCCCUAGGUACAGCGGGGCUGCAGCGUGAUCGCCUGCUCACGCACAGGAAGUGACGACAG		6
18704	MI0004554	mmu-mir-759	Mus musculus miR-759 stem-loop	GGAUUAUAAUAAAUUAAAUGCCUAAACUGGCAGAGUGCAAACAAUUUUGACUCAGAUCUAAAUGUUUGCACUGGCUGUUUAAACAUUUAAUUUGUUCC		6
18705	MI0004589	mmu-mir-496	Mus musculus mir-496 stem-loop	AGUGUUCGAAUGGAGGUUGCCCAUGGUGUGUUCAUUUUAUUUAUGAUGAGUAUUACAUGGCCAAUCUCCUUUCGGCACU		6
18706	MI0004601	mmu-mir-673	Mus musculus mir-673 stem-loop	UGGAGCCUGAGGGGCUCACAGCUCUGGUCCUUGGAGCUCCAGAGAAAAUGUUGCUCCGGGGCUGAGUUCUGUGCACCCCCCUUGCCCUCCA		6
18707	MI0004605	mmu-mir-760	Mus musculus miR-760 stem-loop	CGGGAGGAUGCCUCGGUGCGGGGCGCGUCGCCCCCCUCAGGCCACCAGAGCCCGGAUACCUCAGAAAUUCGGCUCUGGGUCUGUGGGGAGCGAAAUGCAACCCAAACCCCGUUUCCCCG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18708	MI0004611	mmu-mir-674	Mus musculus mir-674 stem-loop	GGCCUAGUCAUCACCCUGAGCCUUGCACUGAGAUGGGAGUGGUGUAAGGCUCAGGUAUGCACAGCUCCCAUCUCAGAACAAGGCUCGGGUGUGCUCAGCU	Landgraf et al. show that the 5' miRNA product is the predominant one [4]. 	6
18709	MI0004633	mmu-mir-488	Mus musculus miR-488 stem-loop	UUCGGGUGAGAGUGAGAAUCCUCUCUCCCAGAUAAUAGCACUCUCAAACAAGUUUCCAUGUUGUUUGAAAGGCUGUUUCUUGGUCAGAAGACUCUCAAUUUCUUCUGGA	The predominant miRNA cloned by Langraf et al. has a 3' terminal U residue, which is incompatible with the genome sequence [2]. 	6
18710	MI0004634	mmu-mir-677	Mus musculus miR-677 stem-loop	GAGCCUUCAGUGAUGAUUAGCUUCUGACUUUCGUUCUUCUGAAUUUGCUGAAGCCAGAUGCCGUUCCUGAGAAGGGGAAAAUGGACAGAACUGAACAUUUUUGAAGGCU		6
18711	MI0004635	mmu-mir-678	Mus musculus miR-678 stem-loop	GUGGACUGUGACUUGCAGAGCUGUGCUCCAAUAUGAGAGAUGGCCAUGCACCCGUGUCUCGGUGCAAGGACUGGAGGUGGCAGU		6
18712	MI0004636	mmu-mir-497	Mus musculus miR-497 stem-loop	CCUGCCCCCGCCCCAGCAGCACACUGUGGUUUGUACGGCACUGUGGCCACGUCCAAACCACACUGUGGUGUUAGAGCGAGGGUA		6
18713	MI0004637	mmu-mir-423	Mus musculus miR-423 stem-loop	ACUUGUGAGGAAAUAAAGGAAGUUAGGCUGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGUCUUGCUUCCUACCCCGCGCUUG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
18714	MI0004638	mmu-mir-679	Mus musculus miR-679 stem-loop	CUAUGGCUUUGGACUGUGAGGUGACUCUUGGUGUGUGAUGGCUUUUCAGCAAGGUCCUCCUCACAGUAGCUAUA		6
18715	MI0004639	mmu-mir-495	Mus musculus miR-495 stem-loop	AAAGAAGUUGCCCAUGUUAUUUUUCGCUUUUAUUUGUGACGAAACAAACAUGGUGCACUUCUU		6
18716	MI0004640	mmu-mir-680-1	Mus musculus miR-680-1 stem-loop	AGAAGUGGGCAUCUGCUGACAUGGGGGCCGAAGUCAGGCGCCAGGAAGCGGGCACUUUGCAUCUUAUCUCCGGAACAUCGAUCCUCUUGACAGCCUUGGGUGUCAGGCU		6
18717	MI0004641	mmu-mir-680-2	Mus musculus miR-680-2 stem-loop	GGGCAUCUGCUGACAUGGGGGCCGAAGUCAGGCGCCAGGCAUCGGGCACUCUGGAUCUUAUCUCUGGAACAUUGAUCCUCCUUGACAGCCUUGGGGGUCAGGCUGGGCUC		6
18718	MI0004642	mmu-mir-680-3	Mus musculus miR-680-3 stem-loop	GGGGGAUUUAACAAAGAACAAAAAAGGUGGGCAUCUGCUGACAUGGGGGCAGAAGUCAGGCUCUAGGCAGCAGGUACUCUUCAUCUU		6
18719	MI0004643	mmu-mir-681	Mus musculus miR-681 stem-loop	GCAGCCUCGCUGGCAGGCAGCUCCAGAGUGUGGCUGUCCUCAUCACUCUCCCUAAGCAGGUAGAUGGGUUUCAGUUCACUCGCAGUCCAGGGCCUCCAGCGGGACAGUUG		6
18720	MI0004644	mmu-mir-682	Mus musculus miR-682 stem-loop	GCCGUCGGCAUCUGGCACUGUGGUUCCUGCAUGAAAACAGUGGCCGGCGGGGCCUGGACCUACAACACCACCUCUGCAGUCACAGUGAAGUCUGCC		6
18721	MI0004645	mmu-mir-449c	Mus musculus miR-449c stem-loop	AGGAUGAAGUGUGGGUGUGUCAGGCAGGCAGUGCAUUGCUAGCUGGCUGUUAGAACUUUAUCCCAACAGUUGCUAGCUGCACUACCCUCUGCUGCACUCAGAAGCAUGC		6
18722	MI0004646	mmu-mir-683	Mus musculus miR-683 stem-loop	UGGGAAGUCCAGCUGGGAGGCUGCAGUGGACCCAGGCUAAAAGCCAAGCUUUUCUGCACUGCAGUGGAUGCCUGCUGUAAGCUGUGUCCUCCUGGGCUGCAUGGAGCCC		6
18723	MI0004647	mmu-mir-684-1	Mus musculus miR-684-1 stem-loop	GUAGGGCAAUCUGUCUUUAAGUAGGGAUAAAUUACUCUUGAACAAAAUGAUCCUAGAUAGUUUUCCCUUCAAGUCAAGCGUCUUGC		6
18724	MI0004648	mmu-mir-684-2	Mus musculus miR-684-2 stem-loop	UGUAGGGCAAUCUGUCUUUAAGUAGGGAUAAAUUACUCUUGAACAAAAUGAUCCUAGAUAGUUUUCCCUUCAAGUCAAGUGUCUUG		6
18725	MI0004649	mmu-mir-685	Mus musculus miR-685 stem-loop	GUCGGGGCGGAUGCCUCCCUCGCCGGAGCGGAUGCCUCCCUCGCCGGAGCUUGGAACAGACUCACGGCCAGCAGUGCGAGUUCAAUGGCUGAGGUGAGGCACCUCCCGG		6
18726	MI0004650	mmu-mir-686	Mus musculus miR-686 stem-loop	GCCACAGCAGGUGCUUAUAUUGCUUCCCAGACGGUGAAGAAAGUAAUAGAGAUCAACCCGUACCUUCUGGGCACCAUGGCUGGGGGUGCAGCGGAUUGCAGCUUCUGGG		6
18727	MI0004651	mmu-mir-719	Mus musculus miR-719 stem-loop	UUUAGGUGCUUAAAGAACAGUAUCUCGGCUACAGAAAAAUGUUUUUGGGUGAUGCUGUGGAUGUGUUUGAAGCCAGGAGAACAGAAGCCAAGAAGUGGCAGAAUGCACCC		6
18728	MI0004652	mmu-mir-687	Mus musculus miR-687 stem-loop	AUAGUCUGACACACAUUUUACACUAUCCUGGAAUGCAGCAAUGAAUCCUGGGUUAUUGUUUCAGUCUGUCAUUGUAUUCUUGGAAAGUG		6
18729	MI0004653	mmu-mir-688	Mus musculus miR-688 stem-loop	GAAAGGGCAGUGAAGAAAAGUAGGGGCUUGCUUGGGGAGAGCACCUCGCAGGCGACUACUUAUUCCAGCUCGCCC		6
18730	MI0004654	mmu-mir-689-1	Mus musculus miR-689-1 stem-loop	CCCGGAUAGCCGGGUCCCCGUCCGUCCCCGCUCGGCGGGGUCCCCGCGUCCUCCCCGCAGCGGCGCGGGGUCUCCCCCCGCCGGGCGUCGGGACCGGGAUCCGGUGCGG		6
18731	MI0004655	mmu-mir-689-2	Mus musculus miR-689-2 stem-loop	CCCGGAUAGCCGGGUCCCCGUCCGUCCCCGCUCGGCGGGGUCCCCGCGUCGUCCCCGCGGCGGCGCGGGGUCUCCCCCCGCCGGGCGUCGGGACCGGGGUCCGGUGCGG		6
18732	MI0004658	mmu-mir-690	Mus musculus miR-690 stem-loop	UGUGUUUUUGUGGAGCUAAUUGGCUGUAUUAAAGUGCUAGUAAGAAACAUUCUCCUCCAGCUGGAGAGAUGGCUCAGCUGUUAAAGGCUAGGCUCACAACCAAAAUAUA		6
18733	MI0004659	mmu-mir-691	Mus musculus miR-691 stem-loop	GCUGAUUUAUUUUUGCUUUCUUCCUUGGGUCUGCUUUGAAUAUUCCUGAAGAGAGGCAGAAAAUGUUAUAUUUAAUAU		6
18734	MI0004660	mmu-mir-692-1	Mus musculus miR-692-1 stem-loop	AGGGUGGCAGGGCCACAACCAGCGCAGACUGGCGCGCCCCAGGGAUCUCUGGGUGAGUAUCUCUUUGAGCGCCUCACUCUCAAGCACAACUAGGAGGCCUCUGCCUUCC		6
18735	MI0004661	mmu-mir-692-2	Mus musculus miR-692-2 stem-loop	GGUGGCAGGGCCACAACCAGCGCAGACUGGCGCGCCCCAGGGAUCUCUGGGCGAGUAUCUCUUUGAGCGCCUCACUCUCAAGCACGACUAGGAGGCCUCUGUGCCUUCC		6
18736	MI0004662	mmu-mir-693	Mus musculus miR-693 stem-loop	AGUUGUAGGCAUGCUCAUUACAGCCACAUCCGAAAGUUUUCCUGGCUAGGGCAGCUUUCAGAUGUGGCUGUAAUGAGCAUGCUCCCAGC		6
18737	MI0004664	mmu-mir-694	Mus musculus miR-694 stem-loop	AAAGGCCAGCUCAGGCAUCGCUUUCAACCCAAGACCAGGCUGAAAAUGUUGCCUGAAGCAGUCUCUGCCU		6
18738	MI0004665	mmu-mir-146b	Mus musculus miR-146b stem-loop	GACUGAGAGAACUUUGGCCACCUGGCUCUGAGAACUGAAUUCCAUAGGCUGUGAGCUCUAGCAGACGCCCUAGGGACUCAGUUCUGGUGCCCGGCUGUGCUAUACCAUC		6
18739	MI0004666	mmu-mir-669b	Mus musculus miR-669b stem-loop	AUGAAUGUAUGUGCAUGUGUAUAUAGUUUUGUGUGCAUGUGCAUGUGUGUCUAUUAAUGUACAUAUACAUACACACAAACAUAUACACGCAUGCGCA		6
18740	MI0004667	mmu-mir-669a-2	Mus musculus miR-669a-2 stem-loop	CAUGUAUGUGCAUGUGUGUAUAGUUGUGUGUGCAUGUUCAUGUCUAUAUUUGAAUAUACAUAACAUACACACACACGUAUAAACGCAAGCACACACA		6
18741	MI0004668	mmu-mir-669a-3	Mus musculus miR-669a-3 stem-loop	UUCCUCCAUGUAUGUGCAUGUGUGUAUAGUUGUGUGUGCAUGUUCAUGUCUAUAUUUGAAUAUACAUAACAUACACACACAUGUAUAAACGCAAGCACACAUACACAGA		6
18742	MI0004671	mmu-mir-467b	Mus musculus miR-467b stem-loop	CCGUGUGCGUAAGUGCCUGCAUGUAUAUGCGUGUAUAUUUUAUGCAUAUACAUACACACACCAACACACACAU	The sequence of miR-467 is of low complexity.  The sequence maps exactly to several genomic positions, and many more with 1 or 2 substitutions. Confidence in this miRNA might therefore be reduced. 	6
18743	MI0004673	mmu-mir-669c	Mus musculus miR-669c stem-loop	CCUCCAUGUAUGUGCAUGUGUGUAUAGUUGUGUGUGGAUGUGUGUAUUUGCAUAUAAAUAACAUACACACACACACACAAGUAAACACAAGUGCACAAACAGACACAGG		6
18744	MI0004674	mmu-mir-297b	Mus musculus miR-297b stem-loop	UCUAUUUGCUUGUGUGUAUAUGUAUGUGUGCAUGAACAUGUGUAUAUGAAUAUACAUAUACAUACACACAUACCCAUACAAACAUGCAUACAAACACACAGAAAAUGGA		6
18745	MI0004675	mmu-mir-695	Mus musculus miR-695 stem-loop	UCACGAGGAAUCCUAGAUUGGGCAUAGGUGACUGAAGUACACAGCUGCCUUUCUUACAAAGGCACUGGUUACCUUGGUCCUGGUCACCGGCUCGGCUAUCUGCUACUCG		6
18746	MI0004676	mmu-mir-499	Mus musculus miR-499 stem-loop	GGGUGGGCAGCUGUUAAGACUUGCAGUGAUGUUUAGCUCCUCUGCAUGUGAACAUCACAGCAAGUCUGUGCUGCUGCCU		6
18747	MI0004677	mmu-mir-696	Mus musculus miR-696 stem-loop	GGUCUGUCGCGGUGCCUGAAGCUGUCCCCGAGCCACGCUUCCUGCUUUCCCGGGCUUGCUGCUUGCGUGUGCUUGCUGUGGGCAGCUU		6
18748	MI0004678	mmu-mir-720	Mus musculus miR-720 stem-loop	CUGGAGCCCCAGAAUGAAGAUGCAGCUUUAGAAUUUGGGUGGUCUAUCUCGCUGGGGCCUCCAG		6
18749	MI0004679	mmu-mir-455	Mus musculus miR-455 stem-loop	CUCCCUGGUGUGAGCGUAUGUGCCUUUGGACUACAUCGUGAACGCAGCACCAUGCAGUCCACGGGCAUAUACACUUGCCUCA	Landgraf et al. show that the 3' mature miRNA product is the predominant one [3].  The 5' miRNA is renamed miR-455* here.  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18750	MI0004680	mmu-mir-491	Mus musculus miR-491 stem-loop	AAUUGACUUAGCUGGGAAGUGGGGAACCCUUCCAUGAGGAGUAGAACACUCCUUAUGCAAGAUUCCCUUCUACCUGACUGAGUUGA		6
18751	MI0004681	mmu-mir-697	Mus musculus miR-697 stem-loop	GAGUGGGGAUGUGUCCUGGAUGUUGGUCUUGACAGGUCUCAGAGGUGACUACCACACAUUGAAGGGGUGGCGGUAACAUCCUGGUCCUGUGGAGACUGUCAUAGUCUCC		6
18752	MI0004682	mmu-mir-698	Mus musculus miR-698 stem-loop	UCAUCUCUGCCCUCACUGUAAGGGAGGGUGGUGGCUAUGUGGGUGGGACAGGGAUGUUCAGUUGCUAAAGACAUUCUCGUUUCCUUCCCUCAGUGUCCCCAGAUGGUGA		6
18753	MI0004683	mmu-mir-699	Mus musculus miR-699 stem-loop	CGUGCAGCGGGGCGUCAUCCGUCAGCUCACAUAGUGACGCAGGCAGUGCGACCUGGCUCGCAC		6
18754	MI0004684	mmu-mir-700	Mus musculus miR-700 stem-loop	UUCACUGGGAGUAAGGCUCCUUCCUGUGCUUGCAGGGGAGAAAUACGAACUGCACGCGGGAACCGAGUCCACCCCCAGU		6
18755	MI0004685	mmu-mir-701	Mus musculus miR-701 stem-loop	GUGGAGCAUCUACCUUGAGCAAGUAAUUAGCCGCUGAAAUAGAUGGAUUGUAUAGAUGAGGUUCUAUCUAUUAAAGAGGCUAGCCACUUAUCAAGUGCUAACAGCCCAC		6
18756	MI0004686	mmu-mir-702	Mus musculus miR-702 stem-loop	CGGGACAAGGUGAGUGGGGUGGUUGGCAUGGGUUGCCCAUGGGGACUCGACGCUGUGCCCACAGCCUCCUGAUGUCCUCCUCACGCAUGCCCACCCUUUACCCCGCUCC		6
18757	MI0004687	mmu-mir-703	Mus musculus miR-703 stem-loop	AGACUGGUUAAUGAUAACAAUGCAUCAUAAAACCUUCAGAAGGAAAGAAUGUUGUGGACCAUUUUUUUUUGUGUGUGGCAGUUUUAAGUUAUUAGUUUUCAAAAUCAGU		6
18758	MI0004688	mmu-mir-704	Mus musculus miR-704 stem-loop	GCUGGGAGCUAGAGGAUGUGGUCAGCUGCAAGGAUCUUCCUCAGACAUGUGCUCUGCUCCUAGGGAUUGUUGACUAC		6
18759	MI0004689	mmu-mir-705	Mus musculus miR-705 stem-loop	AUGUCCCAGUAGUGGUGGGAGGUGGGGUGGGCACAGAGGGAAUGACUUCUUUCUCCUGCAGUCCUCCCUACCUCCCUAACAU		6
18760	MI0004690	mmu-mir-706	Mus musculus miR-706 stem-loop	AGAGAAACCCUGUCUCAAAAAACAAAAAAACAAACAAAAUUACUUUUAGUAGGUUUAUUUUGUUUUUUGAGAUGGCUUUUUUUU		6
18761	MI0004691	mmu-mir-707	Mus musculus miR-707 stem-loop	GGCAUGCAGUCAUGCCGCUUGCCUACGCUUGUGUGAGCAUGGGCAUGCGGUCAUAGUUGUUGCGGGCAAUUCG		6
18762	MI0004692	mmu-mir-708	Mus musculus miR-708 stem-loop	CUGUGUUUGAAAUGGGGACUGCCCUCAAGGAGCUUACAAUCUAGCUGGGGGUAGAUGACUUGCACUUGAACACAACUAGACUGUGAGCUUCUAGAGGGCAGGGGCCUUA	Mineno et al. and Takada et al. identified a mature miRNA from the 3' arm of this hairpin, and named it miR-708 [1,2].  Landgraf et al. later showed that the 5' product was the predominant one [3].  The 3' miRNA is renamed miR-708* here. 	6
18763	MI0004693	mmu-mir-709	Mus musculus miR-709 stem-loop	UGUCCCGUUUCUCUGCUUCUACUCAGAAGUGCUCUGAGCAUAGAACUGUCCUGUUUGAGCAGCACUGGGGAGGCAGAGGCAGGAGGAU		6
18764	MI0004694	mmu-mir-710	Mus musculus miR-710 stem-loop	CUCUCUCGUCAAAUAGAAGCCAAGUCUUGGGGAGAGUUGAGCUUGGUGUGAAAACUGACAUACCCCUUCAACUCUUUAGAACUUAGGUAUCUGAAGUGGAGUGGAUGGAG		6
18765	MI0004695	mmu-mir-711	Mus musculus miR-711 stem-loop	CAUGUUCCUAACUUUGAAUCUCUUCUUAGGGUGCUUCAGGCAAAGCUGGGGACCCGGGGAGAGAUGUAAGUCUGGGGAGAUG		6
18766	MI0004696	mmu-mir-712	Mus musculus miR-712 stem-loop	UCUCCGCUUCUCCUUCACCCGGGCGGUACCCGCUCCGGCGCCGGCCCGCGGGACGCCGCGGCGUCCGUGCGCCGAUGCGAGUCACCCCCGGGUGUUGCGAGUUCGGGGA	mir-712a and mir-712b sequences [1] map to the same genomic locus in mouse genome assembly NCBI36.  The reported miR-712b mature sequence is two bases longer at the 3' end (UCCUUCACCCGGGCGGUACCCG) than that shown here. 	6
18767	MI0004698	mmu-mir-713	Mus musculus miR-713 stem-loop	GGCCUAUCCGGAGGCCCUGAUUGGUUAGUGAGACUUGAUUGACAUGAGCACCUCCCUUAGGGUUAGAGUGCACUGAAGGCACACAGCAUAGGGCUUCCAAGAUCGGGU		6
18768	MI0004699	mmu-mir-714	Mus musculus miR-714 stem-loop	CGACGAGGGCCGGUCGGUCGCCCUGCGGUGGUUGUCUGUGUGUGUUUGGGUCUUGCGCUGGGGGAGGCGGGGUCGACCGCUCGCGGGGUUGGCGCGGUCGCCCGGCGCCG		6
18769	MI0004700	mmu-mir-715	Mus musculus miR-715 stem-loop	GGCUGGGGAGAGGGCUCCGUGCACACCCCCGCGUGCGCGGUACUUUCCUCCCCUCCUGAGGGCCGCCGUGCGGGACGGGGUGUGGGUAGGCAACGGUGGGCUCCCGGGUC		6
18770	MI0004702	mmu-mir-500	Mus musculus miR-500 stem-loop	CUCCUCUGCUCCCCCUCUCUAAUCCUUGCUAUCUGGGUGCUUAGUGCUAUCUCAAUGCAAUGCACCUGGGCAAGGGUUCAGAGAAGGUGAGC	Mouse miR-500 was identified independently by two groups.  Wheeler et al cloned a mature product with the same length as the human ortholog (MIR:MI0003184) [1].  Mineno et al report a shorter mature product with 1 additional base at the 5' end and 3 fewer at the 3' end (AAUGCACCUGGGCAAGGGUU), referred to as miR-500b in [2].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
18771	MI0004703	mmu-mir-501	Mus musculus miR-501 stem-loop	CUUCUGCUCUGCUCAUCCUCUCUAAUCCUUUGUCCCUGGGUGAAAAUGCUAUUUGUAUGCAAUGCACCCGGGCAAGGAUUUGGGGAAGGUGAGCCUGAUCUGCAUGGAG		6
18772	MI0004704	mmu-mir-717	Mus musculus miR-717 stem-loop	UUGUCCGCUAUCACUGUACCGUCAUUUUUCAGUCUCAGACAGAGAUACCUUCUCUGAAUUCAUAGAAGCUGCUCUCCGUUCCGAAGGGAUUCAGAAGUGAUAAAUCCAG		6
18773	MI0004705	mmu-mir-450b	Mus musculus miR-450b stem-loop	GAUACAGAAUUAUUUUUGCAGUAUGUUCCUGAAUACAUAACAUAAGCGUAUUGGGAACAUUUUGCAUGCAUAAUUUUGUAUC		6
18774	MI0004706	mmu-mir-505	Mus musculus miR-505 stem-loop	AAAUUGAUGCACCCAGUGGGGGAGCCAGGAAGUAUUGAUGUUUCUGCCAGGUUAGCGUCAACACUUGCUGGUUUUCUCUCUGGAGUAUCA		6
18775	MI0004707	mmu-mir-718	Mus musculus miR-718 stem-loop	ACGCCCCCGUGUGGCGGAAGGCCGCGGAGGGCAAGAUGGCGGCGGGUCGAGCGCCGCCUCUUCCGCCCGGCCGGGUGUCGCACGAGGC		6
18776	MI0004708	mmu-mir-721	Mus musculus miR-721 stem-loop	GGAAGACAGUGCAAUUAAAAGGGGGAAAAAAGUACCUGGGAUGUUCUGAGAAUUUCAUUUUUCUUGUUAUUGCCACUCCUGCUUGGAA		6
18777	MI0004710	ppt-MIR1211	Physcomitrella patens miR1211 stem-loop	UUACAUGAUUGUCAACAGGGAGGGAUGGUUAUGCAAGAGGGUGCAAGAGGUGGCAGAUCAUCUCUUGAAGCAUCUUGCAUGACCGUCUCUUCCUGCAGGUAGAGUUAUGUAA	Talmor-Neiman et al. identified a mature miRNA from the 5' arm of this precursor, and called it miR1211 [1].  Axtell et al. show by deep sequencing that the 3' product is the predominant one [3].  The 5' miRNA is renamed miR1211* here. 	40
18778	MI0004711	ppt-MIR1212	Physcomitrella patens miR1212 stem-loop	GUAUGAGGAGUUGCAUCCUCUGCUGUGCCCACAUGCGUCGUGGCGCGUGGCGGCCGCGCGUGGGACAGCAUAGAAUGCGGAUCCUUGUA		40
18779	MI0004713	ppt-MIR1214	Physcomitrella patens miR1214 stem-loop	UGUGGUUGGGUUUUCUACUAUGAGAAUCUCGCGGCCAAGGUGGUUUUGGACGACCAUUUCUGCGAUUUUCUCAUAGCAGAUGAACUAGCCCCA		40
18780	MI0004714	ppt-MIR1215	Physcomitrella patens miR1215 stem-loop	CGUGAAGGUACUGGAGCUCAUUGCAAAACUGUAUACGAUCCUUUCAACUUGAACAGCAUUCGAAAGCUUGUGGCUAUUGCUCAGAGGAUGGUAUACAGUUUCGCUGUGGAACUCCAGUCCCUACAUG		40
18781	MI0004715	ppt-MIR1216	Physcomitrella patens miR1216 stem-loop	GCGAGGUUGGUUUUGUAUGUCCAGUGUCUGUCAAUGUCGUUGAUGGUGAUGCGCUUGUAUCUCGAAAGGACCAUUCGUGAGGGAAUGGUGUCGUCGUGUUACAAGCCCAUCACCCUCAACGACAUGACCCGCCUGUUUCAUACUCCACCAAACCUCGC		40
18782	MI0004716	ppt-MIR1217	Physcomitrella patens miR1217 stem-loop	UCCUGUUUCUGGUUGAUCUUGGUAUCAUGUUGCAAAUGGCAAAACCUGUGACCGGAAUGGUACUCAGUUUUUGAAAUUUGAAGCAUGAUGUCAAGUACAACGGAAGUUGGA		40
18783	MI0004717	ppt-MIR1218	Physcomitrella patens miR1218 stem-loop	CAGUGAUUACAUGUGUCGUGGUAGGCAUCCUUAGAGUCGUAGGCCUCUGUGUGGAAUUCAAGAUAGUUCACAGUCGUUUUGAACACACAUCACAGGAGCCUACGACUCUGAAGAUACCUAUCUCGGGACAAAUUUCUG		40
18784	MI0004718	ppt-MIR1219a	Physcomitrella patens miR1219a stem-loop	UGAAGUGUGGACGAUGGAGAGUCAGCCUCUUCCUGCCUCUCACUAGCUUCAUCCCUUCCUCCCUAAAUUUUAGUCUGGGAGGGAAGGAGCUAUUGGUGGUCAGGAAUAGCGCACCCUUCAUUUAUCCACACUUCA		40
18785	MI0004719	ppt-MIR1219b	Physcomitrella patens miR1219b stem-loop	CUCUUCCUGCCUCUCACUAGCUUCAUCCCUUCGAACCCGAAGGUACUAAGGUAAGGAACUAUUGGGAAGCAGGAACAG		40
18786	MI0004720	ppt-MIR1219c	Physcomitrella patens miR1219c stem-loop	GGCCUCUUCCUGCCUCUCACUAGCUUCAUCCCUCAGAAGCUGAAUCUUCUCAGGGAAGGAGCUACUGAAGAGCAGGAAUAGAUUGCACUCUUGGACUCCAACCAAUCUGUCUUCCAUUAUUUGUGUACUCAAAUUCUUCUGUUGUAGUGGCC		40
18787	MI0004721	ppt-MIR1219d	Physcomitrella patens miR1219d stem-loop	AGAGGCGUGUGCGGAGCACCGUGAGUCUUUUCCUGCCUCUCACUAGCUUCUUCCCUCCCUGCCUGAGUCGCAGUCUGGGAGGUAAGGAGCUAUUGGUAGACAGGAAUAGCGCGCACGUAGUCCCACGCAUGUUUCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
18788	MI0004722	ppt-MIR1220a	Physcomitrella patens miR1220a stem-loop	ACUUCUUGCACUCCUCUAUCUCCCUCGGCACCUGCACAGUGAUUUUCUCAAUAUCUUCACGUUGGUGGCCACGUUCGAACAUAUCCCAUGCGGGCAACUCCGGCGUAGGUGUACACGGCCAGCGUUGCUUACCAUCUGGAGGAUACCCUUGCUCAAACCUACGACUCUGUUCCGGUGGUGAGGAAGAUAGAGGAGUUCAAGAAGU	The mature miRNA shown here is the predominant clone by deep sequencing [2].  Talmor-Neiman et al. identify an offset product by Northern blot [1]. 	40
18789	MI0004723	ppt-MIR1220b	Physcomitrella patens miR1220b stem-loop	ACUUCUCGGACUCCUCUAUCUCCCUCGGCACCUGCACAGUCAUUUUAUCAAUAUCUUCACGUUGGUGGCCACGUUCGAACAUAUCCCAUGCGGGCAACUCCGGCGUAGGUGUACAAGGCCAGCGUUGCUUACCAUCUGGAGGAUACCCCUGCUCAAACCUACGACUCUGUUCCGGUGGUGAGGAAGAUAGAGGAGUUCAAGAAGU	The mature miRNA shown here is the predominant clone by deep sequencing [2].  Talmor-Neiman et al. identify an offset product by Northern blot [1]. 	40
18790	MI0004724	ppt-MIR533b	Physcomitrella patens miR533b stem-loop	GGAGGACCGAUAUGGAGAGCUGUCCAGGCUGUGAGGGGAGCACUCGUAUUCUUUUGACCUUUGCUAGAAGAGGGAAUACAGCGCUCUCCCUCACAGUCUGUACAGCUCUCUGUAUCUCUUCCUCU	Axtell et al. show that mature products from both arms are significantly expressed [3], named here miR533b-5p and miR533b-3p. 	40
18791	MI0004725	ppt-MIR535d	Physcomitrella patens miR535d stem-loop	GGUGACAACGAGAGAGAGCACGCCGGAAUGCGUUCAUGCAGCGAGUGCCUGGAGGUGUUCGAGCGUGCCCUCUCCCGUCGUCACC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	40
18792	MI0004726	ppt-MIR1221	Physcomitrella patens miR1221 stem-loop	AACUGAUGGAGAAACUGCCGUGGAUGGUGUGCAGGGUCAAAUACUCUUUUGGCUUUCGAUGUGUGUUUUCCGCUGGCGGCGGUUUGUGUCGAAGUGGUGACCUUAGUGGGUUGGACACAUAUGAAUCAGGAGCAUUUGGCCCAUGCACAGUAUCUACGCAAGUUCCUCGGUCUGGUU		40
18793	MI0004727	ppt-MIR1222a	Physcomitrella patens miR1222a stem-loop	CACGACAUAGCUGGUUGUUGUGGGCAUUCUUGUGCUAGUAAACUCCUUCAUGCAGAAGUGCGCUUCUAGCACCUGCUUGAAGGAGUUCAUUGGUAUAUAAAUGCCCACAACAUGAUGACCGAUUAACGUG		40
18794	MI0004728	ppt-MIR1223a	Physcomitrella patens miR1223a stem-loop	AGACUAGAGGGUCAGCAAGGGUGUGUGACUCUAUAAUCCAAGCUGUGCUAGUAGAUCGCUUAAGAUCGAAGUGCACACCAAGCAUUCGAUUGUAGAGUCAUACACCUCCACUGACACUUCUAGUCU		40
18795	MI0004729	ppt-MIR390c	Physcomitrella patens miR390c stem-loop	GGUAUAAUUACAGAGCUCAGGAGGGAUAGCGCCCAUCUCAGUCUUUUUUAGCAUCCAAUUGAAAUGGUUAACAUUCCUUUGGAUAGCUAGACGGCGAAGCAUGGCGCUGUCCAUUCUGAGCAUUGCAUUUGUACC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The ends of the miRNA may be offset with respect to previous annotations. 	40
18796	MI0004730	hsv1-mir-H1	Herpes Simplex Virus 1 miR-H1 stem-loop	CGAGGGGAACGGGGGAUGGAAGGACGGGAAGUGGAAGUCCUGAUACCCAUCCUACACCCCCCUGCCUUCCACCCUCCGGCCCCCCG		45
18797	MI0004731	bta-mir-26a	Bos taurus miR-26a stem-loop	GGCUGUGGCUGGAUUCAAGUAAUCCAGGAUAGGCUGUUUCCAUCUGUGAGGCCUAUUCUUGAUUACUUGUUUCUGGAGGCAGCU		44
18798	MI0004732	bta-mir-18b	Bos taurus miR-18b stem-loop	CUUGUGUUAAGGUGCAUCUAGUGCAGUUAGUGAAGCAGCUCAGAAUCUACUGCCCUAAAUGCUCCUUCUGGCACA		44
18799	MI0004733	bta-mir-29a	Bos taurus miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUAU		44
18800	MI0004734	bta-let-7f-2	Bos taurus let-7f-2 stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		44
18801	MI0004735	bta-mir-101	Bos taurus miR-101 stem-loop	ACUGUCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAUAUCUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGU		44
18802	MI0004736	bta-mir-103-1	Bos taurus miR-103-1 stem-loop	CUGCCCUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGC		44
18803	MI0004737	bta-mir-148a	Bos taurus miR-148a stem-loop	GAGGCAAAGUUCUGAGACACUCCGACUCUGAAUAUGAUAGAAGUCAGUGCACUACAGAACUUUGUCUC		44
18804	MI0004738	bta-mir-151	Bos taurus miR-151 stem-loop	CCUGCCCUCGAGGAGCUCACAGUCUAGUACGUCUCAUCCCCUACUAGACUGAAGCUCCUUGAGGACAGG		44
18805	MI0004739	bta-mir-16	Bos taurus miR-16 stem-loop	CAUACUUGUUCCGCUGUAGCAGCACGUAAAUAUUGGCGUAGUAAAAUAAAUAUUAAACACCAAUAUUAUUGUGCUGCUUUAGCGUGACAGGGA		44
18806	MI0004740	bta-mir-18a	Bos taurus miR-18a stem-loop	UGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA		44
18807	MI0004741	bta-mir-20a	Bos taurus miR-20a stem-loop	GUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUAAAGUACUGC		44
18808	MI0004742	bta-mir-21	Bos taurus miR-21 stem-loop	UGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUCUGACA		44
18809	MI0004743	bta-mir-221	Bos taurus miR-221 stem-loop	CCAACAUCCAGGUCUAGGGCAUGAACCUGGCAUACAAUGUAGAUUUCUGUGUUUGUUGAGCAACAGCUACAUUGUCUGCUGGGUUUCAGGCUACCUGGAAACACGUUCUU		44
18810	MI0004744	bta-mir-222	Bos taurus miR-222 stem-loop	GCUGCUGGAAUGUGUAGGUACCCUCAAUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUUGUAAUCAGUAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCUUCUACCU		44
18811	MI0004745	bta-mir-26b	Bos taurus miR-26b stem-loop	UGCCCGGGACCCAGUUCAAGUAAUUCAGGAUAGGUUGUGUGCUGUCCAGCCUGUUCUCCAUUACUUGGCUCGGGGGCCGGUGCCC		44
18812	MI0004746	bta-mir-27a	Bos taurus miR-27a stem-loop	UGGCCUGGGGAGCAGGGCUUAGCUGCUUGUGAGCAGGUCCACAUCAAAUCGUGUUCACAGUGGCUAAGUUCCGCCCCC		44
18813	MI0004747	bta-mir-30d	Bos taurus miR-30d stem-loop	GUUGUUGUAAACAUCCCCGACUGGAAGCUGUACCACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC		44
18814	MI0004748	bta-mir-320	Bos taurus miR-320 stem-loop	AAAAACGAAAAAGAGGCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGAAAAAGGAAGAGGG		44
18815	MI0004749	bta-mir-484	Bos taurus miR-484 stem-loop	GUCAGGCUCAGUCCCCUCCCGAUAAACCUCUAAAUAGGGACCUUCCCGGGGGGCUACCUCGGC		44
18816	MI0004750	bta-mir-499	Bos taurus miR-499 stem-loop	GGGCGGGCGGCCGUUAAGACUUGCAGUGAUGUUUAACUCCUCUCCACGUGAACAUCACAGCAAGUCUGUGCUGCUUCCCGUCCCCACGCUGCCUGGGCAGGGU		44
18817	MI0004751	bta-mir-99a	Bos taurus miR-99a stem-loop	CCCAUUGGCAUAAACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACCGCACAAGCUCGCUUCUAUGGGUCUGUGUCAGUGUG		44
18818	MI0004752	bta-mir-125a	Bos taurus miR-125a stem-loop	UGCCGGCCUCUGCGUCCCUGAGACCCUUUAACCUGUGAGGACGUCCAGGGUCACAGGUGAGGUUCUUGGGAGCCUGGCGUCCGGCC		44
18819	MI0004753	bta-mir-125b-1	Bos taurus miR-125b-1 stem-loop	CGCGCGCCUCUCAAUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGCUGCGAGUCGCGCC		44
18820	MI0004754	bta-mir-126	Bos taurus miR-126 stem-loop	UGACGGGACAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGCUGUCA		44
18821	MI0004755	bta-mir-128	Bos taurus miR-128 stem-loop	UGAGCUGUUGGAUUCGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUUUUCAGCUGCUUC		44
18822	MI0004756	bta-mir-145	Bos taurus miR-145 stem-loop	CACCUUGUCCUCACGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAGGUCAUGGUU		44
18823	MI0004757	bta-mir-181a	Bos taurus mir-181a stem-loop	UGCCAGGGCCAGGACCCAGUCUUCAGAGGACUCCAAGGAACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACCGACCGUUGACUGUACCUUGGGUUCCUUA		44
18824	MI0004758	bta-mir-199a	Bos taurus miR-199a stem-loop	UGGAAGCUUCUGGAGAUCCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAAGGG		44
18825	MI0004759	bta-mir-205	Bos taurus miR-205 stem-loop	CUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCGUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAG		44
18826	MI0004760	bta-mir-27b	Bos taurus miR-27b stem-loop	ACCUCUCUGACGAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGACUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGUG		44
18827	MI0004761	bta-mir-30b	Bos taurus miR-30b stem-loop	CCAAGUUUUCAGUUCAUGUAAACAUCCUACACUCAGCUGUAACACACGAGUCGGCUGGGAGGUGGAUGUUUACUUCAGCUGACUUGGA		44
18828	MI0004762	bta-mir-31	Bos taurus miR-31 stem-loop	UCCUGUAACUUGGAACUGGAGAGGAGGCAAGAUGCUGGCAUAGCUGUUGAACUGCGAACCUGCUAUGCCAACAUAUUGCCAUCUCUCUUGUCCG		44
18829	MI0004763	bta-mir-34b	Bos taurus miR-34b stem-loop	GUGCUCGGUUUGUAGGCAGUGUAAUUAGCUGAUUGUACUCUCAUGCUUACAAUCACUAGUUCCACUGCCAUCAAAACAAGGCAC		44
18830	MI0004764	dre-mir-190b	Danio rerio miR-190b stem-loop	UGUUACAGACUAUGUGAUAUGUUUGAUAUUCGGUUGCUUUCUUUAUAUCAUGUCAACUAAAUAUCAGACAUAUUCCUAUAGACUGUGACA		12
18831	MI0004765	dre-mir-722	Danio rerio miR-722 stem-loop	GGAACGGAGUGGAAUUUGAAACGUUUUGGCCAAAAAUGUAGCCAUGGCAAAGGGGUUUUUUGCAGAAACGUUUCAGAUUUCGCUCCGUUCU		12
18832	MI0004766	dre-mir-499	Danio rerio miR-499 stem-loop	ACUGAGAGGGAGGCAGUUAAGACUUGCAGUGAUGUUUAGAGAAAUGUCACAUGAACAUCACUUUAAGUCUGUGCUGGCUCCUGUUCUGAGU		12
18833	MI0004767	dre-mir-723	Danio rerio miR-723 stem-loop	UGCGUAGAGAUAAAGACAGUUUUAAAUGAUGUUACUUUUUUUCAAAUGGAGAAAGACAUCAAUUAAAUCUGUGCUUAUCUCUACAAGCA		12
18834	MI0004768	dre-mir-724	Danio rerio miR-724 stem-loop	CAGCAGACUGGAUUUAAAGGGAAUUUGCGACUGUUAGUCAGAUUUGUAGAACAGCCACACCUUCCUUUUAAGAUCUUGCCUGCUG		12
18835	MI0004769	dre-mir-725	Danio rerio miR-725 stem-loop	CUGCAGUGCACAUUGCUAGGAAUGGUGGCUGAGAUGAAGAGCAGGAUUUCAGUCAUUGUUUCUAGUAGUGCGCGCUGCAG		12
18836	MI0004770	dre-mir-726	Danio rerio miR-726 stem-loop	UCAGUCGUAUGCCUGGAAUUCCGCUAGUUCUGAACUAUUCGUGAUUGGCAAAAGUUCACUACUAGCAGAACUCGGAUAUACAACUGA		12
18837	MI0004771	dre-mir-727	Danio rerio miR-727 stem-loop	CUGUAUGUCAUUUUCAGUCUUCAAUUCCUCCCAGCCCGUACCCAUCGAAACUGUGAGUUGAGGCGAGUUGAAGACUUAAAGUGCUGUACAG		12
18838	MI0004772	dre-mir-728	Danio rerio miR-728 stem-loop	CAUCUUCUGAGGAAAUGUAGUAGACUAUAAGUAUACAGUAAACAUGAACGUAUACUAAGUACACUACGUUUUCUCAAGAGGUG		12
18839	MI0004773	dre-mir-729	Danio rerio miR-729 stem-loop	CGUCAAGGGCCAUCCAGUGACCCGGGGUUGUAUUGUAACCAAGCUGUAAGUGUCCAUGAUGCAUGGGUAUGAUACGACCUGGGUUACAGAAUGGUGAUG		12
18840	MI0004774	dre-mir-34c	Danio rerio miR-34c stem-loop	UGCUGUGUGGUCACCAGGCAGUGCAGUUAGUUGAUUACAAUCCAUAAAGUAAUCACUAACCUCACUACCAGGUGAAGGCUAGUA		12
18841	MI0004775	dre-mir-730	Danio rerio miR-730 stem-loop	GGGUUCUCCGGUCUCCUCAUUGUGCAUGCUGUGUGUCUUCAGUCUGGUCCUCACAGCGCCUGCAAUGUGGAGGCUAGGGGACUC		12
18842	MI0004776	dre-mir-731	Danio rerio miR-731 stem-loop	UGAUGCUGAUCUGGAAUGACACGUUUUCUCCCGGAUCGCCAGAAAUAUGUUUCGCCACCGGGAACUUCGUGUCAGCCAAGAUUGGCAUCA		12
18843	MI0004777	dre-mir-732	Danio rerio miR-732 stem-loop	AGAUAAAGUUCCACCGAGGGUUAAAUGUUUUGGUAUUUUAAUAGUGUCAAUCUCAAAGCAGAGAACUCUCGGUGGAGAUGUAUUU		12
18844	MI0004778	dre-mir-733	Danio rerio miR-733 stem-loop	UGGCUUUUCCGUAGUGUCGCUGUUGCGUUGGUUUAGCUCAGUGGUUACUUCUGUGAUCCCUGAAAAAUCAACCUUUCAUGGUCACCUCGGUGCCA		12
18845	MI0004779	dre-mir-15c	Danio rerio miR-15c stem-loop	CCUUAGACCGCUAAAGCAGCGCGUCAUGGUUUUCAACAUUAGAGAAGGUGCAAGCCAUCAUUUGCUGCUCUAGAGUUUUAAGG		12
18846	MI0004780	dre-mir-734	Danio rerio miR-734 stem-loop	UGAUAUUGAGAGCUGAACCAUUCUGCAGCAUGGCUGCCUGUGGAUCCUCUGGGGAAAGGUAAAUGCUGCAGAAUCGUACCGUUCUUGGUAUCA		12
18847	MI0004781	dre-mir-735	Danio rerio miR-735 stem-loop	GGCUGGUCCGAAGGCGGUGGGUUAGUCUUCUCUCCCCUCUCCCACCGCUAAACUUGACCAGUC		12
18848	MI0004782	dre-mir-736	Danio rerio miR-736 stem-loop	UCUACUGACAGAGAAGCUUUUUGUUUGUGUUAUGUUUAUUUUCAAAUGUAAGACGAACAAAAAGUUUUUCUGUUAGUAGG		12
18849	MI0004783	dre-mir-737	Danio rerio miR-737 stem-loop	CCACAGCUGCUGUGCUGUUGUUUUUUUAGGUUUUGAUUUUUGUGAAAUGUCGAUGAGAAAAUCAAAACCUAAAGAAAAUACUGCGCAGAUAGAUGG		12
18850	MI0004784	dre-mir-738	Danio rerio miR-738 stem-loop	GCUACGGCCCGCGUCGGGACCUCUCGUCUAGCGGCUUCUCCCCUCGGGGGAGGGGGUAGGUCGCGGGGCGAGUGUCCUCCCCGGCGCGGUGCCUCGGC		12
18851	MI0004785	dre-mir-739	Danio rerio miR-739 stem-loop	CGGGUGGAGCCGCCGCGGGCGCAGAUCUUGGUGGUAGUAGCAAAUAUUCAAACGAGAGCUUUGAAGGCCGAAGUGGAGAAGGGUUCCAUGUG		12
18852	MI0004786	dre-mir-740	Danio rerio miR-740 stem-loop	GCAUUUGUGUGCAUAAAAAGUGGUAUGGUACAGUUUGCUUUUAGGUACUUUUUGACAGUGGAAUCAGCCAUAAAAGCGUACUGUACCGUACCAUACCGUAUGGUACCAGGGGC		12
18853	MI0004787	xtr-let-7b	Xenopus tropicalis let-7b stem-loop	CUGGCUGAGGUAGUAGUUUGUGUAGUUAGGGGGCAGUGGUGUUUGCCCAUGGAGAUAACUAGACAAACUACUGCCUUGCCAG		43
18854	MI0004788	xtr-mir-1a-2	Xenopus tropicalis miR-1a-2 stem-loop	UGGGAGACAUACUUCUUUAUAUGUCCAUAUGGAAGUGCCAAUGCUAUGGAAUGUAAAGAAGUAUGUAUCUC		43
18855	MI0004789	xtr-mir-1a-1	Xenopus tropicalis miR-1a-1 stem-loop	ACCUGUUUGGAGUACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUAUCAGG		43
18856	MI0004790	xtr-mir-7-1	Xenopus tropicalis miR-7-1 stem-loop	UGGAUGUUGGUUUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACAACAUUGACAACAAAUCGCAGUCUGCCAUAUGGCACAGACCAUGCCUCUACA		43
18857	MI0004791	xtr-mir-7-3	Xenopus tropicalis miR-7-3 stem-loop	CUGGGUCGGUUUGGAAGACUAGUGAUUUUGUUGUUUUUAUAAAAGUUUGUCACAAACAGCAAAUCGUAGUCUCCACUCUGCCCCAGGA		43
18858	MI0004792	xtr-mir-7-2	Xenopus tropicalis miR-7-2 stem-loop	GAGGUGCAGGCUGACUCUUUGUGGAAGACUAGUGAUUUUGUUGUUGUAAGCCUUAUUGCAUGACAACAAGUCACAGUCUGCCUCACAGUGCCCAGCAAUAUCA		43
18859	MI0004793	xtr-mir-9a-1	Xenopus tropicalis miR-9a-1 stem-loop	GGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUUGUCAAUCCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA		43
18860	MI0004794	xtr-mir-9a-2	Xenopus tropicalis miR-9a-2 stem-loop	GGAAGUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUUUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUC		43
18861	MI0004795	xtr-mir-9b	Xenopus tropicalis miR-9b stem-loop	GUUUCUGUCUUUGGUUACCUAGCUGUAUGAGUAUAACUAAUGUCAUAAAGCUAGACAACCGAACGUAUAAACCA		43
18862	MI0004796	xtr-mir-10a	Xenopus tropicalis miR-10a stem-loop	GAUUUGCCUGUCCUCUGUAUGUACCCUGUAGAUCCGAAUUUGUGUGAGCGCAAUCAUAUCACAAAUUCGUGUCUGGGGGGAUAUGCAGUUGACACAAACG		43
18863	MI0004797	xtr-mir-10b	Xenopus tropicalis miR-10b stem-loop	AACGUUGUCUAUAUGUACCCUGUAGAACCGAAUUUGUGUGGUUCGUACAGUCACAGAUUCGAUUCUAGGGGGAUAUAUGGUCGAUGCA		43
18864	MI0004798	xtr-mir-10c	Xenopus tropicalis miR-10c stem-loop	UAUAUGCACCCUGUAGAAUCGAAUUUGUGUGAGUUCUGAACCACAGAUUCGUCUCUAGGGGGGUAUAUGGG		43
18865	MI0004799	xtr-mir-15a	Xenopus tropicalis miR-15a stem-loop	CCUUGACGUAAAGUAGCAGCACAUAAUGGUUUGUGGGUUACACAGAGGUGCAGGCCAUACUGUGCUGCCGCCAAAACACAAGG		43
18866	MI0004800	xtr-mir-15b	Xenopus tropicalis miR-15b stem-loop	UGUCCUAAAGAAGUGUAGCAGCACAUCAUGAUUUGCAUGCUGUAUUAUAGAUUCUAAUCAUUUUUUGCUGCUUCAUGAUAUUGGGAAA		43
18867	MI0004801	xtr-mir-16c	Xenopus tropicalis miR-16c stem-loop	UUUAGCAGCACGUAAAUACUGGAGUUCAUGACCAUAUCUGCACUCUCCAGUAUUACUUUGCUGCUAUAUU		43
18868	MI0004802	xtr-mir-16a	Xenopus tropicalis miR-16a stem-loop	GCCAGCAGUCCUUUAGCAGCACGUAAAUAUUGGUGUUAAAAUGGUCCCAAUAUUAACUGUGCUGCUAGAGUAAGGUUGGCCU		43
18869	MI0004803	xtr-mir-17	Xenopus tropicalis miR-17 stem-loop	GUCAAGAGUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUUUAACAGAACCUACUGCAGUGAAGGCACUUGUAGCAUUAUAUUGAC		43
18870	MI0004804	xtr-mir-19a	Xenopus tropicalis miR-19a stem-loop	GCAGUCUUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAAAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGCAGCCUG		43
18871	MI0004805	xtr-mir-19b-2	Xenopus tropicalis miR-19b-2 stem-loop	UUCAUGGUUAGUUUUGCAGGUUUGCAUCCAGUUGUUCUUCUGGCUCACUGUGCAAAUCCAUGCAAAACUGAUUAUGGCA		43
18872	MI0004806	xtr-mir-23a-2	Xenopus tropicalis miR-23a-2 stem-loop	CUGUGGCUGGUAGGAUUCCUGGCAGAGUGAUUUGGAAAUGUAUGGUACAAAAUCACAUUGCCAGGGAUUUCCAAUCAGUCCCG		43
18873	MI0004807	xtr-mir-26-1	Xenopus tropicalis miR-26-1 stem-loop	GGCUGCUGCCUGGUUCAAGUAAUCCAGGAUAGGCUGUUUCCUCAAAGCACGGCCUACUCUUGAUUACUUGUUUCAGGAAGUAGCU		43
18874	MI0004808	xtr-mir-26-2	Xenopus tropicalis miR-26-2 stem-loop	UGGGCGCUCGCUUCAAGUAAUCCAGGAUAGGCUGUAAUGUCUCCUGUCAGCCUUUUCUCGAUUACUUGGGACCAGAGCCA		43
18875	MI0004809	xtr-mir-27a	Xenopus tropicalis miR-27a stem-loop	CGGCGGCCCAGGGCUUAGCUGUAUUGUGAGCACUGUCACUCUCGCACCUGUUCACAGUGGCUAAGUUCCGCGCCUC		43
18876	MI0004810	xtr-mir-27b	Xenopus tropicalis miR-27b stem-loop	ACCUUUCUACCAAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGAUUCCCUCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAGGGC		43
18877	MI0004811	xtr-mir-29d	Xenopus tropicalis miR-29d stem-loop	UCAGGAGGCUGGUUUCAUGUGGUGGUUUAGAUUUAACUGCACAAUGUCUAGCACCAUAUGAAAUCAGUGUCCUUA		43
18878	MI0004812	xtr-mir-29b	Xenopus tropicalis miR-29b stem-loop	UCCCGGAAGCUGGUUUCUUGUGGUGACUUAGAUUUAUCCAUCGCUGCAUCUAGCACCAUUUGAAAUCAGUGUUCUAGGAG		43
18879	MI0004813	xtr-mir-30a	Xenopus tropicalis miR-30a stem-loop	GCGACUGUAAACAUCCUCGACUGGAAGCUGUGAAGCAGUUGAAGGGCUUUCAGUCAGAUGUUUGCAGCUGC		43
18880	MI0004814	xtr-mir-30b	Xenopus tropicalis miR-30b stem-loop	GUAUUAGUCUAUGUAAACAUCCUACACUCAGCUCGUAUGUAUAACCUGACUGGGUGGGGGGUGUUUGCCUCGACUGAUCU		43
18881	MI0004815	xtr-mir-30c-1	Xenopus tropicalis miR-30c-1 stem-loop	ACCAUGCAGCAGUGAUUGUAAACAUCCUACACUCUCAGCUGUGAACAUAAGGUGGCUGGGAGAAGGGUGUUUACUCCCCCUGCCAUGGA		43
18882	MI0004816	xtr-mir-34a	Xenopus tropicalis miR-34a stem-loop	CUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGGCACGUUAUAGAAGUAGCAAUCAGCAAAUAUACUGCCCUAGAAGUUCUGCACAUU		43
18883	MI0004817	xtr-mir-34b-2	Xenopus tropicalis miR-34b-2 stem-loop	UUCAGGCAGUGUAGUUAGCUGAUUGUGUUAUAUCAAAUUUGCAAUCACUAGCUAAACUACCAUAAAA		43
18884	MI0004818	xtr-mir-34b-4	Xenopus tropicalis miR-34b-4 stem-loop	UUCAGGCAGUGUAGUUAGCUGAUUGUGUUAUAUCAAAUUUGCAAUCACUAGCUAAACUACCAUAAAA		43
18885	MI0004819	xtr-mir-92a-2	Xenopus tropicalis miR-92a-2 stem-loop	UCCUCUGUGGGUGGGGAUUUGUUGCACUACUGUAUGUAUGAAAAGUAUUGCACUUGUCCCGGCCUGUGGGUGA		43
18886	MI0004820	xtr-mir-98	Xenopus tropicalis miR-98 stem-loop	UCUGCCCUCUUCAGGAUGAGGUAGUAAGUUGUAUUGUUGUGGGGGUUUUUAUUUCCCCAAAUUAGGAGAUAACUAUACAGCUUACUGCCUUCCCUGCAGCAUGGUAAU		43
18887	MI0004821	xtr-mir-99	Xenopus tropicalis miR-99 stem-loop	UAACAUAAACCCGUAGAUCCGAUCUUGUGGUGAAUUCCUUUGCUCAAGCUCGUUUCUAUGGGUCUGUGUCA		43
18888	MI0004822	xtr-mir-106	Xenopus tropicalis miR-106 stem-loop	UGCAAAAGUGCUUAUAGUGCAGGUAGAAUUUAAACCUACUGCACCAUAAGCACUUCCUGCAUC		43
18889	MI0004823	xtr-mir-107	Xenopus tropicalis miR-107 stem-loop	CUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCA		43
18890	MI0004824	xtr-mir-122	Xenopus tropicalis miR-122 stem-loop	GAGCUAUGGAGUGUGACAAUGGUGUUUGUGUCAGAGCUAUCAAACGCCAUUAUCACACUAAUGAGCUAC		43
18891	MI0004825	xtr-mir-125b-1	Xenopus tropicalis miR-125b-1 stem-loop	UGCACCCCUCUCAAUCCCUGAGACCCUAACUUGUGAUGUUUAGCUUUAAAAAUCCACGGGUUAGGCUCUUGGGAGCUGUGAGUUGUGC		43
18892	MI0004826	xtr-mir-125b-2	Xenopus tropicalis miR-125b-2 stem-loop	GACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGAUUUUUUAGCAACAAUCACAAGUUAGGCUCUUGGGACCUAGGCGGAGGG		43
18893	MI0004827	xtr-mir-126	Xenopus tropicalis miR-126 stem-loop	GGCUGUGCAUUAUUACUUUUGGUACGCGCUGUGUCACAUCAAACUCGUACCGUGAGUAAUAAUGCGCAG		43
18894	MI0004828	xtr-mir-128-2	Xenopus tropicalis miR-128-2 stem-loop	GUGCAGCUGGAACGGGGGCCGUUACACUGUAAGAGAGUGAGUAGUAGGUCUCACAGUGAACCGGUCUCUUUUCUUACUGU		43
18895	MI0004829	xtr-mir-129-1	Xenopus tropicalis miR-129-1 stem-loop	GUCCUUCUCAAAUCUUUUUGCGGUCUGGGCUUGCUGUAUGUAAAUACCUAGCCGGGAAGCCCUUACCCCAAAAAGCAUUUGCGGAGGGCG		43
18896	MI0004830	xtr-mir-129-2	Xenopus tropicalis miR-129-2 stem-loop	UCUCAAAGCUUUUUGCGGUCUGGGCUUGCUGUUCUCAAUCAAAGUAUCCAGGAAGCCCUUAUCCCAAAAAGAAUUUGCGAGG		43
18897	MI0004831	xtr-mir-130a	Xenopus tropicalis miR-130a stem-loop	CUGUCCAGUGCCCUUUUUAUGUUGUACUACUAGUGGUCACACACAAAAAAAGCAGUGCAAUGUUAAAAGGGCAUUGGCCAGGG		43
18898	MI0004832	xtr-mir-130c	Xenopus tropicalis miR-130c stem-loop	AUCCGUGGCCCUUUUUCUGUUGUACUACUGGAAUUUGUAAUUAGCAGUGCAAUAUUAAAAGGGCAUUGGCU		43
18899	MI0004833	xtr-mir-130b	Xenopus tropicalis miR-130b stem-loop	CCGCCUGACACUCUUUCCCUGUUGCACUACUGUGGCAGUGAAUAAAGCAGUGCAAUGAUGAAAGGGCAUCAGUCUG		43
18900	MI0004834	xtr-mir-132	Xenopus tropicalis miR-132 stem-loop	CUGUCUCCAGGGCAACCGUGGCUUUAGAUUGUUACUGUAGUUCUGCAUUGGUAACAGUCUACAGCCAUGGUCGCUCGGGCAAGAUGC		43
18901	MI0004835	xtr-mir-133c	Xenopus tropicalis miR-133c stem-loop	AAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCAACUGUUGAAUGGAUUUGGUCCCCUUCAACCAGCUGCAGCUGUGCAUUGA		43
18902	MI0004836	xtr-mir-133d	Xenopus tropicalis miR-133d stem-loop	CUGGUUGCGGCUGGUGAAAAGGAACCACAUCAACCCAGAAAAAGGAUUUGGUCCCCUUCAACCAGCCGCAACUGGU		43
18903	MI0004837	xtr-mir-133b	Xenopus tropicalis miR-133b stem-loop	CUGCUAUGGCUGGUCAAACGGAACCAAGUCCGUCUUCCUUAGAGGUUUGGUCCCCUUCAACCAGCUAUUGCAGUA		43
18904	MI0004838	xtr-mir-135-1	Xenopus tropicalis miR-135-1 stem-loop	AGAUAAAUUCACUGUGGUGUUUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAUGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAAGUCA		43
18905	MI0004839	xtr-mir-138	Xenopus tropicalis miR-138 stem-loop	CGGUGCGGAGCAGCAGCUGGUGUUGUGAAUCAGGCCGUGACCACUCAGAAAACGGCUACUUCACAACACCAGGGUUGCUUCUCAC		43
18906	MI0004840	xtr-mir-139	Xenopus tropicalis miR-139 stem-loop	UGUAUUCUACAGUGCAUGUGUCUCCAGUCAUAUAGAGGCACUGGGGAUACAGCUCUGUUGGAAUAAC		43
18907	MI0004841	xtr-mir-140	Xenopus tropicalis miR-140 stem-loop	CCCUCUCUGUGUCCUCCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAGGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACGGGGAGCU		43
18908	MI0004842	xtr-mir-142-1	Xenopus tropicalis miR-142-1 stem-loop	CAGUGCAGCCACCCAUAAAGUAGAAAGCACUACUAGACAGGACUGAACGCUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGGG		43
18909	MI0004843	xtr-mir-142-2	Xenopus tropicalis miR-142-2 stem-loop	CAGUGCAGCCACCCAUAAAGUAGAAAGCACUACUAGACAGGACUGAACGCUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGGG		43
18910	MI0004844	xtr-mir-146	Xenopus tropicalis miR-146 stem-loop	CAAUGAGUUCUUAGCUUUGAGAACUGAAUUCCAUAGGUUGUUAGAGGUUAGACCUAUGGUGCUUAGUUCCAUAGCUUGGAUCCCACUGGC		43
18911	MI0004845	xtr-mir-148b	Xenopus tropicalis miR-148b stem-loop	UGAGGAACAGCGUUUGAGGUGAAGUUCUGUUAUACACUCCGGCUGUGAGUAAGUGGAAGUCAGUGCAUCACAGAACUUUGUCUCGAGGGCUUCACUA		43
18912	MI0004846	xtr-mir-150	Xenopus tropicalis miR-150 stem-loop	CUCUCUCCCAACCCUUGUACCAGAGUGAUAAUGGGAACUCUGGUACAGAGGAUGGCUGAAAGGA		43
18913	MI0004847	xtr-mir-153-1	Xenopus tropicalis miR-153-1 stem-loop	CACGGCUGCCCUUGUCAUUUUUGUGAUUUGCAGCUUGUAAUUUUGGUCUCAGUUGCAUAGUCACAAAAGUGAUCAUGGGCAGGUGGG		43
18914	MI0004848	xtr-mir-155	Xenopus tropicalis miR-155 stem-loop	UAUUAAUGCUAAUCGUGAUAGGGGUUUUUUAAUACAUAUUGACUCCUACAUGUUAGCAUUAUUAUCAUG		43
18915	MI0004849	xtr-mir-181b-1	Xenopus tropicalis miR-181b-1 stem-loop	AAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUGAGUUAAGAACACAAGCUCGCUGAACGAUGAAUGCAACUGUGUCCCC		43
18916	MI0004850	xtr-mir-181b-2	Xenopus tropicalis miR-181b-2 stem-loop	AAUGGCUGCAAUAAACAUUCAUUGCUGUCGGUGGGUUGUAGUUUAGAAAAGCUCAUUGAUCAAUGAAUGCAAACUGCAGACCA		43
18917	MI0004851	xtr-mir-182	Xenopus tropicalis miR-182 stem-loop	AGUGGCUUCUCUGGCAGUGUUUGGCAAUGGUAGAACUCACACUGGUGAGCUAUGAAGAUCCGGUGGUUCUAGACUUGCCAACUAUGGCCUGGGAAUAAAGCAGCA		43
18918	MI0004852	xtr-mir-183	Xenopus tropicalis miR-183 stem-loop	CAUCCCUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAAAACACAAAAUCAGUGAAUUACCAUAGGGCCAUAAACAGAGCAGAGAAAGAAC		43
18919	MI0004853	xtr-mir-184	Xenopus tropicalis miR-184 stem-loop	CCAGUAUCACUUCCUUAUCACUUUUCCAGCCCAGCUUUUCAUGACAAACUGUUGGACGGAGAACUGAUAAGGCUGUGUGACUG		43
18920	MI0004854	xtr-mir-187	Xenopus tropicalis miR-187 stem-loop	UGGUAUACCUUUGGUUACAACACAGGACAUGGGAGCUUACUUGGAACCCUCGUGUCUUGUGUUGCAGCCAGUGGUGGCCAAA		43
18921	MI0004855	xtr-mir-192	Xenopus tropicalis miR-192 stem-loop	GAGUGUACGGGCCUAUGACCUAUGAAUUGACAGCCAGUGGAUGUGAAGUCUGCCUGUCAAUUCUGUAGGCCACAGGUUCGUCCACCU		43
18922	MI0004856	xtr-mir-193	Xenopus tropicalis miR-193 stem-loop	GUGGUUUCGGAGUCGGGAUUUUGGGGGCGAGAUGAGCUAAUGAUUUAUCCAACUGGCCCGCAAAGUCCCGCUUCUGGAAGUCA		43
18923	MI0004857	xtr-mir-194-1	Xenopus tropicalis miR-194-1 stem-loop	UAGUGUGUAUCAGGUGUAACAGCAACUCCAUGUGGACUUGUCCGUAUUCCAGUGGAGAUGCUGUUACUUUUGAUGGGCAC		43
18924	MI0004858	xtr-mir-194-2	Xenopus tropicalis miR-194-2 stem-loop	UGAUGCUCAUAACCUGUAACAGCAACUCCAUGUGGAAGUAGAUAUAAUAUUCCGGUGGAGAUGCUGUUAUCUGUAAUGUGUAUCUA		43
18925	MI0004859	xtr-mir-199a	Xenopus tropicalis miR-199a stem-loop	AAGAACCUGCUCCGUCGCCCCAGUGUUCAGACUACCUGUUCAGGACAAUGCUGUUGUACAGUAGUCUGCACAUUGGUUAGACUGGGCAUGGGACAG		43
18926	MI0004860	xtr-mir-202-1	Xenopus tropicalis miR-202-1 stem-loop	CUCGCUGUUCCUUUUUCCUAUGCAUAUACCUCUUUGAAAAAUGAAUGUAAAGGGGCAUAGGGCAUGGGAAAAUGGCGCAGCUGAGCC		43
18927	MI0004861	xtr-mir-202-2	Xenopus tropicalis miR-202-2 stem-loop	CUCGCUGUUCCUUUUUCCUAUGCAUAUACCUCUUUGAAAAAUAAAUGUAAAGGGGCAUAGGGCAUGGGAAAAUGGCGCAGCUGAGCC		43
18928	MI0004862	xtr-mir-205b	Xenopus tropicalis miR-205b stem-loop	UGCUGCUGUCCUUCAUUCCACCGGAUCCUGUGUAAAUAUAAUCCAGAUUCCCAGUGGCAUGAAGUGCAUUAG		43
18929	MI0004863	xtr-mir-206	Xenopus tropicalis miR-206 stem-loop	GAGGUCACAUGCUUCUUUAUAUACCCAUAUGAACUACAUUGUUAUGGAAUGUAAGGAAGUGUGUGGCUUC		43
18930	MI0004864	xtr-mir-210	Xenopus tropicalis miR-210 stem-loop	UCCAGAUGCAGGUCAGCCACUGACUAACGCACAUUGCGCUGCUCCUAAAAUGCCACUGUGCGUGUGACAGCGGCUAACCAGCAUCUAGGAA		43
18931	MI0004865	xtr-mir-181a-1	Xenopus tropicalis miR-181a-1 stem-loop	GGCUACUUUAGUGAACAUUCAACGCUGUCGGUGAGUUUGGUAUCUAAAGGCAAACCAUCGAUCGUUGACUGUACAUUACGGCAAUGCCAG		43
18932	MI0004866	xtr-mir-181a-2	Xenopus tropicalis miR-181a-2 stem-loop	UUGAGGGCUUCAGAGAACAUUCAACGCUGUCGGUGAGUUUGAGAAAGUGUAAAAAUAUAAACCAUCGGCCGUUGACUGUACCCUGAGGCUUUUCA		43
18933	MI0004867	xtr-mir-214	Xenopus tropicalis miR-214 stem-loop	UUGGCUGGAAGGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCUCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU		43
18934	MI0004868	xtr-mir-215	Xenopus tropicalis miR-215 stem-loop	AACUGGUAACCAGGAGGAUGACCUAUGAAAUGACAGCCACUUCCAUACCAAACAUGUCUGUCAUUUCUGUAGGCCAAUAUUCUGAUUGCUUUGUUGA		43
18935	MI0004869	xtr-mir-216	Xenopus tropicalis miR-216 stem-loop	UGGCUGUGAAUUGGCUUAAUCUCAGCUGGCAACUGUGAGCAGUUAAUAAAUUAUCUCACAGUGGUCUCUGGGAUUAUACUAAACACAGCAA		43
18936	MI0004870	xtr-mir-217	Xenopus tropicalis miR-217 stem-loop	UUGAUGUUGUAGAUACUGCAUCAGGAACUGAUUGGAUCCCAGGGAGCAGCCAUCAGUUCCUAAUGCACUGCCUUCGGCAUCUA		43
18937	MI0004871	xtr-mir-218-1	Xenopus tropicalis miR-218-1 stem-loop	UGGUAACAAGGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGUGAGGUAUGAGUAAAACAUGGUUCUGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		43
18938	MI0004872	xtr-mir-218-2	Xenopus tropicalis miR-218-2 stem-loop	GGGGUUUUCCUUUGUGCUUGAUCUAACCAUGUGGUAGAACAAUACAUAUUGAACAUGGUUCUGUCAAGCACCAUGGAAGGCCAC		43
18939	MI0004873	xtr-mir-219	Xenopus tropicalis miR-219 stem-loop	AUGGAGCUCUCGCCCUUGAUUGUCCAAACGCAAUUCUUGUUCCAAUAGAAAUAUCAAGCCAAGAAUUGUGCCUGGACAUCUGUGGCUGGUGAUCC		43
18940	MI0004874	xtr-mir-222	Xenopus tropicalis miR-222 stem-loop	CGCUCAGUAAUCAGUGUAGAUCCUGUAUAUCUGUCAGCAGCUACAUCUGGCUACUGGGUCUCUA		43
18941	MI0004875	xtr-mir-223	Xenopus tropicalis miR-223 stem-loop	AGUGUGGCACUGAGUGUAUUUGACAAGCUGAGUCCGACACUCAAUGAGACAGAGUGUCAGUUUGUCAAAUACCCCAAGUGAGGCAC		43
18942	MI0004876	xtr-mir-301-1	Xenopus tropicalis miR-301-1 stem-loop	CUGCUAAUGUGUGCUCUGACUUUAUUGCACUACUGUACUAUACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCAUCUGCAAGCAG		43
18943	MI0004877	xtr-mir-301-2	Xenopus tropicalis miR-301-2 stem-loop	GAAUUGCUCUGACAGUGUUGCACUACUGUGAUCUCAAAUGAAGCAGUGCAAUAGUAUUGUCAAAGCAUUUCAU		43
18944	MI0004878	xtr-mir-302	Xenopus tropicalis miR-302 stem-loop	CCCCACUACUUUAACAUUGGUGUACUUUCUAUGUCUUUAAAAAGGGUAAGUGCUCCAAUGUUUUAGUGG		43
18945	MI0004879	xtr-mir-365-1	Xenopus tropicalis miR-365-1 stem-loop	CCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCACUUACACUACCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCA		43
18946	MI0004880	xtr-mir-367	Xenopus tropicalis miR-367 stem-loop	UUACUGUUGCCUAUGUGCAAACUCUGUGCUAUAUUGUCUAGAAUUGCACUGUAGCAAUGGUGA		43
18947	MI0004881	xtr-mir-383	Xenopus tropicalis miR-383 stem-loop	CUCCUCAGAUCAGAAGGUGAUUGUGGCUUUUAGUAGAUAUUAAGCAGCCACAGCACUGCCUGGUCAGAAAGAG		43
18948	MI0004882	xtr-mir-425	Xenopus tropicalis miR-425 stem-loop	GCCUUGGAAUGACACGAUCACUCCCGUUGAGCCGAAACUCACAGCGCCAUCGGGAAUAUCGUGUCGCUCCAAAGCUC		43
18949	MI0004883	xtr-mir-455	Xenopus tropicalis miR-455 stem-loop	UCCCUGGCGUGAGGGUAUGUGCCCUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGUU		43
18950	MI0004884	xtr-mir-489	Xenopus tropicalis miR-489 stem-loop	GUGGUGGCUUAGUGGUCGUAUGUAUGACGUCAUUUACUGGAUUUUUUAGGAGUGACAUCAUAUGUACGGCUGCUAAACUGCUGC		43
18951	MI0004885	xtr-mir-499	Xenopus tropicalis miR-499 stem-loop	GUGAGAGCGAGGCAGUUAAGACUUGCAGUGAUGUUUAGUUAAAAUCUUUUCAUGAACAUCACUUUAAGUCUGUACUGCUUCUCCCUC		43
18952	MI0004886	xtr-let-7c	Xenopus tropicalis let-7c stem-loop	UGUGUGCAUCCAGGUUGAGGUAGUAGGUUGUAUGGUUUAGAAUGACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGCUCACU		43
18953	MI0004887	xtr-let-7f	Xenopus tropicalis let-7f stem-loop	UGCAGGAUGAGGUAGUAGAUUGUAUAGUUUUGGGGUCACACCCGAUCUGGGAGAUAACUAUACAGUUUACUGUCUUUCCUGCG		43
18954	MI0004888	xtr-let-7g	Xenopus tropicalis let-7g stem-loop	GGCUGAGGUAGUUGUUUGUACAGUUUAAGGGUCUGUGACACCACCCUCUGUUGGAGAUAACUGUACAGGCCACUGCCUUGCCUA		43
18955	MI0004889	xtr-let-7i	Xenopus tropicalis let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACACUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUAG		43
18956	MI0004890	xtr-mir-1b	Xenopus tropicalis miR-1b stem-loop	GCACAUACUUCUUUAUAUGCCCAUACUGAAUGAAAAUGCUAUGGAAUGUUAAGAAGUAUGUA		43
18957	MI0004891	xtr-mir-9-3	Xenopus tropicalis miR-9-3 stem-loop	GUUUCUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAAAUAAGCCGUCAUAAAGCUAGAUAACCGAAAGUAGGAAUCA		43
18958	MI0004892	xtr-mir-15c	Xenopus tropicalis miR-15c stem-loop	CUUUGAGGUGAUCUAGCAGCACAUCAUGGUUUGUAGAAACAAGGAGAUACAGACCAUUCUGAGCUGCCUCUUGA		43
18959	MI0004893	xtr-mir-18a	Xenopus tropicalis miR-18a stem-loop	GUGCUUUUUGUCCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCAUAAAAAGU		43
18960	MI0004894	xtr-mir-23a-1	Xenopus tropicalis miR-23a-1 stem-loop	CUGACAGCGGGGGAUUCCUGGAGAUGGGAUUUUAUUUUGGCAGCCAAUAAAUCACAUUGCCAGGGAUUUCCAACUGUC		43
18961	MI0004895	xtr-mir-24a	Xenopus tropicalis miR-24a stem-loop	CUCUUGUGCCUACUGAACUGAUAUCAGUUCUAUUUCACACACUGGCUCAGUUCAGCAGGAACAGGAG		43
18962	MI0004896	xtr-mir-24b	Xenopus tropicalis miR-24b stem-loop	CUCCCGUACCUACUGGGCUGAUAAUCAGUGGUUAUAUCUUCCCCUGGCUCAGUUCAGCAGGACAGGAG		43
18963	MI0004897	xtr-mir-29a	Xenopus tropicalis miR-29a stem-loop	ACCCUUUUAAAGGAUGACUGAUUUCUUCUGGUGUUCAGAGUCUUUUGUUUUCUAGCACCAUUUGAAAUCGGUUAUAAUGAUGGGGUA		43
18964	MI0004898	xtr-mir-30d	Xenopus tropicalis miR-30d stem-loop	AGUUUGUCGCUGUAAACAUCCCCGACUGGAAGCUGUGAGGCUGCAUUUGAGCUUUCAGUCUGGUGUUUGCUGCUACCGGCU		43
18965	MI0004899	xtr-mir-92b	Xenopus tropicalis miR-92b stem-loop	UACAGAAGGAUCGGGAUGUUGUGCACUGUUGUCCUUUCUCCUGCCAAUAUUGCACUCGUCCCGGCCUCCUGCG		43
18966	MI0004900	xtr-mir-93a	Xenopus tropicalis miR-93a stem-loop	AUGGGCUUCAAAGUGCUGUUCGUGCAGGUAGCUUAAUAACAGACCUACUGCAUGGGCGGCACUUCCCAAGCCC		43
18967	MI0004901	xtr-mir-93b	Xenopus tropicalis miR-93b stem-loop	CUUCAAGUGCUGUUCGUGCAGGUAGCUUAAUAACAGACCUACUGCAUGGGCGGCACUUCCCAAG		43
18968	MI0004902	xtr-mir-96	Xenopus tropicalis miR-96 stem-loop	GGCCUGCUUUGGCACUAGCACAUUUUUGCUUUUGUACAUAUACUUUGAGCAAUUAUGUGUAGUGCCAAUAUAGGA		43
18969	MI0004903	xtr-mir-101a-2	Xenopus tropicalis miR-101a-2 stem-loop	AGGCUGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCUACUCUAAAGGUACAGUACUGUGAUAACUGAAGGAUGGUAGCCA		43
18970	MI0004904	xtr-mir-103-1	Xenopus tropicalis miR-103-1 stem-loop	UUCUCAUUUCCUUUGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGGAUCUGAGA		43
18971	MI0004905	xtr-mir-148a	Xenopus tropicalis miR-148a stem-loop	UAGUCUUUUAAAUCAAAGUUCUGUGACACUUAGACUCUGAAUAUGAUAGCAGUCAGUGCACUACAGAACUUUGUUUUGGGAGUCUG		43
18972	MI0004906	xtr-mir-338-1	Xenopus tropicalis miR-338-1 stem-loop	GUCCCCUGGAACAAUAUCCUGAUGCUGAAUGAGUGGGACAUACAUGCUCCAGCAUCAGUGAUUUUGUUGCAGGCGGCA		43
18973	MI0004907	xtr-let-7e-1	Xenopus tropicalis let-7e-1 stem-loop	CCCUGUGGGAUGAGGUAGUAGGUUGUUUAGUUAUUGGGCCGCACCCACCAAUGGGAGAGAACUACACAACCUACUGUCUCUCCUAAAGUG		43
18974	MI0004908	xtr-let-7a	Xenopus tropicalis let-7a stem-loop	GUGGGCUCCAGGCUGAGGUAGUAGGUUGUAUAGUUGAGGAUAACACCAAAGGAGAUAACUGUACAGCCUCCUAUCUUUCCCUGGGGCUU		43
18975	MI0004909	xtr-let-7e-2	Xenopus tropicalis let-7e-2 stem-loop	GCCCUUUGGGGUGAGGUAGUAGGUUGUUUAGUUGUGGGUUGCACCCUGACGUUUGGAUAACUAUACAAUCUACUGUCUUUCCUGAAGUGGCUG		43
18976	MI0004910	xtr-mir-16b	Xenopus tropicalis miR-16b stem-loop	AAUUGCUCCGCAUUAGCAGCACGUAAAUAUUGGGUGAUAUGAUAUGGAGCCCCAGUAUUAUUGUACUGCUUAAGUGUGGCAAGG		43
18977	MI0004911	xtr-mir-20a	Xenopus tropicalis miR-20a stem-loop	GCUAAAGUGGUGCUAAAGUGCUUAUAGUGCAGGUAGUUUUUCUGUAUUCUACUGCAUAAUGAGCACUUAAAGUACUCCUAGCUG		43
18978	MI0004912	xtr-mir-22	Xenopus tropicalis miR-22 stem-loop	CUGGCCCGCUAGAAGCAGUUCUUCAGUGGCAAGCUUUAUGUUGUUCCUCUGUGCUAAAGCUGCCAGUUGAAGAACUGUUGAAAGUGGCUACU		43
18979	MI0004913	xtr-mir-23b	Xenopus tropicalis miR-23b stem-loop	CCGGUGUGGCUGUUUGGGUUCCUGGCAUGCUGAUUUGUGAGUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACACAACCAUGUCCU		43
18980	MI0004914	xtr-mir-25-1	Xenopus tropicalis miR-25-1 stem-loop	GCUGGUGUUGACAGGCAGAGACAGGAGCAACUGCUGGUGUGCCUUGGUAGCAUUGCACUUGUCUCGGUCUGACAGUGUCGGC		43
18981	MI0004915	xtr-mir-25-2	Xenopus tropicalis miR-25-2 stem-loop	GCUGGUGUUGACAGGCAGAGACAGGAGCAACUGCUGGUGUGCCUUGGUAGCAUUGCACUUGUCUCGGUCUGACAGUGUCGGC		43
18982	MI0004916	xtr-mir-27c-1	Xenopus tropicalis miR-27c-1 stem-loop	CUCUAGAGAGGCAGGACUUAGCUGGCUCUGUGAACAGGUCUUGUGUGUCAAUGUUCACAGUGGCUAAGUUCCACCCCACUGG		43
18983	MI0004917	xtr-mir-27c-2	Xenopus tropicalis miR-27c-2 stem-loop	CUCUAGAGAGGCAGGACUUAGCUGGCUCUGUGAACAGGUCUUGUGUGUCAAUGUUCACAGUGGCUAAGUUCCACCCCACUGG		43
18984	MI0004918	xtr-mir-29c	Xenopus tropicalis miR-29c stem-loop	UCCCUUACACAGGAUGACCGAUCUCUCUUGGUGUUCAGAGGCUCAGGUCUUCAUCUAGCACCAUUUGAAAUCGGUUAUAAUGUAAGGUGA		43
18985	MI0004919	xtr-mir-30c-2	Xenopus tropicalis miR-30c-2 stem-loop	GAGAGACAGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAUACAAAGCUGGGGGAAGGCUGUUUACUCUCUCUG		43
18986	MI0004920	xtr-mir-30e	Xenopus tropicalis miR-30e stem-loop	GGGCAGUUACAGCCUCUGUAAACAUCCUUGACUGGAAGCUGUGAAAUAAUGAUAGUAGCUUUCAGUCGGAUGUUUACAGCUGCUAGCUGC		43
18987	MI0004921	xtr-mir-31	Xenopus tropicalis miR-31 stem-loop	CCUAGUUCUAGAGAGGAGGCAAGAUGUUGGCAUAGCUGUUGCAUCUGAAACCAGUUGUGCCAACCUAUUGCCAUCUUUCUUGUCUACC		43
18988	MI0004922	xtr-mir-33a	Xenopus tropicalis miR-33a stem-loop	CUGUGGUGCAUUGUAGUUGCAUUGCAUGUGAUAUCAGCGGUGUGCAAUGUGCCUGCAGUGCAACACAG		43
18989	MI0004923	xtr-mir-33b	Xenopus tropicalis miR-33b stem-loop	CCCUGGUGCAUUGUUGUUGCAUUGCAUGUCACCUUGGACGUUGUGCAAUGUUUCUUCAGUGCAGUAUGG		43
18990	MI0004924	xtr-mir-34b-3	Xenopus tropicalis miR-34b-3 stem-loop	UGUUGGGUUUUCAGGCAGUGUAGUUAGCUGAUUGUGUUAACAUAAGACUUGCAAUCACUAGCUAAACUACCAGCAAAACUAAACA		43
18991	MI0004925	xtr-mir-34b-1	Xenopus tropicalis miR-34b-1 stem-loop	UGUUGGGUUUUCAGGCAGUGUAGUUAGCUGAUUGUGUUAACAUAAGACUUGCAAUCACUAGCUAAACUACCAGCAAAACUAAACA		43
18992	MI0004926	xtr-mir-92a-1	Xenopus tropicalis miR-92a-1 stem-loop	CUUUCUGUAUAGGUUGGGAUUGGUUGCAAUGCUGUACUAUUUAUGUAGUAUUGCACUUGUCCCGGCCUGUUUAGGAUG		43
18993	MI0004927	xtr-mir-100	Xenopus tropicalis miR-100 stem-loop	GUUGCCAUAAACCCGUAGAUCCGAACUUGUGCUGUGCCCCUCUCACAAGCUCGAGUGUGCGGGUCUGUGUCGGCUU		43
18994	MI0004928	xtr-mir-101a-1	Xenopus tropicalis miR-101a-1 stem-loop	GCGUGAACUGUCCUUUUUCGGUUAUCAUGGUACCGGUGCUGUGUAUAUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGUGCCAUC		43
18995	MI0004929	xtr-mir-103-2	Xenopus tropicalis miR-103-2 stem-loop	CUCUGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUCUAUGUCAAGCAGCAUUGUACAGGGCUAUGAAGGAGCAGAGA		43
18996	MI0004930	xtr-mir-124	Xenopus tropicalis miR-124 stem-loop	UAAGUCUCUGACUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGUGGAGCCUAC		43
18997	MI0004931	xtr-mir-125a	Xenopus tropicalis miR-125a stem-loop	GUCCCUGAGACCCUUAACCUGUGAGGAAGACAUAUGUCACAGGUGAGGUUCUGAGGAGCUGG		43
18998	MI0004932	xtr-mir-128-1	Xenopus tropicalis miR-128-1 stem-loop	UGAGCGGCUGGAACCGGGCCCGGAGCGCUGUCUGAGAGGGUUUAAGUUUCUCACAGUGAACCGGUCUCUUUUUCAGUCUCUUC		43
18999	MI0004933	xtr-mir-135-2	Xenopus tropicalis miR-135-2 stem-loop	CCCCCUGCUGAGGUAUAUGGCUUUUUAUUCCUAUGUGAUUGCUUUCCUAAUUCACAUAGGGCAGAAAGCCAUGUGCUGCACAGGGGAC		43
19000	MI0004934	xtr-mir-137-1	Xenopus tropicalis miR-137-1 stem-loop	GCUCUGUGGCUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUUGAGGAGAGUAUCUUCAGCA		43
19001	MI0004935	xtr-mir-137-2	Xenopus tropicalis miR-137-2 stem-loop	GCUCUGUGGCUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUUGAGGAGAGUAUCUUCAGCA		43
19002	MI0004936	xtr-mir-137-3	Xenopus tropicalis miR-137-3 stem-loop	GCUCUGUGGCUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUUGAGGAGAGUAUCUUCAGCA		43
19003	MI0004937	xtr-mir-143	Xenopus tropicalis miR-143 stem-loop	UGUCUCCCAGCCCAAGGUGCAGUGCUGCAUCUCUGGUCAGUUGUGAGUCUGAGAUGAAGCACUGUAGCUCGGGAAGGGGGAAU		43
19004	MI0004938	xtr-mir-144	Xenopus tropicalis miR-144 stem-loop	UUUGGGAUAUCAUCAUAUACUGUAAGUUUGUUUUAAGACACUACAGUAUAGAUGAUGUACUA		43
19005	MI0004939	xtr-mir-145	Xenopus tropicalis miR-145 stem-loop	ACCUAUUCCUCAAGGUCCAGUUUUCCCAGGAAUCCCUUGGGUGCUGUGGUGGGGAUUCCUGGAAAUACUGUUCUUGGGGUGUAGGC		43
19006	MI0004940	xtr-mir-153-2	Xenopus tropicalis miR-153-2 stem-loop	AGCAGUUGCCAGUGUCAUUUUUGUGACGUUGCAGCUAGUAAUAUGAGCCCAGUUGCAUAGUCACAAAAGUGAUUAUUGGAAACUGU		43
19007	MI0004941	xtr-mir-191	Xenopus tropicalis miR-191 stem-loop	GGCGGUAGCUCUGACAACGGAAUCCCAAAAGCAGCUGUUGUGAAAAUGUUCAGCUGCAGUUGGGACCCGUUCACGGAUCUAUUGCC		43
19008	MI0004942	xtr-mir-196a	Xenopus tropicalis miR-196a stem-loop	UUUGUAUCCAGCUGAUCUGUGGUUUAGGUAGUUUCAUGUUGUUGGGAUUGCUUUUUCUUAACGCGGCAACAAGAAACUGCCUUAAUUACGUCAGUUCGUCUUCAUC		43
19009	MI0004943	xtr-mir-196b	Xenopus tropicalis miR-196b stem-loop	AGCCGCUGUGUGGUUUAGGUAGUUUUAUGUUGUUGGGCAUUCACCUUUCUCUCUACAACAAGAAACUGCCUUAAUUACAUCAGUGGG		43
19010	MI0004944	xtr-mir-199b	Xenopus tropicalis miR-199b stem-loop	AAGAUCCCGAGAGGUGGGUGGUCCCGUUCCCCCAGUGUUCAGACUACGUGUUCGUUGGACAGAACCUGAACAGUAGUCUACACACUGGUUAAACUGGGCCAUGCGGUCAA		43
19011	MI0004945	xtr-mir-200a	Xenopus tropicalis miR-200a stem-loop	UGGUCCUCUAUGGACAUCUUACUAGACAGUGCUGGAUUUAUUUUAUCUUUUCUAACACUGUCUGGUAACGAUGUUUAAAGAGUGAGCCA		43
19012	MI0004946	xtr-mir-200b	Xenopus tropicalis miR-200b stem-loop	CUGUGGCGCUAUUGCCAUCUUACUGGGCAGCAUUGGAUUUUGUCUAUGUUUCUAAUACUGCCUGGUAAUGAUGAUUAUGGCGCCCCACA		43
19013	MI0004947	xtr-mir-203	Xenopus tropicalis miR-203 stem-loop	CCUGGCCGAGUGGUUCUUAACAGUUCAACAGUUCUCUAUCGAAAUUGUGAAAUGUUUAGGACCACUUGAUCCGG		43
19014	MI0004948	xtr-mir-204-2	Xenopus tropicalis miR-204-2 stem-loop	AUGUGACCUGUGGGCUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGGGGCUGGGAAGGCAAAGGGACGUUCAGUUGUCAUCA		43
19015	MI0004949	xtr-mir-204-1	Xenopus tropicalis miR-204-1 stem-loop	UAGAGGACUUCGACAUUGUGACCCAUGGGCUUCCCUUUGUCAUCCUAUGCCUGAGAAUGCUGGAGAGGCAGGGACAGCAAAGGGAUGCUCAGAUGUUACCUCUUG		43
19016	MI0004950	xtr-mir-205a	Xenopus tropicalis miR-205a stem-loop	CCACGUGUCCUGCUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACAUAAUCAGAUUUCAGUGGAGUGAAGCACAAGAGGCAUGUAG		43
19017	MI0004951	xtr-mir-208	Xenopus tropicalis miR-208 stem-loop	UCCUUUCAACAGGCAAGCUUUUUGCUUGGAUUAUGUUUUCUGUUGUUGUAUAAGACGAGCAUAAAGCUUGUUUGUUAGAAG		43
19018	MI0004952	xtr-mir-212	Xenopus tropicalis miR-212 stem-loop	UGGUCAUUGCAUCGGCACCUUGGCUCUAGACUGCUUACUGUGAAACUGUGCUAUAGGAACAGUAACAGUCUACAGUCAUGGCUACUGACGUAUGAC		43
19019	MI0004953	xtr-mir-221	Xenopus tropicalis miR-221 stem-loop	ACCCAGACUUUGGCGUGCACCUGGCAUACAAUGUAGAAAACUGUGUUUGCAAAGCAACAGCUACAUUGUCUGCUGGGUUUCAUGCUGAAUGGA		43
19020	MI0004954	xtr-mir-338-2	Xenopus tropicalis miR-338-2 stem-loop	CAACAAUAUCCUGAUGCCGUCUGAGUGUGCGGGAAAGCUCCAGCAUCAGUGAUUUUGUUG		43
19021	MI0004955	xtr-mir-363	Xenopus tropicalis miR-363 stem-loop	UUUUGUUGUUCGCGGGUGGAUCACGAUGCAAUUUUAUUUAGUUUGGUAGGAGAAAAAUUGCACGGUAUCCAUCUGUAAACCGCAGAA		43
19022	MI0004956	xtr-mir-429	Xenopus tropicalis miR-429 stem-loop	UGCCUGUUGACCAAUGUCUUACCAGACAAGGUUAGAUCUAGUUACUCUCGUCUAAUACUGUCUGGUAAUGCCGUUGGUCACAUUGGC		43
19023	MI0004957	xtr-mir-449	Xenopus tropicalis miR-449 stem-loop	CUGUGUUUAGAAGGAAGGCAGUGUAAUGUUAGCUGGUUGGAAAAUAGCAGACACUGGUUAACUUACACCUGCCCCCCUUCUUUACAU		43
19024	MI0004958	xtr-mir-451	Xenopus tropicalis miR-451 stem-loop	GAGUGGCAAUGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAAGGGUUCUGUUGCUGCUC		43
19025	MI0004959	xtr-mir-18b	Xenopus tropicalis miR-18b stem-loop	CCUUGUGUUAAGGUGCAUCUAGUGCAGUUAGUGACAUAGUGUAGCAUCUACUGCCCUAAAUGCUCCUUUUGGCACAGG		43
19026	MI0004960	xtr-mir-19b-1	Xenopus tropicalis miR-19b-1 stem-loop	GCUCCUGUCAGUUUAGCUGGUUUGCAUCAGCUGACUAUUGUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGC		43
19027	MI0004961	xtr-mir-20b	Xenopus tropicalis miR-20b stem-loop	GCAGUUCCAAAGUGCUCAUAGUGCAGGUAGUUGUAUUGAUGUUCUACUGUAAUAUGGGCACUUACAGUACUGCU		43
19028	MI0004962	xtr-mir-133a	Xenopus tropicalis miR-133a stem-loop	CAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUCUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGGAUUGCAUUG		43
19029	MI0004963	xtr-mir-428	Xenopus tropicalis miR-428 stem-loop	CACGUCGGCCUAACUGGAGCCCUGUCUCAUUGCAGCUGUGAGUAAGUGCUCUCUAGUUCGGUUGCUGAGUG		43
19030	MI0004965	mmu-mir-652	Mus musculus miR-652 stem-loop	AGGAACAGCUAUGUACUGCACAACCCUAGGAGGGGGUGCCAUUCACAUAGAGUAUAAUUGAAUGGCGCCACUAGGGUUGUGCAGUGUACAGCCUACAC	The predominant miRNA cloned by Langraf et al. has a 3' terminal U residue, which is incompatible with the genome sequence [2]. 	6
19031	MI0004966	tni-mir-10d	Tetraodon nigroviridis miR-10d stem-loop	GCCGGUGAGGUGCUCGUCGUCUAUACAUACCCUGUAGAACCGAAUGUGUGUGCAGCUGACUUGAUCACAGAUUGGGUUCUAGGGGAGUCUAUGGGCGCUGAAUAAUCAUCGAUGAACGGC		39
19032	MI0004967	fru-mir-10d	Fugu rubripes miR-10d stem-loop	CCGGUGAGGUGGAUCGUCGUCUAUAAAUACCCUGUAGAACCGAAUGUGUGUGCAGCUGACUUGAUCACAGAUUGGGUUCUAGGGGAGUCUAUGGGCGAUGAAUAAUCACUGA		38
19033	MI0004968	bmo-let-7	Bombyx mori let-7 stem-loop	GGUACUGCCGUCGGCUUGUUGAGGUAGUAGGUUGUAUAGUACGGAAAUACAACACAUAGGUGCGACUGUAUAGCCUGCUAACUUUCCGAGCUGACGGAAUGACA		46
19034	MI0004969	bmo-mir-1	Bombyx mori miR-1 stem-loop	AGCCUUGCGCAAGUUCCGUGCUUCCUUACUUCCCAUAGUCAUUGUAAUCAUAUGGAAUGUAAAGAAGUAUGGAGCUGCGCGGGCG		46
19035	MI0004970	bmo-mir-7	Bombyx mori miR-7 stem-loop	CGCUUCGUGUUGUAUGGAAGACUAGUGAUUUUGUUGUUUUUGUUGACUAACAAGAAAUCACUAAUCUGCCUACAAAGCGACAGCA		46
19036	MI0004971	bmo-mir-8	Bombyx mori miR-8 stem-loop	CACGACGGAGUAACGGUUCGCAUCUUACCGGGCAGCAUUAGAGUCCUGUCUAUAUUUUCUAAUACUGUCAGGUAAAGAUGUCGUCCGCGCUCCACGUUCGUC		46
19037	MI0004972	bmo-mir-9	Bombyx mori miR-9 stem-loop	AGUAGACUGGUUAAUUAUCUUUGGUUAUCUAGCUGUAUGAGUAUUACUGACGUCAUAAAGCUAGGUUACCGGAGUUAAGUGCCGUCUACA		46
19038	MI0004973	bmo-mir-10	Bombyx mori miR-10 stem-loop	AGUGCCCUACAUCUACCCUGUAGAUCCGAAUUUGUUUGAAGUGAGGCGACAAAUUCGGUUCUAGAGAGGUUUGUGUGGUGCACG	Tong et al erroneously published the reverse complement of the sequence shown here [1]. 	46
19039	MI0004974	bmo-mir-14	Bombyx mori miR-14 stem-loop	UUGUCAUUUGUGUCGGGGAGAGAAAUCGACGAGGCUGUUUUAUUUAGUCAGUCUUUUUCUCUCUCCUAUAUGAGUGACAU		46
19040	MI0004975	bmo-mir-34	Bombyx mori miR-34 stem-loop	AGAAUCAGGGUAGACCGCGUUGGCAGUGUGGUUAGCUGGUUGUGUAUGGAAAUGACAACAGCCACUAACGACACUGCUCCUGCGUGCACCCUAAAUCA		46
19041	MI0004976	bmo-mir-124	Bombyx mori miR-124 stem-loop	CAGUCCACCUCCUCGCGUUCACUGCCGGAGCCGUUAUGUAUAUUUAAAAUUCAUAAGGCACGCGGUGAAUGCCAAGAGCGGACUC		46
19042	MI0004977	bmo-mir-263b	Bombyx mori miR-263b stem-loop	AGCCCACGCUGUUCCUUGGCACUGGGAGAAUUCACAGGAGUUGUAAUUCAUACCCGUGAAUUUCCCGAUGCCUUAGCUCAGUGUGGUCA		46
19043	MI0004978	bmo-mir-263a	Bombyx mori miR-263a stem-loop	AUCGAUCCAAGCACAGGCAAUGGCACUGGAAGAAUUCACGGGUUCAGUUUAUAUAUUCCCGUGAUCUCUUAGUGGCAUCACUGGUGCAGGACGAC		46
19044	MI0004979	bmo-mir-275	Bombyx mori miR-275 stem-loop	CAGGCGGCAGCGCCGCGCGCUACUCCGGCGCCAGGACUGUCCUCACCGAGUCAGGUACCUGAAGUAGCGCGCGGUGUCUCCUCCUA		46
19045	MI0004980	bmo-mir-276	Bombyx mori miR-276 stem-loop	CUGGUAAUUACCACUAGCGAGGUAUAGAGUUCCUACGUAUGCUAACACUGUAGGAACUUCAUACCGUGCUCUUGGGUUUGCCAA		46
19046	MI0004981	bmo-mir-277	Bombyx mori miR-277 stem-loop	UUGAUUACGCCUCGGGGUUCGUGCCAGGAGUGCGUUUGCAAAGAGGCCGACAUGUUUGCGUUAUUGCAAUGUUAACACUGUAAAUGCACUAUCUGGUACGACAUCCCGGGGCGUGUAGCAAC		46
19047	MI0004982	bmo-mir-279	Bombyx mori miR-279 stem-loop	ACGUCAAUUUCUUUCGAUGAGUGGAGGUUUAGUGCAUGUUUAUUUACACCAUGACUAGAUCCACACUCAUCCAUGGAAGUUGCGA		46
19048	MI0004983	bmo-mir-282	Bombyx mori miR-282 stem-loop	CGGGACUUUGACCUAGCCUCUCCUUGGCUUUGUCUGUUUCGUUAGUAGCUCAGACAUAGCCUGAUAGAGGUUACGUUUUGUCCCU		46
19049	MI0004984	bmo-mir-283	Bombyx mori miR-283 stem-loop	AACGUUUCCCGACUAAAUAUCAGCUGGUAAUUCUGGGCUUUAUUAAUCCCAGGCUAUCAGCUGGUAUACAGUUAUGAUACGUA		46
19050	MI0004985	bmo-mir-305	Bombyx mori miR-305 stem-loop	CGACCGCCGCACGCCCAUUGUACUUCAUCAGGUGCUCUGGUGAUCAUAGUUCCAGGCGCUUGUUGGAGUACACUUACCGUGUCGGCGGUUA		46
19051	MI0004986	bmo-mir-307	Bombyx mori miR-307 stem-loop	AGCUCGUUCCCGGUUACUCACUCAACCUGGGUGUGAUGUGUGCACUCGUUGCUCGGCCCAUCACAACCUCCUUGAGUGAGCGAUCGUCUAUGAGCC		46
19052	MI0004987	kshv-mir-K12-12	Kaposi sarcoma-associated herpesvirus miR-K12-12 stem-loop	GAUGGCCGGCACGCGGUGUCAACCAGGCCACCAUUCCUCUCCGCAUUAAAGCACUCGGUGGGGGAGGGUGCCCUGGUUGACACAAUGUGCCGCGCAUC	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1]. 	16
19053	MI0004988	ebv-mir-BART15	Epstein Barr virus miR-BART15 stem-loop	UGUGCCGCUUGGAGGGAAACAUGACCACCUGAAGUCUGUUAACCAGGUCAGUGGUUUUGUUUCCUUGAUAGAGACACA	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART5 by Grundhoff et al [1] but is not related to ebv-miR-BART5 (MIR:MI0003727).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
19054	MI0004989	ebv-mir-BART16	Epstein Barr virus miR-BART16 stem-loop	AGGCUUUCAGGUGUGGAAUUUAGAUAGAGUGGGUGUGUGCUCUUGUUUAAUUACACCAAGAUCACCACCCUCUAUCCAUAUCCCACAAUUGAUAAACCU	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART7 by Grundhoff et al [1] but is not related to ebv-miR-BART7 (MIR:MI0003729).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
19055	MI0004990	ebv-mir-BART17	Epstein Barr virus miR-BART17 stem-loop	GUUGAACAGGAUGUGGCACCCUAAGAGGACGCAGGCAUACAAGGUUAUUACCCAGUCCUUGUAUGCCUGGUGUCCCCUUAGUGGGACGCAGGCCUAGGUAGC	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART8 by Grundhoff et al [1] but is not related to ebv-miR-BART8 (MIR:MI0003730).  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
19056	MI0004991	ebv-mir-BART18	Epstein Barr virus miR-BART18 stem-loop	UUGUUGCCGUUGAAAGACGGGUGUCCUGGCUCAAGUUCGCACUUCCUAUACAGUGUUAAAGCCUUGUAUCGGAAGUUUGGGCUUCGUCCCAGUGUACUCGAUAAUGUCGACUGCUGCGA	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART10 by Grundhoff et al [1] but is not related to ebv-miR-BART10 (MIR:MI0003732).  The mature miRNA names and sequences reflect cloning frequencies from Landgraf et al. [2], and may differ subtly from previous annotations. 	9
19057	MI0004992	ebv-mir-BART19	Epstein Barr virus miR-BART19 stem-loop	GUAUCCGUGUCCUGACAACAUUCCCCGCAAACAUGACAUGGGUUAAUUUAAACAUGUUUUGUUUGCUUGGGAAUGCUCUUAGGGCCUGGAAGC	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART17 by Grundhoff et al [1].  The mature miRNA names and sequences reflect cloning frequencies from Landgraf et al. [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
19058	MI0004993	ebv-mir-BART20	Epstein Barr virus miR-BART20 stem-loop	UACAGGCGUAGGGCCUAUUGUAGCAGGCAUGUCUUCAUUCCUGCGUACCGAAUGGCAUGAAGGCACAGCCUGUUACCAUUGGCACCUUUUUUCCAUGUA	The arm of the precursor miRNA giving rise to the mature sequence was verified using microarray hybridisation and Northern blot, but the extents of the mature miRNA shown here are predicted and not experimentally determined [1].  This sequence was named miR-BART18 by Grundhoff et al [1].  The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	9
19059	MI0004994	gga-mir-21	MI0004994 Gallus gallus miR-21 stem-loop	UGUACCAUCCUGUCGGAUAGCUUAUCAGACUGAUGUUGACUGUUGGAUCUCAUGGCAACAACAGUCGGUAGGCUGUCUGACAUUUUGGUAUCUCUCA		10
19060	MI0004995	gga-mir-451	Gallus gallus miR-451 stem-loop	ACACAUGGCUGGCAGGGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAACGGUUCUGCUGACAGCCA		10
19061	MI0004996	gga-mir-144	Gallus gallus miR-144 stem-loop	CCCGCCGCCCUGGGCUGGAUAUCAUCAUAUACUGUAAGUUCACUAUGAGACACUACAGUAUAGAUGAUGUACUCCCCUGGGCUGC		10
19062	MI0004997	gga-mir-456	MI0004997 Gallus gallus miR-456 stem-loop	AUUUAAGCUGCUGUGUGUGUGCGUGUGUGAGCAGGCAUCUUCUCAGCCUACAUGUGGAUUCCUAAAUCUGCAGGCUGGUUAGAUGGUUGUCAUGCAUUCAUCUGAUAACUGC		10
19063	MI0004998	gga-mir-460	Gallus gallus miR-460 stem-loop	CUGACUAUAUAGCACCUGCAUUGUACACACUGUGUGUGUUAACUGGAAAUGCACAGCGCAUACAAUGUGGAUUCUGUAGAAGUCACUCAC		10
19064	MI0004999	gga-mir-757-1	Gallus gallus miR-757-1 stem-loop	CCCGGUGACUUUCUCGCAGAGCUGCAGAUGGGAUUCUCGCUAUGAGCUCUCUGCUGCUCAGUCGGAUACACUCAGUGCUGUA	This sequence is incorrectly named mir-548 in the E-published Xu et al article [1].  Chicken mir-757 is unrelated to mir-548 (MIR:MI0003593). 	10
19065	MI0005000	gga-mir-757-2	Gallus gallus miR-757-2 stem-loop	CCCGGUGACUUUCUCGCAGAGCUGCAGAUGGGAUUCUCGCUAUGAGCUCUCUGCUGCUCAGUCGGAUACACUCAGUGCUGUA	This sequence is incorrectly named mir-548 in the E-published Xu et al article [1].  Chicken mir-757 is unrelated to mir-548 (MIR:MI0003593). 	10
19066	MI0005002	mmu-mir-490	Mus musculus miR-490 stem-loop	UGGAAAGUUCAUUGUUCGACACCAUGGAUCUCCAGGUGGGUCACGUUUAGAUAUACACCAACCUGGAGGACUCCAUGCUGUUGA		6
19067	MI0005003	mmu-mir-676	Mus musculus miR-676 stem-loop	CUUUGCCUGAAUGCAUGACUCUACAACCUUAGGACUUGCAGAAUUAAAGGAAUGCCGUCCUGAGGUUGUUGAGCUGUGCGUUUCUGGGC		6
19068	MI0005004	mmu-mir-615	Mus musculus miR-615 stem-loop	UCGGGAGGGGCGGGAGGGGGGUCCCCGGUGCUCGGAUCUCGAGGGUGCUUAUUGUUCGGUCCGAGCCUGGGUCUCCCUCUUCCCCCCAUCCC		6
19069	MI0005005	bta-mir-106	Bos taurus miR-106 stem-loop	CCUUGGCCAUGUAAAAGUGCUUACAGUGCAGGUAGCUUUUUGAGAUCUACUGCAAUGCAAGCACUUCUUACAUUACCAUGG		44
19070	MI0005006	bta-mir-107	Bos taurus miR-107 stem-loop	CUCUCUGCUUUCAGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCACAGA		44
19071	MI0005007	bta-mir-10a	Bos taurus miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGAUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUC		44
19072	MI0005008	bta-mir-127	Bos taurus miR-127 stem-loop	UGAUCACUGUCUCCAGCCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCUGGUCGGAAGUCUCCUCAUC		44
19073	MI0005009	bta-mir-139	Bos taurus miR-139 stem-loop	GUGUACUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC		44
19074	MI0005010	bta-mir-140	Bos taurus miR-140 stem-loop	UCUCUCUGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACCGGGGCACC		44
19075	MI0005011	bta-mir-142	Bos taurus miR-142 stem-loop	GACAGUGCAGUCACCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUG	In addition to the mature miR-142 sequence shown here, Gu et al. also cloned the offset sequence CCCAUAAAGUAGAAAGCACUA just once [2].  This sequence aligns with that cloned in chicken (MIR:MI0001281). 	44
19076	MI0005012	bta-mir-15b	Bos taurus miR-15b stem-loop	UUGAGACCUUAAAGUACUGUAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUAGAAAUUUAAGGAAAUUCAU		44
19077	MI0005013	bta-mir-181b	Bos taurus miR-181b stem-loop	CUGAUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGACUUUGAAUCAACUCACUGAUCAAUGAAUGUAAACUGCGGACCAAACA		44
19078	MI0005014	bta-mir-193a	Bos taurus miR-193a stem-loop	UGGGAGCUGAGAGCUGGGUCUUUGCGGGCGAGAUGAAGGUGUCGGUUCAACUGGCCUACAAAGUCCCAGUCCUCGGCCCCC		44
19079	MI0005015	bta-mir-20b	Bos taurus miR-20b stem-loop	AGUACCAAAGUGCUCACAGUGCAGGUAGUUUUGGCAGCGCUCUACUGUAGUGUGGGCACUUCCAGUACU		44
19080	MI0005016	bta-mir-215	Bos taurus miR-215 stem-loop	UGUACAGGAAAAUGACCUAUGAAUUGACAGACAACGUGACUAAGUCUGUCUGUCAUUUCUGUAGGCCAAUGUUCUGUAU		44
19081	MI0005017	bta-mir-218	Bos taurus miR-218 stem-loop	UUUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACC		44
19082	MI0005018	bta-mir-30e	Bos taurus miR-30e stem-loop	GGGCAGUCUUUGCUACUGUAAACAUCCUUGACUGGAAGCUGUAAGGCGUUGCAAGGAGCUUUCAGUCGGAUGUUUACAGCGGCAGGCUGCCA		44
19083	MI0005019	bta-mir-345	Bos taurus miR-345 stem-loop	ACCCAAACCCAGGUCUGCUGACUCCUAGUCCAGUGCUUGUGAUGGCUGGUGGGCCCUGAACUAGGGGUCUGGAGGCCUGGGUUUGAAUAUC		44
19084	MI0005020	bta-mir-369	Bos taurus miR-369 stem-loop	UGAAGGGAGAUCGACCGUGUUAUAUUCGCUUUAUUGACUUCGAAUAAUACAUGGUUGAUCUUUUCUCAG		44
19085	MI0005021	bta-mir-380	Bos taurus miR-380 stem-loop	AAGAUGGUUGACCAUAGAACAUGCGCUGUCUCUAUGUCGUAUGUAAUGUGGUCCACGUCUU		44
19086	MI0005022	bta-mir-487a	Bos taurus miR-487a stem-loop	GGUACUUGAAGAGUGGUUAUCCCUGCUGUGUUCGCUGUAUUUAUGACGAAUCAUACAGGGACAUCCAGUUUUUCAGUAUC		44
19087	MI0005023	bta-mir-545	Bos taurus miR-545 stem-loop	CCCAGCCUGGCACAUUCGUAGGCCUCAGUAAAUGUUUAUUGGAUGAAUAAAUGAAUGGCUCAUCAACAAACAUUUAUUGUGUGCCUGCUAACGUGAUCUCCACAGG		44
19088	MI0005024	bta-mir-92	Bos taurus miR-92 stem-loop	UGGGUGGGGAUUUGUUGCACUGCUUGUGUUAUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA		44
19089	MI0005025	bta-mir-98	Bos taurus miR-98 stem-loop	AGGACUCUGCUCAUGCUGGGGUGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUUUUAGGCCCCAAUUUGAAGAUAACUAUACAACUUACUACUUUCCCUGGUGUGUAGCACAUUCA		44
19090	MI0005026	bta-let-7d	Bos taurus let-7d stem-loop	CCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUCGGGCAGGGAUUUUGCCCACAAGGAGGUAACUAUACGACCUGCUGCCUUUCUUAGG		44
19091	MI0005027	bta-mir-124a	Bos taurus miR-124a stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG		44
19092	MI0005028	bta-mir-132	Bos taurus miR-132 stem-loop	CCGCCCCCGCGUCUCCAGGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACCGGAGGUAACAGUCUACAGCCAUGGUCGCCCCGCAGCACGCCCACGCGC		44
19093	MI0005029	bta-mir-138	Bos taurus miR-138 stem-loop	GUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACGAGCAGCGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUUGCAUCA		44
19094	MI0005030	bta-mir-148b	Bos taurus miR-148b stem-loop	UUAGCAUUUGAGGUGAAGUUCUGUUAUACACUCAGGCUGUGGCUCUCUGAAAGUCAGUGCAUCACAGAACUUUGUCUCGAAAGCUUUCUA		44
19095	MI0005031	bta-mir-17	Bos taurus miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUGGUGAC		44
19096	MI0005032	bta-mir-181c	Bos taurus miR-181c stem-loop	UUGCCAAGGGUUUGGGGGAACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACCCCGAGGCCUGGAACUGCC		44
19097	MI0005033	bta-mir-186	Bos taurus miR-186 stem-loop	UGCUUAUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGAUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGGAAGUUUGAGCU		44
19098	MI0005034	bta-mir-191	Bos taurus miR-191 stem-loop	GGCUGGACAGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCGCUUGGAUUUCGUUCCCUGCUCUCCUGCCU		44
19099	MI0005035	bta-mir-192	Bos taurus miR-192 stem-loop	AGACCGAGUGCACAGGGCUCUGACCUAUGAAUUGACAGCCAGUGCUCUUGUGUCCCCUCUGGCUGCCAAUUCCAUAGGUCACAGGUAUGUUCGCCUCAAUGCCAGC		44
19100	MI0005036	bta-mir-199b	Bos taurus miR-199b stem-loop	CCUCCACUCCGUCUACCCAGUGUUUAGACUAUCUGUUCAGGACUCCCAAAUUGUACAGUAGUCUGCACAUUGGUUAGGCUGGGCUGGGUUAGACCCUCGG		44
19101	MI0005037	bta-mir-200a	Bos taurus miR-200a stem-loop	GGGCCUCUGUGGACAUCUUACCGGACAGUGCUGGAUUUCUCGGCUCGACUCUAACACUGUCUGGUAACGAUGUUCAAAGGUGACCC		44
19102	MI0005038	bta-mir-200c	Bos taurus miR-200c stem-loop	CGUCUUACCCAGCAGUGUUUGGGUGCUGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG		44
19103	MI0005039	bta-mir-210	Bos taurus miR-210 stem-loop	CCUCCAGGCGCAGGGCAGCCACUGCCCACCGCACACUGCGCUGCUCCGGACCCACUGUGCGUGUGACAGCGGCUGAUCUGUCCCUGGGCAGCGCGACC		44
19104	MI0005040	bta-mir-214	Bos taurus miR-214 stem-loop	GGCCUGGCUGGACGGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCGCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU	The mature sequence shown here was cloned by Gu et al. [2] and is consistent with that identified in rat (MIR:MI0000954) and zebrafish (MIR:MI0001381).  The mature product reported by Coutinho et al. is extended by two bases at the 5' end [1]. 	44
19105	MI0005041	bta-mir-22	Bos taurus miR-22 stem-loop	GGCUGAGCCGCAGUAGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGUUGCCCUCUGCC		44
19106	MI0005042	bta-mir-23a	Bos taurus miR-23a stem-loop	GGCCGGCUGGGGUUCCUGGGGAUGGGAUUUGCUGCCUGUCACAAAUCACAUUGCCAGGGAUUUCCAACCGACC		44
19107	MI0005043	bta-mir-29b	Bos taurus miR-29b stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG		44
19108	MI0005044	bta-mir-29c	Bos taurus miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA		44
19109	MI0005045	bta-mir-361	Bos taurus miR-361 stem-loop	GGAGCUUAUCAGAAUCUCCAGGGGUACUUAUAAUUUGAAAAAGUCCCCCAGGUGUGAUUCUGAUUUGCUUC		44
19110	MI0005046	bta-mir-423	Bos taurus miR-423 stem-loop	AUAAAGGAAGUUAGGCUGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGUCUUGCUUCCUACCCCGCGC		44
19111	MI0005047	bta-mir-425	Bos taurus miR-425 stem-loop	GAAAGCGCUUUGGAAUGACACGAUCACUCCCGUUGAGUGGGCACCCAAGAAGCCAUCGGGAAUGUCGUGUCCGCCCAGUGCUCUUUC		44
19112	MI0005048	bta-mir-450	Bos taurus miR-450 stem-loop	CAAAGAAAGAUGCUAAACUAUUUUUGCGAUGUGUUCCUAAUAUGUAAUCUAAAUGUAUUGGGAACAUUUUGCAUUCAUAGUUUUGUAUCAAU		44
19113	MI0005049	bta-mir-455	Bos taurus miR-455 stem-loop	UCCCUGGCGUGAGGGUAUGUGCCUUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGCCUA		44
19114	MI0005050	bta-mir-93	Bos taurus miR-93 stem-loop	CUGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUCACCUGACCUACUGCUGAGCCAGCACUUCCCGAGCCCC		44
19115	MI0005051	bta-let-7g	Bos taurus let-7g stem-loop	AGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCC		44
19116	MI0005052	bta-mir-10b	Bos taurus miR-10b stem-loop	CAGUGACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCAUGUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAAC		44
19117	MI0005053	bta-mir-24	Bos taurus miR-24 stem-loop	CUCUGCCUCCCGUGCCUACUGAGCUGAAACACAGUUGAUUUGUGCACACUGGCUCAGUUCAGCAGGAACAGG		44
19118	MI0005054	bta-mir-30a	Bos taurus miR-30a stem-loop	CUGUAAACAUCCUCGACUGGAAGCUGUGAGGCUGCAGAAAGGCUUUCAGUCGGAUGUUUGCAGCUGC		44
19119	MI0005055	bta-mir-200b	Bos taurus miR-200b stem-loop	CCAUCUUACUGGGCAGCAUUGGAUGGUGUCUGGUCUCUAAUACUGCCUGGUAAUGAUGA		44
19120	MI0005056	bta-mir-7	Bos taurus miR-7 stem-loop	AGACUGGAGCGGUUGUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUACUAUGACAACAAGUCACAGC		44
19121	MI0005057	bta-let-7a-1	Bos taurus let-7a-1 stem-loop	UGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUA		44
19122	MI0005058	bta-mir-150	Bos taurus miR-150 stem-loop	CCUCUCUCCUCACGGCCCUGUCUCCCAACCCUUGUACCAGUGUGUGUCUCAGACCCUGGUACAGGUACGGGGAGGCAGGGACCUGGGGGAUCCCAGCAGC		44
19123	MI0005059	bta-mir-342	Bos taurus miR-342 stem-loop	UGGAAGCGGGUGCGAGGCGAGGGGUGCUAUCUGUGGUUGAGGACACGGCAAAUGAAACUGUCUCACACAGAAAUCGCACCCAUCUCCUCGGCCC	The miR-342 mature product reported by Gu et al. is truncated at the 3' end [2]. 	44
19124	MI0005060	bta-mir-487b	Bos taurus miR-487b stem-loop	UUGGUACUUGGAGAGUGGUUAUCCCUGUCCUGUUCGUUUUACUCAUGUCGAAUCGUACAGGGUCAUCCACUUUUUCAGUAUCAA		44
19125	MI0005061	bta-mir-532	Bos taurus miR-532 stem-loop	GACUUGCUUUCUCUCUUACAUGCCUUGAGUGUAGGACCGUUGGCAUCUUAAUUACCCUCCCACACCCAAGGCUUGCAGGAGAGCCA		44
19126	MI0005062	bta-let-7f-1	Bos taurus let-7f-1 stem-loop	UCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGA		44
19127	MI0005063	bta-mir-122	Bos taurus miR-122 stem-loop	CCUUAGCAGAGCUGUGGAGUGUGACAAUGGUGUUUGUGUCCAAACUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGUUAGGC	The mature miR-122 sequence identified by Sonstegard et al [1] has an additional C base at the 5' end, which conflicts with the draft genome sequence. 	44
19128	MI0005064	bta-mir-30c	Bos taurus miR-30c stem-loop	CAGACUGUAACCAUGCCGUAGUGUGUGUAAACAUCCUACACUCUCAGCUGUGAGCUCGAGGUGGCUGGGAGAGGGUUGUUUACUCCUUCUGCCAUGGAAAACGUC	The mature miR-30c sequence identified by Sonstegard et al [1] has an additional G base at the 3' end, which conflicts with the draft genome sequence. 	44
19129	MI0005065	bta-let-7i	Bos taurus let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUA	The 5' terminal base of the mature let-7i sequence identified by Coutinho et al [1] is reported as C, which conflicts with the draft genome sequence that requires U as shown here.  The 5' end reported by Gu et al. is shorter by 7 nts [2]. 	44
19130	MI0005066	bta-mir-23b	Bos taurus miR-23b stem-loop	GGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCAC		44
19131	MI0005067	bta-mir-25	Bos taurus miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCCGGGCAUUGCACUUGUCUCGGUCUGACAGUGCCGGCC	The mature miR-25 sequence identified by Coutinho et al [1] has an additional A base at the 5' end, which conflicts with the draft genome sequence. 	44
19132	MI0005068	bta-mir-34c	Bos taurus miR-34c stem-loop	AGUCUAGUUACUAGGCAGUGUAGUUAGCUGAUUGCUAAUAAUACCAAUCACUAACCACACGGCCAGGUAAAAAGAUU	The mature miR-34c sequence identified by Sonstegard et al [1] has an A base at position 11 of the mature miRNA, which conflicts with the draft genome sequence that has G as shown here. 	44
19133	MI0005069	bta-mir-363	Bos taurus miR-363 stem-loop	UGUUGUCGGGUGGAUCACGAUGCAAUUUUGAUUAGUAUAAUAGGAGAAAAAUUGCACGGUAUCCAUCUGCGAAC		44
19134	MI0005070	mtr-MIR395c	Medicago truncatula miR395c stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUUUGGUCUAAUAUCCAUUAGAAAAGAUAGUCUUUUCUUCUAUGAAGUGUUUGGGGGAACUC		23
19135	MI0005071	mtr-MIR395d	Medicago truncatula miR395d stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUUUGGUCUAAAAUCCAUUAGAAAAAUAGUUCUUCUUAAAUGAAGUGUUUGGGGGAACUC		23
19136	MI0005072	mtr-MIR395e	Medicago truncatula miR395e stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUCUAUUUGGUUUAAAAUCCAUUAGGAUAGAUAGUUCUUCUUAAAUGAAGUGUUUGGGGGAACUC		23
19137	MI0005073	mtr-MIR395f	Medicago truncatula miR395f stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAAUAUCUCUUUGGUUUAAAAUCCAUUAGAAAAGAUAGUAUUUUCUUCUAUGAAGUGUUUGGGGGAACUC		23
19138	MI0005074	mtr-MIR395g	Medicago truncatula miR395g stem-loop	GAGUUCCUCUGAACGCUUCAUAUAAGAGGUUAUCCAUCUUCAUUGAAGUGUUUGGGGGAACUC		23
19139	MI0005075	mtr-MIR395h	Medicago truncatula miR395h stem-loop	GACUUUCUCUGAACACUUCAUACAAGAGGUUAUCCAUCUAAUCUAAAAGUCAUUAGAUAUUUACGAUGGGUCGUUCUUCAAUGAAGUGUUUGGGGGAACUU		23
19140	MI0005076	mtr-MIR395i	Medicago truncatula miR395i stem-loop	GAGUUCCUCUGAAUGCUUCAAUCAUGAGACAAUCUAUAUGAAUAGUUCUUGUUCAAUGAAGUGUUUGGGGGAACUC		23
19141	MI0005077	mtr-MIR395j	Medicago truncatula miR395j stem-loop	GAGUUCCUCUGAAUGCUUCAAACAUGAGACAAUCUAUAUGGAUAGUUCUUGUUCAAUGAAGUGUUUGGGGGAACUC		23
19142	MI0005078	mtr-MIR395k	Medicago truncatula miR395k stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAAUAUCUCUUUGGUUUAAAAUCCAUUAGAAAAGAUAGUAUUUUCUUCUAUGAAGUGUUUGGGGGAACUC		23
19143	MI0005079	mtr-MIR395l	Medicago truncatula miR395l stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUCUAUUUGGUCUAAAGUCCAUUAGAAAAGAUAGCCAUUUUUUCAAUGAAGUGUUUGGGGGAACUC		23
19144	MI0005080	mtr-MIR395m	Medicago truncatula miR395m stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUCUAUUUGGUCUAAAAUCCAUUAGAAAAGAUAGUUCUUCUUAAAUGAAGUGUUUGGGGGAACUC		23
19145	MI0005081	mtr-MIR395n	Medicago truncatula miR395n stem-loop	GAGUUCCUUUGAACGCUUCAUGCAUGAGAAUAUCUAUCUAUUUGGUCUAAAGUCCAUUAGAAAAGAUAGCCAUUUUUUCAAUGAAGUGUUUGGGGGAACUC		23
19146	MI0005082	mtr-MIR395o	Medicago truncatula miR395o stem-loop	GAGUUCCUCUGAACUCUUCAUCUAAAGGGCUAUAGCAAGAAAGAAAGGAAAAUCCUUGUAUGAUGAAGUGUUUGGGGGAACUC		23
19147	MI0005083	mtr-MIR395p	Medicago truncatula miR395p stem-loop	GAGUUCCCUUAAACAUUUCAUUAAGGACUCAAUUUCUUCUCUUCAACCUUGUUGAAGCGUUUGGGGGAACUC		23
19148	MI0005084	osa-MIR395m	Oryza sativa miR395m stem-loop	GAGUUCUCCUCAAAUCACUUCAGUAGAUAGCUAGCUAGGCUUCAUUGCAUUACACUGUUACAAAACUGUGAGCAUGGGGCCAAAAGCUAGUUGUAUAUAGUGAAGUGUUUGGGGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19149	MI0005085	osa-MIR395n	Oryza sativa miR395n stem-loop	GAGUUCCCUUCAAGCACUUCACGACGCACUAUUUAGAGAGUUGUUGUGAAGUGUUUGGGGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19150	MI0005086	osa-MIR395o	Oryza sativa miR395o stem-loop	GAGUUCUCUUUAAGCACUUCAUACGACACCAUUAUUGUUAGGGUUGUUAUGAAGUGUUUGGAGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19151	MI0005087	osa-MIR395p	Oryza sativa miR395p stem-loop	GAGUUCCCUUCAAGCACUUCACGUGGCACUAUUUCAAUGCGUACCGUGUGAAGUGUUUGGGGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19152	MI0005088	osa-MIR395q	Oryza sativa miR395q stem-loop	GAGUUCCCUUCAAGCACUUCACAUGACACUAUUUCAAUGUCUAUUAUGUGAAGUGUUUGGGGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19153	MI0005090	osa-MIR395v	Oryza sativa miR395v stem-loop	GAAUUCUCUUUAAGCACUUCAUACGACACAAUUAUUUCAAGGGUUGUUGUGAAGUAUUUGGCGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19154	MI0005091	osa-MIR395w	Oryza sativa miR395w stem-loop	GAGUUCUCUUUAAUCAUUUCACAUGGCACUAUUUUAAGGCCUACUGUGUGAAGUGUUUGGGGGAUUCUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19155	MI0005092	osa-MIR395r	Oryza sativa miR395r stem-loop	GAGUUCCCUUCAACCACUUCACGUGGCACUAUUUUAGGACCUACUAUGUGAAGUGUUUGGGGGAACUC	Four clusters of rice miR395 genes are found on chromosomes 4, 8 and 9, and the gene names have been rationalised to reflect this arrangement [1]. 	7
19156	MI0005093	mdv1-mir-M1	Mareks disease virus miR-M1 stem-loop	UUCCCCUUUUGCUUGUUCACUGUGCGGCAUUAUUACAUUUACACCGGUAAUGCUGCGCAUGAAAGAGCGAACGGAA		48
19157	MI0005094	mdv1-mir-M2	Mareks disease virus miR-M2 stem-loop	AAAAGAAAGUUGUAUUCUGCCCGGUAGUCCGUUUGUAAGGUCUUGGAACGGACUGCCGCAGAAUAGCUUUCUUG		48
19158	MI0005095	mdv1-mir-M3	Mareks disease virus miR-M3 stem-loop	GCGGCAUGAAAAUGUGAAACCUCUCCCGCUAGAAAUAGAAUCUGCUGGGGGGUUCACAUUUUUAAGUUGU		48
19159	MI0005096	mdv1-mir-M4	Mareks disease virus miR-M4 stem-loop	GAAGUUUAAUGCUGUAUCGGAACCCUUCGUUCGGUGACCACGAAUGGUUCUGACAGCAUGACCUUU		48
19160	MI0005097	mdv1-mir-M5	Mareks disease virus miR-M5 stem-loop	UCAUGAACCGUAUGCGAUCACAUUGACACGGUUUAAAAUACAUACGUGUGUAUCGUGGUCGUCUACUGUUUGUGG		48
19161	MI0005098	mdv1-mir-M6	Mareks disease virus miR-M6 stem-loop	ACGUCCUGGGAAAAUCUGUUGUUCCGUAGUGUUCUCGUGACACUAACUCGAGAUCCCUGCGAAAUGACAGUUUUCUCUGGGAAUUACAUCGUCCUGAUUGUCGCGACAUGGAAUGGAAGC		48
19162	MI0005099	mdv1-mir-M7	Mareks disease virus miR-M7 stem-loop	GGAGAACUGUUAUCUCGGGGAGAUCCCGAUCUCUCCUACCAGCAACUCGAGAUCUCUACGAGAUUACAGUUUUUGGGGGAAAUGUGUCCUCAGAACUGCUUAAUCGUAGAAGCUUCCUAG		48
19163	MI0005100	mdv1-mir-M8	Mareks disease virus miR-M8 stem-loop	AUUCCUACGGAAACCUAUUGUUCUGUGGUUGGUUUCGAUCUAUCGUUCUCGUACUGCGUGACCUCUACGGAACAAUAGUUUUCCAGGAGAUUUCCCGGUUUCGACUGCCGAAGCAUGGAA		48
19164	MI0005101	ath-MIR771	Arabidopsis thaliana miR771 stem-loop	UAAAUUCGUCAUGAGCCUCUGUGGUAGCCCUCACAAUGAUCUCAAUAGAGUGCAUGCCACGAUCUUGUAAAGACGUAGAUGAGGGCUCCUCAGGUGUUCAUGUCGAAUGUUAG		1
19165	MI0005102	ath-MIR472	Arabidopsis thaliana miR472 stem-loop	UCUGUAUGUAUGUAUGGUCGAAGUAGGCAAAAUCUCACCUUUCUAGCAGAUCAACAAUGAAUUUUGUGGAAUAGAUGUUGGAUUUGUAAGGUUUUGGUGUUUGCAAGUGUUGAGAUGCGCAAGAUUUGAGUAAGAUUUUUCCUACUCCGCCCAUACCAUACAUACACC	Lu et al. named this sequence MIR772 [1].  The sequence was later shown to be homologous to poplar MIR472 (MI:MI0002354), and so is renamed ath-MIR472 here [2]. 	1
19166	MI0005103	ath-MIR773	Arabidopsis thaliana miR773 stem-loop	AGGAGGCAAUAGCUUGAGCAAAUAAUUGAUUGCAGAAGUCCAUCGACUAAAGCUGUCACCUGUUUGCUUCCAGCUUUUGUCUCCU		1
19167	MI0005104	ath-MIR774	Arabidopsis thaliana miR774 stem-loop	UCAUUUCAGAUGGCUGUUUGGGUAACUAAUAUUUAAGAUUUUGGUCAAUUUAAGUUACCAAUUUAUAUAUUGGUUACCCAUAUGGCCAUCUCAAAUUU		1
19168	MI0005105	ath-MIR775	Arabidopsis thaliana miR775 stem-loop	UUUAAACGUUGCACUACGUGACAUUGAAACUGUCUUUCAACAUUCCAAUAUUUCAACUUUCGAAUACCCAAUAUUUGGUUUGUUCAAAGACAUUUUCGAUGUCUAGCAGUGCCAAUGUUUAAA		1
19169	MI0005106	ath-MIR776	Arabidopsis thaliana miR776 stem-loop	UUGGGAUUAUAGCCACGAACUCAAUAGAAUUCUUAAGAUCAUGUGAAAACGUUGACAAGAUCGUCUACGAUUUUCCAAGAUUCUAAGUCUUCUAUUGAUGUUCAUGGCUUUAACCUGA		1
19170	MI0005107	ath-MIR777	Arabidopsis thaliana miR777 stem-loop	AGAGAGCAACAAAAUCAGUGUGUAUUUGUUAAGACAAAUGUUUAUAUAAGUCGUCCAUGCGUUGUACAUUUAAUCUUAACUAAUACGCAUUGAGUUUCGUUGCUUUCU		1
19171	MI0005108	ath-MIR778	Arabidopsis thaliana miR778 stem-loop	CCGCCUUGGCUUGGUUUAUGUACACCGAGUAUGUUCAGCUCCAUCCUAUACAGAUUUUGGGACAUGUGCCUAGGGUUGAGGUUUCAUAUAUAGAAAGAACUGAACAAACUCGGUGUACAUAGACCAAACCAAGGCGGU		1
19172	MI0005109	ath-MIR779	Arabidopsis thaliana miR779 stem-loop	AAUGAGAGUAAUAUAGUUGAAUCUUCGAAAGUAUUUCAAGAAGUCAGCUGAGCUUUCUCGUCAUCACUUAUUAGUAAAUAUAGUCUCUAUAUUUUUGAUGAGUGAUGAUUGGAAAUUUCGUUGACUCAUUACUCUUGAUGAUUCUGCUAUGUUGCUGCUCAUU		1
19173	MI0005110	ath-MIR780	Arabidopsis thaliana miR780 stem-loop	CAAGAUAUCAGAUAUUUCACGAAGAUAUCUGCAUAACAGCUACGAGGAAAUUGUGAUUUUAUCGUUUCACAAACAUCAACAGCUCCAUGGAUCGUUAUGGACGGAUAAAUCACAAUCACUAUCCUUUUUCUAGCAGCUGUUGAGCAGGUUUCUUCGUGAAUAUCUGGCAUUUUG	Fahlgren et al [2] identify two mature products from the same arm of the hairpin precursor, named here miR780.1 and miR780.2.  miR780.2 corresponds to the sequence reported by Lu et al [1]. 	1
19174	MI0005111	ath-MIR781	Arabidopsis thaliana miR781 stem-loop	UCAAAUUAGAGUUUUCUGGAUACUUAUUAGUUACUAACAAAGAGAGGGCUUCUUCGAUAUUAACUUUUAAGUAUCCAGAAAACUCUAAAUUUGA		1
19175	MI0005112	ath-MIR782	Arabidopsis thaliana miR782 stem-loop	AACCUUUUUCUACAAACACCUUGGAUGUUCUUUAAAUAAGAUGAAAAGGCUAUUAUUCUAAUGAACAACAUGAAGCCAAAAGAAAAUCCAAGGCGUUUGCAGAAAGAGGUU		1
19176	MI0005113	ath-MIR783	Arabidopsis thaliana miR783 stem-loop	GACACUAGUCUUAACCAUAUCUUUUGUCGGAAGAUUCAGGAGAACAUGGAAGAGCAAAGAUUCUAGCAAAUCUCUUACCCAAUCAACUUCAUCACCAGAUCUUUUGUCGGAAAAUUCAGGAGAACAUGAUCGUUUGGUACGAAUACAAGAUCUGGUGAGAAUGGACGAAGAAGGAAAGAGAGACGUGUUCGUACCAAACGAUCAUGUUCUCCUGAAUCUUCCGACAAAAGAUCUGGUGAUGAAGUUGAUUGGUUAAGUGAUUUACCAGAAGCUUUGCUCGUUCAUGUUCUCCUGAAUCUUCCGACAAAAAAUGUGGUUAAGACUAGUGUCU		1
19177	MI0005114	ptc-MIR171k	Populus trichocarpa miR171k stem-loop	GAUACUGGCUCGGUUCAACCUCAUCGUAGUCUUGAUGAAUGAUUCAAAUCUAUGGUUGGAUUGAGCCGCGCCAAUAUC	This sequence is a predicted homolog of a verified miRNA in Arabidopsis (E. Bonnet, pers. comm.). 	26
19178	MI0005115	ptc-MIR403c	Populus trichocarpa miR403c stem-loop	GGUUUGUGCGUGGAUCUGAGGCCAUCACAACCGUCCACUACACGACCACCCAAUGGCUUUAGAUUCACGCACAAACUCG	This sequence is a predicted homolog of a verified miRNA in Arabidopsis (E. Bonnet, pers. comm.). 	26
19179	MI0005116	hsa-mir-765	Homo sapiens miR-765 stem-loop	UUUAGGCGCUGAUGAAAGUGGAGUUCAGUAGACAGCCCUUUUCAAGCCCUACGAGAAACUGGGGUUUCUGGAGGAGAAGGAAGGUGAUGAAGGAUCUGUUCUCGUGAGCCUGAA		5
19180	MI0005117	hsa-mir-768	Homo sapiens miR-768 stem-loop	CUGUGCUUUGUGUGUUGGAGGAUGAAAGUACGGAGUGAUCCAUCGGCUAAGUGUCUUGUCACAAUGCUGACACUCAAACUGCUGACAGCACACGUUUUUCACAG		5
19181	MI0005118	hsa-mir-770	Homo sapiens miR-770 stem-loop	AGGAGCCACCUUCCGAGCCUCCAGUACCACGUGUCAGGGCCACAUGAGCUGGGCCUCGUGGGCCUGAUGUGGUGCUGGGGCCUCAGGGGUCUGCUCUU		5
19182	MI0005119	sme-bantam-a	Schmidtea mediterranea bantam-a stem-loop	UAUUGGUUUUACUAGUGAUCUAAGAAUGAUAUAUAAAAAUCUGAGAUCACUAUGAAAGCUGGUA		47
19183	MI0005120	sme-bantam-b	Schmidtea mediterranea bantam-b stem-loop	CUUUAAAAACCGGUUUUCGUUGAGAUCUUAGAUAUAUUCAUCUGAGAUCACUGCGAAAGCUGAUUAUGAAGUCGCUUUC		47
19184	MI0005121	sme-bantam-c	Schmidtea mediterranea bantam-c stem-loop	UAGUUUAAAGGCUUUCAUUAUGAUUUUAAAAUGUUAUUUUGAGAUCAUUAUGAAAGCUUUUUACUG		47
19185	MI0005122	sme-let-7a	Schmidtea mediterranea let-7a stem-loop	AUCAAAUUCAUGAGGUAGAAUGUUGGAUGACUAAGGUAAAGGUAACAUAUCAGAGCUGUUCAAUUUUCUGCCUUUAAAAUUUGAU		47
19186	MI0005123	sme-let-7b	Schmidtea mediterranea let-7b stem-loop	GUAACAUUAACAAUUGAGGUAGAUUGUUGGAUGACUUAAUUUUAAAGCCAUUCAACUAUCUGUCUUCUCUUGUUAAAUUAC		47
19187	MI0005124	sme-let-7c	Schmidtea mediterranea let-7c stem-loop	UCAUACUAACUAGAUGAGGUAGUGACUCAAAAGGUUGAAGAAAUACAUCAAAUGGAGUAAAACCUUUUGUUUCUCUAGCUUUAUCAGUUAUAUGA		47
19188	MI0005125	sme-lin-4	Schmidtea mediterranea lin-4 stem-loop	AUCAGUUAUAAUCUCCCUGAGACCUUCGACUGUGUUUGACCAUUAAAUUAUCAGAAAUGAUUGCACAGUCGAUGAUCAUAGGGUUAAAAUAGCCGAU		47
19189	MI0005128	sme-mir-1a	Schmidtea mediterranea miR-1a stem-loop	AGCGAGCAUUUUUCGAGGCAUUUCAUAGAGUCAAAUGAAAAUAAACCUGUGGAAUGUCGAGAAAUAUGCAUGCU		47
19190	MI0005129	sme-mir-1b	Schmidtea mediterranea miR-1b stem-loop	AACAACACACGGGCAUAAUUCAAGAUAUUCGAUAGGGUUUUUGGUAACUAAUGGAAUGUCGUGAAUUAUGGUCUUCAUUGUU		47
19191	MI0005130	sme-mir-1c	Schmidtea mediterranea miR-1c stem-loop	GUUACGUGAGGUGCACAUUAUUCAAAACAUUGAAUCACAUCGAACUGUGGAAUGUUGUGAAUAGUGUCACAGACGUAAU		47
19192	MI0005131	sme-mir-2a-1	Schmidtea mediterranea miR-2a-1 stem-loop	GUUCAUUUAUGUGAGUUCCAGUGUGCUAUGAUGUAUAUUUCUAAAAAUUUCUAUAUAUCACAGCCCCGCUUGGAACGCUAAUUAAUGAAU		47
19193	MI0005132	sme-mir-2a-2	Schmidtea mediterranea miR-2a-2 stem-loop	GUUCACUUAAUUGAGUUCUACGGUGUUGUGAUAUAAUGAUUAUUUAUAUCACAGCCCCGCUUGGAACGCUAAAAUAUGAAU		47
19194	MI0005133	sme-mir-2b	Schmidtea mediterranea miR-2b stem-loop	GGUUAUUGCUUUCAUCAUUGUUGGUUGUCAGUUAUUGUAUUCAAUAUCACAGCCAAUUUUGAUGAGAUGAGAUAGCU		47
19195	MI0005134	sme-mir-2c	Schmidtea mediterranea miR-2c stem-loop	UUUCUUUUUCAAAUACAAAAAUCAUCAAUUUGGUCUGUUAUAAAUGGCUUUUAUCACAGCCAAAACUGAUGAUCUUAUAAAUUUGUCAAACAU		47
19196	MI0005135	sme-mir-2d	Schmidtea mediterranea miR-2d stem-loop	GUGACAUUUUGCCUCUUACGGACAUCAUUAUUUGACUGUCGAUAGAUAUUGGUAACAUUAUUUUGGUAGUAUCACAGCCAAAUUUGAUGUCCUAAAUAAGGUAGUCAC		47
19197	MI0005136	sme-mir-7a	Schmidtea mediterranea miR-7a stem-loop	CAUAAUUUGGAAGACUAUUGAUUUAGUUGAAUUGGUUAAUUUAGUUUCAACUGAUUCUAGUCAUCCUUAUG		47
19198	MI0005137	sme-mir-7b	Schmidtea mediterranea miR-7b stem-loop	GGAAUAACACAGAAAAAUAAUCAUGGAAGACUGUCGAUUUCGUUGUCAGAGCAUUUUUAAAUGUAACAACGAUUUUGAUAAUCUUCCUGGAUUUUUUUGUUGAAACUUCU		47
19199	MI0005138	sme-mir-7c	Schmidtea mediterranea miR-7c stem-loop	UGAAUAAGUUUAAUAUUUUGUGGAAGACUGAUGAUUUGCUGAACGCAUGCAGCCAGCGGGUCUUCUUUCUUCUCAUUAUAUUUUAUUAAUCA		47
19200	MI0005139	sme-mir-8	Schmidtea mediterranea miR-8 stem-loop	AAUGACAUCGAAUCAGACAGUUUAAGACAGAAUUUAAUAAAAUCUAAUACUGUCAGGUAACGAUGCCAUU		47
19201	MI0005140	sme-mir-10	Schmidtea mediterranea miR-10 stem-loop	CUGUCACCGAUCUGAACCCUGUAGAUCCGAGUUUGAUUAAUGCCAAUGUUGAGUUUUGAAGCAUUUCAAUCAAAAUCGAAUCUUCAAGGUGAAGCUGGUGAUAG		47
19202	MI0005141	sme-mir-12	Schmidtea mediterranea miR-12 stem-loop	AUUUUAUCCAUCGCUCACUGAGUAUUCUAUCAGGAGUCGAAAAAUGCGUUAAGUUAACUAACGUUUCGUCUCUUGAUGGUUUACUUAAUAAGCAAAGGAUUUUU		47
19203	MI0005142	sme-mir-13	Schmidtea mediterranea miR-13 stem-loop	GAGCCUUUGGCGGCUGUGAUAUGAUAAUUAUAUCAUAUCACAGUCAUGCUAAAGAGCUU		47
19204	MI0005143	sme-mir-745	Schmidtea mediterranea miR-745 stem-loop	AUUAACUCUGUGAUGAUACGCUCUUACCAGCUAGAAUGCUGAUAAUUUACCACAUGCUGCCUGGUUAAGAGCUGUGUCAAACACCUUUCAAAC		47
19205	MI0005144	sme-mir-746	Schmidtea mediterranea miR-746 stem-loop	UGAUAAUUCGCAUAACAUCUAGCCGGAUAAAUCCUGUGUGCAUUGAUAGAAAGUGAAAUGAUUUUAUUCAUAAGAUCUACCAUAUCUAGCACCAGGGUAUAUCGGGAUUGAAACGAACAUGAUCAUCA		47
19206	MI0005145	sme-mir-31a	Schmidtea mediterranea miR-31a stem-loop	UUUUAUUGUUAUGUUUUAAGGCAAGAUGUUGGCAUAACUGACAACAAUUCGAAAGGAUUAAUUUCAGUUACGUUAGCACUUACCAGAUAGCAAAACAAA		47
19207	MI0005146	sme-mir-31b	Schmidtea mediterranea miR-31b stem-loop	AUUGAUAAUGACAAGGCAAGAUGCUGGCAUAGCUGAUAAACUAUUUAUUACCAGCUAUUCAGGAUCUUUCCCUGAAUAUAUCAAU		47
19208	MI0005147	sme-mir-36	Schmidtea mediterranea miR-36 stem-loop	AGCCACAGUGUUUUGAUGCAUGCUACUUGGUUUUGUUGUUAUUAUAUUAACAUCACCGGGUAGACAUUCAUUAUACAACUGUUGUU		47
19209	MI0005148	sme-mir-61	Schmidtea mediterranea miR-61 stem-loop	UUUUUAGAAUAGAAACUCUUGAUACAGUUUGUGAGUUUCUAGGCAUAUAGAUUUUUCUAUGACUAGAAAGUUCACUUACUGUUGUACGAGUUUUAAACUUCAUU		47
19210	MI0005149	sme-mir-71a-1	Schmidtea mediterranea miR-71a-1 stem-loop	AUUUUAAAUGCAUGAAUGAAAGACACGGGUAGUGAGAUAAGCUAUAUAUCAUCUCAUUGCCAAUGUCUUUUAAACGUGUUAUUU		47
19211	MI0005150	sme-mir-71a-2	Schmidtea mediterranea miR-71a-2 stem-loop	UUGGAUAUAACUGAAAGACACGGGUAGUGAGAUAUGGAUUUUUCAUCUCUAUAUUCGUGUCUUUCAUAUUUAUUCACG		47
19212	MI0005151	sme-mir-71b	Schmidtea mediterranea miR-71b stem-loop	UGAUUCAGUACUCUUUGAAAGACACAGGUAGUGGGACAGAUAUUAUCUAAUAAAAGCUUGUCCUUCUAAUGUGUUUUUCGAAAACCAUUGAAUCAAUCAU		47
19213	MI0005152	sme-mir-71c	Schmidtea mediterranea miR-71c stem-loop	GUAGUUUUCUUGAAAGACAUGGGUAGUGAGAUUAUUUAAAUUAAAUAUUUAAAAUCUCAUUAUUCAAGUUUUUCUUAUAAGC		47
19214	MI0005153	sme-mir-79	Schmidtea mediterranea miR-79 stem-loop	UUGAAACAUAAUCUCUUCUUUGGUCAUCUGGCUUUGUGAUAGAGAAAUUAUCAUCGUAAAGCUAAAUUACCAAAGUGCUAGAAAAUGUUGGAU		47
19215	MI0005154	sme-mir-87a	Schmidtea mediterranea miR-87a stem-loop	UUUGCCAGUAUUUCAACACUUGGUAAUUUGCUCAAACCAAUGUCCGAAAAGGAGUCUGGUGAGCAAAGUUUCAAGUGUAUAUAUGUGGCAUUAAA		47
19216	MI0005155	sme-mir-87b	Schmidtea mediterranea miR-87b stem-loop	UUCAUUGAUGCGUUGAUGCUUCAUUCGAAAUUUUGCUCAAAUCCAUUUUGAUAAUAAUAAUUUUCGAUGGUGAGCAAAGCUUCAAAUGAGAUUUCACGGAAUUCGGUC		47
19217	MI0005156	sme-mir-92	Schmidtea mediterranea miR-92 stem-loop	AAUUGCUAAAUGGUAAAUAUCUAGUGCAAGUCUACAGGUGAAUUUCUUUUUAGAUUGCACUAGUUAAUUAUCAUCAUACAAUUU		47
19218	MI0005157	sme-mir-124a	Schmidtea mediterranea miR-124a stem-loop	UUCAAUCAGAUGUGCUUUUAACGCGGAGCUUUAGUAAUUUAACAUGUAUACUAAGGCACGCGGUGAAUGCUUACUUGAUUGAG		47
19219	MI0005158	sme-mir-124b	Schmidtea mediterranea miR-124b stem-loop	GUAUCCAUGAAAAUUUGCAUUUACAACGUGUCUUUAGUUCAUGUGACACUAAGGCACGCGGUGAAUGCUGAAUUAAAUGGUUUA		47
19220	MI0005159	sme-mir-124c	Schmidtea mediterranea miR-124c stem-loop	UGAUCCUAUUCUUUACUAGCGCUCACCUCGUGACCUUUGUCAGUGUUGGACUAAGGCACGCGGUGAAUGCCAGAUGAAAGGAUGA		47
19221	MI0005160	sme-mir-125a	Schmidtea mediterranea miR-125a stem-loop	CUGUUGUCUGUAUUUAUAUCCCUGAGACCAUUGACUGCAUUUGUUUGAGGUUUCAAUGUAGUUUUUGGUAUCAGGAUUGUGGAUAUGGAGCAUUC		47
19222	MI0005161	sme-mir-125b	Schmidtea mediterranea miR-125b stem-loop	GCAAGUUAUUCGACAUCCCUGAGAUCAUAAUAUGCCUGAGAUUUGAACGCAAACCGGUAGAUUAUUGUCUCAGAGUAAUUGAUAAACUGCA		47
19223	MI0005162	sme-mir-133	Schmidtea mediterranea miR-133 stem-loop	AAAACACUUUUGUAUUUGCUGCUAGAUGGUGAAUCAAAACCGUUUGGGUCUUGGUCCCCAUCAACCAGCAAUUUUCAAGUGUUUAUC		47
19224	MI0005163	sme-mir-184	Schmidtea mediterranea miR-184 stem-loop	GAUUUUCAUUAACUCCUUUGUGUAUCUCCGUUUCACAUUUAUUAUAUCAUUUAUACUGGACGGAGGUUUGCUAAGGAAUAUUUGAAAAUU		47
19225	MI0005164	sme-mir-190a	Schmidtea mediterranea miR-190a stem-loop	GAUUAACUUCGAGAUAUGUUUGGUUAAUUGGUGAUAGGUAACCACCACUGACCGAGCAUAUCCAGUUGUUAAUU		47
19226	MI0005165	sme-mir-190b	Schmidtea mediterranea miR-190b stem-loop	GCACUUCAAAUCGUGAUAUGUUUGGUUUAUUGGUGAGUGUAAACUGAUUUCUAACACCAUUAGCCUAAUGUAUCGUGUCAUUGAGUGC		47
19227	MI0005166	sme-mir-747	Schmidtea mediterranea miR-747 stem-loop	UCAGUUCUGUUCAUAAUCUCAUCUGGUAAUUGAAGUGAUCUAUUUUUUAAAAAAAGAAACUUCAUUAUCAUUUCAGAUUGUAAUCGAAAUGA		47
19228	MI0005167	sme-mir-219	Schmidtea mediterranea miR-219 stem-loop	CGGUAAUUUAUUGCUGAUUGUCCAUACGCAGUUCUCAAGGUCUAGAAUCGACGAAUUGCCGUUUAAGAAUUGCGAAUGGUCAUCAACAAUAAUUGCUG		47
19229	MI0005168	sme-mir-277a	Schmidtea mediterranea miR-277a stem-loop	UGGUAAACUGUUUUCUUUACGUAUUCGUUGGAGCAUUUUUACAAACAAAAUGUAUAAAUGCACUAUCGGAUAUGACAUAGAUACAGUUUAA		47
19230	MI0005169	sme-mir-277b	Schmidtea mediterranea miR-277b stem-loop	GGUUGUAUUGAUCUUGAUCAGAAAUGCAGCUUCAGAGAAAUCACUGUGAAAAUGCAUUAUCUGGCCAAGAAAAUGAAGCCU		47
19231	MI0005170	sme-mir-277c	Schmidtea mediterranea miR-277c stem-loop	AUCAUUUAUAUUAAUCAUAUCAGAUUUGCAUUAUUAUUAUGAAUUAAACAUCAAUAAAUGCAUUAUCUGGUAUGAUAUUUGAAAUGAU		47
19232	MI0005171	sme-mir-278	Schmidtea mediterranea miR-278 stem-loop	GGUCGUGAUCUUUGACUUCGAAUGCUAUUUUCACCAGAUGCUUGUUCAAGUUCAACAGUCAAGCUCGGUGGGAGUAACAUUCGAAAUUAAUUACGAUC		47
19233	MI0005172	sme-mir-281	Schmidtea mediterranea miR-281 stem-loop	UUACAGCUUACAAUGAAGAGCUAUUCAUGAGGUGCAGUAUAAUGACAAUUUCAUCUGUUCCCCAUGUCAUGGAUAUGCUCUUCAUAAAAGCUAUAA		47
19234	MI0005173	sme-mir-67	Schmidtea mediterranea miR-67 stem-loop	GUGUAAUAUUAGCCUCAUUCUAUGGGUUGUUAUGAUGCAAUAUCAUCACAACCUCCAUGAACGAGGGUAAUCGACAUG		47
19235	MI0005174	sme-mir-748	Schmidtea mediterranea miR-748 stem-loop	CAAUCACAUUAUGUCCUUAUUAUAUUGCUGUCAAGUAAGCACUACUGGACGGAAGUGUAAUGAGGGUAAAAUUGUGAAA		47
19236	MI0005175	sme-mir-749	Schmidtea mediterranea miR-749 stem-loop	AUCGCUGGGAUGAGCCUCGGUGGUCCGGGGUGCAGGCUUCAAACCUGUAGUCGGUUGACACCGAAGUGGUUCGAUUCCACCUUUCCAGCGAU		47
19237	MI0005176	sme-mir-750	Schmidtea mediterranea miR-750 stem-loop	AUUGAAAUCAGAUUUUCAGCACUGGAAGGUUUGGUUUAGCUGCUGUGCACCGUCAUGUCGACACAGUCAGAUCUAACUCUUCCAGUUCUAAAGCUGAUAGCGAAC		47
19238	MI0005177	sme-mir-751	Schmidtea mediterranea miR-751 stem-loop	ACUAAUUUUGUUUUCUUGUAAACUCCGAUAGAAUGAUUCAUAAGAUUGACUAUAAAACAUGUUUGAAUGGCCAUGACAAAGUAUU		47
19239	MI0005178	sme-mir-752	Schmidtea mediterranea miR-752 stem-loop	AUUGAUUAUAGUUAUCUAAUUUGAAAACCUCCAAAGUGAUUGUGAAUAAAAGUUUUAUUAAUUUAAUCACAGUCAGCAUUGGUGGUUUGAAAGUAGAGUGAUCUUACAAUCGAA		47
19240	MI0005179	sme-mir-753	Schmidtea mediterranea miR-753 stem-loop	UAAAGUAUAUUUUAGAGCUUGGAUUGUGAUCUCAUAUAUUUAUGAGAUCAUUAUUCAAGCUCUUAAAUAAUACUUUU		47
19241	MI0005180	sme-mir-754	Schmidtea mediterranea miR-754 stem-loop	ACCCAGCAUGUUGCUUGGGGUUAUUACUAUAUUUAUUAAUAUAGUUUUAUCUUCAAGCAAUAUCAGAUGAGGA		47
19242	MI0005181	sme-mir-755	Schmidtea mediterranea miR-755 stem-loop	UUUCUGUAGUGGAGCUAUUGUAUUUCACCGUGGUUGGCUAUCGUGAGAUUCAAUUACUCCAACUACGAUUUA		47
19243	MI0005182	sme-mir-756	Schmidtea mediterranea miR-756 stem-loop	UAAAAGUUGGGAUAAAUCGAUAUGUGGUAAUUUGGAUGACAUAAUUAACUUUGUAAUCUCAUCCAUCUUAUCAUUUAUCAAAAUAUUCUGACAUG		47
19244	MI0005183	sme-mir-277d	Schmidtea mediterranea miR-277d stem-loop	AAGCAUCAAAAAUGUUGGUUAGUUGUGCAUUUUCAUUAAAUAUUAUGUAAAUGCAUUUAUCUGGCCAAGAAAUAGUUGCUU		47
19245	MI0005184	cel-mir-784	Caenorhabditis elegans miR-784 stem-loop	UUCGACGUCCACGUGGCACAAUCUGCGUACGUAGAAAGAUCAAAAAGUCACUUCUAUGUACAAAUGUUGCGCUGCCUGGCACAGUGAA		3
19246	MI0005185	cel-mir-785	Caenorhabditis elegans miR-785 stem-loop	GCUCUUUUUCUCACCCAUCAGCACAGAAUUUUUCGCUAACAGAAACCUCAAAACAAUGUAAGUGAAUUGUUUUGUGUAGAUGGUGGAAAUGAGC		3
19247	MI0005186	cel-mir-786	Caenorhabditis elegans miR-786 stem-loop	GGGAUAGUUCCCGAUCGAAUAUCAGUUGGGGUAUUUACAAAAAGACAAAAUUGUAAUGCCCUGAAUGAUGUUCAAUCGGUGAUGAAUCUC		3
19248	MI0005187	cel-mir-787	Caenorhabditis elegans miR-787 stem-loop	GAUGUAUCAGUGGACGAAAGAUACAUACGAUCUUACAUCUUCAAAAUGGUAUGUAAGCUCGUUUUAGUAUCUUUCGUCUCUGAUCACAUU		3
19249	MI0005188	cel-mir-788	Caenorhabditis elegans miR-788 stem-loop	GCUCACUUUUCCGCUUCUAACUUCCAUUUGCAGAGUUCAAGUAAUCUGGAAAUGGAUUAGAAUCGUGGAAAAGUUAGU		3
19250	MI0005189	cel-mir-789-1	Caenorhabditis elegans miR-789-1 stem-loop	UGUCCUGAAGGCAGGCAAUUGAUGACCCAGACAAGGACUAAUCAAGAUUGUCGAUCUAGUCCCUGCCUGGGUCACCAAUUGUCGGCCCCCGCGGGCA		3
19251	MI0005190	cel-mir-789-2	Caenorhabditis elegans miR-789-2 stem-loop	UGUCCUGAAGGCGGACAAUUGAUGACUCAGGCAGGGACUAAUCAUGAUUGUCGAUUUAGUCCCUGCCUGGGUCACCAAUUGUCGGCCCCCGCGGACA		3
19252	MI0005191	cel-mir-790	Caenorhabditis elegans miR-790 stem-loop	GCCGGCUUGGCACUCGCGAACACCGCGAUUUCACUUAUAACUCGCGGCGUUAGCUCUGUGUCAAACCGGC		3
19253	MI0005192	cel-mir-791	Caenorhabditis elegans miR-791 stem-loop	GAACCUUCGAUUACCUUAUCCGUUGUAGCCAAAGUUCAACGAAGCGGCAACUUUGGCACUCCGCAGAUAAGGCAAUCGAUUGUUU		3
19254	MI0005193	cel-mir-792	Caenorhabditis elegans miR-792 stem-loop	AAGUUGGUCAACGUUUGAGAGUUCAAAAGAUUUAGCAAUUUUAUACGAGUGAAAUUGAAAUCUCUUCAACUUUCAGACGUUUUCUGAUUU		3
19255	MI0005194	cel-mir-793	Caenorhabditis elegans miR-793 stem-loop	UGGUUGGUAAAAGUCUGUUUAACUAUUGUACAUCACAAUUUUCACUGCGAAAAAUUGAGGUAUCUUAGUUAGACAGACAUAUACUACAACCA		3
19256	MI0005195	cel-mir-794	Caenorhabditis elegans miR-794 stem-loop	CUGAGCGUGUCUCUUGAGGUAAUCAUCGUUGUCACUUCGCAAAGUUGGAAUUGAAAACGUUGUCUAUCUCGAAAGGCUUAUCAG		3
19257	MI0005196	cel-mir-795	Caenorhabditis elegans miR-795 stem-loop	GAAACGUUACCUGCUGAGGUAGAUUGAUCAGCGAGCUUGAUACCCCGUUCAAAAUCGUGAUCAGUAUACUUCGUCAGGCAGCUUGUUUU		3
19258	MI0005197	cel-mir-796	Caenorhabditis elegans miR-796 stem-loop	ACUCUAAUGACAAGCUGGAAUGUAGUUGAGGUUAGUAAAAGCACUAUACUUGUUACAAACCUUGCCACGUUCCGACUUGUCAAAAGAGU		3
19259	MI0005198	cel-mir-797	Caenorhabditis elegans miR-797 stem-loop	CGUCCAAUGGACGAUAUCACAGCAAUCACAAUGAGAAGAAUACAUCUAGAUACUCUUUUCAUUGGUUUCUGUGAAAUCGUAUUUGAAUG		3
19260	MI0005199	cel-mir-798	Caenorhabditis elegans miR-798 stem-loop	UACUGUUUCAUGUAGGUGUUAAAGUUUGUACAAGAAGUUAGUUUUCUGUUAAGCCUUACAUAUUGACUGAGCAGUA		3
19261	MI0005200	cel-mir-799	Caenorhabditis elegans miR-799 stem-loop	GUUUUUCAAUUUUUUUCACCGGUUUUAAAAAGUGGUUUCACAUUCAAUAAAGACAUGUGAACCCUGAUAAAGCUAGUGGAAAUAUCGGAAAAC		3
19262	MI0005201	cel-mir-800	Caenorhabditis elegans miR-800 stem-loop	ACGGCGGCUGACAAUUUCCGAGUUAGGCCACUCUUAUAAUCAGUGGCCAAACUCGGAAAUUGUCUGCCGCCGU		3
19263	MI0005203	mmu-mir-804	Mus musculus miR-804 stem-loop	CCCUACACAUCCAUCUUUGAGGUUACAACUUCCCCAGUAGACUGUUUCCUGACAUUCCUUGUGAGUUGUUCCUCACCUGGAAGAUGUGGUGGCGG		6
19264	MI0005204	mmu-mir-805	Mus musculus miR-805 stem-loop	GUCAUAUUUUGGGAACUACUAGAAUUGAUCAGGACAUAGGGUUUGAUAGUUAAUAUUAUAUGUCUUUCAAGUUCUUAGUGUUUUUGGGGUUUGGC		6
19265	MI0005205	mmu-mir-741	Mus musculus miR-741 stem-loop	UUGAUCUACGUAGAUUGGUACCUAUCAUGUAAAUCAUGUAAGCAUGAGAGAUGCCAUUCUAUGUAGAUUAA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
19266	MI0005206	mmu-mir-742	Mus musculus miR-742 stem-loop	UGCUCUACUCACAUGGUUGCUAAUCACGUGAAGUGUAGGUGAAAGCCACCAUGCUGGGUAAAGUA		6
19267	MI0005207	mmu-mir-743a	Mus musculus miR-743a stem-loop	CUGUAUUCAGAUUGGUGCCUGUCAUGUUUAUAAGAAUGAAAGACACCAAGCUGAGUAGAGUA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	6
19268	MI0005209	osa-MIR807a	Oryza sativa miR807a stem-loop	AACCACACUAUCAAUAAAUAGAUUCACCCGUGAGAUGACUUGGUUGUUCCACAUAGGACAAUGACAUGCAUCCUAUUACCAGCCAUCUCAUGAAAUUAAUAGGAUGCCACGUCGACUUGGUUGUUCCACAUAGGACAAUGACAUGCAUCCUAUUACCAGCCAUCUCAUGAAAUUAAUAGGAUGCCACGUCCUCAUCCUAGGUAAAAUAACCACGUCAUCUCACAGGUGAAUCCAUUCAUUGAUAUUGUGGUU	miR807 was misnamed miR562 by Luo et al [1]. 	7
19269	MI0005210	osa-MIR806a	Oryza sativa miR806a stem-loop	UACGUAUAUACUCUCUCCGUUUCAAAAUGUUUGACACCGUUGACUUUUUAAAUACGUGUUUGACCAUUCGUCUUAUUCAAAAAAUUUAAGUAAUUAUUUAUUCUUUUCAUACAUUUGAUUCAUUGUUAAAUAUACUUUCAUGUACACAUAUAGUUUUACGUAUUUCAAAAAAAAAUUUAAUAAGACGAACGGUUAAACAUGUGCUAAAAAGUCAACGGUGUCAAACAUUUUAAAACGGAGGGAGUAUUUGUG	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19270	MI0005211	osa-MIR806b	Oryza sativa miR806b stem-loop	UCAAAAUGUUUGACACCGUUGACUUUUUAAGUACGUGUUUGACUAUUCGUCUUAUUCAAAAAAAUUUAAGUAAUUAUUUAUUCUUUUUAUAUCAUUUGAUUCAUUGUUAAAUAUACUUUCAUGUACACAUAUAAUUUUACAUAUUUCACAAAUUUUUUUUAAUAAGACGAACAGUCAAGAAUGUGCUAAAAAGUCAACGGUGUCAAACAGUUUGA	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19271	MI0005212	osa-MIR806c	Oryza sativa miR806c stem-loop	GAAGAUAGCUUGUAAUGUACUCCCUCCGUUUCAAAAUGUUUGACACCGUUGACUUUUUAGUACGUAUUUGAUCAUUCGUCUUAUUCAAAAAAUUUAAGUAAUUAUUUAUUUUUUUCAUAUCGUUUGAUUUAUUGUUAAAUAUACUUUCAUGUACACAUAUAGUUUUACAUAUUUCAUAAAAUUUUUUGAAUAAGACGAAUGGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAACAUUUCGAAACGGAUGGAGUAUUUAUUGUAACUUU	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19272	MI0005213	osa-MIR806d	Oryza sativa miR806d stem-loop	CUCCCUCCGUCCGAAAUACUCCCUCCUUUCAAAAUGUUUGAUACCGUUGAGUUUUUAAUACGUGUUUGACCAUUCGUUUUAUUCAAAAAAUUUAAAUAAUUAUUUAUUCUUUUCAUAUCAUUUGAUUCAUUGUUAAAUAUACUUUCAUAUGCACAUAUAGUUUUACAUAUUUCACAAUUUUUUUAGAAUAAGACUAACGGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAACAUUUUAAAACGGAGGGAGUAUAAGGGAUUUUAGGUGG	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19273	MI0005214	osa-MIR806e	Oryza sativa miR806e stem-loop	UUAGGUAAUACUCCAUCCGUUUCAAAAUGUUUGACGCCGUUGACUUUUUAGCAUAUGUUUGACCGUUCGUCUUAUUCAAAAAAUUUAAGUAAUUAUUAAUUCUUUUCUUAUCAUUUAAUUUAUUGUUAAAUAUAUUUUUAUGUAGGCAUAUAAUUUUACAUAUUUCACAAAAGUUUUUAAAUAAGACGAACGGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAAUAUUUCGAAACGGAGGGAGUGUGGUUUAG	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19274	MI0005215	osa-MIR806f	Oryza sativa miR806f stem-loop	AUACUCCCUCCGUUUCGGAAUGUUUGACGCCGUUGACUUUUUAUUACAUGUUUGACCGUUCGUCUUAUUCAAAAAAUUUUGACACUUAAUAAUUCUUUUCCUAUCAUUUGAUUCAUUGUUAAAUAUAUUUUCAUGUAGGCAUAUAAUUUUACAUAUUUCAUAAAAGUUUUUGAAUAAGACGAACAGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAAUAUUUCGAAACGGAGGGAGUAU	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19275	MI0005216	osa-MIR806g	Oryza sativa miR806g stem-loop	UGCUCCCUCCGUUUCAAAAUGUUUGACACCGCUGACUUUUUAGUACGUGUUUGAUCAUUCGUUUUAUUCCAAAAAAAUUAAGUAAUUAUUUAUUCUUUUUAUAUCAUUUGAUUCAUUGUUAAAUAUACUUUCAUGUACACAUGUAGUUUUACAUAUUUCACUAACUUUUUUGAAUAAGACGAACGGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAACAUUUUGAAACGGAGGGAGUA	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19276	MI0005217	osa-MIR806h	Oryza sativa miR806h stem-loop	CUGAAAUAGAUAGUACUCCCUCCGUUUCGAAAUGUUUAACGCCGUUGACUUUUUAUCAUAUGUUUGACCGUUCGUCUUAUUCAAAAAAUUUAAGUAAUUAUUAAUUCUUUUCCUAUCAUUUGAUUCAUUGUUAAAUAUAUUUUUAUGUAGGCAUAUAAUUUUACAUAUCUCACAAAAGUUUUUGAAUAAGACGAAUGGUCAAACAUGUGCUAAAAAGUCAACGGUGUCAAACAUUUAGAAACGGAGGGAGUAGUAUGUUUAUUCGCUUCAG	miR806 was misnamed miR561 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19277	MI0005218	osa-MIR807b	Oryza sativa miR807b stem-loop	GAAUUGAUUCACCUGUGAUAUGGCGUGGCUGUUCCACUUAUGAUGAGGACAUGGCAUCCUAUUACCAGCCAUCGCACAAAAUUAAUAGGAUGCCAUAUUCUCGUCCUAGGUGUAACAACCACGUCAUCUCACAGGUGAAUCCAUUU	miR807 was misnamed miR562 by Luo et al [1]. 	7
19278	MI0005219	osa-MIR807c	Oryza sativa miR807c stem-loop	AUAAAAUCAUACUAUCAAUGAAUGGAUUCACCCGUGAUAUGACGUGGUUGUUCCACUUAGGACAAGAACGUGGCAUCCUAUUACAAGCCAUCGCACAAAAUCAAUAGGAUGCCACGUCCUCAUCAUAGGUGGAACAACCACGUCAUCUCACAGGUGAAUCCAUUCAUUGAUAGUGUGGUUUUGU	miR807 was misnamed miR562 by Luo et al [1]. 	7
19279	MI0005220	osa-MIR808	Oryza sativa miR808 stem-loop	ACUUCCUCCGUUUCACAAUGUAAGUCAUUCUAGCAUUUUCCACAUUCAUAUUGAUGUUAAUGAAUCUAGAUAGAUAUAUAUGUCUAGAUUCAUUAACAUCAAUAUGAAUGUGGGAAAUGUAAGAAUGACUUACAUUGUGAAAUGGAGGGAGU	miR808 was misnamed miR564 by Luo et al [1]. 	7
19280	MI0005221	osa-MIR809a	Oryza sativa miR809a stem-loop	UGUACUCCUUCCGUUUCACAAUGUAAGUCAUUAUAGCAUUUUUCAAAUUCAUAUUGAGGUUAAUGAAUCUAUAUAGAUAUAUAUAUGUCUAGAUUCAUUAACAUCAAUAUGAAUGUGAGAAAUGUUAGAAUGACUUACAUUGUGAAAUGGAGGGAGUAACA	miR809 was misnamed miR565 by Luo et al [1]. 	7
19281	MI0005222	osa-MIR809b	Oryza sativa miR809b stem-loop	UUGUUCUAAAUACUUCCUUUUUCACAAUAUAAGUCAUUCUAGCAUUUCCCACAUUCAUAUUGAUGUUAAUGAAUCUAGAUUGAUGUUACAUCAAUAUGAAUGUGAGAAAUGUUAGAAUGACUUACAUUGUGAAACGGAGGGAGUAGUUGCAA	miR809 was misnamed miR565 by Luo et al [1]. 	7
19282	MI0005223	osa-MIR809c	Oryza sativa miR809c stem-loop	AUACUCCCUCCAUUUCACAAUAUAAGUCAUUCUAGCAUAUCCUAUAUUCAUAUUAAUAUUAAUGAAUCUAGAUAUAUAUAUUUAUAUAAAUUCAUUAACAUCAAAUGAAUGUGAGAAAUGUUAGAAUGACUUACAUUGUGAAAUGGAGGAAGUAU	miR809 was misnamed miR565 by Luo et al [1]. 	7
19283	MI0005224	osa-MIR809d	Oryza sativa miR809d stem-loop	UUUACAGGUACUCCCUCCGUUUCACAAUGUAAGUCAUUCUAGCAUUUCCCACAUUCAUAUUGAUGUUAAUGAAUCUAGACAUAGUUAUCUAUCUAGAUUCAUUAACAUCAAUAUGAAUGUGAGAAAUGUUAGAAUGACUUACAUUGUGAAACGGAGGAAGUAGUAAA	miR809 was misnamed miR565 by Luo et al [1]. 	7
19284	MI0005225	osa-MIR809e	Oryza sativa miR809e stem-loop	UACUCCCUCCGUUUCACAAUGUAAGUUAUUCUAACAUUUCCUACAUUUAUAUUAAUGUUAAUGAAUCUAGACAUCAUUAACAUCAAUAUGUCUAGAUUUAUUAACAUCAAUAUGAAUGUGAGAAAUGUUAGAAUAACUUACAUUGUGAAACGGAUGAAGUA	miR809 was misnamed miR565 by Luo et al [1]. 	7
19285	MI0005226	osa-MIR809f	Oryza sativa miR809f stem-loop	UACUCCCUCCGUUUCACAAUUUAAGUCAUUCUAUCAUUUCUCACAUUCAUAUUAAUGUUAAUGAAUCUAGACAUAUAUAUCUAUCUAAAUUCAUUACCAUCAAUAUGAAUGUGAGAAAUGUUAGAAUGAUUUAAAUUGUGAAACGGAGGAAGUA	miR809 was misnamed miR565 by Luo et al [1]. 	7
19286	MI0005227	osa-MIR809g	Oryza sativa miR809g stem-loop	ACUUCCUCCGUUUCACAAUGUAAGUCAUUUUAGCAUUUCCCAUAUUCAUAUUGAUGCUAAUGAAUAUAUAUAAAUAUAUAUGUCUAGAUUCAUUAGCAUCAAUAUGAAUGUGAGAAAUGUUAGAAUGACUUACAUUGUGAAACGGAGGGAGU	miR809 was misnamed miR565 by Luo et al [1]. 	7
19287	MI0005228	osa-MIR809h	Oryza sativa miR809h stem-loop	GUUUCACAAUGUAAGUCAUUCUAACAUUUCCCACAUUCAUAUUGAUGUUAAUGAAUCUAGACAUAUAUAUCUAUUUAGAUUCAUUAAAAUCAAUAUGAAUGUGAGAAAUGUUAGAAUAACUUACAUUGUGAAAC	miR809 was misnamed miR565 by Luo et al [1]. 	7
19288	MI0005229	osa-MIR810	Oryza sativa miR810 stem-loop	AAUAUUCACUAUGGUUGCCAUCAUAAGCCCACCACAUGUGGCUCGCAUGCUUAAAUAACUAACGGCAUAAUUAGAUCACUUGAUGACGACGUAUAUCGGUGUUCGCUAUAUAUACUAUCUACUGGUAAGUAUAUAUAGCGAACACCGAUAUGCGUCAUCAUCAAGUGAUUUAAUUAUGCCGUUAGUUAAGCAUGCGAGCCACAUGUGGUGAGCUUACGAUGACGACCACAGUUUGUU	miR810 was misnamed miR566 by Luo et al [1]. 	7
19289	MI0005230	osa-MIR811a	Oryza sativa miR811a stem-loop	GGAAACUUGAAAACUACCGUUAGAUCGAGAAAUGGACGUCCGAGAUUCGUUCACGUCAUCAUGAGUUAAAAUUUAACUCGCAGAUUCACUCAUGAGUUGAAAUUUUACUGGGAGUUAAAUUUUAACUCAUUGUGACGUGGACGAAUCUCGGACGUCCAUUUCUCGAUCCAACGUUAGUUUCCAAGUUUCC	miR811 was misnamed miR567 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19290	MI0005231	osa-MIR811b	Oryza sativa miR811b stem-loop	GGAAACUUGAAAACUACCGUUAGAUCGAGAAAUGGACGUCCGAGAUUCGUCCACGUCACCAUGAGUUAAAAUUUAACUCGCAGAUUCACUCCUGAGUUAAACUUUUACUGGGAGUUAAAUUUUAACUCAUGGUGACGUGGGCGAAUCUCGAACGUUCGUUUCUGGAUCCAACGGUAGUUUCCAAGUUUCC	miR811 was misnamed miR567 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19291	MI0005232	osa-MIR811c	Oryza sativa miR811c stem-loop	ACCGUUAGAUCGAGAAAUGGACGUUCGAGAUUCGUCCACGUCACCAUGAGUUAAAAUUUAACUCUCAGUAAAUUUUAACUCAUGAGUGAAUCUGCGAGUUAAAUUUUAACUCAGGGUGACGUGGACGAAUCUCGGACGUCUAUUUCUCGAUCCAACGGU	miR811 was misnamed miR567 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19292	MI0005233	osa-MIR812a	Oryza sativa miR812a stem-loop	ACCUCCGUCCCAAAAUAAGUGCAGUUUUACACUAUUCAUCUCCAAAGUUUGAUCGUUCGUCUUAUUUGAAAAUUUUUUAUGAUUACUAUUUUUAUUGUUAUUACAUGAUAAAACAUGAAUAGUAUUUUAUGUGUGACUAAUUUUUUUAAAAAUUUUCAUAAAUUUUUCAAAUAAGACGGACGGUUAAACGUUGGACACGGAUUUUCACGGCUGCACUUAUUUUGAAACGGAGGU	miR812 was misnamed miR569 by Luo et al [1]. 	7
19293	MI0005234	osa-MIR812b	Oryza sativa miR812b stem-loop	GUAUCCGUAUCUACGUUUGACCGUUCGUCUUAUUUGAAAAUUUUAUGAAAAGAUUAAAAAAAUAGUCACGCAUAAAGUAAUAUUCAUGUUUUAUCAUCUAAUAACAAUAAAAAUACUAAUCAUUAAAAAUUUUCAAAUAAGACGGACGGUUAAACGUUGGACACGAAUAC	miR812 was misnamed miR569 by Luo et al [1]. 	7
19294	MI0005235	osa-MIR812c	Oryza sativa miR812c stem-loop	GGUUUCCGCGUCUAAUGUUUGACCGUCCAUCUUAUUUGAAAAAAAUUAAAAACAUAAGUCAUGCAUAAAAUAUUAUUCAUGUUUUAUCAUUUAACAAUAAUAAUAACACCAAUCAUAAAAAAAAAUUAUAUAAGACGGACGGUUAAACGUUGGACACGGAAACC	miR812 was misnamed miR569 by Luo et al [1]. 	7
19295	MI0005236	osa-MIR812d	Oryza sativa miR812d stem-loop	CGUAUCCAACAUUUGAUCAUCUGCCUUAUUCGAAAAAUUUAUAAAAAAAAACAAGUCACGCAUAAAGUAUUAUUCAUGUUUUAUCAUAUAAGAACAAUAAAAAUACUAAUCAUAAAAAAAGUAAAUAAGACGGACGGUUAAACGUUGGACACG	miR812 was misnamed miR569 by Luo et al [1]. 	7
19296	MI0005237	osa-MIR812e	Oryza sativa miR812e stem-loop	GUUUUAGUGCCCAACUUUGACCGUCCGUCUUAUUUGAAAAUUUUUUUAUUACUAUUUUUAUUGUUAUUAGAUGAUAAAAUAUAAAUAUUACUUCAUGCGUGACUUAAUUUUUAAAAAAAUUUCAUAAAAUUUUUAAAUAAGACGGACGGUUAAACGUUGGACACGGAAAC	miR812 was misnamed miR569 by Luo et al [1]. 	7
19297	MI0005238	osa-MIR813	Oryza sativa miR813 stem-loop	UAAACGUAGAUUACUGACAAAACCAAUUCCAUAACCCCUAGGCUAUUUUGCAAGACGAAUCUAAUGAUGUAUAUUAAUCCAUGAUUAGCGACCAAUUACUGUAGCGUCACUAUAAUAAAUCAUGGAUUAAUAUACCUCAUUAGAUUCGUCUCGCAAAAUAGCCUAGGGGUUAUGGAAUGGGUUUUACCACUAAUCUAUGUUUA	miR813 was misnamed miR570 by Luo et al [1]. 	7
19298	MI0005239	osa-MIR814a	Oryza sativa miR814a stem-loop	ACCUAGUACCGGACGAGACACUUCAUAGUACAACGAAUCUGGACAGUAAGCCUGUCCAGAUUCGUUGUACUAUGAAGUGUCAUAUCCGGUCCUAAGU	miR814 was misnamed miR573 by Luo et al [1]. 	7
19299	MI0005240	osa-MIR814b	Oryza sativa miR814b stem-loop	ACCGGACGAGACACUUCAUAGUACAACGAAUCUGGACAUGAAGAUUCGUUGUACUAUAAAGUGUCUCGUCUGGU	miR814 was misnamed miR573 by Luo et al [1]. 	7
19300	MI0005241	osa-MIR814c	Oryza sativa miR814c stem-loop	ACCAGAUGUGACACUUCAUAGUACAACGAAUCUGGACAGGAAGCAUGUCCGGAUUCGUUAUACUAUAAAGUGUCCUAUUCGGU	miR814 was misnamed miR573 by Luo et al [1]. 	7
19301	MI0005242	osa-MIR815a	Oryza sativa miR815a stem-loop	UUUUUUUAGACUCUUAAUUUCUUUUUCUAGGAUGAACUCUUAGGGUGUGUUUGAGGAGAAGGGGAUUGAGGAGAUUGGGGAGA	miR815 was misnamed miR574 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19302	MI0005243	osa-MIR815b	Oryza sativa miR815b stem-loop	CUAAUGGUUCACCUCGUUUUGCGUAUAUUCCCAAUCUUCUCUAUUUCCUUCUCCUCAAACACAGCCUGGGAGUGUUUGAGAAGGGGAUUGAGGAGAUUGGGAAGAUACGUAAAACGAGGUGAGCCAUUAG	miR815 was misnamed miR574 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19303	MI0005244	osa-MIR815c	Oryza sativa miR815c stem-loop	CUUCUCCUCUCUUCUCUCCUCCACCUCAGCAUUUAGCCGGCUUAUAGCCUAUACUUCCUCUAAGGGUGUGUUUGAGGAGAAGGGGAUUGAGGAGAUUGGGAAG	miR815 was misnamed miR574 by Luo et al [1]. The identified mature sequence maps many times to the rice genome, and overlaps annotated transposon and siRNA loci.  This entry may therefore represent an siRNA rather than a miRNA, and may be removed from future database releases. 	7
19304	MI0005245	osa-MIR816	Oryza sativa miR816 stem-loop	AUGUGACAUAUUUUACUACAACGAAUCUGGAUAUGACAGAGGUAUGUUUAAAUUCGUAGUAUUAGGAUGUGUCACAU	miR816 was misnamed miR576 by Luo et al [1]. 	7
19305	MI0005246	osa-MIR817	Oryza sativa miR817 stem-loop	UAUCUCAAUCAGGCCUCAAGUUGGUGUCCGUCAUGGAUGAUGGUCAUCCGUGACGGGCUCCAACUUGAGGCCCGAUUGAGAUA	miR817 was misnamed miR578 by Luo et al [1]. 	7
19306	MI0005247	osa-MIR818a	Oryza sativa miR818a stem-loop	UCCCUCCAUCCCAUAGUAUAAGGGAUUUGGGAAUGAUGUGACAUAUCCUAGUAUAAUGAAUCUGGACAAACCGUCUGUCCAAAUUCAUUGUCCUAGUAUGUGUCACAUCUACUCAAAAUCCCUUAUAUUAUGGGACGGAAGGGA	miR818 was misnamed miR580 by Luo et al [1]. 	7
19307	MI0005248	osa-MIR818b	Oryza sativa miR818b stem-loop	CCUCCGUCCCAUAAUAUAAGAGAUUUUAGAUGGAUGUGAUACAUCUCAGUACAAUGAAUCUGUACUAUAAUAUAUCAUAUCCAUCCAAAAUCCCUUAUAUUAUGGGACGGAGG	miR818 was misnamed miR580 by Luo et al [1]. 	7
19308	MI0005249	osa-MIR818c	Oryza sativa miR818c stem-loop	AUAAUAUACUCAUUUCGUCCUAUAAUAUAAGGGAUUUUGAAGGGAUGUGACACAUCCUAGCUAUAACCAUAUAUCUAGACAUAGCUAGGAACAUAUAUCUAGACAUGCUCUUGUCUAGAUAUAUGUGUUAUAUCUCUCCAAAAUCCCUUAUAUUAUGGGACGGAUGAAUAUGUUAU	miR818 was misnamed miR580 by Luo et al [1]. 	7
19309	MI0005250	osa-MIR818d	Oryza sativa miR818d stem-loop	UUCCUAUUAAUUGUUACUCUCUCCAUCCCAUAAUAUAAGGGAUUUUAGAGGGAUGUGAUCUAGAUUCGUAGUCCGAGGAAACAUCACAUACCUCUAAAAUCCCUUAUAUUAUGGGACGGAGGGAGUACUAGUUUAGGAA	miR818 was misnamed miR580 by Luo et al [1]. 	7
19310	MI0005251	osa-MIR818e	Oryza sativa miR818e stem-loop	CCCCGUCCUAUAAUAUAAGGGAUUUUGAGUUUUUGCUUGCACUGUUUGACCACUCGUCUUAUUUAAAUUUUUUUUGGAAUUAUUAUUAUUUUUGACUUAUUUUAUUAUCCAAAGUACUUUAAGCAUAACUUUUCGUUUUUUAUAUUUGUACAAAUUUUUUGAAUAAAACGAGUGGUCAAACAAUACAAACAAAAACUUAAAAUCCCUUAUAUUAUGGGACGGAGG	miR818 was misnamed miR580 by Luo et al [1]. 	7
19311	MI0005252	osa-MIR819a	Oryza sativa miR819a stem-loop	CCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAGAUGUUAAUGAAUCUAGGCAUAUAACAUCUAUAUGAAUGUGGGCAAUGCUAGAAAGUCUUAUAAUAUGAAACGGAGG	miR819 was misnamed miR581 by Luo et al [1]. 	7
19312	MI0005253	osa-MIR819b	Oryza sativa miR819b stem-loop	GUAAGCUACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUACCCACAUUCAUAUAGAUAUUAAUGAAUCUAGACAUACAUAUAUGUCUAGAUUCAUUAACAUAUAUAUGAAUGUUGAUAAUGCUAGAAAGUCUUAUAAUAUGAAACGGAGGAAGUAGCUUAC	miR819 was misnamed miR581 by Luo et al [1]. 	7
19313	MI0005254	osa-MIR819c	Oryza sativa miR819c stem-loop	UACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAGAUGUUAAUGAAUCUAGGCACACAUAUAUGUCUAGAUUCAUUAACAUAUAUAUGAAUGUGGGCAAUGCUAGAAAGCCUUAUAAUAUGAAACGGAGGAAGUA	miR819 was misnamed miR581 by Luo et al [1]. 	7
19314	MI0005255	osa-MIR819d	Oryza sativa miR819d stem-loop	CUACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAGAUGUUAAUGAAUCUAGACAAGUGUGUCUAGAUUCAUUAACAUCUAUAUGAAUGUGGGCAAUGCUAGAAAGUCUUAUAACCUGAAACGGAGGAAGUAG	miR819 was misnamed miR581 by Luo et al [1]. 	7
19315	MI0005256	osa-MIR819e	Oryza sativa miR819e stem-loop	UACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAGAUGUUAAUGAAUCUAGGCACACAUAUAUGUCUAGAUUCAUUAGCAUAUAUAUGAAUGUGGGCAAUGCUAGAAAGUCUUAUAAUAUGAAACGGAGGAAGUA	miR819 was misnamed miR581 by Luo et al [1]. 	7
19316	MI0005257	osa-MIR819f	Oryza sativa miR819f stem-loop	CCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAUAUGUUAAUGAAUCUAGGCACAUAUACAUGUCUAGAUUCAUUAUCAUAUAUAUGGAUAUGGACAAUGCUAGAAAAUUUUAUAAUAUGAAACGGAGG	miR819 was misnamed miR581 by Luo et al [1]. 	7
19317	MI0005258	osa-MIR819g	Oryza sativa miR819g stem-loop	UCCAUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAGAGAUGUUAAUGAAUCUAAGCACACAUAUAUGUCUAGAUUCAUUAACAUAUAUAUGAAUGUGGGUAAUGUUAGAAAGUCUUAUAAUAUGAAACGGAGGA	miR819 was misnamed miR581 by Luo et al [1]. 	7
19318	MI0005259	osa-MIR819h	Oryza sativa miR819h stem-loop	UACUACUCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCACAUUCAUAUAUAUGUUAAUGCAUCUAGGCACACAUAUAUGUCUAGAUUCAUUAACAUAUAUAUGAAUGUGGACAAUACGAGAAAGUCUUAUAACCUGAAACGGAGGUAGUA	miR819 was misnamed miR581 by Luo et al [1]. 	7
19319	MI0005260	osa-MIR819i	Oryza sativa miR819i stem-loop	CCAUGUAAAUAUCAUUGCCACUCAUUUACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGUCUACAUUCGUAUAGAUAUUAAUGAAUCUAGACACAUAUAUAUGUUUAGAUUCAUUAACAUCUAUAUGAAUACGGGCAAUGCUAGAAAAUCUUAUAAUAUGAAACGGAGGAAGUAAUAUUAUUUAUGUCAUGG	miR819 was misnamed miR581 by Luo et al [1]. 	7
19320	MI0005261	osa-MIR819j	Oryza sativa miR819j stem-loop	GUUAAACUUUUAUACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCUACAUUCAUAUAGAUGUUAAUGAAUCUAGGCACACAUAUAUGUCUAGAUUCAUUAACAUAUAUAUGAAUGUGGGCAAUGCUAGAAAGUUUUAUAAUAUGAAACGGAGGAAGUAUUAUUUAAU	miR819 was misnamed miR581 by Luo et al [1]. 	7
19321	MI0005262	osa-MIR819k	Oryza sativa miR819k stem-loop	GUACUACCUCCGUUUCAGGUUAUAAGACUUUCUAGCAUUGCCCAUAUUCAUAUAGAUGUUAAUGAAUCUUGACACACAUAUGUGUCUAGAUUCAUUAAUAUAUAUAUGAAUGUGGACAAUGCUAGAAAGUCUUAUAAUAUGAAACGGAGGAAGUAC	miR819 was misnamed miR581 by Luo et al [1]. 	7
19322	MI0005263	osa-MIR820a	Oryza sativa miR820a stem-loop	CGGCCUCGUGGAUGGACCAGGAGCUCAACAUUCCUUAAGGUUGUUCUUUCAAACCCAUACAAGGUUCCACCGCCUGCAUUGUUCCAAGAGUGUCUUGGAUGAAAGUAGGAAGUGGAACCUUGUUAGGGUUGGAACGAACUGCCUUAAGGAAGUCGAUGCUCCAGGUCCGUCCAGGAGGACG	miR820 was misnamed miR583 by Luo et al [1]. 	7
19323	MI0005264	osa-MIR820b	Oryza sativa miR820b stem-loop	UGCGUCGGCCUCGUGGAUGGACCAGGAGCUCGACGUUCCUUAAGGCCGUUCUUUCCGACCCAUACAAGGUUCCGUCGCCUGCAUUGUUCCAAGAGUGUCUUGGACGAAAGCAGGAAGUGGAACCUUGUUAAGGUCGGAACGAACUGCCUUAAGGAAGUCGAUGCUUUAGGUCCGUCCACGAGGACGACGCA	miR820 was misnamed miR583 by Luo et al [1]. 	7
19324	MI0005265	osa-MIR820c	Oryza sativa miR820c stem-loop	CGGCCUCGUGGAUGGACCAGGAGCUCGACAUUCCUUAAGGUCGUUCUUUCCGACCCAUACAAGGUUCCGCUGCCUGCAUUGUUCCAAGAGUGUCUUGGACAAAAGCAGGAAGUGGAACCUUGUUAAGGUCGGAACGAACUGCCUUAAGGAAGUCGAUGCUCCAGGUCCGUCCACGAGGACG	miR820 was misnamed miR583 by Luo et al [1]. 	7
19325	MI0005266	osa-MIR821a	Oryza sativa miR821a stem-loop	GAUAUCAGCUGAAAAAGUCAUCAACAAAAAAGUUGAAUAACUCAUCAAGAUCUAAAACUUUUAUUUUGGUCAUUUCUUCAUACGACAAAGUGAUAGUAACAUUGUUCACAGAAUUGACAUAUCUCUUAUCUGGUUUUAUAAACUAUAACACAUAUAUGUAAAAUUUGUGAAUAAUAUUACUAACAUUUCGUCAGAUGAAGAAAUAAAAAAAUAAAAGUUAUAGAUCUUGAUGAGUUAUUCAACUUUGUUGUUGAUGACUUUUUCAAUUGAAAUC	miR821 was misnamed miR584 by Luo et al [1]. 	7
19326	MI0005267	osa-MIR821b	Oryza sativa miR821b stem-loop	CUAAAUGAUUUCAAUUGAAAAAGUCAUCAACAAAAAAGUUGAAUAACUUAUCAAGAUCUAAAACUUUUAUUUUUGUUAUUUCUUCAUCCGACGAAAUGUUAGUAAUAUUAUUCACAAAUUUUACAUAUAUGUGUUAAAGUUUAUAAAACCAGAUAAGAGAUAUGACAAUUUUAUAAAUAAUGUUACCAUCACUUUGUCGUAUGAAGAAAUAACCACAAUAAAAGUUUUAGAUCUUGAAGAGUUAUUCAACUUUGUUGUUGAUGACUUUUUCAGUUGAUAUCAUUUAG	miR821 was misnamed miR584 by Luo et al [1]. 	7
19327	MI0005268	osa-MIR821c	Oryza sativa miR821c stem-loop	UCAACUGAAAAAGUCAUCAACAAAAAAGUUGAAUAACUCAUCAACAUCUAAAACUUUUAUUUUGGUUAUUUCUUCAUACGACAAAGUGAUAGUAACAUUAUUCACAAAAUUGACAUAACUCUUAUCUGGUUUUAUAAACUAUAACACAUAUAUGUAAAAUUUGUGAAUAAUUUUCUAACAUUUUGUCAGAUGAAGAAACAACAAAAAUAAAAGUUUUAGAUCUUGAUGAGUUAUUCAACUUUGUUGUUGAUGACUUUUUCAAUUGA	miR821 was misnamed miR584 by Luo et al [1]. 	7
19328	MI0005269	mdo-mir-1	Monodelphis domestica miR-1 stem-loop	ACCUACUCAGAGUACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUGGUAGGUG		49
19329	MI0005270	mdo-mir-7	Monodelphis domestica miR-7 stem-loop	UUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAACGACAACAAAUCACAGUCUGCC		49
19330	MI0005271	mdo-mir-9-2	Monodelphis domestica miR-9-2 stem-loop	GGAAGUGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA		49
19331	MI0005272	mdo-mir-9-1	Monodelphis domestica miR-9-1 stem-loop	CGAGGCCCGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUGUUAUUGAGCUAUCAUAAAGCUAGAUAACCGAAAGUAGAAAUGACUUUCA		49
19332	MI0005273	mdo-mir-10a	Monodelphis domestica miR-10a stem-loop	CUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUA		49
19333	MI0005274	mdo-mir-10b	Monodelphis domestica miR-10b stem-loop	CAGAAUGUUAUUACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUUUACAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCAC		49
19334	MI0005275	mdo-mir-21	Monodelphis domestica miR-21 stem-loop	UGUCGGAUAGCUUAUCAGACUGAUGUUGACUGUUGGAUCUCAUGGCAACAGCAGUCGAUGAGCUGUCUGACAUU		49
19335	MI0005276	mdo-mir-22	Monodelphis domestica miR-22 stem-loop	CCGAGCCACAGCAGUUCUUCAGUGGCGAGCUUUAUGUCUUGUCCCAGCUAAAGCUGCCAGUUGAAGAACUGCUGAGCUCUG		49
19336	MI0005277	mdo-mir-30a	Monodelphis domestica miR-30a stem-loop	GCGGCUGUAAACAUCCUCGACUGGAAGCUGUGAAGCAGCAGAUGGGGCUUUCAGUCGGAUGUUUGCAGCUGC		49
19337	MI0005278	mdo-mir-31	Monodelphis domestica miR-31 stem-loop	AGCUGGAGAGGAGGCAAGAUGUUGGCAUAGCUGUUGAACUGAGAACCUGCUAUGCCAACAUAUUGCCAUCUUUCUUGUCUAUCAGCA		49
19338	MI0005279	mdo-mir-32	Monodelphis domestica miR-32 stem-loop	GGAGAUAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCUUUAGUGCAAUUUAGUAUGUGUGAUAUUUU		49
19339	MI0005280	mdo-mir-34a	Monodelphis domestica miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGUAAUAGAUAAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUUAGGCCC		49
19340	MI0005281	mdo-mir-100	Monodelphis domestica miR-100 stem-loop	CCUGUUGCCACAAACCCGUAGAUCCGAACUUGUGGUGAUAUUCCACACAAGCUUGUGUCUAUAGGUAUGUGUCUGUCAGG		49
19341	MI0005282	mdo-mir-101-2	Monodelphis domestica miR-101-2 stem-loop	ACUGUCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAUAUGUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGU		49
19342	MI0005283	mdo-mir-101-1	Monodelphis domestica miR-101-1 stem-loop	AGGCUGCCCUGGCUCAGUUAUCACAGUGCUGAUGCUGUCCGUUCUCAAGGUACAGUACUGUGAUAACUGAAGGAUGGCAGCCA		49
19343	MI0005284	mdo-mir-103-1	Monodelphis domestica miR-103-1 stem-loop	UUGUCUUCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGAAGACAUUG		49
19344	MI0005285	mdo-mir-103-2	Monodelphis domestica miR-103-2 stem-loop	CUUGGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUUGCAUUGAUGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACCAAGAU		49
19345	MI0005286	mdo-mir-107	Monodelphis domestica miR-107 stem-loop	CUUCUUUCUGCUUUCGGCUUCUCUACAGUGUUGCCUUGUGGCGUGGAGUUCAAGCAGCAUUGUACAGGGCUAUCAAAGCAUAGA		49
19346	MI0005287	mdo-mir-122	Monodelphis domestica miR-122 stem-loop	CAGAGCUAUGGAGUGUGACAAUGGUGUUUGUGUCCAGUCUAUCAAACGCCAUUAUCACACUAAAUAGCUACUGU		49
19347	MI0005288	mdo-mir-124a-1	Monodelphis domestica miR-124a-1 stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG		49
19348	MI0005289	mdo-mir-124a-2	Monodelphis domestica miR-124a-2 stem-loop	AUCAGAGACUCUGUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAGCGGAGCCUGAAA		49
19349	MI0005290	mdo-mir-124a-3	Monodelphis domestica miR-124a-3 stem-loop	CUCUGCGUGUUCACAGCGGACCUUGAUUUAAUGUCUAUACAAUUAAGGCACGCGGUGAAUGCCAAGAG		49
19350	MI0005291	mdo-mir-125b-1	Monodelphis domestica miR-125b-1 stem-loop	ACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGCUUUUCAGCGACAACCACAGGUCAGGCUCUUGGGACCUAGGCGGAGG		49
19351	MI0005292	mdo-mir-125b-2	Monodelphis domestica miR-125b-2 stem-loop	AAUCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGC		49
19352	MI0005293	mdo-mir-128	Monodelphis domestica miR-128 stem-loop	UGUGCAGCAGGAAGGGGGGCCGUUACACUGUCAGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUCCCUGCUGUGGC		49
19353	MI0005294	mdo-mir-129	Monodelphis domestica miR-129 stem-loop	UGGAUCUUUUUGCGGUCUGGGCUUGCUGUUCCUUAAAUCAGUAGUCAGGAAGCCCUUACCCCAAAAAGUAUCUA		49
19354	MI0005295	mdo-mir-130a	Monodelphis domestica miR-130a stem-loop	UGGCCAGAGCUCUUUUCACAUUGUGCUACUGUCUGCACCUAUCACUAGCAGUGCAAUGUAAAAAGGGCAUUGGCUG		49
19355	MI0005296	mdo-mir-133a	Monodelphis domestica miR-133a stem-loop	CAAUGCUUUGCUAAAGCUGGUAAAAUGGAACCAAAUCACCUAUUCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUAUGCAUUGA		49
19356	MI0005297	mdo-mir-135a	Monodelphis domestica miR-135a stem-loop	AGAUAAAUUCACUCUAGUGUCUUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAAUACAUUGUGAAAUGUCA		49
19357	MI0005298	mdo-mir-135b	Monodelphis domestica miR-135b stem-loop	AGCUCUCUGCUGUGGCCUAUGGCUUUUCAUUCCUAUGUGAUUGCUGUUCCCAACUCAUGUAGGGCUAAAAGCCAUGGGCUACAGGGAGGGGAGAGCCUCC		49
19358	MI0005299	mdo-mir-137	Monodelphis domestica miR-137 stem-loop	CUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGG		49
19359	MI0005300	mdo-mir-138	Monodelphis domestica miR-138 stem-loop	GUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACAAGCAGCUCAUCCUAUUACCCGGCUAUUUCACUACACCAGGGUUGCAUCA		49
19360	MI0005301	mdo-mir-142	Monodelphis domestica miR-142 stem-loop	GCAGUCACCCAUAAAGUAGAAAGCACUACUAACAGCAAUGUAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUG		49
19361	MI0005302	mdo-mir-143	Monodelphis domestica miR-143 stem-loop	CCCGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGUGAGUCUGAGAUGAAGCACUGUAGCUCGGG		49
19362	MI0005303	mdo-mir-144	Monodelphis domestica miR-144 stem-loop	CGGGGCCCAGGCCGGGAUAUCAUCGUAUACUGUAAGUUUGCAAUGAGACACUACAGUAUAGAUGAUGUACUGGCGAGGGCCGCCU		49
19363	MI0005304	mdo-mir-451	Monodelphis domestica miR-451 stem-loop	CUGGCGGGGAAACCGUUACCAUUACUGUGUUUAGUAAUGGUAAGGGUUCUCCCGCUGCGCUG		49
19364	MI0005305	mdo-mir-145	Monodelphis domestica miR-145 stem-loop	CUCAGGGUCCAGUUUUCCCAGGAAUCCCUUAGAUGCUAAGAUGGGGAUUCCUGGAAAUACUGUUCUUGAG		49
19365	MI0005306	mdo-mir-152	Monodelphis domestica miR-152 stem-loop	CCCGGCCCAGGUUCUGUGAUACACUCCGACUUAGACUCUGGAGCAGUCAGUGCAUGACAGAACUUGGGCUUGG		49
19366	MI0005307	mdo-mir-182	Monodelphis domestica miR-182 stem-loop	GCUGUGUUUGGCAAUGGUAGAACUCACACUGGUGAGAUAAUGGAAUCCGGUGGUUCUAGACUUGCCAACUA		49
19367	MI0005308	mdo-mir-184	Monodelphis domestica miR-184 stem-loop	CCAGUCACAUCCCCUUAUCACUUUUCCAGCCCAGCUUUCUAAUGCUAAUUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA		49
19368	MI0005309	mdo-mir-187	Monodelphis domestica miR-187 stem-loop	AUUGUGAGACCUCUGGCUACAACACAGGACACGGGAGCUUUUCUGAACCCUCGUGUCUUGUGUUGCAGCCAGAGGGGCACA		49
19369	MI0005310	mdo-mir-181c	Monodelphis domestica miR-181c stem-loop	UGGGGGAACAUUCAACGCUGUCGGUGAGUUUGAGCAGCUGAAGGCAAACCAUCGACCGUUGAGUGGACCCCG		49
19370	MI0005311	mdo-mir-186	Monodelphis domestica miR-186 stem-loop	ACCUUCCAAAGAAUUCUCCUUUUGGGCUUUUGAUUCUUAAUUUCAGCCCAAAGGUGAAUUUUUUGGGA		49
19371	MI0005312	mdo-mir-193	Monodelphis domestica miR-193 stem-loop	GAGGAUUGGGUCUUUGUGGGCGAGAUGAGGGUGUCAGUUCAACUGGCCUACAAAGUCCCAGUUCUC		49
19372	MI0005313	mdo-mir-196b	Monodelphis domestica miR-196b stem-loop	AACUGGUCUGUGAUUUAGGUAGUUUCCUGUUGUUGGGGCUCCACCUUUCUCUCGACAGCACGAUACUGCCUUCAUUACUUCAGUUG		49
19373	MI0005314	mdo-mir-199b	Monodelphis domestica miR-199b stem-loop	CUCCACUCCGUCUACCCAGUGUUUAGACUAUCUGUUCAGGACUCCAAUAUUGUACAGUAGUCUGCACAUUGGUUAGGCUGGGCUGGGCU		49
19374	MI0005315	mdo-mir-203	Monodelphis domestica miR-203 stem-loop	AGCUGCCCUGGUCCAGUGGUUCUUAACAGUUCAACAGUUCUGUGUAGAGAUUGUGAAAUGUUUAGGACCACUUGAUCUGGG		49
19375	MI0005316	mdo-mir-204	Monodelphis domestica miR-204 stem-loop	CAACUGACUAUGUGACCUGUGGGCUUCCCUUUGUCAUCCUAUGCCUGGAAAUCAGAGUGGGGCAGGGACAGCAAAGGGAUGCUCAGCUGUCGUCUUC		49
19376	MI0005317	mdo-mir-206	Monodelphis domestica miR-206 stem-loop	GAGGCAACAUGCUUCUUUAUAUCCCCAUAUGAAUUAUGCUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCGGGAAG		49
19377	MI0005318	mdo-mir-208	Monodelphis domestica miR-208 stem-loop	UUCCUGUGACAGGUGAGCUUUUGGUCCGGGUUAUACCUGAUGCAUGUGUAUAAGACGAGCAAAAAGCUCGUUGGUCG		49
19378	MI0005319	mdo-mir-214	Monodelphis domestica miR-214 stem-loop	GGGCUGGCUGGACGGAGUUGUCAUGUGUCUGCCUGUCUACACUUGCUGUGCAGAACAUCCUCUCACCUGUACAGCAGGCACAGACAGGCAGUCACAUGACAACCCAGCCU		49
19379	MI0005320	mdo-mir-216	Monodelphis domestica miR-216 stem-loop	GAUGGCUGUGAAUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUAAUAAAUUCCCUCACAGUGGUCUCUGGGAUUAUGCUAAACAGAGCAAUUUC		49
19380	MI0005321	mdo-mir-217	Monodelphis domestica miR-217 stem-loop	UUGAUGUCGUAGAUACUGCAUCAGGAACUGAUUGGAUAAUAUUCAGGCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCU		49
19381	MI0005322	mdo-mir-218	Monodelphis domestica miR-218 stem-loop	UGAUUAUGUGGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGUGAGGUAUGAGUAAAACAUGGUUCUGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		49
19382	MI0005323	mdo-mir-219	Monodelphis domestica miR-219 stem-loop	CAGGGGUUCCGCCGCUGAUUGUCCAAACGCAAUUCUUGUGCGAGUCUGCAGCCAACCGAGAAUUGUGGCUGGACAUCUGUGGCUGAGCUCC		49
19383	MI0005324	mdo-mir-223	Monodelphis domestica miR-223 stem-loop	UCUGGCCCAGAUCCUUCAGUGCCACACUCCGUGUAUUUGACAAGCUGAGUUGGACACUCCGUGUCGUAGAGUGUCAGUUUGUCAAAUACCCCAAGUGAGGCAUUUGCCUAG		49
19384	MI0005325	mdo-mir-338	Monodelphis domestica miR-338 stem-loop	GGCCUUCCUCCCCAACAAUAUCCUGAUGCUGAGUGAGCGGCACAUGGAGACUCCAGCAUCAGUGAUUUUGUUGAAGAGGGUGGCUGCCA		49
19385	MI0005326	mdo-mir-365	Monodelphis domestica miR-365 stem-loop	CCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUACACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCAG		49
19386	MI0005327	mdo-mir-375	Monodelphis domestica miR-375 stem-loop	CCCGCGCCGAGCCCCUCGCACAAACCGGACCUGAGCGUUUUGUUCGUUCGGCUCGCGUGAGGC		49
19387	MI0005328	mdo-mir-383	Monodelphis domestica miR-383 stem-loop	CUCAGAUCAGAAGGUGAUUGUGGCUUUCGGUAGACAUGGAACAGCCACAUCACUGGCUGGUCAGAAAGAG		49
19388	MI0005329	mdo-mir-449	Monodelphis domestica miR-449 stem-loop	UGUGAUGGGAUGGCAGUGUAUUGUUAGCUGGUUGACUAUCUGAACGUGCCAGCUAACAUGCAACUGCUAUCCCAUUGCA		49
19389	MI0005330	mdo-let-7a-2	Monodelphis domestica let-7a-2 stem-loop	AGGUUGAGGUAGUAGGUUGUAUAGUUUAGAAUUACAUCAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCUU		49
19390	MI0005331	mdo-let-7g	Monodelphis domestica let-7g stem-loop	AGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCC		49
19391	MI0005332	mdo-let-7i	Monodelphis domestica let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUA		49
19392	MI0005333	mdo-mir-15a	Monodelphis domestica miR-15a stem-loop	CCUUGGGGUAAAGUAGCAGCACAUAAUGGUUUGUUGGUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG		49
19393	MI0005334	mdo-mir-16	Monodelphis domestica miR-16 stem-loop	GUCAACAGUGCCUUAGCAGCACGUAAAUAUUGGCGUUAAGAUUUUAAAAGUAUCUCCAGUAUUAACUGUGCUGCUGAAGUAAGGUUGGCC		49
19394	MI0005335	mdo-mir-183	Monodelphis domestica miR-183 stem-loop	ACUCCUGUUCUGUGUAUGGCACUGGUAGAAUUCACUGUGAAAACACACUAUCAGUGAAUUACCAAAGGGCCAUAAACAGAGCAGAGAA		49
19395	MI0005336	mdo-mir-96	Monodelphis domestica miR-96 stem-loop	GAUGUCUGCUUGGCCCGUUUUGGCACUAGCACAUUUUUGCUUCUGUCUCUCUGCUCUGAGCAAUCAUGUGUAGUGCCAAUAUGGGAAAAGCAAGAUG		49
19396	MI0005337	mdo-mir-212	Monodelphis domestica miR-212 stem-loop	GGGCAGCGCGCCGGCACCUUGGCUCUAGACUGCUUACUGCCCGGGCCACCCUCAGUAACAGUCUCCAGUCACGGCCACCGACGCCUGGCCC		49
19397	MI0005338	mdo-mir-132	Monodelphis domestica miR-132 stem-loop	GGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACCAGGGGUAACAGUCUACAGCCAUGGUCGCCC		49
19398	MI0005339	mdo-mir-200c	Monodelphis domestica miR-200c stem-loop	CCCCAUCUUACCCAGCAGUGUUUGGGUGCCGCUCGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGAGG		49
19399	MI0005340	mdo-mir-141	Monodelphis domestica miR-141 stem-loop	UGGGGCCAUCUUCCAGUACAGUGGUGGAUGGUGAAGCUUCUAACACUGUCUGGUAAAGAUGCCC		49
19400	MI0005341	mdo-mir-191	Monodelphis domestica miR-191 stem-loop	AGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCAAUUGGAUUUCGUUCCCUGCU		49
19401	MI0005342	mdo-mir-425	Monodelphis domestica miR-425 stem-loop	AAAGUGCUUUGGAAUGACACGAUCACUCCCGUUGAGCGGACAGCCAAGAAGCCAUCGGGAAUAUCGUGUCCGUCCAAUGCUCUUU		49
19402	MI0005343	mdo-mir-181a	Monodelphis domestica miR-181a stem-loop	UGAACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUGAAAACCAUCGACCGUUGAUUGUACC		49
19403	MI0005344	mdo-mir-181b	Monodelphis domestica miR-181b stem-loop	AAGGUCACAAUCAACAUUCAUUGCUGUCGGUGGGUUUAACUGUAUGGACAAGCUCACUGAACAAUGAAUGCAACUGUGGCCCCACUU		49
19404	MI0005345	mdo-mir-200b	Monodelphis domestica miR-200b stem-loop	CCAUCUUACUGGGCAGCAUUGGAUGGUGUCUGUGUUUCUAAUACUGCCUGGUAAUGAUGAUGAUGGGG		49
19405	MI0005346	mdo-mir-200a	Monodelphis domestica miR-200a stem-loop	GGGCCUCUGUGGGCAUCUUACUAGACAGUGCUGGAUUUUUGGAUGUACUCUAACACUGUCUGGUAACGAUGUUUAAAGAGGGAACC		49
19406	MI0005347	mdo-mir-222a	Monodelphis domestica miR-222a stem-loop	UGUAGAUACUGUCUCUUUCCAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCUUAGAGCU		49
19407	MI0005348	mdo-mir-221	Monodelphis domestica miR-221 stem-loop	GCAUGAACCUGGCAUACAAUGUAGAAUUCUGUGUUUAUUAAGUAACAGCUACAUUGUCUGCUGGGUUUCAGGCU		49
19408	MI0005349	mdo-let-7f-2	Monodelphis domestica let-7f-2 stem-loop	GGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCACACCCGAUCUCGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		49
19409	MI0005350	mdo-let-7a-3	Monodelphis domestica let-7a-3 stem-loop	GGGGUGAGGUAGUAGGUUGUAUAGUUUGGGGGUCGCUCCCUCUGUCUGUGAGAUAACUAUACAGUCUACUGUCUUUCCC		49
19410	MI0005351	mdo-let-7b	Monodelphis domestica let-7b stem-loop	GGCGGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGUAGUGAUUUUGCCCCAAUCAGAAGAUAACUAUACAACCUACUGCCUUCCCUGA		49
19411	MI0005352	mdo-mir-29b	Monodelphis domestica miR-29b stem-loop	GCUUCUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAACUACUGAGUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGAGGA		49
19412	MI0005353	mdo-mir-29a	Monodelphis domestica miR-29a stem-loop	AUGACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUCAUUUUCUAGCACCAUUUGAAAUCGGUUAU		49
19413	MI0005354	mdo-mir-17	Monodelphis domestica miR-17 stem-loop	GUCAGAAUAAUGUCAAAGUGCUUACAGUGCAGGUAGUGAUAUGUAGAAUCUACUGCAGUGAAGGCACUUGUAGCAUUAUAGUGAC		49
19414	MI0005355	mdo-mir-18	Monodelphis domestica miR-18 stem-loop	UUGUUCUAAGGUGCAUCUAGUGCAGAUAGUGAAGUAGAUUAGCAUCUACUGCCCUAAGUGCUCCUUCUGGCA		49
19415	MI0005356	mdo-mir-19a	Monodelphis domestica miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUG		49
19416	MI0005357	mdo-mir-20	Monodelphis domestica miR-20 stem-loop	UGAAAGGACAGCUUUUGUAGCACUAAAGUGCUUAUAGUGCAGGUAGUGUUUAGUUAUCUACUGCAUUAUGAGCACUUGAAGUACUGCUAGCUGUAGAACUAC		49
19417	MI0005358	mdo-mir-19b	Monodelphis domestica miR-19b stem-loop	GCACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUAUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUGGUGG		49
19418	MI0005359	mdo-mir-92	Monodelphis domestica miR-92 stem-loop	CUUUCUACACAGGUUGGGAUCAGUUGCAAUGCUGUGUCUGUCUGUAGUAUUGCACUUGUCCCGGCCUGUUGAGUUUGG		49
19419	MI0005360	mdo-let-7a-1	Monodelphis domestica let-7a-1 stem-loop	UCUCCACUGUGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCUUAAAG		49
19420	MI0005361	mdo-let-7f-1	Monodelphis domestica let-7f-1 stem-loop	UCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGA		49
19421	MI0005362	mdo-let-7d	Monodelphis domestica let-7d stem-loop	AAUGGGCUCCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUAGGGCAGGGAUUUUGCCCACAAGGAGUUAACUAUACAACCUGCUGCCUUUCUUAGGGCUCUAUUAUU		49
19422	MI0005363	mdo-mir-23a	Monodelphis domestica miR-23a stem-loop	CGGCUGGGGUUCCUGGGGAUGGGAUUUGAUUACUGCCACAAAUCACAUUGCCAGGGAUUUCCAACUGACCACU		49
19423	MI0005364	mdo-mir-27a	Monodelphis domestica miR-27a stem-loop	UGGCUUGAGGAGCAGGACUUAGCUGCCUUGUGAACAGAGUCAGCAUCAUAUUGUGUUCACAGUGGCUAAGUUCCGCUCCCCUUGCC		49
19424	MI0005365	mdo-mir-24-2	Monodelphis domestica miR-24-2 stem-loop	GCCUCCUGUGCCUACUGAGCUGAAACACAGUUGCUUUGGAUAAACUGGCUCAGUUCAGCAGGAACAGGAGUCU		49
19425	MI0005366	mdo-mir-23b	Monodelphis domestica miR-23b stem-loop	GGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUGAAAAUCACAUUGCCAGGGAUUACCACGCAGCC		49
19426	MI0005367	mdo-mir-27b	Monodelphis domestica miR-27b stem-loop	ACCUCUCUGACAAGGUGCAGAGCUUAGCCGAUUGGUGAACAGUCACUGAUUUCCUCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGGG		49
19427	MI0005368	mdo-mir-24-1	Monodelphis domestica miR-24-1 stem-loop	GGUGCCUACUGAGCUGAUAACAGUUCUGAUUUUACACACUGGCUCAGUUCAGCAGGA		49
19428	MI0005369	mdo-mir-93	Monodelphis domestica miR-93 stem-loop	AGUCUUGGGGGGCUCCAAAGUGCUGUUCGUGCAGGUAGUGUGAUAACCUGACCUACUGCUGAGCUAGCACUUCCAGAGCCCCUGGGACA		49
19429	MI0005370	mdo-mir-25	Monodelphis domestica miR-25 stem-loop	GGCCAGUGUUGAGAGGCGGAGACUUGGGCAAUUGCUGAACUCUGCCCUGGGCAUUGCACUUGUCUCGGUCUGACAGUGCUGGC		49
19430	MI0005371	mdo-mir-302b	Monodelphis domestica miR-302b stem-loop	CCCCUUCUACUUUAACAUGGAGGUACUUUCUGUGUUUAAAAAGGUAAGUGCUUCCAUGUUUUGGUAGGAGU		49
19431	MI0005372	mdo-mir-302c	Monodelphis domestica miR-302c stem-loop	GCUUUAACAUGGGGGUACCUGCUACGUAAUAAAAAGUAAGUGCUUCCAUGUUUCAGUGG		49
19432	MI0005373	mdo-mir-302a	Monodelphis domestica miR-302a stem-loop	CCCACUACUUAAACGUGGAUUUACUUGCUUUGUUUCUAAAAAAGUAAGUGCUUCCAUGUUUUAGUGAUGG		49
19433	MI0005374	mdo-mir-302d	Monodelphis domestica miR-302d stem-loop	CCUCUGCUUUAACAUGGAAGUGCUUGCUGUGAUUUUAAAAAAUUAAGUGCUUCCAUGUUUGAGUUGUGGUG		49
19434	MI0005375	mdo-mir-367	Monodelphis domestica miR-367 stem-loop	ACUGUUGCUAACAUGCAACUCUGUUCUAUGUAAACGGGAAUUGCACUUUAGCAAUGGUGAUGG		49
19435	MI0005377	bmo-mir-31	Bombyx mori miR-31 stem-loop	GUCGAGCCGGUGGCUGGGAAGGCAAGAAGUCGGCAUAGCUGUUUGAAUAAGAUACACGGCUGUGUCACUUCGAGCCAGCUCAAUCCGCCGGCUUUCUUCAAUUUCAAGAUUUGCGGAUGCU		46
19436	MI0005378	bmo-mir-71	Bombyx mori miR-71 stem-loop	GCAAGAUGCUCUCUACCUCUUGAAAGACAUGGGUAGUGAGAUGUCCCGUACAUCUAAAAUUCUCACUACCUUGUCUUUCAUGCGGAUUGGGCAAAUAUCUUCACUCGGCUUCGGAAGAU		46
19437	MI0005379	ath-MIR822	Arabidopsis thaliana miR822 stem-loop	CGACCUUAAGUAUAAGUAGAUAUAUGGGGAUGUAACGCAUGUUGUUUUCUGCGGGAAGCAUUUGCACAUGUUUCGUGGAGAAUGAAAUCACAUUCCAUACAUGAAUAAUAAUUACCUUUUAGAUAGAACAUCGUACUGCUUGAAAAAACAUGUUAAUGUCAUAAACUUUAUGAUGAAAACACCUAUAAAAAGCGUUUUUUCAAGCAUGUGCUAUCUAUGAAGGUAAUUACUAUUCAUGUAUAAAAUAUGAUUUUAUCCUCCAUAAAACAUGUGCAAAUGCUUUCUACAGGAAACAAUAUACGUUGCAUCCCCAUCUACUUACACUUAAGGUCGUUGU		1
19438	MI0005380	ath-MIR823	Arabidopsis thaliana miR823 stem-loop	AAUUUCAGAGAUACUAAUCCAAGAGAUGGCGGAUACGUUUUACAAUCACGAAUCUUGUAUGAUCACUAACCAUUGGAACAAUAAGAGUAUAUAAUGAGUAUAUCACCAUUUAGUUCUAGUGGGUGGUGAUCAUAUAAGAUUGGUAAUGGUAACAGUGAAACAUAUCCCCCAUCUAUUGGGAUUAAUUAGUC		1
19439	MI0005381	ath-MIR825	Arabidopsis thaliana miR825 stem-loop	CUUUCUAUAAUUACUUUUUGUAUAGAAUUCACUAGUUGAUUCCAUCGACUCGUUCAAGCACCAGCUCGAAGAAGCUUAGCUAAUUUAUCUUAGAAAAUAAUGAAAAAGCUAUGCUUCUCAAGAAGGUGCAUGAACAAGUUGAUGUAUAUUUUGAUGUGUAAAGACCAAAAUUGGAUCUCACAUGUG		1
19440	MI0005382	ath-MIR826	Arabidopsis thaliana miR826 stem-loop	AGAGACGUGGAUGCUUCUCGUCCACAAGUUCUUUGGUGCCUCUAUGAUAUAGUCCGGUUUUGGAUACGUGAAAAUCAUAUCAUAUUGCUGCUGUGAAAAGUUAAUUUUCACGUGUCCAAAACCAGAUUAUCUCAUAUUGCUGCUGUGUAUCUUAUCAUCUUUUUCCUGCUACUCUUAC		1
19441	MI0005383	ath-MIR827	Arabidopsis thaliana miR827 stem-loop	UUCCAUGAAACGUUAUAGGUUUUUUUCUUUCUCUCUUGCAACCCUUGAAUGUGUUUGUUGAUUGAUAUCUACACAUGUUGAUCAUCCUUGUGUUGAUCGAUUGGUUUAGAUGACCAUCAACAAACUCUUUCGUGGUUUUGCAUCGCUUCUUGGAAUCUCGAUCAUGUUUUUAGCAUC		1
19442	MI0005384	ath-MIR828	Arabidopsis thaliana miR828 stem-loop	GUGACAAAGUCACAAAAGUGAUAAACUCUCCUUUCCACUUUCUAAUGUUUCUUGCUUAAAUGAGUAUUCCAUGUAAAAAUGAUUCACUCACUCGUAUGGGUGGGUUGGGUUUUCUCUUCAUGAGAUGCUCAUUUGAGCAAGCAAUGUUUGGAAGUGGGACUAUUUAAUAUCAUGUAUGAGUUUUAUCUUUU		1
19443	MI0005385	ath-MIR829	Arabidopsis thaliana miR829 stem-loop	ACGUCAAAAUUGAUUAACAAAAAGUCAAUGAAUCAUUCUACCAAUUGACUUGUACUUUGAAGCUUUGAUUUGAACCUGUCAAUUGGUAUCAAAGCUUCUAAAUCUUUGAAGCUCUGAUACCAAAUGAUGGAAUCAAAUUAAAGCUUCAAGGUAGUAGUCAUCUUGGCAGAGAAAAGAAAAAGCACUUCGAGUUUACCAUCUUGAU		1
19444	MI0005386	ath-MIR830	Arabidopsis thaliana miR830 stem-loop	CAGAGUCUCGCUAGUGUCUUUACUAAACACAAAAUCUGUAAACGCCUCGAUCUCCUCUUCUCCAAAUAGUUUAGGUUAGCUGACAUAUAAUAAUUCAAUAGACCCCAGUUUCUCCAGAUAACCUAACUAUUUUGAGAAGAAGUGAACGAAGAGCGAUUACAAGUUAGGAGAGUGCUUGAAUUUUGAAGAACAUCG		1
19445	MI0005387	ath-MIR831	Arabidopsis thaliana miR831 stem-loop	GCACAAUGCGGACAGUGCUACAAGAAGAGAUUUAUAGAGUCUUAAGAGUCUCAAGAAGCGUACAAGGAGAUGAGGAGUGAAUCACCAAAACAAGUGGUUUUGGUUUGUGAAUCACCAAAACAAGUGGUUUUGGUUUGUGAAUCAGUAUGGUUUACCCAAAACACUUGUUUGGUGUGUUUACUUCUGAUCUCUUCGUACUCUUCUUGCGAUUCUAUGACACUCUACAUGUAACAUCGGCAUGGUUUACCAAAAAGCCU		1
19446	MI0005388	ath-MIR832	Arabidopsis thaliana miR832 stem-loop	AAGAAAGAAAAAAUAAGUGACAAGUAACAAACAUGAGAAAGGUGAAACUUGCUGGGAUCGGGAAUCGAAAGAUCCGAAAGCCAGUCUUUAGAGGAUUCUGAACGGGCUAGUGAAAGUAAACUUGUGAUGUGACCAUAUUGUGCAAUAUGAAUGUAAGUUGGUGGUGUGGUCAUCUCACAAGGUGGCUAAGUCAUCUCACUUAUUUUCUUAACGAAAGCAUCAGCCCGUUUAGCAUCAUCUUCUUGAAGCUUGCCUUUCGCAUCUUUUGAUUCCCAAUCCAAGCAAGGUUCACCUUUUUUUUUGCCAUGACCUUUACAAAAUAUCCAAAUUUUG		1
19447	MI0005389	ath-MIR833	Arabidopsis thaliana miR833 stem-loop	GGACGUAGAUGGUACUCUUACAGAUGGUGAUCGUGAAAACAAACGGAGGAGUUUGUUUGUUGUACUCGGUCUAGUUCAAACCAAAACAUCUUUGCAAAUAUGUAUGGUUUGAGCUAGACCGAUGUCAACAAACAAGCUGCUUCGUUUGUAUUCACCAUCAACAUCUUUAAGAAACGCUGCACCACUC		1
19448	MI0005390	ath-MIR834	Arabidopsis thaliana miR834 stem-loop	UACAACAUAUGUUACCAGUUGUGCUAUCAUUUUUUUCAGCGACAGCCAAAAUCACCACCGCUUCUGCUACGAACAUGUUAAGCCAUCCUUUUAACCGUUGCUGCCACCACUAUUACGGCCAUCACAAGAAAAUUCAUGCAAGUGGAAACGGUGAUAGUAGCAGCUGGUAUGACACGUUGGUAGCAGUAGCGGUGGUAAUGCCGAUAGCGUGAGCGGCAAUGGAAGCAUUGGUGGUGUCAGAAGCAGUCA		1
19449	MI0005391	ath-MIR835	Arabidopsis thaliana miR835 stem-loop	UGCUCGAUUCUUCAGAUAGAAAUUCUGGUCAUCUUUGUGUUUAGGCUUUUUCUUGCAUAUGUUCUUUAUCUCUAUUGAUUGAUAUUGUUCAAUGAGCAACAUACUUUUCUCUUCUACCUGGAUUUGUUUGAUGGUUUUAAGAACUCUGUUCUUUUUGACGUUUUACCCAACAAUAUAACUUCUGUUGUAGUCAUCUUCUGCUGCAACCCAUCCACAAAGCUUAUCAUGCAAGAUUAAACCCUUUCUCGAUGGGUUGCAAGAGAACAUCACUAAAAUAGAAGUAACAUUGUUGGGGAAAAACGUCACAAAUCCAGGUAUUAGAGAAUAGGAUGCUGAUCGUUGAAAAUAACUAUCUAUAAAGAUGGAGAAGAUACGCAAGAAAGAGUUGUAAACACAAAGC		1
19450	MI0005392	ath-MIR836	Arabidopsis thaliana miR836 stem-loop	GCAAAGCUGCCAUUUUAUAGUCCAAAACUUAAAUUUCGUGUUUGCAAGUCUCCACCCAUCGAAGGAAACACUAGAAGAGAUAUAAUUUAUUUGAGGGGAGAAAUAUUUGACACGGAAGCAUAGCUCCAUAUCCUUCAAUGGAGGUGUGGUCCUUCAACAAAAAUACCCCCCUCUUGAAACUCUGUUUCACCACACCUCCAUUGAAGGACCUGAAGCUAUGCUUCCUUGUCAUAUUCCUUACCAUCAAAUAAAUGCUCUGUUUUCCUGUGUUUCCUUUGAUGCGUGGAGACUUUUAAAAACGAAAUUUAAGUUUGGGCUAAAAUAAACGGCAGUUUUG		1
19451	MI0005393	ath-MIR837	Arabidopsis thaliana miR837 stem-loop	UUUUUGAUAAAUACUUUUGUUUGCUUACAAGUAUAAAGCCAUCAUGUUUUUUUCAUCAGUUUCUUGUUCGUUUCAAAAUUAUGAUUUUUGUUUACUUACACUCAUAAUCUUGAAACGAACAAAAAACUGAUGGAAAAACAUGAGGACUUUAUACUUGUAAAUAAAUAAAAAUAUUUAUUAGAAA		1
19452	MI0005394	ath-MIR838	Arabidopsis thaliana miR838 stem-loop	UACUUUUCUAAUAUCACGAGGACUUACAUGGCCUCAAGUCACCUGUGGUGUUGUGCAAGAAGGAGAAGCAAAGUCUGUCUAUGUAUUAUGAGAUAGCUACUUCUAUGGCUAGGAUAUAUGUUGUACAAGACCGGCUUUUCUUCUACUUCUUGCACAACCUGAGGUUAUUGAGGCUAUACAAGUCUUCUUCUAUAAUGUUAUUUAUUA		1
19453	MI0005395	ath-MIR839	Arabidopsis thaliana miR839 stem-loop	CUCACUCAUGUGAGCAGAAAGAGUAGCAUGAUAUUUUCUUCAAGGUCUUUACCAACCUUUCAUCGUUCCCUUCUUUGCAAUAACGCUGUUUUGCAAAACCGUGAUAGUGCUGAGCCGAUGAGCCUCUAAUGAAAUUAUAGACUCAUCGGCUCAGGACCAUUGCGGUUGUGCAAAACGGUGUUAUUGCUGAGAAGGGAACGCAUGAGAGGUUGGUAAAGACCUCAAUGGAAUCUUAUGGUACUCUUUUUGCUCACAUGAGUGAGU		1
19454	MI0005396	ath-MIR840	Arabidopsis thaliana miR840 stem-loop	CGUAAAGCAGGUGAUUCACCAAUUUAGGUUUACAUCCACAGUGUGGAAGACACUGAAGGACCUAAACUAACAAAGGUAAACGGCUCAGUGUGCGGGGUAUUACACUCGGUUUAAUGUCUGAAUGCGAUAAUCCGCACGAUGAUCUCUUUAUCUUUGUUUGUUUAGGUCCCUUAGUUUCUUCUAUACCGUGAAUCCAAUCCUGUAUUGGAUGAGCUGGUUUAUGACC		1
19455	MI0005397	ath-MIR841	Arabidopsis thaliana miR841 stem-loop	GCACCAACACUACUAUGUGCAGAAACUCUGUUCUUAAGUUGCUUGUGAAUACGAGCCACUUGAAACUGAAAGAAACAAAGAAACAAUAUCAGUAUAAAAUUUUAUCAAAUUAUACUACAAAAAAUGAAAUUUCUUUGUUUAUUUCAAUUUCUAGUGGGUCGUAUUCACAUGCAACUCAAGACUAGAGUAUCUACAACAUGGUCGACUUGGUG		1
19456	MI0005398	ath-MIR842	Arabidopsis thaliana miR842 stem-loop	CAGUACCGUUCAGGGUGACAGAAACAUUUUCGAAAAGAGAGGCUAUAAGCGGGAUGAUGAAUCCGACCAUGAUGGUGUUGCAGAAAUUUAUGUAUGAUGUAGUUAUUGUCCAGGGAUCGAAACACCAUCAUGGUCAGAUCCGUCAUCCCACUUAUGUUUUCUUAGGUCAACAAAUAUGGACAAUUGAAAAGUGAAGCUC		1
19457	MI0005399	ath-MIR843	Arabidopsis thaliana miR843 stem-loop	AAUGCCCAACAACUUCGCGUUAUUUCUGAAAACUUCAUAUCUAUUUUCUUUUAGGUCGAGCUUCAUUGGAACCAAAUGGUGGCUCAUCCAUCUAUUACUAAAGCUAUACAGCAGGUGGACAAGCCAUCAUCAUGUUCCUGUGAAGCUCGAUCUAAAAGACUACAGAUUUGAGAUUUUCAAAAAUAACAUGAAGUACAUUCUCCAC		1
19458	MI0005400	ath-MIR844	Arabidopsis thaliana miR844 stem-loop	GGAAGGAGAUGUUUGCAGUUGGUUUAAUGAAUCUUUUACAUUGAAGAGAAGGAAUGGUAAGAUUGCUUAUAAGCUGGAUCUUGAGGGUGAGUGGUCUCUUCUACGCAUUGGGCUUAUAAGCCAUCUUACUAGUUCUUCUUUUCAAUGUUGUCUAAGGACGCUGCUUUUAUCAGGUGAUCAUUUGU	MIR844 was first identified by Rajapopalan et al [1], with two mature products names miR844-5p and miR844-3p.  Fahlgren et al identify a cleavage product for the 5' mature sequence, which is therefore assumed to be the dominant mature miRNA [2]. 	1
19459	MI0005401	ath-MIR845a	Arabidopsis thaliana miR845a stem-loop	AGAUAAGGGAUUGCACGAUUUCUCAAUAGUUCCGUCGCUGCGUUUCCAUCACGUCGAUUGCUGUCAGAGCCACGCCUAUGAAGAAUUUGUGCGGCUCUGAUACCAAUUGAUGCUAUGGAAACAUCGAUAUUGCCUGAUUCCGUGUUUCCUUUUACCUUGUUGU		1
19460	MI0005402	ath-MIR846	Arabidopsis thaliana miR846 stem-loop	CAAACAUCUUGAAUCCGUUGAGGUUGAUCACGAUGAUGCCACAUCCGGUUUCAUUCAAGGACUUCUAUUCAGAACAAACUUCAUGAUUUCUGAACUAAUUGGAUAUGAUAAAUGGUAACAAGUAUUCACUUGCAUUCAAGGGACAAAAAAUCAUUGGGAUAUAUGAUUAUGACAAACACGAUUGGAAGCUGAAUGGUUGCGGGAGGCAAGCAGUGGGAUAAUGAUCUGCAAGUGGAAACUUCUUACUUUUAUCAUAUCCCAUCAGCUCGAAAGUCUUGAUGUUAGUUUUGAAUUGAAGUGCUUGAAUUACACCAGAUUUAUUGUGCUCGUGUAUCCCGGUAAAUUCGACUAAUGACCAA		1
19461	MI0005403	ath-MIR848	Arabidopsis thaliana miR848 stem-loop	AAAACUUUCAGAUUGCACAAGAGAAUAUGAAAAAGUAUUAACACAAGCCUUAUAGCUUGGCAAUCUCAUGUCAAAUAAGGAAAAGAAGAGGAACCCAAGGUAUGUUUCUCAUCUACCUUCUUUGACAUGGGACUGCCUAAGCUAAAGGCUUGCCAUGUUAUCACAUCCUUCUUUCAUUUCGUCGCAACCACUUUA		1
19462	MI0005404	ath-MIR849	Arabidopsis thaliana miR849 stem-loop	UAAUUUGGUUAAAUGUUUUCAACAUUUUUUAUUUAUUUAUGAUUGGACAACUACUAGACCAAUGUUUAGUUAGUACAUCCAAUGUUAUAAGUACAAAAUAAUAUGUGUUGGAUCUACUAACUAAACAUUGGUGUAGUAGUUGUCCGACUCUAUUGUUGGGAGCGAGAAGAUUGAUCCCUGGUUUAAUUG		1
19463	MI0005405	ath-MIR850	Arabidopsis thaliana miR850 stem-loop	UUUUAGAUAGUGUUAUGUAUUUAUUUCUUACCUAUAGAAACCUGUCAGCUAAGAUCCGGACUACAACAAAGCACGUCUACUCUACUAUAUUCUUUUGCGAUAAUCAAUAGAUUCUUCUAACAUCGUAAAGGAAGACAAAAGAGUAUACAUACUUAGUUGUCGUCGUAUCUUUGUUGAGAAGUUUCUAAAUGGCACAUAGAAAGUACAUAAAACUAUAUGAA		1
19464	MI0005406	ath-MIR851	Arabidopsis thaliana miR851 stem-loop	UUUUCUUUCUUUUCCUUUUCGUUUGAUUUUGGAAAGCAAGGGACUGUCGUCUCGGUUCGCGAUCCACAAGUAAUCUUUUGUGGAGAUUAUGAAAACAAUCAUCACGAGAGGCUACGUGUGGGUGGCAAACAAAGACGACAAUCCCUAUUCCAGUUCCAUCAGAACUUGAAAUAUCAUGUGAACU		1
19465	MI0005407	ath-MIR852	Arabidopsis thaliana miR852 stem-loop	UUUAUCCUAAACAUCCUAUUAAGUUUUUAUGCUGAAACAAAGCUCAAAGCUCAGAGCUAAGGCGCUUAUCUUCUUUGAUAUUGCAUGGAGUAUGCUUCUACUUCUCUAGGAGAUGCGUUUUAUGGAAAUAUCAAAGAAGAUAAGCGCCUUAGUUCUGAAGAUAAGCGCCUUAUUCACAAAAUGCAUAAGGUUGUAUUCUUUGUUAGGU		1
19466	MI0005408	ath-MIR853	Arabidopsis thaliana miR853 stem-loop	GAGAGGAACAAUUAGGGUUGUUUCAAACAGGGUAAAGUGUUCCUGCUGCUCCCCUCUUUAGCUUGGAGAAGCCAGUAAAUAUCUUUCUCUUCAAGGAACUUGUGGGCCUCAAGAAAACCUGCUAUAAUUCUAGUUUUUCAACAUUCCUCCUUCUGAUAUCAGCAACAACUCCUUACCCUUAAGAAUGGAGAAUGGAACUUCCUCAAAGAUAUUUACUUGGCCUCUGCAACCGGAAAGGGGAGCAGCAUGAAACUCUUUUAACCCUUACCCUGUAUUUGUCAAAAACAGAU		1
19467	MI0005409	ath-MIR824	Arabidopsis thaliana miR824 stem-loop	UAUCACCAUUUGUACUUGAGUUGUCUCUCAUGUCUAGACCAUUUGUGAGAAGGGAGUUUUUGUUUACACCAAUACCCCCCAGUCUCUAAAUUUGUAAGAAGUAUUAUGCUCAAUUAAGGAACAUAGCUAGUUCGACAUACCAUACUACCCUUUUUAAAACUAUCCUAUAUGUUUGAUGCUAGCAUAGCGUAAUUUUGUGUUCUCAUGGUGCAGCAGGGUUAGUUUAUUGUGUACCUCUAGAUAUAUAUUCUCUUGCUGCGUAGGGUUCCCAAGCUGCCAAAAACUUUUAAAAAUUAGUGAUCUGUUCCCCAAACCCCCAUUCAAUAAGAAAGGUCUACCUGUAGCUCACAGUCACAGCUAUUAGAGCUGUCCUUGCUUCUUUGGGUUUACUGUUUUAGUUAAUUAGUUACCCUAUGAAAGUCUGAUCCUUCAGAAGUUAGGUAUAGAAGUAAGUCGAUUAAGUUCAUUCAUGACUUUUCCAGAUGUUGCAUACAUAACUUUUUUUAUUUGUAUUCGAACUAGUCCAAGCCGAUUCUCAAAAUCAUAUAAAAUCAUUUACACCUUGGUCAUGGUAGCUAAGAAUAUUGUAUCUAAAAUUGGGGAGUGGGGAGAUGUUUGGUUAUAUUCCCUUCUCAUCGAUGGUCUAGAUGUGCGAGGUGACUCUCAUGGAGGUAAAGAACAAUGGUGAU		1
19468	MI0005410	ath-MIR847	Arabidopsis thaliana miR847 stem-loop	CAUUUUCUUGUAUUCAAAGUAUCUUAAGUUAAGAAGAGAAUAAGAUUCUUACAUCUUGAUGAAGAGGAAUGGGAAGCCGAAAUCUAAACUGAAACAGAGGCGUCACCCAAUUAUCAAUUGGUAAGUGAUAUCUAUGUUUCGAUCUGUAUCUCGGCCUUUCACUCCUCUUCUUCUUGAUGUAAGAAUUUGUUAUUCGACACAUUAGAUGGAGUGAAAAAUCUGUUAGAUAU		1
19469	MI0005411	ath-MIR855	Arabidopsis thaliana miR855 stem-loop	UUUUGGAGCAAAAGCUAAGGAAAAGGAAGAUAAGGACGAUUUUGGUUCUGGAAUUAGCGAGGAGUGUCGAUCGACACACUCUUGGUGUCGAUCGACACCAGUUUCGGCCCAGCAAAAACCCUAGACGCUUUCGAGUUUACAAGAGCUCAAGUUUGCCCUAGAAGAUUUCAUUAUUUGCAUUAUUAGUCCGUGGACGUUUUUAGGGUCUAUAUAUAUUGUUUUUAGACCUAAGUUUCUUUUAUCAAGUCUUUUAUCAAGCUUUUGCAAAACCA		1
19470	MI0005412	ath-MIR854a	Arabidopsis thaliana miR854a stem-loop	CGGAUGAGGAUAGGGAGGAGGAGUAUGAUACGAGCAUGUAUCAUUUCAGUGAGCACGUACCUCCAGCGCGGGAGAGCAAGAGCUUGAGUGAAGCUCAUAGAAACAACAGUAAGUUGCAGAGGUGGUGCAAGAAACAAGAUAGGCUACUUAUCAAGUGCUUCAAAGCCAUCACGUUUCUGACGGACAAGAUAAGCUGCUUCUCUUCUACUACAGCUAUUCCG		1
19471	MI0005413	ath-MIR854b	Arabidopsis thaliana miR854b stem-loop	CGGAUGAGGAUAGGGAGGAGGAGUAUGAUACGAGCAUGUAUCAUUUCAGUGAGCACGUACCUCCAGCGCGGGAGAGCAAGAGCUUGAGUGAAGCUCACAGAAACAACAGUAAGUUGCAGAGGUGGUGCAAGAAACAAGAUAGGUUACUUAUCAAGUGCUUCAAGGCCAUCACGUUUCUGACGGACAAGAUAAGUUGCUUCUCUUCUACCACAGCUAUUCCG		1
19472	MI0005414	ath-MIR854c	Arabidopsis thaliana miR854c stem-loop	CGGAUGAGGAUAGGGAGGAGGAGUAUGAUACGAGCAUGUAUCAUUUCAGUGAGCACGUACCUCCAGCGCGGGAGAGCAAGAGCUUGAGUGAAGCUCACAGAACCAACAGUAAGUUGCAGAGGUGGUGCAAGAAACAAGAUAGGCUACUUAUCAAGUGCUUCAAAGCCAUCACGUUUCUGACAGACAAGAUAAGCUGCUUCUCUUCUACUACAGCUAUUCCG		1
19473	MI0005415	ath-MIR854d	Arabidopsis thaliana miR854d stem-loop	CGGAUGAGGAUAGGGAGGAGGAGUAUGAUACGAGCAUGUAUCAUUUCAGUGAGCACGUACCUCCAGCGCGGGAGAGCAAGAGCUUGAGUGAAGCUCACAGAAACAACAGUAAGUUGCAGAGGUGGUGCAAGAAACAAGAUAGGUUACUUAUCAAGUGCUUCAAGGCCAUCACGUUUCUGACGGACAAGAUAAGUUGCUUCUCUUCUACCACAGCUAUUCCG		1
19474	MI0005416	hsa-mir-675	Homo sapiens miR-675 stem-loop	CCCAGGGUCUGGUGCGGAGAGGGCCCACAGUGGACUUGGUGACGCUGUAUGCCCUCACCGCUCAGCCCCUGGG		5
19475	MI0005417	cbr-mir-784	Caenorhabditis briggsae miR-784 stem-loop	CUACCAAGUGGCACAAUACCUGUAUGUAGAUAGUGAAGUAAUAUUGUUCUACAUACACCUAUUGAGCCACCUGGUGG		2
19476	MI0005418	cbr-mir-785	Caenorhabditis briggsae miR-785 stem-loop	UUGCUCUUUCGCAACCGUCAGCACAGAGUGCUUCGACUUACACAGAAUUCGUAAAACCAACUGAUGUAAGUGAAUACUCUGUGUUGAUGGUGAUGAUGCUGAA		2
19477	MI0005419	cbr-mir-786	Caenorhabditis briggsae miR-786 stem-loop	GGGACCCUUCCCAACAAAAUCUCAAAUAGUGGCAUUUACACAAGCAAUGGUAUGUAAUGCCCUGUACGAGAUUUGGUUGGUGAGAAGUCUC		2
19478	MI0005420	cbr-mir-787	Caenorhabditis briggsae miR-787 stem-loop	CCUCAAAAUGGAGAAGAAGGAAACUAGACAAUCUUACAUAGCUCAAAAUAAUCUGUAAGCUCGUCUUAGUUUUCCUCUCCUCUCUAGGGA		2
19479	MI0005421	cbr-mir-788	Caenorhabditis briggsae miR-788 stem-loop	ACUAACUUUUCCGCUUCUCAAUGCUCCAUUUGCAAAAUCAAAUUGAUUUUCUUGCAAAUGGGAUGAGAACCGGAAACGUUUGA		2
19480	MI0005422	cbr-mir-789a	Caenorhabditis briggsae miR-789a stem-loop	GAAACGUGGCCUUGUGGCCUAAUGGAUAAGGCGUCUGACUUCUAAUCAGAAGAUUGCAGGUUCGAUCCCUGCCUGGGUCAAAUGUUUUUGUUUU		2
19481	MI0005423	cbr-mir-789b	Caenorhabditis briggsae miR-789b stem-loop	UUGCCCGACUUCGGAUUCACGUGGUCAUCCAGGCGGUGCACGUUAAAAGAUAUAAAUGCCCUGCCUGGGUCACCAUGUGAAUAGGGAAUACGGUCA		2
19482	MI0005424	cbr-mir-790-1	Caenorhabditis briggsae miR-790-1 stem-loop	AAGUCCCUUCCGAUUGCUUGGCACUCGCGAACACCGCGAUCACUUCCAAUAUCGAUCCGCGGAGUUAGCCAGUGUCAACCAAAUGGAUGUUUGAGACUU		2
19483	MI0005425	cbr-mir-790-2	Caenorhabditis briggsae miR-790-2 stem-loop	GACUGCUUGGCACUCGCGAACACCGCGGUCGAAGUUACUCGCGGAGUUAGCCAGUGUCAACCAGAUG		2
19484	MI0005426	cbr-mir-791	Caenorhabditis briggsae miR-791 stem-loop	GAAUUCUCGAUCACCGUAUCACGUGUGGCCAAAGUCAAAUCCAUUAUUGAACAUUGGCACUCCGCUGAUUUGGUGAUCGACUUUUC		2
19485	MI0005427	cbr-mir-792	Caenorhabditis briggsae miR-792 stem-loop	GAAAACAUCGAAAAAUGAGAAAAUUAUAAUUGUUGGAGGUUGUGACACAAAACUAUGAAAUUGAAAUUUUUUCUAUUUUCGGUCCUUUUUC		2
19486	MI0005428	cbr-mir-235	Caenorhabditis briggsae miR-235 stem-loop	UCCGAUCCGGCCAUGGCCAAUUGCAUAUAUUGCUUUUACUUUUUCAAAAUGCGAAUAUUGCACUUUCCCUGGCCAGAUCUGA		2
19487	MI0005429	cbr-mir-242	Caenorhabditis briggsae miR-242 stem-loop	CAAUUCUUCUAAGCCAAAAAAAGAAUAUUGCGUAGGCCUUUGUUUCGAAAGACCCAAAAAUUGUUCGCAGCAAUCUCCUUCGCAAUAUUUUUUGGAAGAGGAAAUG		2
19488	MI0005430	cbr-mir-255	Caenorhabditis briggsae miR-255 stem-loop	GAUGUCUCUUCAUUAUCAGGUAAGAAAUCUUUGUAGUUUUCCGCGAGUCAACGUGAAAACUGAAGAGAUUUUUUACAGAUUCCGGAGGAGCAUC		2
19489	MI0005431	cbr-mir-359	Caenorhabditis briggsae miR-359 stem-loop	GACAAAUCUUCAUCCGUCAGAGCAUAUCUCAGUUACACAACUUCCUAAAUAGUGUCACUGGUUAUCCUCUGUCGAAAUGAAGAUGUC		2
19490	MI0005432	cbr-mir-392	Caenorhabditis briggsae miR-392 stem-loop	AAAUCCUGCAUUUAUCUGACAUCUCACAUUAUUGAGGAUAUAAACUAAAUAAAGAAAUAUCAUCGAUCAUGUGAGCUGUUAGAUUAUCAGAUUU		2
19491	MI0005433	ath-MIR856	Arabidopsis thaliana miR856 stem-loop	AUGUAUAAGAGGUGAGACUGUUGGCUUUAAUCCUACCAAUAACUUCAGCUGCAUCAUGAAGAGUAGACAGAGAUUCUGGCGGUUGAGGGUUUCUUCGUAGAGGUUGAUCGAUUCUUAAUGUCCUGUGGAUUUUAAGUUCCCAAAACUGUUGCUUAGGACAUACAAGAUCGUUCAAUGUCCAAGAAGAAACCUGAGCCGCUACAAUCAUCGGUCUAAUCUCUUUAGCAGAUGAAGUUAUUUGUGGUAUAAAACCCACAGUUUUAUCAUGCAU		1
19492	MI0005434	ath-MIR857	Arabidopsis thaliana miR857 stem-loop	UUCGACUCCUACAACAAACUUUCACCAUACAAAAUAAUGAAGAAAACACCCAAAAAGGUUUGAAUGUGUGAGGUUAGUCUCAUUUUUAAAAUAGUGACUUGUUUUUUUUAAAAUGUUUUUUAAGAAUGUUUUUUCAGCUUUUUAUUUUAUUUUAAACCUAAAGGUAGCGUGACUAUUGUGGAGAAAUAAAGAAACAUAAGAAAAAAUAUUUUUGGUUUAUAGUAAGAUGUUGUUUUAAAAUAUAUAUUUAAAAACAAUGUCACUAUUUUAAACGGAAUAUAGACAUUUUCUAUUAAUGAGAUUAACGUCGAGCAUUUGAAUUUCUAGAUUUUUUUCUAAGUUAUUUUGUAUGUUGAAGGUGUAUUGUAGGAAUCGGA		1
19493	MI0005435	ath-MIR858	Arabidopsis thaliana miR858 stem-loop	CUCAUCUUUGUUUCGUUGUCUGUUCGACCUUGGUCUCGAUCUCUCCUCAAAACCCUAAUACGCGCUUUAUCGUUUAUUUCAUUCAUCCAUCCUUCUUAUGAUCAUCAUAAACUAACGUACAUGGUUUAUCGGUUUGUUAUUGAUGGGGAUUGGGGUAGAUAGACGAUCGAAACUUUUGAUUUCUGAG		1
19494	MI0005436	ath-MIR859	Arabidopsis thaliana miR859 stem-loop	AAAGGUAGAUGUCGAAAUCUCUCUGUUGUGAAGUCAAACAUGAGUAUGAAUUAACAUUAAUGGAUCUUUUUGAUUCAUAAUACUCAUGUUUGGUUUCACAGUAGAUAGAUAUCGACGUCUAUCUUU		1
19495	MI0005437	ath-MIR860	Arabidopsis thaliana miR860 stem-loop	AUGUCUUGGUUAAAUUCAAUAUAUAUAGUCCAAUCUAUUGAAGUACUAGUACACCAGCUCUAAUAAGCUGAUGUGGGUAAGUAGUUCAAUAGAUUGGACUAUGUAUAUUAAAUUUGACUAAGAGAU		1
19496	MI0005438	ath-MIR861	Arabidopsis thaliana miR861 stem-loop	GUAUCAUUGUUUUCGAACGAUGUCCUUGGAGAAAUAUGCGUCAAUGGAGUCCGUCUUCUUGAGAAGCAUUUUUGAGUGAGAAUGAUUCUCAUGAUGGAUAUGUCUUCAAGGACUUCUUUCAAACAAUGGUAC		1
19497	MI0005439	ath-MIR862	Arabidopsis thaliana miR862 stem-loop	ACAGUAGUUUUCCAAUAGGUCGAGCAUGUGCUGAAACUGUGUGUACAGAGUUCUCAUAAACACACAGUUUCAGCAUAUGCUGGAUCUACUUGAAGACUACUGU		1
19498	MI0005440	ath-MIR863	Arabidopsis thaliana miR863 stem-loop	CUCAUAAGAUGUAGAAACUAGAGAAGAGUUUGGGGGAAAACUCUUUCUUAUGUCUUGUUGAUCUCAAUAGCAUUGAUACAAUGUAUAUAUAUGCAAUUUAGAAUAUGUUUUUCCUAAUUUGAAUAAGAAAUAGAUAAACAUGAAUAAGUAUAUAUAUAUUUCCUAUUUAGAAUAUUUAUUUAUUCAAAUUAGGUGAAACAUAAUCUAGGUUGUAUAUAUAUAUGUUAUACCAAUGCGAUUGAGAGCAACAAGACAUAAUAAAGAGUUUUCGAAAACUUUUUUCUAGUUUCUACAUAAGAGGAG		1
19499	MI0005441	ath-MIR864	Arabidopsis thaliana miR864 stem-loop	GCUUCAGGUAUGAUUGACUUCAAAAAAUACCUUGAAACUAUAAACCUCAGUUUCUUUGAAUUUGAUUUUUAAAGUCAAUAAUACCUUGAAGC		1
19500	MI0005442	ath-MIR865	Arabidopsis thaliana miR865 stem-loop	GAUCUGGGAUGAAUUUGGAUCUAAUUGAGCAAAAAAUUGUGUUUUUUCAAUCUAUUGAAUUUCACAUCCUUAAACCCUUGCAUAUUCAAUCUAUUGAAUUUCGCAUAUUUUUCCUCAAAUUUAUCCAAAAUCAUCCCAAAUC		1
19501	MI0005443	ath-MIR866	Arabidopsis thaliana miR866 stem-loop	UCAUCUAUUCUUACUUUUCAAGGAACGGAUUUUGUUAACUAAAUGAUUCACACCCUUGAAGAAACACGAUCUCGUGUGAAUCAUUUCGUUAACAAAAUCCGUCUUUGAAGAGUAAGUAUAUUGUGA		1
19502	MI0005444	ath-MIR845b	Arabidopsis thaliana miR845b stem-loop	AGUCGGUUUCCAUCACGUCAAUUGCUAUCAGAGCAACGCAUGAUGUAUAAUAACUAAGCGUCGCUCUGAUACCAAAUUGAUGCAAUGGAAACAUCGAUU		1
19503	MI0005445	ath-MIR867	Arabidopsis thaliana miR867 stem-loop	ACACAUAAAACUAGUAUAUUGCCUUGAACAUGGUUUAUUAGGAAAGACAUGAGAACAUAUCUGAACAUAGUUUUUCCUUAUAUACAAUGUUCAAAGUAAUGAAUUAGUUUUAUUUUGU		1
19504	MI0005446	ath-MIR868	Arabidopsis thaliana miR868 stem-loop	GAAUAAGCAUUGUCGGCACUUGAGAAUGUAAAGUGAUGAUCAGCUAUCGUAUUUCAUGUCGUAAUAGUAGUCACGUUAGGGUGAUAUAACGAGGCGAGAGUUAUAUCAUCAUAGUGCGAUUUCUAUUAUGACAUAAAAUACGUUUUGGAUUUUAAAACACUUGACCUUCUUAAGUGCUGAUAAUGCUUCUUUC		1
19505	MI0005447	ath-MIR869	Arabidopsis thaliana miR869 stem-loop	GCCCACCAUACAGAUUUCCAUACGGUAGAAGAAAGUAUCACCUAUCUCAACUCCAGGAUUGGACCAGUACUAGGCUCAUCAUAGUUAAGCCACAAUCCACGAUUCCUCAUCAGCUAUAAAAGCAAAACCUUCAUAUCUAUCCUUGUUUCUAAACCAGUCUCAUAGAUAUGAAGGCUUUGUUUCUGAUGAAGGAUUGUGGGAUUGUUGCUUAACACUGAUGAGCAUAUUAUUGGUUCAAUUCUGGUGUUGAGAUAGUUGACACUUCUUAUACCGUAUGAAAACAUGUGUGGUGGGC		1
19506	MI0005448	ath-MIR870	Arabidopsis thaliana miR870 stem-loop	GAUCGAAGAACAUCAAAUUAGAAUGUGAUGCAAAACUUAGACUCCUAACAUUUGCAACACAAUCUAAUUUGGUGUUUCUUCGAUC		1
19507	MI0005450	mmu-mir-181d	Mus musculus miR-181d stem-loop	ACAAUUAACAUUCAUUGUUGUCGGUGGGUUGUGAGGAGGCAGCCAGACCCACCGGGGGAUGAAUGUCACUGU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2]. 	6
19508	MI0005451	bta-let-7a-2	Bos taurus let-7a-2 stem-loop	AGGUUGAGGUAGUAGGUUGUAUAGUUUAGAAUUACAUCAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCU		44
19509	MI0005452	bta-let-7a-3	Bos taurus let-7a-3 stem-loop	GGGUGAGGUAGUAGGUUGUAUAGUUUGGGGCUCUGCCCUGCUAUGGGAUAACUAUACAAUCUACUGUCUUUCCU		44
19510	MI0005453	bta-let-7b	Bos taurus let-7b stem-loop	CGGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGUAGUGAUGUUGCCCCUCGGAAGAUAACUAUACAACCUACUGCCUUCCCUG	The 3' end of the bovine let-7b hairpin precursor falls in a gap in the genome assembly.  The sequence shown here is predicted from human. 	44
19511	MI0005454	bta-let-7c	Bos taurus let-7c stem-loop	GCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGC		44
19512	MI0005455	bta-let-7e	Bos taurus let-7e stem-loop	CCCGGGCUGAGGUAGGAGGUUGUAUAGUUGAGGAGGACACCCAAGGAGAUCACUAUACGGCCUCCUAGCUUUCCCCAGG		44
19513	MI0005456	bta-mir-103-2	Bos taurus miR-103-2 stem-loop	UUGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUUCAGGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAAC		44
19514	MI0005457	bta-mir-125b-2	Bos taurus miR-125b-2 stem-loop	GACUUUUCCUAGUCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAGCAUCACAAGUCAGGCUCUUGGGACCUAGGCGGAGGGGA		44
19515	MI0005458	bta-mir-15a	Bos taurus miR-15a stem-loop	CCUUGGAGUAAAGUAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCAAAAAUACAAGG		44
19516	MI0005459	bta-mir-195	Bos taurus miR-195 stem-loop	AGCUCCCCUGGCUCUAGCAGCACAGAAAUAUUGGCACUGGGAAGAAAGCCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG		44
19517	MI0005460	bta-mir-19a	Bos taurus miR-19a stem-loop	GCAGUCCUCUGUUAGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGAUGGUGGCCUGC		44
19518	MI0005461	bta-mir-19b	Bos taurus miR-19b stem-loop	CACUGUUCUAUGGUUAGUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUGACUGUGGUAGUG		44
19519	MI0005462	bta-mir-204	Bos taurus miR-204 stem-loop	UUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCAC		44
19520	MI0005463	bta-mir-331	Bos taurus miR-331 stem-loop	GAGUUUGGUUUUGUUUGGGUUUGUUCUAGGUAUGGUCCCAGGGAUCCCAGAUCAAACCAGGCCCCUGGGCCUAUCCUAGAACCAACCUAA		44
19521	MI0005464	bta-mir-34a	Bos taurus miR-34a stem-loop	GGCCAGCUGUGAGUGUUUCUUUGGCAGUGUCUUAGCUGGUUGUUGUGAGUAAUAAUGCAGGAAGCAAUCAGCAAGUAUACUGCCCUAGAAGUGCUGCACGUUGUGGG		44
19522	MI0005465	bta-mir-365	Bos taurus miR-365 stem-loop	ACCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUGCAUUCCACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA		44
19523	MI0005466	bta-mir-374	Bos taurus miR-374 stem-loop	UACAUCGGCCAUUAUAAUACAACCUGAUAAGUGUUACAGCACUUAUCAGGUUGUAUUGUAAUUGUCUGUGUA		44
19524	MI0005467	bta-mir-497	Bos taurus miR-497 stem-loop	CCACCCCAGUCCUGCUCCCGCCCCAGCAGCACACUGUGGUUUGUACGGCACUGUGGCCACGUCCAAACCACACUGUGGUGUUAGAGCGAGGGUGGGGGAGGCACCGCUGAGG		44
19525	MI0005468	bta-mir-660	Bos taurus miR-660 stem-loop	CUGCUCCUUCUCCCGUACCCAUUGCAUAUCGGAGCUGUGAAUUCUCAAAGCACCUCCUAUGUGCAUGGAUUACAGGAGGG		44
19526	MI0005469	bta-mir-99b	Bos taurus miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC		44
19527	MI0005470	mmu-mir-743b	Mus musculus miR-743b stem-loop	UGCAGUGCUGUGUUCAGACUGGUGUCCAUCAUGUGAAAUAUUUGUGAAAGACAUCAUGCUGAAUAGAGUAAGGCCCA		6
19528	MI0005471	mmu-mir-871	Mus musculus miR-871 stem-loop	UGCAGUGCUCUAUUCAGAUUAGUGCCAGUCAUGUGAAAUACAUAUGACUGGCACCAUUCUGGAUAAUGUAAUGCUCA		6
19529	MI0005472	mmu-mir-879	Mus musculus miR-879 stem-loop	UUCUAGGUCCAGAGGCUUAUAGCUCUAAGCCUUGGAUGAAAGAGGCUUAUGGCUUCAAGCUUUCGGAGCUGGAGAC		6
19530	MI0005473	mmu-mir-880	Mus musculus miR-880 stem-loop	UGCACUGCAAUACUCAGAUUGAUAUGAGUCACUUCCUAUUGCAUGUUACUCCAUCCUCUCUGAGUAGAGUAAGGCACA		6
19531	MI0005474	mmu-mir-881	Mus musculus miR-881 stem-loop	UGCAGUACAAUAUUCAGAGAGAUAACAGUCACAUCUUUUCUAAAGUAACUGUGUCUUUUCUGAAUAGAGUAAUGUUCA		6
19532	MI0005475	mmu-mir-882	Mus musculus miR-882 stem-loop	CAGCAGUACCAGGAGAGAGUUAGCGCAUUAGUGCAAUAGUUAGUCCUGAUUUCUGGGUUUUUCUAAUGGCUGCUCUU		6
19533	MI0005476	mmu-mir-883a	Mus musculus miR-883a stem-loop	GCACUAUAAUGCUGAGAGAAGUAGCAGUUACUUUAUUCUAUAAGUAACUGCAACAGCUCUCAGUAUUGUAAGGCUC		6
19534	MI0005477	mmu-mir-883b	Mus musculus miR-883b stem-loop	UGCAAUGCAUUACUGAGAAUGGGUAGCAGUCACUUUGUACUAUGAGUAACUGCAACAUCUCUCAGUAUUGUAAGGUUC		6
19535	MI0005478	mmu-mir-190b	Mus musculus miR-190b stem-loop	UGCUUCUGUGUGAUAUGUUUGAUAUUGGGUUGUUAAAUUAUGAACCAACUGAAUGUCAAGCAUACUCUCACAGCAGUAAG		6
19536	MI0005479	mmu-mir-874	Mus musculus miR-874 stem-loop	UUAGCCCUGCGGCCCCACGCACCAGGGUAAGAGAGACUCACUUCCUGCCCUGGCCCGAGGGACCGACUGGCUGGGC		6
19537	MI0005480	mmu-mir-876	Mus musculus miR-876 stem-loop	UCACGUGCUAUGGAUUUCUCUGUGAAUCACUAUAUCAAAUCUAGUGUGGUAGUGGUUUACAAAGUAAUUCAUAGUGCUUCA		6
19538	MI0005481	mmu-mir-105	Mus musculus miR-105 stem-loop	UGCAUUUUAGCCAAGUGCUCAGAUGCUUGUGGUGGCUGCUUAUGCACCACGAAUGCUUGAGCAUGUGCUAUGGUACCUAC		6
19539	MI0005482	mmu-mir-147	Mus musculus miR-147 stem-loop	UAUGAAUCUAGUGGAAACAUUUCUGCACAAACUAGAUGUUGAUGCCAGUGUGCGGAAAUGCUUCUGCUACAUUUGUAGG		6
19540	MI0005483	mmu-mir-18b	Mus musculus miR-18b stem-loop	UCUCUUGUGUUAAGGUGCAUCUAGUGCUGUUAGUGAAGCAGCUUACAAUCUACUGCCCUAAAUGCCCCUUCUCGCACAGGCUA		6
19541	MI0005484	mmu-mir-193b	Mus musculus miR-193b stem-loop	GGCCCAGAAUCGGGGUUUUGAGGGCGAGAUGAGUUUGUGUUUUAUCCAACUGGCCCACAAAGUCCCGCUUUUGGGGUCA		6
19542	MI0005485	mmu-mir-197	Mus musculus miR-197 stem-loop	GGGGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCCGGCA		6
19543	MI0005487	mmu-mir-220	Mus musculus miR-220 stem-loop	UUGUAGGGCUCCACCACAGUGUCAGACACUUUGGGUGAGGGCACCACACUGAAGGUGUUCAUGAUGCGGUCGGGAUACUCCUCACG		6
19544	MI0005488	mmu-mir-297a-3	Mus musculus miR-297a-3 stem-loop	CUGUGUGUAUAUGUAUGUGUGCAUGUGCAUGUGUGUAUAUGAAUAUACAUAUACAUACACACAUACCCAUACAAACAUGCACACAAACACACAGAAAAUUGA		6
19545	MI0005489	mmu-mir-297a-4	Mus musculus miR-297a-4 stem-loop	CUGUGUGUAUAUGUAUGUGUGCAUGUGCAUGUGUGUAUAUGAGUAUACAUAUACAUACACACAUACCCAUACAAGCAUGCACACAAAUACACGCAAAA		6
19546	MI0005490	mmu-mir-297a-5	Mus musculus miR-297a-5 stem-loop	CUGUGUGUAUAUGUAUGUGUGCAUGUGCAUGUGUGUAUAUGAGUAUACAUAUACAUACGCACAUACCCAUACAAGCAUGCACACAAACCC		6
19547	MI0005491	mmu-mir-297a-6	Mus musculus miR-297a-6 stem-loop	AUGUGCAUGUGUGUAUGUGCAUGAGUGCAUGUGCAUGCAUGUGUGUGCGCAUGUAUGUGUGCAUGUGCAUGUAUGUGUGCAU		6
19548	MI0005492	mmu-mir-297c	Mus musculus miR-297c stem-loop	CUGUGUGUAUAUGUAUGUGUGCAUGUACAUGUGUGUAUAUGAAUAUACAUAUACAUACACACAUACCCAUACAAACAUGCAUACAAACACACAAAAAU		6
19549	MI0005493	mmu-mir-327	Mus musculus miR-327 stem-loop	UGCCCUUAUAACUUGAGGGGCAUGAGGAUAGUCAGUAGUCCAACAUCCCUCUUGAUGGCACAUUGCACA		6
19550	MI0005494	mmu-mir-343	Mus musculus miR-343 stem-loop	UGGGAUAGAGUGGGUGUGGCGGGGGUAGCAGAGCCCAGGGCAACCUCUCCCUUCAUGUGCCCAGAUCCUGCAUGC		6
19551	MI0005495	mmu-mir-344-2	Mus musculus miR-344-2 stem-loop	UUUUUACCAGUCAGGCUCCUGGCUAGAUUCCAGGUACCAACUGGUACCUGAUCUAGCCAAAGCCUGACUGUAAGCUGCAA		6
19552	MI0005496	mmu-mir-421	Mus musculus miR-421 stem-loop	CAUUGUAGGCCUCAUUAAAUGUUUGUUGAAUGAAAAAAUGAAUCAUCAACAGACAUUAAUUGGGCGCCUGCUCUGU		6
19553	MI0005497	mmu-mir-453	Mus musculus miR-453 stem-loop	AGAAGAUGCAGGAGUGCUGUGAGAAGUGCCAUCCCCUGGUACUUGGAGGGAGGUUGCCUCAUAGUGAGCUUGCAUUAUUUAA		6
19554	MI0005498	mmu-mir-465b-1	Mus musculus miR-465b-1 stem-loop	UGCAAUGCCCUAUUUAGAAUGGUGCUGAUCUGAUGAAAUAAAAAAUUGAUCAGGGCCUUUCUAAGUAGAGUAAGGCUUA		6
19555	MI0005499	mmu-mir-465b-2	Mus musculus miR-465b-2 stem-loop	UGCAAUGCCCUAUUUAGAAUGGUGCUGAUCUGAUGAAAUAAAAAAUUGAUCAGGGCCUUUCUAAGUAGAGUAAGGCUUA		6
19556	MI0005500	mmu-mir-465c-1	Mus musculus miR-465c-1 stem-loop	UGCAAUGCCCUAUUUAGAAUGGCGCUGAUCUGAUGAAUAAAAAAAAAAUGAUCAGGGCCUUUCUAAGUAGAGUAAGGCUUA		6
19557	MI0005501	mmu-mir-465c-2	Mus musculus miR-465c-2 stem-loop	UGCAAUGCCCUAUUUAGAAUGGCGCUGAUCUGAUGAAUAAAAAAAAAAUGAUCAGGGCCUUUCUAAGUAGAGUAAGGCUUA		6
19558	MI0005502	mmu-mir-466b-1	Mus musculus miR-466b-1 stem-loop	UGUAUGUGUUGAUGUGUGUGUACAUGUACAUGUGUGAAUAUGAUAUACAUAUACAUACACGCACACAUAAGACACAUAUGAG		6
19559	MI0005503	mmu-mir-466b-2	Mus musculus miR-466b-2 stem-loop	UGUAUGUGUUGAUGUGUGUGUACAUGUACAUGUCUGAAUAUGAUAUACAUAUACAUACACGCACACAUAAGACACAUAUGAG		6
19560	MI0005504	mmu-mir-466b-3	Mus musculus miR-466b-3 stem-loop	UAUAUGUGUUGAUGUGUGUGUACAUGUACAUGUGUGAAUAUGAUAUACAAAUACAUACACGCACACAUAAGACACAUAUGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [1].  The 5' end of the miRNA may be offset with respect to previous annotations. 	6
19561	MI0005505	mmu-mir-466c	Mus musculus miR-466c stem-loop	GUAUAUGUGUUGAUGUGUGUGUGCAUGUACAUAUGUGAAUAUGAUAUACAUAUACAUACACGCACACAUAAGACACAUAUGAGC		6
19562	MI0005506	mmu-mir-466e	Mus musculus miR-466e stem-loop	GUGUAUGUGUUGAUGUGUGUGUACAUGUACAUAUGUGAAUAUGAUAUACAUAUACAUACACGCACACAUAAGACACAUAUGAGC		6
19563	MI0005507	mmu-mir-466f-1	Mus musculus miR-466f-1 stem-loop	CAUGUGUGUUUACGUGUGUGUGCAUGUGCAUGUGUGUAUAUGAAUAUACAUACACAUACACACACACAUACACACACAUGCAACACACACAUAU	Landgraf et al. identify several offset sequences which map to the 3' arm of the miR-466f hairpin precursors [1].  One sequence consistent with all three putative hairpin loci is shown here. 	6
19564	MI0005508	mmu-mir-466f-2	Mus musculus miR-466f-2 stem-loop	AAUGUGUGUUUACGUGUGUGUGCAUGUGCAUGUGUGUAUAUGAAUAUAUGUAUACAUACACACACACAUACACACUCAUGUAACACACACACAC	Landgraf et al. identify several offset sequences which map to the 3' arm of the miR-466f hairpin precursors [1].  One sequence consistent with all three putative hairpin loci is shown here. 	6
19565	MI0005509	mmu-mir-466f-3	Mus musculus miR-466f-3 stem-loop	CAUGUGUGUUUACGUGUGUGUGCAUGUGCAUGUGUGUAUAUGAAUAUAUGUAUACAUACACACACACAUACACACGCACGCAACACACACACAC	Landgraf et al. identify several offset sequences which map to the 3' arm of the miR-466f hairpin precursors [1].  One sequence consistent with all three putative hairpin loci is shown here. 	6
19566	MI0005510	mmu-mir-466g	Mus musculus miR-466g stem-loop	UGUGUUUUCGUGUGUGUGCAUGUGGAUGUAUGUAUAUGAUUUUGCAUAUACAGACACAUGCACACACAUGCGGCACACAC		6
19567	MI0005511	mmu-mir-466h	Mus musculus miR-466h stem-loop	UGUAUAUUUGUGUGUGCAUGUGCUUGUGUGUAUGUGAAUAUAUAUAUCAUACGCACGCACACACACACACAAAUGCAAGCA		6
19568	MI0005512	mmu-mir-467c	Mus musculus miR-467c stem-loop	CCUUUGUGCAUAAGUGCGUGCAUGUAUAUGUGUGUAUAUUUUAUGCAUAUACAUACACACACCUAUACACACAUGCACACAGACAUGCGAGAAUGGC		6
19569	MI0005513	mmu-mir-467d	Mus musculus miR-467d stem-loop	CCUGUGUGCAUAAGUGCGCGCAUGUAUAUGCGUGUAUAUUUUAUGCAUAUACAUACACACACCUACACACACAUGCACACAGACA		6
19570	MI0005514	mmu-mir-493	Mus musculus miR-493 stem-loop	CGCCAGGGCCUUGUACAUGGUAGGCUUUCAUUCAUUUUUUGCACAUUCGGUGAAGGUCCUACUGUGUGCCAGGCCCUGUGCCA		6
19571	MI0005515	mmu-mir-504	Mus musculus miR-504 stem-loop	UCCUGUUGGGAGACCCUGGUCUGCACUCUAUCUGUAAACUUACUGAAGGGAGAGCAGGGCAGGGUUUCCCAUACAGAGG		6
19572	MI0005516	mmu-mir-509	Mus musculus miR-509 stem-loop	GUGGUUCUUUACUCCAGAAUGUGGCAAUCAUGCAUAAUUAAAUGUGAUUGACAUUUCUGUAAUGGAGUAACACAU		6
19573	MI0005517	mmu-mir-568	Mus musculus miR-568 stem-loop	ACACUAUAUUAUGUAUAAAUGUAUACACACUUCUAUAUAUGUCCACAUAUAUGCGGUGUGUGUAUUAUACAGGUAUAGGUGUG		6
19574	MI0005518	mmu-mir-574	Mus musculus miR-574 stem-loop	UGCGGGCGUGUGAGUGUGUGUGUGUGAGUGUGUGUCGCUCCAAGUCCACGCUCAUGCACACACCCACACGCCCGCACG		6
19575	MI0005519	mmu-mir-590	Mus musculus miR-590 stem-loop	AGUCAGAAAUGAGCUUAUUCAUAAAAGUGCAGUAUGGUGAAGUCAAUCUGUAAUUUUAUGUAUAAGCUAGUCUCUGAUUGA		6
19576	MI0005520	mmu-mir-654	Mus musculus miR-654 stem-loop	CUCGGUAAGUGGGAAGAUGGUAAGCUGCAGAACAUGUGUGUUUCUCAUGUCAUAUGUCUGCUGACCAUCACCUUUGGGUCUCUG		6
19577	MI0005521	mmu-mir-92b	Mus musculus miR-92b stem-loop	GGUGGGCGGGAGGGACGGGACGUGGUGCAGUGUUGUUCUUUCCCCUGCCAAUAUUGCACUCGUCCCGGCCUCCGGCCCCCUCG		6
19578	MI0005523	hsa-mir-298	Homo sapiens miR-298 stem-loop	UCAGGUCUUCAGCAGAAGCAGGGAGGUUCUCCCAGUGGUUUUCCUUGACUGUGAGGAACUAGCCUGCUGCUUUGCUCAGGAGUGAGCU		5
19579	MI0005524	hsa-mir-891a	Homo sapiens miR-891a stem-loop	CCUUAAUCCUUGCAACGAACCUGAGCCACUGAUUCAGUAAAAUACUCAGUGGCACAUGUUUGUUGUGAGGGUCAAAAGA		5
19580	MI0005525	hsa-mir-300	Homo sapiens miR-300 stem-loop	UGCUACUUGAAGAGAGGUAAUCCUUCACGCAUUUGCUUUACUUGCAAUGAUUAUACAAGGGCAGACUCUCUCUGGGGAGCAAA		5
19581	MI0005527	hsa-mir-886	Homo sapiens miR-886 stem-loop	CACUCCUACCCGGGUCGGAGUUAGCUCAAGCGGUUACCUCCUCAUGCCGGACUUUCUAUCUGUCCAUCUCUGUGCUGGGGUUCGAGACCCGCGGGUGCUUACUGACCCUUUUAUGCAAUAA		5
19582	MI0005528	hsa-mir-892a	Homo sapiens miR-892a stem-loop	GCAGUGCCUUACUCAGAAAGGUGCCAGUCACUUACACUACAUGUCACUGUGUCCUUUCUGCGUAGAGUAAGGCUC		5
19583	MI0005529	hsa-mir-220b	Homo sapiens miR-220b stem-loop	UUGUAGGGCUCCACCACCGUGUCUGACACUUUGGGCGAGGGCACCACGCUGAAGGUGUUCAUGAUGCGGUCUGGGAACUCCUCGCGG		5
19584	MI0005530	hsa-mir-509-2	Homo sapiens miR-509-2 stem-loop	CAUGCUGUGUGUGGUACCCUACUGCAGACAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGGUAGAGUACUGCAUGACAC	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [3].  The cloned miR-509-5p sequence from [3] includes a 1 nt extension at the 3' end (A), which is incompatible with the genome sequence. 	5
19585	MI0005531	hsa-mir-450b	Homo sapiens miR-450b stem-loop	GCAGAAUUAUUUUUGCAAUAUGUUCCUGAAUAUGUAAUAUAAGUGUAUUGGGAUCAUUUUGCAUCCAUAGUUUUGUAU		5
19586	MI0005532	hsa-mir-874	Homo sapiens miR-874 stem-loop	UUAGCCCUGCGGCCCCACGCACCAGGGUAAGAGAGACUCUCGCUUCCUGCCCUGGCCCGAGGGACCGACUGGCUGGGC		5
19587	MI0005533	hsa-mir-890	Homo sapiens miR-890 stem-loop	GGAAGUGCCCUACUUGGAAAGGCAUCAGUUGCUUAGAUUACAUGUAACUAUUCCCUUUCUGAGUAGAGUAAGUCUUA		5
19588	MI0005534	hsa-mir-891b	Homo sapiens miR-891b stem-loop	CCUUAAUCCUUGCAACUUACCUGAGUCAUUGAUUCAGUAAAACAUUCAAUGGCACAUGUUUGUUGUUAGGGUCAAAAGA		5
19589	MI0005536	hsa-mir-220c	Homo sapiens miR-220c stem-loop	CACUGGGACCACACAGGGCUGUUGUGAAGACUCAGUGAGCUCAUCCCCACACAGCCUUCAGCACAGGGCCUGGCUCAGGGCAG		5
19590	MI0005537	hsa-mir-888	Homo sapiens miR-888 stem-loop	GGCAGUGCUCUACUCAAAAAGCUGUCAGUCACUUAGAUUACAUGUGACUGACACCUCUUUGGGUGAAGGAAGGCUCA		5
19591	MI0005538	hsa-mir-892b	Homo sapiens miR-892b stem-loop	UGCAAUGCCCUACUCAGAAAGGUGCCAUUUAUGUAGAUUUUAUGUCACUGGCUCCUUUCUGGGUAGAGCAAGGCUCA		5
19592	MI0005539	hsa-mir-541	Homo sapiens miR-541 stem-loop	ACGUCAGGGAAAGGAUUCUGCUGUCGGUCCCACUCCAAAGUUCACAGAAUGGGUGGUGGGCACAGAAUCUGGACUCUGCUUGUG		5
19593	MI0005540	hsa-mir-889	Homo sapiens miR-889 stem-loop	GUGCUUAAAGAAUGGCUGUCCGUAGUAUGGUCUCUAUAUUUAUGAUGAUUAAUAUCGGACAACCAUUGUUUUAGUAUCC		5
19594	MI0005541	hsa-mir-875	Homo sapiens miR-875 stem-loop	UUAGUGGUACUAUACCUCAGUUUUAUCAGGUGUUCUUAAAAUCACCUGGAAACACUGAGGUUGUGUCUCACUGAAC		5
19595	MI0005542	hsa-mir-876	Homo sapiens miR-876 stem-loop	UGAAGUGCUGUGGAUUUCUUUGUGAAUCACCAUAUCUAAGCUAAUGUGGUGGUGGUUUACAAAGUAAUUCAUAGUGCUUCA		5
19596	MI0005543	hsa-mir-708	Homo sapiens miR-708 stem-loop	AACUGCCCUCAAGGAGCUUACAAUCUAGCUGGGGGUAAAUGACUUGCACAUGAACACAACUAGACUGUGAGCUUCUAGAGGGCAGGGA		5
19597	MI0005544	hsa-mir-147b	Homo sapiens miR-147b stem-loop	UAUAAAUCUAGUGGAAACAUUUCUGCACAAACUAGAUUCUGGACACCAGUGUGCGGAAAUGCUUCUGCUACAUUUUUAGG		5
19598	MI0005545	hsa-mir-190b	Homo sapiens miR-190b stem-loop	UGCUUCUGUGUGAUAUGUUUGAUAUUGGGUUGUUUAAUUAGGAACCAACUAAAUGUCAAACAUAUUCUUACAGCAGCAG		5
19599	MI0005546	mmu-mir-466d	Mus musculus miR-466d stem-loop	CAUGUGUGUUUGUGUGUGCGUACAUGUACAUGUGUGUAUAUGAAUAUACAUAUACAUACACGCACACAUAGAUACGCACGCACACACACACACAGG	miR-466d-3p reported in [1] has an additional 3' U base which is inconsistent with the current genome sequence (as shown here). 	6
19600	MI0005547	mmu-mir-449b	Mus musculus miR-449b stem-loop	AGACUCGGGUAGGCAGUGUUGUUAGCUGGCUGCGUUGGGUCAGGCCAGCAGCCACAGCUACCCUGCCACUUCCUUCUGGC		6
19601	MI0005548	mmu-mir-878	Mus musculus miR-878 stem-loop	UGCAAUGCUUUAUCUAGUUGGAUGUCAAGACACGUGAAACUUAAGUGCAUGACACCACACUGGGUAGAGGAGGGCUCA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	6
19602	MI0005549	mmu-mir-872	Mus musculus miR-872 stem-loop	AACUUGUUAGAAGGUUACUUGUUAGUUCAGGACCUCAUUACUUUCUGCCUGAACUAUUGCAGUAGCCUCCUAACUGGUUAU	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	6
19603	MI0005550	mmu-mir-873	Mus musculus miR-873 stem-loop	GUGUGCAUUUGCAGGAACUUGUGAGUCUCCUAUUGAAAAUAGACAGGAGACUGACAAGUUCCCGGGAACACCCACAA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	6
19604	MI0005551	mmu-mir-875	Mus musculus miR-875 stem-loop	UCUGUGGUACUAUACCUCAGUUUUAUCAGGUGUUCAUUAAAAUCACCUGAAAAUACUGAGGCUAUGUUUCACUGAGCA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was independently shown in human and rat [2]. 	6
19605	MI0005552	mmu-mir-208b	Mus musculus miR-208b stem-loop	CCUCUCAGGGAAGCUUUUUGCUCGCGUUAUGUUUCUCAUCCGAAUAUAAGACGAACAAAAGGUUUGUCUGAGGGCUG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	6
19606	MI0005553	mmu-mir-877	Mus musculus miR-877 stem-loop	GUAGAGGAGAUGGCGCAGGGGACACAAGGUAGGCCUUGCGGGUCUGUGGACCCUUGGACAUGUGUCCUCUUCUCCCUCCUCCCAG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	6
19607	MI0005554	mmu-mir-511	Mus musculus miR-511 stem-loop	GAUACCCACCAUGCCUUUUGCUCUGCACUCAGUAAAUAAUAAUUUGUGAAUGUGUAGCAAAAGACAGGAUGGGGAUCCA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was independently shown in human and rat [2]. 	6
19608	MI0005555	mmu-mir-544	Mus musculus miR-544 stem-loop	CACCUAGGGAUCUUGUUAAAAAGCAGAGUCUGAUUGAGGGGCCAAGAUUCUGCAUUUUUAGCAAGCUCUCAAGUGAUG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was independently shown in human and rat [2]. 	6
19609	MI0005556	mmu-mir-598	Mus musculus miR-598 stem-loop	GCUGAUGCUGGCGGUGAUGCCGAUGGUGCGAGCUGAAAAUGGGCUGCUACGUCAUCGUCGUCAUCGUUAUCAUCAUCAU	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was independently shown in human and rat [2]. 	6
19610	MI0005557	mmu-mir-653	Mus musculus miR-653 stem-loop	CAUUCUUUCAGUGUUGAAACAAUCUCUACUGAACCAAGCUCCAAAGCGAGUUCACUGGAGUUUGUUUCAGUAUUGCAGGAGUGCU	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was independently shown in human and rat [2]. 	6
19611	MI0005559	hsa-mir-744	Homo sapiens miR-744 stem-loop	UUGGGCAAGGUGCGGGGCUAGGGCUAACAGCAGUCUUACUGAAGGUUUCCUGGAAACCACGCACAUGCUGUUGCCACUAACCUCAACCUUACUCGGUC	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19612	MI0005560	hsa-mir-885	Homo sapiens miR-885 stem-loop	CCGCACUCUCUCCAUUACACUACCCUGCCUCUUCUCCAUGAGAGGCAGCGGGGUGUAGUGGAUAGAGCACGGGU	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19613	MI0005561	hsa-mir-877	Homo sapiens miR-877 stem-loop	GUAGAGGAGAUGGCGCAGGGGACACGGGCAAAGACUUGGGGGUUCCUGGGACCCUCAGACGUGUGUCCUCUUCUCCCUCCUCCCAG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19614	MI0005562	hsa-mir-887	Homo sapiens miR-887 stem-loop	GUGCAGAUCCUUGGGAGCCCUGUUAGACUCUGGAUUUUACACUUGGAGUGAACGGGCGCCAUCCCGAGGCUUUGCACAG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19615	MI0005563	hsa-mir-665	Homo sapiens miR-665 stem-loop	UCUCCUCGAGGGGUCUCUGCCUCUACCCAGGACUCUUUCAUGACCAGGAGGCUGAGGCCCCUCACAGGCGGC	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19616	MI0005564	hsa-mir-873	Homo sapiens miR-873 stem-loop	GUGUGCAUUUGCAGGAACUUGUGAGUCUCCUAUUGAAAAUGAACAGGAGACUGAUGAGUUCCCGGGAACACCCACAA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19617	MI0005565	hsa-mir-543	Homo sapiens miR-543 stem-loop	UACUUAAUGAGAAGUUGCCCGUGUUUUUUUCGCUUUAUUUGUGACGAAACAUUCGCGGUGCACUUCUUUUUCAGUAUC	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression has been independently confirmed in mouse and rat [2]. 	5
19618	MI0005566	hsa-mir-374b	Homo sapiens miR-374b stem-loop	ACUCGGAUGGAUAUAAUACAACCUGCUAAGUGUCCUAGCACUUAGCAGGUUGUAUUAUCAUUGUCCGUGUCU	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19619	MI0005567	hsa-mir-760	Homo sapiens miR-760 stem-loop	GGCGCGUCGCCCCCCUCAGUCCACCAGAGCCCGGAUACCUCAGAAAUUCGGCUCUGGGUCUGUGGGGAGCGAAAUGCAAC	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19620	MI0005568	hsa-mir-301b	Homo sapiens miR-301b stem-loop	GCCGCAGGUGCUCUGACGAGGUUGCACUACUGUGCUCUGAGAAGCAGUGCAAUGAUAUUGUCAAAGCAUCUGGGACCA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19621	MI0005569	hsa-mir-216b	Homo sapiens miR-216b stem-loop	GCAGACUGGAAAAUCUCUGCAGGCAAAUGUGAUGUCACUGAGGAAAUCACACACUUACCCGUAGAGAUUCUACAGUCUGACA	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19622	MI0005570	hsa-mir-208b	Homo sapiens miR-208b stem-loop	CCUCUCAGGGAAGCUUUUUGCUCGAAUUAUGUUUCUGAUCCGAAUAUAAGACGAACAAAAGGUUUGUCUGAGGGCAG	This sequence was identified as a miRNA candidate by Berezikov et al. using RAKE and MPSS techniques [1].  Expression was later confirmed by cloning [2]. 	5
19623	MI0005638	ghr-MIR156a	Gossypium hirsutum miR156a stem-loop	AAGGGAGGUGACAGAAGAGAGUGAGCACACAGGGUACUUUCUUGCAUGCUUGAGCCUUUCAUGCUUGAAGCUCUGCGUGCUCACCCUCUAUCUGUCAUCCACUU		50
19624	MI0005639	ghr-MIR156b	Gossypium hirsutum miR156b stem-loop	GGUGACAGAAGAGAGUGAGCACACAGGGUACUUUCUUGCAUGCUUGAGCCUUUCAUGCUUGAAGCUCUGCGUGCUCACCCUCUAUCUGUCAUCCACUUUUCUCUCUCUCUCUC		50
19625	MI0005640	ghr-MIR156c	Gossypium hirsutum miR156c stem-loop	GGUGUCAGAAGAGAGUGAGCACACAGGGUUCUUUGUAGCAUGCUUGAGCCUUUCAUGCUAGAAGCUAUGUGUGCUCACCCUCUAUCUGUCAUCCACU		50
19626	MI0005641	ghr-MIR156d	Gossypium hirsutum miR156d stem-loop	GAGAGGUUUGACAGAAGAGAGUGAGCACACGCAGGCAGAUUGUAUGAAAGGCCAUACCUUUGCCCGCCGUGUGCUCACUUCUCUUCUGUCAGCUUA		50
19627	MI0005642	gra-MIR157a	Gossypium rammindii miR157a stem-loop	GUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGGUGUGCAAUUAGGAGUCUUGAAGCAAUGCAUCCCACUCCUUUGUGCUCUUUAUGCUUCUGUCAUCACC		51
19628	MI0005643	gra-MIR157b	Gossypium rammindii miR157b stem-loop	GUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGGUGUUGCCUAUGUGCAUGCAUCCCACUCCUUUGUGCUCUCUAUGCUUCUGUCAUCAUC		51
19629	MI0005644	ghr-MIR162a	Gossypium hirsutum miR162a stem-loop	UUUUUAGCGUUGGGGUAAAGACACUGGAGGCAGCGGUUCAUCGAUCUCUUCCUGAGAAUUUUGUUGUGAGAAUAACACAAAUACAUGAAUCGAUCGAUAAACCUCUGCAUCCAGCGCCUUAACUCUCCAUGAAGUUUUAUGUUAGUUA		50
19630	MI0005645	ghr-MIR166b	Gossypium hirsutum miR166b stem-loop	UGAGGGGAAUGUUGUCUGGACCGGGGACACUUGUGUUUCUAAUCCGUUUUCCCUGCAAUAUUGUUCUGAUUAACGUGGGGAUCUUUAUAUUGCUUAUUUUUGUAAUGGAUUAAGGUUGUACUAGUGUCGUCGGACCAGGCUUCAUUCCCCCCAA		50
19631	MI0005646	ghb-MIR169a	Gossypium herbecium miR169a stem-loop	UAUAGAGAGGAAGAAAAGGUCUAACAUGAAGAUAAAGAGUCUUGUUUGGUAGCCAAGGAUGACUUGCCUGCACCUAAUGUCCACGAGGUUUUAAUACAUCAAAAACCCUGGUUGGGUCCCAGGCAGUCACCUUGGCUAACUAGACAGGCUGUUUUCAUUCAUGCUAGGCCUCAUCUUCCGCCCCAUUGG		52
19632	MI0005647	ghr-MIR390a	Gossypium hirsutum miR390a stem-loop	UGGAAGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGGAUGAUCCAUCUUUCAAGCUUUCAUGCAUGUAUGUUAUUUGAUCCUCAUAUAGCGCUAUCCAUCCUGAGUUUCAUCGGUUCUUCUU		50
19633	MI0005648	ghr-MIR390b	Gossypium hirsutum miR390b stem-loop	GUAUGGAAGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGGAUGAUCCAUCUUUCAAGCUUUCAUGCAUGUAUGUUAUUUGAUCCUCAUAUAGCGCUAUCCAUCCUGAGUUUCAUCGGUUCUUCUUGCUUG		50
19634	MI0005649	ghr-MIR390c	Gossypium hirsutum miR390c stem-loop	AGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGGAUGAUCCAUCUUUCAAGCUUUCAUGCAUGUAUGUUAUUUGAUCCUCAUAUAGCGCUAUCCAUCCUGAGUUUCAUCGGUU		50
19635	MI0005650	ghr-MIR396a	Gossypium hirsutum miR396a stem-loop	CUUCGUAUUCUUCCACAGCUUUCUUGAACUGCAAUUUCAUGUAAUCAGAUCAUUCAUUCAUUCGUUGUCGUUGAUGGUGCUGCAUAUAUACGAGUACGUUGUUGCGGUUCAAUAAAGCUGUGGGAAGAUACAAACA		50
19636	MI0005651	ghr-MIR396b	Gossypium hirsutum miR396b stem-loop	CUUCGUAUUCUUCCACAGCUUUCUUGAACUGCAAUUUCAUGUAAUCAGAUCAUUCAUUCAUUCAUUGUCGUUGAUGGUGUUGCAUACAUACGAGUACGUUGUUGCGGUUCAAUAAAGCUGUGGGAAGAUACAAAC		50
19637	MI0005652	ghr-MIR399a	Gossypium hirsutum miR399a stem-loop	UGAGAUAUUACAGGGCAAAAUCUUCAGUGGCAGGCAGUAUAUGGCUCCAUUCAUCAGGCAUCAGCUGUAUGGAAAAUUGCAGUGUGUUCUCCGCCAAUGGAGAUUUGUCCGGUAAUUCCGGUUC		50
19638	MI0005653	ghr-MIR399b	Gossypium hirsutum miR399b stem-loop	UGAGAUAUUACAGGGCAAAAUCUUCAGUGGCAGGCAGCCAUUGUAUAUGGCUCCGUUCAUCAGGCAUCAGCUGUAUGGAAAAUUGCAGUGUGUUCUCCGCCAAUGGAGAUUUGUCCGGUAAUUCCGGU		50
19639	MI0005654	ppt-MIR156c	Physcomitrella patens miR156c stem-loop	GAGUGGGAGUGACAGAAGAGAGUGAGCACAGUUGAGCAUGUACGAGGGUGACGUACUUGCUGAAGUGUGCUCACUCUCUUCAUGUCACGCCUCUC		40
19640	MI0005655	ppt-MIR160a	Physcomitrella patens miR160a stem-loop	GGAGUGGAACUGCCUGGCUCCCUGUAUGCCACCUGCGGGGCUUGCCAAAGUGAUUGUCGAGCUGCAUAGCUGGCAUCCAGGGAGCCAGACAGACCUCCU		40
19641	MI0005656	ppt-MIR160b	Physcomitrella patens miR160b stem-loop	AUGCUAGAUCCGCCUGGCUCCCUGUAUGCCAACUGCGAGCCUUGCUAAAUAUUUGUUUGCCUUGAUUCAUAGCUGGCGUUCAGGGAGUCAAGCAGACCUUGCG		40
19642	MI0005657	ppt-MIR160c	Physcomitrella patens miR160c stem-loop	AUAUUGGAUCCGCCUGGCUCCCUGCAUGCCACUUGCGAAUCUUGCCAAACGUUUUGUCGGGGUUCAUGGCUGGCGUGUGGGGGGUCAGACAGGCCAUACA		40
19643	MI0005658	ppt-MIR160d	Physcomitrella patens miR160d stem-loop	AUGUUGGAUCCGCCUGGCUCCCUGCAUGCCGCCUGUGAAUGCUGUGAAGAGACUUACUAGAAUUCAUAGCUGGCGUGGAGGGAGCCAAGCAGACUCUGAA		40
19644	MI0005659	ppt-MIR166b	Physcomitrella patens miR166b stem-loop	CUUUGUUGUGAGGAAUGCCGCAUGGACCGAAGCCAUGCGCUCCACAUCUAGACGGUGAUUUGGACGCUAUGCUUCGGACCAGGCUUCAUUCCCCUCAGCACAG	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19645	MI0005660	ppt-MIR166a	Physcomitrella patens miR166a stem-loop	UCUGCUGUGAGGAAUGCCCCCUGGCCCGAAGCCAUGUGCCUUUUCAUGUCCACGUGGGGUAAACAUUAAAGCUUCGGACCAGGCUUCAUUCCCCUCAGCACA		40
19646	MI0005661	ppt-MIR167	Physcomitrella patens miR167 stem-loop	ACCAAAAGUUGGAAGCUGCCAGCAUGAUCCUUUAACUUUUCUAGAGGGAAAGAUCAGAUCAUCUGGCUGCUUUCAUCCUGUU		40
19647	MI0005665	ppt-MIR319e	Physcomitrella patens miR319e stem-loop	CUAGCCGUGGGAGCUCCUUCCGGUUCAAUAGUGGCUGAUGUGAGGUUGCACUGCUGCCGAUUCAAACUUCCGGCUUCCCUUUCUUAACACGACAGGGAAUCCGAAUGUCUGAUGCGGGAGCUGUGCGGUCUUCAACUUUAGCGCCUCUUGGACUGAAGGGAGCUCCCAAGUCUU		40
19648	MI0005667	ppt-MIR395	Physcomitrella patens miR395 stem-loop	AAUUUUGAAACCUUCUUUUGCUUCAUAUUCUAGUCGUUGGUUUAUGGUGCCUAAGAAAAAUGGAUCGUUAUGUUUUAUUCAAGAUAUACAGCCAAUGAAUGUAGUAACUAUAAGAAAUGCAGGUAUAGGAUCUUUAAUAGAUGAGUUUGCUGAAGCGUUUGGGGGAAGGGCAAUUUAU	The mature miRNA sequence reported in [1] has a 1-nt insertion with respect to the genome assembly sequence shown here. 	40
19649	MI0005668	ppt-MIR408	Physcomitrella patens miR408 stem-loop	ACAACCAGCACUGCACUGCAUCUUCCCUGUGCCAUCUUCGUCGAUUGUCUCGUACCGAAAGUGAUUCAACCACAGCGAGAUCAGACUCAACUGUUAAAGCUGAUGACACUGAUACGAGAUGAUGAAGACAUAGGCAGGGCAGCCAGUG		40
19650	MI0005669	ppt-MIR414	Physcomitrella patens miR414 stem-loop	AGACGUUCAAGAACAAUUAGAGAAGACCAAUGCUAGAAUGUGGGGCUCACCAGAUUUUCCAACUGCAUUGGCUAGCUCUGCUAGCGCUUUGGCAGUAACCAUAUCUUUGUCAUCUUCAUCAUCGUCAUCUUCGUCAUCAUCUUCGUCAUCCUCAUCAUCCUCGUCCUCAGCAUCAG	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	40
19651	MI0005670	ppt-MIR419	Physcomitrella patens miR419 stem-loop	GGUUGCCUGUGUUAGUUAUAGUUCUAACCGUAAGUCCACGUCGGAGGAGGCUGAUGAAUGAUGACGAUGUAUAGGCCUAUCU	The status of this sequence as a miRNA has been questioned on the basis of lack of conservation in genomes other than Arabidopsis and rice, moderately poor precursor hairpin structure, lack of identified targets, and low Northern blot signal [2].  This sequence may therefore be removed in subsequent data releases. 	40
19652	MI0005671	ppt-MIR477c	Physcomitrella patens miR477c stem-loop	GUUGAUUUUUCCUCUCCCUCAAAGGCUUCCAACGUCCUUUUUGUGAGCAAGCACGCUGGAAGUCUUUGUUGAAGAGGAGGAAACA	This sequence was named miR473a in [1].  The miR477 family contains miRNAs previously called miR473, miR1210 and miR1213 here.  The names and sequences are rationalised in [2].  The mature sequence shown here is the most abundant clone by deep-sequencing [2]. 	40
19653	MI0005672	ppt-MIR477a	Physcomitrella patens miR477a stem-loop	GUUGCUUUUUCCUCUCCCUCAAAGGCUUCCAACAUGAUGUGCGUAAGCCACAACGUUAGAAGCCUUUGUGGGAGAGGAAGAAACA	Talmor-Neiman et al. reported a mature miRNA derived from the 3' arm of this hairpin, and named it miR1210 [1].  A mature miRNA from the 5' arm was named miR473b [2].  This sequence was later determined to be a member of the miR477 family [3], and is therefore renamed here.  The mature sequences shown here are the most abundant clones by deep-sequencing [3]. 	40
19654	MI0005673	ppt-MIR477f	Physcomitrella patens miR477f stem-loop	GUGUUUGUUUUUCUCCCUCAAAGGCUUCCAACAACAGGAGGGUACAAUUCCAUUGUGGUUAUAACCCAUAGUUGAGGUGUUUUUGCUCUCUCUGCUGUCGGAAGCCUUCGAGGGAGAUGAAAGAAUU	This sequence was named miR477a in [1].  The miR477 family contains miRNAs previously called miR473, miR1210 and miR1213 here.  The names and sequences are rationalised in [2]. The mature sequence shown here is the most abundant clone by deep-sequencing [2]. 	40
19655	MI0005674	ppt-MIR477g	Physcomitrella patens miR477g stem-loop	GUGUUCGUUUUUCUCCCUCAAAGGCUUCCAACAACAGUCGGAAUUAACUCUGAUGCGGCCAUUAUCACUGGUUGCAGUGAAUUAUUCUAGUUCUGCUGUUGGAAGCCUUCGUGGGAGACGAAAGAACC	Talmor-Neiman et al. reported a mature miRNA derived from the 3' arm of this hairpin, and named it miR1213 [1].  A mature miRNA from the 5' arm was named miR477b [2].  Names of the miR477 family are rationalised in [3].  The mature sequences shown here are the most abundant clones by deep-sequencing [3]. 	40
19656	MI0005675	ppt-MIR534b	Physcomitrella patens miR534b stem-loop	GCACUCAUGUAUGCAACUUGUAUGGACAGAGUGACUAGUCUAGUGUUCACGAGUGCCAAUUUUUGGAUGCCUUCUAUUGCUGUGCUGGUCUGUGAGGCGGCGUAACUCCUUGUUUUGCAACAGUUGACAGUGCACAAAGUAUAUGUGUGGCUGGUGACGUGCGACGCAUUGGGUAAGAUCUAUGUCUCUUCAGUGCGCGGGGAAGUUUGUCCGCCGACGGCAUUCAGAUUGCUAAACUAGACUCGUCAGUAUGUCCAUUACAGUUGCAUACUUGUGUGG		40
19657	MI0005676	ppt-MIR893	Physcomitrella patens miR893 stem-loop	CUCUGCAUUGCUCUCAAACCUCCUCCCUCUUCCUUGUCCUAGCAUAGAUCCCAGUCCCUUCUUCCUUGUCUUGAUGCACGACCCAAUCCUCUCCUCUUCUUCUUUAUCCCGUCAUACCCAUACUAAGACAAGAAAGAGUUGGAAGAGAGAAUUGGGACUUGUGCUGGGACAAGGAAGAAAGGAACUACUACUUGCACCAAGACAAGGAAAAGGAGGAGGA		40
19658	MI0005677	ppt-MIR894	Physcomitrella patens miR894 stem-loop	CAUAAUUCAAAUAAUCCAAAAAAAAUAAACCAAAUACCUUCCACCUCAAGCGUUUCACGUCGGGUUCACCAAAUAUGUUGUAUUAUGUGAAGUUUUGAUUGAGAAUGCACCGAGCACUUGGCUAUGGAAGGUAAAAGAAAAUUGCAACAAAAAGUCCUAACAAUCCAAUAGGAUUAUAGAAAAUUUAUAAUUAAACGUUAACAAUCAUAAUCAAACAAUA		40
19659	MI0005678	ppt-MIR895	Physcomitrella patens miR895 stem-loop	GAUUCAUGUAAUUAUUGUUAACCUCUUUGUGUUCCGAGCUUUUAUGAUUGGUAGCUUAGCGAGGUGUUGGUAUGAUACCAAUCCCUGGUUUGCUUGUUCCUAAUUGAGUUAUGCUUGCACUCAAAUCUAGGGGAGCGGUAUUUUGGCUCACUCGCAAUGCUUUCAUGUACCCUUCCCGCAUUAUGAGUGCCACUUGGCUCCAUGGUGUGAUAUAUAAGUUUC		40
19660	MI0005680	ppt-MIR896	Physcomitrella patens miR896 stem-loop	CCCACCCUGAGCGGGGGGGUCUGAUUGUGGUCGGUCGAGGGGCGCUGACCGUGUGGCCCAAUGGAUAAGGCGCUUGCCUACGGAGCAAGAGAUUCUGGGUUCGAUCCCCAGCAUGGUCGUGGGUCGCCGGAAUUGUAGAUUGUGGCGCGUGUCAAUUUGGCCGAGUGGUUAAGGCGGCAGACUCGAAAUCUGCUGGGGUUUCCCCGCGCAGGUUCAAAUCCUGCA		40
19661	MI0005681	ppt-MIR897	Physcomitrella patens miR897 stem-loop	UCUUAGCAUUCAAAUGACCAAGGUGUCGAUGCCAAAUGCCAUUCUUAUCUUGAUCAAGUGGAAACUCAGCAAAUGCGGCCACUUCAACUCUAUUCACUAUCUUGCACUUGAUGAAGUAAAGAUUCCCAUCUCUAAAGCCUUUGGCAACAUCAUCUCUACCCAAUGUCUUUAUAAAGCAUCCAUUCUUAUCAAAUUAUAUCUUCUUGGUCACUUCAUAGGCAAG		40
19662	MI0005682	ppt-MIR899	Physcomitrella patens miR899 stem-loop	ACGGCGUUUUUCUCGGAGAAAAAUACCAUCCUUUGGUUCAACAACGGUUGCUGCGUUUUCCACGUUCGGAUACAACCCUGCCCAGUUGCUGUGAGAGAUUGACGAGUGCAAGAAGACCCUCUUUCCAUGUUCCAGACGCAGGCCUUCGCCGAACUGAGAUACAUCGCAAUCGACACACCGGCCGCUUCAGAAUCAGUGACUAGCAUACCCAGCUGCUAUUGG		40
19663	MI0005683	ppt-MIR900	Physcomitrella patens miR900 stem-loop	GAGUAAGAUAGAGCAAAACGCAGCCAAAGAAGAGUCGUCCAGUAGCCGACGUAGAUGGCAUGCAACUCCAACUUCGCAAUGAUACCCGCUCUAAGAUCGCGGUCUUCCCAGGUACAAGAACACAGCUCACCAGUAGUCGACCGCUGGUGAGCUGUGUUCUUGUACCUGGGAAGACCACCAGCGAAGAGAAUAGAAUAGAAUUGGCGAGUUGGAAUCCGAA		40
19664	MI0005684	ppt-MIR901	Physcomitrella patens miR901 stem-loop	UAAAAAAAAUAAUAUGUUGAUAAUAUAUGUGAAAGUAAAUAAGUAUUACCUAAGAUAAGUUGCUAAAAGGUCAAAGGCAGCAAAGGUAAAAGUAAGUAACAAUGGUGGCGACUAGGUUUAUGAUGGCAGCUAGGAUUUAAGAGGCGGCUAGGUAAAGUGGCGGCUAGGUUAAGUGGCGACUAGGGUUUCAUCAAAUGGAUGUAGAUGAAGUUCAGCCAUAG		40
19665	MI0005685	ppt-MIR902a	Physcomitrella patens miR902a stem-loop	GCUCGUGACCCUCUGAAGGGAACUUUGGCCUGAGAAGAGCGUGGGAUUGUAGGAACAUGAGUGGAUCUACAGCAUUUGAGAUUAUUCAUUUGCAUCCGCUACGAUAUGAUGCAGAUUCUUCACCUGUGUGAUACUCUUGAGGUAUAACAGACGAAGGUCUGCAUCAUAGCCAAGCGAACGUAAAUCUGGUGCAUUCAACACUAGAUGCUUAAUUGAGGUGCAU		40
19666	MI0005686	ppt-MIR902b	Physcomitrella patens miR902b stem-loop	GGUUGUGAUAAAUCGGUUCCGUGUCGUCAUAAUCGCAAGUGUUGCAGGCAGUUAUGAGGAGAUGGAGAGCGUGCAGACUUGUUUCCUUCCUCUAGCCUAUGAUGCAGAUUCUUCAUCUGUUUGUUAUCGUUCUCAUGGUGUACAUAACAGACGAAGGUCUGCAUCAUAGCCAAGAGGAAGCAAAUCUUAAUACCUGGCUCGAAUUUGGCCUGCACGCAAUUUU		40
19667	MI0005687	ppt-MIR536c	Physcomitrella patens miR536c stem-loop	UUGUUCGACCAUUGCAGUUGCUUUUAGACGCCAAUGCUUGGCAUGAAUGUCUUGAGUGUCUGGUAGCCUAAAACAGAGAGAUGAUGCAAUUGGUAUGUGGAUCUUCUCUGGUUUUAGAGGAAUCGUUCGCUGGCCUCCAGGUUCGAGACAAUCGUGCCAAGCUUUGUGCUUUCAAGAGCCUUAAUGGUUUUGGACGAUGGGUUCUACUGGAUCUCUAACAUC		40
19668	MI0005688	ppt-MIR171a	Physcomitrella patens miR171a stem-loop	AGGCAUGUGAUAUUGGUGGCGCUCAAUCAGAUGACCAUGCCUGUGAUGCUGGCGUUGCCAUCAGAUUGAGCCGCGCCAAUAUCACAUCCUU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19669	MI0005689	ppt-MIR171b	Physcomitrella patens miR171b stem-loop	AGGCAUGUGUUAUUGGGCCCGCUCAAUCAGAUGUCUUUUCCAGCAACGGCUGGUAUUGUCCUCAGAUUGAGCCGCGCCAAUAUCACAUCCUU		40
19670	MI0005690	ppt-MIR903	Physcomitrella patens miR903 stem-loop	GAACGGCUUCGGCUGGUCUGCCGCUCAACGCGGGGCACUGGUCAGCGUGGGCUACUUCGGCGGGACAAGAGCAGGAUGUAGUUUCCUGCCCCCCAUGCCGCCGAGGUGGCCGAGGAACGAAGCGUGCGGCCCCCUCUCGGGGGGGUCGUGGGACUCGUCCCAACUGCACGCUCGGGACGCUGGCGUAUUGAGCUCUUCAUCCGACCCGUCUU		40
19671	MI0005691	ppt-MIR536b	Physcomitrella patens miR536b stem-loop	GUCGGCAGUUUUCGUAUUUCGCCGACUUCGGUGACUGCAGAAAGUCGAAACAGUAGAGAGCCUGUUGAAUUGCAGCGGUAGACUUGUCUGGCAUCAUUUGGUAGUCGUCAAACUUAUUCUCCCCGAGUUGUAGCGGAAUGAUACCAGAAAUUCGUGCCAAGCUGUGUGCAACCAAGGGGUUUGUUACUUAAGAUCCACAUGGGAGGAGCGUCCCUACCAGCA		40
19672	MI0005692	ppt-MIR904a	Physcomitrella patens miR904a stem-loop	UGUUGGAGUUCCUUCGGUGUGGUGUUGCAAUAUUUGUGAUGCUAAUAUGGUCUUGUCAAUGUUUAGGGGCAAAGGCCUGAUUAUGCAGAUGCUUGGUGUAAGCUUAUGCUUGUACAACUUUUGCUAUUGGCCUCCACCCCUAAAUCUUGGCAAGACCUAAUUAGCCCACAACAUUGAAUUGACCGGGACCGGCGACUAAUCAGUACGAGCUCAAGCAGGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19673	MI0005693	ppt-MIR904b	Physcomitrella patens miR904b stem-loop	CUUUGGAGCGAUGUGUGUCAUGAUGGCGGUAUUUUGUGAUGCUAAUACGGUCUUGUCAAUGUUUAGGGGCAAAGGUGCAACUAUGCAACAUCCCUGGUGCGAGCUCUUGAUCGCGUAAGUGUUGCUAGUGCCCUCCACCCCUAAAUGUUGGCAAGACCUAAUUGGCGCACAACAUUGGGACCGACGCUGGAUCAGCAGAAGUCAAAAGACACAAUUGUGA	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19674	MI0005694	ppt-MIR898b	Physcomitrella patens miR898b stem-loop	UACUGCAGAACUUAGUUACAGAUUCAUCUGCUUUGUUCAUUUCCGGCAUCUUGCUGUGCACUACUUAGUACGCGCGUAGUUGCAGGCAUUCCGGGUGCAGCAACUGACGCGGAAGACUUUUCCCAGAGUGUGCGCUUCAACUGGCGUGCUGAGUAGUGCACAGCAAUAUGCUGGGCAUGGACAGCUACCACCGCUGAGUUCGCUGUAUAGAACGUUUGCU	The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19675	MI0005695	ppt-MIR898a	Physcomitrella patens miR898a stem-loop	CGCAGCGAAGCUUAGCUACACACCAAACUCUCUUGUUUGUUUCCGGCGUAUUGCUGUGCACUACUUAGUACACGCGUAUCGGUUUGCACUCCAGAUGUAGCAAUUGAAAACGAAGAUAUUCCUGGAAAGUUUGCAACCGCGUGGGUGCUAGGCAGUGCACAGCGAUAUGCUGGGUAUGGACAGCUACUUUUGAACUCAAUCAUUUAGUAACUACAGCGCU	Landgraf et al. show that the 5' miRNA is the predominant one [2]. The mature sequence shown here represents the most commonly cloned form from large-scale cloning studies [2].  The ends of the miRNA may be offset with respect to previous annotations. 	40
19676	MI0005696	ppt-MIR156b	Physcomitrella patens miR156b stem-loop	GUGAGGCUCGAGUGCAGACACUAUUCAAGUGUGGGCGGGGGGAGCGGGAGUGACAGAAGAGAGUGAGCACGGUUGCGCCUGUACGAGGAUAACGUACUUGCUCAAGUGUGCUCACUCUCUUCAUGUCGCGCCUCUCCCUCGUCGUUGUGACGUCAUUUGUGAUGAGAGGGUGGGGAGGGGGGUGUGUGAGGGAGGAGGAGGGGAGGUGAAGGGUGUGGUG		40
19677	MI0005697	cre-MIR918	Chlamydomonas reinhardtii miR918 stem-loop	CCAAUACGAGACGUCUGCACCGCACAUGUCUCAGGAAGAGAUCGUCCGUAGUAGCAAGCUGCUGGAGGGUAUCUCGGUCAGCAUCUCGAUUGGCAAGACGUCCACUCCGGGUACGCGCCGCUCAUGCGAUGACGCCUUCAUCGCGUGAGCGGCGUGUACCUGAAGCGGACAUCUUGCCAAACGAAAUGCUGACCGAGAUACCCUGAAGUAGCUUGCUAAUAGUGGCGAUGUCCUCCUGAGACAUGUGCGGCGCAGACGUCCCGCAUUGG		53
19678	MI0005698	cre-MIR905	Chlamydomonas reinhardtii miR905 stem-loop	UGCCGGGCUGGGGCCGGGCGGGCUGUGAUCGACCUGGAGGUCCCUGGAUAUGGCACCUUCGAGGUUGUGGUCACACACUCAGUCCGGGGACCUCGGCCCAGUUGCUGGUGCUAUGCUCUGACUACCCGACAAGCAAGCUUGGGGCCGCCCCCCACAUUGGUCCUGCGGUAGUCAGAACAGAGCACUAGCGACUGGGCCGAGGUAACCCGCACUGAGUGCGUGACCACAACCUCGAAGGUGCCAUAUCCAGGGACCUCCAGGUCGAUCACAGCCCGCCCGGCCCCAGCGCGGCA	Molner et al. and Zhao et al agree that the predominant product from this hairpin precursor is from the 3' arm [1,2].  The product shown here is as described in [2], offset slightly from that described in [1].  Molner et al also identify a number of further offset and overlapping minor products, not shown here [2]. 	53
19679	MI0005699	cre-MIR906	Chlamydomonas reinhardtii miR906 stem-loop	GGCCUACAUACGGUUGGUGGGCGUGAUCAGCAGGGGGAAGCUUUAUCGGAAUUCGAUGUGCAGGGCGUGUGGGCACAUGCCCUGCACAUCGAUUUCCGAUAAAGCUUCCCCCUGCUGAUCACGCCCACCAACCGUAUGUAGGCC		53
19680	MI0005700	cre-MIR907	Chlamydomonas reinhardtii miR907 stem-loop	CCAGCCCAGCGCUCGCACCGCUCGCAGAAGACAUCGCUGGCACCGUGUUGGCCGCCAUUUGAGCGCUUGGUCACAUCGCUGGCACCCACGGCUGGCACCGUGGCCGCCACUUGACCAAGCGCUAAAUAUCGGCCAACNCGGUGCCAGCGAUGUCUUCUGCGAGCGGUGCGAGCGCUGGGCUGG		53
19681	MI0005701	cre-MIR908	Chlamydomonas reinhardtii miR908 stem-loop	GUGGGUUUUGAGAAGAUGCGGUCCGUUGGCUAUAAUGUUGACAGACCACCCGCUCCCUUACUGACGCAGUUGACGCGUUUGAUAGCAGGAUCAUAGUACGGGACCAGUUCCCCUACCAACUGGUCCCGUAACCACUAUGAUCCUGCUAUCAAAGGCGUCAACUACGUCAAUAAGGCAGCGGGUGGUCAAUAUACAUUAUUGCCAACGGACCGGUUCUCCUCAAAUGUCAC	Zhao et al. identify a mature miRNA product from the 5' arm of the hairpin precursor, and named it miR908 [1].  Molner et al. identify 3 mature products, and suggest that an alternative 5' product is the predominant one, named cre-miR908.1 here [2].  The Zhao et al. product is renamed miR908.2 here. 	53
19682	MI0005702	cre-MIR909	Chlamydomonas reinhardtii miR909 stem-loop	GUUCCCGCACACGUGGCUGAAGGUCGCGGAGCUCUUUGCCGACACGGUGGCCAUGUGGUCCCGCAGCUCCUUGCCACACGGGCAUGCAAACAUGACCCUGAAUGGCCCUGCCUGCGGCCUGCCCCGCUCCAGGGCCUUCUGCUGCUGAUGGUGCAGAUGCGGCUGGUGCUGGUCAAACCGGUGGUGGUGGUGCUGGUGCUGUUCGGGCUCCUGCUGCACCGGCAGUAGCGCCAGCAGCUGGNGCAGGUACAGGGCGGCCGCCAGCGGCAGCACCACCACCACCACCACCGGUUCGACCAGCACCAGCCGCACCUGCACCACCAGCAGCGGAUAGAAGGCUCCGGAGCGGGGCAGGCCCAGGCAGGGCCAUUCAGGGUCAAGUUUGCAUGCCCGUGUGGCAAGACGCUGCGGUACCACAUGGCCACCGUGUCGGCGAAGGGCUCCGUGACCUUCAGCCACUUGUGCGGGAAC	Zhao et al. identify a pair of mature miRNA product from the 5' and 3' arms of the hairpin precursor, and named them miR909-5p and miR909-3p [1]. Molner et al. suggest that an alternative 5' product is the predominant one, named cre-miR909.1 here [2].  The Zhao et al. products are renamed miR909.2 and miR909.3 here.  Molner et al. also show a number of offset and overlapping minor products originating from the same hairpin [2], but not catalogued here. 	53
19683	MI0005703	cre-MIR910	Chlamydomonas reinhardtii miR910 stem-loop	CCGCUGCAGCCGGUCAGGUGCACCCGGAGGUGCCGGAGCGGUUGGGGUUGCGGGGCCCGCAGGUAGCUGCCGUUGAGCCCGACGCUGCUGCCGCCGCGCCGGUGCUGCUGCGCGGCAGCACCUGACCGGCUGCAGCAGCGUCGGGCUCGACCGCAGCCACCUGCGGGUCCCGCAGCCCCAGCAGCUACCGACUGCACCUGACCGGCUGCACCUGACCGGCUGCAGGG	Molner et al. confirm that the mature miRNA product identified by Zhao et al. and shown here is the predominant one [2].  They also identify 2 further minor products from the 3' arm, not shown here. 	53
19684	MI0005704	cre-MIR911	Chlamydomonas reinhardtii miR911 stem-loop	AAAUGGCCGUACUACUAUUGUCAUGUCUGACUGCAUCAUGUGUCAUGAUGCAGUCAGACAUGACAAUGGUAGUACGGCCAUUU		53
19685	MI0005705	cre-MIR912	Chlamydomonas reinhardtii miR912 stem-loop	GCCUAUGCCUCUGCCGGCCAUCAAUGGCGCUCACGACAAGGGUGCCAUCGUCACCGGUCUAAUCUAAUGCCAGGCAACCAGGGAAGACACAGGAUCCAUUUUCUAGUGCCUGGCUGGGAUCAAUGCAAGAUGAUAGUUGGAUCCUGGACGCCGAAGGCCAUCAUGCGGUGUCAACCGCAUGACGGCCGUUGGCGUCCAGGAUCUAGCUGUCGUCUUGGAUUGAUCCCAGCCAGGCGCUUGGAGAUGGACCCACGGUCUUCCCUCCCUUGUUGCCUGGGUUCCGAGCAGACCGGCGACGAUGGCACCACCGUCGUUGGCUCCAGGGCAUUGACGGCCCGGCGGAGAACCAGGC	Molner et al. confirm that the mature miRNA product identified by Zhao et al. and shown here is the predominant one [2].  They also identify 3 further minor products from the same hairpin, not shown here. 	53
19686	MI0005706	cre-MIR913	Chlamydomonas reinhardtii miR913 stem-loop	GUAUCUGUGUCGCUCAUGCAAGGGACAGCCAACGAAUUCCCUCGCCACGUUUUGGGGGCUUGCACACUUGCGAGUCCGUGGCCGUGUUUCCAAGGAUGUAUACAAGCGAAGUCGAGACUUUGGUAUUACAUACUCCCACUUCGCUUUUAUACAUUCUUGGAGACACGGCCACGGACUCGCAGGUGUGCAAGCCCCCGAAACGUCGCCAGGGAAUUCUUUGGCUGUCCCUUGCAUGAGCGACACAGAUAC	Zhao et al. identified a mature miRNA product from the 3' arm of this hairpin precursor, and named it miR913 [1].  Molner et al. show that predominant product originates from the 5' arm [2].  The 3' product is renamed miR913* here.  Molner et al. also identify a number of minor products from the same hairpin, not catalogued here. 	53
19687	MI0005707	cre-MIR914	Chlamydomonas reinhardtii miR914 stem-loop	GCCGGACGUUACGGCAUGACGACUCACGGCGUGACGCUGAACUUGUGACGAUCGCCGUUUUAAUUCGGGGGACCUAUAGGCAUUUGUUAACUCAUAAUCGUUUUAAAUCGCUCCGGAUCUAUAGCGAGCUGGGUGCGGGCGACCAUCGCGCUCGAGCUGCAACUCGCCCGGGCACCUGCAAAGCUCGGCGAGCACCAUCGUUAAAUACUUCGUACCAUUCUAUCUCUGCACCUAAACGUGUGCAGCUGAGUCCGCGCGCGGCCCCUCGCUGCUGAUGCCGGGGGCGCCCCCCGCGCCUGUCCCCGCCUCCCCUCCACGGAUUCCGGCGCGCCCGGGGGUUGGUAAUGGGUGCUAAUGCGUGUGGCAGCACGGCGUACAUUUGCCAGUUGCAUCUGGAAUGCUCAGGGCUGGCCUGCUCUGCCCUAGCCUGGCCCUGCCCUUGCACAGGGCACCCCUGCUGCAGUCACUUGCUGCGGCUAAGCACGGCUGCAACCCGUGGGGGGCGCUGCCGAUUGACGCGAAUGCAAGAGAUCGGAGGCCCGGCACCCAUUACCAACCCCCGGGCGCGCCGGAAUCCGUGGAGGGGAGGCGGGGACAGGCGCGGGGGGCGCCCCCGGCAUCGGCAGCGAGGGGCCGCGCGCGGACUCAGCUGCACGCGUUUAGGUGCAGAGAUAGAAUGGUACGAAGUAUUUAACGAUGGUGCUCGCCGAGCUUUGCAGGUGCCCGGGCGAGUUGCAGCUCGAGCGCGAUGGUCGCCCGCACCCAGCUCGCUAUAGAUCCGGAGCGAUUUAAAACGAUUAUGAGUUAACAAAUGCCUAUAGGUCCCCCGAAUUAAAACGGCGAUCGUCACAAGUUCAGCGUCACGCCGUGAGUCGUCAUGCCGUGACGUCCGGC		53
19688	MI0005708	cre-MIR915	Chlamydomonas reinhardtii miR915 stem-loop	CAACGCUGCCGCGGAGGCGCUCGGCGUGGACGGGGACGAGCUCGGCGACCUUCUCUUUACGCUGUCGAAACUAUCGGAGGAGCAGCUCAAAUUCUUUCCAAUAGCCGCUGGCAAUAAGGCAAUCGUUGCGUUUGGGUCCUCUCGCAGACUGCGCAACGCAACGAUUGCCUUAUUGUCAGCGCCUAUCGGAAAGAAUUCGAGCUGCCCCUCCGAUAGUUCCGACAGCGUAAAAAGAAGGUCGCCGAGCUCGGUGCCCGUCCACGCCGAGCCCUCCGCGGCAGCGUUG		53
19689	MI0005709	cre-MIR919	Chlamydomonas reinhardtii miR919 stem-loop	AAUGCGGGACGUCUGCGCCGCACAUGUCUCAGGAGGACAUCGCCACUAUUAGCAAGCUACUUCAGGGUAUCUCGGUCAGCAUUUCGUUUGGCAAGAUGUCCGCUUCAGGUACACGCCGCUCACGCGAUGAAGGCGUCAUCGCAUGAGCGGCGCGUACCCGGAGUGGACGUCUUGCCAAUCGAGAUGCUGACCGAGAUACCCUCCAGCAGCUUGCUACUACGGACGAUCUCUUCCUGAGACAUGUGCGGUGCAGACGUCUCGUAUU	Zhao et al. and Molner et al. independently identified a number of miR/miR* pairs expressed from this hairpin precursor [1,2].  The predominant product by extensive cloning is named here miR919.1 [2].  The second product (miR919.2) is also shown, but others are omitted for clarity. 	53
19690	MI0005710	cre-MIR917	Chlamydomonas reinhardtii miR917 stem-loop	GCAGCAACGGCUCCCAGAGCUGACCAAUGAGGCCAUUGACAACCGCCUGCCGAUUCUCUUUGAAGAAGGCGAGCGACUUGUCGCCCGAAUACAGCGCCCGAAAUUUUGUCACGAUCCAGUCACCGGCGUGCGCUUCGAUGUGCUGUAACACAGGUCGCGGCGUAGCUACUCUUAAGGCCUCAACCAAAGGGCCUUUGCGGCGUUUCACGGUUAUGUUCGAAGUCGGUACUAACAAUCUGAACCAAAGUCGGAGCCCAAGUCUGAACCAAAGUCGUUUGGUUCAGACUGUUAGUGCCGACUUUGGUUCAGACUGCUAGUGCCGACUUCGAACAUAACCGUGAAACGCCGCAAAGGCCCUUUGGUUGAGGACUUAAGAGUAGCUACGCCGCGACCUGUGUUACAGCACAUCGAAGCGCACGCCGGUGACUGGAUCGUGACAAAAUUUCGGGCGCUGUAUUCGGGCGACAAGUCGCUCGCCUUCUUCAAAGAGAAUCGGCAGGCGGUUGUCAAUGGCCUCAUUGGUCAGCUGUGGGAGCCGUUGCUGC		53
19691	MI0005711	cre-MIR916	Chlamydomonas reinhardtii miR916 stem-loop	ACGGAAACGGUUGUACGGGGCGCCGUACGGUGGUUGUGGGAGAGGGGGGGGCUGGUGGAUAUGACGUGGGCCUGUUAGCUCAGUUGGUUAGAGCGUGGUGCUAAUAACGCCAAGGUCAUCGGUUCGAUCCCGAUACGGGCCAGCGGAAGCCUUUUGGGCCACGCGCCCACGCUGCAAUACGCGCACGAGAGGCCUUAAGGAUGUAAGGCCUAUAUGCCUGGUCGGACGGGCGGUCAGACGACAUUUGGGGGUUCGGGGGCGCUCGGGGCUAUGUAUGUUGUGGUGGGAGUCCUGUCAUGGUAUUGGGGAUGGAAAGGCACACAGACGGGAAACAUGCAAAGCUGUGGAGGGUAUGGAUAAGCCGCUGCAUGAACCACAUAACUGUGGAGGGCAGCCGCUGCAAGUACUGCAUUUUGCUUGUGCAGGUAACUGCACUACCAGCCGUGACUACCAGCCCGCAGAUAGCCAUGUGCAAGCAGUAUGCUAGCAGAUGCAUUGUUCUGUGCUGUUCAUUGCCGUGCCAACCACAAUCAAAAGGAGUGGCCUUCCCAUGCCCUUCUGGCAUGCAACUGGCCCACCAAGAACAAGGGAAAACAACAACGGCUGUGAUCCACAACGCCACCAUACUGCUUUCUGCUAAGAGGCCACCCCACUCCCACCACAACGUACACAACCUCGAGCGGCCCCGACCCUCCAAAUAAUGUUUGGCCGUCCGUCCUACCAGGCAAAUACCUUUUGGGCCUUGCCCGCGCACGUUACAGCGUCAGUCUGUGGCCCAAAAGGCUUCCGCUGGCCCGUAUCGGGAUCGAACCGAUGACCUUGGCGUUAUUAGCACCACGCUCUAACCAACUGAGCUAACAGGCCCACAUCAUAUCCCUCAGCCCCCCCCUCUCCCACAACCAGCGUACGGCGCUCCGUACAACCAUUUCCGU		53
19692	MI0005712	hsa-mir-920	Homo sapiens miR-920 stem-loop	GUAGUUGUUCUACAGAAGACCUGGAUGUGUAGGAGCUAAGACACACUCCAGGGGAGCUGUGGAAGCAGUAACACG		5
19693	MI0005713	hsa-mir-921	Homo sapiens miR-921 stem-loop	ACUAGUGAGGGACAGAACCAGGAUUCAGACUCAGGUCCAUGGGCCUGGAUCACUGG		5
19694	MI0005714	hsa-mir-922	Homo sapiens miR-922 stem-loop	AUGGCGUUUUCCCUCUCCCUGUCCUGGACUGGGGUCAGACUGUGCCCCGAGGAGAAGCAGCAGAGAAUAGGACUACGUCAU		5
19695	MI0005715	hsa-mir-923	Homo sapiens miR-923 stem-loop	UAUUUGUCAGCGGAGGAAAAGAAACUAACCAGGAUUCCCUCAGUAAUGGCGAGUG		5
19696	MI0005716	hsa-mir-924	Homo sapiens miR-924 stem-loop	AAUAGAGUCUUGUGAUGUCUUGCUUAAGGGCCAUCCAACCUAGAGUCUACAAC		5
19697	MI0005717	hsa-mir-509-3	Homo sapiens miR-509-3 stem-loop	GUGGUACCCUACUGCAGACGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGGUAGAGUACUGCAU		5
19698	MI0005718	rrv-miR-rR1-1	Rhesus monkey rhadinovirus miR-rR1-1 stem-loop	GGGUCAGACCCCGCGAUCGCACCUUUGGCCGGCCGGCCUCUGCCCGGCCACCGAGGAUGCGGUCAAUGGGUCGAACCC		54
19699	MI0005719	rrv-miR-rR1-2	Rhesus monkey rhadinovirus miR-rR1-2 stem-loop	CAGCCUCCCGCGACCAUGCUGCGCCCCGUAUUCGUGCGGAAGGCAAUUCGAAUAUACGGCGCUGCACGGUUGGAGGGCGGUUG		54
19700	MI0005720	rrv-miR-rR1-3	Rhesus monkey rhadinovirus miR-rR1-3 stem-loop	CAGGGCCCGAUGAGCAGUUAGUCCGUGUUUAGUCGCGCUCCCUGUUGUGUUUAAAUUUAACAGGGUUUGCGACAGACACUGAUUCGCUGCCCAAAGUCGCCGUU	The predicted stem-loop precursor for miR-rR1-3 does not meet the processing rules published by the same authors in [2], and therefore may be incorrect (Cullen BR, pers. comm.). 	54
19701	MI0005721	rrv-miR-rR1-4	Rhesus monkey rhadinovirus miR-rR1-4 stem-loop	CCGUGUUGUGAUUUGGGGAGGGCGGUCAGCGCGCGUUCCCGUGUUUAGGGAAUAUGUAUAUCGCUCGUUAACCGCCCUCCCGAGAUUACUGCUCGG		54
19702	MI0005722	rrv-miR-rR1-5	Rhesus monkey rhadinovirus miR-rR1-5 stem-loop	CAUCGUAACGCCCCCGGAACCCAAAGACACGUGCCCGUGGUCUUAAGAUCGGGCGUGUUCUUUGGAUUCCGUCUCGUUACGAUG		54
19703	MI0005723	rrv-miR-rR1-6	Rhesus monkey rhadinovirus miR-rR1-6 stem-loop	GCGGUGAACCGCGGAAAGGUGUGCACAUCGUAAAAUCACUACUGCGAUGUACGCCCUUUCGCAGUUUACUGC		54
19704	MI0005724	rrv-miR-rR1-7	Rhesus monkey rhadinovirus miR-rR1-7 stem-loop	UGCGAUUCGUGGAGAGCAGUUAACGUGCGUUCCCGUCAAUUAAUACCGGCGCACGUCGAUUGCUCUCUAGGGAUCCCA		54
19705	MI0005725	cgr-mir-21	Cricetulus griseus miR-21 stem-loop	UGUACCACCUUGUCGGGUAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUCUGACAUUUUGGUAUC		55
19706	MI0005726	ame-let-7	Apis mellifera let-7 stem-loop	ACGAUGCCUGGGUGAGGUAGUAGGUUGUAUAGUAGGGAAUGGAAAUUCGCGAUAUACGAAGUCCACUGUACAACUUGCUAACUUUCCCGGUCGUCGACGC		18
19707	MI0005727	ame-mir-10	Apis mellifera miR-10 stem-loop	CCCAGUUAAUGCUCUACAUCUACCCUGUAGAUCCGAAUUUGUUUGAUAAGAGGCGACAAAUUCGGUUCUAGAGAGGUUUGUGUGGUGCAUACAGAGCUAC		18
19708	MI0005728	ame-mir-100	Apis mellifera miR-100 stem-loop	GCUAUACUUGAUGAUACUAACCCGUAGAUCCGAACUUGUGGGCUUUUUUAUAUGUAUACCGCAAGCUCCUAUCUACCGGUACAUGUAGUCAGGCCAGCAU		18
19709	MI0005729	ame-mir-137	Apis mellifera miR-137 stem-loop	GACUUCAUAGGCCAGGUUGGCGACGCGUAUUCUUGGGGAAUUAACACACAUUUGCGCUGUUAUUGCUUGAGAAUACACGUAGUUUGCCUGGUCGUUCACU	Weaver et al. identify a second variant mature miRNA sequence offset including an extra 2 nt (UG) at the 5' end, and 3 nt at the 3' end (GUU) [1] 	18
19710	MI0005730	ame-mir-13a	Apis mellifera miR-13a stem-loop	ACCGAAAUGAAAAUACCUUUUGCGGUCCGAUACAUCAAAUUGGUUGUGGAAUGUUUCGAGUCAUAUCACAGCCAUUUUGAUGAGCUUGGCCCGCAGAAUC		18
19711	MI0005731	ame-mir-14	Apis mellifera miR-14 stem-loop	CUUUUUCUCGGUCGCUAGGUCAGUGGGGGUGAGAAACUGGCUUGGCUCUCUGUGCUACGAUAGUCAGUCUUUUUCUCUCUCCUAUCGGCUUUGCGACAUA		18
19712	MI0005732	ame-mir-2-3	Apis mellifera miR-2-3 stem-loop	AAAUAUCCCCGGACAAGGACAUGCUUUUACCAUCAAAGUUGGUUUGUCAUAGAGAUCGACUAUCACAGCCAGCUUUGAUGAGCAAAAUUGUGUCCGUCUA		18
19713	MI0005733	ame-mir-275	Apis mellifera miR-275 stem-loop	AAACGUUACUUGUCGUGCGCAACGCGCGUUACUCGGGUACUUUAGGCUGUGCCAAUUUCGAAUCAGUCAGGUACCUGAAGUAGCGCGCGCUGCGGCGAAA		18
19714	MI0005734	ame-mir-279	Apis mellifera miR-279 stem-loop	AGAAAAUGAAAAAAUUUCCUGAAUUUGCCAAAUGAGUGAAGGUCUAGUGCACAGAAAAUGAAAUUGUGACUAGAUCCACACUCAUUAAGUACGUUCAGGU		18
19715	MI0005735	ame-mir-283	Apis mellifera miR-283 stem-loop	AAUAAUCUGGUGAUGUAGUCAAAUAUCAGCUGGUAAUUCUGGGAUUUUGACAAUAACCCAGGAUUCUUGCUGGUAUCCGGCUACGAACUGGACGAUCGCC		18
19716	MI0005736	ame-mir-29b	Apis mellifera miR-29b stem-loop	AUUUAAAGACAAUAAGAAGAUAGAGGUACUGACUUCUAUGCGUGCUGGGGUUUGUGCUAAAUCUCCUAGCACCAUUUGAAAUCAGUACUACUCUUCUUAG		18
19717	MI0005737	ame-mir-31a	Apis mellifera miR-31a stem-loop	AUCACGAUUCUAACUGGGCGCCUCGAAGGCAAGAUGUCGGCAUAGCUGAUGCGAUUUUAAAAUUCGGCUGUGUCACAUCCAGCCAACCGAACGCUCAGAC		18
19718	MI0005738	ame-mir-33	Apis mellifera miR-33 stem-loop	UAUUUAUUUGAUUGCUUACCUGUUACAACUGUGCAUUGUAGUUGCAUUGCAUGAAAUAUAACUAUGCAAUACUUCUACAGUGCAACUCUUGUGGCAGAUU		18
19719	MI0005739	ame-mir-34	Apis mellifera miR-34 stem-loop	UUUUUUUGCGAUUGGCAUGUUGGCAGUGUUGUUAGCUGGUUGUGUGGCUACAUUGUAUAUACGACCGCUAUCGGCACUGCAAUUAUGACGAUCGUAGGGU		18
19720	MI0005740	ame-mir-375	Apis mellifera miR-375 stem-loop	AUCGAUUGAAUUAUCAGUUUGGUGCAUCGAUCCUAACGAUCAACAAACUUUUCACUUGAAAGUUUGUUCGUUCGGCUCGAGUUAUCAAACUGAAUGGAUG		18
19721	MI0005741	ame-mir-71	Apis mellifera miR-71 stem-loop	GUCCUCCUUCGGGCGGAUUCCGUCUGAAAGACAUGGGUAGUGAGAUGUUCUCACGCUAUCGCGUCUCACUAUCUUGUCUUUCAUCCGGCGUUCGUUCUGC		18
19722	MI0005742	ame-mir-79	Apis mellifera miR-79 stem-loop	UUCAAGACUGUCAAAGCUUUUGCCUUUACUUUGGUAAUAUAGCUCUAUGAUUUUAAUUAAGGAUCAUAAAGCUAGAUUACCAAAGCAAAGAGCACUAGCA		18
19723	MI0005743	ame-mir-87-1	Apis mellifera miR-87-1 stem-loop	ACAGUACUCUUACGCCUGAAAUUUGCUUUUUACCUGGCCCUCGUGCUCUCUUACUUUGAGAAAAUAAAGGUGAGCAAAGUUUCAGGUGUGUGAGUGCGUU		18
19724	MI0005744	ame-mir-87-2	Apis mellifera miR-87-2 stem-loop	UAUAAAGCAUCCGAACGUUACGGGCGGGCCUGACUCUUUGCUCUGCCCGUAUCUUUUUUUCCACUCUGGGUGAGCAAAGUUUCAGGUGUGUCCGUGACAG		18
19725	MI0005745	ame-mir-92a	Apis mellifera miR-92a stem-loop	UUAUUUUGCAUAGAAGAUAGGCCGAGAUUUGUGACAAUGUUUCGUGAUGAUGUAAUCUUCAAUAUUGCACUUGUCCCGGCCUAUCGGAAUGCAUUAUAUU		18
19726	MI0005746	ame-mir-925	Apis mellifera miR-925 stem-loop	UCUGUCCUUGCAUGCAGGGAUUCGGUUUUGUAACAUUCGCAAAUAGUGCUGACGCGGACCGGGCACGUGAGAGGCUACACGGCACCGUGGUUGAGGGCAG		18
19727	MI0005747	ame-mir-926	Apis mellifera miR-926 stem-loop	UCCGGCGAGUUAAUCGGCGCCACCAUCCUCUCCACCGUUAGAAAAGCGGCCAGGUUGGCGGUGUACGAGGAGAUUAGGAUCAGGGUGAAGAACCACCACA		18
19728	MI0005748	ame-mir-927	Apis mellifera miR-927 stem-loop	AGAUAAAAGCGUGGUAUUUGUUUUAGAAUUCCUACGCUUUACCGAUGUUCGAAGUGGCAAAGCGUUUGAAAUCUGAAACGAAUGCGCAUAAACCUUCAUC		18
19729	MI0005749	ame-mir-928	Apis mellifera miR-928 stem-loop	GUCCAGUAUUCCUGGCUGUGGAAGCUGGCGAACGUCACCCAGUCCCCGUACAGUUACCUGUGGACCAAUACCAGCACCGCGCCUGAAUUAGUUGCGGGAC		18
19730	MI0005750	ame-mir-190	Apis mellifera miR-190 stem-loop	CAAACAAGUCGUCUGGUUUCCGUAAGAUAUGUUUGAUAUUCUUGGUUGUUUUUUAAAGAAUCGACCAGGAAUCAAACAUAUUAUUAUGGUGGUCAGAAAA	Weaver et al. identify this bee homolog of human mir-190b [1].  They also report a second predicted hairpin on the opposite strand, with RT-PCR evidence for the expression of a second mature miRNA (UAAUAAUAUGUUUGAUUCCUGG). 	18
19731	MI0005751	ame-mir-929	Apis mellifera miR-929 stem-loop	ACUUAACUGGGGUCAAAUUGACUCUAGUAGGGAGUCCCUGCAUUCAAUAUGGCGACUUCCUAAUAGAGUCAGGCUGACUCCUUUUAAGACGUUCAACGGA		18
19732	MI0005752	ame-mir-930	Apis mellifera miR-930 stem-loop	CACCUGACCUGAUCCUGGUUCGAUUUUUGUUGCAGGUGAAAAUCUGGUUCCAGAAUAGAAGGAGUAAAUACAAGAAGAUGAUGAAGGCGGCGCAGCAGGG		18
19733	MI0005753	ame-mir-931	Apis mellifera miR-931 stem-loop	ACUUGCUCCUGGGACGGUUGUUGGGGCAUGUGCAGGCGGUUGAACACGACGCGGACGUCGGUCGCCGUCACCCAGUCCUGCAGCACCGGCGAGUUGUCGA		18
19734	MI0005754	ame-mir-932	Apis mellifera miR-932 stem-loop	CAUCGCGUUGCCUCUUCAAUUCCGUAGUGCAUUGCAGAUGAUUGUUCGAAUUGACGAGAAAGAACCUGCAAGCACCGCGGGAGUGAGGUGGCCUCGCGUC		18
19735	MI0005755	hsa-mir-933	Homo sapiens miR-933 stem-loop	ACUUGGGUCAGUUCAGAGGUCCUCGGGGCGCGCGUCGAGUCAGCCGUGUGCGCAGGGAGACCUCUCCCACCCACAGU		5
19736	MI0005756	hsa-mir-934	Homo sapiens miR-934 stem-loop	AGAAAUAAGGCUUCUGUCUACUACUGGAGACACUGGUAGUAUAAAACCCAGAGUCUCCAGUAAUGGACGGGAGCCUUAUUUCU		5
19737	MI0005757	hsa-mir-935	Homo sapiens miR-935 stem-loop	GGCGGGGGCGCGGGCGGCAGUGGCGGGAGCGGCCCCUCGGCCAUCCUCCGUCUGCCCAGUUACCGCUUCCGCUACCGCCGCCGCUCCCGCU		5
19738	MI0005758	hsa-mir-936	Homo sapiens miR-936 stem-loop	UCAAGGCCACUGGGACAGUAGAGGGAGGAAUCGCAGAAAUCACUCCAGGAGCAACUGAGAGACCUUGCUUCUACUUUACCAGGUCCUGCUGGCCCAGA		5
19739	MI0005759	hsa-mir-937	Homo sapiens miR-937 stem-loop	AGCACUGCCCCCGGUGAGUCAGGGUGGGGCUGGCCCCCUGCUUCGUGCCCAUCCGCGCUCUGACUCUCUGCCCACCUGCAGGAGCU		5
19740	MI0005760	hsa-mir-938	Homo sapiens miR-938 stem-loop	GAAGGUGUACCAUGUGCCCUUAAAGGUGAACCCAGUGCACCUUCAUGAACCGUGGUACACCUUUAAGAACUUGGUAUGCCUUC		5
19741	MI0005761	hsa-mir-939	Homo sapiens miR-939 stem-loop	UGUGGGCAGGGCCCUGGGGAGCUGAGGCUCUGGGGGUGGCCGGGGCUGACCCUGGGCCUCUGCUCCCCAGUGUCUGACCGCG		5
19742	MI0005762	hsa-mir-940	Homo sapiens miR-940 stem-loop	GUGAGGUGUGGGCCCGGCCCCAGGAGCGGGGCCUGGGCAGCCCCGUGUGUUGAGGAAGGAAGGCAGGGCCCCCGCUCCCCGGGCCUGACCCCAC		5
19743	MI0005763	hsa-mir-941-1	Homo sapiens miR-941-1 stem-loop	CCCGGCUGUGUGGACAUGUGCCCAGGGCCCGGGACAGCGCCACGGAAGAGGACGCACCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGG		5
19744	MI0005764	hsa-mir-941-2	Homo sapiens miR-941-2 stem-loop	CCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGGACAGCGCCACGGAAGAGGACGCACCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGG		5
19745	MI0005765	hsa-mir-941-3	Homo sapiens miR-941-3 stem-loop	CCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGGACAGCGCCACGGAAGAGGACGCACCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGG		5
19746	MI0005766	hsa-mir-941-4	Homo sapiens miR-941-4 stem-loop	ACGCACCCGGCUGUGUGCACAUGUGCCCAGGGCCCGGGACAGCGCCACGGAAGAGGACGCACCCGGCUGUGUGCACAUGUGCCCAGGGCCC		5
19747	MI0005767	hsa-mir-942	Homo sapiens miR-942 stem-loop	AUUAGGAGAGUAUCUUCUCUGUUUUGGCCAUGUGUGUACUCACAGCCCCUCACACAUGGCCGAAACAGAGAAGUUACUUUCCUAAU		5
19748	MI0005768	hsa-mir-943	Homo sapiens miR-943 stem-loop	GGGACGUUCUGAGCUCGGGGUGGGGGACGUUUGCCGGUCACUGCUGCUGGCGCCCUGACUGUUGCCGUCCUCCAGCCCCACUCAAAGGCAUCCC		5
19749	MI0005769	hsa-mir-944	Homo sapiens miR-944 stem-loop	GUUCCAGACACAUCUCAUCUGAUAUACAAUAUUUUCUUAAAUUGUAUAAAGAGAAAUUAUUGUACAUCGGAUGAGCUGUGUCUGGGAU		5
19750	MI0005770	bna-MIR156a	Brassica napus miR156a stem-loop	UGACAGAAGAGAGUGAGCACACAAAAGUAAUCUGCAUAUACUGCAUUUGCUUCUCUUGCGUGCUCACUGCUCUUUCUGUCAG		57
19751	MI0005771	bna-MIR171	Brassica napus miR171 stem-loop	GAUAUUGGCCUGGUUCACUCAGAUUACACACGUACUAUAUGCAUUCUCUUAGUUAUCUGAUUGAGCCGCGCCAAUAUCUC		57
19752	MI0005772	bna-MIR393	Brassica napus miR393 stem-loop	UCCAAAGGGAUCGCAUUGAUCCUAAUCAAGCUGAGUUAUUCCCGAAUAAUUAUUUUAAUUUUUUCUCAAUGGAAAGAUAGAAAAAAAAAAUUUUGCUUCGUUUUCCGGAUCAUGCGAUCUCUUCGGA		57
19753	MI0005773	bna-MIR396a	Brassica napus miR396a stem-loop	UUCCACAGCUUUCUUGAACUUUCUUUUUCAUUUCCCUUAUUUUASAGCGAAAUUAAAUAACUAAAAAUCUCUAACAUUUAACACUCUASAAAAAAAAAGCUCAASAAAGCUGUGGGA		57
19754	MI0005774	bna-MIR399	Brassica napus miR399 stem-loop	ACAGGGCAAGAUCUCUAUUGGCAGAAAACCAUUACUUAGAUCUUUGCAUCUCUUUCUGCAUUGAUUUGUAGUGAGUUCUCUGCCAAAGGAGAUUUGCCCGGU		57
19755	MI0005775	hsa-mir-297	Homo sapiens miR-297 stem-loop	UGUAUGUAUGUGUGCAUGUGCAUGUAUGUGUAUAUACAUAUAUAUGUAUUAUGUACUCAUAUAUCA	The extents of the mature sequence are not absolutely determined in [1], but are predicted from mouse miR-297. 	5
19756	MI0005776	pta-MIR156a	Pinus taeda miR156a stem-loop	GAUGACAGAAGAUAGAGAGCACAUCCGCUCACAUGCCGGGACUCUGCGUUUGAGGUGUAUGUGGUCUCCAUGAUUCUGUCAUC		58
19757	MI0005777	pta-MIR156b	Pinus taeda miR156b stem-loop	GAUGACAGAAGAUAGAGAGCACAACCGCUCAGAUGCCGGCACUCUGCGUUUGAGGUGUAUGUGCUCUCGUUGAUUUUGUCAUC		58
19758	MI0005778	pta-MIR159a	Pinus taeda miR159a stem-loop	GAUGUGUUGGAGCUCCCUUCAGUCCAACCAAAGCUUGUGCAGCGGUGGUUCAGCUGCUGAUUCAUGCAUUCUACUUCCCUGUCCGUGACUCUCCAGCAGCCUGAACAAAUCAAUCAAUCGACCUGCAUGACAGGAUAGUGGUGUGCAUGACGCAGGAGAUGUACUGUCACUAAACACGCAUUUCUUGGAUUGAAGGGAGCUCCACUUAUC		58
19759	MI0005779	pta-MIR159b	Pinus taeda miR159b stem-loop	UUACGGGGAGCUUUCUUCAGUCCAACGAAAGGCCGUAUAGGGAUGAUUCAACUGCUGGUUCAUGGACUCUACUAUCUUGUAAUCCUCGAGGUUCAGUAUUGGCGGCAAGAUAAUGGUGUGCAUGACACGGGAGUCGUAUUGCCACUACGCUGUUUUUACUUGGAUUGAAGAGAGCUCCCAGAAA		58
19760	MI0005780	pta-MIR159c	Pinus taeda miR159c stem-loop	GAUGUGUGAAUGAUGCGGGAGCUGAUUUUGUCCAGGAAAUGUCUUUUCCUUGGAUUGAAGGGAGCUCCCUUAUGUAGCAUACAUU		58
19761	MI0005782	pta-MIR166a	Pinus taeda miR166a stem-loop	UUGAUUGAGGGGAAUGUUGUCUGGCUCGACUUCAUCCGGAUUUGGGCUCCAAUGUUCGGAUGCCGUCGGACCAGGCUUCAUUCCCCCCAAUCGG		58
19762	MI0005783	pta-MIR166b	Pinus taeda miR166b stem-loop	GGCAGAGUUGGGGUGAGGGGACUGCAGCCUGGCACGAGACCUGAAAACUUUUCUGACAAGCAGCCGGGCGGGCAGAGUCACGCAUGGUGUCGGACCAGGCUUCAUUCCCCUCACAACACUCUUCC		58
19763	MI0005784	pta-MIR166c	Pinus taeda miR166c stem-loop	ACCAAUCGAAUCCGGACCAGGCUUCAUCCCAGGCAUCUGGACCCAAUCGACAGCAGCUCCUUUAGCCUUUGAAAGGAACUCUGUCAAGGUCUCCUCUGCUAUAGACAGGAGUCCAGCGGGGCUAGCAUCUCUUGGGGGAUGCUGAGGUGUUGGAUUAUGUUGGU		58
19764	MI0005785	pta-MIR171	Pinus taeda miR171 stem-loop	UGUGAUUGAGACGAGUCCAUAUCUUCUUCAGGCGAAGCCUCCACCACUCCAAAAGAACUGAAUGCAGGUUUCCGAUGCAUCAAUCUCAGUGCACUAGACAAUAUCAUGUUGGAGGGUACAGACAGUGCCGCCAUGUUUGGAUGGAGGAGACCCAGGUCUGUUAUUGUUCUCGAUACACA		58
19765	MI0005786	pta-MIR319	Pinus taeda miR319 stem-loop	GAUAAGUGGAGCUCCCUUCAAUCCAAGAAAUGCGUGUUUAGUGACAGUACAUCUCCUGCGUCAUGCACACCACUAUCCUGUCAUGCAGGUCGAUUGAUUGAUUUGUUCAGGCUGCUGGAGAGUCACGGACAGGGAAGUAGAAUGCAUGAAUCAGCAGCUGAACCACCGCUGCACAAGCUUUGGUUGGACUGAAGGGAGCUCCAACA	The cloned miR319 sequence in [1] has a 5' terminal G residue, which is incompatible with the genome sequence and the hairpin shown here. 	58
19766	MI0005787	pta-MIR390	Pinus taeda miR390 stem-loop	AAUUAUGAAGCCCAGGAUGGAUAGCGCCAGCCCCACUUGAAAUUUGCAGUGGGCGCUAUCCCUCUGAGCUUUGUAAUU		58
19767	MI0005788	pta-MIR396	Pinus taeda miR396 stem-loop	GAAUCUUGUCAUACUUUUCCACAGCUUUCUUGAACUUUACGUGUACGGGACGAGGAGAUUCUGAUUUCUACGUCUGCGAUUAAAGUUCAAGAAAACUGUGGGAAAGCAUGGUAGGAUUC		58
19768	MI0005789	pta-MIR398	Pinus taeda miR398 stem-loop	AGCAGAGGAGGUUUCCACCGGGGCGACCUGGGAACACGUCUACAUUAAUGUAAUCUCUUGAUUUCUCCAUGAGUCCUGUGAAUGUGAAUGUGUUCCAAGGUCACCCCAGUCGAGCCUACUCUCU		58
19769	MI0005790	pta-MIR408	Pinus taeda miR408 stem-loop	GAGACAGGGACGAGUUAGGGCAUGGGAGUUGCAUAUGCAGAAACGUCUGCUUCUGCCAUUCUUAUGCACUGCCUCUUCCCUGGCUC		58
19770	MI0005791	pta-MIR482a	Pinus taeda miR482a stem-loop	GAGGUGUGGAAGGAUAGGGUAAGACUAAGGUUAAGGAGAAACUCUGCUUCAUUAAUUCUCUGCUCCAGUCUUCCCUACUCCUCCCAUUCCUU		58
19771	MI0005792	pta-MIR482b	Pinus taeda miR482b stem-loop	GAGGUGUGGAAGGAUAGGGUAAGACUAGGGUUAAGCAGAAACUCUGCUUCAUUAAUUCUCUGCUCCAGUCUUCCCUACUCCUCCCAUUCCUU		58
19772	MI0005793	pta-MIR783	Pinus taeda miR783 stem-loop	UUCUUUUGAGGGAAGGGAGCUGGCGUGCAUUUCUUUUUCAGAUAUUUCAUUGCGUUCGCCAAGAUGCUUUGCUGGUUCAUUUUCCCUGAGAUGAA		58
19773	MI0005794	pta-MIR946a	Pinus taeda miR946a stem-loop	CAGAGUGUAUGGAUGUGGAUAGAGAAGGGUUAGUAAACGGUAGAAAACCCAUUUAUUGUAUGUCAUUGGCUGUUCGAGAUUAAGCAGCUGUAAUUCGAUGGCCAUACUCAUUAAAUGGGUUGGCUGUUUGCUCUGUACCAGCCCUUCUCCUAUCCACAAUUGUACUAGUUUG	The cloned miR946 sequences in [1] has an additional 3' A residue, which is incompatible with the genomic sequence and hairpin shown here. 	58
19774	MI0005795	pta-MIR946b	Pinus taeda miR946b stem-loop	CAGAGUGUAUGGAUGUGGAUAUGGAAGGGUUAGUAAACAGUACAAAACCCAUUUAAUAGAGAUUCCAUCGGAGCAUCAUUGUUGGCUGUUAGAUCAAGCAACUGUAUUUUGAUGGCCACACUCAUUGAAUGGGUUGCUUGUUUUGCUUUUAACCAGCCCUUUUUCUAUCCAACUGCCUGUAUUUUGAUGGCCAUGCUCAUUAAAUGGGUUACCUGUUAGCUAUUCACCAGCCCUUCUCCUAUCCACAACUGUACUAGUUUG	The cloned miR946 sequences in [1] has an additional 3' A residue, which is incompatible with the genomic sequence and hairpin shown here. 	58
19775	MI0005796	pta-MIR947	Pinus taeda miR947 stem-loop	ACGCCUAAGGCGCAGCAGCAGAUUCUGAUAGAAGACUCAGGCAAAGCAUUUGUUGUUGGCAGGUUGAAUGCUUUCGGCAGAACCACCAAUAACAAGGGGGGCGCCUGGUGUCUUGCAUCGGAAUCUGUUACUGUUUCCUAGGCGU		58
19776	MI0005797	pta-MIR948	Pinus taeda miR948 stem-loop	AAGUCAUGAAAUCAGGCUGUGUGGGAUCCGGUAACGCCACAGAGUAAGAUAGCAGCGUCAAAGUGACUGUAGGCAUUGGUGGAUAAAGUGAAGCGGUAUUGAUGAGGCCUCACAUUGUCCACCGAUGCCUACAGCCACUUUGACGUUCUCAUCUGAUUUUAUGACGGCCUCACUUCCUCCGCCAAUGCCUGAGGCGGUGUCAUCUGUUUUUGCGGCAUUACCGGAUCCUACAAACCCUGUUUUCAUGGGUU		58
19777	MI0005798	pta-MIR949	Pinus taeda miR949 stem-loop	AGAGCCUCUCCGGGAAUCCAAUGCGCCUUCCUCUUGAACGCCUUUCAACGCGCGUGCUGUGCGUGAAAACGCGUUUAGGAGGAAGGUGUAUUGAUUUCCGGGGAAGCCCU		58
19778	MI0005799	pta-MIR950a	Pinus taeda miR950a stem-loop	GGAAGGUGAUCUUUACAUCAGGUCCUCGGUGGUUUAUUGCUCAUCGUUUGUUUAUAAUAAACCAUCGUGGAGCCGAUGAAAAGAGCACCUCC	The most commonly cloned miR950 sequence in [1] has an additional 3' GA sequence, which is incompatible with the genomic sequence and hairpin shown here. 	58
19779	MI0005800	pta-MIR950b	Pinus taeda miR950b stem-loop	GGAAGGUGAUCUUUACAUCAGGUCCUCGGUGGUUUAUUGCUCAUCGUUUGUUUACGAUAAACCAUCGUGGAGCAGAUGAAAAGAGCACCUCC	The most commonly cloned miR950 sequence in [1] has an additional 3' GA sequence, which is incompatible with the genomic sequence and hairpin shown here. 	58
19780	MI0005801	pta-MIR951	Pinus taeda miR951 stem-loop	GAAGCGAUGGUGUUCUUGACGUCUGGACCACGAGGGUUUGCUUUACGUUGGGCAUGAAGAAACAAUCAUCUACCGCGGUUCAGUCAUCAAGAACACCUUUGCUUU		58
19781	MI0005802	pta-MIR952a	Pinus taeda miR952a stem-loop	GAACCAGUAGCGUAUUGAACAGAGCAUGCCGUUGGUUGAGUAAGUACGUCAAGGGACGAAACAGAAUUAAUUUUCAUUAACAUUUUAUUAACCUUCAACUCUGCCUUGGCCUAGGGCAGUUCCUGAAGGUCACAUUGACUGGGGCGUGAUACAACGCGUAGUCCGCUGGUUGCUGCGACCAUUGGGACUCCCCCAGCCUAUUCUCAGCUGCAACAUUCGCAAGUUAUUUACAGUGUUGCAGCCGAGAAUAAAAUGGGAAGAGUCAAAAGCGUGGCAACAACCAGCCAAUUACGCUUUGUAUCAGCGCCCCAACUGGUGUGAGCUUCGGGAAUUGCCAUAUGCCAAGCCAGAUUUGCAUGCUAAUAAAACAUUAUUCGAAAUUAAUUGCGUUUUGUUGGUUGACAGACUUCCUCCACCAAUGACACGCUCAGUUCAAUUUGCUGAUGGUUC		58
19782	MI0005803	pta-MIR952b	Pinus taeda miR952b stem-loop	GAACUACUCGCGCAUUGAACUGAGAAUGCCAUUGGUGGAGUAAGUACGUCAAGGGACGAAACAGAAUUAAUUUUGAUUAACAUUUUAUUAACCUUCAACUCUACCUUGGCUUAUGGAAGUUCGUGAAGGUCACAGGGCAAGGACUAGUCUGCUGGUUGCUGCCACAGUCAAUUGGGACUCUCCCAAGUUAUUCUCAGCUGCAGCAUUCCGAAGUUAUUCAAUGUUGCAGCCGAGAAUAUUAUGGGGACAGUCCAUUGGUCACAACAGCCAGCCGAUUACACCUUGUAUGAGUGCCCCAACUGGUGUGAGUUUCAUGAACUGCCAGAAGCCAAAACAGAGUUGCAACGCUAAUAAAACAUUAUGCAAAAUUAAUUCCAUUUUGUUGGUUGACAUACUUCAUCCGCUAAUAGCACGCUUAGUUCAAUUUGCUAAUGGUUC		58
19783	MI0005804	osa-MIR529b	Oryza sativa miR529b stem-loop	AUCGUGAAGGCUAAAUGGAGAAGAGAGAGAGUACAGCUUUGGGCGGUUUAGUUGUUAGAUGGUGGAAGUACUUGCGACGCCUACUACCCUUUUCACCAAGGCUGUACGCUCCCUCUUCUUCUCUUAGCUUUUUAUGAU		7
19784	MI0005805	dme-mir-iab-4as	Drosophila melanogaster miR-iab-4as stem-loop	UCGUGUUACGUAUACUGAAGGUAUACCGGAUAGGAUACACUCAGGAUACAUUCAGUAUACGUUUACGA		4
19785	MI0005806	dme-mir-954	Drosophila melanogaster miR-954 stem-loop	UACAAACACAAGAUUUUCUGGGUGUUGCGUUGUGUGUACCUGUGUACAGGCGUAUUCACAUGCAACAUCCCUUACAUCUUGCUUGAU		4
19786	MI0005807	dme-mir-955	Drosophila melanogaster miR-955 stem-loop	GGCCAGCUAAUCAACUCCAUCGUGCAGAGGUUUGAGUGUCCUGUGUUUUGCCUAAUCGCAUUCAAUUUCUGAACGGUAGAGAUGGUACGCUUAGAAA		4
19787	MI0005808	dme-mir-190	Drosophila melanogaster miR-190 stem-loop	CGAACUAAUUGAUGGUUCCAGUGAGAUAUGUUUGAUAUUCUUGGUUGUUUCAUUCAAAAGUUCACCCAGGAAUCAAACAUAUUAUUACUGUGACCCUCGC		4
19788	MI0005809	dme-mir-193	Drosophila melanogaster miR-193 stem-loop	UGUGUGCCCUUAUUAUGGUUGGGAUUUUUUAGAUCAGCAGUUAUUGCUAUAUAGCCAUAUUUAUAAAUCUUCUACUGGCCUACUAAGUCCCAACAUAAUGAGAGUAAA		4
19789	MI0005810	dme-mir-956	Drosophila melanogaster miR-956 stem-loop	GAUCGUUAUCGUGUUUGGAAUGGUCUCGUUAGCUAACGGAUGAGCAAGUGCUCGGCUCACUGGCCCAAAUGCAGUUUGCCCGGAGACGCCGGUUAACCCAGCACUGAAAUGUGUAGUUUCGAGACCACUCUAAUCCAUUGCAGCAUUU		4
19790	MI0005811	dme-mir-957	Drosophila melanogaster miR-957 stem-loop	UGUCCACAAUAGACCUUAGUUUUCGACGUGUUUUGGUGUGCUGGGGAGUUCUAUUCCGAUUGAAACCGUCCAAAACUGAGGCCAACUGUGAGGCGC		4
19791	MI0005812	dme-mir-958	Drosophila melanogaster miR-958 stem-loop	GGCGUGUCUAUGGCAAGUAGAAUAGCAGGCUUAUCACAUGUUUAAUUCAAUCUGCUGUGAGAUUCUUCUAUUCUACUUUCGACAACACCCGU		4
19792	MI0005813	dme-mir-375	Drosophila melanogaster miR-375 stem-loop	CCGGGCAGCGAAUUACUUGGGCCAAGGGAAUGCAAACUGUGAUCAUCCCGAAAGUUUGUUCGUUUGGCUUAAGUUAUUUUCAUGUCCGACU		4
19793	MI0005814	dme-mir-959	Drosophila melanogaster miR-959 stem-loop	UUAACUUUGUUCUAUAUUCUUAGUACUCGGGUUGAUAAAGACCUUUUCUUCAGGGAGCCUUUGUCAUCGGGGGUAUUAUGAAAUAUAGUUUAAAGAAA		4
19794	MI0005815	dme-mir-960	Drosophila melanogaster miR-960 stem-loop	GGGUUUUGUACCACAUUCUGAGUAUUCCAGAUUGCAUAGCUUUGUGCUACUAUUGCUAUACGGUCUGGGACACUUUUAACAUGGUAUCAAAUC		4
19795	MI0005816	dme-mir-961	Drosophila melanogaster miR-961 stem-loop	UCAAGGGCCGAGUUACCUUUGAUCACCAGUAACUGAGAUUGUUUCUGAUACGGUUUCGUUUUCUGGCAAUCAAAAGAACUUGGACUCGA		4
19796	MI0005817	dme-mir-962	Drosophila melanogaster miR-962 stem-loop	GAUGGGGCACUCAGGCUAUAAGGUAGAGAAAUUGAUGCUGUCUACACUAUUCAGACUUCAGUUUCAUUACCUUUCAAUUUGUUUGCCCCCAU		4
19797	MI0005818	dme-mir-963	Drosophila melanogaster miR-963 stem-loop	UUAGUCUAAUCUAAAACAAGGUAAAUAUCAGGUUGUUUCCUGUAUUCGAUCGAAACAUCUGUAUAUACCUUUGUUCCGAUUGGACAAAA		4
19798	MI0005819	dme-mir-964	Drosophila melanogaster miR-964 stem-loop	CAAUAACAUAUUGGUCCAACUUGCCUUAGAAUAGGGGAGCUUAACUUAUGUUUUUGAUGUUUAAGUUAAAAGCCUCUGUUCUAAGACAAUUUGAUGAUCA		4
19799	MI0005820	dme-mir-932	Drosophila melanogaster miR-932 stem-loop	UUGGUUUUGAAGUUUUCAAUUCCGUAGUGCAUUGCAGUGUGUUUCAUUAUUUACUGCAAGCGCUGCGGAUUUGGCAACUUUGACGACCUUC		4
19800	MI0005821	dme-mir-965	Drosophila melanogaster miR-965 stem-loop	GACAAUAUUGCUCAACAUUUUGGGGGGUAAAACUGUACGUUAUAUGUGCCCUUCUGUGAUAUUCAUAAGCGUAUAGCUUUUCCCCUUAAAAGUUAGAGCUAUUGCAA		4
19801	MI0005822	dme-mir-966	Drosophila melanogaster miR-966 stem-loop	AACCUGAUCCGCUGCUGUGGGUUGUGGGCUGUGUGGCUGUGGUAUAGGUGCCGCCAGUUGAUAACCCCCAGCGUGGGCACGGACCCA		4
19802	MI0005823	dme-mir-967	Drosophila melanogaster miR-967 stem-loop	CUUGGAGAGCAGAGAUACCUCUGGAGAAGCGCGUGACCUGACCCCAGCAGGAGAACCCAACCCGCUUUUCCACCUAGGUGUCUCUCUCUCUCUUUAU		4
19803	MI0005824	dme-mir-1002	Drosophila melanogaster miR-1002 stem-loop	UAGAAAUUAUAUAUUUAAGUAGUGGAUACAAAGGGCGAUUUGAUAUAAAAGUGUCGCAUUGUAUGACCUACUUAACUAGCUGAUUUUGU		4
19804	MI0005825	dme-mir-968	Drosophila melanogaster miR-968 stem-loop	UGAUGGAAGCUUCCUUAAGUAGUAUCCAUUAAAGGGUUGUUCUCAACAUGCAAAUCAACCUUUUGAUGUACUACUUUAAGAAUCUCCAGUUA		4
19805	MI0005826	dme-mir-969	Drosophila melanogaster miR-969 stem-loop	AGUCUCUGUCCUACGUCCGAGUUCCACUAAGCAAGUUUUGAGAUCGUUUUAAAAACAAAAACUUGACACGUUGAGCUCGUUCGUGGGAUGGACU		4
19806	MI0005827	dme-mir-970	Drosophila melanogaster miR-970 stem-loop	GAAAGGCAUCUGUUGCAGCUAGCGGGUGUUUUAUUUGGUAGCUGUAAUGAUUUGAAUCUAUCAUAAGACACACGCGGCUAUAACCGUUGUCUAAG		4
19807	MI0005828	dme-mir-971	Drosophila melanogaster miR-971 stem-loop	UCCGUGGCUGGCAUCGCUCGCUGUAAAUUGUAAUCAUCAAAGCGUUUUCUCAGAGCCGCUUGGUGUUACUUCUUACAGUGAGUGUGCCAGUCCGUA		4
19808	MI0005829	dme-mir-972	Drosophila melanogaster miR-972 stem-loop	AGAAUGAUAGGGAAAUUGCUAAAUAUUUUUUUUGUAUAAAUAACUUUUAACUUUUGUACAAUACGAAUAUUUAGGCAUUUCUCAAAUCAAA		4
19809	MI0005830	dme-mir-973	Drosophila melanogaster miR-973 stem-loop	ACCGUCGUCGACUUUUCGUGGUUGGUGGUUGAACUUCGAUUUUAAGUAUUUAAAUAAAAUGAAAUCUGUUCAUUCUCCGACACAAGAAGUUCACGCAAAGG		4
19810	MI0005831	dme-mir-974	Drosophila melanogaster miR-974 stem-loop	CAAUUGUCACCGGUCAUGUCCUCCAAGCGAGCAAAGAAGUAGUAUUUGUGUUUCCAAGAGCAAAUAUAACUUCAUUGGAAGCUAAGUGGAUUUGCCCAAAU		4
19811	MI0005832	dme-mir-975	Drosophila melanogaster miR-975 stem-loop	UUGAAUUUUUGAUUUUAAACACUUCCUACAUCCUGUAUGUGUUUUGCAUCCGGUACAGAUGUGGGAGUCGUUUGCACUCAGAGAUUUCACA		4
19812	MI0005833	dme-mir-976	Drosophila melanogaster miR-976 stem-loop	CAUCGCCAUGCAGUGCCGCGGCAUUGGUGAGGCCAUCUCCAAUGGAUUAGUUCUCAACAUUGGAUUAGUUAUCAUCAAUGCCGGUGCACUGCACCUA		4
19813	MI0005834	dme-mir-977	Drosophila melanogaster miR-977 stem-loop	CGAAUCAACAAACAAGGUAUGCUUUAGAUAACUCGAAUAUCACAUCUUCAGUGUUCGAAAUCUGAUGAGAUAUUCACGUUGUCUAAAUCAUGUUUUGUA		4
19814	MI0005835	dme-mir-978	Drosophila melanogaster miR-978 stem-loop	GUUGGCGGCACAAUCUGCAAUCUACGCCACUGGCUUACGUUGCAAUCGAAAAUCGUGUCCAGUGCCGUAAAUUGCAGUUGUGUGAACGCAAA		4
19815	MI0005836	dme-mir-979	Drosophila melanogaster miR-979 stem-loop	UACAUGUGAGGAUGUCACAAAUACACUGAAUUUGGGGGGAAUUCUUAUGUAUAUACAAAUUCUUCCCGAACUCAGGCUAAUUUUGUGGCAUCCGU		4
19816	MI0005837	dme-mir-980	Drosophila melanogaster miR-980 stem-loop	AGUUGAUUGUAUGUCAGUUUUUCAUUUGGCCUGGCUAGCUUACUCCUUUUUAAAUAUUGCUAGCUGCCUUGUGAAGGGCUUACGUGUAAUUGCAGUUC		4
19817	MI0005838	dme-mir-981	Drosophila melanogaster miR-981 stem-loop	AAACAUCCUCACUGAAGUCGGGUUUCGUUAGCAGCGGGCUGUUUUAAUAAAUUCAACAAGUUCGUUGUCGACGAAACCUGCAUGCUGUGUGGAAAAU		4
19818	MI0005839	dme-mir-982	Drosophila melanogaster miR-982 stem-loop	CGAAAUCAUGUUAGAUCCUGGACAAAUAUGAAGUAAAUUGUUUUUAUGCAUCAAUUACUUGAUAUUCAUCCUUGAACUAAAUGGUUUUAGAGC		4
19819	MI0005840	dme-mir-983-1	Drosophila melanogaster miR-983-1 stem-loop	UAUAUUGCAAUAAUUAAAUAAUACGUUUCGAACUAAUGAUUUUCAGUUCAUUCAUUAGGUAGUUACGCAUUAUCUAGUUGUUGUAAACAUU		4
19820	MI0005841	dme-mir-983-2	Drosophila melanogaster miR-983-2 stem-loop	UAUUAUAUUGCAAUAAUUAAAUAAUACGUUUCGAACUAAUGAUUUUCAGUUCAUUCAUUAGGUAGUUACGCAUUAUCUAGUUGUUGUAAACAUUCAACU		4
19821	MI0005842	dme-mir-984	Drosophila melanogaster miR-984 stem-loop	AGAAACAAAUUUCAUUGAGGUAAAUACGGUUGGAAUUUUGUCUUUUAACUAUAAAUCCAACCGAAUUUGGCUCGGCGAAAUUUUUCAGUU		4
19822	MI0005843	dme-mir-927	Drosophila melanogaster miR-927 stem-loop	UGGUUGCUGUAGAGUUUUAGAAUUCCUACGCUUUACCGUGGCAUACGAAAUUCGGCAAAGCGUUUGGAUUCUGAAACCCUACCGAUCCAUUA		4
19823	MI0005844	dme-mir-985	Drosophila melanogaster miR-985 stem-loop	UAUAUAAUAGCACUGCUGGCUCAUUGGUACAUUUCAUAAGUACCUUAUCAAAUGUUCCAAUGGUCGGGCAGAGCUAUUAUUUGUCC		4
19824	MI0005845	dme-mir-986	Drosophila melanogaster miR-986 stem-loop	CACACCUGAAAUUACCCAUCUCGAAUAGCGUUGUGACUGAGGUAACUGCGCAUCGAAUCUACUCAGCGGCGAGGCUAUUCAAGUAAGGUUAUUUUGGGCC		4
19825	MI0005846	dme-mir-987	Drosophila melanogaster miR-987 stem-loop	UGUUGGACUGUGUUUAAAGUAAAUAGUCUGGAUUGAUGAAAGUUGCAUUCGAGAAUUCAUCAACAGGCAUUUACUUCAACUGCAGUUUGAACAA		4
19826	MI0005847	dme-mir-988	Drosophila melanogaster miR-988 stem-loop	GACGGCGGUACCGGGCAUUUUGGGUGUGUGAUUUGUAGCAAAGUGAUAUGUAUUUGAUCAUCCCCUUGUUGCAAACCUCACGCCAAAGAUGAUCUGCGA		4
19827	MI0005848	dme-mir-989	Drosophila melanogaster miR-989 stem-loop	AAAGAUUUUGGGAAUCGGCCACUACCUUGCAGUCACGUGAUGAAAAGACACAGGUGACACUGAUCCGGAUUUGGUAGUUGACAAAUCCUCCAUGCCGAGAUUAGUUUCAUUUUGCGUCUUUUGAAUUCGAAUAGUUCAUGUGAUGUGACGUAGUGGAACAUACCUGAAAUUACA		4
19828	MI0005849	dme-mir-137	Drosophila melanogaster miR-137 stem-loop	CAAUCUCCAAUGGCCACGUGUAUGCUCGUAGCUAUAACCUGAAAUCCAAAUGUUAUUGCUUGAGAAUACACGUAGUUCACCGAGAUUUGUU		4
19829	MI0005850	dme-mir-990	Drosophila melanogaster miR-990 stem-loop	UCUGCUCUGCGACAUUCACCGUUCUGAGUUGGCCCCAAGUGCACGUGGGCCAGCUUUCAGCUUCGGUGCCAUUUCACCCCGAGCAC		4
19830	MI0005851	dme-mir-991	Drosophila melanogaster miR-991 stem-loop	UAUCACUGCAGUUUCAGGCUUUUCCCAACUACACCUAUUAAUACAUAUUUUAACGUCCUAUUAAAGUUGUAGUUUGGAAAGUUUUGGUUUUGCAUU		4
19831	MI0005852	dme-mir-992	Drosophila melanogaster miR-992 stem-loop	AUUUUCCCAAGUGCCUGGUAUCAGCAAAGUGUUAUUUUUUAUGUUUAUGUAAAGUACACGUUUCUGGUACUAAGUACUUCGAGAAAGUUACC		4
19832	MI0005853	dme-mir-929	Drosophila melanogaster miR-929 stem-loop	AGUCCUGGUGGAGCUCAAAUUGACUCUAGUAGGGAGUCCUUUAAUGAGCGACUCCCUAACGGAGUCAGAUUGAGCUGCAAAGGAGCGA		4
19833	MI0005854	dme-mir-993	Drosophila melanogaster miR-993 stem-loop	AACGCUCCCGUGACCUACCCUGUAGUUCCGGGCUUUUGUUUAAAUGGCGUUCGGCACAUUGUCGGACUGCUGGCUCGAUUAUCAGAAGCUCGUCUCUACAGGUAUCUCACAGGGUAGAA		4
19834	MI0005855	dme-mir-994	Drosophila melanogaster miR-994 stem-loop	UAUCGAGUUAUCUAAGGAAAUAGUAGCCGUGAUUUUACCCAAGAAUUUUUCACAUAUCACAGUUGCUGUUUCUUUUAGAUAGCUCUUUUGU		4
19835	MI0005856	dme-mir-995	Drosophila melanogaster miR-995 stem-loop	CACCUGCACCCCGCAGCCCGAAUUAUGUGGGAGCUGCGCCGUUUCCGUAAUCCGUAGCACCACAUGAUUCGGCUUCGUGGUACAGGAUAU		4
19836	MI0005857	dme-mir-996	Drosophila melanogaster miR-996 stem-loop	UCUGACUCUAUUUUGUCGGCGAACAUGGAUCUAGUGCACGGUGGUUCAUGAUUAAGUUCGUGACUAGAUUUCAUGCUCGUCUAUUAAGUUGGGUCAG		4
19837	MI0005858	dme-mir-252	Drosophila melanogaster miR-252 stem-loop	ACCAAGUUCGCUUUCCUAAGUACUAGUGCCGCAGGAGUUAGGUUCGUGUCCGCAAUACCUCCUGCUGCCCAAGUGCUUAUUAAAGCGGCGAGU		4
19838	MI0005859	dme-mir-997	Drosophila melanogaster miR-997 stem-loop	UUAUGGAUCCUCUUUCAAUGAAUUUAGUAUGCCCAAACUCGAAGGAGUUUCACCUCCAUAAGAGCGACAGUCCUGGAGAAGUUAUCAGAGCCAAAAAAAUUCAUAUGAUGAUGCAUUUUCCGUCUCUGAAAACGUCUUCAGCAGAAGUUGUUUUUAGCGAAGUGAAACUCAUUCGAUUUUGAUCAUACUAACGACAUUGGAUGCUUGGAUCGGCA		4
19839	MI0005860	dme-mir-998	Drosophila melanogaster miR-998 stem-loop	CCUCGUGUCAAAUUCAUUUUGGAACUGAAUUCUCGUGGGUCUGCACUGACAACACUGACCGCUCCAGGGCAAAUUGUUCAUUUUGAAAUUGAAAUUCUGUAGCACCAUGAGAUUCAGCUCUGGCGUGAAUUUCAAACAUGCAU		4
19840	MI0005861	dme-mir-999	Drosophila melanogaster miR-999 stem-loop	AAGGAUGCCGCUCAAUUACCCCGACAUAGUCAUACGGUGAAUGUUGUGUAUUGGAGACCAAUGUUAACUGUAAGACUGUGUCUCGGUGGUUGCCAGCCCAGCCAC		4
19841	MI0005862	dme-mir-1000	Drosophila melanogaster miR-1000 stem-loop	GACGCUUGCCAUUGAUAUUGUCCUGUCACAGCAGUAUUGUAACACUAUAUUAUAGUUUACUGCUGGGUCGGGGCAUUAACAUUGUUGAGCGUCAUUAGCA		4
19842	MI0005863	dme-mir-1001	Drosophila melanogaster miR-1001 stem-loop	AAGCUGGCCUGUCCCUGGGUAAACUCCCAAGGAUCAGGUGGAGAUUGAAUCCCGAUCCUUGGGUUUCUGCUCUCGGGCAAGGUCAGUAGU		4
19843	MI0005864	dme-mir-1003	Drosophila melanogaster miR-1003 stem-loop	GUGGGUAUCUGGAUGUGGUUGGCUCUGGCGGUCCUCUCACAUUUACAUAUUCACAG		4
19844	MI0005865	dme-mir-1004	Drosophila melanogaster miR-1004 stem-loop	GUUGGGGGACAUUGAUCUCGGAGACGGCGGUUUAACUGAUCCAUUCUCUCACAUCACUUCCCUCACAG		4
19845	MI0005866	dme-mir-1005	Drosophila melanogaster miR-1005 stem-loop	GUGAGUUGAUCGAUUUCGAGGUUUUGGCACACGAAUAUAAUCUGGAAUCUUUAAUUCGCAG		4
19846	MI0005867	dme-mir-1006	Drosophila melanogaster miR-1006 stem-loop	GUGAGUUUGAAAUUGAAAUGCGUAAAUUGUUUGGUACAAUUUAAAUUCGAUUUCUUAUUCAUAG		4
19847	MI0005868	dme-mir-1007	Drosophila melanogaster miR-1007 stem-loop	GUAAGCAGUGUUUGAACUCGAUCUUGGUUCUUGGACUCUUGAUAAGCUCAAUUAACUGUUUGCAG		4
19848	MI0005869	dme-mir-1008	Drosophila melanogaster miR-1008 stem-loop	GUAAAUAUCUAAAGUUGAACUUGGCCAAUGGCAAGUCACAGCUUUUUGUGUUUACAG		4
19849	MI0005870	dme-mir-1009	Drosophila melanogaster miR-1009 stem-loop	GUAAGUGUAAGACUUUCUUGAGUUACCCGCGAUGAGUAUCUCAAAAAUUGUUACAUUUCAG		4
19850	MI0005871	dme-mir-1010	Drosophila melanogaster miR-1010 stem-loop	GUAAGUGGUGUAGAUGAAACAAAUUUACCAACAAUUUUGUUGGAUUGUUUCACCUAUCGUUCCAUUUGCAG		4
19851	MI0005872	dme-mir-1011	Drosophila melanogaster miR-1011 stem-loop	GUGAGUUUUUGAGCCAGGAAUAUAGUUCUUAUUAUUGGUUCAAAUCGCUCGCAG		4
19852	MI0005873	dme-mir-1012	Drosophila melanogaster miR-1012 stem-loop	GUGGGUAGAACUUUGAUUAAUAUUGCUUGAAAAAUAUUAGUCAAAGAUUUUCCCCAUAG		4
19853	MI0005874	dme-mir-1013	Drosophila melanogaster miR-1013 stem-loop	GUGAGUUUCGUACACUUAAUUAAUAGGAUCGGCCGUUAAUAAAAGUAUGCCGAACUCGCAG		4
19854	MI0005875	dme-mir-1014	Drosophila melanogaster miR-1014 stem-loop	GUAUAAUGGAAAUAGAUUUUAAUCGCAGGCGCGUCAGUGGUUGAAUUAAAAUUCAUUUUCAUUUGCAG		4
19855	MI0005876	dme-mir-1015	Drosophila melanogaster miR-1015 stem-loop	GUGAGUGAUGCUCCAGUUAGCUUGGCUGAGUGAGGAUUUAAGUCCUGGGACAUCUCUCUUGCAG		4
19856	MI0005877	dme-mir-1016	Drosophila melanogaster miR-1016 stem-loop	GUAAGUAUAGAGAGGAUGUGAUUGGUAAAUUCCAAAGUUCACCUCUCUCCAUACUUAG		4
19857	MI0005878	dme-mir-1017	Drosophila melanogaster miR-1017 stem-loop	GUGAGUUUAGUGGAGUUUAAAGCUUCCCAUCGCCAGCAAUUACGCGAAAGCUCUACCCAAACUCAUCCCCCGAAAAUGAUCCCUUUCUCCCCUUUUCCCAACACAUUUGUAUCCCACUUCCUGCGCGUCUUCGUGGAUUUGUAACUGCUUCAAUGGCUGGACGGUUUAG		4
19858	MI0005879	cel-mir-1018	Caenorhabditis elegans miR-1018 stem-loop	GUAAGUUCAUGAUUUCUCCCAUAUAUUUUUCAUGAGAGAGAUCAUUGGACUUACAG		3
19859	MI0005880	cel-mir-1019	Caenorhabditis elegans miR-1019 stem-loop	GUGAGCAUUGUUCGAGUUUCAUUUUUAAUAAAAUUUAUUUAAAAACUGUAAUUCCACAUUGCUUUCCAG	The miR* sequence was erroneously named mir-803 in [2]. 	3
19860	MI0005881	cel-mir-1020	Caenorhabditis elegans miR-1020 stem-loop	GUAAGUGUUACAGAAUAAUCUUAGACAAAACAACUAAAAUUAAUGAAAAAUUAUUCUGUGACACUUUCAG		3
19861	MI0005882	mdv2-mir-M14	Mareks disease virus type 2 miR-M14 stem-loop	CGUUGUGUGGUACGGUGCACCCUGAGAGAUGAUCUAUAUUCUCAGGAAGUUCCGUGCCCGAAACG		56
19862	MI0005883	mdv2-mir-M15	Mareks disease virus type 2 miR-M15 stem-loop	UUGCGAUGGAAGGGAAAGGCAAACCGGAAAACUUAAGGCCGUUUGGUGUGUUUUUCCCUUCCAUCGCAG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19863	MI0005884	mdv2-mir-M16	Mareks disease virus type 2 miR-M16 stem-loop	GAAACGCAUCCAGUCUGUUUUGGCAUCUGAGUGGCGCGUAGCCGUUGUCAGAUGCCAGAGAGACUGAAAUGUUUC	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19864	MI0005885	mdv2-mir-M17	Mareks disease virus type 2 miR-M17 stem-loop	UCGUCCAGUCCUUCCCGGGUCCCCUAGAGGUGUCACGUUCUAGGACAACCGGGACGGACAGGGCGACGCGCGCGA	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19865	MI0005886	mdv2-mir-M18	Mareks disease virus type 2 miR-M18 stem-loop	GUAUGUUUUCUCUCAGGCUGGCAUUGCACGUGUCAUUGCCGUUGUGCAAUGCCUGCGGAGAGAAAGACGAAU	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19866	MI0005887	mdv2-mir-M19	Mareks disease virus type 2 miR-M19 stem-loop	CGUGUCCCCCCUCGGCGGUGUGCACGGGAGUAUCGGGCGCCGUCCUCAUGCCCCCCUCCGAGGGUAGCACG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19867	MI0005888	mdv2-mir-M20	Mareks disease virus type 2 miR-M20 stem-loop	UCCGUCCUUAGCGUGGUGCCUGAGAUUUUAACACGUAUCGUCUCAAGUACUGCGCGCAAGGACCGA	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19868	MI0005889	mdv2-mir-M21	Mareks disease virus type 2 miR-M21 stem-loop	CGCUUCCUCCUUCGCGGGGUGCUUGAGAUCACCGAAUGACGGGAUCGAGCACCACGCCGAUGGACGGAGAUGGCG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19869	MI0005890	mdv2-mir-M22	Mareks disease virus type 2 miR-M22 stem-loop	CUGGGCCGUCUUACACGCACGUCACUCUGGUCGUAUCGGUAGUCCUAGUGGCUUGCUUGUAGGCUGUCC	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19870	MI0005891	mdv2-mir-M23	Mareks disease virus type 2 miR-M23 stem-loop	UUCGGAUGGUCCGUGGUACGGUGUCCUGUGUUGUGUGAGAGGUCUCCGUACACCGGACCAUCGAA		56
19871	MI0005892	mdv2-mir-M24	Mareks disease virus type 2 miR-M24 stem-loop	CCAUUUUUUCCCUUACGGUGCCUGACGUCGUAUUUUAACGGUUAGAUGCCGUCAGGGAAAGAUGG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19872	MI0005893	mdv2-mir-M25	Mareks disease virus type 2 miR-M25 stem-loop	CGUGUCCUCCUUCGGACGAGUGCUUGCCGGGGAGUAACCGUCAUGCACUACUCCGGGGGUAGGACGCG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19873	MI0005894	mdv2-mir-M26	Mareks disease virus type 2 miR-M26 stem-loop	CCGUCCUUUGUGCUGUGUGUGAGAGGUCGUCAUCCCUUCUCGGGCACCGCACCGAAGGAUGG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19874	MI0005895	mdv2-mir-M27	Mareks disease virus type 2 miR-M27 stem-loop	UCCCUCCUUCGUCCGGUGUUCGAGGCGUGAGACUUUUGUAUUGCCGCGUCGAGCACCGUGCUGGAGGAAGGA	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19875	MI0005896	mdv2-mir-M28	Mareks disease virus type 2 miR-M28 stem-loop	UCGCGAUUUUCUCGACGCCUACCCUCGGCGUUGUUCGUCGGCCGAGGGUAGGCGCAGAGGAAAUCGCGG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19876	MI0005897	mdv2-mir-M29	Mareks disease virus type 2 miR-M29 stem-loop	UCUUCUUCACGUACCUCUCUAUGGCUGCAUCUUUAUGGCCAUAGUGAGGUACGUGUAGG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19877	MI0005898	mdv2-mir-M30	Mareks disease virus type 2 miR-M30 stem-loop	CACAACACUCCCUCGGACGCAGCAGUGUCUGGGCUUCUGCUGACGUGCGAGGGAGUGCUCGCCACGCGAG	The mature sequences shown here represent the longest cloned miRNAs from a distribution of lengths [1]. 	56
19878	MI0005899	cel-mir-1021	Caenorhabditis elegans miR-1021 stem-loop	UACUGUUUUGAAACAAGUGAGAUCAUGUGAAAUCCUCGGAGCUCGGAGCUUUGAAUUUUCCAAAUAUUCAUAUUUAAAUUAUUUGUUUCAAACAGUA		3
19879	MI0005900	cel-mir-1022	Caenorhabditis elegans miR-1022 stem-loop	GGUCCAAAAUCGGCAAGAUCAUUGUUAGGACGCCAUCUUGAAGCAAUAUAAAGAUGAUAGUCCAAUGAUGAUCCAGCUGUUCAAGGCU		3
19880	MI0005901	ppt-MIR160e	Physcomitrella patens miR160e stem-loop	CUGCAGAAAUCAAUGGGGGAAACUGGCACUGCCUGGCUCCCUGUAUGCCACUUGCGAAUUUUGGCAAAACUUGUGGCAGGGUACGUAGCUGCCAUACAGGGAGUCAGACAGACCUUGCAUCUUCCCGGAUUCUCAUGA		40
19881	MI0005902	ppt-MIR160f	Physcomitrella patens miR160f stem-loop	GUUCAUGGUUGAACGGUGGGGAGUUGGACUGCCUGGCUCCCUGUAUGCCACCUGCGGGGCUUGUCAAAAUGAUUGCCAGGCUGCAUAGCUGGCAUCCAGGGAGCCAGACAGACCUUUCUCUUGCCUCAUCCGGGUCCC		40
19882	MI0005903	ppt-MIR160g	Physcomitrella patens miR160g stem-loop	CUCAUGAAAUCAAUGGGGAAUAUUGGACCUGCCUGGCUCCUUGUAUGCCAUCUGCGAAGCUUGACAAAACUAUUGCCAGGGUACAUAGCUGCCAUGCAGGGAGUCAGACAGACCGUACGUCUUCCCAGAUUUACAUGC		40
19883	MI0005904	ppt-MIR160h	Physcomitrella patens miR160h stem-loop	UUAGUUCAGCAUGGGGAGAUAUCGGAUCCGCCUGGCUCCUUGUAUGCCAACUGAGAAGCUUGUUGAACAUUUUGCCAGGAUUCAUAGCUGGCACUCAGGGAGUCAAGCAGGCCAUUGGUCUUGCCAUGACUUUCAC		40
19884	MI0005905	ppt-MIR160i	Physcomitrella patens miR160i stem-loop	CGUUAGCACGGAAUAUGGGAUACUGGAUCCGCCUGGCUCCCUGUAUGCCACCUGCGAAGCAUGCUAAAGGUUUUUGCCAGGAUUUGCAGCUGGCGUUCAGGGAGUCAAGCAGGCCUCAAGUCUUCCCGUAACCAGCGCC		40
19885	MI0005906	ppt-MIR166c	Physcomitrella patens miR166c stem-loop	ACUUGGUGCAACAUGGGACUUUAUCGUGGGGAAUGCCGUCUGGACCGGAGCUGUGUGUCCACUCUGCAUCAAAGCUUCGGACCAGGCUUCAUUCCCCUCGAGGGAGUUUCAUAGCAGUGCUAU		40
19886	MI0005907	ppt-MIR166d	Physcomitrella patens miR166d stem-loop	CAUAUUAGUCAUAUGCGGCUUGUCCUUGGGGAAUGAUGAUUGGACCGAAGUUUUUUAGCGUUGGUUUGCCCAAUUAAAGCUUCGGACCAGGCUUCAUUCCCCUCGUAGAAGUUGCAUGAUGAUGCAAU		40
19887	MI0005908	ppt-MIR166e	Physcomitrella patens miR166e stem-loop	AAUGUGCUUUUGGAGUUGUGAACCUUGCUGUGAGGAAUGCCGCAUGGACCGAAGCUAUGUGCUCCAUCUUAACGUGGUGGUAUUGAUACUACGUUUCGGACCAGGCUUCAUUCCCCUCAGCGCAGUUUCAUCAUGGUGAUGGACGG		40
19888	MI0005909	ppt-MIR166f	Physcomitrella patens miR166f stem-loop	AUGACCAGCAUACCAGUGGUGCUGUGCUGGGAGGAAUGCUGCAUGGUCUGAUGCUUUUGCUGCGACACAAGCCUCGGACCAGGCUUCAUUCCCCUCAGCUCAGUCUCAUAUUGACGGUUCAAG		40
19889	MI0005910	ppt-MIR166g	Physcomitrella patens miR166g stem-loop	GUGCGGAGGUGUUUAGGUGAAACUCUGCUGCGAGGAAUGCCCCCUGGCCCGAAGGCAUGUACUUCUCCCUCUUCGAAUGGUGUGAGCAUCAAGCUUCGGACCAGGCUUCAUUCCCCUCAGCGCAGUUACAUUUCGAUAUUCACGUC		40
19890	MI0005911	ppt-MIR166h	Physcomitrella patens miR166h stem-loop	AGUUCGACAAGACUAUGAGACUUUGUCAUGAGGAAUGACGAGUGGCCCAGAUUCGUUUCUGGUCUAGAAAUUGAAUUUCGGACCAGGCUUCAUUCCCCUUGGCACGGUUCCAUGGAGGUACUGUCA		40
19891	MI0005912	ppt-MIR166i	Physcomitrella patens miR166i stem-loop	CUUGGAGAUUGGAUGGGACUUUGUCGUGGGGAUUGACGCAUGGCACGAAGCUAACAUCCUGAGAUCAGUUGCUUCGGACCAGGCUUCAUUCCCCUUGCCUAAGUUGCAUCAUGUAGUGCU		40
19892	MI0005913	ppt-MIR166j	Physcomitrella patens miR166j stem-loop	GAAGAUGUUAUAUAUAUGUGACAUUGCCGUGAGGAAUGACGUGUGGCCCGAAGCCAUAUCUUGGGUUGCCUUGAUGAAGCUCCGGACCAGGCUUCAUUCCCCUCGGCAGAGUUGCAACAAGUGGGAAAGGG		40
19893	MI0005914	ppt-MIR166k	Physcomitrella patens miR166k stem-loop	GAAGAUGCUGGAUGUGCCUUUGCCGUGAGGAAUGACGUAUGGCCCGAAGCUAUCUCUUGGAUGGCCUUGAUGAAGCUCCGGACCAGGCUUCAUUCCCCUCGGCGGAGUUGCAAAUGUGGACAC		40
19894	MI0005915	ppt-MIR166l	Physcomitrella patens miR166l stem-loop	AAUUUGUGAAGCUGAAUGAAACGUUUUCGUGGGGAAUGACGUGUGGCCCGUAGCCAUGUAUCUUGGCAUGCCAGAAUUAUGCUCCGGACCAGGCUUCAUUCCCCUCGGCAACGUUGCAUGAUGGUAAUUAUGU		40
19895	MI0005916	ppt-MIR166m	Physcomitrella patens miR166m stem-loop	GCCGAGAACAGAGAUUGUGUAGCUCAGCUGUAAGGAAUGUGGCAUGGCUCGAUGCUGUUUGAGCAUGUCAAGUUCAGCCUCGGACCAGGCAUCAUUCCUUUCAUCUCAGUUACACAUUUGACAUCCAGGA		40
19896	MI0005917	ppt-MIR408b	Physcomitrella patens miR408b stem-loop	GUGGAAGAGAGAGAGUGGUGGAAGGGAGGGAAGCCAGCGUGAGGCAAUGCAUGACAACAGCAUGCCCAGGAGGUCCUGAGGGUGUUGUCCUCAUGCACUGCCUCUUCCCUGGCUUCCCUACAUAGCUCGCCAUUCUUGUGCUCU		40
19897	MI0005918	ppt-MIR477d	Physcomitrella patens miR477d stem-loop	GUUGAUUUCGAUUAAACAGAUUGCUUGUUCCUCUCCCUCAAAGGCUUCCAACAACAGGUACUUGGUCUUGUUUUCACCAGCAAAGCUAAGGCCCGUCCCAGAUGUUAGAAGCCUCUGGGGGUGACGAAGCAGCAGCUGUAUGGGUGGUUCCCAU		40
19898	MI0005919	ppt-MIR477e	Physcomitrella patens miR477e stem-loop	GAUGAGAAGAUUCCGAAAGGCGGUUGCUUAUCUCUCUCCCUCAAAGGCUUCCAACAUCAGGUGUAGAAGCCUUGCUAGAAGCCUUUGUGGGAGAGGGGGAAACAAACGCCUUGCAUUAUUGCCGUUC		40
19899	MI0005920	ppt-MIR477h	Physcomitrella patens miR477h stem-loop	UCAGAGGGAGUAUACUCAGGUGUUUGUUUUUCUCCCUCAAAGGCUUCCAACUACAUCAGCAUUCUAUUCCACUUCUGGCUUAAGAUGCAGUGAAUUUGCGUUGUUGUUGGAUGCCUUAGUGGGAGAUGUACAUACCCCUGUCAUUGAUGUGUUGC		40
19900	MI0005921	ppt-MIR529a	Physcomitrella patens miR529a stem-loop	CUCCCCUUUUCUACAUUCAAGCCGGGUUUCGAAGAGAGAGAGCACAGCCCUGGACUUUUCUCAUGUGACCGAUUUUAGCGGUACAUGGUGCACUGUCAUCGGGCUGUUCUCUCUCUCUUCUAGACCCUACUUGGAUGUGUUUCUACUGC		40
19901	MI0005922	ppt-MIR529b	Physcomitrella patens miR529b stem-loop	UUCAGCCGUACUACACCCAAGCCGGGAUUCGAAGAGAGAGAGCACAGCCCGUAACUUUCACUAAAGACCACUUAUUGUGGUUCAUUGGAGAUUUGAUGUCGGGCUGUGCUCUCUCUUUUCCAGUCCCUACUCGGAUGUGUCGCCAUCAC		40
19902	MI0005923	ppt-MIR529c	Physcomitrella patens miR529c stem-loop	UUCAGCUUUACUACAUCCAAGCCAGGAUUCGAAGAGAGAGAGCACAGCCCCGUUACUUUUGCUGAAAGAAUACUUCCUGUGAUCCAUUGGGAAUUUGAUGUUGGGCUGUGCUCUCUCUUUUCCAGUCCCUACCUGGAUGUGCUGCCAUUGC		40
19903	MI0005924	ppt-MIR529d	Physcomitrella patens miR529d stem-loop	CUAGCUUCUCCACAAUUUCUCACCCUCGUUGGGAUCAGAAGAGAGAGAGCACAGCCCGAUGUCCAAUGUUCAGGUCGAAUGGGCUGUGCUCUCUCUCUUCUUGCUCCAACUUGGGUGCUACACGCAUCUAGGGUAC		40
19904	MI0005925	ppt-MIR529e	Physcomitrella patens miR529e stem-loop	UCAGCAAUUUACUCACUCAUGCUGGGAUCAGAAGAGAGAGAGUACAGCCCAAGAGCAACCGCUUAGUUGGAAUGGGCUGUGCUCUCUCUCUUCUGGUUCCAACCUGAGUGCAUGUCGGUUGU		40
19905	MI0005926	ppt-MIR529f	Physcomitrella patens miR529f stem-loop	UGCACAAUUUUCUCACUCAUGCUGGGAUCAGAAGAGAGAGAGUACAGCCCAACGGCCGAUGUUCAGUUGGAACGGGCUGUGCUCUCUCUCUUCUUGUUCCAACCUGGGUGCAUUUCCGUUCU		40
19906	MI0005927	ppt-MIR529g	Physcomitrella patens miR529g stem-loop	UCACCUUUUUCUACAUUCAAGCUGGGGUUCGAAGAGAGAGAGCACAGUCCCAGACUUUUCACUCACGACCACUUUGAGUGUCUUAUGGUGAACAGUAGUCGGGCUGUACUCUCUCUUUUCCAGUCCCUACUCGAAUGUGUUUCUAUCGC		40
19907	MI0005928	ppt-MIR533c	Physcomitrella patens miR533c stem-loop	AGUGUUUGAAAGAGGGUUAGCGACAUUGAGAGCUGUUCAGACUAUGAGAAAGUGUGUGGAAGAGGAUUUGGUGACUUGAACUGGUGCUUCAAGGAAAGCCUAAAGUCCAAGUUCCACUCUUGCUCUCACAGUCUGCACAGCUCUCUGUAUCUCUUCCCCUAGUAUAUGUCU		40
19908	MI0005929	ppt-MIR533d	Physcomitrella patens miR533d stem-loop	CAGCAUCAGCUCAGGGGCAGUAGCAUGGAGAGCUGUUCAGACUCUGAGAGAGGGGUGUGGAAAACAUGUACUGUUGUAUCGACACUCGUCGCUCACAGUCUGCACAGCUCUCUGUGUUGCUCCCUCUAAUUGACUUCA		40
19909	MI0005930	ppt-MIR533e	Physcomitrella patens miR533e stem-loop	GAGUGGUUGUGCAUGACGAGGCAGCGACAGAGAGAGCUGGCCAGACUGUGAGGGAUGGAGCGAAUUUAGCUUGUGCCUUGUGUGGCUCACUCGUGCAGCUCCCUCACAGUCUGCAUGGCUCUCCGUGUCUCUUCCUCUUUUCGGCCACGUUGG		40
19910	MI0005932	ppt-MIR536d	Physcomitrella patens miR536d stem-loop	AGGGUGCAUUCCAAGUGCCGUCCCUUGGAAGCCGCAGUUUGGCACGAAGCCCUUUCUCCUGCCGCUACUGUUUUGUUAGUCAGGUUUGCAGCGUGUCUCGAUAUAGUGGUGUGCUUCCGUUGCUAUCCUUUCCCUCCAGGUAGGAAUUCUGUGGCAAACUAGUGGUUGGUUCGCUUAUCAAGUUGCAGUCCUUCAUACCUUGAUUUUGAAUUACUGCAGUCACACCCUUCUUGUCGGCAGUUUUUUUUUUUUUUGUGUGUCCUACCGACUGCACUGACUGCAGAAAGUCGAAGCAAUGGAGGUGUCGUUGCAUUUUCCUCAUAGUUUUGCUAGCUUCUACUUCUGGGUUGAUGUUGAACCCACUCCACCCACUUGUAGCGGAAAGAUGUUAGAAUUUCGUGCCAAGCUGUGUGCAACCAAGGGGUUUGUUACUUCAAAUCCAC		40
19911	MI0005933	ppt-MIR536e	Physcomitrella patens miR536e stem-loop	UGUGUGGAUCCUAAGUGUCUCCCCUUGGAAGCCGCAGUUUGGCAUGAAGCACUUAUUCCUUUGCGCAUCCAUUUUGUGACUGCUUGUAUUGAGUCGAAUCCAAUUCCUUGCCUUCUACUUCCUUCCAAUCUAGAUCACUCCUGGUUUUUCACAUUGUUUGGUUGUUGGGGGUCAUAUUGUUUGUAUACCUUUUUUCGCACGAAAUCUUCAAUUUGAAAGACGCUGUUGGAAACUCUAAUUUCGAAUUUCUGCAGCCACACCCAAUAGUUUGAGGUCUUGUCGGUAUCUUCCUUUGCGCGCCUACUUCAGUGACUGCAGAAAGUCACUGCAGUCACUACCGGGGACGAACAUACUAGCACUGUUAAUCUCACUAUACUCGUCAAUCUUCAGUUGUCCAUGCACGAUUUCUCCCUAAAAUUAUUGAGGGGAUAUCAGAGUUUCGUGCCAAGCUGUGUGCAACCAAG		40
19912	MI0005934	ppt-MIR536f	Physcomitrella patens miR536f stem-loop	UUCGACGUCGUGUUAAGUGUGAUUCCUUAGCAGCCAUAGUUUGGUAUGAAGCUCUCUCUGAACAUCAGAUAUCGGUCGGUAGAGUUGAGGUUUGUUCACAUGACCUUAGCUCUGUUUUCCGAGCGCUUCGUGCCAAGCUGUGUGCAUCUAAGGGAAUCUCACUUCUGAACAGAAAG		40
19913	MI0005935	ppt-MIR537c	Physcomitrella patens miR537c stem-loop	UCAUAUCUGGACUGUAGAAACACCUGAAGUGACUGAAGUUAGUCCGGUUUAGGUAUGAGAAUGAUUGGAGCACCUCUCCAGAUGUUCCAGAUGUAAUGAAACCGGUGCAAGCUUCAAGCUCUUGAGGUGUUUCUACAGGCUACAUAUGA		40
19914	MI0005936	ppt-MIR537d	Physcomitrella patens miR537d stem-loop	UUGAACAAUGUCAUUAUCAUACAUAGACUGUAGAAACACCUGAAGCUAUUGAUCUCUACUUUGUUGUAACCGAUCUUUAUGGAAAGUGCACGAAAAUGUGUAUGCUGUGAUCGCACGAUUGGUGACAUCAGUAACUUGAGGUGUUUCUACAGGCUACUUAUGCUUGAUGAUUAUCUUA		40
19915	MI0005937	ppt-MIR902c	Physcomitrella patens miR902c stem-loop	UCUAUUGGCGUAUGCUCAUUUCCUCCUUCUAGCGUAUGAUGCAGAUUCUUCAUCUGUUGAACUGAAUUUUUCUUAGUGAUGCAGACGAAGGUCUGCAUCAUAGUCAAGGGGGAGGAAAUAUAUAUCAUGAUUCU		40
19916	MI0005938	ppt-MIR902d	Physcomitrella patens miR902d stem-loop	AAGGAUCCUCCCAUUUGCGCCCACUGGGUUAUGAUGCAGAUUCUUCAUCUACUUCACUGGAGCUUCCACAAGUGGUGCACCAGAUGAAGGUCUGCAUCGUAGCCGAGAGGAAGCAAAUUCUUCUGGACC		40
19917	MI0005939	ppt-MIR902e	Physcomitrella patens miR902e stem-loop	GACAGCGUGCCGUCUCAUUUCCUUCCGCUAGUCUAUGAUGCAGAUUCUUCAUCUGUUUCGUGUGAUGCUUGUGCACGAGUCAGACGAAGGUCUGCAUCAUAGUCAAGAGGAAGCAAAUAUGAAAUUCAGGAGC		40
19918	MI0005940	ppt-MIR902f	Physcomitrella patens miR902f stem-loop	GAGAGAAUGCUCUUUUGCCUUCGCUAAGAUAUGAUGCAGAUUCUUCAUCUGCGGGAUAUUCUUGCGUGGUAUAACAGACGAAGAUCUGCAUCAUAACCAAGCGGGAGUAAACAUUGUGCUACC		40
19919	MI0005941	ppt-MIR902g	Physcomitrella patens miR902g stem-loop	GGUAGCAGGUUUGUUCAUUUUCUUCCGCUAGUCUAUGAUGCAGAUUCUUCAUCUGUUUAGCUGAAUCUGCGUCAGUGUUUCAGUGUUACAGACGAAGGUCUGCAUCAUAGUCAAGAGGAAUGAAAAUACAUUAUAGAUUAU		40
19920	MI0005942	ppt-MIR902h	Physcomitrella patens miR902h stem-loop	CCUGCACAACCCACAAAAUCGUGUUGAUCUAGAUUAUGAUGUAGAUUCUUCAUCUGGAAUUGAAUUUCGAUUUAAGAAGAAGGGUCUACAUCAUAAACUGGAUGAUUACGAUUGUUGGAUAACAGCAG		40
19921	MI0005943	ppt-MIR902i	Physcomitrella patens miR902i stem-loop	GACAACCUGCAGAGUUGUGUUGAUCUGGAUUAUGAUGUAGAUUCUUCAUCUAUGAGUGAAGCUCAAUCAAAGAUGGAGGAUCUGCAUCGUAAACUGGAUUAUCACGACUAUCGAACAACG		40
19922	MI0005944	ppt-MIR902j	Physcomitrella patens miR902j stem-loop	GCGGGUUAAAGUUGAACAGGUUGCCUCUCUCGUAUAUGUUGCAGAUUCUUCAUUUGUCUAGCUGAUCAACUAUAGUAUUGAUUUGUCUAGCUGAUCAACUAUAGUAUUGACUGUCAUGCAAAAGAAGGAUCUGCAACAUAGACAAGAAUAGGUGAUCGAUUUUUAUACACUCA		40
19923	MI0005945	ppt-MIR902k	Physcomitrella patens miR902k stem-loop	GUUGAUUUUGCUGCAUAGAUUAUCUUUCUAUUCUAUGUUGCAGAUUCUUCAUUUGCCGCUCUGCUGAAUGAUCAUAUUGCGGGUGAAGCAAACGAAGGAUCUGCAAUAUAAACCAGAAAAGGUAAUCGUAUUUUGGCCAAUA		40
19924	MI0005946	ppt-MIR902l	Physcomitrella patens miR902l stem-loop	AUUAGCAACUGCUGCACUGGUUAUCUCUCUCGUCUAUGUUGCAGAUUCUUCAUUUGCAAAACUGAUCAUAGAAGUUAAGUGAAAGAAGGAUCUGCAACAUAUACAAGAACGGAUAAUCGGAUGUGAUGAUGAGC		40
19925	MI0005947	ppt-MIR1222b	Physcomitrella patens miR1222b stem-loop	GUGCGUCGAUGCAACUGCUCUAAUCAUUUUCGUACCAGUGUAUUCCUUCAAACCUCUUCUCUUGACUGUAGUGGUGGCCUGAAGGAGUUCAUUGGUACACAAAUCUUGAGAGCAUGGAGGAAAAUAGA		40
19926	MI0005948	ppt-MIR1222c	Physcomitrella patens miR1222c stem-loop	CGAGCGUGAAAAAACUUGCUACAAUCAUUUUCGUACCAGUGCGUUCCUCCAAACCACCACGCUCACGUUGAUGCGAAGUUGGUCUGAAGGAGUUCAUUGGUACACAAAUCAUAAGAGCAUGGAGGACCGGAGAA		40
19927	MI0005949	ppt-MIR1222d	Physcomitrella patens miR1222d stem-loop	CUGAUGUUGUUAUUAUUGUUACGGGCAUUCGUGUGCUGGUGAACUCCUUCAUGCACAAGUGCGGCUCUUCGCGCACCAGCUUUAAGGGGUUCACUGGUAUAUGAAUGCACAUGGCAUGAUCUGAUCACGGG		40
19928	MI0005950	ppt-MIR1222e	Physcomitrella patens miR1222e stem-loop	AGUUGAAUGUGUGCGGUUGUGGGGAUAUUGACGUGCUGGUGAGCUCCUUCAAGCUCGAGUGUGCGUCUUGCCACGGCCUUGAAGGAGUUCAGUGGUACAUCAAUGUCCAUGGCAUACUCAAGGCGGGAC		40
19929	MI0005951	ppt-MIR1223b	Physcomitrella patens miR1223b stem-loop	UUAUAACAACUCUCCAAGGCUGGAUGUCCAGCAAGGGUGUGUGGCUCUAUAAUCUAGAGCUAAAGCUAGAAAUCCACUGCUGUUGCGAUCGAUUGUAGAGUCAUACACCUCUACUGGCCUUCCAGUCUGUUUGCUCACAGCUU		40
19930	MI0005952	ppt-MIR1223c	Physcomitrella patens miR1223c stem-loop	AGGUUCACUCUAUUCAAGGUUGGAUUGUCAGCAAAGGUGUGCGACUCUAUAAUCCAAAGCUUGUGGGAGGAAUUCACCUCGCCUGUGACCGAUUGUAGAGUCAUACACCUCUACUGACCUUCCAGUCUCUUUGCUCACAGCUU		40
19931	MI0005953	ppt-MIR1223d	Physcomitrella patens miR1223d stem-loop	GCGGCGAUGGAUACUAGACUCGAGGUCGAACAAGGGUGUGUGACCCUACAAUCCGAAACGCGAGACUUAAUGCUUCGCCUGCGAUUGUAGAGUCAUACACCUCUGCUAGCCUUCCGGUCUUCCGCUCUAAGCUA		40
19932	MI0005954	ppt-MIR1223e	Physcomitrella patens miR1223e stem-loop	UGACCAUGACAAGCAAUGGAGCUUCGACAAGGGUGUUUGACUCUACUACCCGUGAACCCCAUCAGAUGGAGAUAUGUGGUUGUAGAGUCAUGCACCUCUGCCGAGGCUCCUGCUUUUUACUCCUUU		40
19933	MI0005955	ppt-MIR1223f	Physcomitrella patens miR1223f stem-loop	CGCAAUGAAAUGGAACAGCAUGGAGCUUCAGCAAGGGUGCUUGACUUUAUAACCCGGCUUAAAUUAAUCGUGGUUGUAGAGUCAUGCACCUCUGCUGGCUCUCCUGCUUGGACAUUAUACUUGU		40
19934	MI0005956	ppt-MIR1223g	Physcomitrella patens miR1223g stem-loop	AGUGUAUUGAUCAGCGUGGAGCUUCAGCAUGGGUGUUUGACCUUACAACUCGGCAUUGAUCAAUCGUGGUUGUAGAGUCAUGCACCUCUGCCGACUCUCCGGCUCUGUGUACUGCU		40
19935	MI0005957	ppt-MIR1223h	Physcomitrella patens miR1223h stem-loop	GAGUGAGUGGGUCAGCAGCAUGGAGGUUCGACAAGGGUGCUUGGCCCUACUACCCGUGAACCCACCCAAGGAGAGACGUGGUUGUAGAGUCACGCACCUCUGCCGAGCCUCCUGCUCGUUGUGCUUCUUCUU		40
19936	MI0005958	ppt-MIR1223i	Physcomitrella patens miR1223i stem-loop	CAAGCCUCGUUCAGCAGGGUGCUUCAGCAAGGGUGCUUGAUUCUACUACCCGUCGACCCAUUAGAGGAGCGACGCGGUUGUAGAGUCACGCACCUCUGUUGAGCACCCUGCUCGGAGUAAAGAU		40
19937	MI0005959	ppt-MIR1223j	Physcomitrella patens miR1223j stem-loop	CCCUUCAACACAAGGCUGAAGGGUCAGCAAGGGUGUGUGACUCUACUAUCUGAACUGUGCGAUUUGAUUGCCUCGUAAUGAGGCGUACAUAAAGCUUUUGAUUGUAGAGUCAUGCACCUCUACUGGGCCUUCAGUCUAAUUUUUCUGC		40
19938	MI0005960	ppt-MIR1023a	Physcomitrella patens miR1023a stem-loop	GGGAGCGAUUGGACCACCUUGCAGUUUCAUGGCACACUCUCUCCAUUUCUCUACCGUUCAUGCAGCGGUUGAUCGAUUGGGUUGCUGGUUGAUUGAUCGAUCGAUGGUCAGGAGUUGGAAGAGAAUUGGAGAGAGUGCAUUGUGAAUUGCGGGGUUGACGAGGCGGAGGG		40
19939	MI0005961	ppt-MIR1023b	Physcomitrella patens miR1023b stem-loop	GAAGCGCGGCGGGCCAGCUUGCAAUUUCAUGACACACUCUCUCCAUUUCUCUGCCUGUCAUGACUUGGUUGAUCGAUGGAGCGGUGGUUUUCAUUGCCCGAUUGAGGAUCAGGAGUUGGGGAGAGAAUUGAAGAGAGUGCAUUGUGAAUUGCAAGCUCCUCCUUUCUUUUCG		40
19940	MI0005962	ppt-MIR1023c	Physcomitrella patens miR1023c stem-loop	GCGCAGUUACACAGCUUGCAUUUCGGUGUCCACUCUCUCCGUUUCCCUUCCCAUGAUGGCUAGCCUUGAGUAAGUACAUAUGUUUUGAACACAUGUAUGCUUGCUUAAAAUCCUUUGUCGGAGGGAAUCGGAAAGAGUGUACAAUGAAUUGCAAGCUUGAUUGAUUCG		40
19941	MI0005963	ppt-MIR1023d	Physcomitrella patens miR1023d stem-loop	UGUAGAAGAUGCAGCUUGCAGAUUAUCAUCCACUCUCUCCGUUUCCCUUCCCACAGCUAUCAUCCGGACUAGCAUUUCCUGUACAUACUAGGGAAGGGAAAUGGAGAGAGUGUAUAAUGAAUUGCAUGCUUGAUUGCUGAG		40
19942	MI0005964	ppt-MIR1024a	Physcomitrella patens miR1024a stem-loop	GGACGAGAUCGCGGCCGUCAUGAGUUUUGUCGACGCCCUGCAAUUCAAGCAGACUCGAUUACAAUGUUUGCCGCCGACGUCACGCAUGUCACGUGGUUAUUUGUACUUCAGUCUGGUUGGAUUGUAGGCCUCCGCAAGGCUUCAUGACUCACUCAACUGCUG		40
19943	MI0005965	ppt-MIR1024b	Physcomitrella patens miR1024b stem-loop	GUAGACGCCUUGCAAUUCAAGCAGACUCUAUUAUGCGGCUGCCGCGGACACUACGUGGUUUGUUGUGCUUCAGUCUGGUUGGAUUGUAGGCCUCCGCAAAACUUCAUGACCAUCGCAACUACUG		40
19944	MI0005966	ppt-MIR1025	Physcomitrella patens miR1025 stem-loop	GUUCCGGUGCAAGGUCGUGUUGAGGAGUCGUGUUUUUAGUUUUGUUGUGGGCUGUAAGGGUGGCUGCGGGAGAAAUUAUUAUCAUUCUGCGGGAUGUCCUCUACCCACUCCGCCUUCCCUGUCUGUUGUCGAGUGGGGGUCUCGCCUGCUCCUUCCUUCUGCCACAACAAAGCUAAUAACUCGACUCAUCCUGACACCACGUCUCUGGCU		40
19945	MI0005967	ppt-MIR1026a	Physcomitrella patens miR1026a stem-loop	AUGAAAGUUCUUGAGACACUCUCUAGGUCUGAGAAAGACUUGAGAGGACACUCCUACAAUAGCCUCGGGAACUGCAUGACGUUUUUCAUUAGAUGAGGUGGUUCCCUGAGCAUUUGCAGGACAGUUCUUUCAAGCCUUCCUCGGACUUUGGAUUGUUUGUUCCAUAUCAUG		40
19946	MI0005968	ppt-MIR1026b	Physcomitrella patens miR1026b stem-loop	CAGGAACAUAAUUGAGACUCUCUGAACUCUGAGAAAGACUUGAGAGGACACUCCUGCAACAACUGUGGCAAUUCCAUGCAGUUAUAGCAGCAUCUGCAGCGGCGGUUCUCUCUAGUCUUUCUUGGACUUUGGAUGGCUUCUUCUGCAACAUC		40
19947	MI0005969	ppt-MIR1027a	Physcomitrella patens miR1027a stem-loop	GUGCAAGAGCAGAUACUUAAGUCGAAGAGCAUCUUUCUAUCUUCUCUUCCAAUCUAUUGAUCUGCCCUUCCAAUACUAUCAGAUCAAUAGAUUGGAAGAGCAGAUCGAAAAAUGCUCUCACCUUAAGGAGAGACAGCGACUC		40
19948	MI0005970	ppt-MIR1027b	Physcomitrella patens miR1027b stem-loop	GUGCAAGAGCAGAUACUUAAGUCGAAGAGCAUCUUUCUAUCUUCUCUUCCAAUCUAUUGAUCUGCCCUUCCAAUACUAUCAGAUCAAUAGAUUGGAAGAGCAGAUCGAAAAAUGCUCUCACCUUAAGGAGAGACAGCGACUC		40
19949	MI0005971	ppt-MIR1028a	Physcomitrella patens miR1028a stem-loop	ACCCGAUUUACCUUCACAUCUGUUCCAGCUCUUAGAUCUACAAUGUCACAUGAACACAUACUUGGUAACGAAUCUGGCAGUAAGACUUCAUUUAUAUGGGUCCAUUCCGCUCCAAGCUUUCACAUCUGUGACAGAUUUAGCAAUAUAGUGAAAAUCUGACCGUUGGUGAUGCAACUGAAGCAAGUUUUCACGUGACAUUGUAGAUCUACGUGCCGGAUUAGUGGUGAAAGCCUCAAGUU		40
19950	MI0005972	ppt-MIR1028b	Physcomitrella patens miR1028b stem-loop	CAAACAAGCAAAUCCAUUCUUGGACUAGUUCUUAGAUCUACAAUGCCACCUACAACAGCAAUACUUAAGGUUAUGAGAAGAUAUCUAUCAUGCUCUCUGGAGUGUGGUCCUCUUCUUACAAUCUUAAAUUUUAAAUUUCUUGAAAGGCGGCAUUGUGGACCUAAGACCUUGGUCAAGUGUGGAAUAAGGCUAAA		40
19951	MI0005973	ppt-MIR1028c	Physcomitrella patens miR1028c stem-loop	CGAAGACAUGGAAGAUUUCAUCCGCGACCUUGCUCUUAGAUCUACAAUGCCUCUUGCGAAACUGACAGCGGAAUACCGGACUUUUAUUUGAUCAUGAUGGAAUCCACAUGUGCCUCAUACUUCAGGAAUCCAUGCGGUCCACCAUGUGGCAUUGUAGGUUUAAGAGCUGUGCCGCGGGUGGAUUGAUGAUCACCUGU		40
19952	MI0005974	ppt-MIR1029	Physcomitrella patens miR1029 stem-loop	GCACACAAUGUGCACACGUUACAUCACUAUCAGUAUUUUUGGUUUGAGAGAAAGGAGGACAGGAGGCUACGAGAUUUGUUUGUGUUUGAUUCUUGGGCGAACUCCUCUCUCUCAACCAACCAUACUGAUACUAAUUGACGUUCGAAGUUUGUGCUU		40
19953	MI0005975	ppt-MIR1030a	Physcomitrella patens miR1030a stem-loop	AAGGUACGCAAUUAAAGCUGCACCGUCACAUUUCUGCAUCUGCACCUGCACCAAAACGCGACUUUGAGGUUGUGAUGGAAUUCUGCAGUCACACCCAGCCAUUUGCAAGAGUGUUCUGCCGGUGUUGGAUUGUGGCAAUGGAUUGCAUUCACAGGCUUGUGUACUGGUGCAGUGCUUAUGCAGAAAUGUUGCGUUGUAGCUCAAACUGGAUUGAG		40
19954	MI0005976	ppt-MIR1030b	Physcomitrella patens miR1030b stem-loop	UGUCAUGCAUCUGCAUCUGCACCUGCACCACAAUGUGAUCGCGGCGAUCUCUGUUCCGGAGGUUCAGCCCGGUAGUUUUACAUGCGGCCCUGCAUUCAGCGCUGGCAUCUUCCGUGGACAAGUUUCGUAGCUCACAUUCCGAUGGUGCAGUGCUUAUGCAGAAGCGUUGC		40
19955	MI0005977	ppt-MIR1030c	Physcomitrella patens miR1030c stem-loop	UACUCCUUGCUCUGCUGCAUCGUAAUGCAUCUGCAUCUGCACCUGCACCACGUUGUGAUAGGAACAAAACUCUGUCUUGCUGAUUCCCUGCACACAUGCCUUUGUUACCCAGCAUUCUCGAAUACGGCGUCGGUGCUAUCCUCAGAUAAGUAGAGUUGUCCUCACUAGGUUGGUGAGGUGCAUAUGCAGAGGCGUUACAUUGCAGCUGCUUAAUAUUG		40
19956	MI0005978	ppt-MIR1030d	Physcomitrella patens miR1030d stem-loop	AGUCCUCCGCUCUGCUGCAAUGUAAUGUGUCUGCAUCUGCACCUGCACCACGGUGUAACAGUGGCGACGCUUUUUCUUGCGGAUAUCAGGCACUCAUGCCGUUGCUUCCCUGCAUUUUCCAAUGUGGCGUUGGUGCAAUCCGCAGACAAUCAGUGUCUCUCACAUUACGAUGGUGAGAUGCAGAUGCAGAGGUGUUACAUUGCAACUGACCCUCAAUU		40
19957	MI0005979	ppt-MIR1030e	Physcomitrella patens miR1030e stem-loop	GAAAAUCCUUGAAGCUGCAACGCUACUUUUCUGCAUCUGCACCUGCACCAAGAUGCGAUAACAUGUACAGAUGAACCAAAUACACAGUUGUACUGUCAUGCCCAGUUAGCCACUGGACUUGAUUUGUUGAACAAUUAUUUGUACUCGCUUUAUCGCGUACUGGUGCAGUGCCUAUGCAGACAUGUAGUGUUGUAGCUGGAUGCAGAUC		40
19958	MI0005980	ppt-MIR1030f	Physcomitrella patens miR1030f stem-loop	CCUCUACAUAACUACUCCAAUGCCACGUAUCUGCAUCUGCACCUGCACCAAAGUUUUGUAAUUCUACGGCUCGUGGUAGUCUGUUGUUGUGAAGGUGGGAUGUAGCUGAGUGUAUUACUCGGUGUUCAUUUGAUCAUUAUUACCCGAUGGUGCGGGUUCUUAUGCAGAGCCGUGGCAUUGGAGUAAUCCUCUACUU		40
19959	MI0005981	ppt-MIR1030g	Physcomitrella patens miR1030g stem-loop	CCCCUGCAUUACUGCUUCAAUGCCACGUAUCUGCAUCUGCACCUGCACCAAAGUUUCGAAAUGCUAAGCUCUAAUGUGAAUGAUGACACUUUUUUUGUACCCAAAGUGGGCAUGAAGCUGUGUGUUCUGCUUGGUGAUCGUUUCACAGUUACGACUCGAUGGUGCGGGUUCUUAUGCAGAACCGUGGCAUUGGAGCAAUCCCUUUUAA		40
19960	MI0005982	ppt-MIR1030h	Physcomitrella patens miR1030h stem-loop	GCUACGUUACCUAUCUGCAUCUGCACCUGCACCGAGAUUCGAAGAGUAAUGAAGAAUCAUAUACGCAGUUGCAGUCAUUUCCAGUUCAUCACUGGACCUGACAAAUUGAAGCAAUGAUGCAAUUCUCAUUCUCGCUUAUCGGUGCAGUGCUUAUGCAGAUAUGUGGCGUUG		40
19961	MI0005983	ppt-MIR1030i	Physcomitrella patens miR1030i stem-loop	AAUUCUCCUCUUCAUCGCUGUAAUGCCAUGUUCCUGCAUCUGCACCUGCACCGCACUGCCUCACGAGAAUGUGCACGAAUGGAUCAGAGCGGUGUUGUGCAAAUCCUGCUUUCAGUCAAUCACUGAGCUUGAGUUUUAGCAAUUCUUAUUUCCUCUGAACUUUCUUCUGGCAUUAUAGUGGUGGAGGUGCUUAUGCAGAAAUAUUGCAUUGCGGCUGAGAGCCACUAAUG		40
19962	MI0005984	ppt-MIR1030j	Physcomitrella patens miR1030j stem-loop	AGCCUCCUCUUCAGCGCUGUAAUGCCAUGUUCCUGCAUCUGCACCUGCACCACACUUCUACGAGAGAAUGUGCAGAAGUCAGAGCGGUGUUGUGCGAAUCCUGCUCUCAGUCAAUUGCUGGGAUUGCGUUUCUCCAAUCUUCUUUCUCUGGGCUUUUCUCUGGCAUUGUGGUGGUGUAGGUGCUUAUGCAGAAAUAUUGCCUUGCAGCUUGCAGUUACUAGU		40
19963	MI0005985	ppt-MIR1031a	Physcomitrella patens miR1031a stem-loop	ACUGCGAAAUUUCUGGAUCAUAAAUUUGCUCAAUGCUCUCUGGAGCUUCUGUGUUACCACGUUGGAGAGAGUGUUGAUUUGGACUCCCUGAUAGGGCUUAGGCAUCUUUCAGCCCUUGCUUCGGGUUUUCGUCCUUAUUGGCCUCCCUCAUUGGGCCUCAGAAGCUUCACAGAACAUUGACUUGAUUUGUGACCCUGUGAUGAGGAAG		40
19964	MI0005986	ppt-MIR1031b	Physcomitrella patens miR1031b stem-loop	ACGGCGGAAGUUCUGGAUCACAAAUUUGCUCAAUGCUCUCUGGAGCUUCUGUGCCGUUGCUUUGGGGAGUGUGGGUUUGUCCCCCUGGACAGGUCUGCAGAACCUGACGGCCUUGGCCCUGAUCUGCAUCCCUCUCUUAAUUGAACCUCAGAAGCUUCAUAGGACAUUGACUUGAUUUGUGACCCUGUGAUGAAGAAA		40
19965	MI0005987	ppt-MIR1032	Physcomitrella patens miR1032 stem-loop	ACUAGCAAGAGCCAUGCCUCUGCCCAGGCAGGUGACUGCCUGGAAUUGGGCAUAAAUGCCCAAUUGGACUCCCAAGUGCCCAAUUCCAGGCAAGCCCCUGUCUGGGCAGGAGCAUGAUUUCUUCCAG		40
19966	MI0005988	ppt-MIR1033a	Physcomitrella patens miR1033a stem-loop	UGAUCAGAUACAAUCCGGCGGUGGCAUUGGGAAUGUCCAUCACAACCUGCCAACAUUCCAGGUUAUGUUGACGGGUCGUGAUGGGCACUCUCAGCGUCUCAUGUCACAAAAACGCAGAC		40
19967	MI0005989	ppt-MIR1033b	Physcomitrella patens miR1033b stem-loop	GUGACCAAGAUGGAGAUGAUGGGAUGUUGGGCAUGCUCAACACGAUCUGUCAACAUUCUAGAGUAUAUUGACGGGUCGUGAUGGGCACUCUCAAUGUCCACUUCAUGGUUUUGUGACGU		40
19968	MI0005990	ppt-MIR1033c	Physcomitrella patens miR1033c stem-loop	GAGAUGAAGAUGGAAUUGAUGGGAUGUUGGGCAUGCCCAACACGAUCUGUCAACAUUCUAUGUUAUAUUGACGGGUCGUGAUGGGCACUCUCAAUGUCCACUUCAUGAUAAUAUAACUC		40
19969	MI0005991	ppt-MIR1033d	Physcomitrella patens miR1033d stem-loop	AAGUAUUUACAAGGCUGGCAGUCGCAUUGGGAAUGUCCAUGACGAUCUGUCAACAUUUCAGGUUAUGUUGACGGGUCGUGAUGGGCACUCUCACUGUCUCAUGCUGAUGAUGAUUCGUG		40
19970	MI0005992	ppt-MIR1033e	Physcomitrella patens miR1033e stem-loop	GACUAAGAUAACAUUCGGCAGGGGUGUUGGGAAUGUCCAGCACAACCUGUCAACAUUCCAGGUUAUGUUGACGGGUCGUGAUGGGCACUCUCAGCGUCCCAUGCCCAAACUGCACAUCA		40
19971	MI0005993	ppt-MIR1034	Physcomitrella patens miR1034 stem-loop	GCGUUUCAAGGCUCAUAACCUCAUUCUUGCAAGCACUACGCUGCCAAAGUCAUGACUGUCUUCCUUGCAGAAGCGACUGCAAUGUCGAUAUUCAUUACUUUGGCAGCGCUGUGCUUGCCGAAUUAAGCCUUUGAGUGUUCGUAGA		40
19972	MI0005994	ppt-MIR1035	Physcomitrella patens miR1035 stem-loop	GGGUCUGAAAGCGAAGAAGUUUUUCAAACCGUCUUAGCCCACAAAACGAAUUGUUGUGAUUGUUUGAGAUCGUGUAUUCAUAUGGCAGCCUUGCAAGCUGUCACAGAUCUCUCUGUCACGAUUCGUUUUGUGAGCUAAGAAGGUUUGAAGAAGAGUAUUCUCCAUGUUGU		40
19973	MI0005995	ppt-MIR1036	Physcomitrella patens miR1036 stem-loop	ACUGUAUGUGGCUUGAACGCCAAUAUCAGUGUGGAGUCCGUAAUUAGCUGCGAAAUUCAAUGGCAUUGUGGUGGUUGCAAGGGCGAAUUACACCAACGUGUGCACGCAGCUUCCUUUGUUGAAUUUCGCAGCUAAUUAAGGAUUCUACACAGCUUGGCGUUUGUAUUGUUAUACAGU		40
19974	MI0005996	ppt-MIR1037	Physcomitrella patens miR1037 stem-loop	GUUACUAACCUAAUGCUUGCAAAAGCGGCAGCCAUCAAAUCCUAAUAAGGCUGACUCAACUACAACCUAGUUGCUUCAGCCUUAUUAGGAUUUGAUGGCUGCCACUAUUGCUACAACCUAGUUGCUGC		40
19975	MI0005997	ppt-MIR1038	Physcomitrella patens miR1038 stem-loop	AGUGACAUGGACUCGUGACACGAGCAUCCUAGGUGCGUUUCCACCAAAGAGAGCACCAUCAUUUUGUGUACUCCAUGGUGGAAUCGCAUCCAGGAUGCCAUUGUUACGAUUAGCGAACGC		40
19976	MI0005998	ppt-MIR1039	Physcomitrella patens miR1039 stem-loop	AGGAGCUUAUUGUGUCAGCCACAUUAGGGUCUUUGGGUCUUUCUCUCCUGAAAAUGUUAAGAGCUUGAGCGCUUAAUUUUUCAGGGGAGACGGGCUCAAGGAUCUUGAAGUGGUUGCCUGGGGAUGAUAA		40
19977	MI0005999	ppt-MIR1040	Physcomitrella patens miR1040 stem-loop	AAGAGGUGAUCAUAUCCUUUCAGUAUAGAGGACGUGUUCAUUUGUGUUCACUACUCGAUGUUCAAGACUAUGCUACUUGAACAUCGAGUAGUGAACGCAAAUGAACAUGUUCCUUCAUACAGAAAGGGCUAGCACUGACAUG		40
19978	MI0006000	ppt-MIR1041	Physcomitrella patens miR1041 stem-loop	UGGACAAGUCAUUUAUCUUUAAGUGUACUUUUUCGGGUGAGAGUGGUCCUGAGAAUGAUUGACCAGGAAACAUAACUUCCUCAAAAUCAUUUCAAAACCACCAUCACCUGAAAAACUACAAACUAAGAUAAACUCUGUAAUA		40
19979	MI0006001	ppt-MIR1042	Physcomitrella patens miR1042 stem-loop	GUGAGAUUCUUCAAUACUGUGCAGAAGGGGCUGUGCAGGAACUAGAUAGGUCCAUUGCUGGAUAUGCUUGUCGACGGCAUUGGUCGUGUCUAGUCUCUCCACGGCCCGCUCUGUGUUUGAUUGCCACGCACUA		40
19980	MI0006002	ppt-MIR1043	Physcomitrella patens miR1043 stem-loop	UGAGAAGAGAUUUAACUAGGAAACGGUUGGAGGCCUUCAACUUCAUGCGUGCAAACCCUGAAUGAUUUGGAUGGAUUUUUGCGCGUGAAUUUGAAGGCUCCCAUUCGUUGCUAGCAUGAAGAAUAAGAG		40
19981	MI0006003	ppt-MIR1044	Physcomitrella patens miR1044 stem-loop	UGCUCAAAUUUUUUACCUGCUGCAAGAGAGCACAAAUAUGCACUACAAACUCAAAUGCUGUCAUUCAAAUGUUGAGCAUUUGAGUUUGUAGUGCAUAUUUGUUUUCCUUCGGUUUAAGGUUUCGCGUGAAAU		40
19982	MI0006004	ppt-MIR1045	Physcomitrella patens miR1045 stem-loop	GAAGCGAUAAUGGGUGCACCCUCAACACGAAGUGCUGGCUUUUUGACGUUUUGCUACUAAAUGAAUAACCGUGCAGGUUAAAUUCACUAGCAGCAAGACGUCAAACAACCAGCACUUCGCCUUCAGGGCAACUAGUGUGUAUCGG		40
19983	MI0006005	ppt-MIR1046	Physcomitrella patens miR1046 stem-loop	UCUAUAUCUUGAUGCUCAAAAUUCAGACGUGGAUUUCAUAUUUUUCACGUCAAGAAUCUCACAGGUACAAUUAAGUCAUGAGAUUCUUGUGGUGAAAAAUAUGAAAAAUCCACGUCUGAAUUUUGAAAGCGCUUGCCCUC		40
19984	MI0006006	ppt-MIR1047	Physcomitrella patens miR1047 stem-loop	UUGCGUUAUGUGUGACCUAUGACCUCUUGGAUCACUAGGUAGUCCUUGAUUACAAAGGCCUUAAUUCUUUACAGCAAACGAGUUAAGGCCCCUGUGAUCAGCGAUGACCUAGUUGCUCAAUUGGGCACAGUGUCUCUUCGCGAGG		40
19985	MI0006007	ppt-MIR1048	Physcomitrella patens miR1048 stem-loop	UUCCAUUACUGAUGCCUCGUCUACAAGUCUAGAACAUGAGUGUAGACGACUUAUGUGCUGCAACUGGCAUGCUGGAAGUUAUUAUCCAACACAUAUGUUGUCUACACUCAUGUUCUAGACUUGUAGACAAAUAGCAGCUGUUACU		40
19986	MI0006008	ppt-MIR1049	Physcomitrella patens miR1049 stem-loop	AGCUGGGUGACAGAAUGGUGACUUCGCGAUCAGACCUGUUGGCGAAAGAGAGUCGCCUCUAUUUGGACAGAUCGCCCCUGUAUCGACGUCUCUCUUAGCCAAACAGUCUCGUCGCUUAGGGCCAGAAUAUCCAACGUCC		40
19987	MI0006009	ppt-MIR1050	Physcomitrella patens miR1050 stem-loop	GUAGUUGGUCCUUCUCUUGUUGAUUUCUGUGACCACCUUGAUUCCGGCCUAAUUUGCGCUCAAUCAUCAGCAGCUGGAGGAUCAACUCGAUUAAUGCAAAACAGGCUGAUAUCAGGGUGGUCACAAAAUCAAUCCACGGUUACCCUUACAG		40
19988	MI0006010	ppt-MIR1051	Physcomitrella patens miR1051 stem-loop	UUGGCGUCUCGUCUUGCGCCGAUACCUUAACGUGGUUCAAGUGAACAGGAAGAGGUUUGCGAGAAUGUUGUUCUGAAAGAAUUAACCUGGACAGAGUAGCGCAGAAUGCAACACUAGGGUUUCGGAGUAUCAUUCUAACAAAUCUCUUCCUGUCUACUUGAAGCCACAAUAAGGCUUGGUGCCUGCUAUGAGGUAAG		40
19989	MI0006011	ppt-MIR1052	Physcomitrella patens miR1052 stem-loop	AUGGAGUGUGUUGAAUCCUUGGCCGUAUCCAUGCCGCAAUCAGUAAAAGGGAGUCACGCUGUGUUGUGAGCACUGCAGAGCCAGCAUUCGUGAGUCGAUAGUGAUACAUAUAGAUUGCUUGCUUCCUUUUAUUGAUUGUGGUAUAGAUGCGCUUGAGUGAUACCUUGUGUAAC		40
19990	MI0006012	ppt-MIR1053	Physcomitrella patens miR1053 stem-loop	AACUUUUUAACUUCGAGCCAGCCUGUGAGAUGGGUUAUCUCAAAGUGGACUUUCUCUCUGUCUUGGCUUGAACUCUACUUUGACAUAGCCCACUUCAAAGGUAACUUGAAUACACUCAAAA		40
19991	MI0006013	ppt-MIR1054	Physcomitrella patens miR1054 stem-loop	GCGACAUGGAUUCCAAUUUUGGAGGCAAAGGGAGGAGUAGAAGGGAGGGCUUAACUCGACAUCUGAAAGCAUUGGUUGCAUGCUGUGUUCUUCAACCUGACGGUGUUCUGCAGCAAUGCACACCUUCUGAUGACGUUGCUGCGGACACUCGGUUCAAGUAGGAUCACUGUUACCAACGCCGGUCUGUGUCACAGUAAACCCUCUCUCUAUUCCUGUCUUUGCCUUACAAACAUGUACCUGGGACG		40
19992	MI0006014	ppt-MIR1055	Physcomitrella patens miR1055 stem-loop	UCCUCUCGGUUGCCUUAGAGCAUCCGCAGCCAGCCACUGGAAACACCCCUGAAUCACUAUACCAUACUAUUAUUGAUAUCAAGGUGUAACAAAUAUUGUGAUUUAGGGGUGUUUUCCAGUGACUUGCUGUAGAUGCUCUUACAUCUGUUGUCUA		40
19993	MI0006015	ppt-MIR1056	Physcomitrella patens miR1056 stem-loop	GUCCAUGGUAGGAAACCUAAAACAAAGCCCAGGGUUAUGUUGCAAAAAUCCAGGUGAUGUAAGUAAAAGUCCAAGUGAAGAAACUUACCUCACCUGGAUCUUUGCAUCAUAACCCUGGGCUUUAUUUUGGUAAUCUUAUUACGGA		40
19994	MI0006016	ppt-MIR1057	Physcomitrella patens miR1057 stem-loop	CGUUGAGUCUCACGUUAUGUGGAGAUUAUCAACCCCCAGCUAGAACAGAAGAAUAUGUAUACUAUUCUUGUGUUCUAGCUGGGGGUUGAUAAUGCAAACUAGACAAGAUUUCAGUA		40
19995	MI0006017	ppt-MIR1058	Physcomitrella patens miR1058 stem-loop	UGUGAGCAGUGUCUUAUCAUGACAGUUUGCAGUGCUCUGUGAUGGAAUCUCUAGCGGUCUUGUAUACAGCUCGGCCACAUACAAGACCGCUAGAGAUUCCAUCACGAAGCACUGCAAACUGCCGCGAAGUACGCUUCAUGUA		40
19996	MI0006018	ppt-MIR1059	Physcomitrella patens miR1059 stem-loop	UGCGAGGCAACCUUGAUCCCAUUACGACGUGAAAGUCCUUCACAAACAACAGUGUUUAAAGGAAUCACCUAGAAGUCAUUGUGUAGGAGCUUGGUGGGCGAUCUAAUUGCAAUCAAGGACCGCCCAGUCGCUACCAUUUAACGCCAUCCUCCGACCUGGGACUCGCGUUGUUUGUGGAGGACUUUCACGCCGUAAUGAGAUCACUAGUUCUGUUU		40
19997	MI0006019	ppt-MIR1060	Physcomitrella patens miR1060 stem-loop	AGGAAGAUAUUCUGUACCAUUUUCGAACCUUUGUCAUAGGAUUACACACGCAGAAUUUUUUCUUGAUAAGACCAAUCACCUAACGUGAAAUCGCUGCGUGUGUAUUCCUAGACAAAAGGUUUGAAUGGAAGAUGCUCACACUAUC		40
19998	MI0006020	ppt-MIR1061	Physcomitrella patens miR1061 stem-loop	GUGCUGGGCACGCAAUAAGCAUGUGAGCAUUAUUUCAUAGACUACUCAAACCUCUCAAAGGUAGGGAUAGACCUCUGAGAUGCUUUGAGUAGUCAAUGGAAUAAUGAUGCUGUCCAUAAACUUGAUGUGUGG		40
19999	MI0006021	ppt-MIR1062	Physcomitrella patens miR1062 stem-loop	CGAGUUCGCUUUGCACGGGGUUGUUGUCGUCCCUCACGUGGUGUUUGCAGCUAGGAUGUCGGGAGGGGUCGAUGUGUUGUGGAAUGUUCCGCUCCUUGAAAUUUGAGUGACCCUUACCGUCUGCCAGUGAGGCCGCUUGCAAACACCCGUAUGGGACGACGAAGCUCUGGUGUUGCUCAACAUC		40
20000	MI0006022	ppt-MIR1063a	Physcomitrella patens miR1063a stem-loop	GAACGACGACAGGGUCCGUCGCUCACUUACAUCUUGGAGUACUGCAUCUUCGGAUCUGUUGCGCCUUCCGUGCCUGCUCUGGCAAUCGUCAUGAGCCGUUGGAAUGUGGAAAAUUCCUAUCGUGAAUCAUGGUGGUUUGAGAACCGCGCGGAAAGCAACAUUCAAAUUUGUGGAUGCAUUACUCCAAGAAGUGCGUGGGCAACGGGCUACUUGCAGCUG		40
20001	MI0006023	ppt-MIR1063b	Physcomitrella patens miR1063b stem-loop	AGAGUUACUUGUGCUUCGUAGUUCACUUACAUCUUGGAGUACUGCAUCUUCAGAUCUGUGAGUCUUCGCCGCCUAUUGCCUUCGCCACCAUGCUUGACGAAUGGUUUGAAACUGAUCACAUCCAACUUGAACGGAUAUCCUGCCCCUUCAUAGUGCUGUGAUUCCGUUCAAGCAGUUCAGUUGUCCGACAACCAUGGUGUGGUAGGACAGUAGUACUGCUAAGGCUUUGACAUUUUGAAGAUGCAGCACUACAAGAAGUGUGUGAGCAACGGGCUGGAUUCAAGAU		40
20002	MI0006024	ppt-MIR1063c	Physcomitrella patens miR1063c stem-loop	ACCAAGAAUUUUGCCGUGUUGCCCACUUUCAUCUUGGAGUACUGCAUCUUCACAACCGUCGCUUUUUCAAAUCUGAAUUCCAGUCACUGAAGCUCGGGCUAGAUUUAAGGGCUCUGGGGACGCAGGAAGGUGAGUUCAGUGGUACAAAUAAAAGAAUUAGUGAUAAUUUUCUGGAGCUUAGUAGUCGGAUGGCAGAGGGAAAACAAAAUUAGUAUACUUGACUUGCGUUUUAAGUGUAGAUCCAAAUAGAUUUUCAAAAGAAUAGGUCCUGUUGUCCCUCGAAUUGAAGCUCGUUUUGGAAUCUUACGGAGACGAAGAUGCAUUCCUCCAAGAAGUGAGUGGGUAACAGGCUACAUCAAACGG		40
20003	MI0006025	ppt-MIR1063d	Physcomitrella patens miR1063d stem-loop	ACUACACUUAUUGCCUUUUUGCCCACCCUCAUCUUGGAGUACUGCAUCUUCAUGUCGGCUGCUUUUCAUGUCUGGCUACGAGGUUGCUCAUGUGAUUAGGUUUGAUCCAUGUUAGGCUUUAGGUUGUAUCAGUGAAUUAGUGUCGACAGUUAGGAGUGAAACUUUUUUUAGCUGUUGAUACGCGGGAGUUAUGGGAUUCUCAUUUCAACACAAUGUAAUCUUGUGUCAAUCCAGCCUAUGCUUGUAGAGUUACUGAGUCACAUGAGCACAUCGAAUGCCUUUGAGGCUUUGAAAUUCUACCGACGAGUAGAUGCAGAACUACAAGAAGCGAGUGGGUAACAGGCUAUUUUUCAAGA		40
20004	MI0006026	ppt-MIR1063e	Physcomitrella patens miR1063e stem-loop	CACCGCAUGCUCGCCUUGCUGGUCACCCUCAUCUUGGAGUACUGCAUCUUCACAUCUGUAGCCCUUCAUCUAAGUCUCAGGCAGCACUAGUGCUGUAGUUUCAGCCGAAUUCUUGGUAUUCGAGAAUUUAUGAAUGAGGCACUGAGCACACCAAAAGAGGUCAGAGAUUGGGGAUUCUACUGAUGGGCAGAUGCAGAACUGCAAGAAGCGAGUGGGCAGCAGGCUAUGUUCAUUCG		40
20005	MI0006027	ppt-MIR1063f	Physcomitrella patens miR1063f stem-loop	GGAGGUUUUAAAGCUCUGUCGCUCACUUACAUCUUGGAGUACUGCAUCUUCACAUUCGUCAGAUUUUUCUAUCUGUUGUCAUAUCCCCGGAAUUUUGAAUCAGGUACAUACCUAGCAUCUUCAGAUAAGCACGUGAUCACGUUCAUACGGAUCAGUCGCUAACUCUCUUACGGAGAGCAUAGUGUGGUUUGAUAACAGUGGUGCAGAAGCUCUGCGAAGUUGAAGAUGCAGCACUACAAGAAGUGCGUGAGCGACGGGCUAUAUGAAAGAC		40
20006	MI0006028	ppt-MIR1063g	Physcomitrella patens miR1063g stem-loop	GACUGCGAGUUCGCUUUGUUGCUCACCCUCAUCUUGGAGUACUGCAUCUUCACAUCUCUGGGUUUCACAAUCUGCCUCAGGUUGUUAAAGUGCCGGAGUAAAAUUGUGUUAUUGGAUAUUCAGUAAAGAUGGGUGCGAAAAUGGAGUCAAUCCAUCAUUUGCAUAGUACUAGAGAUAAAGUGUUUACACACUUAUCAUAGUACAAAACUCGGGGCACUUGAGCACACCAUAUGGAAAGAAGGUUUGAAAUUCUUGUGAUGGGCAGAUGCAGAACUGCAAGAAGUGAGUGGGCAACAGGCUAUUUUCGAAGA		40
20007	MI0006029	ppt-MIR1063h	Physcomitrella patens miR1063h stem-loop	AAGAACGGCAAAGGUCCGUCGUCCACUUACAUCUUGGAGUACUGCAUCUUCAGAUCUGUUGCACGUUCACUGCCUGUUUUACCAGCCUCCAUGAACCAUUUGAAUUUGGGCUUCUCUAACGGAGGGAAUCAUGAAGAAUGCUGGUUUGAUAACAGCGCUAAACCUGCGUACAAAGAUGAAGAUGCUUUUCUCCGAGAAGUGCAUGGGCGACGGUCCACAUCUAGCGC		40
20008	MI0006030	ppt-MIR1064	Physcomitrella patens miR1064 stem-loop	ACGUACAGGGCAAUCAACGAUUUCGAGGGCAUUCUGAGAAUAAUCAUCCGAAUGCAGCAGCCCGGGCGGGUGAUUAUUCUCAGAGUUCCCAAGGGAGCGUGGAUCGACCGGCGUA		40
20009	MI0006031	ppt-MIR1065	Physcomitrella patens miR1065 stem-loop	GAUCCAUUGUACUGAUUCCGAAGGAGAAGACAGUCUCUGACUUCUCGCAGAGUGAGCCUGUUUCUGCAGUACUGGAACGAUUGGUUGAGACCACUGGCACUAGGCAAAAACCUUGUUUCUGGUGACUUGGUCUGGGAUCGUACAGAGCUGCAGAACGCUUGACAUGCGGGAAAUCAGAGACAGUCGCUUCCUUUGGUUUCUAAUUGUCACCA		40
20010	MI0006032	ppt-MIR1066	Physcomitrella patens miR1066 stem-loop	GUUGAAGCGUCCGAGCAUGCGGUUACCACUCGUACCCCGCUCAGUAACAUGUGCGAACUUAUUAUCGCACAUGUUGCAGAGCGGGGUACAAGUGGUGGCCGCGUACUCUGCUACGAUUG		40
20011	MI0006033	ppt-MIR1067	Physcomitrella patens miR1067 stem-loop	AGACUUGUUGUUUGCGGUUAAUUAAUUGCACAUACUGAAGUUUGAUGCCAUGUUCUGAUGAAUCCGGUCUUGAUUCCUGAAGGAAAGAAACAUGAAAUUGCCGCUGUGGCAUCUCUACAUGGCAUCAAACGUCAGCAUGUGUAAAUAGUUAAUUGCACGACACCAGAA		40
20012	MI0006034	ppt-MIR1068	Physcomitrella patens miR1068 stem-loop	CUUUUCAACACCUUGGCGCUGGCCUUCGUAGCCAUUUGCUUGAAGGUCAACUCAGACGGGUGGAAGAGGCAAUGUAUUGACGUCUUCCUCCAUUUUCCGACCAUUCUCUAGGCACCACAGAGGCAUCAAUGCUCUGCCUGUUUCUGCCGUGUGGGUUGGUCCUCAAGCAACGGGCUACGAGGACCAAUGUCAAUAAGCAUCAAC		40
20013	MI0006035	ppt-MIR1069	Physcomitrella patens miR1069 stem-loop	UGUUCUUCAAGCACAUGUCCACUUCAUGUUCUCAAGUCUUAUCAUUGGAUUGAGCACCUUGGUCUUUCAAAUAUUCUAUUAUGAUAUGUUGAUAUAUAAUUGGUCUUUCAAGUAUUUUCUCAUUAAUAUGAAAACAUAUUAUUACAAAAUAUUUUUGCAUAUUAUUGUAGUAUACUUGAUAAAUCAAAGUGCUCACUGUAAUGAUAAAGCUUGAGAACAUGAAGUCUACUUGACUUCUACUUUG		40
20014	MI0006036	ppt-MIR1070	Physcomitrella patens miR1070 stem-loop	UUGGACCAUUUUCUCUGUGCUUCGUUGUAUCGGUUUCUAGUAAAACUUGCUGAAAAAUUCUCAACAAGUUUUACGAGCAACCGAUACAACGAAGCAACCGACUGUAUUGUAG		40
20015	MI0006037	ppt-MIR1071	Physcomitrella patens miR1071 stem-loop	GUGAACUAUGUCGCGACGAGAUAGGACCCGCGCAAUUCCCGAACGGGUAGAAGAACCGGAUCUAAAAAUGCGCGGGUCGGGUUCUUCCACCCGUUCUGGAAUUGCGCGGGUUCCUGUCCCCACAAGCAACGAAAA		40
20016	MI0006038	ppt-MIR1072	Physcomitrella patens miR1072 stem-loop	AAUUUGUUCUAAUCUUAUGAGAUGGAUAUGUUCAAGCUUCUAGUUUCACAAUGUGAUAAUUUUAAAUAAUUGUUUUUGUAAUCAAAGUAUGAAUUUUAUGAUUUUAUAUUUCAUUCUAAUUUCUUAAAAAUAAUGUUGGUUGUUUUUGUAGAAUUAUUUUAUAAAUACAUAUUGUAAAAUCUCUAUGUUAUAUGAAAAAAUAUCUUUUAAAAUUUAAAUCCCAAUAAAAAUAUGACAAUACAAUUAUUUUGAUAUUGCAUUGUGUUAUUUGAAGCUUGAAAAUAGGCCAUCUUUAAAAUUAGAACUAAU		40
20017	MI0006039	ppt-MIR1073	Physcomitrella patens miR1073 stem-loop	GCAGACUGAUUUUAACGUGGAAGAAUGAACACAUGAAUGAUAUUAACGUCCACGAUGUAAAUCUAAUGCAGAAUUGUUGCUGGGAUUAACUUCAGUUUCAGACACAAAGUUAAUGACUGUGGAAACCCAGUUCACUACUGUGCUACUUCGUGGGCGUUAAUACAUUUCAUAUGUUCACUCUACCAUUCAAUCGUCUGGACU		40
20018	MI0006040	ppt-MIR1074	Physcomitrella patens miR1074 stem-loop	GAGUUGCAGGUUUUGCUGGAUUUGUGGUCAGGGUUGUUAGUUGUGUUGAUGGGUUAAUUUCAUAACUAACAACAUCAACCCAUCAACACAACGAACAACCCUGACCACAAAUCCAACAAUUUUUUUCAGA		40
20019	MI0006041	ppt-MIR1075	Physcomitrella patens miR1075 stem-loop	GGUUGGUUGAGUGAACUUGACAUCUAUAUUGGUAGGAACCAUGCCUGGAACAAGGCAAAACAACUACCCAAAGUGGGUAUUCUCUUUGCCUUGUUUCAGUCAUGGUUUCUACUGGUGCUUGUCGUUGAUCACUGUCUUUAUC		40
20020	MI0006042	ppt-MIR1076	Physcomitrella patens miR1076 stem-loop	GCGAAAGCUAUUCAAACGUGGUGUUGUAUCACAAGGUGCGAUAAUUGCUCGAAGACAUUGGCAGUUAAGAUAUUUUAGCCCCAUGAAAAUGUGGGUUAGAUGUAAGAGUAGAAGUGUAGGGAUUUGUACGUAGUGUUAAUGUAGCUGUGCAUUGUCAAUUCUGAGUUCCAAAAUCUCCAAGCACUUAUCGCACCCUGCGAUACAACAUACACAGUUGCAAGAUGGAA		40
20021	MI0006043	ppt-MIR1077	Physcomitrella patens miR1077 stem-loop	AAAAUUACCGAGAAACUUGACUCCUUUCAAAUGUUCGGAUGCGUGCGGCCCCGCGUUGGACUUGAGCGCGAAGCUAUAUGUUAGUUUCCACUCAAUACUCGAGGGAUGGACGUAUACGAGCCUGUGAAAGGAGACAAAAAUUUUGUACAAUU		40
20022	MI0006044	ppt-MIR1078	Physcomitrella patens miR1078 stem-loop	CAACAACAAAACAAAAUACCUUGAUGCUUUUUGGAUGAUUCAAUUGUGAUAAAAACUAGUUUAUCACAAUUGAAUUAUCUAAAUAUCUUCAAUGUGUUUUUAUUACAACUA		40
20023	MI0006045	ppt-MIR1079	Physcomitrella patens miR1079 stem-loop	GGCUUGUUAAAGUUUAGACUGAUGUUAGUGACUCACCGAGCUCUUCUUUUUGGAGGUGGGCACUGUGAUGUACGAGAAGUGUGACCUGCAAUAUCGACCACCAAAAGAAUAGCUAUGUGGUUCAUUCUUAUCAUUCUAAUUUUAAGCAAGC		40
20024	MI0006046	smo-MIR156a	Selaginella moellendorffii miR156a stem-loop	UUGUCACUGGCGACAGAAGAGAGUGAGCACACGGGGCCCCGUCCAUGGAUCGCAUGGAUUGAGCUUCGCGUGCUCACUCUCUGUCUGUCAGCUGUGCCUGUU		59
20025	MI0006047	smo-MIR156b	Selaginella moellendorffii miR156b stem-loop	UGGACUGCUGCUGACAGAAGAUAGAGAGCACAGACGUUUGGCUGCAAGAGCGGAAUCCAUAUCCAGCAGCUCUGCGUUCGUGCUCUCUAUUCUUCUGUCAUCAAUCUUUCGA		59
20026	MI0006048	smo-MIR156c	Selaginella moellendorffii miR156c stem-loop	GGAGACUGAUUUGACAGAAGAAAGAGAGCACAUUUGGCUGCACGCUCUUGGUUCUAGUGUGUCACUCAUGCGUGCUCUUCUUCUUCUGUCAUAUCGCAAC		59
20027	MI0006049	smo-MIR156d	Selaginella moellendorffii miR156d stem-loop	GGAUCUAUUGUUGACAGAAGACAGGGAGCACCAGCAGCCACCAGCUCUAGAGAGGCUUUUGGGUGCUUGUGCUCUCUAUUCUUCUGCCAUCAAUCCGACUCGG		59
20028	MI0006050	smo-MIR159	Selaginella moellendorffii miR159 stem-loop	UUGCAGGGGGAGCUCCCUUCAAUUCAACUGAGGUCGGUGCGUCGCUGUUACUCGCUGCUGACUCAUGCAUUCGCCUGACAUGCCCGCAACCAUCAUCAGAUCGUGAUCAGGACACGCCGAAAACAUGCCCGUGAUCACCUCCGCAACUCUCUGAUCUCGGCGAGGUUGAUCACAGAAUCCCCCGAGUUUGAGGCAUGGCAGCCGUGUGCAUGAUGCAGGAGCAGGUGCGGCUUCGGCUCUGAACUUCCCUUGGAUUGAAGGGAGCUCCCUUCCAGAUUC		59
20029	MI0006051	smo-MIR160a	Selaginella moellendorffii miR160a stem-loop	AAAAUCACUCUGCCUGGCUCCCUGUAUGCCAUCUGGGGGGGAUUUAUCAGCUGACGAUGAUAAGCUCCAUAGCUGGCUUACGGGGAGCCACGCAGAGUUUCUCGCU		59
20030	MI0006052	smo-MIR160b	Selaginella moellendorffii miR160b stem-loop	ACAAACAAUCCCUGCCUGGCUCCCUGUAUGCCACCUGAGAAGCCCACCGAAGUGUUUCGGCAGGAUUCCUAGCUGGCGUGCGGGGAGCCAUGCAGAGCUUCUCUCUUU		59
20031	MI0006053	smo-MIR166a	Selaginella moellendorffii miR166a stem-loop	AGCAAGUCCUGGAUGUGGGGAUUGUUGCCUGGCUCGAGGGAGGCAUUCCUUUGAUCUUUUCUCUCCUGGGAAGUACUCCAGAAGAACUGUGCCAGAAAUGUGCGCUCUCGGACCAGGCUUCAUUCCCCUCAUCUGAGAUUGCACC		59
20032	MI0006054	smo-MIR166b	Selaginella moellendorffii miR166b stem-loop	UUCCUCAGUGAGAACCAGGAUGUGGGGAGUGUAGCCUAGCUCGAGAGAUUGAUUUGAUACUAAGGCUACGCACACAAGGUUGUGAUCACAGCUUUGUCUCGGACCAGGCUUCAUUCCCCUCAGUGUGGUGCUCACU		59
20033	MI0006055	smo-MIR166c	Selaginella moellendorffii miR166c stem-loop	UAUGUUGCGGGGAGUGCUGCCUGGCUCGAGACAGCAUCGCCGAGAUCUGAUCAAAUCGCAAAGUUGAGAAACAAGCAUCACAGUUUGAUCUGGAGAUCGUGUUGUGUCGGACCAGGCUUCAUUCCCCUCAGCUACAAA		59
20034	MI0006056	smo-MIR171a	Selaginella moellendorffii miR171a stem-loop	CGAGCGAGAGCGAUAUUGGCUCUGCUCAAUCGCAUGACGCUGCUGCAUCGCACGAAAAAUUUGCGAUGGGAAUGGAUCGAUGGAGUCGCAGCAGAGGCAUGAGAUUGAGCCGUGCCAAUAUCACUGGUGUUUUUC		59
20035	MI0006057	smo-MIR171b	Selaginella moellendorffii miR171b stem-loop	UGUGUCUGUGAUAUUGACAAGGCUCAAUCAGGCUGCAAUGCUACUCGAGCUAAUUAGUGAUGCUGCCAGCUUGAGCCGUGCCAAUAUCACAUAGAUAGCUAGC		59
20036	MI0006058	smo-MIR171c	Selaginella moellendorffii miR171c stem-loop	ACGGAUCAUCGAAAUCGAUGUGUGCUUUGAUAUUGGCAUGAUUCAAUCCCAUGACACCAUCUACAAACACCGAAAAGAGAAGCUUUACGAUGGUCUAGCAAAGUUCUUCUCGCGAAAGAGAAGCCUUACGAAGAUCUAGCCAAAAUUUCGUGGCAUGGACGAGCAAAGGGUGCUGGCAUUGGAUUGAGUCGCGCCAAUAUCAUGUGAUUGCGUUG		59
20037	MI0006059	smo-MIR171d	Selaginella moellendorffii miR171d stem-loop	UGCGAGGUAUGUGAUAUUGGGAUGGCUCAAUCAGAUGGCGUUCGCUGCAAUGCUCAGCCAGCGCUCUCAAAUUGAGCCGCGCCAAUAUCACAUCCUUGGAAAA		59
20038	MI0006060	smo-MIR396	Selaginella moellendorffii miR396 stem-loop	UCUCAUGCUUUUCCACGGCUUUCUUGAACCUGGUGCUCUUCCAAGGCAGGAGGAUCAGAAAACGUUGUGGUAUUUCUCAUCUCCUCGUCUCGUCCUUGGUCUCCCCUUGAAAGAAACUCACCAGUAAGAGUACGAAGUUCAAGAAAGCUGUGGGAAACAAUGGCCGGA		59
20039	MI0006061	smo-MIR408	Selaginella moellendorffii miR408 stem-loop	AUUUAGUAGUAGCUAGGGAGAGACAUUGCAUGAUAGCUACACCAAAGAGCAACCUCGGCUCCUUGUGUGGCUUUGAUGCACUGCCUCUUCCCUGGCUGCGGCCAAGUUA		59
20040	MI0006062	smo-MIR536	Selaginella moellendorffii miR536 stem-loop	GUGUUUUUGAUGCACUCAGCUUGACACGGCCGUGCUUGGAAGUCUGGAAAGUUUUCUUUCACGCUCCACUGAUGCUGCUGCUGCAAUGCGUGCUGACUCUCUCUCUCUCUCUUGGUCGUGUCAAGCUGUGUGCAUCACAACGCAUUGCUCGUUUUCA		59
20041	MI0006063	smo-MIR1080	Selaginella moellendorffii miR1080 stem-loop	UUUCAUCCAGAGGGUUUGCAGAUAGUGUGUGCCUGAUUCUAUGAUGUCUAGAUUUCGUUGGAUUGGACAUUCACUAUCUGCAAACACCUCUGAUGGAAUUC		59
20042	MI0006064	smo-MIR1081	Selaginella moellendorffii miR1081 stem-loop	UCUUUUGUGAGGCUUGCCUUUGAUUCUCUGAGCUCUGGGAGGUGUGAUUCCCUCACCUCCUAGCUCUGAGAAUCAACAGCAAGCCUCACACACAUCGGCUGUUCUUUGAUCUCGUCUUGCAGGCGCGGGAUCCAGGACUUGUGAGGGUUGCCUUUGAUUUUCUGAGCUCUCGGAAGUGUGAUUCCCUCACCACCGAGCUCUGCACACAUCGAGAUCUUUGGCUGUUCUUUGAUCUCGUCUUGCAGGCGCGCGGGAUCCAGGAGCAGCGAUCUUUGUGAGGCUUGCCUUUGAUUCUCUGAGCUCUGGGAGGUGUGAUUCCCUCAGCUCCUAGCUUUGAGAGUCAAUUGCAAGCCUCGCACGCAUCGAGA		59
20043	MI0006065	smo-MIR1082a	Selaginella moellendorffii miR1082a stem-loop	CACACAUAAGAUUUUGAGGCAGGCGUUGGCCUGCUGGCCGGUGGCGAGCUCGCGAUCUUGAUUGAGAGCUCUCGCUCUCUCUCUCUCUCUCUCUCUCUCUCCUCGCAUCGCCUCGCCUCGCCGUCCAGCAGGCCAAUACCUCACUCGAGAUCUUGUUGGA		59
20044	MI0006066	smo-MIR1082b	Selaginella moellendorffii miR1082b stem-loop	UUUGAGGCAGGUGUUGGCCUGCUGGCCGGCGACGAGCUCUAGUGCCCGCGCAACGCUUCGCCGUCCAGCAGGCCAAUACCUCACUCGAGAUCUUGUUUCU		59
20045	MI0006067	smo-MIR1083	Selaginella moellendorffii miR1083 stem-loop	UGGGAGCUCAUAGCCUGGAACGAAGCACGGUUGUGCUUGGUUUCUCGAGCCAUCCAUAAAAUCGCGCUUCGUUUCAUGCUAUGCGCGUCCAUGAU		59
20046	MI0006068	smo-MIR1084	Selaginella moellendorffii miR1084 stem-loop	CAUGACAAUGCUAACUCAGGUGGUAUGUUCCCAUCCAACAAAACGUUUCAUGGAAUUCCACUCGCAGGUUUGAUUGAGUGGGAGCAUACCACUGUGUUAGGAUUGUCACAAAGAAGC		59
20047	MI0006069	smo-MIR1085	Selaginella moellendorffii miR1085 stem-loop	AUCUCUCGAGCCCCUACAAGAGAUAUCAAUCACGCCACUGCUCCCUGUAAGUUACAGCGAGCAGUGCAUGAUUGAUAUGUCUUGUAGGGACUUAGAGAGAU		59
20048	MI0006070	smo-MIR1086	Selaginella moellendorffii miR1086 stem-loop	GAGCACGAACUAGUGCCGUGGUCCUUUUGGCCCCGUGAGGAGUGAAGUGAGCUUCACUGCUAAGCGGAGCCAAAAGCUCUGCGGCACUAAGCUUGUCUGCAA		59
20049	MI0006071	smo-MIR1087	Selaginella moellendorffii miR1087 stem-loop	CGUUAACAUCUUGGAUGAAGUGCUUGCGAAAGCGCUAGCACUAGUUUGCAAACUCUCCGUAGUAAAUUAAUUUCAGAAAUCAAAGGAAAAAAAACACUCACCAUGGUGGCUAAAGCGGCGGAAUGGCUAAAUGAGCUAGUAACUUUCACUAGCGAGUCAUUUGAGACCACUUUAACUGCCAUGGUGAGUGUUUAUUUUCCUUUGAUUUUUGUAAUUGGUUUGUUGCAGAGAGUUUACAGAUUGGUGUUAGUGCUUCCACAAGCGC		59
20050	MI0006072	smo-MIR1088	Selaginella moellendorffii miR1088 stem-loop	CGAGCAGGCCUCUAGACAGAAGAAAGAGAGCACGCAUGAACACUGCCUCUGAUUGCAGCCUCGAUGCGUGCUCUUUUUCUUCUGUCGGGAGUCCCU		59
20051	MI0006073	smo-MIR1089	Selaginella moellendorffii miR1089 stem-loop	GACGACCUCAAGGAUCAUCUUGCUGCUGUGCAAACAAUCCUAAAUGAUCUUAAGGAUGUGGGAGCAAGCAUAAAGGAUGGAGGAAGGGUGACGAGCACCAACUCUGCUUCUUCUUCAUCCUCUAUAUUUGCUUCCCCAUCCUUCAGAUCAUCUAGGAUUGUUUGCACAGUAGCAAGAUGAUCU		59
20052	MI0006074	smo-MIR1090	Selaginella moellendorffii miR1090 stem-loop	GCGCCAGAGUUGAAAGCCAUUCUCAACAAAAUUGUAGUACUCUCGUGAUCAUACUGGACAGCUGCGCUCUUGUUAAGAAUGGCUUUCGAGCCUGCGCUCA		59
20053	MI0006075	smo-MIR1091	Selaginella moellendorffii miR1091 stem-loop	GGCCUCUGGCAUUCGUGCGGCAGUGAGGGAGGAUUUGCCAAUAAUCCAUAGUGCCAUAAAGGAAGAUGUUGCUGUGGUUCCUUCACUGUGUCAUGAAGUGCCUGGAGGUCCUCCUUGAUUGCAGCACGCAUAACCGCAACAUUCACUGCUCUAGCCAUGGCAACCACAUCCUCCUUCAAUGCACCAUGGAUCGCUUGCAAAUCCUCCCUCACUGCUGCACGAAUGGAUCCCAUUC		59
20054	MI0006076	smo-MIR1092	Selaginella moellendorffii miR1092 stem-loop	GUUAUGUGUUUGGCGACGAGGUUUGACAGGAAUGCAUUGGUGUUCUUUUCACCAAAAUGCGAACGCCAUGAAAAAAACGUUCAACAGUGGAAGUCAAUUGAUGUGGGGCGCUUUGGUGAAAAUAAUGCCAAAGCAUUCCUGUCAAGCUUCGUCACC		59
20055	MI0006077	smo-MIR1093	Selaginella moellendorffii miR1093 stem-loop	UUUCACCACACCAUUGGUGAUGGAGGUGUCGUUGCCAAGGAAACUUUCCUUAGCUUUCCUUGGCGCCGACACCUCUGCCAUCACCAAUGG		59
20056	MI0006078	smo-MIR1094a	Selaginella moellendorffii miR1094a stem-loop	AUGUCACAGUACUGUGGUACAGAGAAGCACAUCGCACUGGAGGUGAUUUGUUUCAUUACCUGCGGCUCCAUGUACUUCUCCGUGCCACAGUACUGGAAACGAAA		59
20057	MI0006079	smo-MIR1094b	Selaginella moellendorffii miR1094b stem-loop	UACGUCACAGUACUGUGGUCCAGAGAAGCACAUCGCACUGGAGGUGAUUUCCAUCACCUGUGGCUCCAUGUACUUCUCUGUUCCACAGUACUGGAAACGAAAAGG		59
20058	MI0006080	smo-MIR1094c	Selaginella moellendorffii miR1094c stem-loop	GCAUCACAGUACUGUGGUACAGAGAAGCACAUCGCACUGGAGGUGAUUUCUUCCAUCACCUGCGGCUCCAUGUACUUCGCUGUUCCACAGUACUGGAAACGAA		59
20059	MI0006081	smo-MIR1095a	Selaginella moellendorffii miR1095a stem-loop	UGUCUUGUGUUUGGGAAUAAAGGAACCUAGGAGGGCCGGGUUUGCGAACUUCCUGGGUGGUGAUAUGCUCCGCUGAGCUCGAGCAGUGUAAUUAUCACUUGCUUGCACCGCCGGAAGAAAUGUGAUCCUAGGUUCCCUUGUUUCCAAAUUCAAGGCCGGUG		59
20060	MI0006082	smo-MIR1095b	Selaginella moellendorffii miR1095b stem-loop	AGGUUUGAGCUUGGUAACAGGGGAACCUAGACUGUAAUUUGCUGCUUGCUUUGAUUCCCUUCGUCCUUCCACCGCCAUUCCAGUCUUUGCAGUCACUGUUUCCGAAAAGUUUCGAGAAAAGGAAGAACACUGCUUGGACGCAAGCUCGUCUUGACUCGUUGUGGUGGUUUGGAUUUGUGCAUUUGCGCCAAGGAUUUCGAGUUUCUUGUCUGCUUUCGUCUGGAGGAGAUCGAUGUAUGCUUGUGCUCUAGGUUCCCUUGUUUCCAAAUUCAAGUCUGGUA		59
20061	MI0006083	smo-MIR1096	Selaginella moellendorffii miR1096 stem-loop	UAUGGGGAAUUUCUGAAGCAAGGCGGCAGCAAGAAACCUCCAUGAGAGACUCUCAUGGAGGUAUUUUGCUGCCUCUUUGCUUCAGGAAUUCUCUCCAAA		59
20062	MI0006084	smo-MIR1097	Selaginella moellendorffii miR1097 stem-loop	GCUCAAGUCAUAGCCAUUGUUGUUGUUGGAAUUCCUCUGAAAAGACUCCUAGCCUCCUUGGCAGCCAUAGCAAAAAUGCCAUUAAUUUUUUUGUCGACAUUCUUCUUCCAGCCAGAUUAUCCAUUAGUGGGAGUGGCGGGAUCACAAGAACCAAAGGCAGUCUUCUUCCAUAGAUCAUCCAUCAGUGGCAGUGUUGGGAAUAGGGAACGUGGCAAGCUUGGUAGCAGUGCCUCUUGGGCUCUUGUGAUCUUGCCACUCCCACUGAUGGAUGAUUUGGCUGGAAGAAGAAUGUCGACAAAGGAAUCAACGGCACUGUUGCUAUAUCUGCUAAGGAGGCUAGAAGUCCUUCAAAAGGAAUUCCAACAGCAACAAUGGCUAUGA		59
20063	MI0006085	smo-MIR1098	Selaginella moellendorffii miR1098 stem-loop	GUGGCCAUCGCUGAUGACGUUUGUGCUGAAAUUUGGGAAUGGGUAAAGGGCCUUCACCCGUUCCCAUAUUUCAUCACAAACGCCAUCACGGAACGUCUGCA		59
20064	MI0006086	smo-MIR1099	Selaginella moellendorffii miR1099 stem-loop	GAUGGUUCUUCUUUGUCCCAAGCAUAUAGCAAUGGUGUUUUUGUCUACAAAGUGGGUGUCUUGGGGCAGGAGAGGCUCGAGAAUUUUAGUACCUGAAGAAAAUCUAUGCUACCUAGAAGAGAGUGGACUAGCAGCUAGGGUGAAGGUGUAGAUUUUUUCUACGUACUGAAAUUCUUGAUACAACCUCUCCCACCCCAAAACGCCUAACUUGUAAGCAAAGGCACUAUCGCUGUAUGCUUGGGACAAAGAAAGACUAUUAUCAAGUUAA		59
20065	MI0006087	smo-MIR1100	Selaginella moellendorffii miR1100 stem-loop	AUACCAAGUUUCUGUCACGGACAGAACCCCACUCUCUACUUCGAGCGAUUGAUCCACUCUUUCCAUUCUCGAUGAAGUAAGGAGUGGGGUUCCUCCGCGACAGGCACUUGGUGU		59
20066	MI0006088	smo-MIR1101	Selaginella moellendorffii miR1101 stem-loop	UGUGUGCUUGGGCAUUCUCUCGAAACAAGUGCAGCGAAAAACGCAGAGCUGCGUCUCCGCUACACUUGUUUGCAGAGAAUGCCCAACUGGAAAAAU		59
20067	MI0006089	smo-MIR1102	Selaginella moellendorffii miR1102 stem-loop	AAGCAUGAUUUGGGAGUAGCUAUUGCCAGCGUCAAGCAUGAUGUGCGAGUAGUGUGCAUGAUGUGCAAUCCUGCUUGAUGCUAGUAAUAGCUACUGCACAGUCU		59
20068	MI0006090	smo-MIR319	Selaginella moellendorffii miR319 stem-loop	UUGUUCGCGGGAGCUUCCUUUAGUUCAACUCAGGUGGAGCUGGAGAUGGUCCUGCUGCCGACUCAUGCAUCCGCGUACCUUGGAAAGUUACAAUGCCAGUUUCAGAAAGAGAGCUUCUUUUGUCCAGUGGUAGACGCUUGCAUGAUGCGGGAGCUGGUUCUCUCUCGAGCUUUGAUCGACCUGCCUUGGACUGAAGGGAGCUCCCUUGUUCCCAC		59
20069	MI0006091	smo-MIR1104	Selaginella moellendorffii miR1104 stem-loop	GGAAUAUUGGCUGAAGGAGAAAGAGCGGCUGCAAAAGAAGGAAGAGCACCAUUACAUUGGAGGAGGAGGAGUUCCUUCUUCCGCAGCUGUUCUUUUUCCUUCCGCAGCUGUUC		59
20070	MI0006092	smo-MIR1105	Selaginella moellendorffii miR1105 stem-loop	ACUCGUAUUCCAAAGCAGCAAUCUUCACGUCCAAAGCAGCAAUCUUCACAUUCAAAGCAGUGAUCUAACUUGGUGCAGCGGGAGCAGAUUGCUGCUUCGGAUGUGAAGAUCGCUGCUUGGGAAGACGAGAAGUC		59
20071	MI0006093	smo-MIR1106	Selaginella moellendorffii miR1106 stem-loop	UUGAUCGAUCCCACAUUAAAACCUUUAAAGGUGAGUAUUUUGCGUGAAAGCUUGGAAAAGAUUGAGGGUCACGAAAUAGUAACCUUUAAAGGUGUUAAUGUGUGACAUAACGAAA		59
20072	MI0006094	smo-MIR1107	Selaginella moellendorffii miR1107 stem-loop	AGGUUUCGGUGGUGCUGGUUCCAAUUCAGGUCGCGGCUGCGUUCCCUGUUGCUGGGCUCUGAAUUGAAAUCAGCGCCCUUGAAACUUUGC		59
20073	MI0006095	smo-MIR1108	Selaginella moellendorffii miR1108 stem-loop	GUGAGUCUGUUUAGGCAAGUGAAUAUGUUGCUCUUGUAUUUGUUGCUCUGGACUAAGGUUGCCGCAAAUAGCCUUUGUAAAUGCCACAGUGGUCCUGAUGAGGGGUUAUGUUUCUCAGCUCAAGCCCAGCAUGACCUCUAGCUCCAGACCUUCUGGAAGCAAUGACCUUGAGCUGAGAGACAUAACCCCCCAGCAGGAUCAUUAUGCUGCCCCCAAACGCUAUUUGCGCUAAGUAUGUUGCACCCUACUCCAGGGCAGCCAAUACAAGAGCAACAUAUUUCACUUGCCUAAACAUGUU	Axtell et al. report the alternative production of at least 2 miR/miR* duplexes from the MIR1108 hairpin [1].  The sequence of the most abundant clone is shown here. 	59
20074	MI0006096	smo-MIR1109	Selaginella moellendorffii miR1109 stem-loop	CAUUACUAACGUUGUGCAAGAUAGUGGGAGAUUUUGUGUAACUAAGACUUUUAGUUUUUGAUUAAGACUAAUAGUAUUAGCUACACAAAGUCUCUCACUAUCCUGCAUGGCAUUAGC		59
20075	MI0006097	smo-MIR1110	Selaginella moellendorffii miR1110 stem-loop	CAACACAGGGUUGCUAGGGGCAGUGGUCAAGGAUCUGGGGGCCCAUGUACUGCCUUCCAUGGGCUCCUAGGUCCUUGAGCGCUGCCCCCAGCAACCCU		59
20076	MI0006098	smo-MIR1111	Selaginella moellendorffii miR1111 stem-loop	UGCAACUGGCUUCCAUUGCUUAAUGUCUAUGUGACUUUAGAACCACUGCCGGAAAAGGUUGUCGAAGGUGUACAUAAUCACCACAACAGCCCGGUUUUGUUUGGUCAUGGCUAUGAAACAUCCCAGGAGGGCUAUGAAACAUCUUAGGAAGGUGCCUAUAUCCUGGUCCGACCAGGUCCUGGGAUGUUUCAUAGCCAUGACUAAGCAGGACCAGACUGUUGUGGUUAUGUCCACUUCUGAUGACAUUUUUUUGGCAGUGGUUUCAAAGUUACAUAGACGUUGAGCAGUGAAAGCCAGUUGUUGU	Axtell et al. report the alternative production of at least 2 miR/miR* duplexes from the MIR1111 hairpin [1].  The sequence of the most abundant clone is shown here. 	59
20077	MI0006099	smo-MIR1112	Selaginella moellendorffii miR1112 stem-loop	AUCUACAGGGACUUUGUUAUGGCAUUCCUCGCUCAACUGCUACAGGGACUGCAGCAGUGGAGCGAGGAAUGCUAUAACAAAGUCAUGAUUACUUU		59
20078	MI0006100	smo-MIR1113	Selaginella moellendorffii miR1113 stem-loop	CUUGUCUUUCUUGAGCAGUCAUAAGGUAGCCUUUGUGGAAAGCCCCAUUCGAUUCGUUCGUCUCAAUCAGCAUCAGCAGUAUGACGAUCUCUCGAUUCAGAGCAACAAAGUUCCUUGCAGGAAAACGAGAGAAAAAGAAGAAGUUGAAGUUGAAGAAGAAGCUUCAAAGUUCUUGUGGCAUUCUACAUGGACUGCCUUAUGACUGCUCAGCAGCAAGAUUC		59
20079	MI0006101	smo-MIR1114	Selaginella moellendorffii miR1114 stem-loop	AUUCCAUUCCUGCUCAAUGUUUUGUCACUUGGCUCGAUGUUUCAAAGUNUCAUCCUCGAGCCAAGGGACAAAACAUUGAGCAGGAAUGGAAUCGAUCCAGAUC		59
20080	MI0006102	smo-MIR1115	Selaginella moellendorffii miR1115 stem-loop	CCAGCAAGGUUGAGCUCAGGCACUUUGGUGGCCUGGGGGGCUAAGGUUAUUCAAAUAAUCUUAGCCCCUCAGGUCACCAAAGUGCCUGAGCUCAAGCUUGGGCU		59
20081	MI0006103	smo-MIR1103	Selaginella moellendorffii miR1103 stem-loop	GCCCAUGAACAAGAGUGCACCCCCUUUCCAAUCGGUUAAAGGUCUUAGGAUAGUUGGAGUUUAAGCGUCCUUGGGUUUGAAUAGUACUGGGCUGGGUGACCUCCCGGGAAGUCCAAAUUCAGGAGCUUACAUUAACCCCAAGUAUUCCAAAACGCUUAAUCGAUUGGAAAAAGGAGGUGCAUUCUUGUUCAUAGGCCC		59
20082	MI0006104	hiv1-mir-N367	Human immunodeficiency virus 1 miR-N367 stem-loop	UUGGCAGAAUUACACACCAGGGCCAGGGAUCAGAUAUCCACUGACCUUUGGAUGGUGCUUCAAGCUAGUA	Extensive studies in two labs have failed to confirm the existence of any viral miRNAs in HIV [3,4]. This sequence should be considered at risk of deletion from future releases of miRBase. 	60
20083	MI0006106	hiv1-mir-H1	Human immunodeficiency virus 1 miR-H1 stem-loop	UCCAGGGAGGCGUGCCUGGGCGGGACUGGGGAGUGGCGCCCUCAGAUCCUGCAUAUAAGCAGCGCUUUUUUCGGUGCGUUA	Extensive studies in two labs have failed to confirm the existence of any viral miRNAs in HIV [2,3]. This sequence should be considered at risk of deletion from future releases of miRBase. 	60
20084	MI0006112	rno-mir-466b-1	Rattus norvegicus miR-466b-1 stem-loop	CAUGUGUAUAUAUGUGUGUGUGUAUGUCCAUGUGUGUAUAUGAAUAUACAUACACACACACAUACACACACGUGCAAGCACACACA		8
20085	MI0006113	rno-mir-466b-2	Rattus norvegicus miR-466b-2 stem-loop	CAUGUGUGUAUAUGUGUGUGUGUAUGUCCAUGUGUGUAUAUGAUUAUACAUAUACAUACACACAUACACAUAUACGCAAGCA		8
20086	MI0006114	rno-mir-466c	Rattus norvegicus miR-466c stem-loop	CCUGUGUGUAUGUGAUGUGUGCAUGUACAUGUGUGUAUAUGGAGAAACAUAUACAUGCACACAUACACACACACAGGCA		8
20087	MI0006115	rno-mir-743b	Rattus norvegicus miR-743b stem-loop	UGCAGUGCUGUGUUCAGACUGGUGUCCAUCAUGUGAAAUAUUUGUGAAAGACACCAUACUGAAUAGAGUAAGGCUCA		8
20088	MI0006116	rno-mir-871	Rattus norvegicus miR-871 stem-loop	UGCAGUGCCCUAUUCAGAUUGGUGCCGGUCACAUGAAGUACAUAUGACUGGCACCAUACUGGAUAAUGUAAUGCUCA		8
20089	MI0006117	rno-mir-872	Rattus norvegicus miR-872 stem-loop	AACUUGUUAGAAGGUUACUUGUUAGUUCAGGACCUCAUUACUUUCUGCCUGAACUAUUGCAGUAGCCUCCUAACUGGUUAU		8
20090	MI0006118	rno-mir-874	Rattus norvegicus miR-874 stem-loop	UUAGCCCUGCGGCCCCACGCACCAGGGUAAGAGAGACUCGCUUCCUGCCCUGGCCCGAGGGACCGACUGGCUGGGC		8
20091	MI0006119	rno-mir-877	Rattus norvegicus miR-877 stem-loop	GUAGAGGAGAUGGCGCAGGGGACACAAGGUAGGCCUUGCGGGUCUGUGGGCCCUUGGACAUGUGUCCUCUUCUCCCUCCUCCCAG		8
20092	MI0006120	rno-mir-878	Rattus norvegicus miR-878 stem-loop	UGCAGUGCUUUAUCUAGUUGGCUGUCAGUCACGUGAAACUCAAGUGCAUGACACCAUACUGGGUAGAGGAGGGCUCA		8
20093	MI0006121	rno-mir-879	Rattus norvegicus miR-879 stem-loop	UUCUAGAUCCAGAGGCUUAUAGCUCUAAGCCUUGGAUAAAAGAGGCUUAUGGCUUCAAGCUUUCGGAGCUGGCGAC		8
20094	MI0006122	rno-mir-880	Rattus norvegicus miR-880 stem-loop	UGCACUGCAAUACUCAGAUUGGUAUGAGUCACUUCCUAAAACAUGUUACUCCAUUCAUUCUGAGUAGAGCAAGGCACA		8
20095	MI0006123	rno-mir-881	Rattus norvegicus miR-881 stem-loop	UGCAGUACAAUAUUCAGAGUGGUAGCAGUCACUUUAUUCUAAAGUAACUGUGGCAUUUCUGAAUAGAGUAAUGUUCA		8
20096	MI0006126	rno-mir-883	Rattus norvegicus miR-883 stem-loop	UGCACUCAAUGCUGAGAGAAGUAGCAGUUACUUUUUACUCUUAAGUAACUGCAACAUCUCUCAGUAUUGUAAGGCUC		8
20097	MI0006127	mmu-mir-582	Mus musculus miR-582 stem-loop	ACUCUUUGGAUACAGUUGUUCAACCAGUUACUAAUCUAACUAAUUGUAACCUGUUGAACAACUGAACCCAAAGGGUGCAAA		6
20098	MI0006128	mmu-mir-467e	Mus musculus miR-467e stem-loop	GCCUGUGUGCAUAAGUGUGAGCAUGUAUAUGUGUGUAUAUUUUAUGCAUAUACAUACACACACCUAUAUACACAUGCACACAGACAU		6
20099	MI0006130	rno-mir-147	Rattus norvegicus miR-147 stem-loop	UAUGAAUCUAGUGGAAACACUUCUGCACAAACUCGAUUUUGAUGCCAGUGUGCGGAAAUGCUUCUGCUACAUUUUUAGG		8
20100	MI0006131	rno-mir-17-2	Rattus norvegicus miR-17-2 stem-loop	UUGGCCAUGUCAAAGUGCUUACAGUGCAGGUAGCUUCUUGAGAUCUACUGCACUGCAAGCACUUCUUACAUUACCAUG		8
20101	MI0006132	rno-mir-181d	Rattus norvegicus miR-181d stem-loop	GGUCACAAUUAACAUUCAUUGUUGUCGGUGGGUUGUGAGGAGAAGACCAGACCCACCGGGGGAUGAAUGUCACUGUGGCUGGG		8
20102	MI0006133	rno-mir-182	Rattus norvegicus miR-182 stem-loop	UCCCACCGUUUUUGGCAAUGGUAGAACUCACACCGGUAAGGUACCGGGACCCGGUGGUUAUAGACUUGCCAACUAUGGUGUAAGU		8
20103	MI0006134	rno-mir-188	Rattus norvegicus miR-188 stem-loop	CCCUCUCUCACAUCCCUUGCAUGGUGGAGGGCGAGCUCUCUGAAAACUCCUCCCACAUGCAGGGUUUGCAGGAUGGUGAG		8
20104	MI0006135	rno-mir-190b	Rattus norvegicus miR-190b stem-loop	UGCUUCUGUGUGAUAUGUUUGAUAUUAGGUUGUUAAAUUAUGAACCAACUAAAUGUCAAACAUUCUCACAGCAGUGAG		8
20105	MI0006136	rno-mir-196c	Rattus norvegicus miR-196c stem-loop	CUGAGUGAAGUAGGUAGUUUCGUGUUGUUGGGCCUGGCUUUCUGAACACAACAACACCAAACCACCUGAUUCACUGCAGU		8
20106	MI0006137	rno-mir-301b	Rattus norvegicus miR-301b stem-loop	GCUGCGGGUGCUCUGACUAGGUUGCACUACUGUGCUGUGGAAAGCAGUGCAAUGGUAUUGUCAAAGCAUCUGGGACCA		8
20107	MI0006140	rno-mir-375	Rattus norvegicus miR-375 stem-loop	UCCGGCCCCGCGACGAGCCCCUCGCACAAACCGGACCUGAGCGUUUUGUUCGUUCGGCUCGCGUGAGGCAGGGGC		8
20108	MI0006141	rno-mir-380	Rattus norvegicus miR-380 stem-loop	ACCUGAAAAGAUGGUUGACCAUAGAACAUGCGCUACUUCUGUGUCGUAUGUAGUAUGGUCCACAUCUUCUCAUUAUC		8
20109	MI0006142	rno-mir-384	Rattus norvegicus miR-384 stem-loop	AAUCAGGAAUUGUAAACAAUUCCUAGGCAAUGUGUAUAAUGUUGGUAAGUCAUUCCUAGAAAUUGUUCACAAUGCCUGUAACA		8
20110	MI0006143	rno-mir-410	Rattus norvegicus miR-410 stem-loop	ACUUGAGGAGAGGUUGUCUGUGAUGAGUUCGCUUUAUUAAUGACGAAUAUAACACAGAUGGCCUGUUUUCAAUACC		8
20111	MI0006144	rno-mir-411	Rattus norvegicus miR-411 stem-loop	CUUGGAGAGAUAGUAGACCGUAUAGCGUACGCUUUAUCUGUGACGUAUGUAACACGGUCCACUAACCCUCAGUAUC		8
20112	MI0006145	rno-mir-423	Rattus norvegicus miR-423 stem-loop	GAAGUUAGGCUGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGUCUUGCUUCCU		8
20113	MI0006146	rno-mir-425	Rattus norvegicus miR-425 stem-loop	AGUGCUUUGGAAUGACACGAUCACUCCCGUUGAGUGGGCACCCAAGAAGCCAUCGGGAAUAUCGUGUCCGCCCAGUGCUCUUU		8
20114	MI0006147	rno-mir-434	Rattus norvegicus miR-434 stem-loop	GUUUGAACCACAGCUCGACUCAUGGUUUGAACCAUUGUCAAACUCGUGGUUUGAACCAUCACUCGACUCCUGGUUUGAAUC		8
20115	MI0006148	rno-mir-455	Rattus norvegicus miR-455 stem-loop	GGUGUGAGCGUAUGUGCCUUUGGACUACAUCGUGGACGCAGCACCAUGCAGUCCACGGGCAUAUACACUUGCCUCAAG		8
20116	MI0006149	rno-mir-463	Rattus norvegicus miR-463 stem-loop	ACCCUGUUUUACCUAAUUUGUUGUCCAUCAUGUAAAAUUUAAGUGAUGAUAGACGCCAAUUUGGGUAGAGGAAGGCUC		8
20117	MI0006150	rno-mir-471	Rattus norvegicus miR-471 stem-loop	AGCAGUGCUUUACGUAGUAUAGUGCUUUUCACAUUACACAAAAAGUGAAAGGUGCCAUACUAUGUACAGGAAGGCUUA		8
20118	MI0006151	rno-mir-484	Rattus norvegicus miR-484 stem-loop	GCAUGCAGGGAAGGGGGGGCGGGGCCUCGCGGCCCUGCUGCCUCGUCAGGCUCAGUCCCCUCCCGAUAAACCUCAAA		8
20119	MI0006152	rno-mir-495	Rattus norvegicus miR-495 stem-loop	UACCUGAAAAGAAGUUGCCCAUGUUAUUUUUCGCUUUUAUUUGUGACGAAACAAACAUGGUGCACUUCUUUUUCGAUAUC		8
20120	MI0006153	rno-mir-500	Rattus norvegicus miR-500 stem-loop	CCCCCUCUCUAAUCCUUGCUAUCUGGGUGCUUAGUGCUAUCUCAAUGCAAUGCACCUGGGCAAGGGUUCAGAGAAGGUGA		8
20121	MI0006154	rno-mir-532	Rattus norvegicus miR-532 stem-loop	UUUUCUCUUCCAUGCCUUGAGUGUAGGACUGUUGACAUCUUAAUUACCCUCCCACACCCAAGGCUUGCAGGAGAGCAAG		8
20122	MI0006155	rno-mir-598	Rattus norvegicus miR-598 stem-loop	GCUGAUGCUGGCGGUGAUGCCGAUGGUGCGAGCUGAAAAUGGGCUGCUACGUCAUCGUCGUCAUCGUUAUCAUCAUCAU		8
20123	MI0006156	rno-mir-671	Rattus norvegicus miR-671 stem-loop	CAGGAAGAGGAGGAAGCCCUGGAGGGGCUGGAGGUGAUGGAUGUUUUCCUCCGGUUCUCAGGGCUCCACCUCUUUCGAGCC		8
20124	MI0006157	rno-mir-672	Rattus norvegicus miR-672 stem-loop	CCUUUAGUUUUGAGGUUGGUGUACUGUGUGUGAGUAUACAUAUUUAUCACACACAGUCGCCAUCUUCGAAAGUGAGGGUG		8
20125	MI0006158	rno-mir-673	Rattus norvegicus miR-673 stem-loop	GCCUGAGGGGCUCACAGCUCCGGUCCUUGGAGCUCCAGAGAAAAUGUUGCUCCGGGACUGAGUUCUGUGCACCCCCCUUGCCC		8
20126	MI0006159	rno-mir-674	Rattus norvegicus miR-674 stem-loop	CCUGAGCCUUGCACUGAGAUGGGAGUGGUGUAAGGCUCAGGUAUGCACAGCUCCCAUCUCAGAACAAGGCUCGGGUG		8
20127	MI0006160	rno-mir-708	Rattus norvegicus miR-708 stem-loop	GACUGCCCUCAAGGAGCUUACAAUCUAGCUGGGGGUAGAUGACUUGCACUUGAACACAACUAGACUGUGAGCUUCUAGAGGGCAGGGG		8
20128	MI0006161	rno-mir-742	Rattus norvegicus miR-742 stem-loop	GGCAGUGCUUUACUCACAUGGUUGCUAAUCACGUGAAAUGUAAGUGAAAGCCACCAUGUUGGGUAAAGUAAAGCUCA		8
20129	MI0006162	rno-mir-743a	Rattus norvegicus miR-743a stem-loop	UGCAGUGCUGUAUUCAGAUUGGUGCCUGUCAUGUUUAUAAGAAUGAAAGACGCCAAACUGGGUAGAGUGGAGCUCA		8
20130	MI0006163	rno-mir-758	Rattus norvegicus miR-758 stem-loop	GGUGCGUGAGGUGGUUGACCAGAGAGCACACGCUAUAUUUGUGCCGUUUGUGACCUGGUCCACUAACCCUCAGUAUCU		8
20131	MI0006164	rno-mir-760	Rattus norvegicus miR-760 stem-loop	GGCGCGUCGCCCCCCUCAGGCCACCAGAGCCCGGAUACCUCAGAAAUUCGGCUCUGGGUCUGUGGGGAGCGAAAUGCAAC		8
20132	MI0006165	rno-mir-770	Rattus norvegicus miR-770 stem-loop	CUGUGCCCCCAGCACCACGUGUCUGGGCCACGUGAGCAACGCCACGUGGGCCUGACGUGGAGCUGGGGCCGCAGGG		8
20133	MI0006166	rno-mir-873	Rattus norvegicus miR-873 stem-loop	GUGUGCAUUUGCAGGAACUUGUGAGUCUCCUAUUGAAAAUGGACAGGAGACUGACAAGUUCCCGGGAACACCCACAA		8
20134	MI0006167	rno-mir-92b	Rattus norvegicus miR-92b stem-loop	GGUGGGCAGGAGGGACGGGACGCGGUGCAGUGUUGUUCUUUCCCCUGCCAAUAUUGCACUCGUCCCGGCCUCCGGCCCCCUCG		8
20135	MI0006168	rno-mir-488	Rattus norvegicus miR-488 stem-loop	AAUCCUCUCUCCCAGAUAAUGGCACUCUCAAACAAGUUUCUACAUUGUUUGAAAGGCUGUUUCUUGGUCAGAAGACUCU	The predominant miRNA cloned by Landgraf et al. has a 3' additional U residue, which is incompatible with the genome sequence [1]. 	8
20136	MI0006169	rno-mir-652	Rattus norvegicus miR-652 stem-loop	AUGCACUGCACAACCCUAGGAGGGGGUGCCAUUCACAUAGACUAUAAUUGAAUGGCGCCACUAGGGUUGUGCAGUGUACAA	The predominant miRNA cloned by Landgraf et al. has a 3' additional U residue, which is incompatible with the genome sequence [1]. 	8
20137	MI0006170	tae-MIR159a	Triticum aestivum miR159a stem-loop	GUGGAGCUCCUAUCAUUCCAAUGAAGGGUCUACCGGAAGGGUUUGUGCAGCUGCUCGUUCAUGGUUCCCACUAUCCUAUCUCCAUAGAAAACGAGGAGAGAGGCCUGUGGUUUGCAUGACCGAGGAGCCGCUUCGAUCCCUCGCUGACCGCUGUUUGGAUUGAAGGGAGCUCUGCAU		61
20138	MI0006171	tae-MIR159b	Triticum aestivum miR159b stem-loop	GAGCUCCUUUCGGUCCAAAAAGGGGUGUUGCUGUGGGUCGAUUGAGCUGCUGGGUCAUGGAUCCCGUUAGCCUACUCCAUGUUCAUCAUUCAGCUCGAGAUCUGAAAGAAACUACUCCAAUUUAUACUAAUAGUAUGUGUGUAGAUAGGAAAAUGAUGGAGUACUCGUUGUUGGGAUAGGCUUAUGGCUUGCAUGCCCCAGGAGCUGCAUCAACCCUACAUGGACCCUCUUUGGAUUGAAGGGAGCUCUGCAUCU		61
20139	MI0006172	tae-MIR160	Triticum aestivum miR160 stem-loop	AGAGGUGAAAACAAUGGGAUAUGCCUGGCUCCCUGUAUGCCACUCGCGUAGCUGCCAACUCCCCAAACCUUGCGUUGGCUCUACCGCGGAUGGCGUGCGAGGAGCCAAGCAUGACCGUCUCUCUCUCUCUCUCUCUCUCUCUCUCUCU		61
20140	MI0006173	tae-MIR164	Triticum aestivum miR164 stem-loop	GGUGGAGAAGCAGGGCACGUGCAUCCAUUUCCAGCUCGGCAUUCCCGGCGUCCGGCCGGCCGGCUGCCGCGGCCUUGCCUGGCUGGGUAGUGCGUCGCUCGAUCCGGCCGUGCGCCGGCGGCCGGCCCUUGCAUGCAUGUGCCUUUCUUCUCCACC	The mature sequence cloned in [1] has a U residue at position 14, which is incompatible with the EST assembly and the hairpin shown here. 	61
20141	MI0006174	tae-MIR167	Triticum aestivum miR167 stem-loop	CUGCCCAAGGGAACGAGUGAAGCUGCCAGCAUGAUCUAGCUCCGAGUGAUCAAACAAGAAACGCUGCGGCAGCCUCACUUCUUCCCGCCGUUGGGCACAACUACUUCU		61
20142	MI0006175	tae-MIR171	Triticum aestivum miR171 stem-loop	UGGAAUGGUCACUAUGAUGUUGGCUCGACUCACUCAGACCACGCCUGCCGGCCGGCCGUAGCCAUGCAUCUGCAUGCGGUGGUGGCUCUGAUUGAGCCGUGCCAAUAUCUCAGUGCUCUUUCAUGCAUGC		61
20143	MI0006176	tae-MIR399	Triticum aestivum miR399 stem-loop	UCGUGUGUGAAUCACAGGGCGCUUCUCCCUUGGCACGGUGGCAUGCAUGUACAUAUGAUGGUGGUAGCCUGGUGAGCGUGCGGUGCAGCUUGCUAGCAAGCCGUGCGUGCCAAAGGAGAAUUGCCC		61
20144	MI0006177	tae-MIR408	Triticum aestivum miR408 stem-loop	AUUUUGUGAGUGGAGAGGGGGGAGGAGACAGGGAUGGAGCAGAGCAAGGGAUGAGGCAAGCAACAAAAUUUACCACCUGAUUAUGAGAAGAGGGAGAGAGUUGCCAGAGCUUCUGUUGCUGUUGUUGCUCCCUCCCUGCACUGCCUCUUCCCUGGCUCCCCUCCCAAAUCUCUCCCUCCCCCUCUCU		61
20145	MI0006178	tae-MIR444	Triticum aestivum miR444 stem-loop	GACUCGAGAUAUGCAUGUGGCGGCACCGAGCAUGAGGCAACAACUGCAUUACUUGCGGGGAAGGCGCAAGUAGGACACCUGCAUUACUUGCAAACAAGGCGCAAAAUUAAUAGAAGAUCACCAUACUUGUGGCUUUCUUGCAAGUCAUGCAGUUGCUGCCUCAAGCUUGCUGCCUCCCUUUGCCAAAGCUAUCAGAAAAAACAUAAAGUUCUGUUAGUUUCCCUAAACUUUAAAAACAUAAAGUUCUGUUAGUUUCCCUAAACUUUAAAACAUGUUCUACAAAAUUGAUCUAGAAAUGAUUGGCUUACUGUGCUAAUUUAAAGCAAUAUAAUUACUCGACAACUGCAUAUGCACAUGUUAGAAGCAAGGCAGUAGAAUACUUAUGUUUUCAUCUACUGGCAGGUAGCAACAUGUAUAGAUAUAUCA		61
20146	MI0006179	tae-MIR1117	Triticum aestivum miR1117 stem-loop	GUUUGAAAAUGGGACCUUUAGUACCGGUUCGUGGCACGAACCGGGACUAAAGGUCUUCAACCCCAUUAGUUCCGGUUCGUGCCACAAACCGCGACUAAAAGGGAGGAGCUUUAGUCGC	Yao et al. misname this sequence miR501 in [1].  miR1117 is unrelated to mammalian miR-501; 	61
20147	MI0006180	tae-MIR1118	Triticum aestivum miR1118 stem-loop	GAAGCACGUGGAUAGAGGAAGCACUACAUUAUGGAAUGGAGGGAGUAUGUUGUAGGCAAUGAUUGUUUGCCUUGAAGAUUUUAUAGAUCCUGCUCUGGUCUUUCUGAUUUUGUCUGUUCCUUUUUUUUAUGUUUGGUUCG	Yao et al. misname this sequence miR502 in [1].  miR1118 is unrelated to mammalian miR-502; 	61
20148	MI0006181	tae-MIR1119	Triticum aestivum miR1119 stem-loop	AGCGUCAGCGUGUGAUGCGCCAGCGCGCGCGGAGGAGGAGCUGGCUGGGUCAGCGUCGACGGCGGCGGCCGUGUGCUCCUACGUGGCACGGCGUGAUGCUGAGUCAGCCAGUGGAGUGGUGCUACUUUUUACUAGGUGUGGAGUGGGGAGUGCUAUGCGCGGGGUCGCGUGACGUGG	Yao et al. misname this sequence miR503 in [1].  miR1119 is unrelated to mammalian miR-503; 	61
20149	MI0006182	tae-MIR1120	Triticum aestivum miR1120 stem-loop	GCGGCCGCCCGGGCAGGUACUCCCUCCGUCCCAUAAUAUAAGAACAUUUUUGACAGUGUAGUGUCAAAAACAUUCUUAUAUUAUGAGACGGAGGGAGUAUUUCCCAGCUCCUGAAUCAC	Yao et al. misname this sequence miR504 in [1].  miR1120 is unrelated to mammalian miR-504; 	61
20150	MI0006183	tae-MIR1121	Triticum aestivum miR1121 stem-loop	UAUAUAUGUACUCCCUCUGUAAAGAAAUAUUAGAGUGUUUAGAUCACUUAAGUAGUGAUCUAAACGCUCUUAUAUUUCUUUACGGAGGGAGUACUGUA	Yao et al. misname this sequence miR505 in [1].  miR1121 is unrelated to mammalian miR-505; 	61
20151	MI0006184	tae-MIR1122	Triticum aestivum miR1122 stem-loop	AUAAGUACUCCCUCUGUUCCUAAAUACUCCCUCCGUCCCAAAAAUUUUGGCUUAGAUUUGUCUAAAUACGUAUGUAUCAAGUCAUGUUUUAGUAUUAGAUACAUCCGUAUCUAGACUAAUCUAAGACAAGAAUUUUGGGACGGAGGGAGUAUAAGUCUUUUUAGAGAUUCCACUACAAACUACAUACGGAUGUAUAUAGACAUAUUUUAGAGUGUAGAUUCACUCAUUUUACUUCGUAUGUAGUCCAUAGUGGAAUCUCUAAGAAGGCAUAUAUUUAGGAACAGAGGGUGUACCA	Yao et al. misname this sequence miR506 in [1].  miR1122 is unrelated to mammalian miR-506; 	61
20152	MI0006185	tae-MIR1123	Triticum aestivum miR1123 stem-loop	AAAAAAAUUAUAUGAGACCAGGUCUCAUAUAAAUCAGGUGAGACCCGCCCUGAUGAAUGACAUGUGGAAUUCACAAAUCACAAAGCAUCUAAUCUCUCCCCCCCUGAUUUCAGGUGGGGGGUGGGGUGGAUGCUUUGUGAUUUGUGAAUGACACGUGUCAUCCAUCAGGAUGGGUCUCACCUGCUAAUCCGUGAGACCUGGUCUCAUAGAAUUUUUUU	Yao et al. misname this sequence miR507 in [1].  miR1123 is unrelated to mammalian miR-507; 	61
20153	MI0006186	tae-MIR1124	Triticum aestivum miR1124 stem-loop	AUUACAUGACUCAAAGGAACGGCCCUGGGAGCUCGAUCCUUCUCACAUCCCGCCACGCCAUUGUCGCGUCCAUCCCCACGACGCAGGACGUGAAGAGCGAGUCCAAGGCCGGAAGCUAGACUCGGUACU	Yao et al. misname this sequence miR508 in [1].  miR1124 is unrelated to mammalian miR-508; 	61
20154	MI0006187	tae-MIR1125	Triticum aestivum miR1125 stem-loop	UUUGGCCGUAAAUUUAACCAACGAGACCAACUGCGGCGGGAACAAAAAUUAUAUCGCUGAAUUAUAUCAAAAAUACNAAUUCAGUAGCAUAGGUUUUGCUCCCGCCACAUUCGGUCUUGUUGGUUAAAUUUACGGUCAAA	Yao et al. misname this sequence miR509 in [1].  miR1125 is unrelated to mammalian miR-509; 	61
20155	MI0006188	tae-MIR1126	Triticum aestivum miR1126 stem-loop	GUACUCUCUCCGUUCCUAAAUAUAAGUCUUUAUAGAAAUUCCACUAUGGACUACAUACGGAGCAAAAUAAAUGAAUCUACACUCUAAAAUGCAUCUACAUACAUUCGUAUGUGGUUCAUAGUAAAAUCUCUACAAAGACUUAUAUUUAGAAACGGAGGGAGUAU	Yao et al. misname this sequence miR510 in [1].  miR1126 is unrelated to mammalian miR-510; 	61
20156	MI0006189	tae-MIR1127	Triticum aestivum miR1127 stem-loop	ACAUUAGAUGUACUCAACUACUCCUUCCGUUCGGAAUUACUCGUCCAAGAAAUAAAUGUAUCUAAAUGCAUUUUAGUUGUAGAUACAUCCAUUUUUAUCAUUUUUGUGACAAGUAAUUCCGAACGGAGGGAGUAUAUUCUAAUGUGGAUC	Yao et al. misname this sequence miR511 in [1].  miR1127 is unrelated to mammalian miR-511; 	61
20157	MI0006190	tae-MIR1128	Triticum aestivum miR1128 stem-loop	AUAUGAGAGCAUGGGUGAGAGGUGCUUAGUUACUACUCCCUCCGUCCGAAAAUACUUGUCAUCAAAAUGAAUAAAAGGGGAUGUAUCUAGAACUAAAAUACAUCUAGAUACAUCCCCUUCUAUCCAUUUUGAUGACAACUAUUUCCGGACGGAGGGAGUAAUUGCUUCUUCUGGCUUGGCGUUUAUGU	Yao et al. misname this sequence miR512 in [1].  miR1128 is unrelated to mammalian miR-512; 	61
20158	MI0006191	tae-MIR1129	Triticum aestivum miR1129 stem-loop	CGGCCGCCAUUCAGCCANAAGAAGCAGCGAGCCAGCGGAGACCGGCAGCCAACCAAGGGCGUCGUCGCUCCACCAUGGAAUCAGCUGCUGAUAUGCUCGAACACGACCUGCAAGCUUCAUGUAUCUGCAACACCCCUGCUCCUCAUCCACGACCCAAGUGACCUGAAAGAGCAAGCUGCUGCAGAGGGCAAUCCUCGAUAUCUAAGAAGACCUCGGGCUUAUUAGGGGAAGAGAGCUCGUGCCAGAUCCACUCCCAACUGCCUCCGUCCACCAUGGACGA	Yao et al. misname this sequence miR513 in [1].  miR1129 is unrelated to mammalian miR-513; 	61
20159	MI0006192	tae-MIR1130	Triticum aestivum miR1130 stem-loop	AAAUGUCUUAUACUCCCUCCGUCUCGUAAUGUAAGACGUUUUUAUAAGCUAUGUUAGUCUGUAAAAAAAAGUCUUUGCAAAAACGUCUUACAUUAUGGGACGGAGUGGUAGUAUUUGCAACG	Yao et al. misname this sequence miR514 in [1].  miR1130 is unrelated to mammalian miR-514; 	61
20160	MI0006193	tae-MIR1131	Triticum aestivum miR1131 stem-loop	CAUUAGUACCGGUUCGUGGCUAACCUUUAGCACCGGUUCGUGCCAGGAACCGGUACUAAUGAGGGUGGUGGCAGGAUGUUGUCAGUCUGGGCCCCCUCCA	Yao et al. misname this sequence miR515 in [1].  miR1131 is unrelated to mammalian miR-515; 	61
20161	MI0006194	tae-MIR1132	Triticum aestivum miR1132 stem-loop	UACUCCCUCCGUUUCACAAUGUAAGUCAUUCUAGCAUUUUCCACAUUCAUAUAGGUGUUAAUGAAUCUAGACAUCUAUAUAUAUCUAGAUUCAUUAACACCUAUAUGAAUGUGGGAAAUGUUAGAAUGACUUACAUUAUGGAACGGAAGGAGUA	Yao et al. misname this sequence miR516 in [1].  miR1132 is unrelated to mammalian miR-516; 	61
20162	MI0006195	tae-MIR1133	Triticum aestivum miR1133 stem-loop	ACUUCUUAGUGAUAGUGGUCAAUUACAUCAUAUACUCCCUCCGUCCGAAAAAGUUUGUCCCAAGCUUGUUCCUCAAAUGGAUGUAUCUAGCACUAACUUGAUGCUACAUACAUUCAUUUGAGGGACACGCUUUUUCGGAUGGAGGGAGUAGUAAUUUUGAUAUACACACUGAAGUUGCUA	Yao et al. misname this sequence miR517 in [1].  miR1133 is unrelated to mammalian miR-517; 	61
20163	MI0006196	tae-MIR1134	Triticum aestivum miR1134 stem-loop	CCACGCGUCCGGCAUUCUUCUUCUUCUUGUUGUUGUUGUUGUAAUGGAUUUGGAGGAGGAGGAGGAGGAGGAGCUGCUGUUGAUGCUCCUAGUACAACAAAUAAGGAGGCGGCGGAGGAGGAGCAACAACAACAAGAAGAAGAAGAUUUGGGCUUGAAGCUGCAGCUGCAACAACAUGUA	Yao et al. misname this sequence miR518 in [1].  miR1134 is unrelated to mammalian miR-518; 	61
20164	MI0006197	tae-MIR1135	Triticum aestivum miR1135 stem-loop	CUACUCCCUCCAUUCGGAAUUACUUGUCUCGGAUAUGGAUGUAUCUAGAACUAAAAUACGUCUAGAUACAUCUAUUUCUGCGACAAGUAAUUCCGAACGGAGGGAGUAG	Yao et al. misname this sequence miR519 in [1].  miR1135 is unrelated to mammalian miR-519; 	61
20165	MI0006198	tae-MIR1136	Triticum aestivum miR1136 stem-loop	UACUCCCUCCGUUCCGAAUUACUUGUCGCAGGUAUGGAUGUAUCUAGAUGUAUUUUAGUUCUAAAUACAUCCAUUUCUGCGACGAGUAAUUUGAAACGGAGGGAGUA	Yao et al. misname this sequence miR520 in [1].  miR1136 is unrelated to mammalian miR-520; 	61
20166	MI0006199	tae-MIR1137	Triticum aestivum miR1137 stem-loop	CACGAUGACGACGAUUACAUAGCCUUGUACUCCCUCCGUUCCAAAAUGGAUGACCCAAGUUUGUACUAAAGUUAGUACAAAGUUGAGUCAUCUAUUCUGGAACGGAGGGAGUAGUAGUAAUACAACGUUGCUAGUGAUAAGGAAAAUC	Yao et al. misname this sequence miR521 in [1].  miR1137 is unrelated to mammalian miR-521; 	61
20167	MI0006200	tae-MIR1138	Triticum aestivum miR1138 stem-loop	AUCUUGUAUAGGUCUGUCUAGGACACAUCUAAAUGUGACAUAACUAUGUCACAUCUAAGCUGAUGUCAACUCUGUUUGUGGUCUAUUUUUUUUAUCCUAGUUUUUUUAUUUCUUAUUGCUACAUUAUAUAUUUGUAGGAGCUUAGAUGUGACAUCCUUAAAAACAUCUAGAUGUGAAUUAAACAAACUGAUCUU	Yao et al. misname this sequence miR522 in [1].  miR1138 is unrelated to mammalian miR-522; 	61
20168	MI0006201	tae-MIR1139	Triticum aestivum miR1139 stem-loop	GCCACAGUGGAGAGUAACAUACACUAGUAACAUACACAUAUCCCUAGAACUAUAUAACUACCUUCAUAGKGGUAGCAACAUAAGUGUGGUAUCAUGCAAAGCUUCAUUUAUUAGGUUAUAGACUCAUAUUGCAUUGGGACAUGUGAUGUUAUAGUAACUAGCUAAGUUACUCAAACUACCUCUCUCCUCGAUGUUACUAUUGAAGUUACUCCCACU	Yao et al. misname this sequence miR523 in [1].  miR1139 is unrelated to mammalian miR-523; 	61
20169	MI0006202	ppt-MIR477b	Physcomitrella patens miR477b stem-loop	AUGUGUUGGAACUUGGGAAGCAGGUGCUUGAUCCUCUCCCUCAAAGGCUUCCAACAGCAUGAGCUAGUUUUAGUGUCUCAAAUAUUGUCUGUUGAGGCUAGCUCCUGUUCAGAUCUGUUAGAAGCCUCUGUGGGAGAGGAGCAAUCAGCUGCUGAGUGGCACCUCUGAUC		40
20170	MI0006203	cre-MIR1142	Chlamydomonas reinhardtii miR1142 stem-loop	CGUGGCAGGGGUCAAGGUGUGGAUGCGGCAUGGGUGGCUAACCCCGCCCAUGCCCAGACCACGCUCCAGCCCCUGCCCCG		53
20171	MI0006204	cre-MIR1143	Chlamydomonas reinhardtii miR1143 stem-loop	AGGACGUCCCCUUACGGGAAUAUAAAUAUUAGUGGCAGUGGUACCGCCACUGCCUAUAUUUAUAUACUCCGAAGGAACUUGUUAGCCGAUAGGCGAGGCAACAAAUUUAUUUAUUGUAUAUAAAUAUCCACUAAAAUUUAUUUGCCCGAAGGGGACGUCCU		53
20172	MI0006205	cre-MIR1144a	Chlamydomonas reinhardtii miR1144a stem-loop	CGGCGGCGUUGGACUGCUGGGGUGCAGCAGGCUUGGAACCGGGCACGCAGGAGGUGGGUUUUGUGGCGGCAGGNAGCAGGCAGCGCGGGGCUGCUGGUGGUGGUGGAGGAGGAUGAAGUUCGCCAUUCAAACAACCCUUUCUGCACCGGUCCUGUGCUGCCCGUUGCCUGCAGGAGCAAAACACACCCACUCCGUGUCCGGCUCCAAGAUUGCUGAACCCCUGUCGCUGGCUGCUGCCG	The predominant product from this hairpin precursor is named cre-miR1144a.1 here [1]. 	53
20173	MI0006206	cre-MIR1145	Chlamydomonas reinhardtii miR1145 stem-loop	CCCAACGUGGAAGGGCAUGACCUCCUCCCUUCUGCAGACCUAGGUCAGAAGGACCAGGACCUGCUGGGCCCCAAGGUCAUGGUCGCAAUGCUGGUCAACGCCACCGAGAGGGUCAACACCACCCAGCAGCUCUGGGCGGACAUCAAGCAGAAGACGUCCUCCAGCGGGAGGCCGUCUUCUGCUUGAUGUCCGCCCACAGCUGCUGAUUGGCGUUGACCCUGUCGGUGGCCUUGACCAGCAUCGCGGCAAUGACCUUGGGGCCCAGCAGGUCCUGGUCCUUCUGACCAAGGUCUGCACAAGGGAGGAGGUCAUGAGUCCACGUGGG	Molner et al. identified several expressed products from this hairpin locus -- the predominant 2 are shown [1]. 	53
20174	MI0006207	cre-MIR1146	Chlamydomonas reinhardtii miR1146 stem-loop	AUGGGUCCGAUCGGGAAGCUUUAUCACACUCGGCGUAUGAACAACAAGCUUCCCACAUGGGGCCCA		53
20175	MI0006208	cre-MIR1147	Chlamydomonas reinhardtii miR1147 stem-loop	GCCAUAAUUAGUGCCAGCGCGCUCUCGGCCAAGUCUGGCAGAAGCGGAGGAGCCGCCGCUGCCAGACUUGGCCGAGAACGCGCUGGCACUAAUUGGGGC		53
20176	MI0006209	cre-MIR1148	Chlamydomonas reinhardtii miR1148 stem-loop	CAGGGACUGUUUACCAACGUGCAGGGGGACAUGGUGGAGAUCCUCCUGUCCGGCUACCUGGAGCGCAAGCUGGGCGAGAGGUUUUAGCCAGACAGGAGGAUCUCCNCUAAGUCCCCCUGCACGUUGGUAAACAGUCCCUG		53
20177	MI0006210	cre-MIR1149	Chlamydomonas reinhardtii miR1149 stem-loop	CGACCGCCUCGGGCCCGCUAUGUCGGACAACACCGACCCCCAGCCCGCCAACAAGGAGAUGGCGUUGGCGGGCUGGGGUCGGUGUUGUCUGACAUGGAGGGUCCCAGGCAGUCG		53
20178	MI0006211	cre-MIR1150	Chlamydomonas reinhardtii miR1150 stem-loop	GGACGCGCAGCGGAGCAGAUCCCCGUCAUACCCCGCUUGGUGCAGCGCGUCAAUAUCCCUCUUGGCGAGCUUCGCAAAUAGAGUCGGCCCCAGUUUCCGCUGCAGCUGGGCUUCGUGCUUCCAGCUUCCUGCACGGCUCGCCGUCCGAGCGCCUUGCUUGCCGCCCGAUACGCAGUUCGGAUUCGUAUACGCAUAUCGAACUCAAUCCGAGUCGCGUAUCAUCGGGUGGCAAGGAAGGCGCUGGAAGCCUCUGACAGCGAGCCAUGCAGGAAGCUGAAAGCCUGAAAGCCCACCUGCAGCGGCGACUGGGGCCGACCCUGUUUGCAAAGCUCGCCGAGAGGGACAUUGAUGCGCUGCACCAAGCGGGGUAUGACGGGGAUACGCUCCGCUUCGCGUCC	Molner et al. identified a number of offset and overlapping mature miRNA products frmo this hairpin precursor [1].  The predominant ones are named and shown here. 	53
20179	MI0006212	cre-MIR1151a	Chlamydomonas reinhardtii miR1151a stem-loop	CCGGCCGCGGCAGUCCGGGGCUCAUAACCUGUUGACGCGCGCAGCCCGCGGGCAGUCCCUGCGGGCCGCGCGGCGCUAACGGGGUGUGGGACCCGGACUGACGCGGCCGG		53
20180	MI0006213	cre-MIR1151b	Chlamydomonas reinhardtii miR1151b stem-loop	GUGGUGUGUGCCGCUCACCGGCCACGGCAGUCCGGGGCUCAUAACCUGUUAACGCGCGCAGCCCGCAGGCAGUCCCUGCGGGCCGCGCGGUGCUAACGGGUUGUGGGACCCGGACUGACGCGGCUGGCAUGUGACAGGCCCCAC		53
20181	MI0006214	cre-MIR1152	Chlamydomonas reinhardtii miR1152 stem-loop	GGGGGUAUUCACGGCACCGUCAAGACGGCGCACCUUCUUAACGUCCUUCGGUGCUUGCUUGCACACACUCAAGCAGGCACCGAAGGGCGUUAAGAAGGUGCGCUGUCUUGACGGUGCCGUGAAUACCUUC		53
20182	MI0006215	cre-MIR1153	Chlamydomonas reinhardtii miR1153 stem-loop	CAAAUGGGCCAUCGUAUUACUAUCAGUGCUGCUAGCAACUACAAGGCGGGCAUGAAGGUCGAUUUGAUCCGAUCGACCUUCAUGACCGCCUUGUAAUUGCCGGUAGCACUGAUUGUAAUGCGAUGGCUCAUUUG	Molner et al. identify two miR/miR* pairs from the same hairpin precursor [1]. 	53
20183	MI0006216	cre-MIR1154	Chlamydomonas reinhardtii miR1154 stem-loop	UGUAAUGCGGGAAAAUGGUAACUUAGUCAUCCCAAGGCGUGUAUCACCCAUGUUACGGGCGACCUGUAACACGGGUGAUACACGCCUUGUGACGACUAAGUUACCAUUUUCCCUCGUUACA		53
20184	MI0006217	cre-MIR1155	Chlamydomonas reinhardtii miR1155 stem-loop	UGAGGCUCGUUCCUCAAGCAGGACUCAAAGAACCCGAUCAGCUUGUCGAGCACGACAAGGUGAUCGUGUUUUCUUAGUCCUGCACGAGGAAGGAGCCCCA		53
20185	MI0006218	cre-MIR1156	Chlamydomonas reinhardtii miR1156 stem-loop	UCUGAUCUGCCUGAAGCUCCAGUUGAAACCUGGCAAGGUCGUGUGCCCUCUCCACCGACAUGCGAGGGUCCACCGCCGUGUGGCACAGGCUACCAUGGUAGCCAGUCUGCGCACCUGCAGCCAGCAGCUGAAUUCAUCAGCUGUCGGCUGCAGGUGCGCAGACUGGCUACCUUCGAAGCCUGGGCCUCACGGCGGUGGACCCUCGCAUGUCCGUGAAGGGGGCUCAUGACCCUACCCAGUUUCAGCUGGAGCUUCAGGCACAUCAGA		53
20186	MI0006219	cre-MIR1157	Chlamydomonas reinhardtii miR1157 stem-loop	UCCUGGGCGCAGUGUUCCAGCUGCAGUACACCUGGUCCCGCUAUUUGAAUCUCGCUGAUCGGCACCAUGGGGGUGGUGGUGAUCAGCGCUAUUCAGGUAGCGGGACCAGGUGUACUGCAGCCGGAACACUGCCAGGA		53
20187	MI0006220	cre-MIR1158	Chlamydomonas reinhardtii miR1158 stem-loop	GGCGUGCGCAGCGGCGGCCGCCGCGGCUGAGGAAGCCAUGAUCGAGGCAGCGCAGGCCACAUUGUAGGCCUGCCGCGCGGCUGUGUCACCUCUGACCAGGUGCGACGGGAAGCCGGGCUGCUGGGGCUGCUGCUGACCGCCAGUAGCCUCCUCCACGUCUUGUGCUAGCUCCGCAAGCACCGCGUCCUCUAUGUCCGUCAUGUCGGACUCGGCGUCGGAGCCAGGGCCCUCGGCUCGAGCAUCAGUCGUCCGCGCUGCUGCUGAGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCGACAUGACGGAUAUUGAGGACGCGGUGCUUGCGGAGCUAGCAGAGGACUUGGAGGAGGCCACUGGCGGUCAGCAGCAGCCCCAGCAGCCCAGCUUCCCGUCGCACCUGGUCAGCGGUGCGACAGCCGCGCGGCAAGCAUACAACGUGGCCUGCGCUGCCUCCAUCAUGGCUUCCUCAGCCGCGGCGGCCGCCGGCUUCGAGAGCC	Molner et al. cloned a number of minor products (cloned only once) from the loop end of this hairpin precursor (not shown) [1]. 	53
20188	MI0006221	cre-MIR1160	Chlamydomonas reinhardtii miR1160 stem-loop	UUUGCAUGCUCUCGCCCGCUACACAAACACGAAUGCUCAAACGCUCCCUUCCCGCACGGGUCCUUCCGGCUGCGCCGGUCAAGCCUGCCCUGCUUAAAAAGGGCAAAGUUCGGGCUGACAAGGAAGCAGAGCGGAUCCUCCAGAGCCUCACAGACCUCAAGAAGGUCGGGUUCACAAGCAAAUGACGCCUGCUUAACCAGGUCGUUGCCGCCGGAAAAGUCGUCAGCAGCGUGGCAGCCUGCUUAGCAGGCGUCAUUUGCUUGUGAACCCGACCUUCUUGAGGUCUGUGAGGCUCUGGAGGAUCCGCUCUGCUUCCUUGUCAGCCCGAACUUUGCCCUUUUUAAGCAGGGCAGGCUUGACCGGCGCAGCCGGAAGGACCCGUGCGGGAAGGGAGCGUUUGAGCAUUCGUGUUUGUGUAGCGGGCGAGAGCAUGCAGA		53
20189	MI0006222	cre-MIR1161	Chlamydomonas reinhardtii miR1161 stem-loop	GCCAGGUGACACCACACACCUACUGGAGUUCUCAACAGCUAGGUGACACCACACACCUACUGGAGUUCUCAACAGCUAGGUUUGGUUUGGU		53
20190	MI0006223	cre-MIR1162	Chlamydomonas reinhardtii miR1162 stem-loop	GCGGGGCCCUGACACCACUGCGGCCGCCGGCCUAAAUUACUACAACACGCCGCGCCUGGACCCGAGGGAGGACCCCUCGGGACCCGGUACGUCGUGUUGUAGUAGUUUAGCCCUGCGGUCGCGGUGGGGUCAGGUCCUUCCGC		53
20191	MI0006224	cre-MIR1163	Chlamydomonas reinhardtii miR1163 stem-loop	AUUGACAACGCGCCCGAGCGCCGGCGCACCGGCAAGAACAAGGACAAGUAUGAGAUGCUGCCGUACCCCGGCAACACGCUCAUGGAUGAGGCUGACCUGAAGGGCAUGCUGCGUGCCAUGGCGCCCUUCAUCGUGCGCGCAUAGGGUCUUAACUGCCAGGUUGAAGUCGCACACGCGGAAGACCUUGCUGCCAUCAGGCGCGAUGUCGUACAGCAGGUUGGCGGGCUUCAGGUCAAAGUGCAUGUAGCCGCGAGCGUUCAGGUGCUUUGAUGAAGAGCGCCAUGGCACGCAGCAUGCCCUUCAGGUCGGCCUCAUCCAUAAGCGUGUUGCCGGGGUACGGCAGCAUCUCAAACUUGUCCUUGUUCUUGCCGGUGCGCCGGCGCUCGGGCGCGUUGUCAAU		53
20192	MI0006225	cre-MIR1164	Chlamydomonas reinhardtii miR1164 stem-loop	GGUGCUCUUCUGGUGCAACAGGCCAGUGGUUUGAGUGGUGGUCGACGGCAAUUGCUUCAGUCUUACUUGCUUGGCUUACGUACGUACGCCUCAAGCAAGUAAGACUGAAGCAAUUGCUGCCGACCACCGAUCAAACCACUGGCCUGUUGCACCAGCAGAGCACU		53
20193	MI0006226	cre-MIR1165	Chlamydomonas reinhardtii miR1165 stem-loop	GCACUAUACCGUACAAGCGGUCCGUCCUGCGCCCCAUCCUGCGUUUGAAAACGCANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCAGGACGGACCGCUUGUACGGAUAUGGCGC		53
20194	MI0006227	cre-MIR1166	Chlamydomonas reinhardtii miR1166 stem-loop	GCAACCACGCCGCGCCCUGCCGGUCCCCCACAGUGUAUGACUCCUUUUACCGCUACGAGGAUGGACUAGACAACCCACGCACCGCCUGGUGCCGCCGACUCUGCGCCGGGCCCAUGAGGUCAUGGACCUCGCGGCCCUGGAGGCCCUGGUAGCCGCCGCGCCAUGCCAGGCCGUCAGCGCGCCGGACGCGCCGACAGCCUGGAAUGGCGCGCCAUUCCAGGGCCGCCUCUAGGGCCGCGAGGUCCAUGACCUCAUGGGCCCGGCGCAGAGCCGGCUGGACCAGCCGGGGCGUGGGGUCAUCGAGGCCACCGGCAUAGCGGUAGAAUGAUUCGUAUAACCUAGGGCGCCGGCAGGGCGCGGCGGUGUAGUUGC	Molner et al. cloned a number of additional minor products (cloned only once) from this hairpin precursor (not shown) [1]. 	53
20195	MI0006228	cre-MIR1168	Chlamydomonas reinhardtii miR1168 stem-loop	GCGGCUUGGUCUUUCCGCGGUGGCCUCCUCCUCAAUCUUGGCCUUGCGCGCUUCGGGCUUGGCCUGGUCUACACAGCAGGCAGGGUUGGGAAGCUCCCUUACCCUGCCUGCUGUGUGGACAAGGCCAAGUCCGAAGCACGGAAGGCGAAGAUUGAGGAGGAGCGUGCAGUGCGGGUCCAUGGGUCGUGCCUGC		53
20196	MI0006229	cre-MIR1169	Chlamydomonas reinhardtii miR1169 stem-loop	UACGGUAUCCAGCAAGCAACAUCCACAUAAGCCGGGGUUGGUAGCAACACAUCUACCAACCCCGGCUUAUGUGGAUGUUGCUUGCUGGAUACCGUG		53
20197	MI0006230	cre-MIR1170	Chlamydomonas reinhardtii miR1170 stem-loop	UAUGGGCAAUACUAAAACUGGCAACUUGGCGAUGGACAUGUCACAAUGUCAGUUCUGCCGUGUUCGGCUGAUUGAGCCUGGUCUCAGACCUCAAUCAGCUCAAUCAGCCAAACACGGCAGAACUGGCAUGUCCAUCGCCAAGUUGCCAGUUUCAGUACUGCCCAUA		53
20198	MI0006231	cre-MIR1171	Chlamydomonas reinhardtii miR1171 stem-loop	GGGAGUGGAGUGGAGUGGAGUGGAGUGGAGUGGAGUGGGAGUGGGAGUGGGUGCAAGGGCGUGGGUGGGUGGGUGCGGCGGGCGCGCUUGUCGUGACACCUUGACUCAUCACCCCGCCUCCAACGCCUCCAACGCCUCGCUACUCCCCCUGCAACCCCCUUCCCCACGCCCCCGUCCCUCCGCUCCC		53
20199	MI0006232	cre-MIR1173	Chlamydomonas reinhardtii miR1173 stem-loop	GUUUGGCCUGGUGUUUAAUUUGCUUCCACACAUUUGCAAUGCCAGCAAAUUGCGCAUGCCAAUGCAUUUAUAGGUUAUUGCAUACGCCCUGGAUUGGCAGCGUGAGUGAAAGUGUGCUGGGCUGCGUGCUACUGUAGAUGAGUGGGUACUUGCGAAAUGUAUUGGCGGCCAUUGUAUGGUUGCAAUAGAAAUCAUGCAGGGGAUACUGUGAAUUAUAUACCAUGUACCAUGUGCAAUGUUUCAGAUGUCCCUGCACUAGCAGGCAUUCAGACAUCCCAGCAUCCCAGCGCUGGCAGGCAUGCCUGAAACAUUGCACAUGGUACAUAAUUCACAGUAUCCCCUUCAUGAUUUCCAUUGUAACCAUACAAUGGCAGCCAAUACAUUUCUCAAGUACCCACUCAUCUGUACAGCAGCACGCACCUUCACUCAUGCUGCCAAUCCAGGGCGUAUGCUAUAACCUAUAAAUGCUUUGGCAUGCACAAUUUGCUGGCAUUACAACUGUGUGGAUGCAGAUUAACUUGUAACCACAAAC	Molner et al. cloned a number of additional minor products (cloned only once) from this hairpin precursor (not shown) [1]. 	53
20200	MI0006233	cre-MIR1172	Chlamydomonas reinhardtii miR1172 stem-loop	CAGUAGGAUCGGAGACGCAGUGAAGCCCCCUUGCUGCUGCGAUUCUUUCCGACUUACAACGUGCUCGUGGCGAGCACAUUGUAGGUGUAGAGGAUUGCAGCAGCAACGGGGCUCCGCUGAGUGUCCGAAUCUACUG		53
20201	MI0006234	cre-MIR1167	Chlamydomonas reinhardtii miR1167 stem-loop	GAGCAUCAUGCAUCGUUACACCCCCCACCGUGCACCUUCACGCUCAUGCGCAGCACUGUGCAUGCUUGGGGUGUGAUGAUUUGAAACUU		53
20202	MI0006235	cre-MIR1144b	Chlamydomonas reinhardtii miR1144b stem-loop	GUGCAGCAGGCUUGGUACCGGGCACGCCGGAGGUGGGUAGUGUGGCGGCAGGCAGCAGGCCUCGCGGGGCUGCUGGUGGUGGUGGAGCAGGACGACCGGCGCCCGUCCUCCUCCUCCUCCAACAGCGGCCCCGCGCUGCCAGCUGCCCGCAGCACAAUCACCAACCCCCAGCGUACCCGGCUAAACACCGUGGGCCCACAGCAC		53
20203	MI0006236	cre-MIR1159	Chlamydomonas reinhardtii miR1159 stem-loop	CGUCGACAAUCGGGCACUGUGGCAAACUGCGACAAUGCCAAUGGAGACGGAUGAGACCGUGUUAUUCCAGCAGCCGCGACUCCUGGAAUGGUCACGCGGCUGAGGCACCCUUGCUGGGUACCCCAGCCGAUGCCGAUGUUCCAGCCGCAGUCACGGCGGCAGCCACAGCACGGCCUCAUCCGUCUCCAUUGGCAUUGUACACCGUCUGCCACAGUGCCCGAUUGCCGCCG		53
20204	MI0006237	aga-mir-1174	Anopheles gambiae miR-1174 stem-loop	GCUACGAUCGUGGGUAUUUUAGAUCAUCGACAGACCAAGGCACUUUCGUCACUGGCAUUGUAAGGCCGAGCAGAUGCGGCCUCAACCCAAACCCUCACCCGUGGUUCGCAUCUGCUCCCGUCCAGUGCCCUGUCCAACCAUACUGUCAGAUCUACUUCAUACCCAUGAAUGGUGGCG		19
20205	MI0006238	aga-mir-1175	Anopheles gambiae miR-1175 stem-loop	GAUAUGGAAUAAGUGGAGUAGUGGUCUCAUCGCUUAGCUUCAGAAAAGUGAGAUUCUACUUCUCCGACUUAAUUCAUAUC		19
20206	MI0006239	aga-mir-34	Anopheles gambiae miR-34 stem-loop	GAGGCAAUAUACGCUCUGGCAGUGUGGUUAGCUGGUUGUGUGGUUUUCCCAUCUUCACAGCCACUAUCCGCCCUGCCGUCGCGCUAAUGC		19
20207	MI0006240	aga-mir-12	Anopheles gambiae miR-12 stem-loop	CCGGGGUGAGUAUUACAUCAGGUACUGGUGUGUAAUUUAAACGACCAUCGGACAUGGGGGCUGCCCAACUCCUCUUCUGUCCCCGGUCAAGCUAUCAGUACUUGUGUUAUACUCUCC		19
20208	MI0006241	aga-mir-996	Anopheles gambiae miR-996 stem-loop	GUAGGCGUGCAUGUUUUCUAGUACACGUUUUCAGUUAAAGUUUCGUGACUAGAUUACAUGCUCGUCUAU		19
20209	MI0006242	aga-mir-989	Anopheles gambiae miR-989 stem-loop	GGACAGUACAGUGGCCACGGGGGUACGCCGCUACGUUGCUUUCACUUGGUACGCUCGUAUAGUAUAGAGCUAAAAGUAAACAUAGAUCCAUGUGAUGUGACGUAGUGGUACCCUCCCGUGUCUAUCACAAC		19
20210	MI0006243	aga-mir-306	Anopheles gambiae miR-306 stem-loop	UCACAUGGUCAGGUACUGGAUGACUCUCAGUUGUGUGUAAAAGAUGCUGAGGGCCUUCUGGUACCUACCCCAGUGA		19
20211	MI0006244	ddi-mir-1176	Dictyostelium discoideum miR-1176 stem-loop	CCCAAAGUCGUAUCAGGUGGCCAAUUUUUAUCAAGGAAAGCUGUAUCAUCAAGUGCCUCCCUCUGUCUCUUGAUGAUUCAGCCUUCCUUGACAAAAAUUGCCCACCUGAUACGACUGGGA		63
20212	MI0006245	ddi-mir-1177	Dictyostelium discoideum miR-1177 stem-loop	AUCACCAAAUAAACUAAACCAGUUAGGGUUUAAUGGUUCUAUCUCAAUUGUUUUUUUUUGGAUCCCAAAUUUAAUCUAUUUUAAUUUAAAAAAUGAUUAUUUGUUAUCCAGGAAAAAUAACUGGAAAAGAACCGUUGAGCCCUUUCUGAUUUAUUAAUUAUUUGAUGAC		63
20213	MI0006246	mcmv-mir-m01-1	Mouse cytomegalovirus miR-m01-1 stem-loop	CAAGAGGAGAAUAACGUCGAACGGUGAUUAAUCAUAGUUCUGUCAGACUUUAUUCUCUUCUCU		64
20214	MI0006247	mcmv-mir-m01-2	Mouse cytomegalovirus miR-m01-2 stem-loop	GGAUGAAGAGAAUCGGGUUGGAACGGUGUUUCUUAAGUACGAGCUACCGUUCGACACGGUUUCCUUCGACU		64
20215	MI0006248	mcmv-mir-m01-3	Mouse cytomegalovirus miR-m01-3 stem-loop	AGCGGUGAAGCGACUGUUGCCUCGAAACAUACGGCGGCGCUCGAGGAACGCUCGCUUCACGGCUC		64
20216	MI0006249	mcmv-mir-m01-4	Mouse cytomegalovirus miR-m01-4 stem-loop	GAUUCCUAUGCUAACACGUGCGCGUGACACUACAUGUCUCUCGCGCCGCGUGGUAGCAUUAGAACC		64
20217	MI0006250	mcmv-mir-m21-1	Mouse cytomegalovirus miR-m21-1 stem-loop	CCCCCGCUUGACCGAGGCCCCCAUCGUGCACACGCAGUAAACUACCACCGAUAGGGGACACGUUCAAGCCGGGG		64
20218	MI0006251	mcmv-mir-m22-1	Mouse cytomegalovirus miR-m22-1 stem-loop	CUGGCCUCGGGCCGACGCAGGAGCCCGUUCACAAUACACACGGUUCCCCGUCCGUACCGAGGCCAGAC		64
20219	MI0006252	mcmv-mir-M23-1	Mouse cytomegalovirus miR-M23-1 stem-loop	CUGGCCUCGGUACGGACGGGGAACCGUGUGUAUUGUGAACGGGCUCCUGCGUCGGCCCGAGGCCAG		64
20220	MI0006253	mcmv-mir-M23-2	Mouse cytomegalovirus miR-M23-2 stem-loop	CCCCGGCUUGAACGUGUCCCCUAUCGGUGGUAGUUUACUGCGUGUGCACGAUGGGGGCCUCGGUCAAGCGGGG		64
20221	MI0006254	mcmv-mir-M44-1	Mouse cytomegalovirus miR-M44-1 stem-loop	ACGACCGCGAGCUCCGGAGAAGGAAACUGUCGCUCCGAUCGUAUCUUUUUCCAGAGCCGCGGUCGU		64
20222	MI0006255	mcmv-mir-M55-1	Mouse cytomegalovirus miR-M55-1 stem-loop	CCUGGUGAUCGGCGUGCUAGCCGUCGUGUAUCUCAUCUUCACGAGGCAGCGGUCGGCCGCCGCGAGG		64
20223	MI0006256	mcmv-mir-m59-1	Mouse cytomegalovirus miR-m59-1 stem-loop	CUGUCGGCCGAGGCACUGCUCCUUUUGAGCGGUAGUGCAAAAUUUAGCAGUGCCUCGACCGUCAG		64
20224	MI0006257	mcmv-mir-m59-2	Mouse cytomegalovirus miR-m59-2 stem-loop	UCCCGAAGAGCCCUCACAGAGCCUAAGUGUCCAUCGGACUUAGCCGCUGUCGGCCUCGGAAA		64
20225	MI0006258	mcmv-mir-M87-1	Mouse cytomegalovirus miR-M87-1 stem-loop	CCGAGGCAGCCGUCGGCAGCGGCAGCGGCAGCGUUGAGGGCGCCGUCGCCGGCGGCACCUCUGG		64
20226	MI0006259	mcmv-mir-m88-1	Mouse cytomegalovirus miR-m88-1 stem-loop	AUGACCGACCCCCUGACAUCGGCGGCGCGAGAUUUUUAUGCCGCAGAAGUCGAUGUCGGGGUCUCGGUCGU		64
20227	MI0006260	mcmv-mir-M95-1	Mouse cytomegalovirus miR-M95-1 stem-loop	ACGGUCGUGGGCUUGUGUCGCUUGUUUGCAAUUUCAUCAUAGCGACGUCGGACCGCGACGGCGA		64
20228	MI0006261	mcmv-mir-m107-1	Mouse cytomegalovirus miR-m107-1 stem-loop	CGACCGGUCACUCGUCUCGAGUCACCGUCCGUAGCGACUCGGUGCUCGCGUCGAGUGACCGCUCG		64
20229	MI0006262	mcmv-mir-m108-1	Mouse cytomegalovirus miR-m108-1 stem-loop	CGUUCACGAGCAACCGCCCGAAAUGUGGGUCUUCCGCCUCGUUACGCACGUGUAAGUAUACGGCGUACGGAGCUCCGUUCGUUUCUGACGGUGGCUCGUGUCGAG		64
20230	MI0006263	mcmv-mir-m108-2	Mouse cytomegalovirus miR-m108-2 stem-loop	GAUCACUCGUCGCGAGCGGUCACUCGACGCGAGCACCGAGUCGCUACGGACGGUGACUCGAGACGAGUGACCGGUCGACGAGCGUC	Buck et al [1] and Dolken et al [2] cloned alternative offset mature miRNA sequences from the 5' arm of this hairpin precursor, named mir-m108-2-5p.1 and .2 here. 	64
20231	MI0006264	xtr-mir-31b	Xenopus tropicalis miR-31b stem-loop	GUAACCACUAGGCAAGAUGCUGGCAAGCUAAUUACCUUUUACCUGGCUUUCCAUCUCAGUCUAGCAGCAUUAUUGG		43
20232	MI0006265	xtr-mir-146b	Xenopus tropicalis miR-146b stem-loop	CCAAUGGCAGGGCCCGGCUCUGAGAACUGAAUUCCAUGGACUGUUCCACUCACAGCACCCUCAGUCCACAGUGUUCAGUGCUCCAGUCUGGCUGCCACUA		43
20233	MI0006266	xtr-mir-320	Xenopus tropicalis miR-320 stem-loop	UUCCCCCCUGCUAAGCAAUUAUGCCAAUCAACUUAGUGCAAUCACACGCUACAGUUGAUUGUAAUAAAGGAAAAGCUGGGUUGAGAGGUGACAUGAUUUGCUGGAGGUAUAAAGUUACUG		43
20234	MI0006267	xtr-mir-375	Xenopus tropicalis miR-375 stem-loop	CCUGACGCCGAGCCUGACGUGCAAUGCUUUGUGUCAACGUUUUGUUCGUUCGGCUCGCGUUAAGCAGGUG		43
20235	MI0006268	xtr-mir-427-1	Xenopus tropicalis miR-427-1 stem-loop	AGCACCCAAAACGGGGCUCUCUCUUGUGUAUGAAUUAUGGUGAGAAAGUGCUUUCUGUUUUGGGCGUUGU		43
20236	MI0006269	xtr-mir-427-2	Xenopus tropicalis miR-427-2 stem-loop	AGCACCCAAAACGGGGCUCUCUCUUGUGUAUGAAUUAUGGUGAGAAAGUGCUUUCUGUUUUGGGCGUUGU		43
20237	MI0006270	xtr-mir-427-3	Xenopus tropicalis miR-427-3 stem-loop	AGCACCCAAAACGGGGCUCUCUCUUGUGCAUGAAUUAUGGUGAGAAAGUGCUUUCUGUUUUGGGCGUUGU		43
20238	MI0006271	hsa-mir-1178	Homo sapiens miR-1178 stem-loop	GCGUUGGCUGGCAGAGGAAGGGAAGGGUCCAGGGUCAGCUGAGCAUGCCCUCAGGUUGCUCACUGUUCUUCCCUAGAAUGUCAGGUGAUGU		5
20239	MI0006272	hsa-mir-1179	Homo sapiens miR-1179 stem-loop	GGCUGGAAAGGAAGAAGCAUUCUUUCAUUGGUUGGUGUGUAUUGCCUUGUCAACCAAUAAGAGGAUGCCAUUUAUCCUUUUCUGACUAGCU		5
20240	MI0006273	hsa-mir-1180	Homo sapiens miR-1180 stem-loop	GCUGCUGGACCCACCCGGCCGGGAAUAGUGCUCCUGGUUGUUUCCGGCUCGCGUGGGUGUGUCGGCGGC		5
20241	MI0006274	hsa-mir-1181	Homo sapiens miR-1181 stem-loop	UCCACUGCUGCCGCCGUCGCCGCCACCCGAGCCGGAGCGGGCUGGGCCGCCAAGGCAAGAUGGUGGACUACAGCGUGUGGG		5
20242	MI0006275	hsa-mir-1182	Homo sapiens miR-1182 stem-loop	GGGACUUGUCACUGCCUGUCUCCUCCCUCUCCAGCAGCGACUGGAUUCUGGAGUCCAUCUAGAGGGUCUUGGGAGGGAUGUGACUGUUGGGAAGCCC		5
20243	MI0006276	hsa-mir-1183	Homo sapiens miR-1183 stem-loop	AUUAUUCAAAUGCUCGGAGACACAGAACAUUAGAGAAGACAGGAGUUCACUGUAGGUGAUGGUGAGAGUGGGCAUGGAGCAGGAGUGCC		5
20244	MI0006277	hsa-mir-1184	Homo sapiens miR-1184 stem-loop	CUUGCAGAACGAGGUGAAGGAGGUGGUUCUGCUCAGCAGUCAACAGUGGCCACAUCUCCACCUGCAGCGACUUGAUGGCUUCCGUGUCCUUUUCGUGGG		5
20245	MI0006278	mmu-mir-466l	Mus musculus miR-466l stem-loop	CUAUGUAUGUGCAUGUGUGUUUGUGUGUACAUGUACAUGUAUAUAUAUAUUGAUAUACAUAUAAAUACAUGCACACAUAUUCAUGCAUGCACACGCACACAUUAAUGGCACUCUUAGAUCC		6
20246	MI0006279	mmu-mir-669k	Mus musculus miR-669k stem-loop	UCUUAUGCCCACCAAAAAUGUGCAUGUGUGUAUAGUUGUGUGCAUAUUCACUUCUCUAUAUGAAUAUGCAUAUACACGCAUGCAAACACAUUCAUAGGAAUGGCCAGAGCUAUAUCUCAGUUAGGAG		6
20247	MI0006280	mmu-mir-669g	Mus musculus miR-669g stem-loop	CAUGUGUGCUUACUUGUAUGUGCAUUGUAUGUGUUGACAUGAUAUACAUAACAUAAACACACGUGUAUCUGCAAGCACACACACACAGGAAAAAUUGCAUUCAUUUAUACGUUUGAAUGAUAU		6
20248	MI0006281	mmu-mir-669d	Mus musculus miR-669d stem-loop	CAGCCCGGGAUUUGUGUGUUGCUUGCUCUAUAUGUGUGUAUACUUGUGUGUGCAUGUAUAUGUGUGUAUAUGAAUAUACAUAUACAUACACACCCAUAUACACACGCAUGCAUGCACACAC		6
20249	MI0006282	mmu-mir-466i	Mus musculus miR-466i stem-loop	AGAGAUCAUGUCAGUGAACUGCCACAUUUUUGAUAUAUAUUAUGUAUGUAUGUGUGUGUGUGUGUGUGUGUGUAUAUAUAUACACACACACAUACACACUACAUGUAUGCAACAUAUAUAC		6
20250	MI0006283	mmu-mir-1-2-as	Mus musculus miR-1-2-as stem-loop	UUCCUUUAGCUUCUUCUUGGCGGACAUUACCUACCCAAAAUACAUACUUCUUUACAUUCCAUAGCACUGAAUGUUCAUAUGGGUACAUAAAGAAGUAUGUGCUCUGAGUAGGCACUCCUGCG	Calabrese et al. report the detection of mature products from the antisense strand of mouse mir-1-2, at lower abundance than sense miR-1 [1]. 	6
20251	MI0006284	mmu-mir-1186	Mus musculus miR-1186 stem-loop	UCCACCUGUCUCUGCCUCCCGAGUGCUGGAAUUAAAGGCAUGCACCACCACUGCCCGGCAGGUUCUGUUAUUUCUGAGUGUGAGAAAUAUAUGGGGAAAAGUCUUCAUGGUGAGUCCAAAGG		6
20252	MI0006285	mmu-mir-1187	Mus musculus miR-1187 stem-loop	UCAUAUAGUAUUAAACCGAACUGUUUUCCUUAUAGACACAAUUUAUUUUUACACACACACACACACACAUAUAUAUAUAUAUGUGUGUGUGUAUGUGUGUAAAUAACAAUGUUAAAAUAGUA		6
20253	MI0006286	mmu-mir-669j	Mus musculus miR-669j stem-loop	AGCAUGCGAUUCAUGUGAUGUCCACCAAGAAUGUGCAUGUGUGUAUAGUUGUGUACAUAUUCACUUUUGUAUAUGAAUAUGCAUAUACUCACAUGCAAACAUACUCCCACGAAUGGCCCGA		6
20254	MI0006287	mmu-mir-669f	Mus musculus miR-669f stem-loop	UGUAUGUGCCUGUGUGUAUAGUUGUGUGUGCAUGUGCAUGUGUGUAUAUGAAUAUACAUAUACAUACACACACACGUAUAAACGCAAGCACAAACACACACAGAGGAAUGGCACUCGUUGA		6
20255	MI0006288	mmu-mir-669i	Mus musculus miR-669i stem-loop	AUGUGAUGCCCACCAAUAAUGUGCAUGUGUGUAUAGUUGUGUGCAUAUUCAUUUCUCUAUAUGACUAUGCAUAUACACACAUGCAUACAAACUCACAUACAGGAAUGACAGUCAUAUAUCCUUUUGA		6
20256	MI0006289	mmu-mir-669h	Mus musculus miR-669h stem-loop	UGUGAUGCCCACCAAAAAUAUGCAUGGGUGUAUAGUUGAGUGCAUAUUCAUUUCUCUAUAUGAAUAUGCAUAUACACACAUGCACACACACACACACUCACACACAGGAAUGACACUCGUUUAUC		6
20257	MI0006290	mmu-mir-1188	Mus musculus miR-1188 stem-loop	AUACUCACAGUCUCCCAGCUGGUGUGAGGUUGGGCCAGGAUGAAACCCAAGGCUCUCCGAGGCUCCCCACCACACCCUGCUGCUGAAGACUGCCUAGCAAGGCUGUGCCGAGUGGUGUGG		6
20258	MI0006291	mmu-mir-466f-4	Mus musculus miR-466f-4 stem-loop	CAUCUGCAUCUGUGUGUCUACGUGUGUGUGCAUGUGCAUGUGUGUGUAUCUGUAUGUGAGUGUGUGCAUGCAUGUGUGUGCAUCUAUAUCUGUGUGUCUACUUGUGUGUGAAUGUGCAUAU		6
20259	MI0006292	mmu-mir-466k	Mus musculus miR-466k stem-loop	AUAUAUGUGUGUGUGUGUGUGUGUGUGUACAUGUACAUGUGAGUAUGUGUGUGUAUAUGUUUGUACAUGUGCAUGUGUGUGAGUAUGUGAAUAUAUGUGUAUAUGUGUGCAUGUGCAUGUGU		6
20260	MI0006293	mmu-mir-467f	Mus musculus miR-467f stem-loop	ACGGCUACAUAGAGAAAUCCUGUACCCAGAAAUCGAACGGGGGUGGGUGUGUGUGUAGGUGUGUGUGUGUGUAUGUAUGUAUAUACACACACACACCUACACACAGCUUUUUUGGAAUUU		6
20261	MI0006294	mmu-mir-1190	Mus musculus miR-1190 stem-loop	GCUGACACUCUGAGAGUGUUGGUGAGCUCUGGGGCCUUUGCAGACGUGGGAAGGUCUCUGCUGGCCUGAUGCUUCCCCCGUCAGCUGAGGUUCCCCUCUGUCUGGGAUGCUGCCUUGAGUC		6
20262	MI0006295	mmu-mir-466j	Mus musculus miR-466j stem-loop	GUGUGUGUGUGUGUGCAUUCGUGUGUUUGUGCAUGUGUGUAUGUGUGCACAUUUAUGUGUGUGCAUGUGUAUGUAUGUGUGUGUGCAUGUGCAUGUGUGUAAUUGUGUAUAUAUGUGCAUAC		6
20263	MI0006296	mmu-mir-1191	Mus musculus miR-1191 stem-loop	UGGAACCAGCCUGGUCUACAUAGCAACAUCUAAGCCAGCCAGGGCUACAUAGUGAGAACCUGCCUCAAAAGCAAAACAGCAGUCUUACUAUGUAGCCCUAGAUGGCCUAGAACUCCCUAU		6
20264	MI0006297	mmu-mir-1192	Mus musculus miR-1192 stem-loop	CCUUCCAAACAGUAAAAACAAACAAACAAACAGACCAAAUUUGUCAUUGUUGUUUCGAUUUGCUCUUUUUGUUUGUUUGCUUUUGUGUUUUGAGACAGGGUCUGGCUUGUAUAGCUCAUGC		6
20265	MI0006298	mmu-mir-1193	Mus musculus miR-1193 stem-loop	CUGAAGGGACAAUGAUGCCCACUGUUCUCGGGGUAGCUGUGUGGAUGGUAGACCGGUGACGUACACUUCAUUUAUGCUGUAGGUCACCCGUUUUACUAUCCACCAACACCCAGACCAUCUG		6
20266	MI0006299	mmu-mir-1194	Mus musculus miR-1194 stem-loop	ACACCUUCUGCUGGAGACAAUAUAAGGACAUUGGAAGAAGGGAGUCUAGCUCUUGCUCCUUUGCCUGCUUGCUGCGUGAGAAUGAGUAACUGCUAGAUCCUUGGACUUCCAUUCACAGCUG		6
20267	MI0006300	mmu-mir-669e	Mus musculus miR-669e stem-loop	GCCUGGGAUUCAUGGGCUGUACCCUAUAUAUGGGCAGGUGUGUGUCUUGUGUGUGCAUGUUCAUUUGUGUAUAUGAAUAUGAAUAUACACACACUUACACACUCAUGCACACACACACA		6
20268	MI0006301	mmu-mir-467g	Mus musculus miR-467g stem-loop	GUCUUGUGCAUGCAUAUAUAUAUAUGUGUGUGUGUAUAUAUAUAUACAUAUAUAUACAUACAUACACAUGUAUAUGUAUAUAUACAUACACACACAUAUAUAUAUUCAUGUAUAUAUAUA		6
20269	MI0006302	mmu-mir-467h	Mus musculus miR-467h stem-loop	UUUUCACUUUUGUUUUUCUCAUGUAUAUGUGUAUGUGUGCGGUGUACAUAAUUAUAUCUAUGUGUGCAUGUAUGUGGACAUAAGUGUGUGCAUGUAUAUGUGUGUGUGUGGUGUACAUAAU		6
20270	MI0006303	mmu-mir-1195	Mus musculus miR-1195 stem-loop	UAGAGGCAGGCAGAUCUCUGUGAGUUCGAGGCCAGCCUGCUCAACAGAAUGAGUUCUAGGGCAGCCAGGAACACACAGAGAAACCCUGUCUCAAGAAGGUAAAAAGUAAAAAAAAAAAAAAAA		6
20271	MI0006304	mmu-mir-1196	Mus musculus miR-1196 stem-loop	UGCUGGUCUUGAACUCACAGAAAUCUACCUGCCUCUGCCUUCCAAGUACUGGGCAGUGUGCCACCAAAACCCUACAUUUUUGCUGGGCUGGGGGUGAGGGUGGUUUUUUUUUUUUUAAA		6
20272	MI0006305	mmu-mir-1197	Mus musculus miR-1197 stem-loop	GUGAGCUGGAAUCAGCCAGCGUUACCUCAAGGUAUUUGAAGAUGCGGUUGACCAUGGUGUGUACGCUUUAUUUAUGACGUAGGACACAUGGUCUACUUCUUCUCAAUAUCACAUCUCGCC		6
20273	MI0006306	mmu-mir-1198	Mus musculus miR-1198 stem-loop	UUUUUUUUCUUUUGUUUAUUUUGUUUGUGACAGUUGUCUGUUAUGUGUUCCUGGCUGGCUUGGUACUCAUGUGUAGCCCAAGCUAGCCUCUAACUCAUGGCAGUCAUCCUGUCUCAGUCUC		6
20274	MI0006307	mmu-mir-1199	Mus musculus miR-1199 stem-loop	AGCCUGCGCCGGAGCCGGGGUCUGAGUCCCGGUCGCGCGGGCGAGGAACUCAUUGAGUUGCGCGUGCGGCCGGUGCUCAGUCGGCCCGGCUCCGGUACUCCGCUGCCGCGCGCCCUGGA		6
20275	MI0006308	cpa-MIR162a	Carica papaya miR162a stem-loop	AGGGUAAAGUCACUGGAGGCAGCGGUUCAUCGAUCUCUUCCUGGGAAUUUGGUGUGAAAAAUCACAGAACAUGAAUCGAUCGAUAAACCUCUGCAUCCAGCGUUACCCC	cpa-MIR162a was identified within a 2699 bp putative pri-miRNA isolated from a Carica papaya root cDNA library (accession EF512306). 	65
20276	MI0006309	ptr-mir-1224	Pan troglodytes miR-1224 stem-loop	GUGAGGACUCGGGAGGUGGAGGGUGGUGCCGCCGGGGCCGGGCGCUGUUUCAGCUCGCUUCUCCCCCCACCUCCUCUCUCCUCAG		37
20277	MI0006310	mml-mir-1224	Macaca mulatta miR-1224 stem-loop	GUGAGGACUCGGGAGGUGGAGGGUGGCGCCGCCGGGGCCAGGCGCUGUCUAAGCUCGCUUCUCCCCCCACCUCCUCUCUCCUCAG		32
20278	MI0006311	hsa-mir-1225	Homo sapiens miR-1225 stem-loop	GUGGGUACGGCCCAGUGGGGGGGAGAGGGACACGCCCUGGGCUCUGCCCAGGGUGCAGCCGGACUGACUGAGCCCCUGUGCCGCCCCCAG		5
20279	MI0006312	mml-mir-1225	Macaca mulatta miR-1225 stem-loop	GUGGGUACGGCCCAGUGGGGGGGAGAGGGACACGCCCUGGGCUCUGCCCAGGGUGCAGCCGGACUGACUGAGCCCCUGUGCCGCCCCCAG		32
20280	MI0006313	hsa-mir-1226	Homo sapiens miR-1226 stem-loop	GUGAGGGCAUGCAGGCCUGGAUGGGGCAGCUGGGAUGGUCCAAAAGGGUGGCCUCACCAGCCCUGUGUUCCCUAG		5
20281	MI0006314	ptr-mir-1226	Pan troglodytes miR-1226 stem-loop	GUGAGGGCAUGCAGGCCUGGAUGGGGCAGCUGGGAUGGUCCAAAAGGGUGGCCUCACCAGCCCUGUGUUCCCUAG		37
20282	MI0006315	mml-mir-1226	Macaca mulatta miR-1226 stem-loop	GUGAGGGCAUGCAGGCCUGGAUGGGGCAGCUGGGAUGGUCCAAAAGGGUGGCCUCACCAGCCCUGUGUUCCCUAG		32
20283	MI0006316	hsa-mir-1227	Homo sapiens miR-1227 stem-loop	GUGGGGCCAGGCGGUGGUGGGCACUGCUGGGGUGGGCACAGCAGCCAUGCAGAGCGGGCAUUUGACCCCGUGCCACCCUUUUCCCCAG		5
20284	MI0006317	mml-mir-1227	Macaca mulatta miR-1227 stem-loop	GUGGGGCCAGGCGGUGGUGGGCACCGCUGGGGUGGGCACAGCAGCCAUGCAGAGCAGGCAGCUGACCCCGUGCCAUCCUCUUCCCCAG		32
20285	MI0006318	hsa-mir-1228	Homo sapiens miR-1228 stem-loop	GUGGGCGGGGGCAGGUGUGUGGUGGGUGGUGGCCUGCGGUGAGCAGGGCCCUCACACCUGCCUCGCCCCCCAG		5
20286	MI0006319	hsa-mir-1229	Homo sapiens miR-1229 stem-loop	GUGGGUAGGGUUUGGGGGAGAGCGUGGGCUGGGGUUCAGGGACACCCUCUCACCACUGCCCUCCCACAG		5
20287	MI0006320	mml-mir-1230	Macaca mulatta miR-1230 stem-loop	GUGGGUGGGGGCAUCUCGGAGGAGGUGGGGGGUGUGGCGCCCAGCGGAUGACUCCGAGCGGCUCCUUUCCCAG		32
20288	MI0006321	hsa-mir-1231	Homo sapiens miR-1231 stem-loop	GUCAGUGUCUGGGCGGACAGCUGCAGGAAAGGGAAGACCAAGGCUUGCUGUCUGUCCAGUCUGCCACCCUACCCUGUCUGUUCUUGCCACAG		5
20289	MI0006322	mml-mir-1232	Macaca mulatta miR-1232 stem-loop	GUGGGGUGGCGGCGACAUGGCGGGGGCGGCGGGCCCUGCGGAGGCUGUGCGCCUGACCCCGACCACCCCGCAG		32
20290	MI0006323	hsa-mir-1233	Homo sapiens miR-1233 stem-loop	GUGAGUGGGAGGCCAGGGCACGGCAGGGGGAGCUGCAGGGCUAUGGGAGGGGCCCCAGCGUCUGAGCCCUGUCCUCCCGCAG		5
20291	MI0006324	hsa-mir-1234	Homo sapiens miR-1234 stem-loop	GUGAGUGUGGGGUGGCUGGGGGGGGGGGGGGGGGGCCGGGGACGGCUUGGGCCUGCCUAGUCGGCCUGACCACCCACCCCACAG		5
20292	MI0006325	mml-mir-1235	Macaca mulatta miR-1235 stem-loop	GUGGGCCUGGGUCGGUGGGGACGGGGCGGCUGGGCGUGCCCUGCGGCCGCUGCUCUAACCGCACCGUCCCCCAG		32
20293	MI0006326	hsa-mir-1236	Homo sapiens miR-1236 stem-loop	GUGAGUGACAGGGGAAAUGGGGAUGGACUGGAAGUGGGCAGCAUGGAGCUGACCUUCAUCAUGGCUUGGCCAACAUAAUGCCUCUUCCCCUUGUCUCUCCAG		5
20294	MI0006327	hsa-mir-1237	Homo sapiens miR-1237 stem-loop	GUGGGAGGGCCCAGGCGCGGGCAGGGGUGGGGGUGGCAGAGCGCUGUCCCGGGGGCGGGGCCGAAGCGCGGCGACCGUAACUCCUUCUGCUCCGUCCCCCAG		5
20295	MI0006328	hsa-mir-1238	Homo sapiens miR-1238 stem-loop	GUGAGUGGGAGCCCCAGUGUGUGGUUGGGGCCAUGGCGGGUGGGCAGCCCAGCCUCUGAGCCUUCCUCGUCUGUCUGCCCCAG		5
20296	MI0006329	mml-mir-1239	Macaca mulatta miR-1239 stem-loop	GUGGGUGGGCAGGUGGGUGGGAAGCCCUGGGACGCUGCCUCCUCUCUCCUGGGGCCUCUCUCGGGCUGGGGGCUGGUCUCAGUUUCCCCAUUCUGCCUGGCCUAG		32
20297	MI0006330	mml-mir-1240	Macaca mulatta miR-1240 stem-loop	GUGGGCCAGGGCCGCGGGGGGGAGCAAGCCAUCUAGCAUUCCUGGGAAACGCUUACAUCUCACCAUGACCCUGAUCCCACUAG		32
20298	MI0006331	mml-mir-1241	Macaca mulatta miR-1241 stem-loop	GUGAGGGGGCUGGCAUGGCGAGGAGGCGCCAGAGAAGCCAUAGUGUGGGGAUGGGCUGCACACUCACCUCUCUGUGCCUUCCAG		32
20299	MI0006332	hsa-mir-1200	Homo sapiens miR-1200 stem-loop	UGCUACUUCUCCUGAGCCAUUCUGAGCCUCAAUCACUUGCCAGAGAGAUUGGUUCAGGAAUUUGUCAGGGAUAGCC		5
20300	MI0006333	hsa-mir-1201	Homo sapiens miR-1201 stem-loop	UUUACAGUUUGCCAUGAUGAAAUGCAUGUUAAGUCCGUGUUUCAGCUGAUCAGCCUGAUUAAACACAUGCUCUGAGCAGACUAAA		5
20301	MI0006334	hsa-mir-1202	Homo sapiens miR-1202 stem-loop	CCUGCUGCAGAGGUGCCAGCUGCAGUGGGGGAGGCACUGCCAGGGCUGCCCACUCUGCUUAGCCAGCAGGUGCCAAGAACAGG		5
20302	MI0006335	hsa-mir-1203	Homo sapiens miR-1203 stem-loop	UCCUCCCCGGAGCCAGGAUGCAGCUCAAGCCACAGCAGGGUGUUUAGCGCUCUUCAGUGGCUCCAGAUUGUGGCGCUGGUGCAGG		5
20303	MI0006336	hsa-mir-663b	Homo sapiens miR-663b stem-loop	GGUGCCGAGGGCCGUCCGGCAUCCUAGGCGGGUCGCUGCGGUACCUCCCUCCUGUCUGUGGCGGUGGGAUCCCGUGGCCGUGUUUUCCUGGUGGCCCGGCCGUGCCUGAGGUUUC		5
20304	MI0006337	hsa-mir-1204	Homo sapiens miR-1204 stem-loop	ACCUCGUGGCCUGGUCUCCAUUAUUUGAGAUGAGUUACAUCUUGGAGGUGAGGACGUGCCUCGUGAU		5
20305	MI0006338	hsa-mir-1205	Homo sapiens miR-1205 stem-loop	GAAGGCCUCUGCAGGGUUUGCUUUGAGGUACUUCCUUCCUGUCAACCCUGUUCUGGAGUCUGU		5
20306	MI0006339	hsa-mir-1206	Homo sapiens miR-1206 stem-loop	CAGUGUUCAUGUAGAUGUUUAAGCUCUUGCAGUAGGUUUUUGCAAGCUAGUGAACGCUG		5
20307	MI0006340	hsa-mir-1207	Homo sapiens miR-1207 stem-loop	GCAGGGCUGGCAGGGAGGCUGGGAGGGGCUGGCUGGGUCUGGUAGUGGGCAUCAGCUGGCCCUCAUUUCUUAAGACAGCACUUCUGU		5
20308	MI0006341	hsa-mir-1208	Homo sapiens miR-1208 stem-loop	CACCGGCAGAAUCACUGUUCAGACAGGCGGAGACGGGUCUUUCUCGCCCUCUGAUGAGUCACCACUGUGGUGG		5
20309	MI0006342	rno-mir-146b	Rattus norvegicus miR-146b stem-loop	UGGCCACCUGGCCCUGAGAACUGAAUUCCAUAGGCUGUGAACUCUAGCAGAUGCCCUAGGGACUCAGUUCUGGUGCCUGGCUGUGCUA		8
20310	MI0006343	rno-mir-551b	Rattus norvegicus miR-551b stem-loop	GUGCUCUUGUGGCCCAUGAAAUCAAGCUUGGGUGAGACCUGGUACAGAACAGGAAGGCGACCCAUACUUGGUUUCAGUGGCUGCAAGAAUGGCUCUAU		8
20311	MI0006344	hsa-mir-548e	Homo sapiens miR-548e stem-loop	UUAUUAGGUUGGUACAAAAGCAAUCGCGGUUUUUGCUAUUACUUUUAAAGGCAAAAACUGAGACUACUUUUGCACCAACCUGAUAGAA		5
20312	MI0006345	hsa-mir-548j	Homo sapiens miR-548j stem-loop	GGGCAGCCAGUGAAUAGUUAGCUGGUGCAAAAGUAAUUGCGGUCUUUGGUAUUACUUUCAGUGGCAAAAACUGCAUUACUUUUGCACCAGCCUACUAGAACGCUGAGUUCAG		5
20313	MI0006346	hsa-mir-1285-1	Homo sapiens miR-1285-1 stem-loop	UGUAGAGAUAGGAUCUCACUUUGUUGCCCAGGCUGGUCUCAAACUCCUGGUCUGGGCAACAAAGUGAGACCUUAUCUCUACAAG		5
20314	MI0006347	hsa-mir-1285-2	Homo sapiens miR-1285-2 stem-loop	UUUGGGAGGCCGAGGCUGGUGCAUCACUUGAGCCCAGCAAUUUGAGACCAAUCUGGGCAACAAAGUGAGACCUCCGUCUCUACAAAGA		5
20315	MI0006348	hsa-mir-1286	Homo sapiens miR-1286 stem-loop	UGUCCUCUGGGGACUCAGCUUGCUCUGGCUGCUGGAUUGAAUUAGCUGCAGGACCAAGAUGAGCCCUUGGUGGAGACA		5
20316	MI0006349	hsa-mir-1287	Homo sapiens miR-1287 stem-loop	GUUGUGCUGUCCAGGUGCUGGAUCAGUGGUUCGAGUCUGAGCCUUUAAAAGCCACUCUAGCCACAGAUGCAGUGAUUGGAGCCAUGACAA		5
20317	MI0006350	hsa-mir-1289-1	Homo sapiens miR-1289-1 stem-loop	UUCUCAAUUUUUAGUAGGAAUUAAAAACAAAACUGGUAAAUGCAGACUCUUGGUUUCCACCCCCAGAGAAUCCCUAAACCGGGGGUGGAGUCCAGGAAUCUGCAUUUUAGAAAGUACCCAGGGUGAUUCUGAUAAUUGGGAACA		5
20318	MI0006351	hsa-mir-1289-2	Homo sapiens miR-1289-2 stem-loop	CCACGGUCCUAGUUAAAAAGGCACAUUCCUAGACCCUGCCUCAGAACUACUGAACAGAGUCACUGGGUGUGGAGUCCAGGAAUCUGCAUUUUUACCCCUAUCGCCCCCGCC		5
20319	MI0006352	hsa-mir-1290	Homo sapiens miR-1290 stem-loop	GAGCGUCACGUUGACACUCAAAAAGUUUCAGAUUUUGGAACAUUUCGGAUUUUGGAUUUUUGGAUCAGGGAUGCUCAA		5
20320	MI0006353	hsa-mir-1291	Homo sapiens miR-1291 stem-loop	GGUAGAAUUCCAGUGGCCCUGACUGAAGACCAGCAGUUGUACUGUGGCUGUUGGUUUCAAGCAGAGGCCUAAAGGACUGUCUUCCUG		5
20321	MI0006354	hsa-mir-548k	Homo sapiens miR-548k stem-loop	CUUUUCUCAAGUAUUGCUGUUAGGUUGGUGCAAAAGUACUUGCGGAUUUUGCUUUACUUUUAAUGGCAAAAACCGCAAUUAUUUUUGCUUCAACCUAAUAUGAUGCAAAAUUGGCU		5
20322	MI0006355	hsa-mir-1293	Homo sapiens miR-1293 stem-loop	AGGUUGUUCUGGGUGGUCUGGAGAUUUGUGCAGCUUGUACCUGCACAAAUCUCCGGACCACUUAGUCUUUA		5
20323	MI0006356	hsa-mir-1294	Homo sapiens miR-1294 stem-loop	CACCUAAUGUGUGCCAAGAUCUGUUCAUUUAUGAUCUCACCGAGUCCUGUGAGGUUGGCAUUGUUGUCUGGCAUUGUCUGAUAUACAACAGUGCCAACCUCACAGGACUCAGUGAGGUGAAACUGAGGAUUAGGAAGGUGUA		5
20324	MI0006357	hsa-mir-1295	Homo sapiens miR-1295 stem-loop	AGGACAUUUUGCCCAGAUCCGUGGCCUAUUCAGAAAUGUGGCCUGUGAUUAGGCCGCAGAUCUGGGUGAAAUGUCCUCC		5
20325	MI0006358	hsa-mir-1297	Homo sapiens miR-1297 stem-loop	UGUUUAUCUCUAGGGUUGAUCUAUUAGAAUUACUUAUCUGAGCCAAAGUAAUUCAAGUAAUUCAGGUGUAGUGAAAC		5
20326	MI0006359	hsa-mir-1299	Homo sapiens miR-1299 stem-loop	CCUCAUGGCAGUGUUCUGGAAUCCUACGUGAGGGACAAUCAUUCAGACCCACGUAGCAGUGUUCUGGAAUUCUGUGUGAGGGA		5
20327	MI0006360	hsa-mir-1300	Homo sapiens miR-1300 stem-loop	CCACCACUGCUGGCCAUCUGAUCUACAAAUGCAGUGGCAUUGACAAAAGAACCAUUGAAAAUUUGAGAAGGAGGCUGCUGAGAUGGGA		5
20328	MI0006361	hsa-mir-548l	Homo sapiens miR-548l stem-loop	UAUUAGGUUGGUGCAAAAGUAUUUGCGGGUUUUGUCGUAGAAAGUAAUGGCAAAAACUGCAGUUACUUGUGCACCAACCAAAUGCU		5
20329	MI0006362	hsa-mir-1302-1	Homo sapiens miR-1302-1 stem-loop	CAGAAAGCCCAGUUAAAUUUGAAUUUCAAGUAAACAAUGAAUAAUUGUGUAUGUAAGAAUAUCCCAUACAAUAUUUGGGACAUACUUAUGCUAAAAAUUAUUCCUUGCUUAUCUGAAAUUCAAAUGUAACUAGGAUUCCUGUA		5
20330	MI0006363	hsa-mir-1302-2	Homo sapiens miR-1302-2 stem-loop	GGAUGCCCAGCUAGUUUGAAUUUUAGAUAAACAACGAAUAAUUUCGUAGCAUAAAUAUGUCCCAAGCUUAGUUUGGGACAUACUUAUGCUAAAAAACAUUAUUGGUUGUUUAUCUGAGAUUCAGAAUUAAGCAUUUUA		5
20331	MI0006364	hsa-mir-1302-3	Homo sapiens miR-1302-3 stem-loop	GGAUGCCCAGCUAGUUUGAAUUUUAGAUAAACAACGAAUAAUUUCGUAGCAUAAAUAUUUCCCAAGCUUAGUUUGGGACAUACUUAUGCUAAAAAACAUUAUUGGUUGUUUAUCUGAGAUUCAAAAUUAAGCAUUUUA		5
20332	MI0006365	hsa-mir-1302-4	Homo sapiens miR-1302-4 stem-loop	AAUGCAGAAGCACAGCUAAAAUUUGAAUUUCAGAUAAACAAAUUUUUCUUAGAAUAAGUAUGUCUCCAUGCAACAUUUGGGACAUACUUAUGCUAAAAUAUUAUUUGUGUUUCAUCUGAAAUUCAAAUUCAACUGGACAUCCUGUAUUUU		5
20333	MI0006366	hsa-mir-1302-5	Homo sapiens miR-1302-5 stem-loop	UGCCCGGCCUCCCAUUAAAUUGGUUUUUCAGACAAAUCACAAAUUUGUUUAGGUAUAAGUAUAUCCCAUGUAAUCUUUGGGACAUACUUAUGCUAAAAUAAUUGUUCCUUGUUGAUUGGAAAUUUUAAUUUUAAUUAGGUGUCCUGUAUU		5
20334	MI0006367	hsa-mir-1302-6	Homo sapiens miR-1302-6 stem-loop	AACAAAUAAUUUGGUAAUAUAUGUAUGGCCCACACAAUAUUUAGGACAACAAUAUUUGGGACAUACUUAUGCUAAAAAAGUAUUUGUUGA		5
20335	MI0006368	hsa-mir-1302-7	Homo sapiens miR-1302-7 stem-loop	ACAACAUGUUUUUAGGACAUGUAUGUCUGGUGCAAUAAUUGGGACAUACUUAUGCUAAAAAAAUUAGUGUUC		5
20336	MI0006369	hsa-mir-1302-8	Homo sapiens miR-1302-8 stem-loop	CCCAUUUAAACUUGAAUUUCAUAUAAACACCGUAAUUUUCAGCAUUAGUGUAUCACAUGCAGUAUUUGGGACAUACUUAUGCUAAAAAAUUAGGUGGUGUUGAUCUGAAAUUCCAGUGUAGAUGGGCA		5
20337	MI0006370	hsa-mir-1303	Homo sapiens miR-1303 stem-loop	GGCUGGGCAACAUAGCGAGACCUCAACUCUACAAUUUUUUUUUUUUUAAAUUUUAGAGACGGGGUCUUGCUCUGUUGCCAGGCUUU		5
20338	MI0006371	hsa-mir-1304	Homo sapiens miR-1304 stem-loop	AAACACUUGAGCCCAGCGGUUUGAGGCUACAGUGAGAUGUGAUCCUGCCACAUCUCACUGUAGCCUCGAACCCCUGGGCUCAAGUGAUUCA		5
20339	MI0006372	hsa-mir-1305	Homo sapiens miR-1305 stem-loop	AAGAUCCUGCUGUUUCUACCAUUAGUUUUGAAUGUUUAUUGUAAAGAUACUUUUCAACUCUAAUGGGAGAGACAGCAGGAUUCUCC		5
20340	MI0006373	hsa-mir-1243	Homo sapiens miR-1243 stem-loop	CUAAAACUGGAUCAAUUAUAGGAGUGAAAUAAAGGUCCAUCUCCUGCCUAUUUAUUACUUUGCUUUGGUAAUAAAUCUAUUUUUAAAAGAACC		5
20341	MI0006374	hsa-mir-548f-1	Homo sapiens miR-548f-1 stem-loop	AUUAGGUUGGUGCAAAAGUAAUCACAGUUUUUGACAUUACUUUCAAAGACAAAAACUGUAAUUACUUUUGGACCAACCUAAUAG		5
20342	MI0006375	hsa-mir-548f-2	Homo sapiens miR-548f-2 stem-loop	UAAUAACUAUUAGGUUGGUGCGAACAUAAUUGCAGUUUUUAUCAUUACUUUUAAUGGCAAAAACUGUAAUUACUUUUGCACCAACCUAAUAUUUUAGU		5
20343	MI0006376	hsa-mir-548f-3	Homo sapiens miR-548f-3 stem-loop	AUUAGGUUGGUGCAAACCUAAUUGCAAUUUUUGCAGUUUUUUUAAGUAAUUGCAAAAACUGUAAUUACUUUUGCACCAACCUAAUAC		5
20344	MI0006377	hsa-mir-548f-4	Homo sapiens miR-548f-4 stem-loop	GAGUUCUAACGUAUUAGGUUGGUGCAAAAGUAAUAGUGGUUUUUGCCAUUAAAAGUAAUGACAAAAACUGUAAUUACUUUUGGAACAAUAUUAAUAGAAUUUCAG		5
20345	MI0006378	hsa-mir-548f-5	Homo sapiens miR-548f-5 stem-loop	UAUUAGGUUGCUGCAAAAGUAAUCAUGUUUUUUUCCAUUGUAAGUAAUGGGAAAAACUGUAAUUACUUUUGUACCAACCUAAUAGC		5
20346	MI0006379	hsa-mir-1244	Homo sapiens miR-1244 stem-loop	AUCUUAUUCCGAGCAUUCCAGUAACUUUUUUGUGUAUGUACUUAGCUGUACUAUAAGUAGUUGGUUUGUAUGAGAUGGUUAAAAA		5
20347	MI0006380	hsa-mir-1245	Homo sapiens miR-1245 stem-loop	AUUUAUGUAUAGGCCUUUAGAUCAUCUGAUGUUGAAUACUCUUUAAGUGAUCUAAAGGCCUACAUAUAAA		5
20348	MI0006381	hsa-mir-1246	Homo sapiens miR-1246 stem-loop	UGUAUCCUUGAAUGGAUUUUUGGAGCAGGAGUGGACACCUGACCCAAAGGAAAUCAAUCCAUAGGCUAGCAAU		5
20349	MI0006382	hsa-mir-1247	Homo sapiens miR-1247 stem-loop	CCGCUUGCCUCGCCCAGCGCAGCCCCGGCCGCUGGGCGCACCCGUCCCGUUCGUCCCCGGACGUUGCUCUCUACCCCGGGAACGUCGAGACUGGAGCGCCCGAACUGAGCCACCUUCGCGGACCCCGAGAGCGGCG		5
20350	MI0006383	hsa-mir-1248	Homo sapiens miR-1248 stem-loop	UUUACCUUCUUGUAUAAGCACUGUGCUAAAAUUGCAGACACUAGGACCAUGUCUUGGUUUUUGCAAUAAUGCUAGCAGAGUACACACAAGAAGAAAAGUAACAGCA		5
20351	MI0006384	hsa-mir-1249	Homo sapiens miR-1249 stem-loop	GGGAGGAGGGAGGAGAUGGGCCAAGUUCCCUCUGGCUGGAACGCCCUUCCCCCCCUUCUUCACCUG		5
20352	MI0006385	hsa-mir-1250	Homo sapiens miR-1250 stem-loop	CUGUCCCGCUGGCCUGGCAGGUGACGGUGCUGGAUGUGGCCUUUUUGCCUUUUCUAAAGGCCACAUUUUCCAGCCCAUUCAACCUUCCAGAGCCCUCUGAAGUGGCCACAGGC		5
20353	MI0006386	hsa-mir-1251	Homo sapiens miR-1251 stem-loop	GUGGACUCUAGCUGCCAAAGGCGCUUCUCCUUCUGAACAGAGCGCUUUGCUCAGCCAGUGUAGACAUGGC		5
20354	MI0006387	hsa-mir-1253	Homo sapiens miR-1253 stem-loop	AGCAGCAAGAGAUAGAAUCCAAAAGAGAAGAAGAUCAGCCUGCAGAUGUGGACUGCUAAAUGCAGGCUGAUCUUCUCCCCUUUGGGAUUCUCUUAUGAGAAGCCA		5
20355	MI0006388	hsa-mir-1254	Homo sapiens miR-1254 stem-loop	GGUGGGAGGAUUGCUUGAGCCUGGAAGCUGGAGCCUGCAGUGAACUAUCAUUGUGCCACUGUACUCCAGCCUAGGCAACAAAAUGAAAUCCUGUCUA		5
20356	MI0006389	hsa-mir-1255a	Homo sapiens miR-1255a stem-loop	AUUGGAAAUCCUUUGAGUUGCUUCUCAAGGAUGAGCAAAGAAAGUAGAUUUUUUAGAUUCUAAAGAAACUAUCUUCUUUGCUCAUCCUUGAGAAGCAACUCCUUAUCCAUUAA		5
20357	MI0006390	hsa-mir-1256	Homo sapiens miR-1256 stem-loop	AGUCAGCCUGUUGAAGCUUUGAAGCUUUGAUGCCAGGCAUUGACUUCUCACUAGCUGUGAAAGUCCUAGCUAAAGAGAAGUCAAUGCAUGACAUCUUGUUUCAAUAGAUGGCUGUUUCA		5
20358	MI0006391	hsa-mir-1257	Homo sapiens miR-1257 stem-loop	GCCCUGGGCUUGUGCUUGGGGAGUGAAUGAUGGGUUCUGACCCCCAUGCACCCCUGUGGGCCCCUGGCAUCACUGGCCCCAUCCUUCACCCCUGCCAACCACGCUUGCCCUGUGCCU		5
20359	MI0006392	hsa-mir-1258	Homo sapiens miR-1258 stem-loop	CUGUGGCUUCCACGACCUAAUCCUAACUCCUGCGAGUCCCUGGAGUUAGGAUUAGGUCGUGGAAGCCACAGGA		5
20360	MI0006393	hsa-mir-1259	Homo sapiens miR-1259 stem-loop	GAACUUCCUGCUGGCAUAUAUGAUGACUUAGCUUUUUUCCCCGACAGAUCGACUAUGUUGAUCUAACUUUUCUAAGCCAGUUUCUGUCUGAUAUGCCAGCUUGAGCAGCUC		5
20361	MI0006394	hsa-mir-1260	Homo sapiens miR-1260 stem-loop	ACCUUUCCAGCUCAUCCCACCUCUGCCACCAAAACACUCAUCGCGGGGUCAGAGGGAGUGCCAAAAAAGGUAA		5
20362	MI0006395	hsa-mir-548g	Homo sapiens miR-548g stem-loop	AGUUAUUAGAUUAGUGCAAAAGUAAUUGCAGUUUUUGCAUUACGUUCUAUGGCAAAACUGUAAUUACUUUUGUACCAACAUAAUACUUC		5
20363	MI0006396	hsa-mir-1261	Homo sapiens miR-1261 stem-loop	UGCUAUGGAUAAGGCUUUGGCUUAUGGGGAUAUUGUGGUUGAUCUGUUCUAUCCAGAUGACUGAAACUUUCUCCAUAGCAGC		5
20364	MI0006397	hsa-mir-1262	Homo sapiens miR-1262 stem-loop	AUCUACAAUGGUGAUGGGUGAAUUUGUAGAAGGAUGAAAGUCAAAGAAUCCUUCUGGGAACUAAUUUUUGGCCUUCAACAAGAAUUGUGAUAU		5
20365	MI0006398	hsa-mir-1263	Homo sapiens miR-1263 stem-loop	CUACCCCAAAAUAUGGUACCCUGGCAUACUGAGUAUUUUAAUACUGGCAUACUCAGUAUGCCAUGUUGCCAUAUUUUGGGGUAGCA		5
20366	MI0006399	hsa-mir-548n	Homo sapiens miR-548n stem-loop	AGGUUGGUGCAAAAGUAAUUGUGGAUUUUGUCGUUAAAAAUAGCAAAACCCGCAAUUACUUUUGCACCAACCUAA		5
20367	MI0006400	hsa-mir-548m	Homo sapiens miR-548m stem-loop	AUAUUAGGUUGGUGCAAAGGUAUUUGUGGUUUUUGUCAUUAAAGUAAUGCAAAAGCCACAAAUACCUUUGCACCAACCUAAUAUUA		5
20368	MI0006401	hsa-mir-1265	Homo sapiens miR-1265 stem-loop	AUGGUUUGGGACUCAGGAUGUGGUCAAGUGUUGUUAAGGCAUGUUCAGGAACAAUACUUGACCACAUUUUGAAUUCCAAACCAUAU		5
20369	MI0006402	hsa-mir-548o	Homo sapiens miR-548o stem-loop	UGGUGAAAAUGUGUUGAUUGUAAUGGUUCCUAUUCUGAUCAAUAAACAUGGUUUGAGCCUAGUUACAAUGAUCUAAAAUUCACGGUCCAAAACUGCAGUUACUUUUGCACCAAC		5
20370	MI0006403	hsa-mir-1266	Homo sapiens miR-1266 stem-loop	ACAGGUAGUGUCCCUCAGGGCUGUAGAACAGGGCUGGGAUUACUAAAGCCCUGUUCUAUGCCCUGAGGGACACUGAGCAUGUCA		5
20371	MI0006404	hsa-mir-1267	Homo sapiens miR-1267 stem-loop	CUCCCAAAUCUCCUGUUGAAGUGUAAUCCCCACCUCCAGCAUUGGGGAUUACAUUUCAACAUGAGAUUUGGAUGAGGA		5
20372	MI0006405	hsa-mir-1268	Homo sapiens miR-1268 stem-loop	UAGCCGGGCGUGGUGGUGGGGGCCUGUGGUCCCAGCUACUUUGGAGGCUGAG		5
20373	MI0006406	hsa-mir-1269	Homo sapiens miR-1269 stem-loop	UGGAUUGCCUAGACCAGGGAAGCCAGUUGGCAUGGCUCAGUCCAAGUCUGACCACCUGAGGAAUGCCUGGACUGAGCCGUGCUACUGGCUUCCCUGGUCUCCAGC		5
20374	MI0006407	hsa-mir-1270	Homo sapiens miR-1270 stem-loop	CACAGAGUUAUACUGGAGAUAUGGAAGAGCUGUGUUGGGUAUAAGUAACAGGCUUUUCUUUAUCUUCUAUGUGGCUCUUUGCA		5
20375	MI0006408	hsa-mir-1272	Homo sapiens miR-1272 stem-loop	CCAGAUCAGAUCUGGGUGCGAUGAUGAUGGCAGCAAAUUCUGAAAACGUGCUCAGUGUCUUUAUAACAGGAAAGCCGUAAACUUAGAAAUGUAGGCUGCAGCUCGUGUGCUCUGUGGUCUGGGCUGGUA		5
20376	MI0006409	hsa-mir-1273	Homo sapiens miR-1273 stem-loop	UGAGGCAGGAGAAUUGCUUGAACCCGGGUGGUGGAGGUUGCAGUGAGCCAAGAUUGCGCCACUGCACUCCAGCCUGGGCGACAAAGCAAGACUCUUUCUUGGA		5
20377	MI0006410	hsa-mir-1274a	Homo sapiens miR-1274a stem-loop	GAUGUCCCUGUUUGUCCCUGUUCAGGCGCCACCUGUGGCUGUCUGCCACAAGUACUAUUUGAGACCAUCAC		5
20378	MI0006411	hsa-mir-548h-1	Homo sapiens miR-548h-1 stem-loop	UCUGUCCAUUAGGUGGGUGCAAAAGUAAUCGCGGUUUUUGUCAUUACUUUUAAUGGUAAAAACUGGAAUUACUUUUGCACUGACCUAAUAUUAAGCCAGAUA		5
20379	MI0006412	hsa-mir-548h-2	Homo sapiens miR-548h-2 stem-loop	GUAUUAGGUUGGUGCAAAAGUAAUCGCGGUUUUUGUCAUUACUUUCAAUGGCAAACACCACAAUUACUUUUGCACCAACCUAAUAUAA		5
20380	MI0006413	hsa-mir-548h-3	Homo sapiens miR-548h-3 stem-loop	UCUGAUUCUGCAUGUAUUAGGUUGGUGCAAAAGUAAUCGCGGUUUUUGUCAUUGAAAGUAAUAGCAAAAACUGCAAUUACUUUUGCACCAACCUAAAAGUAGUCACUGUCUUCAGAUA		5
20381	MI0006414	hsa-mir-548h-4	Homo sapiens miR-548h-4 stem-loop	GCUAUUAGGUUGGUGCAAAAGUAAUCGCGGUUUUUGUCAUUACUUUAAUUACUUUACGUUUCAUUAAUGACAAAAACCGCAAUUACUUUUGCACCAACCUAAUACUUGCUA		5
20382	MI0006415	hsa-mir-1275	Homo sapiens miR-1275 stem-loop	CCUCUGUGAGAAAGGGUGUGGGGGAGAGGCUGUCUUGUGUCUGUAAGUAUGCCAAACUUAUUUUCCCCAAGGCAGAGGGA		5
20383	MI0006416	hsa-mir-1276	Homo sapiens miR-1276 stem-loop	CCCCAGCUAGGUAAAGAGCCCUGUGGAGACACCUGGAUUCAGAGAACAUGUCUCCACUGAGCACUUGGGCCUUGAUGGCGGCU		5
20384	MI0006417	hsa-mir-302e	Homo sapiens miR-302e stem-loop	UUGGGUAAGUGCUUCCAUGCUUCAGUUUCCUUACUGGUAAGAUGGAUGUAGUAAUAGCACCUACCUUAUAGA		5
20385	MI0006418	hsa-mir-302f	Homo sapiens miR-302f stem-loop	UCUGUGUAAACCUGGCAAUUUUCACUUAAUUGCUUCCAUGUUUAUAAAAGA		5
20386	MI0006419	hsa-mir-1277	Homo sapiens miR-1277 stem-loop	ACCUCCCAAAUAUAUAUAUAUAUGUACGUAUGUGUAUAUAAAUGUAUACGUAGAUAUAUAUGUAUUUUUGGUGGGUUU		5
20387	MI0006420	hsa-mir-548p	Homo sapiens miR-548p stem-loop	AUUAGGUUGGUAUAAAAUUAAUUGCAGUUUUUGUCAUUACUUUCAAUAGCAAAAACUGCAGUUACUUUUGCACCAAUGUAAUAC		5
20388	MI0006421	hsa-mir-548i-1	Homo sapiens miR-548i-1 stem-loop	CAGAUGGCUCUGAAGUUUGCACCCUAUUAGGUUGGUGCAAAAGUAAUUGCGGAUUUUGCCAUUAAAAGUAAUGGCAAAAAUAGCAAUUAUUUUUGUACCAGCCUAGUAUCUUUUCUCCUUCUACCAAACUUUGUCCCUGAGCCAUCUCA		5
20389	MI0006422	hsa-mir-548i-2	Homo sapiens miR-548i-2 stem-loop	UAGAUGGCUCCGAAGUUUGCAUCCUAUUAGUUUGGUGCAAAAGUAAUUGCGGAUUUUGCCAUUAAAAGUAAUGGCAAAAAUAGCAAUUAUUUUUGUACCAGCCUAGUAUCUUUUCUCCUUCUAACAAAGUUCGUCCCUGAUCCAUCUCA		5
20390	MI0006423	hsa-mir-548i-3	Homo sapiens miR-548i-3 stem-loop	CAGAUGGCUCCGAAGUUUACAUCCUAUUAGGUUUGUGCAAAAGUAAUUGCGGAUUUUGCCAUUAAAAGUAAUGGCAAAAAUAGCAAUUAUUUUUGUACCAGCCUAGUAUCUUUUCUCCUUCUACCAAACUUUGUCCCUGAGCCAUCUCA		5
20391	MI0006424	hsa-mir-548i-4	Homo sapiens miR-548i-4 stem-loop	AGGUUGGUGCAAAAGUAAUUGCGGAUUUUGCCAUACUUUUAACGGCAAAAACCACAAAUAUUAUUGCACCAACCUAU		5
20392	MI0006425	hsa-mir-1278	Homo sapiens miR-1278 stem-loop	AUUUGCUCAUAGAUGAUAUGCAUAGUACUCCCAGAACUCAUUAAGUUGGUAGUACUGUGCAUAUCAUCUAUGAGCGAAUAG		5
20393	MI0006426	hsa-mir-1279	Homo sapiens miR-1279 stem-loop	AUAUUCACAAAAAUUCAUAUUGCUUCUUUCUAAUGCCAAGAAAGAAGAGUAUAAGAACUUCC		5
20394	MI0006427	hsa-mir-1274b	Homo sapiens miR-1274b stem-loop	CUUCUUCACUCACGUCCCUGUUCGGGCGCCACUUGUGGCUGUCGGUUCGGGACUGAAUGAAGAAGGA		5
20395	MI0006428	hsa-mir-1281	Homo sapiens miR-1281 stem-loop	AGGGGGCACCGGGAGGAGGUGAGUGUCUCUUGUCGCCUCCUCCUCUCCCCCCUU		5
20396	MI0006429	hsa-mir-1282	Homo sapiens miR-1282 stem-loop	CCUUCUUCUCGUUUGCCUUUUUCUGCUUCUGCUGCAUGAUCUCCGAGUCCCUGGGGGUAGAGAUGAUGGGGCACUGGGAGGUACCAGAGGGCAAAAAGGAC		5
20397	MI0006430	hsa-mir-1283-2	Homo sapiens miR-1283-2 stem-loop	CUCAAGCUGUGAGUCUACAAAGGAAAGCGCUUUCUGUUGUCUGAAAGAAAAGAAAUCGCUUCCCUUUGGAGUGUUACGGUUUGAGAA		5
20398	MI0006431	hsa-mir-1284	Homo sapiens miR-1284 stem-loop	AUUUUGAUAUAUAAGCCAGUUUAAUGUUUUCUAUACAGACCCUGGCUUUUCUUAAAUUUUAUAUAUUGGAAAGCCCAUGUUUGUAUUGGAAACUGCUGGUUUCUUUCAUACUGAAAAUCU		5
20399	MI0006432	hsa-mir-1288	Homo sapiens miR-1288 stem-loop	GAGGGUGUUGAUCAGCAGAUCAGGACUGUAACUCACCAUAGUGGUGGACUGCCCUGAUCUGGAGACCACUGCCUU		5
20400	MI0006433	hsa-mir-1292	Homo sapiens miR-1292 stem-loop	CCUGGGAACGGGUUCCGGCAGACGCUGAGGUUGCGUUGACGCUCGCGCCCCGGCUCCCGUUCCAGG		5
20401	MI0006434	hsa-mir-1252	Homo sapiens miR-1252 stem-loop	AGAAAGAAGGAAAUUGAAUUCAUUUAGAAAAGAGAAUUCCAAAUGAGCUUAAUUUCCUUUUUUCU		5
20402	MI0006435	hsa-mir-1255b-1	Homo sapiens miR-1255b-1 stem-loop	UACGGAUGAGCAAAGAAAGUGGUUUCUUAAAAUGGAAUCUACUCUUUGUGAAGAUGCUGUGAA		5
20403	MI0006436	hsa-mir-1255b-2	Homo sapiens miR-1255b-2 stem-loop	UCUUACGGAUGAGCAAAGAAAGUGGUUUGCGCCUCAAGAAACCACUUUCUUUGCUCAUCCAUAAGGA		5
20404	MI0006437	hsa-mir-1280	Homo sapiens miR-1280 stem-loop	UCUGUCCCACCGCUGCCACCCUCCCCUCUGCCUCAGUGUGCCAGGCAUCAGCACUCACUCACAGAGGCAGGCUGGAUGGCGGGUGGGACAACAG		5
20405	MI0006438	bol-MIR824	Brassica oleracea miR824 stem-loop	CCUCGAGUUGUCUUUCAUGUCUAGACCAUUUGUGAGAAGGGAUUUUUUGUUUGCACCGUUCACCCCACUUUCAAUCUGUAGUGAGUAUUAAGGAAAAUAGCUUGUUCAACAUAUCACACUACUCUUUUAGAAACAAUACUAUAUUUUAGAUGCUUUUCCAGCUUGAUAUACGUUGUUUUGUUAUGUAUAUCUGUAUUAUCCCGGCUACCAAAACGUUAAGAAAUAAGGUGAACAUCCUAAAACCUGCAUCCAAUUAGAAAGGUCUAGGUCACAGAUAUUACUUGUUAUCUCUUGAUUAAGCUAUUUUAUUUCUAUCAGCAUGAUCAGAUCAUUCAGGAGUUAAGUAUAAACUAAAAUACAUUAAGUCCAUUCAUGACAUUUCUGGAUGCUGCAUACAUAAUAUUUUCCUUGUUUUUGGACUAUGCCACACUUCGGACAGACAUUUUGCCUAAGAGAUGUCAAACCUCUGUCUGGAGUGUUAGAGGUAUUUCAUGAUAGCUAAGAACUUGAAUCUUGCACUACUUAGCUACACUAGAUUACUUCAUAGUAAAUAACUUGGGGAGUGGGGGAAGGUGCUGGGNUAUUAUUCCCUUCUCAUCGAUGGUCUAGAUGUGCGAGGUGACUCUCAUUGAGG		68
20406	MI0006439	bra-MIR824	Brassica rapa miR824 stem-loop	CCUCGAGUUGUCUUUCAUGUCUAGACCAUUUGUGAGAAGGGAUUUUUUGUUUGCACCGUUCACCCCACUCUCAAUCUGUAGUGAGUAUUAAGGAAAAUAGCUUGUUCAACAUAUCACACUACUCUUUUAGAAACAAAACUAUAUUUUAGAUGCUUUUCCAGCUUGAUAUACGUUGUUUUGUUAUGUAUACCUGUAUUCUCCCGGCUACCAAAACGUUAAGAAAUAAGGUGAACAUCUCCCCAAAACCUGCAUCCAAUUAGAAAGGUCUAGGUCACAGCCAUUACUUGCUAUCUCUCGAUUAAGCUAUUUUAUUUCUAUCAUCAUCAUCAGAUCAUUCAGGAGUUAAGUAUAAAAUAAAAUACAUUAAGUCCAUUCAUGACAUUUCUGGAUGCUGCAUACAUAAUAUUUUGUUUUUGGACUAUGCCACACUUCGGACAGACAUUUUUCCUACGAGAUGUCAAACCUCUGUCUGGAGUGUUAGAGGUAUUUCAUGAUAGCUAAGAACUUGAAUCUUGCACUACUUAGCUACACUAGUUUACUUCAUAGUAAAUAACUUGGGGAGUGGGGAAGGUGCUGGGUUAUUAGUCCCUUCUCAUCGAUGGUCUAGAUGUGCGAGGUGACUCUCAUUGAGG		69
20407	MI0006440	bna-MIR824	Brassica napus miR824 stem-loop	CCUCGAGUUGUCUUUCAUGUCUAGACCAUUUGUGAGAAGGGAUUUUUUGUUUGCACCGUUCACCCCACUCUCAAUCUGUAGUGAGUAUUAAGGAAAAUAGCUUGUUCAACAUAUCACACUACUCUUUUAGAAACAAAACUAUAUUUUAGAUGCUUUUCCAGCUUGAUAUACGUUGUUUUGUUAUGUAUACCUGUAUUCUCCCGGCUACCAAAACGUUAAGAAAUAAGGUGAACAUCUCCCCAAAACCUGCAUCCAAUUAGAAAGGUCUAGGUCACAGCCAUUACUUGCUAUCUCUCGAUUAAGCUAUUUUAUUUCUAUCAUCAUCAUCAGAUCAUUCAGGAGUUAAGUAUAAAAUAAAAUACAUUAAGUCCAUUCAUGACAUUUCUGGAUGCUGCAUACAUAAUAUUUUGUUUUUGGACUAUGCCACACUUCGGACAGACAUUUUUCCUACGAGAUGUCAAACCUCUGUCUGGAGUGUUAGAGGUAUUUCAUGAUAGCUAAGAACUUGAAUCUUGCACUACUUAGCUACACUAGUUUACUUCAUAGUAAAUAACUUGGGGAGUGGGGAAGGUGCUGGGUUAUUAGUCCCUUCUCAUCGAUGGUCUAGAUGUGCGAGGUGACUCUCAUUGAGG		57
20408	MI0006441	hsa-mir-1308	Homo sapiens miR-1308 stem-loop	CCCCGCAUGGGUGGUUCAGUGGCAGAAUUCUCAAAUUGUAAUCCCCAUAAUCCC		5
20409	MI0006442	hsa-mir-664	Homo sapiens miR-664 stem-loop	GAACAUUGAAACUGGCUAGGGAAAAUGAUUGGAUAGAAACUAUUAUUCUAUUCAUUUAUCCCCAGCCUACAAAAUGAAAAAA	This miRNA sequence overlaps an annotated snoRNA, ACA38b.  However, both miR and miR* sequences are identified in reference [1], and the sequence is homologous with rat mir-664. 	5
20410	MI0006443	hsa-mir-1306	Homo sapiens miR-1306 stem-loop	GUGAGCAGUCUCCACCACCUCCCCUGCAAACGUCCAGUGGUGCAGAGGUAAUGGACGUUGGCUCUGGUGGUGAUGGACAGUCCGA		5
20411	MI0006444	hsa-mir-1307	Homo sapiens miR-1307 stem-loop	CAUCAAGACCCAGCUGAGUCACUGUCACUGCCUACCAAUCUCGACCGGACCUCGACCGGCUCGUCUGUGUUGCCAAUCGACUCGGCGUGGCGUCGGUCGUGGUAGAUAGGCGGUCAUGCAUACGAAUUUUCAGCUCUUGUUCUGGUGAC		5
20412	MI0006445	bna-MIR397a	Brassica napus miR397a stem-loop	GAACAUCAUUGAGUGCAGCGUUGAUGUGAUUUACUUCUCUUUUUCAUUGUUGAAUGGAUUAAAGCAAUUUACAUCAACGUUGGCUCAAUUAUGUUU		57
20413	MI0006446	bna-MIR397b	Brassica napus miR397b stem-loop	GAACAUCAUUGAGUGCAGCGUUGAUGUGAUUUACUUAUCUUUUUCAUUGUUGAAUGGAUUAAAGCAAUUUACAUCAACGUUGGCUCAAUUAUGUUU		57
20414	MI0006447	bna-MIR390a	Brassica napus miR390a stem-loop	AUUUCAGGUGAUGUAGUUGAGAAGUAGCUGUAAAGCUCAGGAGGGAUAGCGCCAUGUCUCACCGGUACUAUAAAAUGUUUGUAUAUCUAUAUUGGCGCUAUCCAUCCUGAGUUCUAUGGCUUCUUCUUGCUUUUAUCCUGAGAU		57
20415	MI0006448	bna-MIR390b	Brassica napus miR390b stem-loop	GUAGAGAAGAAUCUGUAAAGCUCAGGAGGGAUAGCGCCAUCAUGAUCACACACAUCGAUAUUUUUGGCGCUGUCCAUCCUGAGUUUCAUUGGCUCUUCUUACUAC		57
20416	MI0006449	bna-MIR390c	Brassica napus miR390c stem-loop	GCGUAGUAGAGAAGUAGCUGUAAAGCUCAGGAGGGAUAGCGCCAUGACUCAUCACCAUUACUAUAUGUCUUUGUAUAUGUAAUGGCGCUAUCCAUCCUGAGUUCCAUGGCUUCUUCUUGCUUUUAUGU		57
20417	MI0006450	bna-MIR171a	Brassica napus miR171a stem-loop	UGGUCAAGCGAGAUAUUAGUGCGGUUCAAUCAAAUAGUCUCACUCUUAGUUGAUAGAGAUUGAUUUUGUUCGAUUGAGCCGUGCCAAUAUCACGCAUAUAACCA		57
20418	MI0006451	bna-MIR171b	Brassica napus miR171b stem-loop	GGUAACGCGAGAUAUUAGUGCGGUUCAAUCAAAUAGUCGUGUUCUCACUUGAUAGAGAUCGGUUUUGUUCGAUUGAGCCGUGCCAAUAUCACGCGUCAACC		57
20419	MI0006452	bna-MIR171c	Brassica napus miR171c stem-loop	GCGAGAUAUUAGUGCGGUUCAAUCAAAUAGUCGUACUCUUAGCUAUUAGAGAUCGGUUUUGUUCGAUUGAGCCGUGCCAAUAUCACGC		57
20420	MI0006453	bna-MIR171d	Brassica napus miR171d stem-loop	ACAAUGCGAGAUAUUGGUGCGGUUCAAUCAGAAAUCCACACUCUUUUGUUGUAGAGAUCGGUUUGUUUGAUUGAGCCGUGCCAAUAUCACGAGUGU		57
20421	MI0006454	bna-MIR171e	Brassica napus miR171e stem-loop	CAAUACGAGAUAUUGGUGUGGUUCAAUCAGAAAACCACACUCUUUUGUUGUAGAGAUCGGUUUGUUUGAUUGAGCCGUGCCAAUAUCACGAG		57
20422	MI0006455	bna-MIR171f	Brassica napus miR171f stem-loop	ACGAAAGAGUCCUCUUUGAUAUUGGCCUGGUUCACUCAGAUCUUCCAGAUUACACACGUACUAUAUACAUUCUCUCAGUUAUCUGAUUGAGCCGCGCCAAUAUCUCAGUGCUCUCUCGU		57
20423	MI0006456	bna-MIR171g	Brassica napus miR171g stem-loop	AGCACGAAAGAGUCCUCUUUGAUAUUGGCCUGGUUCACUCAGAUUACACACGUACUAUAUGCAUUCUCUUAGUUAUCUGAUUGAGCCGCGCCAAUAUCUCAGUGCUCUCUCGUCU		57
20424	MI0006457	bna-MIR169a	Brassica napus miR169a stem-loop	UGUGACCAAAGUAGUGUGCAGCCAAGGAUGACUUGCCGAUUUAAAAUAUCUGAUAAGUAUUUUAUUUCGUAUUUUAAAGAAAAAAAUCAUGAUCGGCAAGUUGUCCUUGGCUAUACGUUUCUUUGUGUCGCG		57
20425	MI0006458	bna-MIR169b	Brassica napus miR169b stem-loop	GUGACCAAAGUAGUGUGCAGCCAAGGAUGACUUGCCGAUUUGAAAUAUAUUUUUAAUACUUUACUAAGACAUCUUUUCAGUUUCAAAUUUGUCUUGGAGAGGCUAGGAAGAAAUUACAAUUUAUUUCGUAGUUUAAAGAAAAAAUAUGAUCGGCAAGUUUUCCUUGGCUACAUGUUUCUUUGUGUCGC		57
20426	MI0006459	bna-MIR169c	Brassica napus miR169c stem-loop	AGAUGAAUAGAAGAAUCAUAUUUGGUAGCCAAGGAUGACUUGCCUAUUUCUUGAGAGUAAAAUGGGCAUGGUGUCAUGUUAAAAGUUACUGUAGGUAGUUUCAAUUUGACCAUUUUCCUUACAAAUGAUAUUAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUCUCUCAUCU		57
20427	MI0006460	bna-MIR169d	Brassica napus miR169d stem-loop	GAAGGAGAUGUCAAAGAUGAAUAGGAGAUUUCUAUUUGGUAGCCAAGGAUGACUUGCCUACUUCUUUGCGAAGGAAAAUGGUCACGGUGUCAUGUUUGAAAGUGAAUAUACAUUUUUAAGAGUAUAUCAAUUAGUGACCAUUUUGCGUAUAAAAAGAUAUUAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUUUCUCAUCUCAGACAUUUACCUUC		57
20428	MI0006461	bna-MIR169e	Brassica napus miR169e stem-loop	GUUUCAGGCAGUCUCCUUGGCUAUCUUGACAUGCUUUUUUCUUCCAUGUUAUACCUUCUUUCUUUGUAUUUUUCGAAUCCAAAUAAUAUUUUUUUCUAUAAAUUUACUACGAAAAUCCUUUAAACAAUCUCUAACAAAGUAUGUUAUUAGAAAACUACCACUUUUUGCAUUUAUUACAAAUGCAUGUACGUGGUGAGUGUAUGCAUUCUUUAGAAGGAAAUGUCAAAGGUGAAUAGAAGAUCAUAUUUGGUAGCCAAGGAUGACUUGCCUAUUUCU		57
20429	MI0006462	bna-MIR169f	Brassica napus miR169f stem-loop	GUCAAAGAUGAAUAGGAGAAUUCUAUUUGGUAGCCAAGGAUGACUUGCCUACUUCUUUGCGAAGGAAAAUGGUCACGGUGUCAUGUUUGAAAGUGAAUAUAUAUUUAUAAGAGUAUAUCAAUUAGUGACCAUUUUGCGUAUAAAAAGAUAUUAGGCAGUCUCCUUGGCUAUCCUUAUAUGUUCUUCUUUCUCAUCUCAGAC		57
20430	MI0006463	bna-MIR169g	Brassica napus miR169g stem-loop	GAGAAACGGUGACAUGAAGAAUGAGAAGUUGUGUGGUAGCCAAGGAUGACUUGCCUGCGUCUUUAACACCAUAUCAAAGACUUUAUCGAUAGUCUCUGAGUUGGUUAGGCUGUAGGCAGUCUCCUUGGCUAUUCAGACACUCCUCUUUCUCCUCAUUUCACAUUUCUC		57
20431	MI0006464	bna-MIR169h	Brassica napus miR169h stem-loop	GAGAAAUGGUGACAUGAAGAAUGAGAAGUUGUGUGGUAGCCAAGGAUGACUUGCCUGCGUCUUAGACCAUAUCUAUCAAAGACUAAAAGAUUGAUAGUCUUCGAUGAAUUGGUUAAUCGGUAGGCAGUCUCCUCGGCUAUUCAGACAGUUCUCUUUCUCCUCAUUUCACAUUUCUC		57
20432	MI0006465	bna-MIR169i	Brassica napus miR169i stem-loop	AGAGUCAUGUUUAGUAGCCAAGGAUGACUUGCCUGCUCUUUUUCACCUCCAUGAUUCAAUUUUAUGUACAGUUUUGGAUUACUAUGCUUCUAAAGAGUAUAGUAAUUCAAAAUCUUGUUGAAUCUUUGAGGGUAACAGUUUCAGGCAGUCUCCUUGGCUAUCUUGACAUGCUUU		57
20433	MI0006466	bna-MIR169j	Brassica napus miR169j stem-loop	GUGUUUAGUAGCCAAGGAUGACUUGCCUGCUCUUGUUCACCUCCACGAUUCAACUUUAUACGUUGAAGGGUUUUGGAUUAUUGUGCAUUCAACAUGUAUAAUAAUUUGAAAUCAUGUUGAAUCUUUGUGGGUUAGGUUUCAGGCAGUCUCCUUGGCUAUUUUGACAU		57
20434	MI0006467	bna-MIR169k	Brassica napus miR169k stem-loop	AAACGGUGACAUGAAGAAUGAGAAGUUGUGUGGUAGCCAAGGAUGACUUGCCUGCGUCUUAACACCAUAUCACAGACUUUAUCGAUAGUCUCUGAGUUGGUUAGGCUGUAGGCAGUCUCCUCGGCUAUUCAGACACUCCUCUUUCUCCUCAUUUC		57
20435	MI0006468	bna-MIR169l	Brassica napus miR169l stem-loop	CAUGGCGAAAAGAGUCGUGUUUAGUAGCCAAGGAUGACUUGCCUGCUCUUGUUCACCUCCACGAUUCAACUUUAUACGUUGAAGGGUUUUGGAUUAUUGUGCAUUCAACAUGUAUAAUAAUUUGAAAUCAUGUUGAAUCUUUGUGGGUUAGGUUUCAGGCAGUCUCCUUGGCUAUUUUGACAUACUUUUUUCAUCCAUG		57
20436	MI0006469	bna-MIR169m	Brassica napus miR169m stem-loop	UAUAUGUAUCAGAGAGUCAUGCAUGGGAAAAUAGAGAAUGAUAAUGAGCCAAAGAUGACUUGCCGAUUUUACCAAAGAAUUUAAAACUGAUAAUGGUGACUGGCAAGUCGACUUUGGCUCUGUUUCCUUCUCUUCUUUUCGAUGUAAGACUCUAGAUAUCUAU		57
20437	MI0006470	bna-MIR168	Brassica napus miR168 stem-loop	UUACGGCGGCCUCUGACUCGCUUGGUGCAGGUCGGGAACUGAUUGGCUGACACCGCCACGUGGCUUUCCAUGGUUGGCUUGUGAGCAGGGAUCGGAUCCCGCCUUGUAUCAAGUGAAUCCGAGUCCGACGUGA		57
20438	MI0006471	bna-MIR167a	Brassica napus miR167a stem-loop	GGUGUACAGGCAUCUGAUGAAGCUGCCAGCAUGAUCUAAUUAACUUUCUUUCUCUGUUGAUUUUAUGACAAUGGAAAAGAGAUGAGUGUCGAUUAGAUCAUGUUCGCAGUUUCACCCAUUGACUGUCGCACC		57
20439	MI0006472	bna-MIR167b	Brassica napus miR167b stem-loop	GGCGCACCGGCAUCUGAUGAAGCUGCCAGCAUGAUCUAAUUAUCUUUCUUUCUCUGUUGACGAUGGAAAAGACAUGAGUGUUGAUUAGAUCAUGUUCGCAGUUUCACCCGUUGACUGUCUCGCC		57
20440	MI0006473	bna-MIR167c	Brassica napus miR167c stem-loop	GGUGCACCGGCAUCUGAUGAAGCUGCCAGCAUGAUCUAGUUAACUUUAUUUCUCCGUUGUUUAUCCAUGACAAUGGAAAAGGGAUAAGUGUCGAUUAGAUCAUGUUCGUAGUUUCACCCGUUGACUGUCGCAUC		57
20441	MI0006474	bna-MIR166a	Brassica napus miR166a stem-loop	UUGAGGGAAUGUUGUUUGGCUCGAAGACUCUAGCUUAUCAUGUUAGAUCUUCUUCGAUUUAAUCGAAUCAAACCUCCAUGUUUGAGAUCUGAUUUAGGAUUUUAGGGUCGUCGGACCAGGCUUCAUUCCCCCCAA		57
20442	MI0006475	bna-MIR166b	Brassica napus miR166b stem-loop	AAGUUCAGGUGGAUGAUGCUUGGCUCGAGACCAUUCAAUAUGAUCAUUGUGAUGAUGAUGAUGAUGAUGAUAAUGAUAAUGAUAAUGAUGUCGGACCAGGCUUCAUUCCCCUCAACUU		57
20443	MI0006476	bna-MIR166c	Brassica napus miR166c stem-loop	GAGCCAAAAGUUCAGGUGGAUGAUGCUUGGCUCGAGACCAUUAAAUAUGAUCAUUGUGAUGUUGAUGAUGAUGAUGAUAAUGAUAAUGAUAGUCGGACCAGGCUUCAUUCCCCUCAACUUACACGUUU		57
20444	MI0006477	bna-MIR166d	Brassica napus miR166d stem-loop	GUGGUGCGGUUUAGGGCUGAGAGGACUGUUGUCUGGCUCGAGGUCAUGAAGAAUGAAACCUAAACCUAAAUGAUUCUCGGACCAGGCUUCAUUCCCCCCAGCCGUUUUAUCGCCAUAUAUAUGCCCAC		57
20445	MI0006478	bna-MIR164	Brassica napus miR164 stem-loop	CCACGUUGGAGAAGCAGGGCACGUGCAAACCAACAAACACGAGAUCUAUCUCAUGUAAUUUGCACGUGCUCCACUCCUCCAACAUG		57
20446	MI0006479	bna-MIR161	Brassica napus miR161 stem-loop	UUUAUUGCUUCGAUCAAUGCACUGAAAGUGACUACACCAGGAUUUGUUUUUAAGUUUUUGCUCUCAUCUAUAUGAUAAAGAUGAAAAUUAGCCUCUGAUGUAGUCACUUUCAAUGCGUUGAUCAUAGCAUGGAAA		57
20447	MI0006480	bna-MIR159	Brassica napus miR159 stem-loop	GUAGGGCUCCUUAUAGUUCAAACGAGAGUUUAGCAGGGUAAAGAAAAGCUGCUAAGCUAUGAAUCCCAUAAGCCCUAAUCCUUAUAUAUAAAAAGGAUUUGGUUAUAUGGCUUACAUAUCUCAGGAGCUUUAACUUGCCCUUUAAUUGCUUUUACUCUUCUUUGGAUUGAAGGGAGCUCUACA		57
20448	MI0006481	bna-MIR156b	Brassica napus miR156b stem-loop	UAGGUUUGAGAGUGAUGCUGGUUGUUGACAGAAGAUAGAGAGCACUAAGGAUGACAUGCAAGUACAUAUGUAUGUAUCAUCACACCGCCUGUGGAUGAUUACAAAAAUAAAACCAAUUCAAAAGAGAGAGAGAGAGAGCCUGCAUGUCUACUCUUUCGUGCUCUCUAUACUUCUGUCACCACCAUUAUUUCUUCUUCUUUCUUACCUA		57
20449	MI0006482	bna-MIR1140a	Brassica napus miR1140a stem-loop	CUCAAUCUUUUAUAUGGCUCCGAUUGGCUUUAGGCUGUUGUGGCUUUGACUUCUUUCUAAAGUCUUCAAAAUUUAGUUUUUCACAAUCACGUUAAAUUUUUUUAAAAGUCACAGCCACAACAGCCUAAACCAAUCGGAGCCAUGGUGAUG		57
20450	MI0006483	bna-MIR1140b	Brassica napus miR1140b stem-loop	CUCAAUCUUUUAUAUGGCUCCGAUUGGCUUUAGGCUGUUGUGGCUUUGACUUCUUUCUAAAGUCUUCAAAAUUUAGUUUUUCACAAUCACGUUAAAUUUUUUUAAAAGUCACAGCCACAACAGCCUAAACCAAUCGGAGCCAUGGUGAUG		57
20451	MI0006484	bna-MIR156c	Brassica napus miR156c stem-loop	GGGAGUGAUGCAGGUUGUUGACAGAAGAUAGAGAGCACUAAGGAUGACAUGCAAGUACAAGGAUAUAAGGAAAUUCAAGAAAGAGAGGAAAAAAGAGCCUGCAUCUUUACUCUUUUGUGCUCUCUAUACUUCUGUCAAUACCAUUAUUUAUUCCU		57
20452	MI0006485	vvi-MIR156a	Vitis vinifera miR156a stem-loop	AGAAAUAUGUUGACAGAAGAGAGGGAGCACAACCCAGCAUCAGCUAAAGACUCUUUGCUUUUCUUGGGAGUGUGCUCUCUCUUCUUCUGUCAUCAUCACACUCC		70
20453	MI0006486	vvi-MIR156b	Vitis vinifera miR156b stem-loop	CAUUGAAAACUGACAGAAGAGAGUGAGCACACAGAGGCAAUUGUAUAAGUUUAUGCUUUUGCUUUUGCGUGCUCAUUUCUCUUUCUGUCAGCUUCCAGUGCC		70
20454	MI0006487	vvi-MIR156c	Vitis vinifera miR156c stem-loop	AAGGAAUAGGUGACAGAAGAGAGUGAGCACACAUGGUCUGUUCUUGCAUGGGUCCAUGCUUGAAGCUCUGCGUGCUCACUCUCUAUCUGUCAUCUGUCCUCUCU		70
20455	MI0006488	vvi-MIR156d	Vitis vinifera miR156d stem-loop	AGAGAGAGACUGACAGAAGAGAGUGAGCACAUGCAGGCAAUUUGUAUAAGGGUAUACCUAUGCCGGUGCGUGCUCACCUCUCUUUCUGUCAGCUUCAGGUGCU		70
20456	MI0006489	vvi-MIR156e	Vitis vinifera miR156e stem-loop	GUAUGGUAGGUGACAGAGGAGAGUGAGCACUCAUGGUUCUUUUCUUGCAUGAAGUUUCUAUGCUUGAAGCUCUGUGUGCUUACUCCCUAUCUGUCACCCCUCAAGCAU		70
20457	MI0006490	vvi-MIR156f	Vitis vinifera miR156f stem-loop	UUAUGUUCUGUUGACAGAAGAUAGAGAGCACAACUGAACAUACCCAAGAGGGCUUGUGUUUGAGCAGUCUUGUCCUCUCUCUUCUCCUGUCAACAGAACUUGCUG		70
20458	MI0006491	vvi-MIR156g	Vitis vinifera miR156g stem-loop	GGUGAUGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAUGUGCAUGGAGUUUGCAUCUCACUCCUUUGUGCUCUCUAGACUUCUGUCAUCACCUCAGCCCC		70
20459	MI0006492	vvi-MIR156i	Vitis vinifera miR156i stem-loop	GGUGACGUUGUUGACAGAAGAUAGAGAGCACAGAUGAUGAAAUGCAAGGAGCCAGCAUCUCACUCCUUUGUGCUCUCUAUUCUUCUGUCAUCACCUUAAGGCC		70
20460	MI0006493	vvi-MIR159a	Vitis vinifera miR159a stem-loop	GGGUUUAUGGGAGCUCCUUUACGCUCCAGUUCUGAAAGGAGAUGAUGGUAUCCACAGCUGCUGGUUCAUGAGUACCUAUGGCUGCACAAUAUAUAUAGCAAUGUUGUGUGCAAACUAUGGGUGUGCAUGACCUCGGAGAAGUGGUUGCCUUGAUCUUUCUGGCCUUGGAGUGAAGGGAGCUCUCAUAACCCUUC		70
20461	MI0006494	vvi-MIR159b	Vitis vinifera miR159b stem-loop	GGGCUUGUGGGAGCUUCUUUACACUCCAGAACUGAAAGGAGAUACUACUGCUGGUUCAUGAAAACCUAUGGCUGCAUUCUCUAUACUGAAAUUUUGUAUACAAACUAUGGGUUUGCAUGAACUUGGAGAAGUGUUUGCUUUUAUCUUUUCUGGCCUUGGAGUGAAGGGAGCUCUCAUAACCGAUC		70
20462	MI0006495	vvi-MIR159c	Vitis vinifera miR159c stem-loop	UUUUGGAGUGGAGCUCCUUGAAGUCCAAUAGAGGGUCUUACUGGGUAGAUUGAGCUGCUGACUUAUGGAUCCCACAGCCCUAUCCCGUCAAUGGGGGGCAUUGGAUAGGCUUGUGGCUUGCAUAUCUCAGGAGCUGCAUUAUCCAAGUUUAGAUCCUUGUUUGGAUUGAAGGGAGCUCUACACCUCUCUC		70
20463	MI0006496	vvi-MIR160a	Vitis vinifera miR160a stem-loop	GGGGUUGAUCUGCCUGGCUCCCUGAAUGCCAUCUAAGAAGCUUGUCAAGGUUGUUGACUCUCUUCCUAGUUGGCAUCAGAGGAGUCAUGCAGGCCCCAACAUU		70
20464	MI0006497	vvi-MIR160b	Vitis vinifera miR160b stem-loop	AAUAUUGUUCUGCCUGGCUCCCUGAAUGCCAUCUAAGAAGCUUGUUAAAGAGUGUUGACAACCUUCCUAUUUGGCAUGAGGGGAGUCAAGCAGGCGAAACACUU		70
20465	MI0006498	vvi-MIR160c	Vitis vinifera miR160c stem-loop	AAAUGGGUUGUGCCUGGCUCCCUGUAUGCCACACGUAGAGACCACUCCCUUUCCCGGAUUGGCUAUUUGCGGGUGGCGUGCGAGGAGCCAAGCAUACCCACCAUUC		70
20466	MI0006499	vvi-MIR160d	Vitis vinifera miR160d stem-loop	CAUACUUACAUGCCUGGCUCCCUGUAUGCCAUUUGCAAAGUCCACCCGAGGAUUGGUAGCCUUCGCGGAUGGCGUGCGAGGAGCCAUGCAUGCAUCUUGCUU		70
20467	MI0006500	vvi-MIR160e	Vitis vinifera miR160e stem-loop	AAUAUUGUUCUGCCUGGCUCCCUGAAUGCCAUCUAAGAAGCUUGUUAAAGAGUGUUGACAACCUUCCUAUUUGGCAUGAGGGGAGUCAAGCAGGCGAAACACUU		70
20468	MI0006501	vvi-MIR160f	Vitis vinifera miR160f stem-loop	UAAGCAUAUAUGCCUGGCUCCCUGUAUGCCAUUUGCAGAGCCCACCGGCACAUCGAUGGCCUUCGUGGAUGGCGUAUGAGGAGCCAUGCAUAUGCCCCAUCU		70
20469	MI0006502	vvi-MIR162	Vitis vinifera miR162 stem-loop	UGAAGUCACUGGAUGCAGCGGUUCAUCGAUCUCUUCCUGAAAUUGUUGUGAAAAAAGCAGAUCAAGAAUCGGUCGAUAAACCUCUGCAUCCAGCGUUCACUCC		70
20470	MI0006503	vvi-MIR164a	Vitis vinifera miR164a stem-loop	AGCUCCUUGUUGGAGAAGCAGGGCACGUGCAGAUUUGCCUCACUUUUCCCCCUUUUUUCUUCUUUACUCCCACCACCGCCCACAGGCUUGCACGUGCUCCCCUUCUCCAACAUGGGUUCCU		70
20471	MI0006504	vvi-MIR164b	Vitis vinifera miR164b stem-loop	UAAACCAUGCUGGAGAAGCAGGGCACAUGCUGGAUCAAUCAGCACCUGGAUCUGAGAUUUUACAUGUGCCCUGGCUCUCCCACUUGGAUCCUA		70
20472	MI0006505	vvi-MIR164c	Vitis vinifera miR164c stem-loop	UUGAGCAAGAUGGAGAAGCAGGGCACGUGCAUUACUAGCUCAUGCACCACAAACCAAUAAUCUUUUGCUCGAGUUAGACUCUUGCUUGCUGCUUUGA		70
20473	MI0006506	vvi-MIR164d	Vitis vinifera miR164d stem-loop	AAGCUCUUGAUGGAGAAGCAGGGCACGUGCAGUUCACAAAUUCUAAUCUGCUCUGCACGUGCAGUUCACAAAUUCUAAUCUGCUCUGCACGUGCUCCCCUUCUCCAACAUGGGUUCCU		70
20474	MI0006507	vvi-MIR166a	Vitis vinifera miR166a stem-loop	GCGGGUGUUUGGAAUGAGGUUUGAUCCAAGAUCCUUCCUUUUUCUCCAUUAAUUCCUUCAGUACUGGUCAUGAUUUAGUUACUUCAUAAUCGGUUGAUCUCGGACCAGGCUUCAUUCCUGACACCAAGCU		70
20475	MI0006508	vvi-MIR166b	Vitis vinifera miR166b stem-loop	GUUUUUUGAGGGGAAUGUUGGCUGGCUCGAGGCAUUCACAUAAGAAGAAGAUAUAUAAGUGAAGGUGUCGGACCAGGCUUCAUUCCUCUCAAAUAUACA		70
20476	MI0006509	vvi-MIR166c	Vitis vinifera miR166c stem-loop	CUAUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACACUUACCUUAACUUUGAUCCGUUUCUCUAGAUCCAUAUCACCUAUAUAUAUGUAUUAUUGUAUUUUUAUUUGUACUGAGCAUGUGUUGGUGUCGUCGGACCAGGCUUCAUUCCCCCCAAUUAUCGC		70
20477	MI0006510	vvi-MIR166d	Vitis vinifera miR166d stem-loop	CUGCUUUGAGGGGAUUGUUGUCUGGCUCGAGGCCACCAACCAUCUUUGAUUGAUUCAAAUACUUUGAUCAGCUUCAACCCAUCUUCUCCUUCAAUUCAAUUCCACCCUCUGAUUAUGUGUUAGUGCCCUCGGACCAGGCUUCAUUCCCCUCAAUCACUGC		70
20478	MI0006511	vvi-MIR166e	Vitis vinifera miR166e stem-loop	GUGUUUUGAGGGGAAUGUUGUCUGGCUCGAGGACACCAACUAGAUCUAUGAUCUGCGUGUAAUUGUGAAUGGGUGAUCGUCUCUCAGUUUUGAAGGAGAGAUUUUGAGUGAUCUUUGAUCAUGGGUUGGUGUCGUCGGACCAGGCUUCAUUCCCCCCAAUUUAUUG		70
20479	MI0006512	vvi-MIR166f	Vitis vinifera miR166f stem-loop	UGUAGUUGUGGGGAAUGUUGGCUGGCUCGAGGCUUUCUUGAGUGAUUUUAUGUAUACCUCAAAAAGCUUCGGACCAGGCUUCAUUCCCCUCAACACACUU		70
20480	MI0006513	vvi-MIR166g	Vitis vinifera miR166g stem-loop	AACAGUUGAGGGGAAUGUUGUCUGGUUCGAGAUCCUUCGUAUGAAGCUCAAGCAGCGUUUGAAUGAUUUCGGACCAGGCUUCAUUCCCCUCAACCCAAAA		70
20481	MI0006514	vvi-MIR166h	Vitis vinifera miR166h stem-loop	AACAGUUGAGGGGAACGCUGUCUGGUUCGAGACCACUCGCUUCAAGUACAGACAUAAUCUGAAUGAUCUCGGACCAGGCUUCAUUCCCCCCAACUCAACA		70
20482	MI0006515	vvi-MIR167a	Vitis vinifera miR167a stem-loop	UUUGAGAGGUUGAAGCUGCCAGCAUGAUCUGGUGAAACAAACACCAUCUCUUUCUUCUCUAACCCCAUGUCUGGAUUCGUCCACCGAUCCAUUAUUAUAGACCAGGCCGCCCGUUUCCCAUGUAGUGAUCGAUAAUUAGGCUCGGGGUUUUCACUUUUUAGUGGGAUCUAAUCCUUAGGAUGGAUGUUUGUAUGGGUGGUAUAUAUCAUGGUGAGGUCUGUUUUCUAUUUUAAUUCUAACGGGGUUUUGAUUUAGCUGAGGGGGUAUAAUUCAUAGCCUAAUUCCAAAACCUAACUCCAUAGAGAUAGGGUUCCAUGAUCAGGUCAUCUUGCAGCUUCAAUCACUCACUCA		70
20483	MI0006516	vvi-MIR167b	Vitis vinifera miR167b stem-loop	CAAUAGCAGUUGAAGCUGCCAGCAUGAUCUAAGCUUUUCUGUUGCCCACCCUUUCUCCAGGAAAGACUAGAUCAUGUGGCAGUUUCACCUGUUGAUGGA		70
20484	MI0006517	vvi-MIR167c	Vitis vinifera miR167c stem-loop	CAGUAGCAGUUGAAGCUGCCAGCAUGAUCUCAACUUCCCUAUACAAGUCAAGGAAAGAUCAGAUCAUGUGGUAGCCUCACCUGUUGAUGGG		70
20485	MI0006518	vvi-MIR167d	Vitis vinifera miR167d stem-loop	AGGGAAUAAGUGAAGCUGCCAGCAUGAUCUAGCUUUGGCUAGGGAUACAGAGAAAGAGAGAGAUCAGAGCUAACCCUAGCUAGGUCAUGCCCUGACAGCCUCACUCCUUCCUUCU		70
20486	MI0006519	vvi-MIR167e	Vitis vinifera miR167e stem-loop	CACUAUCAGUUGAAGCUGCCAGCAUGAUCUAAACUUGCUUCCCUUUGUGAACAGAGAUCAGAUCAUGUGGCAGUUUCACCUGUUGUUGGU		70
20487	MI0006520	vvi-MIR168	Vitis vinifera miR168 stem-loop	GGUCUCUAAUUCGCUUGGUGCAGGUCGGGAACCGACUUCGCCGCUCCGGCAGCGCCGGAGGCACGCGGCGGCCUACGAUUGGUUGCUGAGCGAAUUCCGAUCCCGCCUUGCAUCAACUGAAUCGGAGACGGC		70
20488	MI0006521	vvi-MIR169a	Vitis vinifera miR169a stem-loop	GAGAGUGGAAUGCAGCCAAGGAUGACUUGCCGGAAUUUAUAUAUAGUGAGAAGAGAAGAGGCUAUAUGCUUUCACAUAUAUAGUGAACCCUGGCAAGUUGUCCUUGGCUACAUUUGAUUCUCUU		70
20489	MI0006522	vvi-MIR169y	Vitis vinifera miR169y stem-loop	CGUUGUUUGGUAGCGAAGGAUGACUUGCCUACAGCCUCCUUAAGGUUUCAAAAUACCGAGCUUGUCUACCUUUGAUCAAAUGAUUCAAGAAACAAAAGAAAAGAAAGGCCAUGGCAGCCAUCCAUCAGAGUCAACAUGAGAAUCAUGUUCUAUAGAAAUUGGAGUCAUUCUUGAGAAUGAACACGACACUAUUAGCUUGGAAUCUAUAAUGUGGUUUAUGGCAAGUCUCCUUGGCACCUGAUGGCCUC		70
20490	MI0006523	vvi-MIR169c	Vitis vinifera miR169c stem-loop	GGGAGUAGAAUGCAGCCAAGGAUGACUUGCCGGAGAUGGGGCAUUCCUCGUUAAUCCGGCAAGUUGUCCUUGGCUACAUUGGGCUCUCUU		70
20491	MI0006524	vvi-MIR169d	Vitis vinifera miR169d stem-loop	GAGUGGAAUGCAGCCAAGAAUGAUUUGCCGGAAUUUAUAUAUAGUGAGAAGAGAAGAGGCUAUAGGCUUUCACAUAUAUAGUGAACCCUGGCAAGUUGUCCUUGGCUACAUUUGAUUCUC		70
20492	MI0006525	vvi-MIR169e	Vitis vinifera miR169e stem-loop	GUCUUGUCUGAUAGCCAAGGAUGACUUGCCUGCCCUAUCCCAAGUGGGUCAAUUUCUUUCUUUUUUCCAAGUAGUGUUUGAUAUUUGAUAUAUCAUGAAUCCGGUUGUUUGGGUUCCAGGCAGUCACCUUGGCUAAUUUUACAGGCUCU		70
20493	MI0006526	vvi-MIR169f	Vitis vinifera miR169f stem-loop	GAUAUUAUGGUGCAGCCAAGGAUGACUUGCCGAAAAUAAUUUGCUCGAUCGUUAAUGUGCUUCUCCAGUUUCUAUUGCAAUUUAUGCAUAGGGCAAUAUAUAUAUCCUUUAUAGCUUGUUAAUUCAGAUAUUGACUGAGGAAUCAAUAAUGGGCAAGUUGUGUUUGGCUACAUGUUUAUCUCAU		70
20494	MI0006527	vvi-MIR169g	Vitis vinifera miR169g stem-loop	GAAAGUAUGGUGCAGCCAAGGAUGACUUGCCGACUCUCUACUUAGCCAUCUGCCUUUCUCCAAGGAGGCUUGCAGUACUGAUGAAGCCGGCAAGUUGUCUUUGGCUACAUGCUUCUUUCUG		70
20495	MI0006528	vvi-MIR169j	Vitis vinifera miR169j stem-loop	GAGAGUGGAGUGCAGCCAAGGAUGACUUGCCGGAAUUCACAUAUAGAGUGGAAUGAGGCAAUAGACCGGCCUCUUCUCAUGGUGUCCCUGGCAGGUUGUCCUUGGCUACCUUUCGCUCUCUU		70
20496	MI0006529	vvi-MIR169k	Vitis vinifera miR169k stem-loop	GAGAGUGGAGUGCAGCCAAGGAUGACUUGCCGGAAUUCACAUAUAGAGUGGAAUGAGGCAAGAGGCCGGCCUCUUCCCAUGGUGUCCCUGGCAGGUUGUCCUUGGCUACCUUUCGUUCUCUU		70
20497	MI0006530	vvi-MIR169m	Vitis vinifera miR169m stem-loop	AGAGUGGAAGUGAGCCAAGGAUGACUUGCCGGCAGCUGCAGCAAGGCAUUAAGGUUUAACUGGCCAUAACUGGCAAGCAUCCGAGGCUCUGUUUCACCCUCU		70
20498	MI0006531	vvi-MIR169p	Vitis vinifera miR169p stem-loop	AGUGUGGAAUUGAGCCAAGGAUGACUUGCCGGCAGCUGCAGCAAGGCAUUAAGGUUUAACUGGCUAUAACUGGCAAGCAUCCGAGGCUCUGUUUCACCCUCU		70
20499	MI0006532	vvi-MIR169r	Vitis vinifera miR169r stem-loop	AGGGUGGAAUUGAGUCAAGGAUGACUUGCCGAUAUAUAUUUGCAGAAGGCAUGCAGGGGCUUUUAGCUAUGUGUAACCGGCAAGUUGACUUGACUCAGUUUGGCCCUCU		70
20500	MI0006533	vvi-MIR169s	Vitis vinifera miR169s stem-loop	GAAAGUGGAUUGCAGCCAAGGAUGACUUGCCGGCACUUGGCAUUAGGCACCAUCGAUCAUCUUCCCGGCAAGUUGUUCCUGGCUACAUUCUGCUCUCUU		70
20501	MI0006534	vvi-MIR169t	Vitis vinifera miR169t stem-loop	AGGGUGGAAUCGAGUCAAGGAUGACUUGCCGAUAUAUAUUUGCGGAAGGACUUGCAUGGGCCUUUAGCUAUGUGUAACCGGCAAGUUGACUUGACUCAGUUUGGCCCUCU		70
20502	MI0006535	vvi-MIR169u	Vitis vinifera miR169u stem-loop	AGGGUGGAAUUGAGUCAAGGAUGACUUGCCGUUAUAUAUUUGCAGAAGGGCACGCAGGGGCCUUUAGCUAUGUGUUACCGGCAAGUUGACUUGACUCUGUUUGGCCCUCU		70
20503	MI0006536	vvi-MIR171a	Vitis vinifera miR171a stem-loop	UGGUGGGAAGCGUGAUGUUGGGACGGCUCAAUCAAACCAAAGAUCUCAAUGGUUGAGUCCUUUAAUCUGAUUGAGCCGUGCCAAUAUCAUGUUCAAUAC		70
20504	MI0006537	vvi-MIR171b	Vitis vinifera miR171b stem-loop	UGGGGGGAGGUAUUGGCGUGCCUCAAUUUAAAGACAUGGUUAGAUGAAGAGAUAUUAGCCAUGUGAUUUGAUUGAGCCGCGUCAAUAUCUCCUUUUGCA		70
20505	MI0006538	vvi-MIR171c	Vitis vinifera miR171c stem-loop	UGGUAUUACGGGAUAUUGGUGCGGUUCAAUAAGAAAGCAGUGCUCGCAAUCUUUUUGAGUUCUGGUUUUUGAUUGAGCCGUGCCAAUAUCACGUGUCAUUGCU		70
20506	MI0006539	vvi-MIR171d	Vitis vinifera miR171d stem-loop	UAGAUACACGAGAUAUUGAUACGGUUCAAUUAGAAAGCUGUGUUCUAAGUUAAGAACUCUGUUGUUUGAUUGAGCCGUGCCAAUAUCACGUCCUACUUCU		70
20507	MI0006540	vvi-MIR171e	Vitis vinifera miR171e stem-loop	GGAAAGUAAGCGAUGUUGGUGAGGUUCAAUCCGAAGACGGAUUUACGAAGAGCCGUAAAGAACGAUCUCUGAUUGAGCCGCGCCAAUAUCACUUUCUGCUAAG		70
20508	MI0006541	vvi-MIR171f	Vitis vinifera miR171f stem-loop	UUGAAGAAAGCGAUGUUGGUGAGGUUCAAUCUGAAGAUUGAUUUAUGCUUGAAUGUAAAAACUGAUCUCAGAUUGAGCCGCGCCAAUAUCACUUUUCUGUGGC		70
20509	MI0006542	vvi-MIR171h	Vitis vinifera miR171h stem-loop	UUUCACGAGAUGUUGGUGCGGUUCAACCUAACUGUAGUGUCCAUGAAUGUAUCGACUCUGAUGUUUGGUUGAGCCGCGCCAAUAUCCCGUCUAUCU		70
20510	MI0006543	vvi-MIR171i	Vitis vinifera miR171i stem-loop	GAAGAAGGUGGGGAUGUUGGAAUGGCUCAAUCAAAUCAAAUCUCCCAAGGGUUUUGGGUCCUUUAAUCUGAUUGAGCCGUGCCAAUAUCAUCAUGUUCACUUC		70
20511	MI0006544	vvi-MIR172a	Vitis vinifera miR172a stem-loop	UAUUGCCGAUGCAGCAUCAUCAAGAUUCUCAUCCUUGAAAAGUUUGGCAGAGAUAACAUCACCACCGUGCAUUUGCAUGUGAAUCUUGAUGAUGCUACAUGCGCAAACAA		70
20512	MI0006545	vvi-MIR172b	Vitis vinifera miR172b stem-loop	UAUUGCCGAUGCAGCAUCAUCAAGAUUCUCAACCCCAAAACUUGAGGCAGCGAAGAUGGCAUCGCUGCCGCGCCGGGCUUUCGCAUGUGAAUCUUGAUGAUGCUACACCUGCAAACAA		70
20513	MI0006546	vvi-MIR172c	Vitis vinifera miR172c stem-loop	GUUUGCGGAUGGAGCAUCAUCAAGAUUCACAAGUAUUGAGACUCAGUGCGUGGUGGUGAUGGUGACUUUUGUGGUCCCUUCCUACACUCCGAUGGCUCUUUGAUGUGGGAAUCUUGAUGAUGCUGCAGCGGCAAUAAA		70
20514	MI0006547	vvi-MIR172d	Vitis vinifera miR172d stem-loop	GUUAGCUGAUGCAGCAUCAUCAAGAUUCACACCCAAUGGAAGGGCAGUGAUGCAAUCUCUGCCAAAGAUUUUGAGAUGAGAAUCUUGAUGAUGCUGCAUUCGCAGUGAA		70
20515	MI0006548	vvi-MIR319b	Vitis vinifera miR319b stem-loop	UGUGGAAGAAGGAGCUCUCUUUAGUCCAGUCCGAGACAGCUUCAAGGCUGAUACGUGGCUGCUGACUCGUUGCUUCAAGAACUCAUCACAUAGGCCUGGAAAAGAUGGAUGGUUUUUUGAUCCAACGAUGCAGGAGCUGCGUUCAGUUAUGGCUGUCACGUCUUGGACUGAAGGGAGCUCCCUUGUAUUCCACA		70
20516	MI0006549	vvi-MIR319c	Vitis vinifera miR319c stem-loop	UUACAUUGAAGAGAGCUUUCUUCAGUCCACUCAUGGGUGGCAGUAGGAUUGAAUUAGCUGCCGACUCAUUCAUCCAAAUACUGUGUUAAGGACUACCCAGUAAAUGAUUGAAUGAUGCGGGAGACAAAUUGGAUCUUAAGCUCCCUGUGCUUGGACUGAAGGGAGCUCCCUUCACUGCAAUC		70
20517	MI0006550	vvi-MIR319f	Vitis vinifera miR319f stem-loop	AGUGGUUUAAGAGAGCUUCCUUCAGUCCACUCAUGGAUGGGUUAGGGGUUUGGAUUAGCUGCCGACUCAUUCAUUCAAACACAGUAGAAUGGAAAUGGAGUUUACUACUGUGAAUGUGUGAAUGAUGCGGGAGGUAAAUUUCAUCCUUUUCUUGUCUGUGCUUGGACUGAAGGGAGCUCCCUUCUACUGUUUU		70
20518	MI0006551	vvi-MIR319g	Vitis vinifera miR319g stem-loop	GAACAGCUGAAGAGCUCCUUUUAGUCCAAUAAAGAGGGCUGAGGGGCGGCCAGAGCUGCCAUCUCAUGCACUUGGCUAUGCUUAUUCUUUUCUCAAUCAAUUCGGUUCGAGUAUGGCUGUGGAGUGACAAAUGCUAAGUUUAGCCUGAUGCAUGACAUGGGAGCAACUCCUCCGCACGCUUUGCCCACUCAUUGGACUGAAGGGAGCUCCCAGGGCAGAUCU		70
20519	MI0006552	vvi-MIR390	Vitis vinifera miR390 stem-loop	AGAAUCUGUUAAGCUCAGGAGGGAUAGCGCCAUGAGCCAUGAUGAAAAUGAUUGUUGAGUUGAAAAUUUUUUCUAGCUUGUUUUUUGGGUCAUCAUUUUGUGUGUGUGGCGCUAUCUAUCCUGAGUUUCACGGGUUCUUC		70
20520	MI0006553	vvi-MIR393b	Vitis vinifera miR393b stem-loop	GGAGGAGGCAUCCAAAGGGAUCGCAUUGAUCCCAAACUCUCCAUGUCUUUGGAUCAUGCUAUCCCUUUGGAUUCCUCCUUUGG		70
20521	MI0006554	vvi-MIR394a	Vitis vinifera miR394a stem-loop	CAGAGCCAUUUUGGCAUUCUGUCCACCUCCAUGCACAUCAUGGGUCUAUAUUCUUUUGGAGGUGGCCAGCAUGCCAAAGUGGCUCUGUA		70
20522	MI0006555	vvi-MIR394b	Vitis vinifera miR394b stem-loop	ACAGAGUUUAUUGGCAUUCUGUCCACCUCCCAUCUCUUGAAAAUCUCUCUUUUCUCUCUGUGGAGGUGGGCAUACUGCCAACCAAGCUCUGUU		70
20523	MI0006556	vvi-MIR395a	Vitis vinifera miR395a stem-loop	GUCCCCUAGAGUUCCCUUGAUCACUUCACUAGGGAGCUUCGCUAGUUUUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUACCGA		70
20524	MI0006557	vvi-MIR395b	Vitis vinifera miR395b stem-loop	GUCCCCUAGAGUUCCCCUUACCACUUCACUGGGGAUCUUCUCUAAUGAAUGCCUACGUACUGAAGUGUUUGGGGGAACUCCUGGUGCCAU		70
20525	MI0006558	vvi-MIR395c	Vitis vinifera miR395c stem-loop	GUCCCCUAGAGUUCCCUUGACCACUUCACUGGGGACCUUCUCUAGUUAUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGCCAU		70
20526	MI0006559	vvi-MIR395d	Vitis vinifera miR395d stem-loop	GCCCCCUAGAGUUCCCCUGACCACUUCAUUGGGGAUCUUCUCUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCAU		70
20527	MI0006560	vvi-MIR395e	Vitis vinifera miR395e stem-loop	CUCCCCUAGAGUUCCCUUGACCACUUCACUGGGGACCUUCUCUAAUUAUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGCCAU		70
20528	MI0006561	vvi-MIR395f	Vitis vinifera miR395f stem-loop	GUACCCUAGAGUUCCCCUGACCACUUCACUGGGGAUCUUCUCUAAUGACUUCCCACUGAAGUGUUUGGGGGAACUCCUGGUGUCAU		70
20529	MI0006562	vvi-MIR395g	Vitis vinifera miR395g stem-loop	GUCCCCUAGAGUUCCCCUGAGCACUUCAUUGGGGAUCCUUAGUUUUCAAUUCCUACUGAAGUGUUUGGGGGAACUCCCGGUGUCAU		70
20530	MI0006563	vvi-MIR395h	Vitis vinifera miR395h stem-loop	GUCCCCUAGAGUUCCCUUGACCACUUCACUGGGGACCUUCUCUAAUUAUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGCUAU		70
20531	MI0006564	vvi-MIR395i	Vitis vinifera miR395i stem-loop	GCCCCCUAGAGUUCCCCUGACCACUUCACUGGGGAUCUUCUGUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCAU		70
20532	MI0006565	vvi-MIR395j	Vitis vinifera miR395j stem-loop	GCCCCCUAGAGUUCCCCUGACCACUUCACUGGGGAUCUUCUUUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCAU		70
20533	MI0006566	vvi-MIR395k	Vitis vinifera miR395k stem-loop	UCCCCUAGAGUUCCCUUGACCACUUCACUGGGGACCUUCUCUAAUUAUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGCCAUU		70
20534	MI0006567	vvi-MIR395l	Vitis vinifera miR395l stem-loop	GCCCCCUAGAGUUCCCCUGACCACUUCACUGGGGGAUCUUCUGUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGUCAU		70
20535	MI0006568	vvi-MIR395m	Vitis vinifera miR395m stem-loop	GUCCCCUAGAGUUCCCUUGAACACUUCACUGGGGACCUUCUCUAGUUAUAAUGACUUCCUACUGAAGUGUUUGGGGGAACUCCUGGUGCCAU		70
20536	MI0006569	vvi-MIR396a	Vitis vinifera miR396a stem-loop	UCCUGUCAUGCUUUUCCACAGCUUUCUUGAACUACUUUUCCAUCUACCUGUUUGAUGAUCUUCUUCAUAAGGAGUGUGAAAUAGAAGCUCAAGAAAGCUGUGGGAGGACAUGGCAA		70
20537	MI0006570	vvi-MIR396b	Vitis vinifera miR396b stem-loop	UCCUGCCAUGCUUUUCCACAGCUUUCUUGAACUUCUUCUCCCUGUUUGGUGGUCUCCUACGUUUACCCAUCCACUGAAGUUCAAGAAAGCUGUGGGAAACCAUGGCUU		70
20538	MI0006571	vvi-MIR396d	Vitis vinifera miR396d stem-loop	CUUUGUAUUCUUCCACAGCUUUCUUGAACUGCAUUUUUCAGACUACUGGUGUGUUUUUGUAUGCACUCAAAGUCAUUGUAACAGUUGCGGUUCAAUAAAGCUGUGGGAAGAUACCAACAG		70
20539	MI0006572	vvi-MIR398a	Vitis vinifera miR398a stem-loop	ACACCCCAAGGGAGUGGCACCUGAGAACACCGGUUGUGUUGGCUGCGCCAAGCUCUGCUAGCUAAUGCAUUUUGUGUUCUCAGGUCACCCCUUUGGGGCACCA		70
20540	MI0006573	vvi-MIR399a	Vitis vinifera miR399a stem-loop	GAGAAUAACAGUGUGAUUCUCCUUUGGCAGAGAUAUCACGCAUGGAGUAGAAGGCGGUAGCUGCUCUGCCAAAGGAGAAUUGCCCUGUUAUUCAAUU		70
20541	MI0006574	vvi-MIR399b	Vitis vinifera miR399b stem-loop	AUCAAUCAUAGGGCACCUCUUUCUUGGCAGGCACUGGCUCCUAUAUAUGAAUAUACAUAGCUUAGCUGCAGUAAAAAGAUGUGACUUGCCAAAGGAGAGUUGCCCUGUGACUGCUUC		70
20542	MI0006575	vvi-MIR399e	Vitis vinifera miR399e stem-loop	GCAUAUUACAGGGCAAAUUAUCUUUUGGCAGGCAGCCACUUAGAGACACAGCCAAGCCAUGCAUUCUUGUAGUGUGCCCUCUGCCAAAGGAGAUUUGCCCGGCAAUUCUUCU		70
20543	MI0006576	vvi-MIR399g	Vitis vinifera miR399g stem-loop	AUGAAUUGCUGGGCAAUACUCCAUUGGCAGUUGGCCACUCGGCUGACCGCGGUUGACUUCACAAGUAGCAGACUAAGCUCACUGCCAAAGGAGAUUUGCCCCUCAAUUCAGCU		70
20544	MI0006577	vvi-MIR399h	Vitis vinifera miR399h stem-loop	AGGAAUAACAGUGCAAUCCUCCUUUGGCAGAAAGAUCAUGCACAUGCAUACUUCUGUUUUGCCAAAGGAGAAUUGCCCUGCCAUUCGCUC		70
20545	MI0006578	vvi-MIR408	Vitis vinifera miR408 stem-loop	AAGAGGAAGACGGGGACGAGGUAGUGCAUGGAUGGAACUAUUAACAGAAGAAUGUUAAGCUGUUUUUGCUCUACCCAUGCACUGCCUCUUCCCUGGCUCUGUCUCUC		70
20546	MI0006579	vvi-MIR479	Vitis vinifera miR479 stem-loop	GUAGACAUGGUGUGGUAUUGGUUCGGCUCAUCUUCUUUCAUUCAUUUUCAUCGGCUCAAAGACGAGCCGAACCAAUAUCACUCUUGUAUGCUUC		70
20547	MI0006580	vvi-MIR535a	Vitis vinifera miR535a stem-loop	UGUAAUUGCUUGACAACGAGAGAGAGCACGCUAGUCAGCAUUCAUGCGAGGAACAUGACUGUGUACAGGCGUGCUCUCUCUCGCUGUCAUACAAUCUUCUC		70
20548	MI0006581	vvi-MIR535b	Vitis vinifera miR535b stem-loop	UGUAAUUGCUUGACAACGAGAGAGAGCACGCUAGUCAGCAUUCAUGCGAGGAACAUGACUGUGUACAGGCGUGCUCUCUCUCGCUGUCAUACAAUCUUCUC		70
20549	MI0006582	vvi-MIR535c	Vitis vinifera miR535c stem-loop	UGUAAUUGCUUGACAACGAGAGAGAGCACGCUAGUCAGCAUUCAUGCGAGGAACAUGACUGUGUACAGGCGUGCUCUCUCUCGCUGUCAUACAAUCUUCUC		70
20550	MI0006583	vvi-MIR535d	Vitis vinifera miR535d stem-loop	UGUAAUUGCUUGACAACGAGAGAGAGCACGCUAGUCUGCAUUCAUGCGAGGAACAUGACUGUGUACAGGCGUGCUCUCUGUCGCUGUCAUACAAUCUUCUC		70
20551	MI0006584	vvi-MIR535e	Vitis vinifera miR535e stem-loop	UGUAAUUGCUUGACAACGAGAGAGAGCACGCUAGUCUGCAUUCAUGCGAGGAACAUGACUGUGUACAGGCGUGCUCUCUGUCGCUGUCAUACAAUCUUCUC		70
20552	MI0006585	age-mir-506	Ateles geoffroyi miR-506 stem-loop	CACGCUCUGUAUAGUACCUUAUUCAGGAAGGUGUUACCCAUACAGAUUAAUAUUUGAAUGGCGCCCUUCUGAGUAGAGUAAUGUGCAACACGGACCACAUUU		28
20553	MI0006586	age-mir-507	Ateles geoffroyi miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAUUAGUGCCAUUCAUGUGGCUAGAAAUUUGUUUGGCACUUUUUAGAGUGAAAUAAUGCACAACAGGUAC		28
20554	MI0006587	age-mir-508	Ateles geoffroyi miR-508 stem-loop	UGAGUGUAGUGCCCUACUCCAGAGGGUGUCAAUCACAUAAACUAAAGCACGAUUGUCACCUUUUUGAGUAGAGUAAUACACAUCA		28
20555	MI0006588	age-mir-509a	Ateles geoffroyi miR-509a stem-loop	AAUGCUGUGUGUGGUACCCUGCUGCAGAGAGUGGCAAUUGUAUAUAAUUAAAAAUGAUUGACACGUCUGCAGGUAGAGUAAUGCAUGACACAUG		28
20556	MI0006589	age-mir-509b	Ateles geoffroyi miR-509b stem-loop	CAUGCUGUAUGUGGUACCCUGCUGCAGAGAGUGGCAAUCGUAUAUAAUUAAAAAUGAUUGACACGUCUGCAGAUAGAGUAAUGCAUGACACAUG		28
20557	MI0006590	age-mir-510	Ateles geoffroyi miR-510 stem-loop	GCUAUAUGCGUGUGGUGCUCUACUCCAGAGAGUAGCAAUCACGUAUAAUUAAAGGUGAUUGAAACCUCUGAGAGUAGAGUAACACAUGACAUGUACUAC		28
20558	MI0006591	age-mir-513b	Ateles geoffroyi miR-513b stem-loop	CAGCGUGCAGUGCCCUUCACAAGGAGCUGUCAUUCAUGUGGACAAAAACAUGAAUGUCGCCUUCUUGAGAAGAGUAAUGUACAGCAUG		28
20559	MI0006592	age-mir-513c-1	Ateles geoffroyi miR-513c-1 stem-loop	CAGCGUGCAGUGCCUUUCUCAAGAAGGUGUCAUUCAUGUGAACUAAAAUAUGAUGUCACCUUCUUGAGAAGAGUAAUGUACAGCAUG		28
20560	MI0006593	age-mir-513a-1	Ateles geoffroyi miR-513a-1 stem-loop	CAGCGUGCAGUGCCCUUCACAAGGAGGUGUCAUUCAUGUGGACUAAAACACGAAUACUGCCUUCUUGAGAAGAGUAAUGUACAGCAUG		28
20561	MI0006594	age-mir-513d	Ateles geoffroyi miR-513d stem-loop	CAUUCAGCGUGCAGUGCCCUUCACAACGAGGUGUCAUUUAUGUAAACUGAAACAUAAAUGUCACCUUUUUGAGAAGAGUAAUGUACAGGAUG		28
20562	MI0006595	age-mir-513e-2	Ateles geoffroyi miR-513e-2 stem-loop	CAUCCAGCAUGCAGUGCCCUUACAAGAAGGUGCCAUUCAUGUGAACUAAAAUAUGAAUGCCGCCUUCUUGAUAAGAGUAAUGUACGGCAUG		28
20563	MI0006596	age-mir-513a-2	Ateles geoffroyi miR-513a-2 stem-loop	CAGCGUGCAGUGCCCUUCACAAGGAGGUGUCAUUCAUGUGGACAAAAACAUGAAUGCCGCCUUCUUGAGAUGAGUAAUGUACAGCAUG		28
20564	MI0006597	age-mir-513c-2	Ateles geoffroyi miR-513c-2 stem-loop	CAGCGUGCAGUGCCUUUCUCAAGAAGGUGUCAUUCAUGUGAACUAAAAUAUGAAUGUCGCCUUCUUGAGAAGAGUAAUGUACAGCAUG		28
20565	MI0006598	age-mir-514	Ateles geoffroyi miR-514 stem-loop	CAAGUUGUUUGUGGUACCCUACUCCGAAGAGUGUCAAUCAUGUGUAAUUCAAUUUGAUUGACACUUUUGUGAGUAGAGUAACAUACGACAUG		28
20566	MI0006599	ssy-mir-506	Symphalangus syndactylus miR-506 stem-loop	CCAUGCUAUGUGUAGUGCCUUAUUCAGGAAGGUGUUACUUAAUAGAUUAAUAUUUGUAAGGCACCCUUCUGAGUAGAGUAAUGUGCAACAUGG		67
20567	MI0006600	ssy-mir-507	Symphalangus syndactylus miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAUAAGUGCCAUUCAUGUGUCUAGAAAUAUGUUUUGCACCUUUUGGAGUGAAAUAAUGCACAACAGGUAC		67
20568	MI0006601	ssy-mir-508	Symphalangus syndactylus miR-508 stem-loop	UGAGUGUAGUGCCCUACUCCAGAGGGCGUCACUCACGUAAACUAACACAUGAUUGUAGCCCUUUUGAGUAGAGUAAUACACAUCA		67
20569	MI0006602	ssy-mir-509a	Symphalangus syndactylus miR-509a stem-loop	CAUGCUGUGUGUGGUACCCUACUACAGGCAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGGUAGAGUACUGCAUGACACAUG		67
20570	MI0006603	ssy-mir-509b	Symphalangus syndactylus miR-509b stem-loop	CAUGCUGUGUGUGGUACCCUACUGCAGGCAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUAGGUAGAGUACUGCAUGACACAUG		67
20571	MI0006604	ssy-mir-510	Symphalangus syndactylus miR-510 stem-loop	CUGUGUGUGUGUGUGGUGUCCUACUCCGGAGAGUGGCAAUCACAUAUAAUUAAGUGUGAUUGAAACCUCUAAGAGUGGAAUAACACAUGACAUGUACU		67
20572	MI0006605	ssy-mir-513c	Symphalangus syndactylus miR-513c stem-loop	UGUACAGUGCCUUUCCCAAGGAGGUGUCAUUUACGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGAGUAAUGUACA		67
20573	MI0006606	ssy-mir-513b-1	Symphalangus syndactylus miR-513b-1 stem-loop	AGUGUACAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUGUGACCUUCUUGAGAAGAGUAAUGUACA		67
20574	MI0006607	ssy-mir-513a	Symphalangus syndactylus miR-513a stem-loop	UGUGCAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGAGUAAUGUACA		67
20575	MI0006608	ssy-mir-513b-2	Symphalangus syndactylus miR-513b-2 stem-loop	UGUGCAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUUUGAGAAGGGUAAUGUACA		67
20576	MI0006609	ssy-mir-514	Symphalangus syndactylus miR-514 stem-loop	AUGUUGUCUGUGGUACCCUACUCUGGAUAGUGACAAUCAUGUGUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACACGU		67
20577	MI0006610	mml-mir-506	Macaca mulatta miR-506 stem-loop	UGUCUAGUGCCGUUAUGUGUAGUGCCUUAUUCAGGAAGGUGUUACUUAAUAUAUUAAUAUUUGUAAGGCACCCUUCUGAGUAGAGUAAUGUGCAACAUGGACAUCAUUU		32
20578	MI0006611	mml-mir-507	Macaca mulatta miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAUAAGUGCCAUUCAUGUGUCUAGAAAUAUGUUUUGCACCUUUUGGAGUGAAAUAAUGCACAACAGGUAC		32
20579	MI0006612	mml-mir-508	Macaca mulatta miR-508 stem-loop	UGAGUGUCGUGCUCUACUCCAGAGGGCGUCACUCACAUAAACUAAAACAUGAUUGUCGCCUUUUUGAGUAGAGUAAUACACAUCA		32
20580	MI0006613	mml-mir-509-1	Macaca mulatta miR-509-1 stem-loop	CAUGUUGUGUGUGGUACCCUACUGCAGGCAGUGGCAAUUAUGUAUAGUUAAAAAUGAUUGGUAUGUCUGUGGGUAGAGUAAUGCAUGACACAUG		32
20581	MI0006614	mml-mir-509-2	Macaca mulatta miR-509-2 stem-loop	CAUGCUGUGUGUGGUACCCUACUACAGGCAGUGGCAAUCAUGUAUAGUUAAAAAUGAUUGGUAUGUCUGUGGGUAGAGUAAUGCAUGACACAUG		32
20582	MI0006615	mml-mir-510	Macaca mulatta miR-510 stem-loop	UGCUGUGUGUGUGUGGUAUCCUACUCCGGAGAGUGGCAAUCACAUAUAAUUAAGUGUGAUUGAAACCUCUAAGAGUGGAGUAACACAUGACAUGUACU		32
20583	MI0006616	mml-mir-513b-1	Macaca mulatta miR-513b-1 stem-loop	UUUACAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACCUUUUUGGGAAGAGUAAUGUACAA		32
20584	MI0006617	mml-mir-513b-2	Macaca mulatta miR-513b-2 stem-loop	GUGUGCAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACCUUUUUGGGAAGAGUAAUGUACA		32
20585	MI0006618	mml-mir-513a-1	Macaca mulatta miR-513a-1 stem-loop	GUGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACCUUUCUGCGAAGGGUAAUGUACAU		32
20586	MI0006619	mml-mir-513a-2	Macaca mulatta miR-513a-2 stem-loop	UGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGAGUAAUGUACA		32
20587	MI0006620	mml-mir-513a-3	Macaca mulatta miR-513a-3 stem-loop	CUGUACAUUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACUUUUCUGAGAAGAGUAAUGUACAG		32
20588	MI0006621	mml-mir-514-1	Macaca mulatta miR-514-1 stem-loop	AUGUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAAUGCAUGACACGU		32
20589	MI0006622	ptr-mir-506	Pan troglodytes miR-506 stem-loop	CCAUACUAUGUGUAGUGCCUUAUUCAGGAAGGUGUUACUUAAUAGAUUAAUAUUUGUAAGGCACCCUUCUGAGUAGAGUAAUGUGCAACAUGG		37
20590	MI0006623	ptr-mir-507	Pan troglodytes miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAGAAGUGCCAUGCAUGUGUCUAGAAAUAUGUUUUGCACCUUUUGGAGUGAAAUAAUGCACAACAGAUAC		37
20591	MI0006624	ptr-mir-508	Pan troglodytes miR-508 stem-loop	UGAGUGUAGUGCCCUACUCCAGAGGGCAUCAGUCAUGUAAACUAAAACAUGAUUGUAGCCUUUUUGAGUAGAGUAAUACACAUCA		37
20592	MI0006625	ptr-mir-509a-1	Pan troglodytes miR-509a-1 stem-loop	CAUGCUGUGUGUGGUACCCUACUGCAGACAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGAUAGAGUACUGCAUGACACAUG		37
20593	MI0006626	ptr-mir-509b	Pan troglodytes miR-509b stem-loop	CGUGCUGUGUGUGGUACCCUACUGCAGACGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGAGUAGAGUACUGCAUGACACAUG		37
20594	MI0006627	ptr-mir-509a-2	Pan troglodytes miR-509a-2 stem-loop	CAUGCUGUGUGUGGUACCCUACUGCAGACAGUGGCAAUCAUGUAUAAUUAAAAAUGAUUGGUACGUCUGUGGAUAGAGUACUGCAUGACACAUG		37
20595	MI0006628	ptr-mir-510	Pan troglodytes miR-510 stem-loop	CUGUGUAUGUGUGUGGUGUCCUACCCAGGAGAGUGGCAAUCACAUAUAAUUAGGUGUGAUUGAAACCUCUAAGAGUGUAGUACACAUGACAUGUACU		37
20596	MI0006629	ptr-mir-513a-1	Pan troglodytes miR-513a-1 stem-loop	UGUGCAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUGCUGAGAAGAGUAAUGUACA		37
20597	MI0006630	ptr-mir-513b	Pan troglodytes miR-513b stem-loop	UGUACAGUGCCUUUCACAAGGAGAUGUCAUUUAUGUGAACUAAAAUAUAAAUGUCACCUUUUUGAGAGGAGUAAUGUACA		37
20598	MI0006631	ptr-mir-513a-2	Pan troglodytes miR-513a-2 stem-loop	UGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUGCUGAGAAGAGUAAUGUACA		37
20599	MI0006632	ptr-mir-513a-3	Pan troglodytes miR-513a-3 stem-loop	UGUGCAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGGGUAAUGUACA		37
20600	MI0006633	ptr-mir-514-1	Pan troglodytes miR-514-1 stem-loop	UGUCUGUGGUACCCUACUCUGGAAAGUGACAAUCAUGUAUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACA		37
20601	MI0006634	ptr-mir-514-2	Pan troglodytes miR-514-2 stem-loop	UGUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAACUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACA		37
20602	MI0006635	ptr-mir-514-3	Pan troglodytes miR-514-3 stem-loop	UGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAACUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCAUGACA		37
20603	MI0006636	ptr-mir-514-4	Pan troglodytes miR-514-4 stem-loop	UGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAACUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGCCUGACA		37
20604	MI0006637	pbi-mir-506	Pygathrix bieti miR-506 stem-loop	UGUCUAGUGCCUUUAUGUGUAGUGCCUUAUUCAGGAAGGUGUUACUUAAUGUAUUAACAUUUGUAAGGCACCCUUCUGAGUAGAGUAAUGUGCAACAUGGAUAUCAUUU		66
20605	MI0006638	pbi-mir-507	Pygathrix bieti miR-507 stem-loop	GUGCUGUGUGUAGUGCUUCACUUCAAUAAGUGCCAUUCAUGUGUCUAGAAAUAUGUUUUGCACCUUUUGGAGUGAAAUAAUGCACAACAGGUAC		66
20606	MI0006639	pbi-mir-508	Pygathrix bieti miR-508 stem-loop	UGAGUGUAGUGCUCUACUCCAGAGGGCGUCAAUCACAUAAACUAAAACAUGAUUGUCACCUUUUUGAGUAGAGCAAUACACAUCA		66
20607	MI0006640	pbi-mir-509	Pygathrix bieti miR-509 stem-loop	CAUGCUGUGUGUGGUACCCUACUUCAGGCAGUGGCAAUCCUGUAUAGUUAAAAAUGAUUGAUACGUCUGUGGGUAGAGUAAUGCAUGACACAUG		66
20608	MI0006641	pbi-mir-510	Pygathrix bieti miR-510 stem-loop	UGCUGUGUGUGUGUGGUAUCCUACUCCGGAGAGUGGCAAUCACAUAUAAUUAAGUGUGAUUGAAACCUCUAAGAGUGGAGUAACACAUGACGUGUACU		66
20609	MI0006642	pbi-mir-513a-1	Pygathrix bieti miR-513a-1 stem-loop	UGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACCUUUCUGGGAAGAGUAAUGUACA		66
20610	MI0006643	pbi-mir-513b	Pygathrix bieti miR-513b stem-loop	UGUGCAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAAGUAUAAAUGUCACCUUUUUGAGAAGAGUAAUGUACA		66
20611	MI0006644	pbi-mir-513c-1	Pygathrix bieti miR-513c-1 stem-loop	UGUACAGUGCCUUUCACAGGGAGGUGUCAUUUGUGUGAACUAAACUAUAAAUGUCACCUUUCUGGGAAGUGUAAUGUACA		66
20612	MI0006645	pbi-mir-513a-2	Pygathrix bieti miR-513a-2 stem-loop	UGUACAGUGCCUUUCACAGGGAGGUGUCAUUUAUGUGAACUAAACUAUAAAUGUCACCUUUCUGAGAAGAGUAAUGUACA		66
20613	MI0006646	pbi-mir-513c-2	Pygathrix bieti miR-513c-2 stem-loop	UGUACAUUGCCUUUCACAGGGAGGUGUCAUUUGUGUGAACUAAACUAUAAAUGUCACCUUUCUGGGAAGAGUAAUGUACA		66
20614	MI0006647	pbi-mir-514	Pygathrix bieti miR-514 stem-loop	AUGUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAACGUAUGACACGU		66
20615	MI0006648	hsa-mir-513b	Homo sapiens miR-513b stem-loop	GUGUACAGUGCCUUUCACAAGGAGGUGUCAUUUAUGUGAACUAAAAUAUAAAUGUCACCUUUUUGAGAGGAGUAAUGUACAGCA		5
20616	MI0006649	hsa-mir-513c	Homo sapiens miR-513c stem-loop	GCGUACAGUGCCUUUCUCAAGGAGGUGUCGUUUAUGUGAACUAAAAUAUAAAUUUCACCUUUCUGAGAAGAGUAAUGUACAGCA		5
20617	MI0006650	age-mir-513e-1	Ateles geoffroyi miR-513e-1 stem-loop	CAGCGUGCAGUGCCCUUACAAGAAGGUGCCAUUCAUGUGAACUAAAAUAUGAAUGCCGCCUUCUUGAGAAGAGUAAUGUACGGCAUG		28
20618	MI0006652	hsa-mir-1321	Homo sapiens miR-1321 stem-loop	ACAUUAUGAAGCAAGUAUUAUUAUCCCUGUUUUACAAAUAAGGAAAUAAACUCAGGGAGGUGAAUGUGAUCAAAGAUAG	Afanasyeva et al. refer to this sequence using the internal identifier MYCNAMP_NB2_241 [1].  Some additional sequences reported in [1] do not meet miRBase requirements for miRNA identification. 	5
20619	MI0006653	hsa-mir-1322	Homo sapiens miR-1322 stem-loop	AGUAUCAUGAAUUAGAAACCUACUUAUUACAUAGUUUACAUAAGAAGCGUGAUGAUGCUGCUGAUGCUGUA	Afanasyeva et al. refer to this sequence using the internal identifier MYCNSC_NB2_237 [1].  Some additional sequences reported in [1] do not meet miRBase requirements for miRNA identification. 	5
20620	MI0006654	hsa-mir-720	Homo sapiens miR-720 stem-loop	CCGGAUCUCACACGGUGGUGUUAAUAUCUCGCUGGGGCCUCCAAAAUGUUGUGCCCAGGGGUGUUAGAGAAAACACCACACUUUGAGAUGAAUUAAGAGUCCUUUAUUAG		5
20621	MI0006656	hsa-mir-1197	Homo sapiens miR-1197 stem-loop	ACUUCCUGGUAUUUGAAGAUGCGGUUGACCAUGGUGUGUACGCUUUAUUUGUGACGUAGGACACAUGGUCUACUUCUUCUCAAUAUCA	Afanasyeva et al. refer to this sequence using the internal identifier MYCNSC_NB5_330 [1].  Some additional sequences reported in [1] do not meet miRBase requirements for miRNA identification. 	5
20622	MI0006657	hsa-mir-1324	Homo sapiens miR-1324 stem-loop	CCUGAAGAGGUGCAUGAAGCCUGGUCCUGCCCUCACUGGGAACCCCCUUCCCUCUGGGUACCAGACAGAAUUCUAUGCACUUUCCUGGAGGCUCCA	Afanasyeva et al. refer to this sequence using the internal identifier MYCNSC_NB8_202 [1].  Some additional sequences reported in [1] do not meet miRBase requirements for miRNA identification. 	5
20623	MI0006963	osa-MIR1423	Oryza sativa miR1423 stem-loop	GCACAACACUAGUAUUUGGGAGGCAACUACACGUUGGGCGCUCGAUCCAGGGGUGGGAAAAUCGGGCGCCCACGUUUUCCCCACCCCCGGAUCGAGCGCCCAAGCGGUAGUUGUCUCCCAAAUACUUGUGCUGUGC		7
20624	MI0006964	osa-MIR1424	Oryza sativa miR1424 stem-loop	CCAGCUAGUUUAGCUCCCAGGCCAGUCAAGGUAGAGGCAGCUCAAAGUGUAGUCAUCUCUUGAUCGUUGAUUGCUCCAGUCCUAUCCCAUGCUCCUCCUUGAGCUCCCAAUCAUUGAGCUCUCGGAUCCUCUCUGCUCUUCUCUGAUCUGGUGUCGUUCCAGUUUCCAAACAUGUUGCAGAAUGAAGAACACUGAACAACAAGAUUAUAAGGUAGGUAAGUAGUUGAUCAUUUCAGGUUUCCAGAGAUGAUAAAGCAAUCAGGGAUGCAUGCACACUGAUGCUGAUUGUACAAACUCCAA		7
20625	MI0006965	osa-MIR1425	Oryza sativa miR1425 stem-loop	CUGUUGACUGCAUUAGGAUUCAAUCCUUGCUGCUAAAUGUAUUGCUUAUAUUCAGCAAUAUAAUGUUCAGCAGCAAGAACUGGAUCUUAAUAUAGUCGAUAG		7
20626	MI0006966	osa-MIR1426	Oryza sativa miR1426 stem-loop	AAAUAGAAUCUUGAUGAUGAUUAAAAGGAGGGACGAUAGGCAGGCCGUGAAGCAAAUAUGUAAGACGGUUGCCGGGAAUUCUAGAAAGUGAAAAAAAAACCCCAUUGAUAAUCAUAUUCGAUUUUCAAAA		7
20627	MI0006967	osa-MIR1427	Oryza sativa miR1427 stem-loop	UGGCUGCGCGCGACCGCGCCGUCCCGCAGGCCAGCGCCGCGCCACCGCGCGGUUCCGCAGCAGGGACAUGCGCCACCCGUUACAGCCAACUGAAAUCUGCACUGAUUUGAUUACAUGCGCACGUAUAUAUGCAGUGCAUGCAGCGAGUGUGCGCUGUUCCUGGAUUCGGUCGCGCGUGGCCGUGCUGCGGAACCGUGCGGUGGCGCGGCGCCGGCCUGCGGGACCGCGCAGUCGCGCGCAGCCAAGCCACGGGACCG		7
20628	MI0006968	osa-MIR1428	Oryza sativa miR1428 stem-loop	GGUUAGUGCGUUUUGCAAAUUCGCAGGCCCUAUCUUGUGGUAUGAACUGAGUACGCGAUGAUUUAUCCUGCGUAUUGGGGGCUUACCAUAAGAUAAAGCCGUGAAUUUGCAAAACGUUCA		7
20629	MI0006969	osa-MIR1429	Oryza sativa miR1429 stem-loop	GUAAUAUACUAAUCCGUGCAUCCAUCGUAUAUCUUACACGUCAUGUGAACGUGCAUCGGUUCAUAAUGUUGUGUUUAUAAAUGUUAAUGGUAUGUGUGGUUGCACGGGUUUGUAUGUUGC		7
20630	MI0006970	osa-MIR1430	Oryza sativa miR1430 stem-loop	AUGAGGAGAUUGCCUCUGUUAGCCAAGAAUGGCUUGCCUAUCUCCACUAUUUGGUUCAUCACUGGAACACACUUGGGGUUCUCAGAUGGUGGAUGAAAUAUGGAAGAUGGUGAGCCUUCCUGGCUAAGAGAGUGAUUCUCAU		7
20631	MI0006971	osa-MIR1431	Oryza sativa miR1431 stem-loop	GGGAUUCAGAAAGGAAAGACUUAGGGUUGCAAGCGGGUCAACCCGUGAACCCGCUUAUAGGCAAAAUUAGUAGGUAACCCGUAUAAAUGAGUUUAUGGAUCGACCCACUUGCAUCUCUAAGUGCGGCAAAUCGGACCACGACGUGAAAACACACGGGUUAUCACUUAUUUUACAUAUAAGUAGGUUUGCGAGUUGGCCCGCUUGCAUCCCUAGAUGCCGUCUUAGCUCUUAACAAGCAUG		7
20632	MI0006972	osa-MIR1432	Oryza sativa miR1432 stem-loop	CCUGUGAUCAGGAGAGAUGACACCGACAUCGCCGGAAUUCGUUCUUGGUCUUGUGCCAUGAUGAAUUGAUGGUCCGUUUGAUGCAGGUGUCAUCUCCCCUGAACAUAGG		7
20633	MI0006973	osa-MIR1433	Oryza sativa miR1433 stem-loop	AGGCCAUCUUCGAUAGCCAAGGAUGAUUUGCCUGUAGCCCCAUUGUCAUCAGCUCUCUCCGUCGAGAGCGACAACCGGGCUCUACUGGCAAGUCUCCUCGGCUACCCGAGUACCUCUUAUGCUAUCCCA		7
20634	MI0006974	osa-MIR444b	Oryza sativa miR444b stem-loop	AUGCAAGGGGAUGGUGACAAGCUUGUGGCAGCAACUGCACAUCUUGCAAGAAAAUCUUUAGGGUUUUUCAGACCAUACCGAUGAUUUUCUUGCAAGUUGUGCAGUUGUUGUCUCAAGCUUGCUGCCUCCCUUUGCCAA		7
20635	MI0006975	osa-MIR444c	Oryza sativa miR444c stem-loop	AGUUGCUGCAAGUGGAGGCGGCAAGCUAGAGACAGCAACUGCAUAUCUUGCAAGAAAAUCGGUUUUAUGGCCAUACCGAUGAUUUUCUUGCAAGCUGUGCAGUUGUUGUCUCAAGCUUGCUGCCUCCCUUUGCCAGAA		7
20636	MI0006976	osa-MIR444d	Oryza sativa miR444d stem-loop	AGUUAUUGCACAUGGUGGCACCAAGCAUGAGGCAACAACUGCAUUACUUGCAAGAAAGGCACAAAAUCAUUAGAUGAUUACUUGUGGCUUUCUUGCAAGUUGUGCAGUUGCUGCCUCAAGCUUGCUGCCUCCCUCUGCCAAAU		7
20637	MI0006977	osa-MIR444e	Oryza sativa miR444e stem-loop	GGUUUUGUAACCAGGGGCAAUAAGCUAGAGGCACCAACUGCAUAACUUGCGAGAAACUUGUUGGAUGAUGAUCUUGCCAAUGAUUUUGCCGCAAGUUAUGCAGUUGCUGCCUCAAGCUUACUGCCUUUGUUUGCUAAACC		7
20638	MI0006978	osa-MIR444f	Oryza sativa miR444f stem-loop	AUGGUGGCACCAAGCAUGAGGUUACAACUGCAUUACUUGCAAGGGAAUCACAAGUCACAAGAAACACAUGUUAUUACAAUGGAUAAUCAAUGGGUCAUCAUACUAUGACUUUCUUGCAAGUUGUGCAGUUGUUGCCUCAAGCUUGCUGCCUCCG		7
20639	MI0006986	osa-MIR810b	Oryza sativa miR810b stem-loop	AGCCCACCACAUGUGGCUCGCAUGCUUAAAUAACUAACGGCAUAAUUAGAUCACUUGAUGACGACGUAUAUCGGUGUUCGCUAUAUAUACUAUCUACUGGUAAGUAUAUCUUUAAUAUACUUACCAGUAGAUAGUAUAUAUAGUGAACACCGAUAUGCGUCAUCAUCAAGUGAUUUAAUUAUGCCGUUAGUUAAGCAUGCGAGCCACAUGUGGUGAGCUUACG		7
20640	MI0006987	mdv1-mir-M9	Mareks disease virus miR-M9 stem-loop	GCGGUUUUUCUCCUUCCCCCCGGAGUUCACUGUAUCGUACGUUGUAAACUCCGAGGGCAGGAAAAAGUGC		48
20641	MI0006988	mdv1-mir-M10	Mareks disease virus miR-M10 stem-loop	UGGCGUUGUCUCGUAGAGGUCCAGAUCUCUCCUGUUGGCAACUCGAAAUCUCUACGAGAUAACAGUUUG		48
20642	MI0006989	mdv1-mir-M11	Mareks disease virus miR-M11 stem-loop	AAAUUUUCCUUACCGUGUAGCUUAGACUCGGAAGAACUAUUUUGAGUUACAUGGUCAGGGGAUUU		48
20643	MI0006990	mdv1-mir-M12	Mareks disease virus miR-M12 stem-loop	GAUCAAGGCCCUCCGUAUAAUGUAAAUGUCCAAAGGUUUGCAUAAUACGGAGGGUUCUGAUC		48
20644	MI0006991	mdv1-mir-M13	Mareks disease virus miR-M13 stem-loop	AGUUUUCCAGGAGAUUUCCCGGUUUCGACUGCCGAAGCAUGGAAACGUCCUGGGAAAAUCU		48
20645	MI0007021	osa-MIR1435	Oryza sativa miR1435 stem-loop	ACUUUUCUUAAGUCAAACUUUUUUUUAGAUUUGAUCAAAUUUAUAAAAAAAAUAUAGCAAUAUUUUUAGAAAAAAAUAUGUUCAAUAUUAAAUGUAAUGAAACUAAUUUGGUGCUAUAACUGUUUUUAUAUUUUUCUAUAAUAAAUUUGAUUAAACUUUGAAGUAGUUUGACUUAAAAAAAGU		7
20646	MI0007022	osa-MIR1436	Oryza sativa miR1436 stem-loop	AGUUUAUGUGCUACUCCCUCCGUCCCAUAAUAUUAAAACCUAGGACUGGAUAGGACGUUUCAUAGUACAAUGACUCAGAGUCAUUGUACUAUGAAACGUCCUAUCCAGUCCUAGGUUUUAACAUUAUGGGACGGAGGGAGUAGUCUCAACCUAUAUAAACU		7
20647	MI0007024	osa-MIR1437	Oryza sativa miR1437 stem-loop	GCGCGCGGGGAGGGAGGGAACGGUGCCUAGUGCGGCACCGGAGCUCGCCAGCACGCAGGAGUGAGGUGAGGAGGACGGCGGCCAGGGCGCGGAGAGCUUGCCGGCGCUCCGCCACCGCCGCUACCUCCUUCCGCGUGCUGGCGAGCUCCGGCGCCGCACUAGGCACUGUUUCCUCCCUCCCCACGCGC		7
20648	MI0007025	osa-MIR1438	Oryza sativa miR1438 stem-loop	GUUGUGAUAUAAGGUUUUAGGGUAAUUUUAUCAUUUUUAAGAAAACAAAAUUUAAUACCUUCAGAUAUUCGGUAUCUAUGUAAAAAAUUUUUAGAUCCCUCAAUAAAAUUUAAUACCUAAAAUCUAAACGUAUUAAAUUUUGUUUUCUUAAAAAUUAUAAAAUUACCCUAAUACAUAAUACCUCAAU		7
20649	MI0007028	osa-MIR1440	Oryza sativa miR1440 stem-loop	AAAUGCCAAUGCUCAAAUACCACUCUCCUAAAUUUCCAUUCCCAAAUACCACCCGGGCCCACAUGUCAGCCUCAUCCAGCACAGGGUCCCACAUCACUUUUGUUUGAAUGGAAAGUGAGGCUGACAUGUGGGCCCGGAUGGUAUUUGGUAAUGAAAAUUUGGGAGAGUGGUAUUUGAGCACUGGCAUUU		7
20650	MI0007029	osa-MIR1441	Oryza sativa miR1441 stem-loop	GUUUUUUCAUUCGUGUCCGAAAACUCCUUUUGAUAUCUGGUCAAACAUUCGAUGUGACAUCUAAAAAUUUUCUUUUCGCGAACUAAGGGCCUGUUUAGUUCGCGAAAAGAAAAUUUUUGGGUGUCACAUCGGACGUUUAACCGGAUGUCGGAAAAGGUUUUCAGACACGAAUAAAAAAAC		7
20651	MI0007030	osa-MIR1442	Oryza sativa miR1442 stem-loop	UCUAUAUUCAUAGUACUAGAUGUGUCACAUCCAGUACUAGGUUGGUGUUUUAUGGGACGAAGGGAGUAGAUCUUUUGCUAAGUGGAGGCUAAAUUCUCAUCAUCAGAGGAGUAUACUACUCCAUCCGUCCCAUAAUAUAAGGGAUAAUGGGUGGAUGCGACACAUCCUAGUAAAAUGAAUCUGGA		7
20652	MI0007031	osa-MIR1439	Oryza sativa miR1439 stem-loop	UAUUGUUUUGUUAUAAAUGUAAUACUACCUCCGUCCCAAAAUAUAGCCAUUUUUAGCUAUGAAUCUAGACAUUGUUUUUAGCUAUGAAUCUAGACAUACAAUGUCCAAAUUCAUAACUAAAAAUGCUUAUAUUUUGGAACGGAGUGAGUAUUAAAUUUGUAGUUUUGUGAUA		7
20653	MI0007032	ptc-MIR171l	Populus trichocarpa miR171l stem-loop	GGAGAAGUAGACACGGUGUGAUAUUGGUCCGGCUCAUCUUCUGUGCAUAAGCAUCUGAAGUUCUUCACUCAUGAAGACGAGCCGAAUCAAUAUCACUCUUGUAUGCUUCUUC		26
20654	MI0007033	ptc-MIR171m	Populus trichocarpa miR171m stem-loop	GAAGCAGACAUGGCGUGGUAUUGAUCCGGCUCAUCUUCUGUAUUUGCAUCAGAAGUUCUUCGCUGAAGACGAGCCGAAUCAAUAUCACUCUUGUACGCUUC		26
20655	MI0007034	ptc-MIR171n	Populus trichocarpa miR171n stem-loop	GAAGCAGACAUGGCGUGGUAUUGAUCCGGCUCUUCUUCUGUAUUUGCAUCAGAAGUUUUUCGCUGAAGACGAGCCGAAUCAAUAUCACUCUUGUACGCUUC		26
20656	MI0007035	ptc-MIR530a	Populus trichocarpa miR530a stem-loop	GCCAACAUGUUGCCUUUAUCUGCAUUUGCACCUGCACCUUACUUGUUUCUUUCUUUUGUUUUUGACUCCAAAACCAAAAGUAAGUUUGAAACAUUAAAACAAGCUUGAGGUGCAGGUGCAGGUGCAGGUGAAUGCCAUGUUGGU		26
20657	MI0007036	ptc-MIR530b	Populus trichocarpa miR530b stem-loop	GCCAAUAUGUUGCCUUUAUCUGCAUUUGCACCUGCAUCUUUUGCGUUUGUUUUGUUUUUGACUCCACAAACAAAAUCAAGUUCUGUCGAUACAGUAUGUGGGACAAUUAGAUAUGGAAACUAAUAAGCUUAGUUGAGGUGCAGGUGCAAGUGCAGGUGAAUGCCAUUUUGGU		26
20658	MI0007037	ptc-MIR1444a	Populus trichocarpa miR1444a stem-loop	GUUUAUCACUUGAAUGUUGACCGAAUAUGGAUGAAAAGUUGUUUUCUGUUUCCUUUCCUCCACAUUCGGUCAAUGUUCCAGUGAUGAGC		26
20659	MI0007038	ptc-MIR1444b	Populus trichocarpa miR1444b stem-loop	UUUAUCCCUCGAAUAUUGAUCGAAUAUGUAUGAAAUAUGAUGGUUAUAUGUUUCAUUCACAUUCGGUCAACGUUCGAGUGAUAAA		26
20660	MI0007039	ptc-MIR1444c	Populus trichocarpa miR1444c stem-loop	UUUAUCCCUCGAAUAUUGAUCGAAUAUGUAUGAAAUAUGAUGGUUAAAUGUUUCAUUCACAUUCGGUCAACGUUCGAGUGAUAAA		26
20661	MI0007040	ptc-MIR1445	Populus trichocarpa miR1445 stem-loop	AAGCUAAUUAAUCUGAUUUCCCUAGUUUAUAAGUUGUUACAAUUGAAUGAACCUUGUUUGCAAGCAUAGGAUUAGUUGCCGCCCACCAUAAAUCCCUUGUAGACUAGAAAAAUCUAAUCUGAUUUGGUUU		26
20662	MI0007041	ptc-MIR827	Populus trichocarpa miR827 stem-loop	CAUGAAUAUAUUUGUUGAUAGUCAUCUAGUGAACAUUGAAAGUCAUAUUAGAUGACCAUCAACGAAAACAUUCAUG		26
20663	MI0007042	ptc-MIR1446a	Populus trichocarpa miR1446a stem-loop	CCAACUUCUUCUGAACUCUCUCCCUCAACCGCUACUCUAGAGCUUGGCAAUCCUUGUCGAUUGUUUCUGUGUAGCGGUUGAGGUGAGGGGUUCAGAACAUGUUGG		26
20664	MI0007043	ptc-MIR1446b	Populus trichocarpa miR1446b stem-loop	CCAAUUUCUUCUGAACUCUCUCCCUCAACCGCCACUCUAGAGGUUGGCACCUUGUCAAUUGUUUCUGUGUAGCGGUCGAGGUGAGGGGUUCAGAACAUGUUGG		26
20665	MI0007044	ptc-MIR1446c	Populus trichocarpa miR1446c stem-loop	CCAACUUUUUCUGAACUCUCUCCCUCAACUGCUAUUCUAGAGCUUCCUGAGCUAACCCUUGUGUUUCUGUGUAGCAGUCAAGGUGGGAGGCUCAGAAAAUGUUGG		26
20666	MI0007045	ptc-MIR1446d	Populus trichocarpa miR1446d stem-loop	CCAACUUCUUCUGAACUCUCUCCCUCAACUGCUACUCUAGAUCUUGCCAAUCCCUGUCAAGUGUUUCUGUGUAGCAGUCGAGGUGAGAGGUUCAGGAAAUGUUGG		26
20667	MI0007046	ptc-MIR1446e	Populus trichocarpa miR1446e stem-loop	CCAACUUUUUCUGAACUCUCUCCCUCAACUGCUAUUCUAGAGCUUGUUAAUCCUUGUCAAGUGUUUCCCUGUAGCAGUCGAGGCGAGGGGGUUUCGGAAAAUGUUGG		26
20668	MI0007047	ptc-MIR1447	Populus trichocarpa miR1447 stem-loop	GAGGCCCUAAUCAGGGCACUGCAAUUCUAAAUGUCUGUUGGCAAGUGGCGAUGCCAGACGUUUGAAAUUUACUUAUCAUUUAUUAGUCAGAAUUGCAGUGCCUUGAUUUGGGCUUU		26
20669	MI0007048	ptc-MIR1448	Populus trichocarpa miR1448 stem-loop	GUUACGGGUAUGGGAGGAUUGGACAGUACUGCUUGGUUUUAAUUAACCAAAGUCUGUUCUUUCCAACGCCUCCCAUACCGGUAAU		26
20670	MI0007049	ptc-MIR1449	Populus trichocarpa miR1449 stem-loop	GAUUAGUUGAGGUGCACGUAAGAUAACUCGAUGUUAAUUUAAAAAAACAAACAGGAUCUCAAUAAAAUAAAUUUAAAAAAUACAGAAGGGUAAAUAGUGCUUGCAUUAAUUAAUC		26
20671	MI0007050	ptc-MIR1450	Populus trichocarpa miR1450 stem-loop	GAGUCAAUUAGGUCAGUUGUGUAGUCUGACCCGAGCCAUUGAAGACAAUCAUUUGUUGGUGUCUCAUUGGAUUUGUUACCUGACAGUGUUUAUCCAACAAAUGAUUCUCUUCAAUGGCUCGGUCAGGUUACACAAGCAAUCUAGUUGGCUC		26
20672	MI0007051	osa-MIR827	Oryza sativa miR827 stem-loop	GAUUUUCGCUGACGGCCGAUUUAACACAGCCACCAGCGAAAAUGAAUUUUUGCUAGCGGCUGAUGUAAGAUGACCGCUAGCAAAGAUCCAUUUUUGCUGGUGGCUGGCUUAAGAUGACCAUCAGCGAAAAUG		7
20673	MI0007052	pta-MIR482c	Pinus taeda miR482c stem-loop	AGGAGUGGGAGGGUAGGAGAAGGCUCUGUGGUGAGGUCUCAGUCAUAAUCUCAUCAGUCUUCCCUAUUCCUCCCAUUCCU		58
20674	MI0007053	pta-MIR482d	Pinus taeda miR482d stem-loop	GAGGUGUGGAAGGAUAGGGUAAGACUAAGGUUAAGGAGAAACUCUGCUUCAUUAAUUCUCUGCUCCAGUCCUCCCUACUCCUCCCAUUCCUU		58
20675	MI0007073	hiv1-mir-TAR	Human immunodeficiency virus 1 miR-TAR stem-loop	GGGUCUCUCUGGUUAGACCAGAUCUGAGCCUGGGAGCUCUCUGGCUAACUAGGGAACCCAC		60
20676	MI0007077	ssc-mir-99b	Sus scrofa miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC		27
20677	MI0007079	odi-mir-1468	Oikopleura dioica miR-1468 stem-loop	GAAGAUGAGUAAAAUUAAGGCGAGAUGAGGUCUUUGGACAGUUAAUUAAUGACCGAUGACCUACCGCCUCAAUUUAACUUGCUCUAAAUUCGACAGAGAGAUUUU		73
20678	MI0007080	odi-mir-1469	Oikopleura dioica miR-1469 stem-loop	AGGCCGGAGAUCGUCAAUGGAGAACGCUUCAGCUUUGCGAGCAUCCUCUGUGGGACAAUCUUCUUUGGCAAGAUGGUCGCGAAACUUCCGGAGUCGAUUUCUAC		73
20679	MI0007081	odi-mir-1470	Oikopleura dioica miR-1470 stem-loop	AAAGUGAUGCGAUGACACACCUUAACACCAGUGCGCUGAAGGGGAUCCAAUAUAACAAACCCUUCCGCGGACAGGUGUUAGGUGAAUCUUCACGUUGCAACUUU		73
20680	MI0007082	odi-mir-1471	Oikopleura dioica miR-1471 stem-loop	UUAACUUGAAUAGAAUCACCUUGGUAUCAAAAUUUGCGCUGCUGGAAAUUAAAUAAAUUGUUAACAGACAAGUUUUGAUACAAGGUAACUCGAAACAAGUUAC		73
20681	MI0007083	odi-mir-1472	Oikopleura dioica miR-1472 stem-loop	CGCUUUUCAAAUAGACUUGCUGAAAAGUAGAGAAAAUGAGCGGUUUUGAAAAUCCAGUGACAACUUGGCAGUAAGAUGAUUUAGUACCCUUAAUAAAACUUGU		73
20682	MI0007084	odi-mir-1473	Oikopleura dioica miR-1473 stem-loop	AAUCCGCACUCCGUUAGAAUCUGGAGCCAUCGCAGAUUCGGACUUGUUGUUUGUUUCAAAUUCUGUCAAGCUCGGGUUUAUCGGUGUGCGGCGGGCUGCGCA		73
20683	MI0007085	odi-mir-1474	Oikopleura dioica miR-1474 stem-loop	AAUGCAAUUGAAAAAUGUCAGGACUGAGGUUGUGCUUGAGCUUUAAUUGAGCAUAAUCACGCUCUUGAUUUUUGUCAUUGUAAAAGCUCGACGAGUAAACCC		73
20684	MI0007086	odi-mir-1475	Oikopleura dioica miR-1475 stem-loop	GAUAAUGAGUCGCAUCCGUCCUAAGUUUAUUAUGUGACCUACAGAUCAAAAAGAUAAAAUGAUUCUCUGGGCACAGGUAAACUUUGACGAGCGAGCUCACG		73
20685	MI0007087	odi-mir-1476	Oikopleura dioica miR-1476 stem-loop	AGCCGAGAAAUCUUUUCUGGGCAAAGGUAAAUGUAUGCGUAAGCAUCACUUACCCACAUCUUACAUGUACCGUUGCUCAGAGACGGUCUCGCGCUAUCAUCG		73
20686	MI0007088	odi-mir-1477	Oikopleura dioica miR-1477 stem-loop	GACGUGUAUUUGGCAUGUGCAAAGCCCUAACAUUUCUAGUAGCCCGGGGGGAGUGUAUAGAAAUGGAGGGAGUAGCACCCGCCAAGCGUUUGAGCUUUCGACA		73
20687	MI0007089	odi-mir-1478	Oikopleura dioica miR-1478 stem-loop	CACCAGUACCUAGCGUGGAACUAGUAUGGAGCAGGCUGACCUUACACAAGAAAAAGCCCUCAGUCCUUCAAGCUAGUACCCCUUUAGGGCUGGCACGAUCGAC		73
20688	MI0007090	odi-mir-1479	Oikopleura dioica miR-1479 stem-loop	GUCGCGAGGUGGAGACAACGAGUCCUUGAAAUUACCGGCUGAGAACAGAAAAUAACCACUCAGCUGGUAUAUCAGGAUCGUUUCCUGCAUCCGUGAGCACUCG		73
20689	MI0007091	odi-mir-1480	Oikopleura dioica miR-1480 stem-loop	UCUUCUUGUUGACUCGGUGGCUCAUUCUCGGCUUGUGUCAGAAUUAUUGCUGAUCCGAAAUGAUCGUGAUCAGAAGGAUAAAAAUGAUAACAAGCAUUCUAGAA		73
20690	MI0007092	odi-mir-1481	Oikopleura dioica miR-1481 stem-loop	CUACCGCAAGAGGGGCCACAAUGAAGAUAGAAGAUGGCUUCAGAGUUUUAUUUGUACUGAGCCGACUUCUAUUCAUUGUCGCUUUUAAUGCGAGUACACUCGAC		73
20691	MI0007093	odi-mir-1482	Oikopleura dioica miR-1482 stem-loop	UUGAUGCCGAGACGCUUGAACUUCUCAGGAACAGGCUAGACUGGUAUAUCCUGCAAACGAGAGAAGCCUAUUUCAGAGGUUUGAACACAUUAGCACAACAACUC		73
20692	MI0007094	odi-mir-1483	Oikopleura dioica miR-1483 stem-loop	CAACCCAGUUUCUCGCGGCAGUGAGUCGAUAGCGCCCUUUCGGCGUAUCUAGAAAAUUUUCGAAAGGGCCAUCGCCUAUAUCUGCCCAAAGAAACUGGGAAUA		73
20693	MI0007095	odi-mir-1484	Oikopleura dioica miR-1484 stem-loop	UCGCAGGGACCGGUCGACCAUAAUGCGUUGUUUGACCUUUUGGCUGGCUGAAGCCAGGAACGGGUGAAACUUCGUAGAUUUGGUCACUCGGCUCUAGAUCGAG		73
20694	MI0007096	odi-mir-1485	Oikopleura dioica miR-1485 stem-loop	ACCGUUUUUUAGCUGAAGGUAAAGCUGGCUACAUAACGUUUGCGCUUAGACAGAAGACGUUAUGUUGUCCCUACCUACAGCUAGCUGCUCGCAUUUCGACAGAU		73
20695	MI0007097	odi-mir-1486	Oikopleura dioica miR-1486 stem-loop	CUUAACCGGUUGCCACUAGGUGGUUUUUUCGAUGAAGGUGCCCAGUAAACUGGGUACCCUCCCGAAUUAAAACACUUACUAUUUAUAGUGAUAAAAAAUUUUAU		73
20696	MI0007098	odi-mir-1487	Oikopleura dioica miR-1487 stem-loop	ACACGAGCGCCAGACUGGCAGUGGGGACAAGUUUAGGCCCUGAGGCGGAUUGAAAAAUGCCCCAAGGCCUGGGCCCACUUCUUGACUGGCCCCGUGACAAAC		73
20697	MI0007099	odi-mir-1489	Oikopleura dioica miR-1489 stem-loop	UGAGCUGUUGUUAGAUAGGUAAACCACGGAUUGCUUAUUGAAAAAGAUAGUAAGCCGUCCCUGGAAUAUCUUCCCUAACACGUGCUUCUAUUCGACUAUCUU		73
20698	MI0007100	odi-mir-1490a-1	Oikopleura dioica miR-1490a-1 stem-loop	GGCUCGUUUACAGUUAGGCAGUGAGUUGAUAGCGCCCUGAAAUGGAAAAAUCAGGGCCUCUCACCCACUACCAUGACUGUACUUGCCCUAUUCGACCCUCUC		73
20699	MI0007101	odi-mir-1490a-2	Oikopleura dioica miR-1490a-2 stem-loop	UAUCGCCAGAAAAUUAGGCAGUGAGUUGAUAGCGCCCUGAACUGCGAAUUUCACCGUCCCGGGACUAUCGUUACUGUCCCAUUUUCUGGCCGAAUAUUCGAC		73
20700	MI0007102	odi-mir-1490b	Oikopleura dioica miR-1490b stem-loop	CGCCGGUCUUUCGCGAGGCAGUGAGUUGAUAGCGCCCUGUAGAGUGGGUUUAGAACUAAACGAGGCCUAUCCUUACUCGCCACAACGAAGCGCUGACUGUUC		73
20701	MI0007103	odi-mir-1491	Oikopleura dioica miR-1491 stem-loop	UGGCUCGUUUCUGCGACCCUGAGUGCAGAAUCUUGGUCUGGUGGAACUAAAUAGAACCAACGCCGGACCAGGAAUUUGUCCGGGAAACAGAACGGGCCACU		73
20702	MI0007104	odi-mir-1492	Oikopleura dioica miR-1492 stem-loop	CUAAUUAUGAGCAGAUCAGGCAGGACGUGGUUUUGUGCGAAACCGGCGAAAUCUGAGUUUGAUGGUAUUGCACAUACCCGGCCUUGCUGAUCUUGCUUUCA		73
20703	MI0007105	odi-mir-1493-1	Oikopleura dioica miR-1493-1 stem-loop	UGUCACUCGAAAAGCAGAACUGUCUGAAUGGUUGGCUAAACGGGCUAAAACUCCCGAAACUAGCCAGUCUGCGAGACAGUUCCGUUUUUCAGCGACCUGA		73
20704	MI0007106	odi-mir-1493-2	Oikopleura dioica miR-1493-2 stem-loop	UUGAGAUCAAGGAUGAGAACUGUCUGAAUGGUUGGCAGUCGGAAAUUUUAAUUUAUACCGACGCCAGCUAUGCACACAGUUUAAAUUCGAGAUCUACCAC		73
20705	MI0007107	odi-mir-1494	Oikopleura dioica miR-1494 stem-loop	GGUUAUUGAAUGAUAAAGCAGCAAGGACAGUGUUUGGUGAUUUUGACCAACUGAAGACUAUCUUUGCUCGCUCCAUCAAGCUAGCCACGAACUACGAGAGAU		73
20706	MI0007108	odi-mir-1495	Oikopleura dioica miR-1495 stem-loop	AGUGAAAAUUCGAGUUUCAGAAUUUGUUUCGUGCGGUAUUUCAGUUCUGUAUUUUCAAUCUUGGAAGUGUAAUACCCAUGGAAGCAUUUUCGAAUUUGACCAA		73
20707	MI0007109	odi-mir-1496	Oikopleura dioica miR-1496 stem-loop	CAGGCAGCGAUUUGAUAGCAGUGAGAGUUUAGCAUUCGCAACAUUUUUUACUGUUGCGAUGCUGCUAACUGCUUUUGAGUUACUGUCACUAUCGACGACGGAUAACU		73
20708	MI0007110	odi-mir-1497a	Oikopleura dioica miR-1497a stem-loop	UCGAGAGUCUCUAGCUUUUGCGAAUCCGCUUCCUCAGUGCUUCCAUAAGUUUAAGUUCACGCUUAUUGAAGAACUGCAGGUGGUGGAUUUACUCUUGCAAUAA		73
20709	MI0007111	odi-mir-1497b	Oikopleura dioica miR-1497b stem-loop	AGUAGUCUUUUUGACAGAAAUUGGUCCUACCUGACUUUUCUUCGAUAAGCUAUUUGAUAAGGCUAUUGAAGAACUGCAGGUGGUGGUCCGACUUCUGCCAAAA		73
20710	MI0007112	odi-mir-1497c	Oikopleura dioica miR-1497c stem-loop	UUUUUCAGAAAAUGACAGUGGAUAGUCCUACCUGACUUUUUUCCAAUAAGCUGUUAAAAAUGCUAUUGAAGAAUUGCAGGUGGUGGUCCUUCUGAUGCCAAAG		73
20711	MI0007113	odi-mir-1497d-1	Oikopleura dioica miR-1497d-1 stem-loop	CACUUUUUAUAAUUGUUGAUUGACUAUAAGCUAUCUAAAAUUCUUCUUUACUUUACAUUAGAGUAUUGAAGAAUUGCAGGUGGUGGAUAGUGUAUCAUCAUCU		73
20712	MI0007114	odi-mir-1497d-2	Oikopleura dioica miR-1497d-2 stem-loop	AAAAAAGAACAUUCUUGAAUCACUCUCAACCAUCUAAUAUUUUUCCAUACGUUAAGAUAAAUGUAUUGAAGAAUUGCAGGUGGUGGAUAGUUUUUCAACCUUU		73
20713	MI0007115	odi-mir-1497e	Oikopleura dioica miR-1497e stem-loop	UACCCACAAUUGACUCUGUGUUUACACCUCCAUUUAAUUCUGAAAGACUCAAAAUUGACAAGGUUUUGAAGAAUUACAGGUGGUGGAAAUACAGUUGUCCACG		73
20714	MI0007116	odi-mir-1497f-1	Oikopleura dioica miR-1497f-1 stem-loop	AACUAAAACAAAGGCCUAGACCCUGACCACCUUUCUUUUCUUGGAAAACUUAUAGAGUUAAGCUUUUGAAGAAUUGCAGGUGGUAGGGGGUCUACGCUGAUUG		73
20715	MI0007117	odi-mir-1497f-2	Oikopleura dioica miR-1497f-2 stem-loop	UUGUUAAAUCCUUCUGGACCUCAAACACCUUGCUUUUCUUGAGAAACUCGAGUAAAAAUGAGCUUUUGAAGAAUUGCAGGUGGUAGGGGCCAGGGAAACAAUC		73
20716	MI0007118	odi-mir-1497g	Oikopleura dioica miR-1497g stem-loop	UGAAAAAACUUGCUUGGAAUUAGGUCCACCACCUUACAGUUCUGUCAAGGGUUGAGCCAUUGCUCUUGAAGAAUUGCAGGUGGUAGGUUCUGUCCAGGAAACA		73
20717	MI0007119	odi-mir-1497h	Oikopleura dioica miR-1497h stem-loop	AAAAGGUUGAAGAGCAUGAACACCCCUUUCCAAUUCUUAGAUGAGCUAUUUAAGUCACAAGCUUAUUGAAGAAUUGCAGGUGGUGGACAAGCCUUUCAAAAAU		73
20718	MI0007120	odi-mir-1498	Oikopleura dioica miR-1498 stem-loop	CUGGCGAUUUUGCGAAGGAAUGUAGAAUUAGGAAUUCGGAUAGCUGUUUAUAAAUAGAUGCUUUCGAAUUUCAAUUUUCAUUCUCCCGCAAGGUCAGCCACAGA		73
20719	MI0007121	odi-mir-1499	Oikopleura dioica miR-1499 stem-loop	CGGCUCGCGUCGAGGCACACCUUUACCAGUGCGCUGGAGCGAAUCGAACCUGAACCAGCCGCAUCGGUUAAGGUGCCACUCGACCGUAGGAAUAUCAUUGUA		73
20720	MI0007122	odi-mir-1500	Oikopleura dioica miR-1500 stem-loop	AUCUUCAUUGCAUUAUUUUUAAUCAACUGCGUGAUCUUAUUCAAGUCUUUGGAAUAAUUUGAAACUUGAUAAGACUGUCAUUGAUGAAAAUUUAUGUAACCU		73
20721	MI0007123	odi-mir-1501	Oikopleura dioica miR-1501 stem-loop	UGACGAUUCCGCGACCAGCUGAGUCUUUGAGAGUAGAGCAUGGAUCGAGCGGACGUUCUGCUUUCUAUGCUGUACUGCAAAGGCUCCGGUGGGAUAGCGCGG		73
20722	MI0007124	odi-mir-1502	Oikopleura dioica miR-1502 stem-loop	GCAAGCUCGGAGCAGUGAACUUUACCAUGGAACCGGGACUAUUUCACAUAAUCACGUGACCCUGGUUUCGUUGUAAAGUUUUCUUUACUGAGCUGACCAAUC		73
20723	MI0007125	odi-mir-1503	Oikopleura dioica miR-1503 stem-loop	CUCAGGUAGAAUCCUCUGAUCGAUGGGCGGUAGUGACGAUUUCUUUUUAGGGCGCAGAAGAGUCCCGAGGAAGAUCUUGUGGCAAUCAAUAAAAUCUUGG		73
20724	MI0007126	odi-mir-1504	Oikopleura dioica miR-1504 stem-loop	GCAGCAAAUGAGCGGGCGCGCUCCUAACCCUAGUUGCAGGUACAAGCUUUCGCCUCGCAAGAUAAAGUGUACUUGGUGCUUGGGUUGUUCAAUUUGGGGCG		73
20725	MI0007127	odi-mir-1505	Oikopleura dioica miR-1505 stem-loop	UUGAAGAACUCGCCUAGGUCAGUCUCUGUCUUUCUUCCUUUCACAGUUGGCUUCGGAAGAGCGGCAGUAGACUGACUCGGCGCCUCAUUUUUAGCCUCCUUCU		73
20726	MI0007128	odi-mir-1506	Oikopleura dioica miR-1506 stem-loop	UUGAGAACUCGCCUUUGGCAGUACCUAAGUCCCUGAGCUCUAAAAAUGAUCAGAGACUUUUCUUACUGCCUCAGGCUGGUACCUCACCUUCGACGAAGCUA		73
20727	MI0007129	cin-mir-1473	Ciona intestinalis miR-1473 stem-loop	GCGGCUCUGGCACCCACGUAUUCGAUCUUGCGAGAGAUAAAGGACAUCUCAAGCUCGGGUUUAUGGGUGUUGGACCAAGC		74
20728	MI0007130	cin-mir-1497	Ciona intestinalis miR-1497 stem-loop	GCCGGAAUCUGGCUGUUAGCGCAACCACUUGUGAAUCUCCAACACUCGGCUUUGUCCACGACUUUGUUGAAGAAUUGCAGGUGGUAGGUGCUUUCAAGCCGUAU		74
20729	MI0007131	csa-mir-1473	Ciona savignyi miR-1473 stem-loop	CGAAACAUCAUUAAAUAACCUACGUGGGUCUGGCUCCCAAAUCUUCGAUCUUGUGAGAUAUAUUCUCAAGCUCGGUUUUAUGGGUGCCGCAUCCAACGACA		72
20730	MI0007132	csa-mir-1497	Ciona savignyi miR-1497 stem-loop	ACCAUCAGGCUGGUAUAAGCGUAACCUCUUGUAAAUCUCCAACACUAAGCUUGGUUACAGCUCUGUUGAAGAAUUGCAGGUGGUAGGUGCUAUCCAUGCAUUA		72
20731	MI0007133	odi-mir-1a	Oikopleura dioica miR-1a stem-loop	CAAAAUCAGCCGGAAAUCGCGAAGCCAUACUUUUUGACAUUCUUUGCUGAACUUUUAAAUGACGCUGGAAUGUUGAGAAGUGUGAUUUGGCGAUUUU		73
20732	MI0007134	odi-mir-1b	Oikopleura dioica miR-1b stem-loop	AAUAAAAGUCACGGUGCCUGUCCACAUUUACUGACAUUCUUUGCCUAUUUCAAAGUGCAAGGGCUUGGAAUGUUAAGAAGUGUGACUAGACAAGUGACUCUC		73
20733	MI0007135	odi-mir-1c	Oikopleura dioica miR-1c stem-loop	UGACAUGGCAGCCACGGUUUACGUACUCAUUUACAUUCUUUAAGACGCUGGUUUUAAUUUCCUUAUGGAAUGUAAAGAAGUAUGUGAAAGUGGGAUGCCCUU		73
20734	MI0007136	odi-let-7a	Oikopleura dioica let-7a stem-loop	AAAAUAUUGACGCAAUGAGGUAGUGGACUGUUUAGGAAGGAAAUUAAAAUAAAUCCAUUCCUAAACUUCACACUAACUCCUUAAGUCGCCCACACCAUCGCCG		73
20735	MI0007137	odi-let-7b	Oikopleura dioica let-7b stem-loop	UCGGCUUGGUGUCGUUGAGGUAGUGGUUGUAAUAGCUCAAGAAUAUACCCUCCCGAGCGCUAUUCCACAAUCUACUUCUCCAUCACCGAUCCACAGUCGACA		73
20736	MI0007138	odi-let-7c	Oikopleura dioica let-7c stem-loop	AGGACUAGUUCUGCAUGAGGUAGUAGGUUAUGCUGUUCGGAAAAUAAUAUAAACGGUAACAGCGUAAAAUGCGCCUCUCCAGAACUCAGUCCAUAUUCGACA		73
20737	MI0007139	odi-let-7d	Oikopleura dioica let-7d stem-loop	CGCCAGUUCCGUUUGAGGUAGUGGGUUGUAUCGCUGAGGGAACUAAAGUUUCACCCUGGCGCUGCAACAAACUACCCCCUACGGCGCGUGGUGCUACUCG		73
20738	MI0007140	odi-mir-7-1	Oikopleura dioica miR-7-1 stem-loop	AUCUGGUUGACGGUUUGGAAGACUAGUGAUUUUGUUGACUUGGACAUAAUUGUCGUUUCUUGUCAACUCACACUAGUUUCCCGUACUGCAUCGGAUUCAAUC		73
20739	MI0007141	odi-mir-7-2	Oikopleura dioica miR-7-2 stem-loop	AUCUGGUUGACGGUUUGGAAGACUAGUGAUUUUGUUGACUUGGACAUAAUUGUCGUUUCUUGUCAACUCACACUAGUUUCCCGUACUGCAUCGGAUUCAAUC		73
20740	MI0007142	odi-mir-31	Oikopleura dioica miR-31 stem-loop	UGUCAAUUUGCGACGAGGCAAGAUGCUGGCAUUGCUGCCAGUCCCGCUAAAUGCGCUCUCGGCAGCUCGACGGCAUUUGCUUCAUCGCAUUGAUAACGCUCG		73
20741	MI0007143	odi-mir-92a	Oikopleura dioica miR-92a stem-loop	ACAGUAAUACUUGGUUGAGAUUCUAGGUCUAGUCAGAGUGGGUUUACAGACGAUUUUUAUAUCUGUAUUGCACUCGUCCCGGCCUUGGAAUACUUUAACUA		73
20742	MI0007144	odi-mir-92b	Oikopleura dioica miR-92b stem-loop	UAACCUUUUCGAAAGUCUACCAGUCGCGAUUAAGUGCUUUGUUAACUAAAACUAGAAUAUUAAAUAUUGCACUGGUCCCGACUAAUAGAAGUGCGAGAACA		73
20743	MI0007145	odi-mir-124a	Oikopleura dioica miR-124a stem-loop	UUUUGAACUAAGCUUACUGGGCAGUAUUCCGCUUGUGUGCUUGACAAUUUAAGUGUAGCACUUUGUAAGGCACGCGGUGAAUGCUAAGCAGUGAGCUAUUAC		73
20744	MI0007146	odi-mir-124b	Oikopleura dioica miR-124b stem-loop	CCGCUACCGGGCUUAAUUAGUAUUCGCAAGAGCUGCUUGAGAAGUGCUCGAUUCUAGCAUCGUUCUAAGGCACUCGGUGAAUGCUAAAUGAGCUCUGGAAUA		73
20745	MI0007147	odi-mir-219	Oikopleura dioica miR-219 stem-loop	GAGUGAAAUAUUCGGUGAUUGUCCAAACGCAAUUAGUAGACGAAAGAGAAACGGAUUGACGUUUGGCCAAUCGGCCUAAAAUACUCUGCAGUCGACGGUAA		73
20746	MI0007148	odi-mir-281	Oikopleura dioica miR-281 stem-loop	UUCAUUUAUCAAGGCUGAAAGCAAAAAGGAGGCAAAGUUCAUGAUUGUCGAAAGACAAGGAAUACUGUCAUGGAAUUGCUCUCUUGAUGCUCUUUGCAAAC		73
20747	MI0007149	cin-let-7a-1	Ciona intestinalis let-7a-1 stem-loop	AUGGCCGUGACCACAAUGAGGUAGUAGGUUAUGCAGUUAUAGCCUCCCUUUUAUACUGAGUGGAGCACAGGAGAUACUGUGUAACCUUCUGCCUUUGUGGCUUCGUGUUU		74
20748	MI0007150	cin-let-7a-2	Ciona intestinalis let-7a-2 stem-loop	AUAGUUGUCGAUAUUAUGAGGUAGUAGGUUAUGCAGUUUUGCGACAUUAUUCUCGUUGCGUUGGAGAUAACUGUGUAGCCUACUGACUCUAAUGUCUUCAGCUCUCUCUU		74
20749	MI0007151	cin-let-7b	Ciona intestinalis let-7b stem-loop	AGGUACACCUGCUGUUGAGGUAGUAGGUUAUGUUGUUGCACAUAAUACUGCAUUGGAGAUACACCAUGACCUUCUAACCUCUGCACCAUGUCUAUCACUUUCAACAUGG		74
20750	MI0007152	cin-let-7c	Ciona intestinalis let-7c stem-loop	UGAACUGAUUCAAGUUGAGGUAGUAGGUUAUAUCAGUUGAUUAUAUGAACCAGGAGAUAACUGUAUAGCCCACUAGCUUACUUGCAUGGUUUACUUUCAACCAAAAAGAG		74
20751	MI0007153	cin-let-7d	Ciona intestinalis let-7d stem-loop	UCAGCUAUUCGUGGCUGAGGUAGUUGGUUGUAUUGUUUCCCUUGUGUAAUGUUAACUAUACAGCCCGCUAGCUUAACCAUGGUUGCUAACUAUCCACGAAU		74
20752	MI0007154	cin-let-7e	Ciona intestinalis let-7e stem-loop	UCAGCUAUUCGUGGCUGAGGUAGUUGGUUGUAUCGGUUCCCUUGUGAAAUGUUAACUAUACAGCCCGCUAACUUAACCAUUGGUUGCUAACUAUCCAC		74
20753	MI0007155	cin-mir-7	Ciona intestinalis miR-7 stem-loop	AUAUCCGCACCCGGUUGGAAGACUAGUGAUUUUGUUGUUAUAGCAACAACAAUCUAUGGUCUCCUGCACGGAAGUGGA		74
20754	MI0007156	cin-mir-31	Ciona intestinalis miR-31 stem-loop	AUGUAACUGGUUCUAUGGCAAGAUGUUGGCAUAGCUAUUUCACAUGAUGUGAUAUAGUGUGCUAAUAUCUAGCUUUGGUACUAGCUUAAGAAAUCAACGCAA		74
20755	MI0007157	cin-mir-33	Ciona intestinalis miR-33 stem-loop	UGGUAGUUUUCCCUUGUGCAUUGUAGUUGCAUUGCACUGUUGCAUUGUGGGUAAUGUGACAACAAUACAACCGGGAUUUCUGCACAGUCAUCAUAAAUUUG		74
20756	MI0007158	cin-mir-34	Ciona intestinalis miR-34 stem-loop	UUUCACGUGAUUCUGAGGCAGUGUAGUUAGCUAGUUGUUUUCUUGCCGAGAUGGACUUGCAUCCCGAACGGUUUAUUUCGAACAACUGCUUUUUGCACUACCACGGAAAUCACUUGACU		74
20757	MI0007159	cin-mir-78	Ciona intestinalis miR-78 stem-loop	AUUAGAUGUUGAGAAGGACACUUAUCGGGCAUCAAGUUUGUGAUGAACAGCGUCAUGGAUGAAACUGGAGGCCUGGUUGUUUCCUGUAUAGUUGAUAAUGG		74
20758	MI0007160	cin-mir-92a	Ciona intestinalis miR-92a stem-loop	GAAGCUUUAGUGAAGUUUGAUUAUAUAUUACUCGACGGCUGGUACAAGAGCACGAUCGAUUAGGAUAUUGCACUUGUCCCGGUCUUAGGGUGGUAUAAAAA	Norden-Krichmar et al refer to this sequence as mir-25 [1]. 	74
20759	MI0007161	cin-mir-92b	Ciona intestinalis miR-92b stem-loop	AAAAAGCUCCAUUUUCGCAGUUUACUUGCAGGUUUGGACCGGUGCACCAGAUUAUAUAAGAUUUCUAUUGCACUUGUCCCGGCCUUCAAAUACUGCUGAAC		74
20760	MI0007162	cin-mir-92c	Ciona intestinalis miR-92c stem-loop	UCCCAAACUUAUAAACUGUACCUGCAUACUUAGGCCUGGCGAAGUGCAUUGCGUUGUCAUGGUCGUAUUGCACUCGUCCCGGUCUAUGUAUCUGGUAAAAA		74
20761	MI0007163	cin-mir-101	Ciona intestinalis miR-101 stem-loop	UUGAACCAUUUUUUCUUACAGAUUGGUGACGCUGACUGAUAUAUGUGAGAAAAGUGAACAUAUGGUACAGUACUGUGAUAAAUAUUUGACAGGAAGAAAAGG		74
20762	MI0007164	cin-mir-124-1	Ciona intestinalis miR-124-1 stem-loop	UAUGUUCGGUAGUAUUUAUUGUGGACCUUGCUGUGUGACGUCACAAUAAGGCACGCGGUGAAUGCCAACGAAUUUUU		74
20763	MI0007165	cin-mir-124-2	Ciona intestinalis miR-124-2 stem-loop	CGUAAUAUUUAAAGGGCGCUUAUGAGUCGUGUUUACUGUGGACCUUGCUGUGUGACGUCACAAUAAGGCACGCGGUGAAUGCCAAUCAAAAGUCGCCGC		74
20764	MI0007166	cin-mir-126	Ciona intestinalis miR-126 stem-loop	UUUCGAUGCUGCCUUGUUACCUACGGUACCAGGUAGAAAGUAUGUCAUCUCGUACCGUGAGUAAUAAAGCAUUCUCGGGAG		74
20765	MI0007167	cin-mir-133	Ciona intestinalis miR-133 stem-loop	AGAAAACAUUGCGGGUGUCGGUCGUUGGUAAAGUGGAAUCAAACCUUACGGUUUUAGUCCAUGGUUUGGUCCCCUUCAACCAGCUGCUGCUACCACGCACA		74
20766	MI0007168	cin-mir-141	Ciona intestinalis miR-141 stem-loop	UGGUGUAUCUUGGUCAUAUAGUGUUGUAGAUUCAUGAUCUAACACUGUCUGGUAAAGAUGCAUUCGACGUGUCUC		74
20767	MI0007169	cin-mir-153	Ciona intestinalis miR-153 stem-loop	UAAUAAAAUGAGAAUUCUGUGUACGUGUGUCAUUUUUCUAUUAUGCAACUUUUUUUUCAUGUUAGUUGCAUAGUAACAAAAGUGAUCAUACGUUCGCAUGAG		74
20768	MI0007170	cin-mir-155	Ciona intestinalis miR-155 stem-loop	GGUUGAGAUUGAAUGUUAAUGCUAAUAGUGAUAGGGUUCAUAAACCUUAUAAAGUUUAUUAAUAUUCCAAAAUCACUCAAAAUGCCACCAAUAGUUUUCUC		74
20769	MI0007171	cin-mir-181	Ciona intestinalis miR-181 stem-loop	AGAUGUUUGUGUAAUAACAUUCAACCUGUCGAGCAAGCCUGCUUAACUAGUCGUUGUUAUUUUUGACCUCGCUACUGCAGAUGUUGGACAUGUUUGGUGUAAGUAACAAUGUUG		74
20770	MI0007172	cin-mir-183	Ciona intestinalis miR-183 stem-loop	CUGGUGUUUUCGGUGUAUGGCACUGGUAGAAUUCACUGCCAAGCCAGUGGUUCAACAAGCGCCGUAAGCUGGAAACACUA		74
20771	MI0007173	cin-mir-184	Ciona intestinalis miR-184 stem-loop	GCGUAAUAGAACUUGCCACUUCUUCGCUUUCCAUCAUUUUGGGGUUAAAUCACCCAAGCCAUUGAUGGACGGAGAACUGAUAAGGGCUCUUGCGUUGGUCAA		74
20772	MI0007174	cin-mir-199	Ciona intestinalis miR-199 stem-loop	UUGAUAGGACUUGAUGUGGCGGUAAAGGAUACACCUGCAGCAACUUUGCGGCACUUCGGCAUACGACAGUAGUCUGCACAUUGGGUGUCUAGCUGCUACAUG		74
20773	MI0007175	cin-mir-200	Ciona intestinalis miR-200 stem-loop	UUCGUGCCAACCGAAUCACCAACCACGUAGUAUCGGAGCAUUGUGUGUCUAAUACUGCCUGGUAAUGGUGAUUGGGUGGAUACGUA		74
20774	MI0007176	cin-mir-216	Ciona intestinalis miR-216 stem-loop	UUACUCGAGCCUGCUUAAUCUCAGCUGGCAAUCUGUGAUGUCAUAAUCAUCACGGGGCAAGAUGGGAUUUUGCUGACUAAGGGUUUAACGACUCAGCGUAUUAU		74
20775	MI0007177	cin-mir-217	Ciona intestinalis miR-217 stem-loop	AUAGUUGUCGUGAUUUACUGCAUUAGGAACUGAUUGGUCCAAAAACCUCCAAUCAUAUCCUUGUGCAUUAUAUUUCGGGAACGACUCACUUCAAAGUUAAACA		74
20776	MI0007178	cin-mir-219	Ciona intestinalis miR-219 stem-loop	AUGGCGUCUGUUUCGUGAUUGUCCAAACGCAAGCUCAGUUUUAAAAUACUGCGAUUGUGUCUGGACAUCUCAAAUCAGAAGGCUGCUGUCUUCAAAAACCAA		74
20777	MI0007179	cin-mir-281	Ciona intestinalis miR-281 stem-loop	UUGGAAAAUAUAUAACUGUCCAGUGCGUGUCGGAGAGUAAUUUCAUGUUAGUGACAUCAUACUACUGUCAUGGAGUUGCUCUCUUAUUAGCGCUGAGGCCA		74
20778	MI0007180	cin-mir-672	Ciona intestinalis miR-672 stem-loop	ACAUUGAUGGAGAUAUGAGUUUGGUGUACUGUGUGUUGCAUGUCGUCAAGCAUCCAAUGGCUCGACUUGCCCGACAUCCCACAACGGGUUCAUGGUUUCAA		74
20779	MI0007181	csa-let-7a	Ciona savignyi let-7a stem-loop	CAAAGCCGCUCAAAAUGAGGUAGUAGGUUAUAUCAGUUGAAUAUUUUACCAUGGUGAUAACUGUAUAACCAACUAGCUUUCUUAAACGGUUUACUAUCAGCA		72
20780	MI0007182	csa-let-7b	Ciona savignyi let-7b stem-loop	UAGUAGUCUUGUUGUUGAGGUAGUAGGUUAUGUUGUUGCGUGAAUUACAACACACAGGAGAUACAACAUGACUUACUCAUCUCUGCAGAAGGGCUACAGCUA		72
20781	MI0007183	csa-let-7c-1	Ciona savignyi let-7c-1 stem-loop	GGGCUUCUCCCACAAUGAGGUAGUAGGUUAUGCAGUUUUUGCCUUGAAUGUUUUUAGAGGCACAGGAGCUACUGUGUAACCUUCUGCCUUUGUGGCAGAUG		72
20782	MI0007184	csa-let-7c-2	Ciona savignyi let-7c-2 stem-loop	CUCUUGCUGAUAACAUGAGGUAGUAGGUUAUGCAGUUUGGCGACAAUAUUUCGUUGCAAAGGAGAUAACUGUGUAACUUGCUGGCUCUUUUAUCGACAACUC		72
20783	MI0007185	csa-let-7d	Ciona savignyi let-7d stem-loop	GAGGCUAUUCACAGAUGAGGUAGUUGGUUGUAUUGUUUUACACCUUCGGCGAUAACUAUACAGCCAGCUAACUUUACUGUGGUUGCUAAAUAUCGUCCAGCA		72
20784	MI0007186	csa-mir-7	Ciona savignyi miR-7 stem-loop	CCGUCCUCUACCACGUGGAAGACUAGUGAUUUUGUUGUUUCAUCAACAACAAUCUUUAGUCUACUGCACGGUUGAUGGAUGCUAUCAUCAUUUCUUAUUUUUG		72
20785	MI0007187	csa-mir-31	Ciona savignyi miR-31 stem-loop	AUGUGACUAGCACUAUGGCAAGAUGUUGGCAUAGCUAUAAAAAUGUUAAACAUAGUGUGCUAAUGUCUAGCCUUGGCGCUAG		72
20786	MI0007188	csa-mir-34	Ciona savignyi miR-34 stem-loop	AUUCACGUGAUUCUGAGGCAGUGUAGUUAGCUAGUUGUUUUCUUAUCCGGGUGGGUUUGUACCCCACAUCGGUUUUCAUAUAAACAACUACUUUUUGCACUA		72
20787	MI0007189	csa-mir-92a	Ciona savignyi miR-92a stem-loop	AUCAUAACCACAACUAUGUAUCAAUAUGCCUAGACCAGACAAAGUGUAUUGCGUUGUUGCAAUCGUAUUGCACUUGUCCCGGUCUAAGCAUUUGGUAAGAAAG		72
20788	MI0007190	csa-mir-92b	Ciona savignyi miR-92b stem-loop	CCCAGCCUGACAAAGACCUACUGAAUACAGUGCUGCGGUCGGUUUAGGCGCAUUAUCUCUGUUGAUAUUGCACUUGUCCCGGUCUUAGUAAAGUAUGACU		72
20789	MI0007191	csa-mir-92c	Ciona savignyi miR-92c stem-loop	GUAUAUAGCAGUCAGGAACGGCCGAGUGUGGUGUAUUGUACUCGUAGAAAUAACAGUAUUGCACCUGUCCCGGCCGAUCUUGGGUGCGCCU		72
20790	MI0007192	csa-mir-124-1	Ciona savignyi miR-124-1 stem-loop	UUAUAAUCGACGUCAUAGCCAAGUUCGAUCGUGUUUAUUGUGGACCUUGCCGUGUGACGUCACAGUAAGGCACGCGGUGAAUGCCAACGAACUCGCGCUGCAU		72
20791	MI0007193	csa-mir-124-2	Ciona savignyi miR-124-2 stem-loop	GUGACGUAAAAUCAAUAAUGCGCUUCAUCCGCGUUUGCUGCGGACCUUCUUGUGUGACAUCACAAUAAGGCACGCGGUGAAUGCCAAUGAAACGUCAUCACU		72
20792	MI0007194	csa-mir-126	Ciona savignyi miR-126 stem-loop	GUGUCAUAAUUAUGGUUUUCGAUGCUGCCUUGUUACCUACGGUACCAGGUAGAAAGUAAGUCAUCUCGUACCGUGAGUAAUAAAGCAUUCUCGGAGGCUCA		72
20793	MI0007195	csa-mir-133	Ciona savignyi miR-133 stem-loop	UGAGUAAAAAAAACACUGCUUGUGACGGUUGUUGGUAAAGAGGAUCGAACCUGGAAAAUGAUGGUUUGGUCCCCUUCAACCAGCUACCGAUGCAACGCACG		72
20794	MI0007196	csa-mir-141	Ciona savignyi miR-141 stem-loop	UUGGUCGUCGGUCGCAUCUUCAUCACGCGGUGUUCUAGAACUCAUUCUAACACUGUCUGGUAAAGAUGCGAUCGGCGGCUACUU		72
20795	MI0007197	csa-mir-153	Ciona savignyi miR-153 stem-loop	GGAAAACAUUGUCUUUACUGUUCACGAGUGUCAUUUUAAUACUAUGCAGCUUUGAAUAAUGUUAGUUGCAUAGUAAUAAAAGUGAUCAUGCGUUUACAAGAA		72
20796	MI0007198	csa-mir-155	Ciona savignyi miR-155 stem-loop	UAGCUAAUUGUACUACUCUUACUGACGUGUCACAUAAUUAACAGCAAUUACGGGACGGAUCACUGAGCUGUAGUGAUACAGAAAGUCAGCGCAUCUGUAAUUAAUGCUAAUAAGUGAUUUAUGGUUUCGUUCUACAAA		72
20797	MI0007199	csa-mir-183	Ciona savignyi miR-183 stem-loop	ACAGUGUUGACGAAAUAUGGCACUAGUAGAAAUCACUGUAGCCAACACCCAGUGGUUUCACAGGUGCCAUAAAUUGGAAACACUACUUUCUACAGCGAUAACA		72
20798	MI0007200	csa-mir-200	Ciona savignyi miR-200 stem-loop	GGUCACUGAAGCAUCAACCCGGUAGUACGAUAUGUGAGCUGUAUAAUACUGCCUGGUAAUGAUGAUUCAGUGGCGUCGCG		72
20799	MI0007201	csa-mir-216a	Ciona savignyi miR-216a stem-loop	UGUCCCGGCUCAUUCUAAUCUCAGCUGGCAAUCUGUGAUUGGCUGAAAAUCACAGAUGCAGAUGGGAUUCUGAUGAGUCGGGA		72
20800	MI0007202	csa-mir-216b	Ciona savignyi miR-216b stem-loop	GUGACGCUUGUCGUCUAAUCUCUGCAGGCAACUGUGAUGUCAUAGUCACAUAUGUGUGCAGAGGUUGGAUGAAAUGUAGUC		72
20801	MI0007203	csa-mir-217	Ciona savignyi miR-217 stem-loop	GAAAGUGGGGCGAGAUACUGCAUUAGGAACUGAUUGGUUGUUAAUUUCACUCAGUUUCAGGUGCAUUAAAUUGCUACACUAUAUGUCAUCCACCAGUAUGAG		72
20802	MI0007204	csa-mir-219	Ciona savignyi miR-219 stem-loop	AUGGCGACUGUUUCAUGAUUGUCCAAACGCAAUACAGGUGUUACAAUAAAUUCUGUGUUUUCGUAUGGACAUCGUAAUACAGAGUGUCACAUGCUUCAUCAA		72
20803	MI0007205	csa-mir-281	Ciona savignyi miR-281 stem-loop	AAUUCGUUUAUUUUACAUGUCAAGUGCGUGUCGGAGGGUUAUUUCAUGCCGGUCUAGCAUUGCGCUGUCAUGGAGUUGCUCUCUCAUUGGCGCUAUGGCUUA		72
20804	MI0007263	mdo-mir-1540	Monodelphis domestica miR-1540 stem-loop	UAGCGGGGGUGAUUCCAUAGAGCGCAUGUCCAUCCCCAGAGAGCCAGAGCAUAUGCUCCAUGGAAUCACCCCCACCA	This sequence is referred to by the unofficial identifier Mdo-10 in [1]. 	49
20805	MI0007264	mdo-mir-1541	Monodelphis domestica miR-1541 stem-loop	AUGGAGCAGAUGGUGUGCUCGUUUGGAUGUGGCAGUUUGCGAGGGAUGGGCAUCCCAUGAUCCUCCAG	This sequence is referred to by the unofficial identifier Mdo-27 in [1]. 	49
20806	MI0007265	mdo-mir-1542-1	Monodelphis domestica miR-1542-1 stem-loop	CCGGUGCCUGGCACAUAGGAGUUUCAUAAAUGUAUUUUCAUUAAUUUAUUGAUCUCCAAUGCCUAGCACAGU	This sequence is referred to by the unofficial identifier Mdo-172a in [1]. 	49
20807	MI0007266	mdo-mir-1542-2	Monodelphis domestica miR-1542-2 stem-loop	UAGUACAGUGCCUGGCACAUAGGAGCUUCAUAAAUGUGUGUUGAUUUAUUUAUUGAUCUCCAAUGCCUAGCACUGUGCCU	This sequence is referred to by the unofficial identifier Mdo-172b in [1]. 	49
20808	MI0007267	mdo-mir-1543	Monodelphis domestica miR-1543 stem-loop	GAUAGUGCUUUGCACCACUGAGAGUGGAUUAACUUCCUUUAUGAAGUUAGUCCUAGUCUAGGUGCACACAUGUC	This sequence is referred to by the unofficial identifier Mdo-174 in [1]. 	49
20809	MI0007268	mdo-mir-340	Monodelphis domestica miR-340 stem-loop	UGGACGGUGAUCAAGGUGUGACUAUAAAGUAAUGAGAUUGAUUUCUGUGGUAUAGUAAAUGGAAAUCAGUUUCAUUACCUUACAGUCACAUCUAAUCUUCU	This sequence is referred to by the unofficial identifier Mdo-182 in [1]. 	49
20810	MI0007269	mdo-mir-1544	Monodelphis domestica miR-1544 stem-loop	AGCAGCUGCCCCUGCACCCAGGGAUAGGAUAGCGGUUCACUUGGAAGCCCCCUUUUCUAUCCCUGGUACUGGCGCCGCUGCU	This sequence is referred to by the unofficial identifier Mdo-202a in [1]. 	49
20811	MI0007270	mdo-mir-1545	Monodelphis domestica miR-1545 stem-loop	CCGGACACAGUGCGCAGGGAUAGAUAAGAGGUCACUUUAGAAUCCACUUUCCAUCCCUUGCACUGUUUCCGC	This sequence is referred to by the unofficial identifier Mdo-253a in [1]. 	49
20812	MI0007271	mdo-mir-1546	Monodelphis domestica miR-1546 stem-loop	AUGCCUUGCCGGAAAUCAGGGAUUCUCAGGGAUGGAAGUGAGACAAAAUACCUUCCACCUCUCAGAAUCCCUAUUUUCUUUCAAGGCCC	This sequence is referred to by the unofficial identifier Mdo-254 in [1]. 	49
20813	MI0007272	mdo-mir-1547	Monodelphis domestica miR-1547 stem-loop	UAAAGAACGUAUGAUGUAUCAGAGUCUUGGGUCCUUGUGUAGAUGCUUUGAGACUUCAAGGAUCCCUGACUUGAUCAUUGUGGGUUCUCCC	This sequence is referred to by the unofficial identifier Mdo-302 in [1]. 	49
20814	MI0007273	mdo-mir-1548	Monodelphis domestica miR-1548 stem-loop	GAGGAGGGCUCACGCGGGCACGCACGCGGGCUGGUGUGCAUCCUGCAGCGGGCUCCCCUU	This sequence is referred to by the unofficial identifier Mdo-305 in [1]. 	49
20815	MI0007274	mdo-mir-1549	Monodelphis domestica miR-1549 stem-loop	CUCGCCGGGCUCGUAGGUAGAAGCUGAGUUUUGUUUUGCUUCCGCCCUGCAAGCCCGGUAGCU	This sequence is referred to by the unofficial identifier Mdo-315 in [1]. 	49
20816	MI0007568	mml-mir-1-1	Macaca mulatta miR-1-1 stem-loop	GCUUGGGAAACAUACUUCUUUAUAUGCCCAUAUGGACCUGCUAAGCUAUGGAAUGUAAAGAAGUAUGUAUCUCAGGC		32
20817	MI0007569	mml-mir-1-2	Macaca mulatta miR-1-2 stem-loop	ACCUACUCAGAGUACAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUAUUUUUGGUAGGC		32
20818	MI0007570	mml-let-7a-1	Macaca mulatta let-7a-1 stem-loop	UGGGAUGAGGUAGUAGGUUGUAUAGUUUUAGGGUCACACCCACCACUGGGAGAUAACUAUACAAUCUACUGUCUUUCCUA		32
20819	MI0007571	mml-let-7a-2	Macaca mulatta let-7a-2 stem-loop	AGGCUGAGGUAGUAGGUUGUAUAGUUUAGAAUUACAUCAAGGGAGAUAACUGUACAGCCUCCUAGCUUUCCU		32
20820	MI0007572	mml-let-7a-3	Macaca mulatta let-7a-3 stem-loop	GGGUGAGGUAGUAGGUUGUAUAGUUUGGGGCUCUGCCCUGCUAUGGGAUAACUAUACAAUCUACUGUCUUUCCU		32
20821	MI0007573	mml-let-7b	Macaca mulatta let-7b stem-loop	CGGGGUGAGGUAGUAGGUUGUGUGGUUUCAGGGCAGUGAUGUUGCCCCUCAGAAGAUAACUAUACAACCUACUGCCUUCCCUG		32
20822	MI0007574	mml-let-7c	Macaca mulatta let-7c stem-loop	GCAUCCGGGUUGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCCUUGGAGC		32
20823	MI0007575	mml-let-7d	Macaca mulatta let-7d stem-loop	CCUAGGAAGAGGUAGUAGGUUGCAUAGUUUUAGGGCAGGGAUUUUGCCCACAAGGAGGUAACUAUACGACCUGCUGCCUUUCUUAGG		32
20824	MI0007576	mml-let-7e	Macaca mulatta let-7e stem-loop	CCCGGGCUGAGGUAGGAGGUUGUAUAGUUGAGGAGGACACCCAAGGAGAUCACUAUACGGCCUCCUAGCUUUCCCCAGG		32
20825	MI0007577	mml-let-7f-1	Macaca mulatta let-7f-1 stem-loop	UCAGAGUGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCCUGA		32
20826	MI0007578	mml-let-7f-2	Macaca mulatta let-7f-2 stem-loop	UGUGGGAUGAGGUAGUAGAUUGUAUAGUUUUAGGGUCAUACCCCAUCUUGGAGAUAACUAUACAGUCUACUGUCUUUCCCACG		32
20827	MI0007579	mml-let-7g	Macaca mulatta let-7g stem-loop	AGGCUGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCCA		32
20828	MI0007580	mml-let-7i	Macaca mulatta let-7i stem-loop	CUGGCUGAGGUAGUAGUUUGUGCUGUUGGUCGGGUUGUGACAUUGCCCGCUGUGGAGAUAACUGCGCAAGCUACUGCCUUGCUAG		32
20829	MI0007581	mml-mir-7-1	Macaca mulatta miR-7-1 stem-loop	UUGGAUGUUGGCCUAGUUCUGUGUGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUUGACAACAAAUCACAGUCUGCCAUAUGGCACAGGCCAUGCCUCUACAG		32
20830	MI0007582	mml-mir-7-2	Macaca mulatta miR-7-2 stem-loop	CUGGAUACAGAGUGAAGUGGCUGGCCCCGUCUGGAAGACUAGUGAUUUUGUUGUUGUCUUACUGCGCUCAACAACAAAUCCCAGUCUGCCGAAUGGUGCCAGCCAUUGCA		32
20831	MI0007583	mml-mir-7-3	Macaca mulatta miR-7-3 stem-loop	AGAUUAGAGUGGCUAUGGUCUAGUGCUGUGUGGAAGACUAGUGAUUUUGUUGUUCUGAUGUGCUACGACAACAAAUCACAGCCGGCCUCAUAGCGCAGACUCCCUUCGAC		32
20832	MI0007584	mml-mir-9-1	Macaca mulatta miR-9-1 stem-loop	CGGGGUUGGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAAUAACCCCA		32
20833	MI0007585	mml-mir-9-2	Macaca mulatta miR-9-2 stem-loop	GGAAGCGAGUUGUUAUCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUAAAAACUCCUUCA		32
20834	MI0007586	mml-mir-9-3	Macaca mulatta miR-9-3 stem-loop	GGAGGCCCGUUUCUCUCUUUGGUUAUCUAGCUGUAUGAGUGCCACAGAGCCGCUCUCAAGCUAGAUAACCGAAAGUAGAAAUGACUCUCA		32
20835	MI0007587	mml-mir-10a	Macaca mulatta miR-10a stem-loop	GAUCUGUCUGUCUUCUGUAUAUACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUAUGUAGUUGACAUAAACACUCCGCUC		32
20836	MI0007588	mml-mir-10b	Macaca mulatta miR-10b stem-loop	CCAGAGGUUGUAACGUUGUCUAUAUAUACCCUGUAGAACCGAAUUUGUGUGGUAUCCAUAUAGUCACAGAUUCGAUUCUAGGGGAAUAUAUGGUCGAUGCAAAAACUUCA		32
20837	MI0007589	mml-mir-16-2	Macaca mulatta miR-16-2 stem-loop	GUUCCACUCUAGCAGCACGUAAAUAUUGGCGUAGUGAAAUAUGUAUUAAACACCAAUAUUACUGUGCUGCUUCAGUGUGAC		32
20838	MI0007590	mml-mir-18b	Macaca mulatta miR-18b stem-loop	UGUGUUAAGGUGCAUCUAGUGCAGUUAGUGAAGCAGCUUAGAAUCUACUGCCCUAAAUGCCCCUUCUGGCA		32
20839	MI0007591	mml-mir-20b	Macaca mulatta miR-20b stem-loop	AGUACCAAAGUGCUCAUAGUGCAGGUAGUUUUGGCAUGACUCUACUGUAGUGUGGGCACUUCCAGUACU		32
20840	MI0007592	mml-mir-23b	Macaca mulatta miR-23b stem-loop	CUCAGGUGCUCUGGCUGCUUGGGUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUACCACGCAACCACGACCUUGGC		32
20841	MI0007593	mml-mir-26a-2	Macaca mulatta miR-26a-2 stem-loop	GGCUGUGGCUGGAUUCAAGUAAUCCAGGAUAGGCUGUUUCCAUCUGUGAGGCCUAUUCUUGAUUACUUGUUUCUGGAGGCAGCU		32
20842	MI0007594	mml-mir-26b	Macaca mulatta miR-26b stem-loop	CCGGGACCCAGUUCAAGUAAUUCAGGAUAGGUUGUGUGCUGUCCAGCCUGUUCUCCAUUACUUGGCUCGGGGACCGG		32
20843	MI0007595	mml-mir-27b	Macaca mulatta miR-27b stem-loop	ACCUCUCUAACAAGGUGCAGAGCUUAGCUGAUUGGUGAACAGUGAUUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGCACCUGAAGAGAAGGUG		32
20844	MI0007596	mml-mir-29b-1	Macaca mulatta miR-29b-1 stem-loop	CUUCAGGAAGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUUCUUGGGGG		32
20845	MI0007597	mml-mir-29b-2	Macaca mulatta miR-29b-2 stem-loop	CUUCUGGAAGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUUUUAGGAG		32
20846	MI0007598	mml-mir-29c	Macaca mulatta miR-29c stem-loop	AUCUCUUACACAGGCUGACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUAUGAUGUAGGGGGA		32
20847	MI0007599	mml-mir-30c-1	Macaca mulatta miR-30c-1 stem-loop	ACCAUGCUGUAGUGUGUGUAAACAUCCUACACUCUCAGCUGUGAGCUCAAGGUGGCUGGGAGAGGGUUGUUUACUCCUUCUGCCAUGGA		32
20848	MI0007600	mml-mir-30c-2	Macaca mulatta miR-30c-2 stem-loop	AGAUACUGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCUCUCU		32
20849	MI0007601	mml-mir-30d	Macaca mulatta miR-30d stem-loop	UUGUUGUAAACAUCCCCGACUGGAAGCUGUAAGACACAGCUAAGCUUUCAGUCAGAUGUUUGCUGCUAC		32
20850	MI0007602	mml-mir-30e	Macaca mulatta miR-30e stem-loop	GGGCAGUCUUCGCUACUGUAAACAUCCUUGACUGGAAGCUGUAAGGUGUUCAGAGGAGCUUUCAGUCGGAUGUUUACAGCGGCAGGCUGCCA		32
20851	MI0007603	mml-mir-33b	Macaca mulatta miR-33b stem-loop	GCGGGCGGCCCCGCGGUGCAUUGCUGUUGCAUUGCACGUGUGUGAGGCGGGUGCAGUGCCUCGGCAGUGCAGCCCGGAGCCGGCCCCUGGCACCGC		32
20852	MI0007604	mml-mir-34b	Macaca mulatta miR-34b stem-loop	GUGCUCGGUUUGUAGGCAGUGUCAUUAGCUGAUUGUACUGUGGUGGUUACAAUCACUAACUCCACUGCCAUCAAAACAAGGCAC		32
20853	MI0007605	mml-mir-34c	Macaca mulatta miR-34c stem-loop	AGUCUAGUUACCAGGCAGUGUAGUUAGCUGAUUGCUGAUAGUACCAAUCACUAACCACACGGCCAGGUAAAAAGAUU		32
20854	MI0007606	mml-mir-92a-2	Macaca mulatta miR-92a-2 stem-loop	UCAUCCCUGGGUGGGGAUUUGUUGCAUUACUUGUGUUCUAUAUAAAGUAUUGCACUUGUCCCGGCCUGUGGAAGA		32
20855	MI0007607	mml-mir-92b	Macaca mulatta miR-92b stem-loop	CGGGCCCCGGGCGGGCGGGAGGGACGGGACGCGGUGCAGUGUUGUUCUUUCCCCCGCCAAUAUUGCACUCGUCCCGGCCUCCGGCCCCCCCGGCCC		32
20856	MI0007608	mml-mir-95	Macaca mulatta miR-95 stem-loop	AACACAGUGGGCACUCAAUAAAUGUCUGUUGAAUUGAAAUGCGUUACAUUCAACGGGUAUUUAUUGAGCACCCACUCUGUG		32
20857	MI0007609	mml-mir-99b	Macaca mulatta miR-99b stem-loop	GGCACCCACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGUGUCUGUGGGUCCGUGUC		32
20858	MI0007610	mml-mir-101-2	Macaca mulatta miR-101-2 stem-loop	ACUGUCCUUUUUCGGUUAUCAUGGUACCGAUGCUGUAUAUCUGAAAGGUACAGUACUGUGAUAACUGAAGAAUGGUGGU		32
20859	MI0007611	mml-mir-103-2	Macaca mulatta miR-103-2 stem-loop	UUGUGCUUUCAGCUUCUUUACAGUGCUGCCUUGUAGCAUUCAGGUCAAGCAGCAUUGUACAGGGCUAUGAAAGAACCA		32
20860	MI0007612	mml-mir-105-2	Macaca mulatta miR-105-2 stem-loop	UGUGCAUCGUGGUCAAAUGCUCAGACUCCUGUGGUGGCUGCUUAUGCACCACGGAUGUUUGAGCAUGUGCUAUGGUGUCUA		32
20861	MI0007613	mml-mir-122a	Macaca mulatta miR-122a stem-loop	CCUUAGCAGAGCUGUGGAGUGUGACAAUGGUGUUUGUGUCUAAACUAUCAAACGCCAUUAUCACACUAAAUAGCUACUACUAGGC		32
20862	MI0007614	mml-mir-124a-2	Macaca mulatta miR-124a-2 stem-loop	AGGCCUCUCUCUCCGUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCAAGAAUGGGGCUG		32
20863	MI0007615	mml-mir-125a	Macaca mulatta miR-125a stem-loop	UGCCAGUCUCUGGGUCCCUGAGACCCUUUAACCUGUGAGGACAUCCAGGGUCACAGGUGAGGUUCUUGGGAGCCUGGCGUCUGGCC		32
20864	MI0007616	mml-mir-126	Macaca mulatta miR-126 stem-loop	CGCUGGUGAUGGGACAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCGCUGUCCACAGCA		32
20865	MI0007617	mml-mir-128b	Macaca mulatta miR-128b stem-loop	UGUGCAGUGGGAAGGGGGGCCGAUACACUGUACGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUUCCCUACUGUGUC		32
20866	MI0007618	mml-mir-129	Macaca mulatta miR-129 stem-loop	GGAUCUUUUUGCGGUCUGGGCUUGCUGUUCCUCUCAACAGUAGUCAGGAAGCCCUUACCCCAAAAAGUAUCU		32
20867	MI0007619	mml-mir-130b	Macaca mulatta miR-130b stem-loop	GGCCUGCCCGACACUCUUUCCCUGUUGCACUACUGUGGGCCACUGGGAAGCAGUGCAAUGAUGAAAGGGCAUCGGUCAGGUC		32
20868	MI0007620	mml-mir-132	Macaca mulatta miR-132 stem-loop	CCGCCCCCGCGUCUCCAGGGCAACCGUGGCUUUCGAUUGUUACUGUGGGAACUGGAGGUAACAGUCUACAGCCAUGGUCGCCCCGCAGCACGCCCACGCGC		32
20869	MI0007621	mml-mir-133c	Macaca mulatta miR-133c stem-loop	GGGAGCCAAAUGCUUUGCUAGAGCUGGUAAAAUGGAACCAAAUCGACUGUCCAAUGGAUUUGGUCCCCUUCAACCAGCUGUAGCUGUGCAUUGAUGGCGCCG		32
20870	MI0007622	mml-mir-133b	Macaca mulatta miR-133b stem-loop	CCUCAGAAGAAAGAUGCCCCCUGCUCUGGCUGGUCAAACGGAACCAAGUCCGUCUUCCUGAGAGGUUUGGUCCCCUUCAACCAGCUACAGCAGGGCUGGCAAUUCCCAGUCCUUGGAGA		32
20871	MI0007623	mml-mir-134	Macaca mulatta miR-134 stem-loop	CAGGGUGUGUGACUGGUUGACCAGAGGGGCGUGCACUGUGUUCACCCUGUGGGCCACCUAGUCACCAACCCUC		32
20872	MI0007624	mml-mir-135a-1	Macaca mulatta miR-135a-1 stem-loop	AGGCCUCGCUGUUCUCUAUGGCUUUUUAUUCCUAUGUGAUUCUACUGCUCACUCAUAUAGGGAUUGGAGCCGUGGCGCACGGCGGGGACA		32
20873	MI0007625	mml-mir-135b	Macaca mulatta miR-135b stem-loop	CACUCUGCUGUGGCCUAUGGCUUUUCAUUCCUAUGUGAUUGCUGUCCCAAACUCAUGUAGGGCUAAAAGCCAUGGGCUACAGUGAGGGGCGAGCUCC		32
20874	MI0007626	mml-mir-136	Macaca mulatta miR-136 stem-loop	UUGGAUGAGCCCUCGGAGGACUCCAUUUGUUUUGAUGAUGGAUUCUUAUGCUCCAUCAUCGUCUCAAAUGAGUCUUCAGAGGGUUCUAUCAU		32
20875	MI0007627	mml-mir-137	Macaca mulatta miR-137 stem-loop	GGUCCUCUGACUCUCUUCGGUGACGGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGUAGUCGAGGAGAGUACCAGCGGCA		32
20876	MI0007628	mml-mir-138	Macaca mulatta miR-138 stem-loop	CGUUGCUGCAGCUGGUGUUGUGAAUCAGGCCGACGAGCAGCGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUUGCAUCA		32
20877	MI0007629	mml-mir-139	Macaca mulatta miR-139 stem-loop	GUGUAUUCUACAGUGCACGUGUCUCCAGUGUGGCUCGGAGGCUGGAGACGCGGCCCUGUUGGAGUAAC		32
20878	MI0007630	mml-mir-140	Macaca mulatta miR-140 stem-loop	UGUGUCUCUCUCUGUGUCCUGCCAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGACAGGAUACCGGGGCACC		32
20879	MI0007631	mml-mir-142	Macaca mulatta miR-142 stem-loop	GACAGUGCAGUCACCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUGAGUGUACUGUG		32
20880	MI0007632	mml-mir-143	Macaca mulatta miR-143 stem-loop	GCGCAGCGCCGUGUCUCCCAGCCUGAGGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUCAGGAAGAGAGAAGUUGUUCUGCAGC		32
20881	MI0007633	mml-mir-144	Macaca mulatta miR-144 stem-loop	UGGGGCCCUGGCUGGGAUAUCAUCAUAUACUGUAAGUUUGUGAUGAGACACUACAGUAUAGAUGAUGUACUAGUCCGGGCACCCCC		32
20882	MI0007634	mml-mir-146a	Macaca mulatta miR-146a stem-loop	CCUAUGUGUAUCCUCAGCUUUGAGAACUGAAUUCCAUGGGUUGUGUCAGUGUCAGACCUGUGAAAUUCAGUUCUUCAGCUGGGAUAUCUCUGUCGUCGU		32
20883	MI0007635	mml-mir-146b	Macaca mulatta miR-146b stem-loop	CCUGGCACUGAGAACUGAAUUCCAUAGGCUGUGAGCUCUAGCAAUGCCCUGUGGACUCAGUUCUGGUGCCCGG		32
20884	MI0007636	mml-mir-147a	Macaca mulatta miR-147a stem-loop	AAUCUAAAGAAAACAUUUCUGCACACACACCAGACUAUUGAAGCCAGUGUGUGGAAAUGCUUCUGCUACAUU		32
20885	MI0007637	mml-mir-147b	Macaca mulatta miR-147b stem-loop	UAUAAAUCUAGUGGAAACAUUUCCGCACAAACUAGAUUCUGGACACCAGUGUGCGGAAGUGCUUCUGCUGCAUUUUUAGG		32
20886	MI0007638	mml-mir-148a	Macaca mulatta miR-148a stem-loop	GAGGCAAAGUUCUGAGACACUCCGACUCUGAGUAUGAUAGAAGUCAGUGCACUACAGAACUUUGUCUC		32
20887	MI0007639	mml-mir-148b	Macaca mulatta miR-148b stem-loop	CAAGCACGAUUAGCAUUUGAGGUGAAGUUCUGUUAUACACUCAGGCUGUGGCUCUCUGAAAGUCAGUGCAUCACAGAACUUUGUCUCGAAAGCUUUCUA		32
20888	MI0007640	mml-mir-149	Macaca mulatta miR-149 stem-loop	GCCGGCGCCCAAGCUCUGGCUCCGUGUCUUCACUCCCGUGUUUGUCCGAGGAGGGAGGGAGGGACGGGGGCUGUGCUGGGGCAGCCGGA		32
20889	MI0007641	mml-mir-150	Macaca mulatta miR-150 stem-loop	CUCCCCAUGGCCCUGUCUCCCAACCCUUGUACCAGUGCUGGGCUCAGACCCUGGUACAGGCCUGGGGGACAGGGACCUGGGGAC		32
20890	MI0007642	mml-mir-151	Macaca mulatta miR-151 stem-loop	UUUCCUGCCCUCGAGGAGCUCACAGUCUAGUAUGUCUCAUCCCCUACUAGACUGAAGCUCCUUGAGGACAGGGAUGGUCAUACUCACCUC		32
20891	MI0007643	mml-mir-152	Macaca mulatta miR-152 stem-loop	UGUCCCCCCCGGCCCAGGUUCUGUGAUACACUCCGACUCGGGCUCUGGAGCAGUCAGUGCAUGACAGAACUUGGGCCCGGAAGGACC		32
20892	MI0007644	mml-mir-154	Macaca mulatta miR-154 stem-loop	GAGGUACUUGAAGAUAGGUUAUCCGUGUUGCCUUCGCUUUAUUUGUGACGAAUCAUACACGGUUGACCUAUUUUUCAGUACCAA		32
20893	MI0007645	mml-mir-155	Macaca mulatta miR-155 stem-loop	CUGUUAAUGCUAAUCGUGAUAGGGGUUUUUACCUCCAACUGACUCCUACAUGUUAGCAUUAACAG		32
20894	MI0007646	mml-mir-181b-2	Macaca mulatta miR-181b-2 stem-loop	CUGAUGGCUGCACUCAACAUUCAUUGCUGUCGGUGGGUUUGAGUCUGAAUCAACUCACUGAUCGAUGAAUGCAAACUGCGGACCAAACA		32
20895	MI0007647	mml-mir-181d	Macaca mulatta miR-181d stem-loop	GUCCCCUCCCCUAGGCCACAGCCAAGGUCACAAUCAACAUUCAUUGUUGUCGGUGGGUUGUGAGGACCGAGGCCAGACCCACCGGGGGAUGAAUGUCACUGUGGCUGGGCCAGACACGGCUUAAGGGGAAUGGGGAC		32
20896	MI0007648	mml-mir-184	Macaca mulatta miR-184 stem-loop	UCAGUCACGUCCCCUUAUCACUUUUCCAGCCCAGCUUUAUGACUGUAAGUGUUGGACGGAGAACUGAUAAGGGUAGGUGAUUGA		32
20897	MI0007649	mml-mir-185	Macaca mulatta miR-185 stem-loop	AGGGCGCGAGGGAUUGGAGAGAAAGGCAGUUCCUGAUGGUCCCCUCCUCAGGGGCUGGCUUUCCUCUGGUCCUUCCCUCCCA		32
20898	MI0007650	mml-mir-186	Macaca mulatta miR-186 stem-loop	UGCUUGUAACUUUCCAAAGAAUUCUCCUUUUGGGCUUUCUGGUUUUAUUUUAAGCCCAAAGGUGAAUUUCUUGGGAAGUUUGAGCU		32
20899	MI0007651	mml-mir-187	Macaca mulatta miR-187 stem-loop	GGUCAGGCUCACUAUGACACAGUGUGAGACCUCGGGCUACAACACAGGACCCGGGUGCUGCUCUGACCCCUCGUGUCUUGUGUUGCAGCCGGAGGGACGCAGGUCCGCA		32
20900	MI0007652	mml-mir-190b	Macaca mulatta miR-190b stem-loop	UGCUUCUGUGUGAUAUGUUUGAUAUUGGGUUGUUUAAUUAGGAACCAACUAAAUGUCAAACAUAUUCUUACAGCAGCUG		32
20901	MI0007653	mml-mir-191	Macaca mulatta miR-191 stem-loop	CGGCUGGACAGCGGGCAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCGCUUGGAUUUCGUCCCCUGCUCUCCUGCCU		32
20902	MI0007654	mml-mir-192	Macaca mulatta miR-192 stem-loop	GCUGAGACCGAGUGCACAGGGCUCUGACCUAUGAAUUGACAGCCAGUGCUCUCGUCUCCCCUCUGGCUGCCAAUUCCAUAGGUCACAGGUAUGUUCGCCUCAAUGCCAGC		32
20903	MI0007655	mml-mir-193a	Macaca mulatta miR-193a stem-loop	GGAUGGGAGCUGAGGGCUGGGUCUUUGCGGGCGAGAUGAGGGUGUCGGAUCAACUGGCCUACAAAGUCCCAGUCCUCGGCCCCCG		32
20904	MI0007656	mml-mir-193b	Macaca mulatta miR-193b stem-loop	GUGGUCUCAGAAUCGGGGUUUUGAGGGCGAGAUGAGUUUAUGUUUUAUCCAACUGGCCCUCAAAGUCCCGCUUUUGGGGUCAU		32
20905	MI0007657	mml-mir-194-2	Macaca mulatta miR-194-2 stem-loop	UGGCUCCCGCCCCCUGUAACAGCAACUCCAUGUGGAAGUGUCCACUGAUUCCAGUGGGGCUGCUGUUAUCUGGGGCGAGGGCCGG		32
20906	MI0007658	mml-mir-195	Macaca mulatta miR-195 stem-loop	AGCUUCCCUGGCUCUAGCAGCACAGAAAUAUUGGCACAGGGAAGCAAGUCUGCCAAUAUUGGCUGUGCUGCUCCAGGCAGGGUGGUG		32
20907	MI0007659	mml-mir-196a-2	Macaca mulatta miR-196a-2 stem-loop	UGCUCGCUCAGCUGAUCUGUGGCUUAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAGUUACAUCAGUCGGUUUUCGUCGAGGGC		32
20908	MI0007660	mml-mir-196b	Macaca mulatta miR-196b stem-loop	ACUGGUCGGUGAUUUAGGUAGUUUCCUGUUGUUGGGAUCCACCUUUCUCUCGACAGCACGACACUGCCUUCAUUA		32
20909	MI0007661	mml-mir-197	Macaca mulatta miR-197 stem-loop	GGCUGUGCCGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGCAUGGCC		32
20910	MI0007662	mml-mir-199a-2	Macaca mulatta miR-199a-2 stem-loop	GCCAACCCAGUGUUCAGACUACCUGUUCAGGAGGCUCUCAACGUGUACAGUAGUCUGCACAUUGGUUAGGC		32
20911	MI0007663	mml-mir-200a	Macaca mulatta miR-200a stem-loop	CCGGGCCCCUGUGAGCAUCUUACCGGACAGUGCUGGAUUUCCCAGCUUGACUCUAACACUGUCUGGUAACGAUGUUCAAAGGUGACCCAC		32
20912	MI0007664	mml-mir-203	Macaca mulatta miR-203 stem-loop	GUGCUGGGGACUCGCGCGCUGGGUCCAGUGGUUCUUAACAGUUCAACAGUUCUGUAGCGCAAUUGUGAAAUGUUUAGGACCACUAGACCCGGCGGGCACGGCGACAGCGA		32
20913	MI0007665	mml-mir-204	Macaca mulatta miR-204 stem-loop	GGCUACAGUCUUUCUUCAUGUGACUCGUGGACUUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGUUCAAUUGUCAUCACUGGC		32
20914	MI0007666	mml-mir-205	Macaca mulatta miR-205 stem-loop	AAAGAUCCUCAGGCAAUCCAUGUGCUUCUCUUGUCCUUCAUUCCACCGGAGUCUGUCUCAUACCCAACCAGAUUUCAGUGGAGUGAAGUUCAGGAGGCAUGGAGCUGACG		32
20915	MI0007667	mml-mir-206	Macaca mulatta miR-206 stem-loop	UGCUUCCCGAGGCCACAUGCUUCUUUAUAUCCCCAUAUGGAUUACUUUGCUAUGGAAUGUAAGGAAGUGUGUGGUUUCGGCAAGUG		32
20916	MI0007668	mml-mir-208a	Macaca mulatta miR-208a stem-loop	UGACAGGCGAGCUUUUGGCCCGGGUUAUACCUGAUGCUCACGUAUAAGACGAGCAAAAAGCUUGUUGGUCA		32
20917	MI0007669	mml-mir-208b	Macaca mulatta miR-208b stem-loop	CCUCUCAGGGAAGCUUUUUGCUCGAAUUAUGUUUCUGAUCCGAAUAUAAGACGAACAAAAGGUUUGUCUGAGGGCAG		32
20918	MI0007670	mml-mir-210	Macaca mulatta miR-210 stem-loop	ACCCGGCAGUCCCUCCAGGCGCAGGGCAGCCCCUGCCCACCGCACACUGCGCUGCCCCAGACCCACUGUGCGUGUGACAGCGGCUGAUCUGUGCCUGGGCAGCGCGACCC		32
20919	MI0007671	mml-mir-212	Macaca mulatta miR-212 stem-loop	CGGGGCACCCCGCCCGGACAGCGCGCCGGCACCUUGGCUCUAGACUGCUUACUGCCCGGGCCGCCCUCAGUAACAGUCUCCAGUCAGGGCCACCGACGCCUGGCCCCGCC		32
20920	MI0007672	mml-mir-216a	Macaca mulatta miR-216a stem-loop	GAUGGCUGUGAGUUGGCUUAAUCUCAGCUGGCAACUGUGAGAUGUUCAUACAAUCCCUCACAGUGGUCUCUGGGAUUACGCUAAACAGAGCAAUUUCCUUGCCCUCGCGA		32
20921	MI0007673	mml-mir-216b	Macaca mulatta miR-216b stem-loop	GCAGACUGGAAAAUCUCUGCAGGCAAAUGUGAUGUCACUGAAGAAAUCACACACUUACCCGUAGAGAUUCUACAGUCUGACA		32
20922	MI0007674	mml-mir-217	Macaca mulatta miR-217 stem-loop	AAUAUAAUUAUUACAUAGUUUUUGAUGUCGCAGAUUCUGCAUCAGGAACUGAUUGGAUAAGAAUCAGUCACCAUCAGUUCCUAAUGCAUUGCCUUCAGCAUCUAAACAAG		32
20923	MI0007675	mml-mir-218-1	Macaca mulatta miR-218-1 stem-loop	AAUGUAGCGAGAUUUUCUGUUGUGCUUGAUCUAACCAUGUGGUUGCGAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUGGAACGUCACGCAGCUUUCUACA		32
20924	MI0007676	mml-mir-219-2	Macaca mulatta miR-219-2 stem-loop	ACUCAGGGGCUUCGCCACUGAUUGUCCAAACGCAAUUCUUGUACGAGUCUGCGGCCAACCGAGAAUUGUGGCUGGACAUCUGUGGCUGAGCUCCGGG		32
20925	MI0007677	mml-mir-220b	Macaca mulatta miR-220b stem-loop	GACAGCGUGGCGUUGUAGGGCUCCACCACCGUGUCCGACACCUUGGGCGAGGGCAUGACGCUGAAGGUGUUCAUGAUGCGGUCCGGGAACUCCUCGCGGAUCUUGCUGAUG		32
20926	MI0007678	mml-mir-220c	Macaca mulatta miR-220c stem-loop	GACAGCGUGGCAUUGUAGGGCUCCACCACUGUGUCUGACACCUUGGGCGAGGGCACGACGCUGAAGGUGUUCAUGAUGCGGUCCGGAUACUCCUCACG		32
20927	MI0007679	mml-mir-220d	Macaca mulatta miR-220d stem-loop	GUGGCGUUGUAGGGCUCCACCACCGUGUCUGACACCUUGGGUGAGGGCAUGACGCUGAAGGUGUUCAUGAUGCGGUCUGGGUACUCUUCCCGGAUCUUGCUGAUG		32
20928	MI0007680	mml-mir-222	Macaca mulatta miR-222 stem-loop	GCUGCUGGAAGGUAUAGGUACCCUCAAUGGCUCAGUAGCCAGUGUAGAUCCUGUCUUUCGUAAUCAGCAGCUACAUCUGGCUACUGGGUCUCUGAUGGCAUCUUCUAGCU		32
20929	MI0007681	mml-mir-296	Macaca mulatta miR-296 stem-loop	AGGACCCUUCCAGAGGGCCCCCCCUCAAUCCUGUUGUGCCUAAUUCAGAGGGUUGGGUGGAGGCUCUCCUGAAGGGCUCU		32
20930	MI0007682	mml-mir-297	Macaca mulatta miR-297 stem-loop	UGUAUGUAUGUGUGCAUGUGCAUAUAUGUGUGUGUAUAUAUAUAUAUGUAUUAUGUACUCAUAUAUCA		32
20931	MI0007683	mml-mir-298	Macaca mulatta miR-298 stem-loop	UCAGGUCUUCAGCAGAAGCCGGGUGGUUCUCCCAGUGGUUUUCCUUGACUGUGAGGAACUAGCCUGCUGUUUUGCUCAGGAAUGAGCU		32
20932	MI0007684	mml-mir-299	Macaca mulatta miR-299 stem-loop	AAGAAAUGGUUUACCGUCCCACAUACAUUUUCAAUAUGUAUGUGGGACGGUAAACCGCUUCUU		32
20933	MI0007685	mml-mir-301a	Macaca mulatta miR-301a stem-loop	ACUGCUAACGAAUGCUCUGACUUUAUUGCACUACUGUACUUUACAGCUAGCAGUGCAAUAGUAUUGUCAAAGCAUCUGAAAGCAGG		32
20934	MI0007686	mml-mir-301b	Macaca mulatta miR-301b stem-loop	CCGCAGGUGCUCUGACGAGGUUGCACUACUGUGCUCUGAGAAGCAGUGCAAUGAUAUUGUCAAAGCAUCUGGGACCA		32
20935	MI0007687	mml-mir-302a	Macaca mulatta miR-302a stem-loop	CCACCACUUAAACGUGGAUGUACUUGCUUUGAAACUAAAGAAGUAAGUGCUUCCAUGUUUUGGUGAUGG		32
20936	MI0007688	mml-mir-302b	Macaca mulatta miR-302b stem-loop	GCUCCCUUCAACUUUAACAUGGAAGUGCUUUCUGUGACUUUAAAAUAAGUAAGUGCUUCCAUGUUUUAGUAGGAGU		32
20937	MI0007689	mml-mir-302c	Macaca mulatta miR-302c stem-loop	CCUUUGCUUUAACAUGGGGGUACCUGCUGUGUGAAACAAAAGUAAGUGCUUCCAUGUUUCAGUGGAGG		32
20938	MI0007690	mml-mir-302d	Macaca mulatta miR-302d stem-loop	CCUCUACUUUAACAUGGAGGCACUUGCUGUGGUAUGACAAAAAUAAGUGCUUCCAUGUUUGAGUGUGG		32
20939	MI0007691	mml-mir-320	Macaca mulatta miR-320 stem-loop	GCUUCGCUCCCCUCCGCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGAAAAAGGAUGAGG		32
20940	MI0007692	mml-mir-323	Macaca mulatta miR-323 stem-loop	UUGGUACUUGGAGAGAGGUGGUCCGUGGCGCGUUCGCUUUAUUUAUGGCGCACAUUACACGGUCGACCUCUUUGCAGUAUCUAAUC		32
20941	MI0007693	mml-mir-324	Macaca mulatta miR-324 stem-loop	CUGACUAUGCCUCCCCGCAUCCCCUAGGGCAUUGGUGUAAAGCUGGAGACCCACUGCCCCAGGUGCUGCUGGGGGUUGUAGUC		32
20942	MI0007694	mml-mir-325	Macaca mulatta miR-325 stem-loop	AUGCAGUGCUUGGUUCCUAGUAGGUGUCCAGUAAGUGUUUGUUACAUAAUUUGUUUAUUGAGGACCUCCUAUCAAUCAAGCACUGUGCUAGGCUCUGG		32
20943	MI0007695	mml-mir-329-1	Macaca mulatta miR-329-1 stem-loop	GUGGUACCUGAAGGGAGGUUUUCUGGGUUUCUGUUUCUUUAAUGAGGAUGAAACACACCUGGUUAACCUCUUUUCCAGUAUCAA		32
20944	MI0007696	mml-mir-329-2	Macaca mulatta miR-329-2 stem-loop	GGUACCUGAAGGGAGGUUUUCUGGGUCUCUGUUUCUUUACUGAGGAUGAAACACACCUGGUUAACCUCUUUUCCAGUAUC		32
20945	MI0007697	mml-mir-330	Macaca mulatta miR-330 stem-loop	CUUUGGCGAUCACUGCCUCUCUGGGCCUGUGUCUUAGGCUCUGCAAGAUCAACCGAGCAAAGCACACGGCCUGCAGAGAGGCAGCGCUCUGCCC		32
20946	MI0007698	mml-mir-331	Macaca mulatta miR-331 stem-loop	GAGUUUGGUUUUGUUUGGGUUUGUUCUAGGUAUGGUCCCAGGGAUCCCAGAUCAAACCAGGCCCCUGGGCCUAUCCUAGAACCAACCUAAACUC		32
20947	MI0007699	mml-mir-335	Macaca mulatta miR-335 stem-loop	GAGCGGGGGUCAAGAGCAAUAACGAAAAAUGUUUGUCAUAAACCGUUUUUCAUUAUUGCUCCUGACCUCCUCUCAUUUGCUAUAUUCA		32
20948	MI0007700	mml-mir-337	Macaca mulatta miR-337 stem-loop	GUAGUCAGUAGUUGGGGGGUGGGAACGGCUUCAUACAGGAGUUGAUGCACAGUUAUCCAGCUCCUAUAUGAUGCCUUUCUUCAUCCCCUUCAA		32
20949	MI0007701	mml-mir-338	Macaca mulatta miR-338 stem-loop	UCUCCAACAAUAUCCUGGUGCUGAGUGAUGACUCAGGUGACUCCAGCAUCAGUGAUUUUGUUGAAGA		32
20950	MI0007702	mml-mir-339	Macaca mulatta miR-339 stem-loop	CGGGGCGGCCGCUCUCCCUGUCCUCCAGGAGCUCACGUGUGCCUGCCUGUGAGCGCCUCGACGACAGAGCCGGCGCCCGCCCCAGUGUCUGCGC		32
20951	MI0007703	mml-mir-340	Macaca mulatta miR-340 stem-loop	UUGUACCUGGUGUGAUUAUAAAGCAAUGAGACUGAUUGUCAUAUGUUGUUUGUGGGAUCCGUCUCAGUUACUUUAUAGCCAUACCUGGUAUCUUA		32
20952	MI0007704	mml-mir-342	Macaca mulatta miR-342 stem-loop	GAAACUGGGCUCAAGGUGAGGGGUGCUAUCUGUGAUUGAGGGACAUGGUUAAUGGAAUUGUCUCACACAGAAAUCGCACCCGUCACCUUGGCCUACUUA		32
20953	MI0007705	mml-mir-345	Macaca mulatta miR-345 stem-loop	AAACCCUAGGUCGGCUGACUCCUAGUCAAGGGCUCGUGGUGGCUGGUGGGCCCUGAACGAGGGUUCUGGAGGCCUGGGUUUGAAUAUC		32
20954	MI0007706	mml-mir-346	Macaca mulatta miR-346 stem-loop	GUCUGUCUGCCCGCAUGCCUGCCUCUCUGUUGCUCUGAAGGAGGCAGGGGCUGGGCCUGCAGCUGCCUGGGCAGAGCGGCUCCUGC		32
20955	MI0007707	mml-mir-361	Macaca mulatta miR-361 stem-loop	GGAGCUUAUCAGAAUCUCCAGGGGUACUUUAUAAUUUCAAAAAGUCCCCCAGGUGUGAUUCUGAUUUGCUUC		32
20956	MI0007708	mml-mir-362	Macaca mulatta miR-362 stem-loop	CUCGAAUCCUUGGAACCUAGGUGUGAGUGCUAUUUCAGUGCAACACACCUAUUCAAGGAUUCAAA		32
20957	MI0007709	mml-mir-363	Macaca mulatta miR-363 stem-loop	UGUUGUCGGGUGGAUCACGAUGCAAUUUUGAUUAGUAUCAUAGGAGAAAAAUUGCACGGUAUCCAUCUGUAAACC		32
20958	MI0007710	mml-mir-365-1	Macaca mulatta miR-365-1 stem-loop	ACCGCAGGGAAAAUGAGGGACUUUUGGGGGCAGAUGUGUUUCCAUUCCACUAUCAUAAUGCCCCUAAAAAUCCUUAUUGCUCUUGCA		32
20959	MI0007711	mml-mir-365-2	Macaca mulatta miR-365-2 stem-loop	AGAGUGUUCAAGGACAGCAAGAAAAAUGAGGGACUUUCAGGGGCAGCUGUGUUUUCUGACUCAGUCAUAAUGCCCCUAAAAAUCCUUAUUGUUCUUGCAGUGUGCAUCAGG		32
20960	MI0007712	mml-mir-367	Macaca mulatta miR-367 stem-loop	CCACUACUGUUGCUAAUAUGCAACUCUGUUGAACACAAAUUGGAAUUGCACUUUAGCAAUGGUGAUGG		32
20961	MI0007713	mml-mir-369	Macaca mulatta miR-369 stem-loop	UUGAAGGGAGAUCGACCGUGUUAUAUUCGCUUUAUUGACUUCGAAUAAUACAUGGUUGAUCUUUUCUCAG		32
20962	MI0007714	mml-mir-370	Macaca mulatta miR-370 stem-loop	AGACAGAGAAGCCAGGUCACGUCUCUGCAGUUACACAGCUCAUGAGUGCCUGCUGGGGUGGAACCUGGUCUGUCU		32
20963	MI0007715	mml-mir-371	Macaca mulatta miR-371 stem-loop	GUGGCACUCAAACUGUGGGGGCACUUUCUGCUCUCUGGUGAAAAAAGUGCCGCCAUGUUUUGAGUGUUAC		32
20964	MI0007716	mml-mir-372	Macaca mulatta miR-372 stem-loop	GUGAUCCUCAAAUGUGGAGCACUAUUCUGAUGUCCAAGUGGAAAGUGCUGCGACAUUUGAGCGUCAC		32
20965	MI0007717	mml-mir-373	Macaca mulatta miR-373 stem-loop	GGGAUACCCAAAAUGGGAGCACUUUCCCUUUUGUCUGUGCUGGGAAGUGCUUCGAUUUUGGGGUGUCCC		32
20966	MI0007718	mml-mir-374a	Macaca mulatta miR-374a stem-loop	UACAUCGGCCAUUAUAAUACAACCUGAUAAGUGUUACAGCACUUAUCAGAUUGUAUUGUAAUUGUCUGUGUA		32
20967	MI0007719	mml-mir-374b	Macaca mulatta miR-374b stem-loop	ACUCGGAUGGAUAUAAUACAACCUGCUAAGUGUCCUAGCACUUAGCAGGUUGUAUUAUCAUUGUCCGUGUCU		32
20968	MI0007720	mml-mir-375	Macaca mulatta miR-375 stem-loop	CCCCGCGACGAGCCCCUCGCACAAACCGGACCUGAGCGUUUUGUUCGUUCGGCUCGCGUGAGGC		32
20969	MI0007721	mml-mir-376a-1	Macaca mulatta miR-376a-1 stem-loop	UAAAAGGUAGAUUCUCCUUCUAUGAGUACAUUAUUUAUGAUUAAUCAUAGAGGAAAAUCCACGUUUUC		32
20970	MI0007722	mml-mir-376a-2	Macaca mulatta miR-376a-2 stem-loop	GGUAUUUAAAAGGUAGAUUUUCCUUCUAUGGUUACGUGUUUGAUGGUUAAUCAUAGAGGAAAAUCCACGUUUUCAGUAUC		32
20971	MI0007723	mml-mir-376b	Macaca mulatta miR-376b stem-loop	CAGUCCUUCUUUGGUAUUUAAAACGUGGAUAUUCCUUCUAUGUUUACGUGAUUCCUGGUUAAUCAUAGAGGAAAAUCCAUGUUUUCAGUAUCAAAUGCUG		32
20972	MI0007724	mml-mir-376c	Macaca mulatta miR-376c stem-loop	AAAAGGUGGAUAUUCCUUCUAUGUUUAUGUUAUUUAUGGUUAAACAUAGAGGAAAUUCCACGUUUU		32
20973	MI0007725	mml-mir-377	Macaca mulatta miR-377 stem-loop	UUGAGCAGAGGUUGCCCUUGGUGAAUUCGCUUUAUUUAUGUUGAAUCACACAAAGGCAACUUUUGUUUG		32
20974	MI0007726	mml-mir-378	Macaca mulatta miR-378 stem-loop	AGGGCUCCUGACUCCAGGUCCUGUGUGUUACCUCGAAAUAGCACUGGACUUGGAGUCAGAAGGCCU		32
20975	MI0007727	mml-mir-379	Macaca mulatta miR-379 stem-loop	AGAGAUGGUAGACUAUGGAACGUAGGCGUUAUGAUUUUUGACCUAUGUAACAUGGUCCACUAACUCU		32
20976	MI0007728	mml-mir-380	Macaca mulatta miR-380 stem-loop	AAGAUGGUUGACCAUAGAACAUGCGCUAUCUCUGUGUCGUAUGUAAUAUGGUCCACGUCUU		32
20977	MI0007729	mml-mir-381	Macaca mulatta miR-381 stem-loop	UACUUAAAGCGAGGUUGCCCUUUGUAUAUUCGGUUUAUUGACAUGGAAUAUACAAGGGCAAGCUCUCUGUGAGUA		32
20978	MI0007730	mml-mir-382	Macaca mulatta miR-382 stem-loop	UACUUGAAGAGAAGUUGUUCGUGGUGGAUUCGCUUUACUUAUGACGAAUCAUUCACGGACAACACUUUUUUCAGUA		32
20979	MI0007731	mml-mir-383	Macaca mulatta miR-383 stem-loop	CUCCUCAGAUCAGAAGGUGAUUGUGGCUUUGGGUGGAUAUUAAUCAGCCACAGCACUGCCUGGUCAGAAAGAG		32
20980	MI0007732	mml-mir-384	Macaca mulatta miR-384 stem-loop	UGUUAAAUUAGGAAUUGUAAACAAUUCCUAGGCAAUAUGUAUAAUGUUCAUAAGACAUUCCUAGAAAUUGUUCAUAAUGCCUGUAACA		32
20981	MI0007733	mml-mir-409	Macaca mulatta miR-409 stem-loop	UGGUACUCGGGGAGAGGUUACCCGAGCAACUUUGCAUCUGGACGACGAAUGUUGCUCGGUGAACCCCUUUUCGGUAUCA		32
20982	MI0007734	mml-mir-410	Macaca mulatta miR-410 stem-loop	GGUACCUGAGGAGAGGUUGUCUGUGAUGAGUUCGCUUUUAUUAAUGACGAAUAUAACACAGAUGGCCUGUUUUCAGUACC		32
20983	MI0007735	mml-mir-411	Macaca mulatta miR-411 stem-loop	UGGUACUUGGAGAGAUAGUAGACCGUAUAGCGUACGCUUUAUCUGUGACGUAUGUAACACGGUCCACUAACCCUCAGUAUCA		32
20984	MI0007736	mml-mir-412	Macaca mulatta miR-412 stem-loop	CUGGGGUACGGGGAUGGAUGGUCGACCAGUUGGAAAGUAAUUGUUUCUAAUGUACUUCACCUGGUCCACUAGCCGUCCGUAUCCGCUGCAG		32
20985	MI0007737	mml-mir-421	Macaca mulatta miR-421 stem-loop	CACAUUGUAGGCCUCAUUAAAUGUUUGUUGAAUGAAAAAAUGAAUCAUCAACAGACAUUAAUUGGGCGCCUGCUCUGUG		32
20986	MI0007738	mml-mir-422a	Macaca mulatta miR-422a stem-loop	GAGAGAAGCACUGGACUCAGGGUCAGAAGGCCUGAGUCUCCCUGCUGCAGAUGGGCUGUGUGUCCCUGAGCCAAGCCUUGUCCUCCCUGG		32
20987	MI0007739	mml-mir-423	Macaca mulatta miR-423 stem-loop	AUAAAGGAAGUUAGGCUGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGUCUUGCUUCCUACCCCGCGC		32
20988	MI0007740	mml-mir-424	Macaca mulatta miR-424 stem-loop	CGAGGGGAUACAGCAGCAAUUCAUGUUUUGAAGUGUUCUAAAUGGUUCAAAACGUGAGGCGCUGCUAUACCCCCUCGUGGGGAAGGUAGAAGGUGGGG		32
20989	MI0007741	mml-mir-425	Macaca mulatta miR-425 stem-loop	GAAAGCGCUUUGGAAUGACACGAUCACUCCCGUUGAGUGGGCCCCCGAGAAGCCAUCGGGAAUGUCGUGUCCGCCCAGUGCUCUUUC		32
20990	MI0007742	mml-mir-429	Macaca mulatta miR-429 stem-loop	CGCCGGCCGAUGAGCGUCUUACCAGACACGGUUAGACCUGGCUCUCUGUCUAAUACUGUCUGGUAAAACCGUCCAUCCGCGGC		32
20991	MI0007743	mml-mir-431	Macaca mulatta miR-431 stem-loop	UCCUGCUUGUCCUGCGAGGUGUCUUGCAGGCCGUCAUGCAGGCCACACUGACGGUAACGUUGCAGGUCGUCUUGCAGGGCUUCUCGCAAGACGACAUCCUCAUCACCAACGACG		32
20992	MI0007744	mml-mir-432	Macaca mulatta miR-432 stem-loop	UGACUCCUCCAUGUCUUGGAGUAGGUCAUUGGGUGGAUCCUCUAUUUCCUUAUGUGGGCCACUGGAUGGCUCCUCCAUGUCUUGGAGUAGAUCA		32
20993	MI0007745	mml-mir-433	Macaca mulatta miR-433 stem-loop	CCAGGGAGAAGUACGGUGAGCCUGUCAUUAUUCAGAGAGGCUAGAUCCUCUGUGUUGAGAAGGAUCAUGAUGGGCUCCUCGGUGUUCUCCAGG		32
20994	MI0007746	mml-mir-448	Macaca mulatta miR-448 stem-loop	GCCGGGAGGUUGAACAUCCUGCAUAGUGCUGCCAGGAAAUCCCUAUUUCAUACUAAGAGGGGCUGGCUGGUUGCAUAUGUAGGAUGUCCCAUCUCCCAGCCUACUUCGUCA		32
20995	MI0007747	mml-mir-449a	Macaca mulatta miR-449a stem-loop	CUGUGUGUGAUGAGCUGGCAGUGUAUUGUUAGCUGGUUGAAUAUGUGAAUGGCAUCAGCUAACAUGCAACUGCUGUCUUAUUGCAUAUACA		32
20996	MI0007748	mml-mir-449b	Macaca mulatta miR-449b stem-loop	UGACCUGAAUCAGGUAGGCAGUGUAUUGUUAGCUGGCUGCUUGAGUCAAGUCAGCAGCCACAACUACCCUGCCACUUGCUUCUGGAUAAAUUCUUCU		32
20997	MI0007749	mml-mir-450a-1	Macaca mulatta miR-450a-1 stem-loop	AAAUGAUACUAAACUGUUUUUGCGAUGUGUUCCUAAUAUGUACUAUAAAUAUAUUGGGAACAUUUUGCAUGUGUAGUUUUGUAUCAAUAUA		32
20998	MI0007750	mml-mir-450a-2	Macaca mulatta miR-450a-2 stem-loop	CCAAAGAAAGAUGCUAAACUAUUUUUGCGAUGUGUUCCUAAUAUGUAAUAUAAAUGUAUUGGGGACAUUUUGCAUUCAUAGUUUUGUAUCAAUAAUAUGG		32
20999	MI0007751	mml-mir-450b	Macaca mulatta miR-450b stem-loop	GCAGAAUUAUUUUUGCAAUAUGUUCCUGAAUAUGUAGUAUAAGCGUAUUGGGAUCAUUUUGCAUCCAUAGUUUUGUAU		32
21000	MI0007752	mml-mir-451	Macaca mulatta miR-451 stem-loop	CUUGGGAAUGGCAAGGAAACCGUUACCAUUACUGAGUUUAGUAAUGGUAAGGGUUCUCUUGCUAUAUCCAGA		32
21001	MI0007753	mml-mir-452	Macaca mulatta miR-452 stem-loop	GCUAAGCACUUACAACUGUUUGCAGAGGAAACUGAGACUUUGUAACUAUGUCUCAGUCUCAUCUGCAAAGAAGUAAGUGCUUUGC		32
21002	MI0007754	mml-mir-453	Macaca mulatta miR-453 stem-loop	GCAGGAAUGCUGUGAGCAGUGCCACCUCAUGGUACUCGGAGGGAGGUUGUCCGUGGUGAGUUCGCAUUAUUUAAUGAUGC		32
21003	MI0007755	mml-mir-454	Macaca mulatta miR-454 stem-loop	UCUGUUUAUCACCAGAUCCUAGAACCCUAUCAAUAUUGUCUCUGCUGUGUAAAUAGUUCUGAGUAGUGCAAUAUUGCUUAUAGGGUUUUGGUGUUUGGGAAGAACAAUGGGCAGG		32
21004	MI0007756	mml-mir-455	Macaca mulatta miR-455 stem-loop	UCCCUGGCGUGAGGGUAUGUGCCUUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACACUUGCCUCAAGGCCUAUGUCAUC		32
21005	MI0007757	mml-mir-484	Macaca mulatta miR-484 stem-loop	GUCAGGCUCAGUCCCCUCCCGAUAAACCCCUAAAUAGGGACUUUCCCGGGGGGUGACCCUGGC		32
21006	MI0007758	mml-mir-485	Macaca mulatta miR-485 stem-loop	ACUUGGAGAGAGGCUGGCCGUGAUGAAUUCGAUUCAUCAAAGCGAGUCAUACACGGCUCUCCUCUCUUUUAGU		32
21007	MI0007759	mml-mir-486	Macaca mulatta miR-486 stem-loop	GUAUCCUGUACUGAGCUGCCCCGAGCUGGGCAGCAUGAAGGGCCUCGGGGCAGCUCAGUACAGGAUGC		32
21008	MI0007760	mml-mir-487a	Macaca mulatta miR-487a stem-loop	GGUACUUGGAGAGUGGUCAUCCCUGCUGUGUUCGCUUUGUUUAUGACGAAUCAUACAGGGACAUCCAGUUUUUCAGUAUC		32
21009	MI0007761	mml-mir-487b	Macaca mulatta miR-487b stem-loop	UUGGUACUUGGAGAGUGGUUAUCCCUGUCCUGUUCGUUUUGCUCGUGUCGAAUCGUACAGGGUCAUCCACUUUUUCAGUAUCAA		32
21010	MI0007762	mml-mir-488	Macaca mulatta miR-488 stem-loop	GAGAAUCAUCUCUCCCAGAUAAUGGCACUCUCAAACAAGUUUCCAAGUUGUUUGAAAGGCUAUUUCUUGGUCAGAUGACUCUC		32
21011	MI0007763	mml-mir-489	Macaca mulatta miR-489 stem-loop	GUGGCAGCUUGGUGGUCGUAUGUGUGGCGCCAUUUACUUGAACCUUUAGGAGUGACAUCACAUAUACGGCAGCUAAACUGUUAC		32
21012	MI0007764	mml-mir-490	Macaca mulatta miR-490 stem-loop	UGGAGGCCUUGCUGGUUUGGAAAGUUCAUUGUUCGACACCAUGGAUCUCCAGGUGGGUCAAGUUUAGAGAUGCACCAACCUGGAGGACUCCAUGCUGUUGAGCUGUUCACAAGCAGCGGACACUUCCA		32
21013	MI0007765	mml-mir-491	Macaca mulatta miR-491 stem-loop	UUGACUUAGCUGGGUAGUGGGGAACCCUUCCAUGAGGAGUAGAACACUCCUUAUGCAAGAUUCCCUUCUACCUGGCUGGGUUGG		32
21014	MI0007766	mml-mir-492	Macaca mulatta miR-492 stem-loop	ACUACAGCCACUACUACAAGACCUUCGAGGACCUGCGGGACAAGAUUCUUGGUGCCGUCAAUGAGAACUCCAGGAUUGUCCUGCAGAUCAACAAUGCCUGUCUGGCUGCAGAUG		32
21015	MI0007767	mml-mir-493	Macaca mulatta miR-493 stem-loop	CUGGCCUCCAGGGCUUUGUACAUGGUAGGCUUUCAUUCAUUCGUUUGCACAUUCGGUGAAGGUCUACUGUGUGCCAGGCCCUGUGCCAG		32
21016	MI0007768	mml-mir-494	Macaca mulatta miR-494 stem-loop	GAUACUCGAAGGAGAGGUUGUCCGUGUUGUCUUCUCUUUAUUUAUGAUGAAACAUACACGGGAAACCUCUUCUUUAGUAUC		32
21017	MI0007769	mml-mir-495	Macaca mulatta miR-495 stem-loop	UGGUACCUGAAAAGAAGUUGCCCAUGUUAUUUUCGCUUUAUAUGUGACGAAACAAACAUGGUGCACUUCUUUUUCGGUAUCA		32
21018	MI0007770	mml-mir-496	Macaca mulatta miR-496 stem-loop	CCCGAGUCAGGUACUCGAAUGGAGGUUGUCCAUGGUGUGUUCAUUUUAUUUAUGAUGAGUAUUACAUGGCCAAUCUCCUUUCGGUACUCAAUUCUUCUUGGG		32
21019	MI0007771	mml-mir-497	Macaca mulatta miR-497 stem-loop	CCACCCCGGUCCUGCUCCCGCCCCAGCAGCACACUGUGGUUUGUACGGCACUGUGGCCACGUCCAAACCACACUGUGGUGUUAGAGCGAGGGUGGGGGAGGCACCGCCGAGG		32
21020	MI0007772	mml-mir-498	Macaca mulatta miR-498 stem-loop	AAUCCUCCUUGGGAAGUGAAGCUCAGGCUGUGAUUUCAAGCCAGGGGGCGUUUUUCUGUGACUGGAUGAAAAGCACCUCCGGGGCUUGAAGCUCACAGUUUGAGAGCAAUCAUCUAAGGAAGUU		32
21021	MI0007773	mml-mir-499	Macaca mulatta miR-499 stem-loop	GCCCUGUCCCCGUGUCUUGGGCGGGCAGCUGUUAAGACUUGCAGUGAUGUUUAACUCCUCUCCACGUGAACAUCACAGCAAGUCUGUGCUGCUUCCCGUCCCUACGCUGCCUGGGCAGGGU		32
21022	MI0007774	mml-mir-500	Macaca mulatta miR-500 stem-loop	GCUCCCCCUCUCUAAUCCUUGCUACCUGGGUGAGAGUGCUAUCUGAAUGCAAUGCACCUGGGCAAGGAUUCUGAGAGCGAGAGC		32
21023	MI0007775	mml-mir-501	Macaca mulatta miR-501 stem-loop	GCUCUUCCUCUCUAAUCCUUUGUCCCUGGGUGAGAGUGCUUUCUGAAUGCAGUGCACCCAGGCAAGGAUUCUGAGAGGGUGAGC		32
21024	MI0007776	mml-mir-502	Macaca mulatta miR-502 stem-loop	CCCUCUCUAAUCCUUGCUAUCUGGGUGCUAGUGCUGUCUCAAUGCAAUGCACCUGGGCAAGGAUUCAGAGAGGGGGAGCU		32
21025	MI0007777	mml-mir-503	Macaca mulatta miR-503 stem-loop	UGCCCUAGCAGCGGGAACAGUUCUGCAGUGAGUGAUCAGUACUCUGGAGUAUUGUUUCCGCUGCCAGGGUA		32
21026	MI0007778	mml-mir-504	Macaca mulatta miR-504 stem-loop	GCUGCUGUUGGGAGACCCUGGUCUGCACUCUAUCUGUAUUCUUACUGAAGGGAGCGCAGGGCAGGGUUUCCCAUACAGAGGGC		32
21027	MI0007779	mml-mir-505	Macaca mulatta miR-505 stem-loop	GAUGCACCCAGUGGGGGAGCCAGGAAGUAUUGAUGUUUCUGCCAGUUUAGCGUCAACACUUGCUGGUUUCCUCUCUGGAGCAUC		32
21028	MI0007780	mml-mir-511-1	Macaca mulatta miR-511-1 stem-loop	CAAUAGACACCCACCUUGUCUUUUGCUCUGCAGUCAGUAAAUAUUUUUUUGUGAAUGUGUAGCAAAAGACAGAAUGGGGGUCCAUUG		32
21029	MI0007781	mml-mir-511-2	Macaca mulatta miR-511-2 stem-loop	CAAUAGACACCCACCUUGUCUUUUGCUCUGCAGUCAGUAAAUAUUUUUUUGUGAAUGUGUAGCAAAAGACAGAAUGGGGGUCCAUUG		32
21030	MI0007782	mml-mir-512-1	Macaca mulatta miR-512-1 stem-loop	UCUCACUCUGUGGCACUCAGCCUCGGGGGCACUUUCUGGUGUCAGAAUGAAAGUGCUGUCAUUGCUGAGAUCCAAUGACUGAGG		32
21031	MI0007783	mml-mir-512-2	Macaca mulatta miR-512-2 stem-loop	GGUACUUCUCACUCUGUGGCACUCAGCCUCGGGGGCACUUUCUGGUGUCAGAAUGAAAGUGCUGUCAUUGCUGAGAUCCAAUGACUGAGGCGAGCACC		32
21032	MI0007784	mml-mir-514-2	Macaca mulatta miR-514-2 stem-loop	GUUGUCUGUGGUACCCUACUCUGGAGAGUGACAAUCAUGUAUAAUUAAAUUUGAUUGACACUUCUGUGAGUAGAGUAAUGCAUGACAC		32
21033	MI0007785	mml-mir-516a-1	Macaca mulatta miR-516a-1 stem-loop	UCUCAGGCUGUGACCGUCUCGAGGAAAGAAGCACUUUCUGUUGUCUAAAGAAAAGGAAGUGUUUCCUUCCCGAGGGUUACGGUUUGAGA		32
21034	MI0007786	mml-mir-516a-2	Macaca mulatta miR-516a-2 stem-loop	UCUCAGGCUGUGACCGUCUCGAGGAAAGAAGCACUUUCUGUUGUCUAAAGAAAAGGAAGUGUUUCCUUCCCGAGGGUUACGGUUUGAGA		32
21035	MI0007787	mml-mir-517a	Macaca mulatta miR-517a stem-loop	CUCAUGCAGUGACCCUCUAGAUGGAAGCACUGUCUGUGGUCUAAAAGAAAAGAUCGUGCAUCCUUUUAGAGUGUUACCGUUUGAGA		32
21036	MI0007788	mml-mir-517b	Macaca mulatta miR-517b stem-loop	GUGACCCUCUAGAUGGAAGCACUGUCUGUGGUCUAAAAGAAAAGAUCGUGCAUCCUUUUAGAGUGUUAC		32
21037	MI0007789	mml-mir-518a	Macaca mulatta miR-518a stem-loop	UCUCAUGCUGUGACCCUACAAAGGGAAGCCCUUUCUGUUGUCUAAACGAAAAGAAAGUGCUUCUCUUUGCUGGGUUACGGUUUGAGA		32
21038	MI0007790	mml-mir-518b	Macaca mulatta miR-518b stem-loop	UCAGGCUGUGACCCUCCAGAGGGAAGCACUUUCUGUUGUCUGAAAGAAAGCAAAGCGCUCCCCUUUAGAGGAUUACGGUUUGA		32
21039	MI0007791	mml-mir-518c	Macaca mulatta miR-518c stem-loop	GCGAGAAGAUUUCAUGCUGUGACUCUCUGGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAACAAAGCGCUUCUCUUUAGAGAGUUACGGUUUGAGAAAAGC		32
21040	MI0007792	mml-mir-518d	Macaca mulatta miR-518d stem-loop	CAUGCUGUGACUCUCUGGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAACAAAGCGCUUCUCUUUAGAGAGUUACGGUUUGAGA		32
21041	MI0007793	mml-mir-518e	Macaca mulatta miR-518e stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCGAUUUCUGUGAUCUGAAAGAAAAGAAAAUGGUUCCCUUUAGAGUGUUACUGUUUGAGA		32
21042	MI0007794	mml-mir-518f	Macaca mulatta miR-518f stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCACUUUAUCUUGUGUGAAAGGAAAGAAAGCGCUUCCCUUCAGAGGAUUACUCUUUGAGA		32
21043	MI0007795	mml-mir-519a	Macaca mulatta miR-519a stem-loop	CUCAGGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUGGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGGUUACCGUUUGAG		32
21044	MI0007796	mml-mir-519b	Macaca mulatta miR-519b stem-loop	CAUGCUGUGACCCUCUGGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAACGUGCAUCCCUUUAGAGGGUUACUCUUUG		32
21045	MI0007797	mml-mir-519c	Macaca mulatta miR-519c stem-loop	UCUCAGUCUGUGACCCUCUAGAAGGAAGCACUUUCUGUUGUUUGAAAGAAAAGAAAGUGCAUCAUUUUAGAGGAUUACAGUUUGAGA		32
21046	MI0007798	mml-mir-519d	Macaca mulatta miR-519d stem-loop	UCCCAAGCUGUGACCCUCCAAAGGGAAGCACUUUCUGUUUGUUGUCUGAGAGAAAACAAAGUGCUUCCUUUUAGAGUGUGACCGCUUGGGA		32
21047	MI0007799	mml-mir-520a	Macaca mulatta miR-520a stem-loop	CUCAGGCUGUGACCCUCCAGAGGGAAGUAUUUUCUGUUGUCUGAAGGAAAAGAAAGUGCUUCCCUUUGGACUGUUUCGGUUUGAG		32
21048	MI0007800	mml-mir-520b	Macaca mulatta miR-520b stem-loop	CCCUCUAGAGGGAAGCGCUUUCUGUGGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGG		32
21049	MI0007801	mml-mir-520c	Macaca mulatta miR-520c stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUGGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGGUUACCGUUUGAGA		32
21050	MI0007802	mml-mir-520d	Macaca mulatta miR-520d stem-loop	UCUCAUGCUGUGACCCUACAAAGGGAAGCCCUUUCUGUUGUCUAAACGAAAAGAAAGUGCUUCUCUUUGCUGGGUUACGGUUUGAGA		32
21051	MI0007803	mml-mir-520e	Macaca mulatta miR-520e stem-loop	GCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUGGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGGUUACCGUUUGAGA		32
21052	MI0007804	mml-mir-520f	Macaca mulatta miR-520f stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCGCUUUCUGUGGUCUGAAAGAAAAGAAAGUGCUUCCUUUUAGAGGGUUACCGUUUGAGA		32
21053	MI0007805	mml-mir-520g	Macaca mulatta miR-520g stem-loop	UCCCAUGCUGUGGCCCUCUAGAGAAAGCACUUUCUGUUUGUUGUCUGAGGAAAAACAAAGUGCUUCCCUUCAGAGUGUGGCUGUUUGGGA		32
21054	MI0007806	mml-mir-520h	Macaca mulatta miR-520h stem-loop	UCCCAAGCUGUGACCCUCCAAAGGGAAGCACUUUCUGUUUGUUGUCUGAGAGAAAACAAAGUGCUUCCUUUUAGAGUGUG		32
21055	MI0007807	mml-mir-521	Macaca mulatta miR-521 stem-loop	UCUCAUGCUGUGACCCUCCAAAGGGAAGUACUUUCUGUUGUCUAAAAGAAAAGAACGCACUUCCCUUUGGAGUGUUACCGUUUGAGA		32
21056	MI0007808	mml-mir-522	Macaca mulatta miR-522 stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCGAUUUCUGUGAUCUGAAAGAAAAGAAAAUGGUUCCCUUUAGAGUGUUACUGUUUGAGA		32
21057	MI0007809	mml-mir-523a	Macaca mulatta miR-523a stem-loop	UCUCAGGCUGUGACCCUCUAGAGGGAAGCACUUUCUGUUGUCUGGAAGAAAAGAAUGCGCUUCCCUUUAGAGGGUUACUCUCUGAGA		32
21058	MI0007810	mml-mir-523b	Macaca mulatta miR-523b stem-loop	UCUCAUGAUGUGACCCUCUAGAGCGAAGCGCUUUCUGUUGGCUAGAAAAGAAUAGGAAGCGCUUCCCUUUAGAGUGUUACGCUUUGAGA		32
21059	MI0007811	mml-mir-523c-1	Macaca mulatta miR-523c-1 stem-loop	CAUGCUGUGACCCUCUGGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAACGUGCAUCCCUUUAGAGGGUUACUCUUUGAGA		32
21060	MI0007812	mml-mir-523c-2	Macaca mulatta miR-523c-2 stem-loop	UCCCAUGCUGUGACCCUCUGGAGGGAAGCGCUUUCUGUUGUCUGAAAGAAAAGAACGUGCAUCCCUUUAGAGGGUUACUCUUUGAGAAGA		32
21061	MI0007813	mml-mir-525	Macaca mulatta miR-525 stem-loop	CUCAGGCUGUGACUCUCCAGAGGGAUGCACUUUCUUUUAUGUGAAAAAAAAAGAAGGCGCAUCCCUUUGGAGCGUUACGGUUUGGG		32
21062	MI0007814	mml-mir-532	Macaca mulatta miR-532 stem-loop	CGACUUGCUUUCUCUCCUCCAUGCCUUGAGUGUAGGACCGUUGGCAUCUUAAUUACCCUCCCACACCCAAGGCUUGCA		32
21063	MI0007815	mml-mir-539	Macaca mulatta miR-539 stem-loop	AUACUUGAGGAGAAAUUAUCCUUGGUGUGUUCGCUUUAUUUAUGAUGAAUCAUACAAGGACAAUUUCUUUUUGAGUAU		32
21064	MI0007816	mml-mir-542	Macaca mulatta miR-542 stem-loop	CAGACCUCAGACAUCUCGGGGAUCAUCAUGUCACGAGAUACCACUGUGCACUUGUGACAGAUUGAUAACUGAAAGGUCUGGGAGCCAUUCAUCUUCA		32
21065	MI0007817	mml-mir-544	Macaca mulatta miR-544 stem-loop	AUUUUCAUCACCUAGGGAUCUUGUUAAAAAGCAGAUUCUGAUUCAGGGACCAAGAUUCUGCAUUUUUAGCAAGUUCUCAAGUGAUGCUAAU		32
21066	MI0007818	mml-mir-545	Macaca mulatta miR-545 stem-loop	CCCAGCCUGGCACAUUAGUAGGCCUCAGUAAAUGUUUAUUAGAUGAAUAAAUGAAUGACUCAUCAGCAAACAUUUAUUGUGUGCCUGCUAAAGUGAGCUCCACAGG		32
21067	MI0007819	mml-mir-548a	Macaca mulatta miR-548a stem-loop	UCCAGGGAGGUAUUAAGUUGGUGCAAAAGUAAUUGUGGUUUUUUGCCAUUAAAAGUAAUGACAAUACUGGCAAUUACUUUUCCUCCAAACCUGAUAUU		32
21068	MI0007820	mml-mir-548b	Macaca mulatta miR-548b stem-loop	CAGGCUAUGUAUUUAGGUUGGUGCAAAAGUAAUUGGGGCUUGGGCCUUUAUUUUCAAUGGCAAAAACCUCAAUUGCUUUUGUGCCAACCUAAUACUU		32
21069	MI0007821	mml-mir-548c	Macaca mulatta miR-548c stem-loop	UGUGAUGUAUUAGGUUGAUGCAAAAGUAAUUGGGGUUUUUUGUCAUUAAAAGUAGUGACAAAACCGGCAAUUACUUCUGCACCAAACUAAUAUAA		32
21070	MI0007822	mml-mir-548d	Macaca mulatta miR-548d stem-loop	AAACAAGUUGUAUUAGGUUGGUGCAAAAGUAAUUGUGGUUCUUGCCUAUAAAAGUAAUGGCAAAAACCACAAUUUCUUUUGCACCAAACUAAUAAAG		32
21071	MI0007823	mml-mir-548e	Macaca mulatta miR-548e stem-loop	CCUAGAAUGUUACUAGGUUGGUGCAAAAGUAAUUGCGAGUUUUACCAUUACUUUCAAUGGCAAAACCGGCAGUUACUUUUGCACCAACGUAAUACUU		32
21072	MI0007824	mml-mir-548f	Macaca mulatta miR-548f stem-loop	AUUUAGGUUGGUGCAAAAGUAAUUGCGGAUUUUGCCAUUGAAAGUAAUGGCCAAAACCACAGUUCCUUUUGCACCAAUCUAUAGA		32
21073	MI0007825	mml-mir-549	Macaca mulatta miR-549 stem-loop	AGACAUGCAACUCAAGAAUAUAUUGAGAGCUCAUCCAUAGUUGUCACUGUCUCAGAUCAUGACAAUUAUGGAUGAGCUCUUAAUAUAUCCCAGGC		32
21074	MI0007826	mml-mir-550	Macaca mulatta miR-550 stem-loop	UGAUGCUUUGCUGGCUGGUGCAGUGCCUGAGGGAGUAAGAGCCCUGUUGUUGUAAGAUAGUGUCCUACUCCCUCAGGCACAUCUCCAGCAAGU		32
21075	MI0007827	mml-mir-551a	Macaca mulatta miR-551a stem-loop	GGGGACUGCCGGGUGACCCUGGAAAUCCAGAGUGGGUGGGGCCUGUCUGACCAUUUCUAGGCGACCCACUCUUGGUUUCCAGGGUUGCCCUGGAAA		32
21076	MI0007828	mml-mir-551b	Macaca mulatta miR-551b stem-loop	AGAUGUGCUCUCCUGGCCCAUGAAAUCAAGCGUGGGUGAGACCUGGUGCAGAACAGGAAGGCGACCCAUACUUGGUUUCAGAGGCUGCGAGAAUA		32
21077	MI0007829	mml-mir-552	Macaca mulatta miR-552 stem-loop	ACCAUUCAAAUAUACCACAGUUUGUUUGACCAUUAACCUGUUUGUUGAAGAUGCCUUUCAACGGGUGACUGGUUAGACAAACUGUGGUAUAUUCA		32
21078	MI0007830	mml-mir-553	Macaca mulatta miR-553 stem-loop	CUUCAAUUUUAUUUGAAAAAGGUGAGGUUUUGUUUUGUCUGAGAAAAUCUCACUGUUUUAGACUGAGG		32
21079	MI0007831	mml-mir-554	Macaca mulatta miR-554 stem-loop	ACCUGAGUAACCUUUGCUAGUCCUGACUCAGCCAGUACUGAUCUUACACUGGCAGUGGGUCAGGGUUCAUAUUUUGGCAUCUCUCUCUGGGCAUCU		32
21080	MI0007832	mml-mir-556	Macaca mulatta miR-556 stem-loop	GAUAGUAAUGAGAAAGAUGAACUCAUUGUAAUAUGAGCUUCAUUUAUGCAUUUCAUAUUACAAUUAGCUGAUCUUUUUUUUU		32
21081	MI0007833	mml-mir-557	Macaca mulatta miR-557 stem-loop	AGAAUGGGCAAAUGAAUAGUAAAUUUGGAGGCCUGGGGCCCUCCCUGCUGCUGGACAAGUGUCUGCAUGGGUGAGCCUUAUCUUUGAAAGGAGGUGGA		32
21082	MI0007834	mml-mir-558	Macaca mulatta miR-558 stem-loop	GUGUGUGUGUGUGUUUGUGUUUAUUUUGGCAUAGUAGCUCUAGACUCUAUUAUAGUUUCCUGAGCUGCUGUACCAAAAUACCACAAACUGCCUG		32
21083	MI0007835	mml-mir-562	Macaca mulatta miR-562 stem-loop	AGUGAAAUUGCUGGGUCAUAUGGUCAGUCUACUUUCAGAGUAAUUGUGAAAGUAUUUUUCAAAGUAGCUGUACCAUUUGCAUUCCCUGUGGCAAU		32
21084	MI0007836	mml-mir-563	Macaca mulatta miR-563 stem-loop	AGCAAAGAAGUGUGUUGCCCUCCAGGAAAUGUGUGUUGCUCUGAUGUAAUUAGGCUGACAUACAUUUCCCUGGUAGCCA		32
21085	MI0007837	mml-mir-567	Macaca mulatta miR-567 stem-loop	GGAUUCUUACAGGACACUAUGUUCUUCCAGGACAGAACAUUCUUUGCUAUUUUGUACUGGAAGAACAUGCAAAACUUUAAAAAAAGUUAUUGCU		32
21086	MI0007838	mml-mir-568	Macaca mulatta miR-568 stem-loop	AUAUACACUAUAUUAUGUAUAAAUGUAUACACACUUCCUAUAUGUAUCCACAUAUAUAUAGUGUAUAUAUUAUACAUGUAUAGGUGUGUAUAUG		32
21087	MI0007839	mml-mir-569	Macaca mulatta miR-569 stem-loop	GGUAUUGUUAGAUUAAUUUUGUGGGACAUUAACAACAGCAUCAGCAGCAACAUCAGCUUUAGUUAAUGAAUCCUGGAAAGUUAAGUGACUUUAUUU		32
21088	MI0007840	mml-mir-570	Macaca mulatta miR-570 stem-loop	UAUUAGGUUGGUGCAAACGUAAUUGCAGUUUUUGCCAUUACUUUUAAAGGCAAAAGUAGCAAUUACCUUUGCACCAACCU		32
21089	MI0007841	mml-mir-572	Macaca mulatta miR-572 stem-loop	GUCGAGGCCGUGGCCCGGAAGUGAUCGGGGCCGCCGCGGACGGAAGGGCGCCUCUGCUUCGUCCGCUCGGCGGUGGCCCAGCCAGGCCCGCGGGA		32
21090	MI0007842	mml-mir-573	Macaca mulatta miR-573 stem-loop	UUUAGAGGUGUCUCCCUGAAGUGAUGCAUAACCGAUCAGGAUCUACUCAUGUCAACUUUGGUAAAGUUAUGUUGCUUGUCAGGGUGAGGAGAGGUUUUG		32
21091	MI0007843	mml-mir-576	Macaca mulatta miR-576 stem-loop	UACAAUCCAGUGAGGAUUCUAAUUUCUCCACAUCUUUGGUAAUAAGUUUUGGCAAAGAUGUGGAAAAAUUGGAAUCCUCAUUGGAUUGGUUAUAA		32
21092	MI0007844	mml-mir-577	Macaca mulatta miR-577 stem-loop	UGGGGGAAUGAAGAGUAGAUAAAAUAUUGGUACCUGAUGAGUGUGAGGCCAGGUUUCAAUACUUUAUCUGCUCUUCAUUUUCCCAUAUCUACUUAC		32
21093	MI0007845	mml-mir-578	Macaca mulatta miR-578 stem-loop	GAUAAAUAUAUAGACAAAAUACAAUCCUGGACUAUAAGAAGCUCCUAUAGCUCCUGUAGCUUCUUGUGCUCUGGGAUUGUAUUUUGUUUAUAUAU		32
21094	MI0007846	mml-mir-579	Macaca mulatta miR-579 stem-loop	CAUAUUAGGUUAAUGCAAAAGUAAUCGCGGUUUGUGCCAAAUGGCGAUUUGAAUUAAUAAAUUCAUUUGGUACAAACCGCGAUUACUUUUGCAUCAGC		32
21095	MI0007847	mml-mir-580	Macaca mulatta miR-580 stem-loop	AUAAAAUUUCCAGUUGGAACCUAAUGAUUCAUCAGACUCAGAUAUUUAAGUUAACAGUAUUUGAGUCUGAUGAAUCAUUAGGUUCCAGUCAGAAAUU		32
21096	MI0007848	mml-mir-581	Macaca mulatta miR-581 stem-loop	GUUCUGUGAACGUAUUCUUGUGUUCUGUAGAUCAGUGCUUUUAGAAAAUUUGUGUGAUCUAGAGAACACAAAGAAUACCUACACAGAACCAUCUGC		32
21097	MI0007849	mml-mir-582	Macaca mulatta miR-582 stem-loop	AUCUGUGCUCUUUGAUUACAGUUGUUCAACCAGUUACUAAUCUACCUAAUUGUAACUGGUUGAACAACUGAACCCAAAGGGUGCAAAGUAGAAACAUU		32
21098	MI0007850	mml-mir-583	Macaca mulatta miR-583 stem-loop	AACUCGCACAUUUACCAAAGAGGAAGGUCCCAGUACUGCAGGGAUCUUAGCAGUACUGGGACCUACCUCUUUGGU		32
21099	MI0007851	mml-mir-584	Macaca mulatta miR-584 stem-loop	UAGGGUGACCAGCCAUUAUGGUUUGCCUGGGACUGAGGAAUUUGCUGGGAUAUGUCAGUUCCAGGCCAACCAGGCUGGUUGGUUUCCCUGAAGCAAC		32
21100	MI0007852	mml-mir-586	Macaca mulatta miR-586 stem-loop	AUGGGGUAAAACCAUUAUGCAUAUUGUAUUUUUAGGUCCCAAUACGUGUGGACCCUAAAAAUGCAAUGCAUAAUGGUUUUAUACUCUUUAUCUUCUUAU		32
21101	MI0007853	mml-mir-587	Macaca mulatta miR-587 stem-loop	CUCCUAGGCACCCUCUUUCCACAGGUGAUGAGUUACAGGGCCCAGGGAAUGUGUCUGCACCUGUGACUCAUCACUGGUGGAAGCCCAUAC		32
21102	MI0007854	mml-mir-589	Macaca mulatta miR-589 stem-loop	UCCAGCCUGUGCCCAGCAGCCCCUGAGAACCACGUCUGCUCUGAGCUGGGUACUGCCUGUUCAGAACAGACGCUGCUUCCCAGACGCUGCCAGCUGGCC		32
21103	MI0007855	mml-mir-590	Macaca mulatta miR-590 stem-loop	UAGCCAGUCAGAAAUGAGCUUAUUCAUAAAAGUGCAGUAUGGUGGAGUCAGUCUGUAAUUUUAUGUAUAAGCUGGUCUCUAACUGAAACGUGCAGCA		32
21104	MI0007856	mml-mir-592	Macaca mulatta miR-592 stem-loop	UAUUAUGCCAUGACAUUGUGUCAAUAUGCGAUGAUGUGUUGUGAUGGCACAGCGUCAUCACGUGGUGACGCAACAUCAUGACGUAAGACGUCACAAC		32
21105	MI0007857	mml-mir-593	Macaca mulatta miR-593 stem-loop	CCCCCAGAGUGUGUCAGGCAUCAGCCAGGCAUCGCUCAGCCCCUUUCCCUCUGGGGGAGCAAGGAGUGGUGCUGGGUUUGUCUCUGCUGGGGUUUCUCCU		32
21106	MI0007858	mml-mir-597	Macaca mulatta miR-597 stem-loop	UACUUACUCUACAUGUGUGUCACUUGACGACCACUGUGAAGAGAGUAAAAUGUACAGUGGUUCUCUUGGGGCUCAAGCGUAACGUAGAGUGCUGGUC		32
21107	MI0007859	mml-mir-598	Macaca mulatta miR-598 stem-loop	GCUUGAUGAUGCUGCUGAUGCUGGCGGUGAUCCCGAUGGUGUGAGCUGGAAAUGGGGUGCUACGUCAUCGUUGUCAUCGUCAUCAUCAUCAUCCGAG		32
21108	MI0007860	mml-mir-599	Macaca mulatta miR-599 stem-loop	AAAGACAUGCUGUCCACAGUGUGUUUGAUAAGCUGACAUGGGACAGGGAUUCUUUUCACUGUUGUGUCAGUUUAUCAAACCCAUACUUGGAUGAC		32
21109	MI0007861	mml-mir-600	Macaca mulatta miR-600 stem-loop	AAGUCACUUACUGUGUCUCCAGCUUCACAGGAAGGCUCUUGUCUGUCAGGCAGUGGAGUUACAGACAAGAGCCUUGCUCAGGCCAGCCCUGCCC		32
21110	MI0007862	mml-mir-601	Macaca mulatta miR-601 stem-loop	UGCAUGAGUUCAUCUUGGUCUAGGAUUGUUGGAGGAGUCAGAAAAAUUACCCCAGGGAUCCUGAAGUCAUUGGGGUGGA		32
21111	MI0007863	mml-mir-604	Macaca mulatta miR-604 stem-loop	AGAGCAUCGUGCUUGACCUUCCACGCUCCCGUGUCCACUAGCAGGCAGGUUUUCUGACACGGGCUGCGGGAUUCAGGACAGCGCAUCACGGAGA		32
21112	MI0007864	mml-mir-605	Macaca mulatta miR-605 stem-loop	CCCUAGCUUGGUUCUAAAUCCCACGGUGCCUUCUCCUUGGGAAAAACAGAGAAGGCACUGUGGGAUUUAGAACCAAGUUAGG		32
21113	MI0007865	mml-mir-607	Macaca mulatta miR-607 stem-loop	UCGCCCAAAGUCACACAGGUUAUAGAUCUGGAUUGGAACCCAGGUAGCCAGACUGCCUGGGUUUGAAUCCAGAUCUGUAACCUGUGUGACUUUGG		32
21114	MI0007866	mml-mir-609	Macaca mulatta miR-609 stem-loop	UGCUCUGCUUUUCCUAGGGUGUUGCUCUCAUCUCUGGUCUAUAAUGGGGUAAAUGUAGAGAUGAGGGCAACAGCCUAGGAACAGCAGAGGAACC		32
21115	MI0007867	mml-mir-611	Macaca mulatta miR-611 stem-loop	AAAAUGGUGAGAGGGUUAAGGGGAGUUCCCGACGGAGAUGCGAGGACCCCUCGGGGUCUGACCCACA		32
21116	MI0007868	mml-mir-612	Macaca mulatta miR-612 stem-loop	UCUCAUCUGGACCCCACUGGGGAGGGCUUCUGAGCUCCUCAGCACUGGCAGGAGGGGCUCCAGGGGCCCUCCCUCCAUGGCAGCCAGGACAGGACUCUCA		32
21117	MI0007869	mml-mir-615	Macaca mulatta miR-615 stem-loop	CUCGGGAGGGGCGGAAGGGGGGUCCCCGGUGCUCGGAUCUCGAGGGUGCUUAUUGUUCGGUCCGAGCCUGGGUCUCCCUCUUCCCCCCAACCCCCC		32
21118	MI0007870	mml-mir-616	Macaca mulatta miR-616 stem-loop	UUAGGUAAUUCCUCCUCUCAAAACCCUCCAAUGACUUCCCUGACAUGACAUAGGAAGUCACUGGAGAGUUUUGAGCAGAGGAAUGACCUGUUUUAAAA		32
21119	MI0007871	mml-mir-618	Macaca mulatta miR-618 stem-loop	UCUUGUUCACAACCAAACUCUACUUGUCCUUCUGAGUGUGAUUACGCCCAUGGAGUAGCUCAGGAGGCAAACAGGGUUACCCUGUGGAUAGGUCUGAAAA		32
21120	MI0007872	mml-mir-619	Macaca mulatta miR-619 stem-loop	CGCCCACCUCAGCCUCCCAAAAUGCUGGGAUUACAGGCAUGAGCCACCGCAGUCGACCAUGAUCUGGACAUGUUUGUGCCUGGGAUUGUCAGUUUGCAG		32
21121	MI0007873	mml-mir-624	Macaca mulatta miR-624 stem-loop	AAUGCUGUUUCAAGGUAGUACCAGUAUCUUGUGUUCAGUGGAACCAAGGUAAACACAAGAUACUGGUAUUACCUUGAGAUAGCAUUAACACCUAAGUG		32
21122	MI0007874	mml-mir-625	Macaca mulatta miR-625 stem-loop	AGGGUAGAGGUAUAAGGGGGGAAAGUUCUGCAGGCCUGUAAUUAGAUCUCAGGACUGUAGAACUUUCUCCCUCACCUCUGCCCU		32
21123	MI0007875	mml-mir-626	Macaca mulatta miR-626 stem-loop	ACCGAUAUCUUUGUCUUAUUUCUGAGCUGAGGGGUUAUUUUUAUGCAGUCUAAAUGAUCUCAGCUGUCCGAAAAUGUCUUCAAGUUUAAAGGCUU		32
21124	MI0007876	mml-mir-627	Macaca mulatta miR-627 stem-loop	UACUUAUUACCGGUAGUGAGUCUGUAAGAAAAGAGGAGGUGGUGGUUUUCCUCCUCUUUUCUUAGAGACUCACUACCAGUAAUAAGAAAUACUACUA		32
21125	MI0007877	mml-mir-628	Macaca mulatta miR-628 stem-loop	AUAGCUGUUGUGUCACUUCCUCAUGCUGACAUAUUUACUAGAGGGUAAAAUUAAUAACCUUCUAGUAAGAGUGGCAGUCGAAGGGAAGGACUCAU		32
21126	MI0007878	mml-mir-631	Macaca mulatta miR-631 stem-loop	GUGGAGAGCCUGGUUAGACCUGGCCCAGACCUCAGCUACACAAGCUGAUGGACUGAGUCAGGGGCCACACUCUCC		32
21127	MI0007879	mml-mir-632	Macaca mulatta miR-632 stem-loop	CGCCUCCUGCCGCAGUGCCUGACGGGAGGCGGAGCGGCGAACGAGGCCGUCGGCCAUUUUGUGUCUGCUUCCUGUGGGACGCGGUCGUAGCCGU		32
21128	MI0007880	mml-mir-633	Macaca mulatta miR-633 stem-loop	AACCUCUCUUAGCCUCUGUUUCUUUACUGUGGUAGAUACUAUUAGCCUAAAAUAAGAAGGCUAAUAGUAUCUACCACAAUAAAAUUGUUGUGAUGAUA		32
21129	MI0007881	mml-mir-636	Macaca mulatta miR-636 stem-loop	UGGCGGCCUGGGCGGGAGCGCGCGGGCGGGGCCGGCCCCGCUGCCUGGAAUUAACCCCGCUGUGCUUGCUCGUCCCGCCUGCAGCCCUAGGCGGCGUCG		32
21130	MI0007882	mml-mir-638	Macaca mulatta miR-638 stem-loop	GUAAGCGGGCGCGGCAGGGAUCGCGGGCGGGCGGCGGCCUAGGGUGCGGAGGGCGGACCGGGAAUGGCGCUCCCUGCGCCGCCGGCGUAACUGCGGCGCU		32
21131	MI0007883	mml-mir-639	Macaca mulatta miR-639 stem-loop	UGGCCGACGGGGCGCGCGCGGCCGGGAGGGGCGGGGCGGACGCACAGCCGCGUUUAGUCUAGCGCAGCGGUCGCGAGCGCUCUGGGUAUCCUGUCCUG		32
21132	MI0007884	mml-mir-640	Macaca mulatta miR-640 stem-loop	GUGACCCUGGGCAAGUUCCUGAAGAUCAAACACAUCAGAUCCCUUAUCUGUAAAAUGGGCAUGAUCCAGGAACCUGCCUCUAUGGUUGCCUUGGAG		32
21133	MI0007885	mml-mir-642	Macaca mulatta miR-642 stem-loop	AUCUGAGCUGGGAGGGUCCCUCUCCAAAUGUGUCUUGGGGUGGGGGAUCAAGACACAUUUGGAGAGGGAACCUCCCAACUCGGCCUC		32
21134	MI0007886	mml-mir-643	Macaca mulatta miR-643 stem-loop	ACCAACUGAUACGCAUUAUCUACGUGAGCUAGAAUACAAGUAGUUGGUGUCUUCAGAGACACUUGUAUUCUAGCUCAGGUAGAUACUGAAUGGAAAA		32
21135	MI0007887	mml-mir-644	Macaca mulatta miR-644 stem-loop	UUUUAUUUAGUAUUCUUCCAUCAGUGUUCAUAAGGGAUGUUGGUCUGUAGUUUUCUUAUAGUGUGGCUUGCUUAGAGCAAAGGUGGUUCCCU		32
21136	MI0007888	mml-mir-648	Macaca mulatta miR-648 stem-loop	AGCACAGACGCCUCCAAGUGUGCAGGGCACUGAUGGGGGCCAGGGCAGGCCCAGCCAAAGUGCAGGACCUGGCACUUAGUCGGAGGUGAGGAUG		32
21137	MI0007889	mml-mir-649	Macaca mulatta miR-649 stem-loop	GCCCUAGCCAAAUACUGUAUUUUUUAUCAACAUUUGGUUGAAAAACAUCUGUGUAUUAGUAAACCUGUGUUGUUCAAGAGUCCGCUGUGCUUUGCUG		32
21138	MI0007890	mml-mir-650a-1	Macaca mulatta miR-650a-1 stem-loop	CAGUGCUGGGAUCUCAGGAGGCAGCGCUCUCAGGACGUCUCCACCAUGGUCUGGGCUCUGCUCCUCCUCACCCUCCUCACUCAGGGCACAGGUGA		32
21139	MI0007891	mml-mir-650a-2	Macaca mulatta miR-650a-2 stem-loop	CAGUGCUGGGAUCUCAGGAGGCAGCGCUCUCAGGACUUCUCCACCAUGGUCUGGGCUCUGCUCCUCCUCACCCUCCUCACUCAGGGCACAGGUGA		32
21140	MI0007892	mml-mir-650b	Macaca mulatta miR-650b stem-loop	CAGUGCUGGGGUCUCAGGAGGCAGCGCUCUCGGGACAUCUCCACCAUGGCCUGGGAUCUGCUCCUCUUCACCCUCCUCACUCAGGGCACAGGUGA		32
21141	MI0007893	mml-mir-650c	Macaca mulatta miR-650c stem-loop	CAGUGCUGGGGUGUCAGGAGGCAGCGCUCUCAGUCUCCACCAUGGCCUGGGCUCUGCUCCUCCUCACUCUCCUCACUCAUGGCACGGGUGA		32
21142	MI0007894	mml-mir-650d	Macaca mulatta miR-650d stem-loop	CAGUGCUGGGGUCUCAGGAGACAGUGCUGUCGGGACGUCUCCACCAUGGCCUGGGCUCUGCUCCUCCUCACCCUUCUCACUCAAGGCACAGG		32
21143	MI0007895	mml-mir-651	Macaca mulatta miR-651 stem-loop	AAGCUAUCACUGCUUUUUAGAAUAAGCUUGACUUUUGUUCAAAUAAAAACGCAAAAGGAAAGUGUAUCUUAAAAGGCAAUGACAGUUUAAUAUGUUU		32
21144	MI0007896	mml-mir-652	Macaca mulatta miR-652 stem-loop	ACGAAUGGCUAUGCACUGCACAACCCUAGGAGAGGGUGCCAUUCACAUAGACUAUAAUUGAAUGGCGCCACUAGGGUUGUGCAGUGCACAACCUGCAC		32
21145	MI0007897	mml-mir-653	Macaca mulatta miR-653 stem-loop	UUCAUUCCUUCAGUGUUGAAACAAUCUCUACUGAACCAGCUUCAAACAAAUUCACUGGAGUUUGUUUCAAUAUUGCAAGAAUGAUAAGAUGGAAGC		32
21146	MI0007898	mml-mir-654	Macaca mulatta miR-654 stem-loop	GGGUAAGUGGAAAGAUGGUGGGCCGCAGAACAUGUGCUGAGUUCGUGCCAUAUGUCUGCUGACCAUCACCUUUAGAAGCCC		32
21147	MI0007899	mml-mir-656	Macaca mulatta miR-656 stem-loop	CUGAAAUAGGUUGUCUGUGAGGUGUUCACUUUCUAUAUGAUGAAUAUUAUACAGUCAACCUCUUUCCGAUAUCGAAUC		32
21148	MI0007900	mml-mir-657	Macaca mulatta miR-657 stem-loop	GGAGGAGAGGGUCCUGGAGAAGCGUGGACGGCUCCAGGUGGGUUCUGGCAGGUCCUCACCCUCUCUAGGCCCCAUUCUC		32
21149	MI0007901	mml-mir-660	Macaca mulatta miR-660 stem-loop	CUGCUCCUUCUCCCAUACCCAUUGCAUAUCGGAGUUGUAAAUUCUCAAAACACCUCCUGUGUGCAUGGAUUACAGGAGGGUGAGCCUUGUCAUCGUG		32
21150	MI0007902	mml-mir-661	Macaca mulatta miR-661 stem-loop	GGAGAGGCUGUGCUGUGGGGCAGGCGCUGGCCUGGGUGGCCUGAGCCCUGAUUUUGGGCUGCCUGGGUAUCUGGCCCGUGCGUGACCUUGGGGCGGCU		32
21151	MI0007903	mml-mir-662	Macaca mulatta miR-662 stem-loop	GCUGUUGAGGCUGUACAGCCAGGACCUGACGGUGGGGUGGCUUCGGGCCUUCUGCAGGUCUCCCACGUUGUGGCCCAGCAGCGCAGUCACGUUGC		32
21152	MI0007904	mml-mir-663	Macaca mulatta miR-663 stem-loop	CCGUUCGGCGUCCCAGGCGGGGCGCUGCGGGACCGCCCUCGUGUCUGUGGCGGUGGGAUCCCGUGGCCGUGUUUUCCUGGUGGCCCGGCC		32
21153	MI0007905	mml-mir-664	Macaca mulatta miR-664 stem-loop	CUGGCUAGGGAAAAUGAUUGGAUAGAAAAUGUUAUUCUAUUCAUUUAUCCCCAGCCUA		32
21154	MI0007906	mml-mir-668	Macaca mulatta miR-668 stem-loop	GGUAAGUGCGCCUCGGGUGAGCAUGCACUUAAUGUGGGUGUAUGUCACUCGGCUCGGCCCACUACC		32
21155	MI0007907	mml-mir-671	Macaca mulatta miR-671 stem-loop	GCAGGUGAACUGGCAGGCCAGGAAGAGGAGGAAGCCCUGGAGGGGCUGGAGGUGAUGGAUGUUUUCCUCCGGUUCUCAGGGCUCCACCUCUUUCGGGCCGUAGAGCCAGGGCUGGUGC		32
21156	MI0007908	mml-mir-675	Macaca mulatta miR-675 stem-loop	CCCAGGGUCUGGUGCGGAGAGGGCCCACAGUGGACUUGGUGACACUGUAUGCCCUCACCGCUCAGCCCCUGGG		32
21157	MI0007909	mml-mir-758	Macaca mulatta miR-758 stem-loop	GCCUGGAUACGUGAGAUGGUUGACCAGAGAGCACACGCUUUAUAUGUGCCGUUUGUGACCUGGUCCACUACCCCUCAGUAUCUAAUGC		32
21158	MI0007910	mml-mir-765	Macaca mulatta miR-765 stem-loop	UUUAGGGGCUGAUGAAAGUGGAGUUCAGUAGACAACCCUUUUCAAGCCCUGCAAGAAACUGGGGUUUCUGGAGGAGAGGGAAGGUGCUGAAGGGGCUGCUCUCGUGAGCCUGAA		32
21159	MI0007911	mml-mir-767	Macaca mulatta miR-767 stem-loop	GCUUUUAUAUUGUAGGUUUUUGCUCAUGCACCAUGGUUGUCUGAGCAUGCAGCAUGCUUGUCUGCUCAUACCCCAUGGUUUCUGAGCAGGAAUCUUCAUUGUCUACUGCU		32
21160	MI0007912	mml-mir-768	Macaca mulatta miR-768 stem-loop	CUGUGCUUUGUGUGUUGGAGGAUGAAAGUACGGAGUGAUCCAUCGGCUAAGUGUCUUAUCACAAUGCUGACACUCAAACUGCUGACAGCACACGUUUUUCACAG		32
21161	MI0007913	mml-mir-770	Macaca mulatta miR-770 stem-loop	AGGAGCCACCUUCCGAGCCUCCAGUACCACGUGUCAGGGCCACAUGAGCUGGGCCUCGUGGGCCUGAUGUGGUGCUGGGGCCUCAGGGGUCUGCUCUU		32
21162	MI0007914	mml-mir-802	Macaca mulatta miR-802 stem-loop	GUUCUGUUAUUUGCAAUCAGUAACAAAGAUUCAUCCUUGUGUCCAUCAUGCAGCAAGGAGAAUCUUUGUCACUUAGUGUAAUUAAUAGCUGGAC		32
21163	MI0007915	mml-mir-874	Macaca mulatta miR-874 stem-loop	UUAGCCCUGCGGCCCCACGCACCAGGGUAAGAGAGAGUCUCGCUUCCUGCCCUGGCCCGAGGGACCGACUGGCUGGGC		32
21164	MI0007916	mml-mir-875	Macaca mulatta miR-875 stem-loop	UUAGUGGUACUAUACCUCAGUUUUAUCAGGUGUUCCUAAAAUCACCUGGAAAUACUGAGGUUGUGUCUCACUGAAC		32
21165	MI0007917	mml-mir-876	Macaca mulatta miR-876 stem-loop	UGAAGUGCUGUGGAUUUCUUUGUGAAUCACCAUAUCUAAGCUAAUGUGGUGGUGGUUUACAAAGUAAUUCAUAGUGCUUCA		32
21166	MI0007918	mml-mir-877	Macaca mulatta miR-877 stem-loop	GCUAGAGAAGGUAGAGGAGAUGGCGCAGGGGACACGGGCUAAGACUCGGGGGUUCCUGGGACCCUCAGACAUGUGUCCUCUUCUCCCUCCUCCCAGGUGUAUG		32
21167	MI0007919	mml-mir-885	Macaca mulatta miR-885 stem-loop	CCGCACUCUCUCCAUUACACUACCCUGCCUCUUCUCCAUGAGAGGCAGCGGGGUGUAGUGGAUAGAGCACGGGU		32
21168	MI0007920	mml-mir-886	Macaca mulatta miR-886 stem-loop	CCGGGUCGGAGUUAGCUCAAGCGGUUACCUCCUCAUGCCGCACUUUCUAACUGUCCAUCUCUGUGCUGGGGUUCGAGACCCGCGGGUGCUUACUGACCCUUUUAUGCACUAA		32
21169	MI0007921	mml-mir-887	Macaca mulatta miR-887 stem-loop	UGCAGAUCCUUGGGAGCCCUGUUAGACUCUGGAUUUUACACUUGGAGUGAACGGGCGCCAUCCCGAGGCUUUGCACAG		32
21170	MI0007922	mml-mir-888	Macaca mulatta miR-888 stem-loop	GGCAGUGCCCUACUCAAAAAGCUGUCAGUCACUUAUGUUACAUGUGACUGACACCUCUUUAGAUGAAGGAAGGCUCA		32
21171	MI0007923	mml-mir-889	Macaca mulatta miR-889 stem-loop	GUGCUUAAAGAAUGGCUGUCCGUAGUAUGGUCUCUAUAUUUAUGAUGAUUAAUAUCGGACAACCAUUGUUUUAGUAUCC		32
21172	MI0007924	mml-mir-890	Macaca mulatta miR-890 stem-loop	UGCCCUACUUGGAAAGGCACCAGUUACUUAGAUUACACGUAACUGUUCCCUUUCUGAGUAGAGUAAGGCUUA		32
21173	MI0007925	mml-mir-891	Macaca mulatta miR-891 stem-loop	CCUUAAUCCUUGCAACUUACCUGAGUCAUUGAUUCAGUAAAACAUUCAAUGGCACAUGUUUGUUGUUAGGGUCAAAAGA		32
21174	MI0007926	mml-mir-892	Macaca mulatta miR-892 stem-loop	GCAGUGCUCUACUUAGAAAGGUGCCAGUCACUUACAUUACAUGUCACUGUGUCCUUUCUGCGUAGAGUAAGGCUC		32
21175	MI0007927	mml-mir-920	Macaca mulatta miR-920 stem-loop	GUAGUUGUUCUGCAGAAGACCUGGAUGUGGAAGAGCUAAGACACACUCCAGGGGAGCUGUAGAAGCGGUAACACG		32
21176	MI0007928	mml-mir-922	Macaca mulatta miR-922 stem-loop	UGGCGUUCUCUCUCUCCCUGUCCUGGACUGGGGUCAGACCGUGCCCCGAGGAGAAGCAGCAGAGAAUGAGACUACGUCGU		32
21177	MI0007929	mml-mir-924	Macaca mulatta miR-924 stem-loop	AAUAGAGUCUUGUGUUGUCUUGCUUAAAGGCCAUCCAACCUAGAGUCUA		32
21178	MI0007930	mml-mir-933	Macaca mulatta miR-933 stem-loop	CUUGGGUCAGUUCAGAGGUCCUCGGGGCGCGCGUCGAGUCAGCCGUGUGCGCAGGGAGACCUCUCCCACCCACAGU		32
21179	MI0007931	mml-mir-934	Macaca mulatta miR-934 stem-loop	AGGAAUAAGGCUUCUGUCUACUACUGGAGACACUGAUAGUGUAAAACCCAGAGUCUUCGGUAAUGGACGGGAGCCUUAUUUCU		32
21180	MI0007932	mml-mir-936	Macaca mulatta miR-936 stem-loop	UCAAGGACACUGGGACAGGAGAGGGAGGAAUCGCAGAAAUCACUCCAGGAGCAACUGAGAGACCUUGCUUCUACUUUACCAGGUCCUGCUGGCCCAGA		32
21181	MI0007933	mml-mir-937	Macaca mulatta miR-937 stem-loop	AGCACUGCCCCCGGUGAGUCAGGGUGGGGCUGGCCCCCUGCUUCGCGCCCAUCCGCACUCUGACUCUCCACCUGCCUGCAGGAGCU		32
21182	MI0007934	mml-mir-938	Macaca mulatta miR-938 stem-loop	GAAAGUGUACCAUGUGCACUUAAAGAUGAAGCCGGUGCACCUUCAUGAACUGUGGUACACCUUUAAGAACUUGGU		32
21183	MI0007935	mml-mir-939	Macaca mulatta miR-939 stem-loop	UGUGGGCAGGGCCCUGGGGAGCUGAGGCUCUGGGGGUGGCCGGGGCUGACCCCUGGGCCUCUGCUCCCCAGUGUCUGACCGUG		32
21184	MI0007936	mml-mir-940	Macaca mulatta miR-940 stem-loop	GUGGGGUGUGGGCCCGGCCCCAGGAGCGGGGCCUGGGCAGCCCCGUGUGUUGAGGAAGGAAGGCAGGGCCCCCGCUCCCCGGGCCUGACCCCAC		32
21185	MI0007937	mml-mir-942	Macaca mulatta miR-942 stem-loop	AUUAAGAGAGUACCUUCUCUGUUUUGGCCAUGUGUGUACUCACAGCCCCUCACACGUGGCCGAAACAGAGAAGGUACUUUCCUAAU		32
21186	MI0007938	mml-mir-944	Macaca mulatta miR-944 stem-loop	GUUCCAGACACAUCUCAUCUGAUAUACAAUAUUUUCUUAAAUUGUAAAAAGAGAAAUUAUUGUAUAUCAGAUGAGAUGUGUCUGGGGU		32
21187	MI0007939	vvi-MIR156h	Vitis vinifera miR156h stem-loop	UGCCUCACAAUGACAGAAGAGAGAGAGCAUGCUGGUGGGAAAACAAUUACAACUUUUGAUCAUCUGAUCUGGAAAUGCUUGUAAGCGGCAUUCUCUUGGAUUGUAAUCUGAAUUCUGCCUCUAUCAUCAACCUGCCCACAAACGAUUUCCUUCAACUGAGUGCCUUUCCGGCUUGAGCCUUCUGCAUGAUCAGCUGAGUUCUUUCUGCGCCUUUCAUUGUGUCCUGCC		70
21188	MI0007940	vvi-MIR169b	Vitis vinifera miR169b stem-loop	GGGGUCGAAUUGAGCCAAGGAUGGCUUGCCGUCAUCUGCAGCAAGAGUUGGAGACUUUUAACUGUGCGUGCACGGUUAGUCAUCCUUGGCUCAUUUGGCCCUUCU		70
21189	MI0007941	vvi-MIR169h	Vitis vinifera miR169h stem-loop	AGGGUGGAAUUGAGCCAAGGAUGGCUUGCCGUCCUUUGUCACUAUUUGAGGCAUUAACUGGUCACGCACGGAGGGUUAUCCUUGACUCCUUUAGCUCCUCU		70
21190	MI0007942	vvi-MIR169i	Vitis vinifera miR169i stem-loop	AGGGUGGAAUUGAGCCAAGGAUGACUGGCCGUCAUUUUUCAGUUGGUAUUUGAGGCUUUAACUGGUCAUGCACGGCUGGUUAUCCCUGUCUCCUUUAGCUCCUCU		70
21191	MI0007943	vvi-MIR169l	Vitis vinifera miR169l stem-loop	AGGGUGGAAUUGAGCCAAGGAUGACUUGCCGUCCUUUGCAUCAAGCAUUGAAGCUUUAACUGGGCAUGCACGGCUAGUUAUUCUUGGCUCAUUUGGCCCCUCU		70
21192	MI0007944	vvi-MIR169n	Vitis vinifera miR169n stem-loop	UGAGUGGAAUAGAGCCAAGGAUGACUUGCCGGCAACUGCAGCAAGGCAUAGGGUUUAACUGGUCAUAACUGGCAAGCAUCUGAGGCUCUAUUUCACCCUCU		70
21193	MI0007945	vvi-MIR169o	Vitis vinifera miR169o stem-loop	AGGGUGGAUUUGAGCCAAGGAUGACUUGCCGCCAUCAGCAGCAAGCAUUGAAGCUUUAACUGGGCAUGGACAGCGAGUUAUUCUUGGCUCAUGCGGCCCCUCU		70
21194	MI0007946	vvi-MIR169q	Vitis vinifera miR169q stem-loop	AGGGUGGAAUAGAGCCAAGGAUGACUUGCCGGCAUUUGCAGUAAGUCUAUAUUAACUGGAACAGCCGGCAUGUAAUCCUGGCUCUAUUUGGUCCUCU		70
21195	MI0007947	vvi-MIR169v	Vitis vinifera miR169v stem-loop	AGGGAGGAACAAAGCCAAGGAUGAAUUGCCGGCGAUGAAAGUAGGCAGCUUUGUCCAUGGAUCGGCAAUUUAUUUCUUGGCUAUGUUGGGCUCUCU		70
21196	MI0007948	vvi-MIR169w	Vitis vinifera miR169w stem-loop	GGUUAUGUGGUGCAGCCAAGGAUGACUUGCCGGCAACUCCCUUUAUUGUACUCAUGCAUGCUCAUACUUAUACUGUUGUGGGCAUCAUUUAAGUGGCAAAAAUGGUGGUCGGCGAGUCAUUCUUAGCUACAUUUCUGCCUCAU		70
21197	MI0007949	vvi-MIR169x	Vitis vinifera miR169x stem-loop	GUCUCGUCUGGUAGCCAAGGAUGACUUGCCUAAAUCCACCAGGUUUCAAAACACUGAAUGUAAUUAUCCACAAAGCGAUUCCGUGGUCUUUAGGCAGUCAUUCCUUCGGCUAAACUGACCGGCUC		70
21198	MI0007950	vvi-MIR171g	Vitis vinifera miR171g stem-loop	GCCAGCCUCUCCAUGUUGGUUCCAUCGGUGGGGGACACCAACUCCUUGAGCCGAACCAAUAUCACCCGAGCCAAAU		70
21199	MI0007951	vvi-MIR319e	Vitis vinifera miR319e stem-loop	UGCAGAAAUGGGGGUUCCUUUGCAGCCCAAAACAACUCCAUCGCUGAAGAAGAUGAUGAACUUCAUGCUCCUUGUUUUGGACUGAAGGGAGCUCCUAGUUCUUCUCU		70
21200	MI0007952	vvi-MIR393a	Vitis vinifera miR393a stem-loop	GGUGGACAGUUCCAAAGGGAUCGCAUUGAUCCCAUGGUUAUCUUCCACCUCUCUUACCAGACUAUCAUAACAAAGUCUGGCCUUUUUCCCAUUGGAUCAUGCUAUCCCUUAGGAACUCUCCAUCAG		70
21201	MI0007953	vvi-MIR394c	Vitis vinifera miR394c stem-loop	CAGAGCCAUUUUGGCAUUCUGUCCACCUCCAUAUAUACCAAUUCUUCUGAAUUGGCGCCCACAAGCGUUUGGAGGCGGCCAGGAUGCCAAAUUGGCUCUGUA		70
21202	MI0007954	vvi-MIR395n	Vitis vinifera miR395n stem-loop	GGCCUUGAGAGUUCCCCCAACCCCUCCAGUAUGACCAUCUCUCUUCUUCUUUUAAUUUGUUCAUCAAAUCUUCUUCUACUAUCUAUUUCCAGGGUGAUUUCCUCUACUGAAGAGUCUGGAGGAACUCUUGGUGCCAC		70
21203	MI0007955	vvi-MIR396c	Vitis vinifera miR396c stem-loop	UUCUGUGAUCUUCCACAGCUUUCUUGAACUGUUUUGGAAGCCUUCCACUUCCAUGCAAUGGAGGAGUUCAACCAACAGCUCAGGAAAGUUGUGGAACAUUACUGAGAG		70
21204	MI0007956	vvi-MIR397a	Vitis vinifera miR397a stem-loop	GAAGAAAACAUCAUUGAGUGCAGCGUUGAUGAAACUGAAGUAUUCCAUUUUUCAGCUUCUUUGAAGUCCGGCAAGAUGGGUUCUGGUUGAUUCCAUUGGCGCUGCACUCAAUCAUGUC		70
21205	MI0007957	vvi-MIR397b	Vitis vinifera miR397b stem-loop	GAAGAAAACAUCAUUGAGUGCAGCGUUGAUGAAACUGAAGUAUUCCAUUUUUCAGCUUCUUUGAAGUCCGGCAAGAUGGGUUCUGGUUGAUUCCAUUGGCGCUGCACUCAAUCAUGUC		70
21206	MI0007958	vvi-MIR398b	Vitis vinifera miR398b stem-loop	GUGUCCUACAGGUGUGACCUGAGAAUCACAUGCCCGCACCACCCAUCUUUGCUCUCAUGUGUUCUCAGGUCGCCCCUGCUGGACUCCC		70
21207	MI0007959	vvi-MIR398c	Vitis vinifera miR398c stem-loop	GUGUCCUACAGGAGUGACCUGAGAAUCACAUGCCCGCAUCACCCAUCUUUGCUCUCAUGUGUUCUCAGGUCGCCCCUGCUGGACUCCC		70
21208	MI0007960	vvi-MIR399c	Vitis vinifera miR399c stem-loop	ACCGGUCUCAGGGCCUCUUUCACUUGGUAGGUGACAUAGAUGUGAAUGAUCUGCCAAAGGAGAGUUGCCCUGUGUCUGGUUA		70
21209	MI0007961	vvi-MIR399d	Vitis vinifera miR399d stem-loop	GUAAAUUAUAGAGCAGAUUUCUUUUGGCAGAUGGCGAUCACAAGCCAAUGUGCUCAAAGGGCAUUGAGUGUGUCUGCCAAAGGAGAUUUGCUCGUGAAUUUAACU		70
21210	MI0007962	vvi-MIR399f	Vitis vinifera miR399f stem-loop	GUUGCAUUAGAGGGCCAAAUCUGCUUUGGCAUGAAGCCCAUUUAGCAGGCUCGUCUGUGUCUGCAGUCUUCUCGCUGCCGAAGGAGAUUUGUCCUGCAAUUCUUCUG		70
21211	MI0007963	vvi-MIR399i	Vitis vinifera miR399i stem-loop	AGUAGUUGUAGGGCUUCUCUCCUUCUGGCAGGAGAUGGCAAUAGAUUAUCCUUUGUGGCUUAUCUCCGGUGUUGAUUAACUUCCAAUGACCCGCCAAAGGAGAGUUGCCCUGUGACUACUUC		70
21212	MI0007964	vvi-MIR403a	Vitis vinifera miR403a stem-loop	GCACAUCUCAAGUUUGUGCGUGAAUCAAACCCCAUCGUAGCCGUCCAUAUCUUCGGGUACUAAUCACGGGGCGAUUCGACGGCGUUAGAUUCACGCACAAACUCGUGAGUUCUGA		70
21213	MI0007965	vvi-MIR403b	Vitis vinifera miR403b stem-loop	ACAAACCUCGAGUUUGUGCGCGAAUCCAACGCCUCGAUCUUCUUUCAAAGGGGUGUUAGAUUCACGCACAAACUCGGGAUCUGUCU		70
21214	MI0007966	vvi-MIR403c	Vitis vinifera miR403c stem-loop	GCACAUCUCAAGUUUGUGCGUGAAUCAAACCCCAUCGUAGCCGUCCAUAUCUUCGGGUACUAAUCACGGGGCGAUUCGACGCCGUUAGAUUCACGCACAAACUCGUGAUCUGUCC		70
21215	MI0007967	vvi-MIR403d	Vitis vinifera miR403d stem-loop	ACAAACCUCGAGUUUGUGCGCGAAUCCAACCCCUCAAUCUUCUUUCAAAGGGGUGUUAGAUUCACGCACAAACUCGGGAUCUGUCU		70
21216	MI0007968	vvi-MIR403e	Vitis vinifera miR403e stem-loop	GCACAUCUCAAGUUUGUGCGUGAAUCAAACCCCAUCGUAGCCGUCCAUAUCUUCGUGUACUAAUCACGGGGCGAUUCGACGCCGUUAGAUUCACGCACAAACUCGCGAUCUGUCC		70
21217	MI0007969	vvi-MIR403f	Vitis vinifera miR403f stem-loop	UGAGAUGAGGAGUUUGUGCGUGACUCUAAAACCGCCUGAUCUAAACCUUUUCCCGAUGCGAUACCUUUUCUAUGGUCUUAGAUUCACGCACAAACUCGUAAUCUGUCU		70
21218	MI0007970	vvi-MIR477	Vitis vinifera miR477 stem-loop	GAAGUUGUCAAUCUCCCUCAAAGGCUUCCAAUUUUCCUGGCUGAUUAUCAAGGUUGGAAAGUUGGAAGACAGUGGGGGACCUUGGAAGCUUACC		70
21219	MI0007971	vvi-MIR482	Vitis vinifera miR482 stem-loop	AAUGUUUGGGAAUUGGAGAGUAGGAAAGCUUAGCCAUCUAUUCCCUUCAUGGUUUCCUCUCCAUGGAUUGGGGGUCUAGAGCUAGUCUUUCCUACUCCUCCCAUUCCUAUUGUUUUC		70
21220	MI0007972	vvi-MIR828a	Vitis vinifera miR828a stem-loop	UAUAAAGUUUCUUGCUCAAAUGAGUAUUCCAAACAACAGCUUGUGAAGCAAUGAUUACUGUCAUAGUCUCUGCAUGUGGAUUGUUGUUGAGAUGCUCAUUUGAGGAAGCAACCUUAAAAAUG		70
21221	MI0007973	vvi-MIR828b	Vitis vinifera miR828b stem-loop	GCUCUUGGUUUCUUGCUCAAAUGAGUGUUCCACAUCAACCUGGAUAGUCAUUUCCUGCAAAACCAGGUUUCU		70
21222	MI0007974	vvi-MIR845a	Vitis vinifera miR845a stem-loop	UUUCACUUGAUUAGUUCCUUCAUGAGUUAUUGCAAGUAAUCUCCAAAUUUCCUUAGCGGAUUUACAUUGACAUAUUCUAUUAUAUUCAUUCCUAUCCAUAGCACAUUGCAAAGUAAAAACGACUUUAGCAUUUAAUUGAAAAUUUCUUCUAUCAAGCUCAUUCCAUUCUUGCUUGGGUUUUGGAACCAAAAUUCCAUCAACUAAUUUAGUGGGUAAAGUUGGGCCAUCUUCAAUGGCAUCCCAUACAUCUAAAUCAGUUGAUUGUAAGUACCAAGUCAUUCUAGCUUUCCAAUAGGGAUAGUCGGUUCCCGUAAAGAAUGGAGCUCUAUGUUUUGAACAAUUUUCAGUUUGAGAUGAGCUUGAUGGAAUAGCCAUUUUCCUCUUAGAUGAUUAAGUCUUAAGCAAGAGGUCUAGCUCUGAUACCAAUUGAUAAAACAAAGGC		70
21223	MI0007975	vvi-MIR845b	Vitis vinifera miR845b stem-loop	UUUCACUUGAUUAGUUCCUUCAUGAGUUAUUUCAAGCAAUCUCCAAAUUUCCUUAGCAGAUUUACAUUGGCAUAUUCUAUUAUAUUCAUUCCUAUCCAUAGCACAUUGCAAAGUAAAAACGACUUUAGCAUUUAAUUGAAAAUUUCUUCUAUCAAGCUCAUUCCAUUCUUGCUUGAGUUUUGGAACCAAAACUCCAUCAACUAAUUUAGUGGGAAAAGUUGGGCCAUCUUCAAUGACAUCCCAUACAUCUAAAUCAGUUGAUUGUAAGUACCAAGUCAUUCUAACUUUCCAAUAGGGAUAGUCGGUUCCCGUAAAGAAUGGAGCUCUAUGUUUUGAACAAUUUUCAGUUUGAGAUGAGCUUGAUGGAACAACCAUUUUCCUCUUAGAUGAUUAAGUCUUAAGCAAGAGGUCUAGCUCUGAUACCAAUUGAUAAAACAAAGGC		70
21224	MI0007976	vvi-MIR845c	Vitis vinifera miR845c stem-loop	CAAUUAUGUGUUUUGGUUGUCUGAGUUUCAUGUUGGCAAUUUCUUAAUGAUUAAACAUGAGGCUCUGAUACCAAUUGAUGCAUAAACCAU		70
21225	MI0007977	vvi-MIR845d	Vitis vinifera miR845d stem-loop	AUAACCAACAUUAAUUAUCCCUAGGGCCAUGGGAUAAACAAAAACUCUGCAAAACCAAGUUAGCACACCCUAGAAUGGUUCUAGCACAAUUACUAACCUAUGGCUCUGAUACCAAUUGAUGGGAAAAACCU		70
21226	MI0007978	vvi-MIR845e	Vitis vinifera miR845e stem-loop	AGAACGCACAUUAAUUAUCCCUAGGGCCAUGGGAUAAACAAAAACCUUGAAAAAACAAGUUAGCACACCCUAGAAUGGUUCUAGCACGAUUACUAACCUAUGGCUCUGAUACCAAUUGAUGGGAAAAACUC		70
21227	MI0007979	cel-mir-1817	Caenorhabditis elegans miR-1817 stem-loop	UGUACAUUUCAAUUUUCGAGUAGCCAAUGUCUUCUCUAUCAUGCAUUUUACAAAUAAUGAGUACAUGAUAGUGAAAUAUUUGCUUCCUGAAUUUCAGAGAUGUUU	This sequence was erroneously named mir-801 in [1]. 	3
21228	MI0007980	cel-mir-1818	Caenorhabditis elegans miR-1818 stem-loop	CUGGAAAGAGUGGCCUUUUGUGGUCUUCAUGCCAUGAUUUUAUCACUCAAACUGAUAAAAUCAUAGUUUGGAAACCUCGACAGGCUUUUCUUUUCUU	This sequence was erroneously named mir-802 in [1]. 	3
21229	MI0007981	cel-mir-1819	Caenorhabditis elegans miR-1819 stem-loop	AAUCAGUGAUCAAUCAUGCUCAAAACAUUCGACAUAACUUAAUUUCUUUGUGGAAUGAUUGAGCUUGAUGGAUCGAUGAAA	This sequence was erroneously named mir-804 in [1]. 	3
21230	MI0007982	cel-mir-1820	Caenorhabditis elegans miR-1820 stem-loop	UUCAAAAAUUGCAUUUUCCAUCUUUUGAUUGUUUUUCGAUGAUGUUCGUUAAAUCGGUAUAAGCGAACCAUUGUAAACAAUCAAAGAAUGGAGAAUCAAUUUAUGAU	This sequence was erroneously named mir-805 in [1]. 	3
21231	MI0007983	cel-mir-1821	Caenorhabditis elegans miR-1821 stem-loop	AUAUGUAGUUGGUACAAGUUUGCCCAACUUGCAGACUUUUCAAUUUUCGGCAAGUGGAAUUGAGGUCUUAUAGUUAGGUAGACAUUUACUACAACUAAUAUAUA	This sequence was erroneously named mir-806 in [1]. 	3
21232	MI0007984	cel-mir-1822	Caenorhabditis elegans miR-1822 stem-loop	AUUCUUGAAAACUCCAAUAGUUUCUCUGGGAAAGCUAUCGGCCAAAUUUAACUGUCCGAGCUGCCCUCAGAAAAACUCUUGGCUCAUCGAGAAA	This sequence was erroneously named mir-807 in [1]. 	3
21233	MI0007985	cel-mir-1823	Caenorhabditis elegans miR-1823 stem-loop	CUUUGACCUGAACGUCACCCCUAACCCUAUGCAGUAUUUGGAGCUCAUAAAAUACUGGAAGUGUUUAGGAGUAAUGCUCAGUUGUCAGAA	This sequence was erroneously named mir-808 in [1]. 	3
21234	MI0007986	cel-mir-1824	Caenorhabditis elegans miR-1824 stem-loop	GUUCACCAGAGUUGGCAGUGUUUCUCCCCCAACUUUUGUUACAGAAUUGCAAAAAUGUUGGCCGUGGUGAACACUUCCGCCUCUGGUUUGAAG	This sequence was erroneously named mir-809 in [1]. 	3
21235	MI0007987	cfa-mir-216	Canis familiaris miR-216 stem-loop	AAAUCUCUGCAGGCAAAUGUGAUGUCACUAAAGAAAUCACACACUUACCCGUAGAGAUUCUG		20
21236	MI0007988	cfa-mir-33	Canis familiaris miR-33 stem-loop	GUGCAUUGUAGUUGCAUUGCAUGUUCUGGCGGUACCCGUGCAAUGUUUCCACAGUGCAUCA		20
21237	MI0007989	cfa-let-7a	Canis familiaris let-7a stem-loop	UGAGGUAGUAGGUUGUAUAGUUUGGGGCUCUGCCCUGCUCUGGGUAACUAUACAAUCUACUGUCUUUCC		20
21238	MI0007990	cfa-mir-26a-2	Canis familiaris miR-26a-2 stem-loop	UUCAAGUAAUCCAGGAUAGGCUGUUUCCGUCUGUGAGGCCUAUUCUUGAUUACUUGUUUC		20
21239	MI0007991	cfa-mir-1835	Canis familiaris miR-1835 stem-loop	UGCACCCUGAGAGCUGGAGCAGGUCUCUUACGGGAACCAUCUUCAACUCUGUGGAUGCAGG		20
21240	MI0007992	cfa-mir-32	Canis familiaris miR-32 stem-loop	UAUUGCACAUUACUAAGUUGCAUGUUGUCACGGCCUCAAUGCAAUUUAGUGUGUGUGAUAUU		20
21241	MI0007993	cfa-mir-204	Canis familiaris miR-204 stem-loop	UUCCCUUUGUCAUCCUAUGCCUGAGAAUAUAUGAAGGAGGCUGGGAAGGCAAAGGGACGU		20
21242	MI0007994	cfa-mir-31	Canis familiaris miR-31 stem-loop	AGGCAAGAUGCUGGCAUAGCUGUUGAACUGAGAACCUGCUAUGCCAACAUAUUGCCAUC		20
21243	MI0007995	cfa-mir-101-2	Canis familiaris miR-101-2 stem-loop	GGUUAUCAUGGUACCGAUGCUGUAUAUCUGAAAGGUACAGUACUGUGAUAACUGA		20
21244	MI0007997	cfa-mir-491	Canis familiaris miR-491 stem-loop	GUGGGGAACCCUUCCAUGAGGAGUAGAACACUCCUUAUGCAAGAUUCCCUUCUA		20
21245	MI0007998	cfa-mir-150	Canis familiaris miR-150 stem-loop	UCUCCCAACCCUUGUACCAGUGCUGUGCCUCAGUCCCUGGUACAGGCAUGGGGGGCA		20
21246	MI0007999	cfa-mir-455	Canis familiaris miR-455 stem-loop	UAUGUGCCUUUGGACUACAUCGUGGAAGCCAGCACCAUGCAGUCCAUGGGCAUAUACA		20
21247	MI0008000	cfa-mir-30a	Canis familiaris miR-30a stem-loop	UGUAAACAUCCUCGACUGGAAGCUGUGAAGCCACAGAUGGGCUUUCAGUCGGAUGUUUGCAGC		20
21248	MI0008001	cfa-mir-30c-2	Canis familiaris miR-30c-2 stem-loop	UGUAAACAUCCUACACUCUCAGCUGUGGAAAGUAAGAAAGCUGGGAGAAGGCUGUUUACUCU		20
21249	MI0008002	cfa-mir-206	Canis familiaris miR-206 stem-loop	ACAUGCUUCUUUAUAUCCCCAUACGGAUUACGUUGCUAUGGAAUGUAAGGAAGUGUGUGG		20
21250	MI0008003	cfa-mir-99b	Canis familiaris miR-99b stem-loop	CACCCGUAGAACCGACCUUGCGGGGCCUUCGCCGCACACAAGCUCGAGUCUGUGGGUCUG		20
21251	MI0008004	cfa-let-7e	Canis familiaris let-7e stem-loop	UGAGGUAGGAGGUUGUAUAGUUGAGGAGGACACCCACGGAGAUCACUAUACGGCCUCCUAGCUUUCC		20
21252	MI0008005	cfa-mir-125a	Canis familiaris miR-125a stem-loop	UCCCUGAGACCCUUUAACCUGUGAGGACAUCCAGGGUCACAGGUGAGGUUCUUGGGAGCC		20
21253	MI0008006	cfa-let-7f	Canis familiaris let-7f stem-loop	UGAGGUAGUAGAUUGUAUAGUUGUGGGGUAGUGAUUUUACCCUGUUCAGGAGAUAACUAUACAAUCUAUUGCCUUCCC		20
21254	MI0008007	cfa-mir-219-1	Canis familiaris miR-219-1 stem-loop	UGAUUGUCCAAACGCAAUUCUCGAGUCUCUGGCUCUGGCCGAGAGUUGAGUCUGGACGUCCCG		20
21255	MI0008008	cfa-mir-23b	Canis familiaris miR-23b stem-loop	GUUCCUGGCAUGCUGAUUUGUGACUUAAGAUUAAAAUCACAUUGCCAGGGAUUA		20
21256	MI0008009	cfa-mir-27b	Canis familiaris miR-27b stem-loop	AGAGCUUAGCUGAUUGGUGAACAGUGACUGGUUUCCGCUUUGUUCACAGUGGCUAAGUUCUGC		20
21257	MI0008010	cfa-mir-24-1	Canis familiaris miR-24-1 stem-loop	GGUGCCUACUGAGCUGAUAUCAGUUCUCAUUGUACACACUGGCUCAGUUCAGCAGGAACAGG		20
21258	MI0008011	cfa-mir-151	Canis familiaris miR-151 stem-loop	UCGAGGAGCUCACAGUCUAGUAUGUCUCAGCCCUACUAGACUGAGGCUCCUUGAGG		20
21259	MI0008012	cfa-mir-30d	Canis familiaris miR-30d stem-loop	UGUAAACAUCCCCGACUGGAAGCUGGAAGACAGCAAAGCUUUCAGUCAGAUGUUUGCUGC		20
21260	MI0008013	cfa-mir-30b	Canis familiaris miR-30b stem-loop	UGUAAACAUCCUACACUCAGCUGUAGUACAUGGAUUGGCUGGGAGGUGGAUGUUUACUUC		20
21261	MI0008014	cfa-mir-1836	Canis familiaris miR-1836 stem-loop	UAGGCCAUGGUAGAUAGAGAUGGAGUAACCAUUUCAUCUCAUCUGCACUGCCCAGAC		20
21262	MI0008015	cfa-mir-122	Canis familiaris miR-122 stem-loop	UGGAGUGUGACAAUGGUGUUUGUGUCCAAACUAUCAAACGCCAUUAUCACACUAAAUA		20
21263	MI0008016	cfa-mir-196b	Canis familiaris miR-196b stem-loop	UAGGUAGUUUCCUGUUGUUGGGAUCCACCUUUCUCUCGACAGCACGACACUGCCUUCA		20
21264	MI0008017	cfa-mir-183	Canis familiaris miR-183 stem-loop	UAUGGCACUGGUAGAAUUCACUGUGAACAGUCUCGGUCAGUGAAUUACCGAAGGGCCAUAAA		20
21265	MI0008018	cfa-mir-148a	Canis familiaris miR-148a stem-loop	AAAGUUCUGAGACACUCCGACUCUGAAUAUGAUAGAAGUCAGUGCACUACAGAACUUUGU		20
21266	MI0008019	cfa-mir-129-1	Canis familiaris miR-129-1 stem-loop	CUUUUUGCGGUCUGGGCUUGCUGUUCCUCUCAACAGUAGUCAGGAAGCCCUUACCCCAAAAAGUA		20
21267	MI0008020	cfa-mir-335	Canis familiaris miR-335 stem-loop	UCAAGAGCAAUAACGAAAAAUGUUUGUCAUAAACCGUUUUUCAUUAUUGCUCCUGACC		20
21268	MI0008021	cfa-mir-29b-1	Canis familiaris miR-29b-1 stem-loop	AGCUGGUUUCAUAUGGUGGUUUAGAUUUAAAUAGUGAUUGUCUAGCACCAUUUGAAAUCAGUGUU		20
21269	MI0008022	cfa-mir-29a	Canis familiaris miR-29a stem-loop	ACUGAUUUCUUUUGGUGUUCAGAGUCAAUAUAAUUUUCUAGCACCAUCUGAAAUCGGUUA		20
21270	MI0008023	cfa-mir-30e	Canis familiaris miR-30e stem-loop	UGUAAACAUCCUUGACUGGAAGCUGUAAGGUGCUCAGAGGGGCUUUCAGUCGGAUGUUUACAGC		20
21271	MI0008024	cfa-mir-30c-1	Canis familiaris miR-30c-1 stem-loop	UGUAAACAUCCUACACUCUCAGCUGUGAGCUCAAGGUGGCUGGGAGAGGGUUGUUUACUCC		20
21272	MI0008025	cfa-mir-135	Canis familiaris miR-135 stem-loop	UUAUGGCUUUUUAUUCCUAUGUGAUAGUAAUAAAGUCUCAUGUAGGGAUGGAAGCCAUGAAA		20
21273	MI0008026	cfa-mir-383	Canis familiaris miR-383 stem-loop	AGAUCAGAAGGUGAUUGUGGCUUUGGGUGGAUAUUAAUCAGCCACAGCACUGCCUGGUCAGA		20
21274	MI0008028	cfa-mir-1837	Canis familiaris miR-1837 stem-loop	AUGUGAUGGCUCUUCUGAGAAGUACUUCGAUGGCUCCUCUCAGAGGGACUGCGACAUCU		20
21275	MI0008029	cfa-mir-130a	Canis familiaris miR-130a stem-loop	GCUCUUUUCACAUUGUGCUACUGUCUGCACCUACCACUAGCAGUGCAAUGUUAAAAGGGCAU		20
21276	MI0008030	cfa-mir-129-2	Canis familiaris miR-129-2 stem-loop	CUUUUUGCGGUCUGGGCUUGCUGUACAUAACUCGAUAGCCGGAAGCCCUUACCCCAAAAAGCA		20
21277	MI0008031	cfa-mir-192	Canis familiaris miR-192 stem-loop	CUGACCUAUGAAUUGACAGCCAGUGCUCUCAUCUCUCCUCUGGCUGCCAAUUCCAUAGGUCACAG		20
21278	MI0008032	cfa-mir-128-1	Canis familiaris miR-128-1 stem-loop	CGGGGCCGUAGCACUGUCUGAGAGGUUUACAUUUCUCACAGUGAACCGGUCUCUUU		20
21279	MI0008033	cfa-mir-7-1	Canis familiaris miR-7-1 stem-loop	UGGAAGACUAGUGAUUUUGUUGUUUUUAGAUAACUAAAUCGACAACAAAUCACAGUCUGCCAUA		20
21280	MI0008034	cfa-mir-181c	Canis familiaris miR-181c stem-loop	AACAUUCAACCUGUCGGUGAGUUUGGGCAGCUCAGGCAAACCAUCGACCGUUGAGUGGACC		20
21281	MI0008035	cfa-mir-181d	Canis familiaris miR-181d stem-loop	AACAUUCAUUGUUGUCGGUGGGUUGUGAGGACGGAGGCCAGACCCACCGAGGGAUGAAUGUCAC		20
21282	MI0008036	cfa-let-7g	Canis familiaris let-7g stem-loop	UGAGGUAGUAGUUUGUACAGUUUGAGGGUCUAUGAUACCACCCGGUACAGGAGAUAACUGUACAGGCCACUGCCUUGCC		20
21283	MI0008037	cfa-mir-191	Canis familiaris miR-191 stem-loop	CAACGGAAUCCCAAAAGCAGCUGUUGUCUCCAGAGCAUUCCAGCUGCGCUUGGAUUUCGUUCCC		20
21284	MI0008038	cfa-mir-425	Canis familiaris miR-425 stem-loop	AAUGACACGAUCACUCCCGUUGAGUGGGCACCCAAGAAGCCAUCGGGAAUGUCGUGUCCGCCC		20
21285	MI0008039	cfa-mir-23a	Canis familiaris miR-23a stem-loop	GUUCCUGGGGAUGGGAUUUGCUGCCUGUCACAAAUCACAUUGCCAGGGAUUU		20
21286	MI0008040	cfa-mir-27a	Canis familiaris miR-27a stem-loop	GGGCUUAGCUGCUUGUGAGCAGAGUCCACACCAAGUCGUGUUCACAGUGGCUAAGUUCCG		20
21287	MI0008041	cfa-mir-24-2	Canis familiaris miR-24-2 stem-loop	CGUGCCUACUGAGCUGAAACACAGUUGAUUUGUGCAGACUGGCUCAGUUCAGCAGGAACAGG		20
21288	MI0008042	cfa-mir-199-1	Canis familiaris miR-199-1 stem-loop	CCAGUGUUCAGACUACCUGUUCAGGGGGCUCUGAAUGUGUACAGUAGUCUGCACAUUGGUU		20
21289	MI0008043	cfa-mir-708	Canis familiaris miR-708 stem-loop	AAGGAGCUUACAAUCUAGCUGGGGGUGAACGGCUUGCACAUGAACGCAACUAGACUGUGAGCUUCUAGA		20
21290	MI0008044	cfa-mir-1838	Canis familiaris miR-1838 stem-loop	CCACCAGCUGGCGUUCCCUGGCGUGGGAACGAGAGGCAGGGGCUGCUGGCUGGAGGGA		20
21291	MI0008045	cfa-mir-139	Canis familiaris miR-139 stem-loop	CUACAGUGCACGUGUCUCCAGUGUGGCUCCGAGGCUGGAGACGCGGCCCUGUUGGAA		20
21292	MI0008047	cfa-mir-138b	Canis familiaris miR-138b stem-loop	AGCUGGUGUUGUGAAUCAUGCCGACGAGCAGCGCAUCCUCUUACCCGGCUAUUUCACGACACCAGGGUU		20
21293	MI0008048	cfa-mir-15a	Canis familiaris miR-15a stem-loop	UAGCAGCACAUAAUGGUUUGUGGAUUUUGAAAAGGUGCAGGCCAUAUUGUGCUGCCUCA		20
21294	MI0008049	cfa-mir-16-1	Canis familiaris miR-16-1 stem-loop	UAGCAGCACGUAAAUAUUGGCGUUAAGAUUCUAAAAUUAUCUCCAGUAUUAACUGUGCUGCUGAA		20
21295	MI0008050	cfa-mir-17	Canis familiaris miR-17 stem-loop	CAAAGUGCUUACAGUGCAGGUAGUGAUAUGUGCAUCUACUGCAGUGAAGGCACUUGUAG		20
21296	MI0008051	cfa-mir-19a	Canis familiaris miR-19a stem-loop	AGUUUUGCAUAGUUGCACUACAAGAAGAAUGUAGUUGUGCAAAUCUAUGCAAAACUGA		20
21297	MI0008052	cfa-mir-20	Canis familiaris miR-20 stem-loop	UAAAGUGCUUAUAGUGCAGGUAGUGUUUCGUUAUCUACUGCAUUAUGAGCACUUAAAGU		20
21298	MI0008054	cfa-mir-19b-1	Canis familiaris miR-19b-1 stem-loop	GUUUUGCAGGUUUGCAUCCAGCUGUGUGAUAUUCUGCUGUGCAAAUCCAUGCAAAACUG		20
21299	MI0008055	cfa-mir-92a-1	Canis familiaris miR-92a-1 stem-loop	AGGUUGGGAUCGGUUGCAAUGCUGUGUUUCUGUAUGGUAUUGCACUUGUCCCGGCCUGU		20
21300	MI0008056	cfa-mir-138a	Canis familiaris miR-138a stem-loop	AGCUGGUGUUGUGAAUCAGGCCGUUGCCAAUCAGAGAACGGCUACUUCACAACACCAGGGUC		20
21301	MI0008057	cfa-mir-128-2	Canis familiaris miR-128-2 stem-loop	GGGGGCCGAUACACUGUACGAGAGUGAGUAGCAGGUCUCACAGUGAACCGGUCUCUUU		20
21302	MI0008058	cfa-mir-26a-1	Canis familiaris miR-26a-1 stem-loop	UUCAAGUAAUCCAGGAUAGGCUGUGCAGGUCCCAAUGGGCCUAUUCUUGGUUACUUGCACG		20
21303	MI0008059	cfa-mir-499	Canis familiaris miR-499 stem-loop	UUAAGACUUGCAGUGAUGUUUAACUCCUCUCCACGUGAACAUCACAGCAAGUCUGUGCU		20
21304	MI0008060	cfa-mir-1-1	Canis familiaris miR-1-1 stem-loop	CAUACUUCUUUAUAUGCCCAUAUGGACCUGCUAAGCUAUGGAAUGUAAAGAAGUAUGUA		20
21305	MI0008061	cfa-mir-124-5	Canis familiaris miR-124-5 stem-loop	GUGUUCACAGCGGACCUUGAUUUAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCA		20
21306	MI0008062	cfa-mir-124-1	Canis familiaris miR-124-1 stem-loop	GUGUUCACAGCGGACCUUGAUUUAAAUGUCCAUACAAUUAAGGCACGCGGUGAAUGCCA		20
21307	MI0008063	cfa-mir-320	Canis familiaris miR-320 stem-loop	GCCUUCUCUUCCCGGUUCUUCCCGGAGUCGGGAAAAGCUGGGUUGAGAGGGCGA		20
21308	MI0008064	cfa-mir-130b	Canis familiaris miR-130b stem-loop	ACUCUUUCCCUGUUGCACUACUGUGGGCCGCUGGGAAGCAGUGCAAUGAUGAAAGGGCAU		20
21309	MI0008065	cfa-mir-185	Canis familiaris miR-185 stem-loop	UGGAGAGAAAGGCAGUUCCUGAUGGUCCCCUCCCCAGGGGCUGGCUUUCCUCUGGU		20
21310	MI0008066	cfa-mir-1306	Canis familiaris miR-1306 stem-loop	CCACCUCCCCUGCAAACGUCCAGUGAUGCAGAGGUAAUGGACGUUGGCUCUGGUGGUG		20
21311	MI0008068	cfa-mir-196a	Canis familiaris miR-196a stem-loop	UAGGUAGUUUCAUGUUGUUGGGAUUGAGUUUUGAACUCGGCAACAAGAAACUGCCUGAG		20
21312	MI0008069	cfa-mir-148b	Canis familiaris miR-148b stem-loop	GAAGUUCUGUUAUACACUCAGGCUGUGGCUCUCUGAAAGUCAGUGCAUCACAGAACUUUGU		20
21313	MI0008070	cfa-mir-200c	Canis familiaris miR-200c stem-loop	CGUCUUACCCAGCAGUGUUUGGGUGCUGGUUGGGAGUCUCUAAUACUGCCGGGUAAUGAUGGA		20
21314	MI0008071	cfa-mir-1307	Canis familiaris miR-1307 stem-loop	CGACCGGACCUCGACCGGCUCGUCUAUGUUGCCAAUCGACUCGGCGUGGCGUCGGUCGUG		20
21315	MI0008072	cfa-mir-107	Canis familiaris miR-107 stem-loop	AGCUUCUUUACAGUGUUGCCUUGUGGCAUGGAGUUCAAGCAGCAUUGUACAGGGCUAU		20
21316	MI0008073	cfa-mir-146b	Canis familiaris miR-146b stem-loop	UGAGAACUGAAUUCCAUAGGCUGUGAGCUUGAGCAAACAGCCUAGGGACUCAGUUCUGGUG		20
21317	MI0008074	cfa-mir-124-2	Canis familiaris miR-124-2 stem-loop	GUGUUCACAGCGGACCUUGAUUUAAUGUCAUACAAUUAAGGCACGCGGUGAAUGCCA		20
21318	MI0008075	cfa-mir-99a-1	Canis familiaris miR-99a-1 stem-loop	AACCCGUAGAUCCGAUCUUGUGGUGAAGUGGACGGCACAAGCUCGCUUCUAUGGGUCUG		20
21319	MI0008076	cfa-let-7c	Canis familiaris let-7c stem-loop	UGAGGUAGUAGGUUGUAUGGUUUAGAGUUACACCCUGGGAGUUAACUGUACAACCUUCUAGCUUUCC		20
21320	MI0008077	cfa-mir-125b-2	Canis familiaris miR-125b-2 stem-loop	UCCCUGAGACCCUAACUUGUGAGGUAUUUUAGUAACAUCACAAGUCAGGCUCUUGGGACCU		20
21321	MI0008078	cfa-mir-155	Canis familiaris miR-155 stem-loop	UUAAUGCUAAUCGUGAUAGGGGUUUUUACCUCCGACUGACUCCUACAUGUUAGCAUUAACA		20
21322	MI0008079	cfa-mir-218-1	Canis familiaris miR-218-1 stem-loop	UUGUGCUUGAUCUAACCAUGUGGUUGCCAGGUAUGAGUAAAACAUGGUUCCGUCAAGCACCAUG		20
21323	MI0008080	cfa-mir-574	Canis familiaris miR-574 stem-loop	UGAGUGUGUGUGUGUGAGUGUGUGUCGCUCCGGGUCCACGCUCAUGCACACACCCACA		20
21324	MI0008081	cfa-mir-9-2	Canis familiaris miR-9-2 stem-loop	UCUUUGGUUAUCUAGCUGUAUGAGUGUAUUGGUCUUCAUAAAGCUAGAUAACCGAAAGUA		20
21325	MI0008082	cfa-mir-28	Canis familiaris miR-28 stem-loop	AAGGAGCUCACAGUCUAUUGAGUUGCCUUUCUGACUUUCCCACUAGAUUGUGAGCUCCUGGA		20
21326	MI0008083	cfa-mir-15b	Canis familiaris miR-15b stem-loop	UAGCAGCACAUCAUGGUUUACAUACUACAGUCAAGAUGCGAAUCAUUAUUUGCUGCUCUA		20
21327	MI0008084	cfa-mir-16-2	Canis familiaris miR-16-2 stem-loop	UAGCAGCACGUAAAUAUUGGCGUAGUGAAAUAAAAAUUAAACACCAAUAUUAUUGUGCUGCUUUA		20
21328	MI0008085	cfa-mir-7-2	Canis familiaris miR-7-2 stem-loop	UGGAAGACUAGUGAUUUUGUUGUUGUCUCACUGCAUCCAACAACAAGUCCCAGUCUGCCACA		20
21329	MI0008086	cfa-mir-9-3	Canis familiaris miR-9-3 stem-loop	UCUUUGGUUAUCUAGCUGUAUGAGUGCCACAGAGCCGUCAUAAAGCUAGAUAACCGAAAGU		20
21330	MI0008087	cfa-mir-1839	Canis familiaris miR-1839 stem-loop	AAGGUAGAUAGAACAGGUCUUGUUAGCAAAAUAAAUUCAAGACCUACUUAAUCUACCAACA		20
21331	MI0008088	cfa-mir-26b	Canis familiaris miR-26b stem-loop	UUCAAGUAAUUCAGGAUAGGUUGUGUGCUGUCCAGCCUGUUCUCCAUUACUUGGCU		20
21332	MI0008089	cfa-mir-1840	Canis familiaris miR-1840 stem-loop	UUAGGGCGCGUCACGUGACGGGCUCGUCGCUCCGCCGUCACGUGACGGGCCUCGGCG		20
21333	MI0008090	cfa-mir-664	Canis familiaris miR-664 stem-loop	UGGGCUAGGAAAAAUGAUUGGAUAAAAAAUAUUAUUCUAUUCAUUUAUCUCCCAGCCUACA		20
21334	MI0008091	cfa-mir-194	Canis familiaris miR-194 stem-loop	UGUAACAGCAACUCCAUGUGGAUUGUGUGCCAAUUUCCAGUGGAGAUGCUGUUACUUU		20
21335	MI0008092	cfa-mir-143	Canis familiaris miR-143 stem-loop	GGUGCAGUGCUGCAUCUCUGGUCAGUUGGGAGUCUGAGAUGAAGCACUGUAGCUC		20
21336	MI0008093	cfa-mir-378	Canis familiaris miR-378 stem-loop	CUCCUGACUCCAGGUCCUGUGUGUUACCUCGAAAUAGCACUGGACUUGGAGUCAGAAGGC		20
21337	MI0008094	cfa-mir-146a	Canis familiaris miR-146a stem-loop	UGAGAACUGAAUUCCAUGGGUUGUGUCAGUGUCAGACCUGUGAAGUUCAGUUCUUCAG		20
21338	MI0008095	cfa-mir-1271	Canis familiaris miR-1271 stem-loop	CUUGGCACCUAGUAAGCACUCAGUAAAUACUUGUUGAGUGCCUGCUAUGUGCCAGGCA		20
21339	MI0008096	cfa-mir-1841	Canis familiaris miR-1841 stem-loop	AGAGGAAAGCUGGACGGCAAGCCUGAAGGGAAGAAGGUGGCUCCGUCCUCUUUCCAAGCC		20
21340	MI0008097	cfa-mir-218-2	Canis familiaris miR-218-2 stem-loop	UUGUGCUUGAUCUAACCAUGUGGUGGAACGAUGGAAACGGAACAUGGUUCUGUCAAGCACCGCG		20
21341	MI0008098	cfa-mir-103	Canis familiaris miR-103 stem-loop	UCGGCUUCUUUACAGUGCUGCCUUGUUGCAUAUGGAUCAAGCAGCAUUGUACAGGGCUAUGA		20
21342	MI0008099	cfa-mir-328	Canis familiaris miR-328 stem-loop	AGGGGGGCAGGAAGGGCUCAGGGAGAAAGUGUGUGCAGCCCCUGGCCCUCUCUGCCCUUCCGU		20
21343	MI0008100	cfa-mir-140	Canis familiaris miR-140 stem-loop	CAGUGGUUUUACCCUAUGGUAGGUUACGUCAUGCUGUUCUACCACAGGGUAGAACCACGGA		20
21344	MI0008101	cfa-mir-34a	Canis familiaris miR-34a stem-loop	UGGCAGUGUCUUAGCUGGUUGUUGUGAGUAAUAGUGAAGGAAGCAAUCAGCAAGUAUACUGCCCUA		20
21345	MI0008102	cfa-mir-99a-2	Canis familiaris miR-99a-2 stem-loop	AACCCGUAGAUCCGAUCUUGUGGUGAUAGUCCACACAAGCUUGUGUCUAUAGGUAUG		20
21346	MI0008103	cfa-mir-125b-1	Canis familiaris miR-125b-1 stem-loop	UCCCUGAGACCCUAACUUGUGAUGUUUACCGUUUAAAUCCACGGGUUAGGCUCUUGGGAGC		20
21347	MI0008104	cfa-mir-497	Canis familiaris miR-497 stem-loop	CAGCAGCACACUGUGGUUUGUACGGUACUGUGGCCACGUCCAGACCACACUGUGGUGUUAGGGUGAG		20
21348	MI0008105	cfa-mir-195	Canis familiaris miR-195 stem-loop	UAGCAGCACAGAAAUAUUGGCACUGGGAAGAGAGUCUGCCAAUAUUGGCUGUGCUGCUCUA		20
21349	MI0008106	cfa-mir-34c	Canis familiaris miR-34c stem-loop	AGGCAGUGUAGUUAGCUGAUUGCUAAUAGUACCAAUCACUAACCACACGGCCAGG		20
21350	MI0008107	cfa-mir-101-1	Canis familiaris miR-101-1 stem-loop	AGUUAUCACAGUGCUGAUGCUGUCCAUUCUAAAGGUACAGUACUGUGAUAACUGA		20
21351	MI0008108	cfa-mir-186	Canis familiaris miR-186 stem-loop	CAAAGAAUUCUCCUUUUGGGCUUUCUGAUUUUAUUUUAAGCCCAAAGGUGAAUUUUUUGGG		20
21352	MI0008109	cfa-mir-106b	Canis familiaris miR-106b stem-loop	UAAAGUGCUGACAGUGCAGAUAGCGGUCCUCCGUGCUACCGCACUGUGGGUACUUGCUG		20
21353	MI0008110	cfa-mir-93	Canis familiaris miR-93 stem-loop	CAAAGUGCUGUUCGUGCAGGUAGUGUGAUUACCUGACCUACUGCUGAGCUAGCACUUCCCG		20
21354	MI0008111	cfa-mir-25	Canis familiaris miR-25 stem-loop	AGGCGGAGACUUGGGCAAUUGCUGGACGCUGCCCGCGCAUUGCACUUGUCUCGGUCUGA		20
21355	MI0008112	cfa-mir-197	Canis familiaris miR-197 stem-loop	CGGGUAGAGAGGGCAGUGGGAGGUAAGAGCUCUUCACCCUUCACCACCUUCUCCACCCAGC		20
21356	MI0008113	cfa-mir-193b	Canis familiaris miR-193b stem-loop	CGGGGUUUUGAGGGCGAGAUGAGUUUAUGUUUGAUCCAACUGGCCCACAAAGUCCCGCU		20
21357	MI0008114	cfa-mir-590	Canis familiaris miR-590 stem-loop	GAGCUUAUUCAUAAAAGUACAGUAUGAUCCAGUAAACCUGUAAUUUUAUGUAUAAGCUAGU		20
21358	MI0008116	cfa-mir-1842	Canis familiaris miR-1842 stem-loop	UGGCUCUGCGAGGUCAGCUCAAGGUGGGUCUGGAUAUUGAGCAGGCCUGUCAGGGCGUUG		20
21359	MI0008117	cfa-mir-137	Canis familiaris miR-137 stem-loop	GGGUAUUCUUGGGUGGAUAAUACGGAUUACGUUGUUAUUGCUUAAGAAUACGCGU		20
21360	MI0008118	cfa-mir-1-2	Canis familiaris miR-1-2 stem-loop	CAUACUUCUUUAUGUACCCAUAUGAACAUACAAUGCUAUGGAAUGUAAAGAAGUAUGUA		20
21361	MI0008119	cfa-mir-92b	Canis familiaris miR-92b stem-loop	AGGGACGGGACGCGGUGCAGUGUUGUUCUCUCCCCCGCCAAUAUUGCACUCGUCCCGGCCUCC		20
21362	MI0008120	cfa-mir-350	Canis familiaris miR-350 stem-loop	AGUGCACGCGCUUUGGGACAGUGAAGAAAAUAAUGUUCACAAAGCCCAUACACUUUU		20
21363	MI0008121	cfa-mir-29b-2	Canis familiaris miR-29b-2 stem-loop	AGCUGGUUUCACAUGGUGGCUUAGAUUUUUCCAUCUUUGUAUCUAGCACCAUUUGAAAUCAGUGUU		20
21364	MI0008122	cfa-mir-29c	Canis familiaris miR-29c stem-loop	ACCGAUUUCUCCUGGUGUUCAGAGUCUGUUUUUGUCUAGCACCAUUUGAAAUCGGUUA		20
21365	MI0008123	cfa-mir-1843	Canis familiaris miR-1843 stem-loop	ACUGGAGGUCUCUGUCUGGCUUAGGACAGCUGGCUAAGUCUGAUCGUUCCCCUCCAUACA		20
21366	MI0008124	cfa-mir-199-2	Canis familiaris miR-199-2 stem-loop	CCAGUGUUCAGACUACCUGUUCAGGACAAUGCCGUUGUACAGUAGUCUGCACAUUGGUU		20
21367	MI0008125	cfa-mir-9-1	Canis familiaris miR-9-1 stem-loop	UCUUUGGUUAUCUAGCUGUAUGAGUGGUGUGGAGUCUUCAUAAAGCUAGAUAACCGAAAGUA		20
21368	MI0008126	cfa-mir-181a-1	Canis familiaris miR-181a-1 stem-loop	AACAUUCAACGCUGUCGGUGAGUUUGGAAUUAAAAUCAAAACCAUCGACCGUUGAUUGUACC		20
21369	MI0008127	cfa-mir-181b-1	Canis familiaris miR-181b-1 stem-loop	AACAUUCAUUGCUGUCGGUGGGUUGAACUGUGUGGACAAGCUCACUGAACAAUGAAUGCAAC		20
21370	MI0008128	cfa-mir-342	Canis familiaris miR-342 stem-loop	GGGUGCUAUCUGUGAUUGAGGGACAUGGCAAAUAGAAUUGUCUCACACAGAAAUCGCACCCGU		20
21371	MI0008129	cfa-mir-345	Canis familiaris miR-345 stem-loop	UGCUGACUCUUAGUCCAGUGCUCGUGAUGGCUGGUGGGCCCUGAACUAGGGGUCUGGAGG		20
21372	MI0008130	cfa-mir-493	Canis familiaris miR-493 stem-loop	UGUACAUGGUAGGCUUUCAUUCAUUCGUUUGCACAUUCGGUGAAGGUCUACUGUGUGCCAG		20
21373	MI0008131	cfa-mir-433	Canis familiaris miR-433 stem-loop	UACGGUGAGCCUGUCAUUAUUCAGAGAGGCUAGAUCCUCUGUGUUGAGAAGGAUCAUGAUGGGCUCCUCGGUGU		20
21374	MI0008132	cfa-mir-127	Canis familiaris miR-127 stem-loop	CCUGCUGAAGCUCAGAGGGCUCUGAUUCAGAAAGAUCAUCGGAUCCGUCUGAGCUUGGCU		20
21375	MI0008133	cfa-mir-136	Canis familiaris miR-136 stem-loop	ACUCCAUUUGUUUUGAUGAUGGAUUCUUACGCUCCAUCAUCGUCUCAAAUGAGUCU		20
21376	MI0008134	cfa-mir-379	Canis familiaris miR-379 stem-loop	UGGUAGACUAUGGAACGUAGGCUUUGUGAUUUUUGACCUAUGUAACAUGGUCCACUAAC		20
21377	MI0008135	cfa-mir-411	Canis familiaris miR-411 stem-loop	AUAGUAGACCGUAUAGCGUACGCUUUAUCUGUGACGUAUGUAACACGGUCCACUAACC		20
21378	MI0008136	cfa-mir-380	Canis familiaris miR-380 stem-loop	AUGGUUGACCAUAGAACAUGCGCUAGCUCUAUGUCGUAUGUAAUAUGGUCCACGUCU		20
21379	MI0008137	cfa-mir-323	Canis familiaris miR-323 stem-loop	AGGUGGUCCGUGGCGCGUUCGCUUUAUUUAUGGCGCACAUUACACGGUCGACCUCU		20
21380	MI0008138	cfa-mir-329	Canis familiaris miR-329 stem-loop	AGAGGUUUUCUGGGUUUCUGUUUCUUUCAUGAGGAUGAAACACACCCAGUUAACCUCUUU		20
21381	MI0008139	cfa-mir-543	Canis familiaris miR-543 stem-loop	GAAGUUGCCCGUGUUUUUUUCGCUUUAUUUGUGACGAAACAUUCGCGGUGCACUUCUU		20
21382	MI0008140	cfa-mir-495	Canis familiaris miR-495 stem-loop	GAAGUUGCCCGUGUUAUUUUCGCUUGAUACGUGCCGAAACAAACAUGGUGCACUUCUU		20
21383	MI0008141	cfa-mir-376-3	Canis familiaris miR-376-3 stem-loop	GGUGGAUGUUCCUUCUAUGUUUACGGGAUUUAUAGUUAAUCAUAGAGGAAAAUCCACGU		20
21384	MI0008142	cfa-mir-376-2	Canis familiaris miR-376-2 stem-loop	GUAGAUUUUCCUUCUAUGAUUACGUGUUUGAUGGUUAAUCAUAGAGGAAAAUCCACGU		20
21385	MI0008143	cfa-mir-376-1	Canis familiaris miR-376-1 stem-loop	GUAGAUUCUCCUUCUAUGAGUACAUUAUUUAUGAUUAAUCAUAGAGGAAAAUCCACGU		20
21386	MI0008144	cfa-mir-487	Canis familiaris miR-487 stem-loop	GUGGUUAUCCCUGUCCUGUUCGUUUUACUCAUGUCGAAUCGUACAGGGUCAUCCACUU		20
21387	MI0008145	cfa-mir-382	Canis familiaris miR-382 stem-loop	AAGUUGUUCGUGGUGGAUUCGCUUUACUUAUGACGAAUCAUUCACGGACAACACUUU		20
21388	MI0008146	cfa-mir-485	Canis familiaris miR-485 stem-loop	AGAGGCUGGCCGUGAUGAAUUCGAUUCAUCAAAGCGAGUCAUACACGGCUCUCCUCUCU		20
21389	MI0008147	cfa-mir-409	Canis familiaris miR-409 stem-loop	AGGUUACCCGAGCAACUUUGCAUCUGGACGACGAAUGUUGCUCGUUGAACCCCU		20
21390	MI0008148	cfa-mir-369	Canis familiaris miR-369 stem-loop	AGUUCGACCGUGUUAUAUUCGCUUUAUUGACUUCGAAUAAUACAUGGUUGGUCUUU		20
21391	MI0008149	cfa-mir-410	Canis familiaris miR-410 stem-loop	AGGUUGUCUGUGAUGAGUUCGCUUUAUUAAUGCCGAAUAUAACACAGAUGGCCUGU		20
21392	MI0008150	cfa-mir-219-2	Canis familiaris miR-219-2 stem-loop	UGAUUGUCCAAACGCAAUUCUUGUACGAGUCUGCGGCCAACCGAGAAUUGUGGCUGGACAUCUGU		20
21393	MI0008151	cfa-mir-199-3	Canis familiaris miR-199-3 stem-loop	CCAGUGUUUAGACUAUCUGUUCAGGACUCCCAAAUUGUACAGUAGUCUGCACAUUGGUU		20
21394	MI0008152	cfa-mir-181a-2	Canis familiaris miR-181a-2 stem-loop	AACAUUCAACGCUGUCGGUGAGUUUGGGAUUUGAAAAAACCACCGACCGUUGACUGUACC		20
21395	MI0008153	cfa-mir-181b-2	Canis familiaris miR-181b-2 stem-loop	AACAUUCAUUGCUGUCGGUGGGUUUGAGUCUGAAUCAACUCACUGAUCAAUGAAUGCAAA		20
21396	MI0008154	cfa-mir-126	Canis familiaris miR-126 stem-loop	CAUUAUUACUUUUGGUACGCGCUGUGACACUUCAAACUCGUACCGUGAGUAAUAAUGCG		20
21397	MI0008155	cfa-mir-212	Canis familiaris miR-212 stem-loop	ACCUUGGCUCUAGACUGCUUACUGCCCGGGCCGCCCUCAGUAACAGUCUCCAGUCACGGCCA		20
21398	MI0008156	cfa-mir-132	Canis familiaris miR-132 stem-loop	AACCGUGGCUUUCGAUUGUUACUGUGGGAACCGGAGGUAACAGUCUACAGCCAUGGUCGC		20
21399	MI0008157	cfa-mir-22	Canis familiaris miR-22 stem-loop	AGUUCUUCAGUGGCAAGCUUUAUGUCCUGACCCAGCUAAAGCUGCCAGUUGAAGAACUGU		20
21400	MI0008158	cfa-mir-144	Canis familiaris miR-144 stem-loop	AGGAUAUCAUCAUAUACUGUAAGUUUGCGACAAGAUACUACAGUAUAGAUGAUGUACUAG		20
21401	MI0008159	cfa-mir-193a	Canis familiaris miR-193a stem-loop	UGGGUCUUUGCGGGCGAGAUGAGGGUGUCGGUUCAACUGGCCUACAAAGUCCCAGU		20
21402	MI0008160	cfa-mir-142	Canis familiaris miR-142 stem-loop	CCCAUAAAGUAGAAAGCACUACUAACAGCACUGGAGGGUGUAGUGUUUCCUACUUUAUGGAUG		20
21403	MI0008161	cfa-mir-10	Canis familiaris miR-10 stem-loop	UACCCUGUAGAUCCGAAUUUGUGUAAGGAAUUUUGUGGUCACAAAUUCGUAUCUAGGGGAAUA		20
21404	MI0008162	cfa-mir-152	Canis familiaris miR-152 stem-loop	AGGUUCUGUGAUACACUCCGACUCGGGCUCUGGAGCAGUCAGUGCAUGACAGAACUUGG		20
21405	MI0008163	cfa-mir-338	Canis familiaris miR-338 stem-loop	AACAAUAUCCUGGUGCUGAGUGAUGACACAUGCAACUCCAGCAUCAGUGAUUUUGUUGA		20
21406	MI0008164	cfa-mir-1844	Canis familiaris miR-1844 stem-loop	AGGACUACGGACGGGCUGAGCUUUCAGGCUCCCCACAGCUCUGCCCGACUCUGGUUCGCA		20
21407	MI0008165	cfa-mir-21	Canis familiaris miR-21 stem-loop	UAGCUUAUCAGACUGAUGUUGACUGUUGAAUCUCAUGGCAACAGCAGUCGAUGGGCUGUC		20
21408	MI0008166	cfa-mir-423a	Canis familiaris miR-423a stem-loop	UGAGGGGCAGAGAGCGAGACUUUUCUAUUUUCCAAAAGCUCGGUCUGAGGCCCCUCAGU		20
21409	MI0008167	cfa-mir-652	Canis familiaris miR-652 stem-loop	ACAACCCUAGGAGAGGGUGCCAUUCACAUAGACUAUAAUUGAAUGGCGCCACUAGGGUUGUGC		20
21410	MI0008168	cfa-mir-224	Canis familiaris miR-224 stem-loop	CAAGUCACUAGUGGUUCCGUUUAGUAGAUGAUUAUGCAUUGUUUCAAAAUGGUGCCCUAGUGACUGCAA		20
21411	MI0008169	cfa-mir-424	Canis familiaris miR-424 stem-loop	AGCAGCAAUUCAUGUUUUGAAGUGCUUUAAAUGGUUCAAAACGUGAGGCGCUGCUAU		20
21412	MI0008170	cfa-mir-503	Canis familiaris miR-503 stem-loop	UAGCAGCGGGAACAGUACUGCAGUGGGCAAUCGGUGUUCUGGAGUAUUGUUUCUGCUGCCCGG		20
21413	MI0008171	cfa-mir-542	Canis familiaris miR-542 stem-loop	UCGGGGAUCAUCAUGUCACGAGAUACCACUGUGCACUUGUGACAGAUUGAUAACUGAAA		20
21414	MI0008172	cfa-mir-450b	Canis familiaris miR-450b stem-loop	UUUUGCAAUAUGUUCCUGAAUAUGUAAUAUAAGUGUAUUGGGAACAUUUUGCAUCCAU		20
21415	MI0008173	cfa-mir-106a	Canis familiaris miR-106a stem-loop	AAAGUGCUUACAGUGCAGGUAGCAUUCUGCGAUCUACUGCAAUGCAAGCACUUCUUA		20
21416	MI0008174	cfa-mir-19b-2	Canis familiaris miR-19b-2 stem-loop	GUUUUGCAGGUUUGCAUUUCAGCGUACUUGUGCAUAUAGGGCUGUGCAAAUCCAUGCAAAACUG		20
21417	MI0008175	cfa-mir-92a-2	Canis familiaris miR-92a-2 stem-loop	GGGUGGGGAUUUGUGGCAUUACUUGUGUUCCAUAUAAAGUAUUGCACUUGUCCCGGCCUGU		20
21418	MI0008176	cfa-mir-363	Canis familiaris miR-363 stem-loop	UCGGGUGGAUCACGAUGCAAUUUUGAUGAGUAUAAUAGGAGAAAAAUUGCACGGUAUCCAUCUGUAA		20
21419	MI0008177	cfa-mir-361	Canis familiaris miR-361 stem-loop	UUAUCAGAAUCUCCAGGGGUACUUAAAAUUUGAAAAAGUCCCCCAGGUGUGAUUCUGAUUUGC		20
21420	MI0008178	cfa-mir-384	Canis familiaris miR-384 stem-loop	UGUAAACAAUUCCUAGGCAAUGUGUAUAAUGUUUGUAAGUCAUUCCUAGAAAUUGUUCACAAU		20
21421	MI0008179	cfa-mir-374a	Canis familiaris miR-374a stem-loop	UUAUAAUACAACCUGAUAAGUGUUGUAGCACUUACCAGGUUGUAUUGUAAUU		20
21422	MI0008180	cfa-mir-374b	Canis familiaris miR-374b stem-loop	AUAUAAUACAACCUGCUAAGUGUCCUAGCACUUAUCAGGUUGUAUUAUCAUU		20
21423	MI0008181	cfa-mir-421	Canis familiaris miR-421 stem-loop	CUCAUUAAAUGUUUGUUGAAUGAAAAAAUGAAUCAUCAACAGACAUUAAUUGGGCG		20
21424	MI0008182	cfa-mir-98	Canis familiaris miR-98 stem-loop	UGAGGUAGUAAGUUGUAUUGUUGUGGGGUAGGGAUUUUAGGCCCCAAUUAGAAGAUAACUAUACAACUUACUACUUUCCC		20
21425	MI0008183	cfa-mir-221	Canis familiaris miR-221 stem-loop	ACCUGGCAUACAAUGUAGAUUUCUGUGUUUGUUGGGCAACAGCUACAUUGUCUGCUGGGUUU		20
21426	MI0008184	cfa-mir-532	Canis familiaris miR-532 stem-loop	CAUGCCUUGAGUGUAGGACCGUUGGUAUCUUAAUUACCCUCCCACACCCAAGGCUUGCA		20
21427	MI0008185	cfa-mir-500	Canis familiaris miR-500 stem-loop	AAUCCUUGCUACCUGGGUGAGAGUGCUUUCUGAAUGCAAUGCACCUGGGCAAGGAUUCU		20
21428	MI0008186	cfa-mir-660	Canis familiaris miR-660 stem-loop	UACCCAUUGCAUAUCGGAGUUGUGAAUUCUCAAAGCACCUCCUGUGUGCAUGGAUUACA		20
21429	MI0008187	cfa-mir-502	Canis familiaris miR-502 stem-loop	AAUCCUUGCUAUCUGGGUGCUAGUGCUGUCUCAAUGCAAUGCACCUGGGCAAGGAUUCA		20
21430	MI0008188	cfa-mir-676	Canis familiaris miR-676 stem-loop	CUCUUCAAUCUCAGGACUCGCAGAAUUAAUGGAAUGCCGUCCUAAGGUUGGUGAGUU		20
21431	MI0008189	cfa-let-7j	Canis familiaris let-7j stem-loop	UGAGGUAGUAGAGUGCAGUAGUUAUAAAAGGAAUCUCUGGAGCUAGAUUGCUGUACUUCAUACCUGCU		20
21432	MI0008190	hsa-mir-320d-1	Homo sapiens miR-320d-1 stem-loop	UUCUCGUCCCAGUUCUUCCCAAAGUUGAGAAAAGCUGGGUUGAGAGGA		5
21433	MI0008191	hsa-mir-320c-2	Homo sapiens miR-320c-2 stem-loop	CUUCUCUUUCCAGUUCUUCCCAGAAUUGGGAAAAGCUGGGUUGAGAGGGU		5
21434	MI0008192	hsa-mir-320d-2	Homo sapiens miR-320d-2 stem-loop	UUCUCUUCCCAGUUCUUCUUGGAGUCAGGAAAAGCUGGGUUGAGAGGA		5
21435	MI0008193	hsa-mir-1825	Homo sapiens miR-1825 stem-loop	AGAGACUGGGGUGCUGGGCUCCCCUAGACUAGGACUCCAGUGCCCUCCUCUCC		5
21436	MI0008194	hsa-mir-1826	Homo sapiens miR-1826 stem-loop	AUUGAUCAUCGACACUUCGAACGCAAUUGCAGCCCGGGUUCCUCCCAGGGCUUUGCCUGUCUGAGCGUCGCUUGCCGAUCAGUAG		5
21437	MI0008195	hsa-mir-1827	Homo sapiens miR-1827 stem-loop	UCAGCAGCACAGCCUUCAGCCUAAAGCAAUGAGAAGCCUCUGAAAGGCUGAGGCAGUAGAUUGAAU		5
21438	MI0008196	cel-mir-1828	Caenorhabditis elegans miR-1828 stem-loop	GAUCACUUUUAUCGGUUCCGGUCCCUCUGCAAAAAAGUGGACUGGAAGCAUUUAAGUGAUAGU		3
21439	MI0008197	cel-mir-1829a	Caenorhabditis elegans miR-1829a stem-loop	AAGGGGACUUCUAAUUGUUUGUAAAAAAUCGAGUAUUACAACCAUUGGAAUUUCUCUAUU		3
21440	MI0008198	cel-mir-1829b	Caenorhabditis elegans miR-1829b stem-loop	AAGCGAUCUUCUAGAUGGUUGUAAAACAUCGAGUAUUACAACCACUGGAAUUUCUCUAUU		3
21441	MI0008199	cel-mir-1829c	Caenorhabditis elegans miR-1829c stem-loop	AAGCGAAAUUCAAGAUGGUUGUAAAACAUCGAGUACUACAACCACUGGAAUUUCUCUAUUGC		3
21442	MI0008200	cel-mir-1830	Caenorhabditis elegans miR-1830 stem-loop	CGAGGUUUCACGUUUUCUAGGCCACGCCGCAAAUAGCCAGCUUGUGGCCUAGGAAAUGAGAAAACUCGGC		3
21443	MI0008201	cel-mir-1831	Caenorhabditis elegans miR-1831 stem-loop	ACCUGGCUGGGGGUAUCUCGUGAUCAUGAAGACGGGAUCCCCAUGGUGA		3
21444	MI0008202	cel-mir-1832	Caenorhabditis elegans miR-1832 stem-loop	CAGCGAUUCGAACUCCGCCCACUGCACCUGAUUGGUUGACAAGUGGGCGGAGCGAAUCGAUGAU		3
21445	MI0008203	cel-mir-1833	Caenorhabditis elegans miR-1833 stem-loop	ACGCUUACUUCGCAAGCCUCGCGCGUUUUCUUUUCAAGAGAAAAAGCGUGCGAGGCUUGCGAAAUAAGUGUGC		3
21446	MI0008204	cel-mir-1834	Caenorhabditis elegans miR-1834 stem-loop	UGACUCGGUGUGUGAUCUCUUACCGUUUUAUGGAUAAGAGAUCAACCAUUGAGAUCCAA		3
