Merge pull request #4106 from solgenomics/topic/wishlist
[sgn.git] / static / documents / primer3-libraries / human.txt
blob9a1e8f5bbfdc84a120e01a225f8b48ddc9d84e08
1 >ALU Human ALU interspersed repetitive sequence - a  consensus
2 GGCCGGGCGCGGTGGCTCACGCCTGTAATCCCAGCACTTTGGGAGGCCGAGGCGGGCGGATCACCTGAGGTCAGGAGTTCGAGACCAGCCTGGCCAACATGGTGAAACCCCGTCTCTACTAAAAATACAAAAATTAGCCGGGCGTGGTGGCGCGCGCCTGTAATCCCAGCTACTCGGGAGGCTGAGGCAGGAGAATCGCTTGAACCCGGGAGGCGGAGGTTGCAGTGAGCCGAGATCGCGCCACTGCACTCCAGCCTGGGCGACAGAGCGAGACTCCGTCTCAAAAAAAA
3 >MIR mammalian-wide interspersed repeat (MIR) - a consensus
4 ACAGYAYAGCATAGTGGTTAAGAGCACGGRCTCTGGAGCCAGACTGCCTGGGTTCGAATCCCGGCTCTGCCACTTACTAGCTGTGTGACCTTGGGCAAGTTACTTAACCTCTCTGTGCCTCAGTTTCCTCATCTGTAAAATGGGGATAATAATAGTACCTACCTCATAGGGTTGTTGTGAGGATTAAATGAGTTAATAYATGTAAAGCGCTTAGAACAGTGCCTGGCACATAGTAAGCGCTCAATAAATGTTRGYTATTATT
5 >MIR2 Repetitive element - a consensus
6 TTNTTTATTGTCTGTCTCCTCCACTAGANTGTAAGCTCCATGAGGGCAGGGATTTTGTCTGTYTTGTTCACTGCTGTATCCCCAGCGCCTAGAACAGTGCCTGGCACATAGTAGGCGCTCAATAAATATTTGTTGAATGAATGAATGAAT
7 >L1 Human L1 interspersed repetitive sequence - full length copy
8 GGCGGTGGAGCCAAGATGACCGAATAGGAACAGCTCCAGTCTATAGCTCCCATCGTGAGTGACGCAGAAGACGGGTGATTTCTGCATTTCCAACTGAGGTACCAGGTTCATCTCACAGGGAAGTGCCAGGCAGTGGGTGCAGGACAGTAGTGCAGTGCACTGTGCATGAGCCGAAGCAGGGCGAGGCATCACCTCACCCGGGAAGCACAAGGGGTCAGGGAATTCCCTTTCCTAGTCAAAGAAAAGGGTGACAGATGGCACCTGGAAAATCGGGTCACTCCCGCCCTAATACTGCGCTCTTCCAACAAGCTTAACAAATGGCACACCAGGAGATTATATCCCATGCCTGGCTCAGAGGGTCCTACGCCCATGGAGCCTCGCTCATTGCTAGCACAGCAGTCTGAGGTCAAACTGCAAGGTGGCAGTGAGGCTGGGGGAGGGGTGCCCACCATTGTCCAGGCTTGAGCAGGTAAACAAAGCCGCCTGGAAGCTCGAACTGGGTGGAGCCCACCACAGCTCAAGGAGGCCTGCCTGCCTCTGTAGGCTCCACCTCTAGGGGCAGGGCACAGACAAACAAAAGACAACAAGAACCTCTGCAGACTTAAATGTCCCTGTCTGACAGCTTTGAAGAGAGTAGTGGTTCTCCCAGCACATAGCTTCAGATCTGAGAACAGGCAGACTGCCTCCTCAAGTGGGTCCCTGACCCCCGAGTAGCCTAACTGGGAGGCATCCCCCAGTAGGGCGGACTGACACCTCACATGGCTGGTACTCCTCTAAGACAAAACTTCCAGAGGAATGATCAGGCAGCAGCATTTGCGGTTCACCAATATCCACTGTTCTGCAGCCACCGCTGCTGATACCCAGGAAAACAGCATCTGGAGTGGACCTCCAGTAAACTCCAACAGACCTGCAGCTGAGGGTCCTGACTGTTAGAAGGAAAACTAACAAACAGAAAGGACATCCACACCAAAAACCCATCTGTACATCACCATCATCAAAGACCAAAGGTAGATAAAACCATAAAGATGGGGAAAAAGCAGAGCAGAAAAACTGGACACTCTAAAAATGAGAGTGCCTCTCCTTCTCCAAAGTAACGCAGCTCCTCACCAGCAATGGAACAAAGCTGGGCAGAGAATGACTTTGACGAGTTGAGAGAGGAAGGCTTCAGAAGATCAAACTACTCCAAGCTAAAGGAGGAAGTTCGAACAAACGGCAAAGAAGTAAAAAACTTTGAAAAAAAATTAGATGAATGGATAACTAGAATAACCAATGCACAGAAGTCCTTAAAGGACCTGATGGAGCTGAAAACCAAGGCAGGAGAACTACGTGACAAATACACAAGCCTCAGTAACCGATGAGATCAACTGGAAGAAAGGGTATCAATGACGGAAGATGAAATGAATGAAATGAAGCATGAAGAGAAGTTTAGAGAAAAAAGAATAAAAAGAAACGAACAAAGCCTCCAAGAAATATGGGACTATGTGAAAAGACCAAATCTACATCTAATTGGTGTAGCTGAAAGTGATGGGGAGAATGGAACCAAGTTGGAAAACACTCTGCAGGATATTATCCAGGAGAACTTCCCCAATCTAGCAAGGCAGCCCAAATTCACATTCAGGAAATACAGAGAACGCCACAAAGATACTCCTAGAGAAAAGCAACTCCAAGACACATAACTGACAGATTCACCAAAGTTGAAATGAAGGAAAAAATGTTAAGGGCAGCCAGAGAGAAAGGTCGGGTTACCCACAAAGGGAAGCCCATCAGACTAACAGCTGATCTATCGGCAGAAACTCTACAAGCCAGAAGAAAGTGGGGGCCAATATTCAACATTGTTAAAGAAAAGAATTTTCGGCCCAGAATTTCATATCCAGCCAAACTAAGCTTCATAAGCATTGGAGAAATAAAATCCTTTACAGACAAGCAAATGCTGAGAGATTTTGTCACCACCAGGCCTGCCCTACAAGAGCTCCTGAAGGAAGCACTAAACATGGAAAGGAACAACTAGTATCAGCCACTGCAAAAACATGCCAAATTGTAAACGACCATCAAGGCTAGGAAGAAACTGCATCAAGGAGCAAAATAACCAGCTAACATCATAATGACAGGATCAAATTCATACATAACAATACTCACCTTAAATGTAAATAGGCTAAATGCTCCAATTAAAAGACACAGACTGGCAAATTGGATAAGGAGTCAAGACCCATCTGTCGTTATGTATTCAGGAAACCCATCTCACGTGCAGAGACACACATAGGCTCGAAATAAAAGGATGGAGGAATATCTACCAAGCAAATGGAAAACAAAAAAAGGCAGGGGTTGCAATCCTAGTCTCTGATAAAACAGATTTTAAACCAACAAAGATCAAAAGAGACAAAGAAGGCCATTACATAATGGCAAAGGGATCTATTCAAGAAGAAGAACTAACTATACTAAATATATATGCACCCAATACAGGAGCACCCAGATTCATAAAACAAGTCCTGAGTGACCTACAAAGAGACTTAGATGCCCACACAATAATAATGGGAGACTTTAACACCCCACTGTCAACATTAGACAGATCAACGAGACAGAAAGTTAACAAGGATATCCAGGAATTGGACTCAGCTCTGCACCAAGCAGACCTAATAGACATCTACAGAACTCTCCACCCCAAATCAACAGAATATACATTCTTTTCAGCACCACACCACACCTATTCCAAAACTGACCACATAGTTGGAAGTAAAGCTCTCCTCAGCAAATGTAAAAGAACAGAAACTATAACAAACTGTCTCTCAGACCACAGTGCAATCAAACTAGAACTCAGGATTAAGAAACTCACTCAAAACCACTCAGCTACATGGAAACTGAACAGCCTGCTCCTGAATGACTACTGGGTACATAACAAAATGAAGGCAGAAATAAAGATGTTCTTTGAAACAACGAGAACAAAGACACAACACACCAGAATCTCTGAGACACATTCAAAGCAGTGTGTAGAGGGAAATTTATAGCACTAAATGCCCACAAGGGAAAGCAGGAAAGATCTAAAATTGACACCCTAACATCACAATTAAAAAACTAGAGAAGCAGGAGCAAACACATTCAAAAGCTAACAGAAGACAAGAAATAACTAAGATCAGAGCAGAAGTGAAGAAGATAGAGACACAAAAAACCCTTCAAAAAAATCAATGAATCCAGAAGCTGTTTTTTTGAAAAGATCAACAAAATTGATAGACTGCTAGCAAGACTAATAAAGAAGAAAGGGGAGAAGAATCAAATAGACGCAATAAAAAATGACACGGGGTATCACCACTGATCCCACAGAAATACAAACTACCGTCAGAGAATACTATAAACACCTCTACGCAAATAAACTAGAAAATCTAGAAGAAATGGATAAATTCCTCGACACATACACTCTGCCAAGACTAAACCAGGAAGAAGTTGTATCTCTGAATAGACCAATAACAGGCTCTGAAATTGAGGCAATAATTAATAGCTTATCAACCAAAAAAAGTCCGGGACCAGTAGGATTCATAGCCGAATTCTACCAGAGGTACAAGGAGGAGCTGGTACCATTCCTTCTGAAACTATTCCAATCAATAGAAAAAGAGGGAATCCTCCCTAACTCATTTTATGAGGCCAGCATCATCCTGATACCAAAGCCTGACAGAGACACAACAAAAAAAGAGAATGTTACACCAATATCCTTGATGAACATCGATGCAAAAATCCTCAATAAAATACTGGCAAACTGAATCCAGCAGCACATCAAAAAGCTTATCCTCCATGATCAAGTGGGCTTCATCCCTGCCATGCAAGGCTGGTTCAACATACGAAATCAATAAACATAATCCAGCATATAAACAGAACCAAAGACACAAACCATATGATTATCTCAATAGATGCAGAAAAGGCCTTTGACAAAATTCAACAATGCTTCATGCTAAAAACTCTCAATAAATTAGGTATTGATGGGACATATCTCAAAATAATAAGAGCTATCTATGACAAACCCACAGCCAATATCATACTGAGTGGACAAAAACTGGAAGCATTCCCTTTGAAAACTGGCACAAGGCAGGGATGCCCTCTCTCACCACTCCTATTCAACATAGTGTTGGAAGTTCTGGCCAGGGCAATCAGGCAGGAGAAGGAAATAAAGGGCATTCAATTAGGAAAAGAGGAAGGTGAAATTGTCCCTGTTTGCAGATGACATGATTGTATATCTAGAAAACCCCATTGTCTCAGCCCAAAATCTCCTTAAGCTGATAAGCAACTTCAGCAAAGTCTCAGGATATAAAATCAGTGTGCAAAAATCACAAGTATTCCTATGCACCAATAACAGACAAACAGAGAGCCAAATCATGAGTGAACTCCCATTCACAATTGCTTCAAAGAGAATAAAATACCTAGGAATCCAACTTACAAGGGATGTGAAGGACCTCTTCAAGGAGAACTACAAACCACTGCTCAATGAAATAAAAGAGGATACAAACAAATGGAAGAACATTCCATGCTTATGGGTAGGAAGAATCATATCGTGAAAATGGTCATACTGCCCAAGGTAATTTATAGATTCAATGCCATCCCCATCAAGCTACCAATGACTTTCTTCACAGAACTGGAAAAAACTACTTTAAAGTTCATATGGAATCAAAAAAGAGCCCACATCACCAAGGCAATCCTAAGCCAAAAGAACAAAGCTGGAGGCATCACGCTACCTGACTTCAAACTATACTACAATGCTACGGTAACCAAAACAGCATGGTACTGGTACCAAAACAGAGATCTAGACCAATGGAACAGAACAGAGCCCTCAGAAATAATGCCGCATATCTACAACTATCCGATCTTTGACAAACCTGAGAGAAACAAGCAATGGGGAAAGGATTCCCTATTTAATAAATGGTGCTGGGAAAACTGGCTAGCCATATGTAGAAAGCTGAAACTGGATCCTTCCTTACACCTTATACAAAAATTAATTCAAGATGGATTAAAGACTTAAACATTAGACCTAAAACCATAAAAACCCTAGAAAAAAACCTAGGCAATACCATTCAGGACATAGGCATGGGCAAGGACTTCATGTCTAAAACACCAAAACGAATGGCAACAAAAGACAAAATGGACAAACGGGATCTAATTAAACTAAAGAGCTTCTGCACAGCTAAAGAAACTACCATCAGAGTGAACAGGCAACCTACAAAATGGGAGAAAATTTTTGCAATCTACTCATCTGACAAAGGGCTAATATCCAGAATCTACAATGAACTCAAACAAATTTACAAGAAAAAACAAACAACCCCATCAAAAAGTGGGCAAAGGATATGAACAGACACTTCTCAAAAGAAGACATTTATGTAATCAAAAAACACATGAAAAAATGCTCATCATCACTAGCCATCAGAGAAATGCAAATCAAAACCACAATGAGATACCATCTCACACCAGTTAGAATGGCGATCATTAAAAAGTCAGGAAACAACAGGTGCTGGAGAGGATGTGGAGAAACAGGAACAACTTTTACACTGTTGGTGGGACTGTAAACTAGTTCAACCATTGCGGAAGTCAGTGTGGCAATTCCTCAGGAATCTAGAACTAGAAATACCATTTGACCCAGCCATCCCATTACTGGGTAGATACCCAAAGGATTATAAATCATGCTGCTATAAAGACACATGCACACGTATGTTTATTGCAGCACTATTCACAATAGCAAAGACTTGGAACCAACCCAAATGTCCAACAACGATAGATTGGATTAAGAAAATGTGGCACATATACACCATGGAATACTATGCAGCCATAAAAAATGATGAGTTCATGTCCTTTGTAGGGACATGGATGAAGCTGGAAACTATCATTCTCAGCAAACTATCACAAGGACAATAAACCAAACACCGCATGTTCTCACTCATAGGTGGGAATTGAACAATGAGAACACATGGACACATGAAGAGGAACATCACACTCTGGGGACTGTTATGGGGTGGGGGGCAGGGGCAGGGATAGCACTAGGAGATATACCTAATGCTAAATGACGAGTTAATGGGTGCAGCACACCAACATGGCACATGTATACATATATAACAAACCTGCCGTTGTGCACATGTACCCTAAAACTTGAAGTATAATAATAAAAAAAA
9 >L1PA2 3'-end of L1 repeat (subfamily L1PA2) - a consensus sequence
10 CTAATATCCAGAATCTACAATGAACTCAAACAAATTTACAAGAAAAAAACAAACAACCCCATCAAAAAGTGGGCGAAGGACATGAACAGACACTTCTCAAAAGAAGACATTTATGCAGCCAAAAAACACATGAAGAAATGCTCATCATCACTGGCCATCAGAGAAATGCAAATCAAAACCACTATGAGATATCATCTCACACCAGTTAGAATGGCAATCATTAAAAAGTCAGGAAACAACAGGTGCTGGAGAGGATGTGGAGAAATAGGAACACTTTTACACTGTTGGTGGGACTGTAAACTAGTTCAACCATTGTGGAAGTCAGTGTGGCGATTCCTCAGGGATCTAGAACTAGAAATACCATTTGACCCAGCCATCCCATTACTGGGTATATACCCAAAGGACTATAAATCATGCTGCTATAAAGACACATGCACACGTATGTTTATTGCGGCACTATTCACAATAGCAAAGACTTGGAACCAACCCAAATGTCCAACAATGATAGACTGGATTAAGAAAATGTGGCACATATACACCATGGAATACTATGCAGCCATAAAAAATGATGAGTTCATGTCCTTTGTAGGGACATGGATGAAATTGGAAATCATCATTCTCAGTAAACTATCGCAAGAACAAAAAACCAAACACCGCATATTCTCACTCATAGGTGGGAATTGAACAATGAGATCACATGGACACAGGAAGGGGAATATCACACTCTGGGGACTGTGGTGGGGTGGGGGGAGGGGGGAGGGATAGCATTGGGAGATATACCTAATGCTAGATGACGAGTTAGTGGGTGCAGCGCACCAGCATGGCACATGTATACATATGTAACTAACCTGCACAATGTGCACATGTACCCTAAAACTTAAAGTATAATAAAA
11 >L1PA7 3'-end of L1 repeat (subfamily L1PA7) - a consensus sequence
12 CTAATATCCAGAATCTACAAGGAACTTAAACAAATTTACAAGAAAAAAACAAACAACCCCATCAAAAAGTGGGCAAAGGATATGAACAGACACTTCTCAAAAGAAGACATTTATGYAGCCAACAAACAYATGAAAAAAAGCTCATCATCACTGGTCATTAGAGAAATGCAAATCAAAACCACAATGAGATACCATCTCAYGCCAGTTAGAATGGCGATCATTAAAAAGTCAGGAAACAACAGATGCTGGAGAGGATGTGGAGAAATAGGAATGCTTTTACACTGTTGGTGGGAGTGTAAATTAGTTCAACCATTGTGGAAGACAGTGTGGCGATTCCTCAAGGATCTAGAACCAGAAATACCATTTGACCCAGCAATCCCATTACTGGGTATATACCCAAAGGATTATAAATCATTCTRCTATAAAGACACATGCACACGTATGTTTATTGCAGCACTATTCACAATAGCAAAGACTTGGAACCAACCCAAATGCCCATCAATGATAGACTGGATAAAGAAAATGTGGCACATATACACCATGGAATACTATGCAGCCATAAAAAAGGATGAGTTCATGTCCTTTGCAGGGACATGGATGAAGCTGGAAACCATCATTCTCAGCAAACTAACACAGGAACAGAAAACCAAACACCGCATGTTCTCACTCATAAGTGGGAGTTGAACAATGAGAACACATGGACACAGGGAGGGGAACATCACACACCGGGGCCTGTCGGGGGGTGGGGGGCTAGGGGAGGGATAGCATTAGGAGAAATACCTAATGTAGATGACGGGTTGATGGGTGCAGCAAACCACCATGGCACATGTATACCTATGTAACAAACCTGCACGTTCTGCACATGTATCCCAGAACTTAAAGTATAATAATA
13 >L1PA11 3'-end of L1 repeat (subfamily L1PA11) - a consensus sequence
14 CTAATATCCAGAATSTACAARGAACTTAAACAAATTTACAAGAAAAAAACAAAMAACCCCATCAAAAAGTGGGCAAAGGACATGAACAGACACTTCTCAAAAGAAGACATWTATGTGGCCAATAAGCACATGAAAAAAAGCTCAACATCACTGATCATTAGAGAAATGCAAATCAAAACCACAATGAGATACCATCTCAYRCCAGTCAGAATGGCAATTATTAAAAAGTCAAGAAACAACAGATGCTGGYGAGGCTGTGGAGAAATAGGAATGCTTTTACACTGTTGGTGGGAATGTAAATTAGTTCAACCATTGTGGAAGACAGTGTGGCGATTCCTCAAGGATCTAGAACCAGAAATACCATTTGACCCAGCAATCCCATTACTGRGTATATACCCAAAGGAATATAAATCATTCTATTATAAAGACACATGCAYGTGTATGTTYATTGCAGCACTATTCACAATAGCAAAGACATGGAATCAACCYAAATGCCCATCAATGATAGACTGGATAAAGAAAATGTGGTACATATACACCATGGAATACTATGCAGCCATAAAAAAGAATGAGATCATGTCCTTTGCAGGAACATGGATGGAGCTGGAGGCCATTATCCTTAGCAAACTAAYGCAGGAACAGAAAACCAAATACCGCATGTTCTCACTTATAAGTGGGAGCTAAACGATGAGAACACATGGACACATGGAGGGGAACAACACACACTGGGGCCTGTCGGAGGGTGGAGGGTGGGAGGAGGGAGAGCATCAGGAAAAATAGCTAATGGATACTGGGCTTAATACCTGGGTGATGGGATGATCTGTGCAGCAAACCACCATGGCACACGTTTACCTATGTAACAAACCTGCACATCCTGCACATGTACCCCGGAACTTAAAATAAAAGTTGAAA
15 >L1PA15 3'-end of L1 repeat (subfamily L1PA15) - a consensus sequence
16 CTAATATCCAGAATSTACAARGAACTTAAACAAATTTACAAGAAAAAAACAAAMAACCCCATCAAAAAGTGGGCAAAGGACATGAACAGACACTTCTCAAAAGAAGACATWTATGTGGCCAATAAGCACATGAAAAAAAGCTCAACATCACTGATCATTAGAGAAATGCAAATCAAAACCACAATGAGATACCATCTCAYRCCAGTCAGAATGGCAATTATTAAAAAGTCAAGAAACAACAGATGCTGGYGAGGCTGTGGAGAAATAGGAATGCTTTTACACTGTTGGTGGGAATGTAAATTAGTTCAACCATTGTGGAAGACAGTGTGGCGATTCCTCAAGGATCTAGAACCAGAAATACCATTTGACCCAGCAATCCCATTACTGRGTATATACCCAAAGGAATATAAATCATTCTATTATAAAGACACATGCAYGTGTATGTTYATTGCAGCACTATTCACAATAGCAAAGACATGGAATCAACCYAAATGCCCATCAATGATAGACTGGATAAAGAAAATGTGGTACATATACACCATGGAATACTATGCAGCCATAAAAAAGAATGAGATCATGTCCTTTGCAGGAACATGGATGGAGCTGGAGGCCATTATCCTTAGCAAACTAAYGCAGGAACAGAAAACCAAATACCGCATGTTCTCACTTATAAGTGGGAGCTAAAYATTGAGTACACATGGACATAAAGAAGGGAACAACAGACACTGGGGCCTACTTGAGGGTGGAGGGTGGGAAGAGGGAGAGGATCAAAAAACTACCTATCGGGTACTATGCTTATTACCTGGGTGATGAAATAATCTGTACACCAAACCCCAGCGACACGCAATTTACCTATATAACAAACCTGCACATGTACCCCCTGAATCTAAAATAAAAGTTAAAA
17 >L1PB1 3'-end of L1 repeat (subfamily L1PB1) - a consensus sequence
18 CTAATATCCAGAATCTATAAGGAACTCAAACAAATCAGCAAGAAAAAAACAAACAATCCCATCAAAAAGTGGGCTAAGGACATGAAYAGACAMTTCTCAAAAGAAGATATRYAAATGGCCAACAAGCATATGAAAAAATGCTCAACATCACTAATTATCAGGGAAATGCAAATCAAAACCACAATGCRATACCATCTTACTCCTGCAAGAATGGCCATAATTAAAAAATCAAAAAATAATAGATGTTGGCGTGGATGTGGTGAAAAGGGAACACTTYTACACTGCTGGTGGGAATGTAAACTAGTACAACCACTATGGAAAACAGTATGGAGATTYCTTAAAGAACTAAAAGTAGAACTACCATTTGATCCAGCAATCCCACTACTGGGTATCTACCCARARGAAAAKAAGTCATTATAYGAAAAAGAYACTTGCACACRCATGTTTATAGCAGCACAATTYRCAATTGCAAAAATATGGAACCAACCCAAATGCCCATCAATCAAYRAGTGGATAAAGAAAATGTGRTATATATATACCATGGAATACTACKCAGCCATAAAAAAGAATGAAATAATGGCATTTGCAGCAACCTGGATGGARYTGGAGACYATTATTCTAAGTGAAGTAACTCAGGAATGGAAAACCAAACATYRTATGTTCTCACTTATAAGTGGGAGCTAAGCTATGAGGATGCAAAGGCGTAAGAATGATACAATGGACTTTGGGGACTCGGGAGATCGGGRGAAAGGGTGGGAGGGGGGTGAGGGATAAAAGACTACAAATTGGGTACAGTGTACACTGCTCGGGTGATGGGTGCACCAAAATCTCACAAATCACCACTAAAGAACTTATTCATGTAACCAAACACCACCTGTTCCCCAAAAACCTATTGAAATAAA
19 >L1PB3 3'-end of L1 repeat (subfamily L1PB3) - a consensus sequence
20 CTAATATCCAGAATCTATAAGGAACTCAAACAAATCAGCAAGAAAAAAACAAACAATCCCATCAAAAAGTGGGCTAAGGACATGAAYAGACAMTTCTCAAAAGAAGATATRYAAATGGCCAACAAGCATATGAAAAAATGCTCAACATCACTAATTATCAGGGAAATGCAAATCAAAACCACAATGCRATACCATCTTACTCCTGCAAGAATGGCCATAATTAAAAAATCAAAAAATAATAGATGTTGGCGTGGATGTGGTGAAAAGGGAACACTTYTACACTGCTGGTGGGAATGTAAACTAGTACAACCACTATGGAAAACAGTATGGAGATTYCTTAAAGAACTAAAAGTAGAACTACCATTTGATCCAGCAATCCCACTACTGGGTATCTACCCARARGAAAAKAAGTCATTATAYGAAAAAGAYACTTGCACACRCATGTTTATAGCAGCACAATTYRCAATTGCAAAAATATGGAACCAACCCAAATGCCCATCAATCAAYRAGTGGATAAAGAAAATGTGRTATATATATACCATGGAATACTACKCAGCCATAAAAAAGAATGAAATAATGGCATTTGCAGCAACCTGGATGGARYTGGAGACYATTATTCTAAGTGAAGTAACTCAGGAATGGAAAACCAAACATYRTATGTTCTCACTTATAAGTGGGAGCTAAGCTATGGGTATATACGGGCATATAGAGTGGTATAATAGACAYTGGAGACTCAAAAGGTGGAGGGTAGGAGAGGGGTGAGGGATGAAAAATTACCTATTGGGTACAATGTWCACTATTCGGGTGATGGGTACACTAAAAGCCCAGACTTCACCACTAYACAATATATCCATGTAACAAAAAKGCACYTGTACCCCCTAAATYTATAAAAATAAA
21 >L1MA2 3'-end of L1 repeat (subfamily L1MA2) - a consensus sequence
22 YTAATATCCAGAATMTATAAGGAACTCAAACAAATCAACAAGAAAAAAACAAATAATCCMATTAAAAARTGGGCAAAAGACATGAAYAGACATTTCTCAAAAGAAGACATACAAATGGCCAACARGYATATGAAAAAATGCTCAACATCACTAATCATCAGAGAAATGCAAATCAAAACYACAATGAGATATCATCTCACCCCAGTTARAATGGCTTTTATTAAAAAGACAAAAAATAACARATGCTGGYGAGGATGTGGAGAAAAGGGAACTCTTAYAYACTGTTGGTGGGAATGTAAATTAGTACARCCAYTATGGAAAACAGTTTGGAGRTTYCTCAAAAAACTAAAAATAGARCTACCATATRATCCAGCAATCCCACTRCTGGGTATATAYCCAAAAGAAAGGAAATCAGTATATYAAARAGATACCTGCACTCCCATGTTTATTGCAGCACTATTCACAATAGCHAAGATTTGGAATCAACCTAAGTGTCCATCAACRGATGAATGGATAAAGAAAATGTGGTACATATACACAATGGAGTACTATTCAGCCATAAAAAAGAATGARATCYTGTCATTTGCAGCAACATGGATGGAACTGGAGGTCATTATGTTAAGTGAAATAAGYCARGMACARAAAGACAAACAYTGCATGTTCTCACTTATTTGTGGGATCTAAAAATCAAAACAATTGAACTCATGGAGATAGAGAGTAGAAGGATGGTTACCAGAGGCTGGGAAGGGTAGTNGGAGGATTGGGGGGNGGKGRRGAGGGATGGTTAATGGGTACAAAAAAATAGTTAGAAAGAATGAATAAGACCTAGTATTTGATAGCACAACAAGGTGACTATAGTCAATAATAATTTAATTGTACATTTTAAAATAACTAAAAGAGTATAATTGGATTGTTTGTAACACAAAGGATAAATGCTTGAGGGGATGGATACCCCATTTTCCATGATGTGATTATTACACATTGCGTGCCTGTATCAAAACATCTCATGTACCCCATAAATATATACACCTACTATGTACCCACAAAAATTAAAA
23 >L1MA5 3'-end of L1 repeat (subfamily L1MA5) - a consensus sequence
24 TTAATATCCAAAATATATAAGGAACTCAAACAACTCAACAAGAARAAAACAAATAACCCAATTAAAAAATGGGCAAARGACCTGAATAGACATTTYTCAAAAGAAGACATACAAATGGCCAACAGATATATGAAAAAATGCTCAACATCACTAATCATCAAGGAAATGCAAATTAAAACCACAATGAGATATCACCTCACACCTGTTAGAATGGCTATTATCAAAAAGACAGAAAATAATAAATGTTGGYGAGGATGTGGAGAAAAGGGAACTATTGTACACTGTTGGTGGGAATGTAAATTAGTAYAGCCAYTATGGAAAACAGTATGGAGGTTCCTCAAAAAAYTAAAAATARAACTACCATATGATYCAGCAATCCCACTWCTGGGTATATATCCAAARGAATTGAAATCAGTATGTYGAAGAGATAYCTGCACTCCCATGTTTAYTGCAGCAYTATTCACAATAGCCAAGATATGGAAWCAACCTAAGTGTCCATCAAYGGAWGAATGGATAAAGAAAATGTGGTATATATACACAATGGAATACTATTCAGCCATAAAAAAGAATGAAATCCTGTCATTTGYARCAACATGGATGAACCTGGAGGACATTATGCTAAGTGAAATAAGCCAGGCACAGAAAGACAAATACCGCATGTTCTCACTCATATGTGGAAGCTAAAAAAGTTGATCTCATAGAAGTAGAGAGTAGAATAGTGGTTACTAGAGGCTGGGAAGGGTAGGGRGAGGGGGGRATAGGGAGAGGTTGGTTAAWGGRTACAAAATTACAGTTAGATAGGAGGAATAAGTTCTAGTGTTCTGTAGCACCGTAGGGTGACTATAGTTAACAAYAATTTATTGTATATTTTCAAATAGCTAGAAGAGAGGATTTTGAATGTTCCCAACACAAAGAAATGATAAATGTTTGAGGTGATGGATATGCTAATTACCCTGATTTGATCATTACACAWTGTATACATGTATCGAAATATCACACTGTACCCCATAAATATGTACAATTATTATGTGTCAATTAAAAA
25 >L1MA9 3'-end of L1 repeat (subfamily L1MA9) - a consensus sequence
26 TTAATATCCAAAATATATAAGGAACTCAAACAACTCAACAAGAARAAAACAAATAACCCAATTAAAAAATGGGCAAARGACCTGAATAGACATTTYTCAAAAGAAGACATACAAATGGCCAACAGATATATGAAAAAATGCTCAACATCACTAATCATCAAGGAAATGCAAATTAAAACCACAATGAGATATCACCTCACACCTGTTAGAATGGCTATTATCAAAAAGACAGAAAATAATAAATGTTGGYGAGGATGTGGAGAAAAGGGAACTATTGTACACTGTTGGTGGGAATGTAAATTAGTAYAGCCAYTATGGAAAACAGTATGGAGGTTCCTCAAAAAAYTAAAAATARAACTACCATATGATYCAGCAATCCCACTWCTGGGTATATATCCAAARGAATTGAAATCAGTATGTYGAAGAGATAYCTGCACTCCCATGTTTAYTGCAGCAYTATTCACAATAGCCAAGATATGGAAWCAACCTAAGTGTCCATCAAYGGAWGAATGGATAAAGAAAATGTGGTATATATACACAATGGAATACTATTCAGCCATAAAAAAGAATGAAATCCTGTCATTTGYARCAACATGGATGAACCTGGAGGACATTATGCTAAGTGAAATAAGCCAGGCACAGAAAGACAAATACTGCATGATCTCACTTATATGTGGAATCTAAAAAAGTCAAAYTCATAGAAACAGAGAGTAGAATGGTGGTTACCAGGGGCTGGGGRAKGGGGGAAATGGGAAGATGTTGGTCAAAGGGTACAAAGTTKCAGTTATGTARGATGAATAAGTTCTRGAGAYCTAATGTACAGCATGGTGACTATAGTTAATAATACTGTATTGTATACTTGAAATTTGCTAAGAGAGTAGATYTTAAGTGTTCTCACCACANACAAATGGTAACTATGTGAGGTGATGGATATGTTAATTAGCTTGAYTGTGGTAATCATTTCACAATGTATACATATATCAAAACATCACGTTGTACACCTTAAATATATACAATTTTTATTTGTCAATTATACCTCAATAAAGCTGRAAA
27 >L1MA10 3'-end of L1 repeat (subfamily L1MA10) - a consensus sequence
28 TTAATATCCAAAATATATAAAGAACTCYTACAACTCAACAAAAAAAAAACAAACAACCCAATTAAAAAATGGGCAAARGACTTGAATAGACATTTCTCCAAAGAAGAYATAYAAATGGCCAATAAGYACATGAAAARATGCTCAACATCAYTAATCATTAGGGAAATGCAAATCAAAACCACAATGAGATAYCACCTYACACCCATTAGGATGGCTATTATYAAAAAAMCAGAAAATAACAAGTGTTGRYGAGGATGTGGAGAAATTGGAACCCTTRTRCATTGCTGGTGGGAATGTAAAATGGTRCARCCACTRTGGAAAACAGTATGGHRGTTCCTCAAAAAATTAAAAATAGAATTACCATATGACCCAGCAATYCCACTYCTRGGTATATACCCAAAAGAATTGAAATCATGTTCYYAHAAAGATAYTTGTACACCMATGTTCATAGCAGCATTATTCAYAATAGCCAAAAGGTGGAAACAACCCAAATGTCCATCAATGRWTGAATGGATAAACAAAATGTGGTATATACATACAATGGAATATTATTCAGCCTTAAAAAGGAAGGAAATYCTGACAYATGCTACAACATGGATGAACCTTGARGACATTATGCTAAGTGAAATAAGCCAGTCACAAAAGGACAAATACTGCATGATTCCACTTATATGAGGTATCTAAAATAGTCAAACTCATAGAARCAGAGAGTAGAATGGTGGTTGCCAGGGGCTGGGGGRAGGGGGAAATGGGGAGTTGCTGTTCAATGGGTATAAAGTTTCAGTTATGCAAGATGAATAAGTTCTAGAGATCTGCTGTACAACATTGTGCCTATAGTTAATAATACTGTATTGTACACTTAAAAWTTGTTAAAAGRGTAGATCTCATGTTAAGTGTTCTTATCGCACAACAAAAAAATGGGGAACTTTTGGRRGTGATGGATATGTTCATTATCTTGATTGTGGTGATGGTWTCACGGGTGTNTACATATGTCAAAACTCATCAAATTGTACACWTTAAATATATGCAGTTTTTAGTGTATAATTATACCTCAACAAAGCTGTTTT
29 >L1MB3 3'-end of L1 repeat (subfamily L1MB3) - a consensus sequence
30 TTAATATCCAAAATATATAAAGAACTCYTACAACTCAACAAAAAAAAAACAAACAACCCAATTAAAAAATGGGCAAARGACTTGAATAGACATTTCTCCAAAGAAGAYATAYAAATGGCCAATAAGYACATGAAAARATGCTCAACATCAYTAATCATTAGGGAAATGCAAATCAAAACCACAATGAGATAYCACCTYACACCCATTAGGATGGCTATTATYAAAAAAMCAGAAAATAACAAGTGTTGRYGAGGATGTGGAGAAATTGGAACCCTTRTRCATTGCTGGTGGGAATGTAAAATGGTRCARCCACTRTGGAAAACAGTATGGHRGTTCCTCAAAAAATTAAAAATAGAATTACCATATGACCCAGCAATYCCACTYCTRGGTATATACCCAAAAGAATTGAAATCATGTTCYYAHAAAGATAYTTGTACACCMATGTTCATAGCAGCATTATTCAYAATAGCCAAAAGGTGGAAACAACCCAAATGTCCATCAATGRWTGAATGGATAAACAAAATGTGGTATATACATACAATGGAATATTATTCAGCCTTAAAAAGGAAGGAAATYCTGACAYATGCTACAACATGGATGAACCTTGARGACATTATGCTAAGTGAAATAAGCCAGTCACAAAAGGACAAATACTGTATGATTCCACTTATATGAGGTACCTAGAGTAGTCAAATTCATAGAGACAGAAAGTAGAATGGTGGTTGCCAGGGGCTGGGGGGAGGGGGGAATGGGGAGTTAKTGTTTAATGGGTACAGAGTTTCAGTTTGGGAAGATGAAAAAGTTCTGGAGATGGATGGTGGTGATGGTTGCACAACAATGTGAATGTACTTAACGCCACTGAACTGTACACTTAAAAATGGTTAAAATGGTAAATTTTATGTTATGTATATTTTACCACAATTAAAA
31 >L1MB7 3'-end of L1 repeat (subfamily L1MB7) - a consensus sequence
32 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCCATTTATATGAAATGTCCAGAATAGGCAAATCCATAGAGACAGAAAGTAGATTAGTGGTTGCCAGGGGCTGGGGGRAAGGGGAAATGGGGAGTGACTGCTAATGGGTACGGGGTTTCTTTTTGGGGTGATGAAAATGTTCTAAAATTAGATAGTGGTGATGGTTGCACAACTYTGTGAATATACTAAAAACCACTGAATTGTACACTTTAAAAGGGTGAATTTTATGGTATGTGAATTATATCTCAATAAARCTAT
33 >L1MC2 3'-end of L1 repeat (subfamily L1MC2) - a consensus sequence
34 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCCAACTATATGACATTCTGAAAAAGGNAAAACTATGGAGACAAGTAAAAAGATCAGWGATTNCTAGAGKGASTRGGARRGGGAGGGAAGAATAGGTGGAGCNCAGGGGATTTTTAGGGCAGCGAAACTATTCTGTATGATACTATAATGGTGGATACATGACATTATACATTTGTCAAAAYCCATAGAACTGTACAAYACAAAGAGTGAACCCTAATGTATGGACTTTAGTTAATAATAATGTATCAATGTTGGTTCATCAATTGTAACAAATGTACCACATTAATGCAAGATGTTAATAATAGGGTAAACTRTTGTGTGGGGGAGGGAGTATATGGGAACTCTCTGTACTTTCTGCTCAATTTTTCTGTAAACCTAAAACTGYTTCAAAAAATAAAGTCTATTAATAA
35 >L1MD1 3'-end of L1 repeat (subfamily L1MD1) - a consensus sequence
36 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCCATTTACATAACATTCTTAAAATGACAAAATTWTAGARWTGRAGARCAGATTCCTGGTTGCCAGGGGTTAGGGACGGGGGTGGGGGTGGAGGGAGGTGGGCATSSTGGAGTTCCCTGTGGTGATGGAAATGTTCTGTATCTTCACTGTCACTGTATCAATGTCAATATCCTGGTTGTGATAYTGTAYTATAGTTTTGTAAGATGTTACCATTGGGGGAAGCTGGGTGAAGGGTACACGGGATCTCTCTGTAYTATTTCTTACAATTGTCTGTGAGTKTAYAATTATTTCAAAATAAAGTTTAATTTAAA
37 >L1MD2 3'-end of L1 repeat (subfamily L1MD2) - a consensus sequence
38 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCCATTTATATAACATTCTTAAAACGACAAAACTATAGAGATGGAGAACAGATTAGTGRTTGCCAGGKGTTAGGGATRCAGGRAGGAGGTGGATGTGRYTATAAARRGGTAGCATGAGRGAATYTTTATGGTGATGGAACWGTTCTGTATCTTGAYTGTGGTGRTGGTTACACGAATNTATACATGTGATAAAATTGCATAGAACTAAATACACACACACACATAAGTACAAGTAAAACTGGCGAAATCTGAATAAGATTRATGGATTGTAYCAATGTCAATTTCCTGGTTKTGATATTGTAYTATAGTTTTCCAAGATGTTACCATTGGGGGAAGCTGGGTGAAGGGTACACGGGATCTCTCTGTAYTATTTCTTACAATTGTCTGTGAGTKTAYAATTATTTCAAAATAAAGTTTAATTTAAA
39 >L1ME2 3'-end of L1 repeat (subfamily L1ME2) - a consensus sequence
40 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCCATTTATATGAAATTCWAGAACAGGCAAAACTAATCTATAATGNTAGAAATCAGAATAGTGGTTGCCTCTGGKGAGGGTRAATGACTGGRAAGGGRCATGAGGGAATTTTCTGGGGTGATGGAAATGTTCTATATCTTGATCGGGGTGGTGGTTACACGAGTGTATACATTTGTCAAAACTCATCGAACTGTACACTTAAAATCTGTGCATTTTACTGTATGTAAATTATAYCTCAATTTTAAAAAA
41 >L1ME3a 3'-end of L1 repeat (subfamily L1ME3a) - a consensus sequence
42 YTTGTATCCAGAATATATAAAGAACTCTTACAACTCAACAATAAAAAAACAAACAACCTAATTAAAAAATGGGCAAAAGAYTTGAATAGATATTTCTCCAAAGAAGATATAYAAATGGCCAATAAGCACATGAAAAGATRCTCAACATCATTAGTCATCAGGGAAATGCAAATYAAAACCACAATGAGATAYCACTTCACACCCAYTAGAATGGCTAAAATTAAAAAGACAGRMAATAMCAARTGTTGGYRAGGATGTRGAGAAAYTGGAACHCTCATACAYTGCTGGTGGGAATGTAAAATGGTACARCYACTTTGGAAAACAGTTTGGCAGTTCCTCAAAAAGTTAAMAATAGAGTTACCATATGACCCAGCAATTYCACTCCTAGGTATWTACCCAAGAGAAATGAAAACATAYRTCCAYACAAAAACTTGTACACAAATGTTCATAGCAGCATTATTCATAATAGCCAAAAAGTGGAAACAACCCAAATGTCCATCAATRATWGAATGGATAAACAAAATGTGGTATATCCATACAATGGAATATTATTCAGCMATAAAAAGGAATGAAGTAMTGATMYATGCAACAACATGGATGAACCTTGAAAACATTATGCTAAGTGAAAGAAGCCARRCACAAAAGRCCACATATTGTATGATTCTATTTGCATAAAATACAAAACCAGGCAAAACTAATCAATGNTGTTAGAAGTCAGGATAGTGGTTGTTCTGGGAATAGTAATGACTGTAAGGRARCATGAGAGGGCTTTCTGGGGTGCTGGTAATGTTCTGTTTCTTGATCTGGGTGCTGGTTACACGGCTGTGTTCARTTTGTGAAAATTCATYAAGCTGTACACTTATGATWTATGCAYTTTTATGTATGTATATTATAYYTCAATAAAAA
43 >THE1b consensus sequence
44 TGATATGGTTTGGCTGTGTCCCCACCCAAATCTCATCTTGAATTGTAGCTCCCATAATTCCCACGTGTCGTGGGAGGGACCCGGTGGGAGGTAATTGAATCATGGGGGCGGGTCTTTCCCGTGCTGTTCTCGTGATAGTGAATAAGTCTCACGAGATCTGATGGTTTTATAAAGGGGAGTTYCCCTGCACANGCTCTCTTGCCTGCCGCCATGTAAGACGTGMCTTTGCTCCTCCTTCGCCTTCYGCCATGATTGTGAGGCCTCCCCAGCCATGTGGAACTGTGAGTCCATTAAACCTCTTTYCTTTATAAATTACCCAGTCTCGGGTATGTCTTTATTAGCAGCATGAGAACGGACTAATACA
45 >MSTa consensus sequence
46 TGATATGGTTTGGATCTGTGTCCCCACCCAAATCTCATGTTGAATTGTAATCCCCAATGTTGGAGGTGGGGCCTGGTGGGAGGTGATTGGATCATGGGGGCGGATTYCTCATGAATGGTTTAGCACCATCCCCTTGGTGCTGTYCTCGTGATAGTGAGTGAGTTCTCATGAGATCTGGTCGTTTAAAAGTGTGTGGCACCTCCCYCCTCTCTCTCTTGCTCCTGCTCTCGCCATGTGACGTGCCTGCTCCCCCTTCGCCTTCCGCCATGATTGNAAGCTTCCTGAGGCYTCCCCAGAAGCCGAGCAGATGCCAGCGCCATGCTTCCTGTACAGCCTGCAGAACCGTGAGCCAATTAAACCTCTTTTCTTTATAAATTACCCAGTCTCAGGTATTTCTTTATAGCAATGTGAGAACAGACTAATACA
47 >MSTc consensus sequence
48 TGCTACGGTTTGAATGTTTGTCCCCTCCAAAACTCATGTTGAAACTTAATCCCCAATGTGGCAGTATTGAGAGRTGGGGCCTTTRAGAGGTGATTGGGTCATGAGGGCTCTGCCCTCATGAATGGATTAATGGATTAACGTATTAATGGATTAATTGGTTATCACGGGAGTGGGATCGGTGGCTCTATCATAAAARYCATTTTGNCTCTCGNRTGNGCCCCTTCTTGCCCTTTCACGCCTTCCGCCATGTTATGACAGAGCACAAGGCCCTCACCAGAAACCAGATGCAGCCGCCATGATCTTGGACTTCCCAGCCTSCAGAACCGTGAGCAAAATAAACCTCTTTTCTTTATAAATTACCCAGTCTATGGTATTCCGTTAAAGCAGCACGAACGGACTAAGACA
49 >MLT1a (MLT1a subfamily) - consensus sequence
50 TGCTATGGACTGAATGTTTGTGTCCCCCCAAAATTCATATGTTGAAGCCCTAATCCCCAATGTGATGGTATTAGGAGGTGGGGCCTTTGGGAGGTGATTAGGATTAGATGAGGTCATGAGGGCGGGGCCCTCATAATGGGATTAGTGCCCTTATAAAAGAGACCYCAGAGAGCTCCCTTGCCCCTTCCGCCATGTGAGGACACAGTGAGAAGGCGCCGTCTACGAACCAGGGAATGAGCCCTCACCAGAAACTGAATCTGCCGGCGCCTTGATCTTGGACTTCCCAGCCTCCAGAACTGTGAGAAATAAATTTCTGTTGTTTAAGCTACCCAGTCTATGGTATTTTGTTATAGCAGCCCGAACAGACTAAGACA
51 >MLT1b (MLT1b subfamily) - consensus sequence
52 TGTTATGGGCTGAATTGTGTCCCCCCAAAATTCATATGTTGAAGTCCTAACCCCCAGTACCTCAGAATGTGACTGTATTTGGAGATAGGGTCTTTAAAGAGGTAATTAAGTTAAAATGAGGTCATTAGGGTGGGCCCTAATCCAATATGACTGGTGTCCTTATAAGAAGAGGAAATTWGGACACAGACACGCACAGAGGRAAGRCCATGTGARGACACAGGGAGAAGGCGGCCATCTRCAAGCCAAGGAGAGAGGCCTCAGAAGAAACCAACCCTGCCGRCACCTTGATCTCGGACTTCYAGCCTCCAGAACTGTGAGAAAATAAATTTCTGTTGTTTAAGCCACCCAGTCTGTGGTACTTTGTTACGGCAGCCCTAGSAAACTAATACA
53 >MLT1c (MLT1c subfamily) - consensus sequence
54 TGTTATGGGTTGAATTGTGTCCCCCCAAAATTGATATGTTGAAGTCCTAACCCCTAGTACCTCAGAATGTGACCTTATTTGGAAATAGGGTCWTTGCAGATGTAATTAGTTAAGATGAGGTCATACTGGAGTAGGGTGGGCCCTAAATCCAATATGACTGGTGTCCTTATAARAAGAGGAAATTTGGACACAGACACGCACACGGGGAGAAGGCCATGTGAAGACGGAGGCAGAGATTGGAGTGATGCAKCTACAAGCCAAGGAACGCCAARGRYTGCCAGCAAACCACCAGAAGCTAGGAAGAGGCAAGGAACAGATTCTCCCTCACAGCCYTCAGAGGARRCCAGCCCTGCCGACACCTTSATCTCGGACTTCTGGCCTCCAGAACTGTGAGAGAATAMATTTCTGTTGTTTAAGCCACSCAGTTTGTGGTACTTTGTTACGGCAGCCCYAGGAAACTAATACA
55 >MLT1d (MLT1d subfamily) - consensus sequence
56 TGTGGTAGGCWGAATAATGGCTCCCCAAAGATGTCCACGTCCTAATCCCCAGAACCTGTGAATATGTTACCTTACATGGCAAAAGGGACTTTGCAGATGTGATTAAGTTAAGGATCTTGAGATGGGGAGATTATCCTGGATTATCCGGGTGGGCCCAATGTAATCACAAGGGTCCTTAWAAGAGGGAGGCAGAGGGTCAGAGTCAGAAGAAGGAGATGTGACGATGGAAGCAGRRAGNGAAAACTCAACGTTGCTGGCTTTGAAGATGGAGGAAGGGGCCATGAGCCAAGGAATGCGGGCAGCCTCTAGAAGCTGGAAAAGGCAAGGAAACGGATTCTCCCCTAGAGCCTCCAGAARGAACGCGGCCCTGCCGACACCTTGATTTTAGCCCAGTGAGACYCATTTTGGACTTCTGACCTCCAGAACTGTAAGATAATAAATTTGTGTTGTTTTAAGCCACTAAGTTTGTGGTAATTTGTTACAGCAGCMAYAGGAAACTAATACA
57 >MLT1e (MLT1e subfamily) - consensus sequence
58 TGTGGTAGGCAGAATTCTAARATGMTCCCAATGATCCTCGCCTCCTGGCGTAATCTCCTTGAGTGTGAGTAGGACCTGTGACTTGCTTCTAGCCAACGGAATATGGCAAAGGTGATGARATRTCACGTGATTACGCGTACGTGATTATGTAASATTCAGTCTTTGMCGTCATTCTTGCCGAGAGACTCTCCTSCTGGTYTTGAAGAAGTAAGCTGCCACGTCATGAGNNNNCNNANNAGARYGCCGCAAGGCAAGGGNNTCTAGAGCTGAGAGTCGCCCTTACTGATGGGCAGCAAGAAGCAAGCCACCTCAGTCCTACAGCCGCAAAGAACTGAATTCTGCCAACAACCTAGTGAGCTTGGAAGCAGATCCTGCCCAGTCGAGCCTCCAGATGAGANCGCAGCCCTGGCTGACGCCTTGACTGCAGCCTTGNTAGACCTTGAGCAGAGGACCCAGCTAAGCCGTGCCCAGACTCCTGACCCACAGAAACTGTGAGATAATAAATGTGTGTTGTTTTAAGCCGCTAAGTTTGTGGTAATTTGTTACGCAGCAATAGAAAACTAACACA
59 >MLT1f (MLT1f subfamily) - consensus sequence
60 TGTGGTAGCCAGCCTCCAAGATGGCCCCCAATGATCCCTGCTCCTGGTATTCACAYCCTTGTATGGTCYCYTCCTACATTGARYYAGGGCTRGTCTGTGTGACCAATAGAATAGGGCAGAAGTGATGGCGTGTSACTTCCAAGAYTARGTCAYAAAWAACACTGTGGYTTCTGCYTTGNTCTCTTCGGGCTACTCACTCTGGGGGAAGCCAGCTGCCATGCTATGAAGACACTCAAGCAGCCTATGGAGAAGTCCACGTGGSAAGGAACTGAGGTCTCCTGCCAACAGCCAGCTTCGACYTGCCAGCCATGTGAGTGAGCCATCTTGGAAGCGGATCCTCCAGCCCCAGTYAAGCCTTCAGATGACTGCAGCCCCGGCTGACATCTTGACTGCAACCTCATGAGAGACCCTGAGCCAGAACTACCCAGCTAAGCTGCTCCTARATTCCTGACCCACAGAAACTGTGAGATAATAAATGTTTRTTGTTTTAAGCCACTAAGTTTTGGGGTAATTTGTTACGCAGCAATAGATAACTAATACA
61 >THE1BR THE-1B Mammalian LTR retrotransposon internal sequence - a consensus
62 GTAAATTGGTACCAGTAGAGTGGGGCGCTGCTGAAAAGATACCCGAAAATGTGGAAGCGACTTTGGAACTGGGTAACAGGCAGAGGTTGGAACAGTTTGGAGGGCTCAGAAGAAGACAGGAAAATGTGGGAAAGTTTGGAACTTCCTAGAGACTTGTTGAATGGCTTTGACCAAAATGCTGATAGTGATATGGACAATAAAGTCCAGGCTGAGGTGGTCTCAGATGGAGATGAGGAACTTGTTGGGAACTGGAGCAAAGGTGACTCTTGTTATGTTTTAGCAAAGAGACTGGCGGCATTTTGCCCCTGCCCTAGAGATTTGTGGAACTTTGAACTTGAGAGAGATGATTTAGGGTATCTGGCGGAAGAAATTTCTAAGCAGCAAAGCGTTCAAGAGGTGACTTGGGTGCTGTTAAAGGCATTCAGTTTTAAAAGGGAAGCAGAGCATAAAAGTTCGGAAAATTTGCAGCCTGACAATGCGATAGAAAAGAAAATCCCATTTTCTGAGGAGAAATTCAAGCCGGCTGCAGAAATTTGCATAAGTAACGAGGAGCCGAATGTTAATCCCCAAGACAATGGGGAAAATGTCTCCAGGGCATGTCAGAGATCTTCGCGGCAGCCCCTCCCATCACAGGCCCGGAGGCCTAGGAGGAAAAAATGGTTTCGTGGGCCAGGCCCAGGGTCCCCGTGCTGTGTGCAGCCTAGGGACTTGGTGCCCTGCGTCCCAGCCGCTCCAGCCATGGCTAAAAGGGGCCAACGTACAGCTCGGGCCGTGGCTTCAGAGGGTGCAAGCCCCAAGCCTTGGCAGCTTCCACGTGGTGTTGAGCCTGCGGGTGCACAGAAGTCAAGAATTGAGGTTTGGGAACCTCCGCCTAGATTTCAGAGGATGTATGGAAACGCCTGGATGTCCAGGCAGAAGTTTGCTGCAGGGGCGGGGCCCTCATGGAGAACCTCTGCTAGGGCAGTGCGGAAGGGAAATGTGGGGTCGGAGCCCCCACACAGAGTCCCTACTGGGGCACTGCCTAGTGGAGCTGTGAGAAGAGGGCCACCGTCCTCCAGACCCCAGAATGGTAGATCCACCGACAGCTTGCACCGTGCGCCTGGAAAAGCCGCAGACACTCAACGCCAGCCCGTGAAAGCAGCCAGGAGGGAGGCTGTACCCTGCAAAGCCACAGGGGCGGAGCTGCCCAAGACCATGGGAACCCACCTCTTGCATCAGCGTGACCTGGATGTGAGACATGGAGTCAAAGGAGATCATTTTGGAGCTTTAAGATTTGACTGCCCCGCTGGATTTCGGACTTGCATGGGGCCTGTAGCCCCTTTGTTTTGGCCAATTTCTCCCATTTGGAATGGCTGTATTTACCCAATGCCTGTACCCCCATTGTATCTAGGAAGTAACTAACTTGCTTTTGATTTTACAGGCTCATAGGCGGAAGGGACTTGCCTTGTCTCAGATGAGACTTTGGACTGTGGACTTTTGAGTTAATGCTGAAATGAGTTAAGACTTTGGGGGACTGTTGGGAAGGCATGATTGGTTTTGAAATGTGAGGACATGAGATTTGGGAGGGGCCAGGGGCGGAA
63 >MSTAR MSTa-Mammalian LTR internal retrotransposon sequence - a consensus
64 GAAWATTGGTACTGAGGAGTGGAGCATTGCTATAAAGATACCTGAAAATGTGGAAGCGACTTTGGAACTGGGTAACAGGCAGAGGTTGGAAGAGTTTGGAGGGCTCAGAAGAAGACAGGAAGATGAGGGAAAGTTTGGAACTTCTTAGAGACTTGTTAAATGGTTGTGACCAAAATGCTGATAGTGATATGGACAGTAAGGGCCAGGCTGACGAGGTCTCAGATGGAAATGAGGAACTTATTGGGAACTGGAGCAAAGGTCACTCTTGTTATACATTAGCAAAGAGCTTGGCTGCATTTTGCCCCTGCCCTAGAGATTTGTGGAAGTTTGAACTTGAGAGTGATGATCTAGGGTATCTGGCGGAAGAAATTTCTAAGCAGCAAAGCGTTCAAGATGTGACCTGGCTGCTTTTAACAGCTTACAGTCATATGCGAGAGCAAAGAAATCACTTAAAGTTGGAATTTATATTTAAAAGGGAAGCAGAGCGTAAAAGTTTGGAAAATTTGCAGCCTGGCCATGTGATAGAAAAGAAAAACCCGTTTTCTGGAGAGAAATTCAAGCAGGCTGCGGAGCGACCGTTTGCTAAAGAGATTAGCATAACTAAAAGGAAGCCAAGTGCTGATAGCCAAGACAATGGGAAAAAGGCCTCGAAGGCATTTCAGAAATCTTCGAGGTGGTCCTTCCCATCACAGGCCCAGAGGCCTAGGAGGACTGAATGGTTTCGTGGGCCAGGCCCAGGGCCCCGCTGCCCTGTGCAGCCTCGGGACACTGCTCCCTGCATCCCGGCTGCTYCGGCTCCAGCCGTGGCTCAAAGGGCCCCAGGTACAGCTCGAGCTGCCGCTTCGGAGAGTGCAAGCTATAAGCCTTGGTGGCTTCCACATGGTGTTAAGCCTGCAGGTGCACAGAATGCAAGAGTGAAGGAGGCTTGGCAGCCTCCACCTAGATTTCAGAGGATGTATGGGAAATCCTGGGTGCCCAGGCAGAAGCCTGCTGCAGGGACGGAGCCCTCACAGAGAACCTCTACTAGAGCAGTGCCAAAGGGAAATGTGGGGTTGGAGCCCCCACACAGAGTCCCCACCGGGGCACTGCCTAGTGGAGCTGTGGGAAGGGGGCCACTGTCCTCCAGACCCCAGAATGGTAGAGCCACTGGCAGCGTGCACCGCCAGCCTGGAAAAGCCGCAGGCATCAGACTCCAACCCGTGAGAGCAGCCACGTGGGCTGTGCCCAGCAAAGCCACAGGGGCGGAGCTGCCCAAGGCCTTGGGAGCCCACCCCTCGCACCAGCGTGCCCTGGATGCGAGACACGGAGTCAAAGGAGATTATTTTGGAGCTTTAAGATTTAATGACTGCCCTGCTGGGTTTCGGACTTGCGTGGGGCCTGTAGCCCCTTTCTTTTGGCCCATTTCTCCCTTTTGGAATGGAAATATTTACCCAATGCCTGTACCACCATTGTATCTTGGAAGTAAATAACTTCTTTTTGATTTTACAGGCTCATAGGTGGAAGGAACTTGCCTTGTCTCAGATGAGACTTTGGACTTTGGACTTTTGAGTTAATGCTGGAATGAGTTAAGACTTTGGGGGACTGTTGGGAAGGCATGATTGTATTTTGCAATGTGAGAAGGACGTGAGATTTGGGGGAACCAGGGGCAGAA
65 >MLT1R MLT1-Mammalian LTR retrotransposon internal sequence - a consensus
66 GATTTTGGCACTAGGAAGTGGGGTGCTTACGTAACAAATACCTAAAAATGTGGAAGCGACTTTGGAACTGGGTAATAAGTAGAGGCTGGAAGAGTTTTGAGGTACATGYTAGAAAAAGCCTAGATTTCCTTGAAGAGACTGTTGGTAGAAATATGGATATTAAAGGYAATTCTGGTGGGGGGCTCAGAAAGGAAGWGGAGAGCTATAGAGAAAGCTCCCGTCGTCTTAGAGAATACAAAAATCGTCATGAACAGAATGTTGCTAGAAATATGAATGTTAAAGGTGCTTCTGGTGAGGTCTCAGACGGAAATGAGGGAGATGTTATTGAAAATTGGAGGAAAGGTGATCCTTGTTATAAAGTAGCAAAGAACTTGGCTGAATTGTGTTCATGTCCTAGGGCTTTATGGAAAGTAGAACTTGYAAGTGATGAACTKGGATATTCAGCTGAGGAAATTTCTAAGCAAAGTGTTGAGGGCGCAACCTGACTTCTCCTAACTGCTTATAGTAAAATGTGAGAGACATAAAGATGGAANTGTTGAGTAAAAAGGAACCAGAACGTAAAGATTTGGAAAATTCTCAGCCTGATCATGTAACAGAAANNNCAATAGCGTTCTCTGGAAAGAANACCAAGGATGTNNCCGNGCAACCGTTTGCTAAAGAGATTAGRATCGTGACTCGTGGGTCCAATCAACCATCTCAGCARAARCCARGAATAGAGATGRGGTTATTTAGGAAATATCTGTGGAGGACTCTCTTATCTGATGGCTCGAACCCCTATGACTTNCATAGGAGACCGACAAGGNTTTTGAGAATNTTACACCAGCAGAAACACTGCCAACTTGGACTRAAGGGRACAGAGACGAGAAAAAATGAAGGAAGRGTGGCAGACCGAAGGTGGGGCTGTCTCGTTTCAGAGCATGGKGTCACCCCAGCGGGCCCGGAAGATGAATCTCAGGACTCAGAGGCATTAGCCTCCAGCCTTAAGATCTAATGAAGTTTGCCCTGCTGGGTTTTGGACTTGCTTGGGACCNGTGACTCCTTTCTTYYYTTCYATTTCTCCCTTTTGGAATGGGAATATCTATCCTATGCCTGYCCCACCGTTGTATTTTGGAAGCAGATAACTTGTTTNATTRCACAGGTCCACAGATGGAGAGGAATTTTGCCYCTGAATGAATCTYACCCTGAGTYTCTNCCAYACYTGATGYRGRTGATATTTCGCTGAGATTGTGGACTAAGAGTTGGTGCTGGAAGGGGTTAGACATTGGGGAGATGTTGCTATGGGATGCAGGGATTTTGCATGTGAGAAGGACATGATTATGGGGGGAGCGGAGGGCAAAC
67 >MLT2A1 Interspersed repeat MLT2A1- a consensus
68 TGTGATGGTTAATACTGAGTGTCAACTTGATTGGATTGAAGGATACAAAGTATTGATCCTGGGTGTGTCTGTGAGGGTGTTGCCAAAGGAGGTTAACATTGGACTCAGTGGGCTGGGGAGAGGCAGACCCACCCTTAATCTGRGTGGGCGCMATCYAATCAGCTGCCAGCGTGGCTAGAATATAAAGCAGGCAGAAAAATGTGAAAAGAGAGACTGGCCTAGCCTCCCAGCCTACATCTTTCTCCCGTGCTGGATGCTTCCTGCCCTTGAACATCAGACTCCAAGTTCTTCAGTTTTGGGACTCGGACTGGCTCTCCTTGCTCCTCAGCTTGCAGACGGCCTATTGTGGGACCTTGTGATCGTGTGAGTTAATACTTAATAAACTCCCCTTTATATATATCTATTCYATTAGTTCTGTCCCTCTAGAGAACCCTGACTAATACA
69 >MLT2B2 Interspersed repeat MLT2B2 - a consensus
70 TGTGATGGTTAATTTTATGTGTCAACTTGACTGGGCTAARGGGTGCCCAGATAGCTGGTTAAACATTATTTCTGGGTGTGTCTGTGAGGGTGTTTCCAGATGAGATTAGCATTTGAATCAGCGGACTGAGTAAAGAAGATTGCCCTCACCAATGTGGGCGGGCATCATCCAATCCGTTGAGGGCCTGRATAGAACAAAAAGGCAGAGGAAGGGTGAATTTGCTCTCTCTCCTTGAGCTGGGACATCCATCTTCTCCTGCCCTTGGACATTAGAACTCCAGGTTCTCGGGCCTTCGGACTYCGGGACTTGCACCAGCAGCCCCCCAGATTCTCAGGCCTTCGGACTCGGACTGARYYACGCCACCGGCTTCCCTGGTTCTCCAGCTTGCAGACGGCATATCGTGGGACTTCTCAGCCTCCATAATCACGTGAGCCAATTCCCCTAATAAATCYCYTCTATCCATCCTATTGGTTCTGTCTCTCTGGAGAACCCTGACTAATACA
71 >MLT2C2 Interspersed repeat MLT2C2 - a consensus
72 TGTGATAGTTAATTTTATGTGTCAACTTGGCTAGGCTATGGTGTCCAGACGTTTGGTCAAACAYCAGTCTAGATGTTGCTGTGAAGGTATTTTRTAGATGTGATTAACATTTAYAGTCAGTTGACTTTAAGTAAAGGAGATTACCCTCCATAATGTGGGTGGGCCTCATCCAATCAGTTGAAGGCCTTAAGAGCAAAGACTGAGGTTTCCCGAGGAAGAAGAAATTCTGCCTCAAGACTGCAACGTGGAAATCCTGCTGNTTTWCCAGCCTCCAAGCCTTCGGACTCGAACTGCAACATCARCTCTTSCCTGGGTCTCCAGCCTGCCGGCCTACCCTGCAGATTTCGGACTTGCCAGCCTCCACAATCGCGTGAGCCAATTCCTTAAAATAAATCTCTCTCTACACACACCCTATTGGTTCTGTTTCTCTGGAGAACCCTGACTAATACA
73 >MLT2D Interspersed repeat MLT2D - a consensus
74 TGTGATAGTTAATTTTATGTGTCAACTTGGCTAGGCTATGGTGTCCAGACGTTTGGTCAAACATTAGTCTGGGTGTTTCTGTGAAGGTTATTTTTTGGATGAGATTAACATTTAAATCGGTAGACTGAGTAAAGCAGATTACCCTCCCTAATGTGGGTGGACCTCATCTAATCAGTTGAAGGCCTGAATGGAAAAAAAGGGCTGACCCTCCCCCAAGTAAGAGGAAATTCTGCCTGCCTGATNGTCTTCGAACTGGAATATCAGCTCTGCGGATTTTGGACTTGCCAGCCTCCATAATTGCATGAGCCAATTCCTTATAATAAATCTATCTACTCTCTCTACACACACCCTATTGGTTCTGTTTCTCTGGAGAACCCTGACTAATACA
75 >LTR1 LTR from human endogenous retrovirus-like sequence (HUERS-P2).
76 TGATATGGGAGTGCTGGGAAGGGAAGAGCGTGGTCCCTTTAAATGATACAGAAGGGGGAAAGGAAGTGCTGTGTGGAGGAGGATGTGGTCCCTGGCTAGTACTCCAACCACACAGACCTAGGTTAAGGACAGGCATTTTTGTTGCATTTCCCAAGACCACCCTGGCCTGCCATGCCCCCATCCTGTGCCTATAAAAACCCAAGACCCTAATAAGGCAGAGATAGAAGCAGCTGGACGTCATGAGGAACACATCAGTGGAAGAGCACACAAGCGGCTAGTCATCAAGAGCTCACCAGTGGAAGAGCAGCCCGATAGGCACTGGCACGCAGGCAGGTACCGGCATGCCAGCAGGCCATCGACTGGCAAAATGATGCCGAATTTGGCTGGAGTGGTCAGAGAAGAGCCAGGTCACTGAGCTGCCGGACTCCAGGGGAAAACCATCTCCCTTCTGGCTCCCCCATCCACTGAGAGCTATTTCTACTCAATAAAACCTTGCAGTCATTCTCCAGGCCCACATGTGATCTGATTCTTCTGGTACATCAAGGCAAGAAACCCCAGGATACAGAAAGCCCTCTGTCCTTGTGACAAGGTAGAGGGTCTAACTGAGCTGGTTAACACAAGCTGCCTGTAGATGGCAAACTAAAAGAGCACCTTGTAACACATGCCCACTGGAGCTTCAGGAGCTGTAAACATTCACCCCTAGACACTGCCATGGGATTGGAGCCCCACAGCTTGCCTGTCCAAATGCTCCCCTAGAGGTTTGAGCAGCAGGGCACTGAAGAAGTGAGCCACACCCCCATCACATCCCCTGTGAGGGGAACAAGGGAACCTTTCCTATTTCA
77 >LTR2 LTR from human endogenous retrovirus (4-14), 3' long terminal repeat
78 TAAGGAAGGAGACCACCTCTCCCATTGTCTCCTGTTTCATGAGAAAGCAAAAAGTTAAAAAAAGAAGCAGAAGTGAGATCAATGGCCAGATGGTTTAGTGCCAAGAACCAGGCCTGGTAGTTAAACATCAACTCCTGACCTAACCGCTTGTGCTATCCATAGATTCCAGATATTGTATGAGGAAGACTTGTGAAACTTTCTGTTCTGTTCTGCTAGCCCCCATCACTGATGCATGTAGCTCTCAGTCATGTAGCCCCCACTTGCACAATGTATCATGACCCTTTCACGTGGACCCCTCAGAGTTGTAAGCTCTTAAAAGGGACAGGAATCTTTACTTTGGGGAGCTCGGATCTTGAGACGCGAGTCTACCAATGCTCCCAGCTGATTAAAGCCTCTTCCTTCATAGAACCGGTGTCTAAGAGGTTTTGTCTGTGACTGTTCCTGCTACA
79 >LTR3 LTR from human DNA related to mouse mammary tumor virus (MMTV) 3' LTR
80 GTTGGAGGCCGAAAGAATAGGGTCGTGACCAACTCAGTATACCACTGGAGGCTATATGAGCAAACAGCAAACTGTTCTCATGAATGCAGGATGCTGGCAAGCTGACAACTGCATCTGCCACCAGAAGGAATGCTGAGGGCAGTCATACCCCACGTGCAGTGTTCCTTGTGGTTATCTATAGGAATATCTGGAGGCTGTTGTATAAAGAAAGCAATTATGTGAGCCCGTGATAAATCAAGCAGCTGACCAACCATTACCTCTTCCTCCCTGTTGATTCTACCTAATAAATACAAAGGGCTGTAGAAGCTCAGGGCCCTTGTTCCCTAGAAGAAAGGAGCCGCCTGTCTCCTTCTTTAAAACAGATCTTTTTGTCTTTGTCTTCATTTCTGCATTTGTTCTCTTTTGTTCAGTCCCAAACCGACAGCCATA
81 >LTR4 LTR from human endogenous retrovirus ERV3, POL-ENV-3'LTR region
82 GAAGCAGGAAATATAAAAGGAAAAACAAGTAAAGGGAAAACAAGTCCTTTCCTGACCAGTCTGACTCACTCCAAAGTCCTGCTGGAGCTATGATAATTATCTGCAAGGCCAGGCAGGGGCTCCGAAGGAGGGCTCCAGGAGCAGGGATGAGAAAAACAAGTTCTCCTTATCAGTTTCCCTGTTTGAAATTCTCTCCCCATAACATTATTCTTTGTTCTGCTCTCACAACTATTTTTGTAACTATTTCTGCAAGTCTGTAAAGATTTTGTAAGTTCTTGTTTTTCTTTCTGTAGCATGGCAAGGTCACAAGACATGTTTAAGTAAGGTAGGCTCATGTTGCAAATCCTGTTGTAAAACCTGTCACGGTATGATTAACTGCCTTTGTTCTGCTTCTGTAAGACTGCTTTCTCACCTCGCAGGTTTTGCGCCAAAAACCCGACTTGCCCCTGCCTGATGCATGTATAAAAGTCAAGCCCGTCTTTGTTCCGGGCTCAGCCTTTGGATGTTAATCCGCTGGGCCAGTGGCCACCTAAATAAAACCTTCCTGTTGCACCCAGTGATCTCTCCGGCCTCCTGATACCCACAACA
83 >LTR5 LTR from human endogenous retrovirus 5' LTR, clone HERV-K18
84 TGTGGGGAAAAGCAACAGAGGTCAGATTGTTACTGTGTCTGTATAGAAAGAAGTAGACATAGGAGACTCCATTTTGTTCTGTACTAAGAAAAATTATTCTGCCTTGAGATGCTGTTAATCTATGACCTTACCCCCAACCCCGTGCTCTCTGAAACATGTGCTGTGTCAAACTCAGGGTTAAATGGATTAAGGGCGGTGCAAGATGTGCTTTGTTAAACAGATGCTTGAAGGCAGCATGCTCATTAAGAGTCATCACCACTCCCTAATCTCAAGTACCCAGGGACACAAAAACTGCGGAAGGCTGCAGGGGCCTCTGCCTAGGAAAGCCAGGTATTGTCCAAGGTTTCTCCCCATGTGAGAGTCTGAAATATGGCCTCGTGGGAAGGGAAAGACCTGACCGTCCCCCAGCCCGACACCCATAAAGGGTCTGTGCTGAGGAGGATTAGTATAAGAGGAAAGCATGCCTCTTGCAGTTGAGACAAGAGGAAGGCATCTGTTTCCCACCCATCCTTGGGCAATGGAATGTCTCGGTATAAAACCCGATTGTACGTTCCACCTACTGAGATAGGGAGAAACCACCTTAGGGCTGGAGGTGGGACATGCAGGCAGCAATACTGCTTTGTAAAGCATTGAGATGTTTATGTGTATGCATATCTAAAAGCACAGCATTTAATCCTTTACCTTGTCTATGATGCAAAGACCTTTGTTCACGTGTTTGTCTGCTCACCCTCTCCCCACTATTGTCTTGTGACCCTGACACATCTCCCTCTCAGAGAAACACCCACGAATGATCAATAAATACTAAGGGGACTCAGAGGCTGGTGGGATCCTCCATATGCTGAACGTTGGTTCCCCGGGCCCCCTTATTTCTTTCTCTATACTTTGTCTCTGTGTCTTTTTCTTTTCCAAGTCTCTCATTGCACCTTACGAGAAACACCCACAGGTGTGGAGGGGCAACCCACCCCTTCA
85 >LTR6 LTR from  human SSAV-related endogenous retroviral LTR-like element
86 TGGCCAGATTCCTGCTTAGATTCATCACTCACATCAAAAAGGCCAACAGAGCCCAACAAGAAACATAGGTCCCCAAGCATAGGCCAGGCCCCTTAAAACTGTGCCTAAGTCGAGTGAAGCCTTTAGATTAATTCTTTTTATTTATCTCTCTTGTTTATTTCCACCTGTTATGCCCTCCGTGCCTTCCTATTCTTCTCACTTCTTTCACGACAGGACGTGTATTTGCAAACACTACTTGGAAGGCAAGAACCTCCAAGAAAGTCTCTTTTGCAGTCGATTTATGTGCTTTGTTCCCAGAGCCTGCCCATAACCTTGAAGAACAATGCAACCTGCCGGTCATAGAAGCGGGGAACATCAACCTTGCTACAGGGTTCGGACACACAGGAAGCCGGACTGGATGTAAAAACTCTAAAAGTGAAAAAAAAAGGACTCCAGAGCATTGACTTTTACCTCTGTCCTAAAAATCACCCTGACTCTAGTTGTCACGATTCTTACCAATTTTTCTGCCCTCACTGGTTTTGTGTGACCCTAGCCA
87 >LTR7 LTR from human endogenous retrovirus RTVL-H2
88 TGTCAGGCCTCTGAGCCCAAGCTAAGCCATCACATCCCCTGTGACTAGCACATATACGCTCAGATGGCCTGAAGTAACTGAAGAATCACAAAGAAGTGAAAATGCCCTGCCCCACCTTAACTGATGACATTCCACCACAAAAGAAGTGAAAATGGCCGGTCCTTGCCTTAAGTGATGACATTACCTTGTAAGAGTCCTTTTCCTGGCTCATCCTAGCTCAAAAATCTCCCCTACTGAGCACCCTGCGACCCCCACTCCTACCCGCCAAAGAACAACCCCCCTTTGACTGTAATTGTCCTTTACCTACCCAAATCCTATAAAACAGCCCCACCCCTATCTCCCTTTGCTGACTCTCTTTTCGGACTCAGCCCGCCTGCACCCAGGTGATTAAAAGCTTTATTGCTCACACAAAGCCTGTTTGGTGGTCTCTTCACACGGACGCGCATGAAA
89 >LTR8 region
90 TGAAACCGTCTTTGCAAAATTATAACTGAGATAGTGAAAGAGATTTAACTTAACTGCTTTTATCTTGCTTTTAACCTTTAAGCTGTCCTTGTTTATTCCTGGGTGTGGGCTGAACTAACTTTTGGAGAAACTTAGTTTATAGTTTATAGTTTAAACAAAGACAGTAACAGCCCTTTCCCAAGCAGACCTCCTTCATGCCTGGGGACTAGATTGCTTCTGTAGGACTAATGTTAGCGACCAAATTAAAAATTATGGTTTAGGAGTTATGCAGTTTGAGGCTACAAAATTTTAACCCTCTCTAAACTGCTCCTAAGATCAGTGCTTGAGATATTTTGCAGACCCTGCCCTTGACGGATCAGCTGGCACCAACCAGATCAATCAACTGGCTCATCTGATCTTGCGGCCCCCACCCAGGAACTGACTCAGCGCAAAAAGACAGCTTCAACTTCCTATGATTTCATCCCTGACCAATCAACACTCCTGGCTCACTGGCTTCCCCCCACCCACCAAGTTATCCTTAAAAACTCTGATTCCTGAATGCTCAGGGAGACTGATTGGAGTAACAATAAAACTCCAGTCTCCCACACAGACGGCTCTGTGTGAATTACTCTTTCTCCATTGCAATTCCCCTGTCTTGTTGAATCGGCTCTGTCCAGGTAGTGTGCAAGGTGAACCCCTTGGGTGGTTACA
91 >LTR9 LTR from human endogenous retrovirus-like sequence (HUERS-P3)
92 AAAGAATAAATCACTGATATAAGAGTTAAGAAAAAATCACTTAGGCAGAGAGCAAGGGTATGGGAGTCCTCAGTAAGGCTTTTATTTTTAATGAAAAGCAGCCCCAAATCATTTTCTAACAAAAAGCACCCTGCAAGCTGGAAGTTTGCACAGGTGGATGCTGGCAGGAACTAAGGATTAGATATGTTCAAGATGGTGGTTCCATCTTCCCTTCTTTGCCAGCCAGGTGTACTGTAAAGGAGCAGACAAGATGGCGCTAATCAACTGGAAAGCCCAGTTGCATAAAAAGATTAGGCTTCCCTGCGCACCATGCAAACGTCATATCTGATCAAACCAATCTATGAGCTCTATGTAAATCAGACACCACTTCCTCAAACTGGACTATAAAACTCGATGGATTCACCACCAGCTGGTCTTTTCCGCTTGGAGACCCCTTCCTCTATAGAGGAAGCTGTTTCTCTTTGTCTTCTCTCCTACCCATTAAACCTCTGCTCCTAAACTCCTCATGTGTGTCCATATCCTAAATTTTCCTGGCACGTGACAACAAACCCCAGTGTATACACACCCCAGACAACATAGCCACTTCAAAATGGGGGCTCGTCTGGGAT
93 >LTR10 Human DNA sequence 5'-flanking minisatellite PMS32
94 TGTTGTAAATAAATTTTTGGTGCTGCAAAAGAAATACCACTCAAACATAAGTTTAATTTTCTCAGCAAGGCAATTTTACTTCTCTAGAAGGGTGCGACTCGCAGATGGAGCAATGGCCAGAGCACACCTGAACAAGGGAGGGGAAGGGGTTCTGATTCCTGACACAGGTAGCCCCTACTGATGCGTCGTTCCCGTATCGGCTAGGGTTGGACTGCACAGTCTAAGCTAATTCCGATTGGCTACTTTAAAGAGAGCAGGGGTATGAGCCAGAGTGGCGGGGTGAGTAGTTTGGTGGGAAGGGTGGTT
95 >LTR11 LTR from human HTLV-I related endogenous retroviral sequence (HRES-1/1)
96 TGTGTTTCTGCAGGATGTACAGCCCTCCCAGCACGGTGCTCGCTTCCCTAATGCCATTCCACAGTATTTGTTGCAGAGAAGGAAGGCAGCATGCCAGGACAGATGGAGACAGGACTAATTTGGCCTGAGGTATGTAATTTTGAACTTGAGCCTCTCTCTGGGACTGTAAAACTCCAAATCAAAGCTAATCTGAGAATACATACATCTGAAAGATGATTAGGACTGTAAACATCTATTAATATTCAACTCTGATACAAAGTACAAGTTGTTTATTCTTACCACGCAAGGCCAAAAAAGGGGAGAAAAAAAAAAAAGCACACAGCATATGCACTGGAAAGTTTCGCTTATTCAAAACAGTATTTGTCAAGCACCTCCAGTCTGGTGCTGCAGGGGAAACAAAGATTAAACAGCCAGGCGGACACTGCTCTGCTTCCAAGGTGCTTACGGTCTTAAGAAGGAGACAAGACATGTTTATAAATAGCCAAAATGCAACCCAGAAAAGGCTAAAAAACACTGAGAGGGAGGGAGAAATAAACGAAGCAAGAGGTCTCCGGAGGAAGAGATGAATGAATTAGCCTATTAATAACTCCGTCACTGTAATCCCAATGTAAAGCAAGAATTCCAAACCAGGAAAGGTCAAACTGAAGTATTTGAGGAACACAGGCGTCGCCTAAGCCCTTCACA
97 >LTR12 LTR from human ERV9 endogenous retroviral sequence (HRES-1/1)
98 TGTATCTAGTTAATCTGGTGGGGAGTTGGAGAATCTTTATGTCTAGCTAAGGGATTGTAAATACACCAATCAGCACTCTGTATCTAGCTCAAGGTTTGTAAACACACCAATCAGAACCCTGTGTCTAGCTCAGGGTTTGTGAATGCACCAATCAGCACTCTGTATCTAGTTAATCTGGTGGGGACTTGGAGAATCTTTATGTCTAGCTAAGGGATTGTGAATGCACCAATCGGCACTCTGTATCTAGCTCAAGGTTGTAAATGGACCAATCAGCACTCTATGTCTAGCTCAGTGTTTGTAAATACACCAATCGACACTCTATCTAGCTAATCTAGTGGGGACGTGGAGAACTTTTGTGTCTAACTCAGGGATGTAAATGCACCAATCAGAACCCTGTCAAAATGGACCAATAGCTCTCTGTAAAACAGACTGACTTTCTGTAAAATGGACCAATCAGCAGGATGTGGGTGGGGCCAGATAAGAGAAGAAAAGCAGGCTGCCTGAGCCAGCAGTGGCAACCCGCTTGGGTCCCCTTCCACACTGTGGAAGCTTTGTTCTTTCGCTCTTTGCAATAAATCTTGCTGCTGCTCACTCTTTGGGTCCACACTGCCTTTATGAGCTGTAACACTCACCGCGAAGGTCTGCAGCTTCATCTGAAGCAGCGAGACACGAACCCACCAGGAGGAACAAACAACTCCGATGCGCTGCCTTAAGAGCTGTAACACCGCGAGGTCTCGAGCTTCACTCCTGAGCCAGCAAGACCACAAACCCACCAGAAGGAAGAAACTCAGGAAAACAGCCGAACATCAGAAGGAATAAACTCTGGACACACCACCTTTAAGAACTGTGACACTCGCTGCGAGCGTCTGTGGCTTCA
99 >LTR13 LTR from a  putative human endogenous retrovirus
100 TGTGGGCCGCAAGCCAGGGAGCTGCCCAGGCAAGAGCCTGAAGGCACAAGCTGTTCCAGTACAGCAAAGAAAATAATTAGAATAAGAAAAGTTTTACTAGAGATAGGAAACGGATAGGATTATATCTGACTATTATTAATCATTAGTTTGTAGCATCACTCTTTGTTCTATTACCATAATGATCTCTGTTCTATTATGATTACCTTGGGGGAAACCAGGCCACACAGAGTTAGGAGCTGAAGGGCCACAGTGAGAGGTGACCAGAAGACGAGAGTGTGAGCCCTCATTCACGCCCAGAGAAGGGCCGCTGGAGGGCTCCTTGGCCTAGCGGTAATGCCAGTGCCTGGGAAGGCCCTGGTTACTTAGCAGGCCTTGGTCTAGCGGTGGCCCCAGTGCCTGGGAAGGCACCCGTTACTTAGCAGACCCGGAAAGGAATCTCCCTCTCTCCAGGGGAGACAGAGAACGCTCCGCTCCACCACCTCTTGTGGGAGGTCTGACATTAGCCAGGCCGGGCCGAGTCATCCGGAGGCTCCAACGTCTGTCTCCCTGTGATGCTGTGCTTCAGTGGTCACGCTCCTTGTTCACTTTCATGTTCAGCCTGTGCACCTGGCTCCTCCTTTTAAGTTCTTAGAAGACAGCAGTAGCAGAACTAGTAGGAGTACCACAGTCTTCGATCTTTCTGATAAGTGCATAGAAGAAACGCTGACGTTTGCTGTCCTCCCTCTCCACCTCGGCTACCACAAAGGGAAAGGCCCCCTGTCCAGTGGACACGTGACTCGCGTGACCTATCGATCATTGGAGATGACTGGCACTCCTTACCCTGCCCCCTTGCCTTGACTACAATAAATAGCAGCGCCTCCAGGCACTCGGGGCCACTACCTGTCTGTCTCCGCGCTTTGGTGGCAGTGGTCCCCCGGGCCCAGCTGTCTTTCTTCCTATCTCTTTGTCTTCTGTCTTTATCTCTTCGATCTCTCGTCTCCGCACACACGCGAAGAGAAAACCCACAGACCCGGTAGGGGTGGACCCTACA
101 >MER1A Nonautonomous DNA transposon
102 CAGGGGTCCCCAACCCCCGGGCCACGGACCGGTACCGGTCCGTGGCCTGTTAGGAACCGGGCTGCACAGCAGGAGGTGAGCGGCGGGCGAGTGAGCGAAGCTTCATCTGTAKTTACAGCCGCTCCCCATCACTCGCATTACCGCCTGAGCTCCACCTCCTGTCAGATCAGCGGTGGCACTAGATTCTCATAGGAGCGCGAACCCTATTGTGAACTGCGCATGCGAGGGATCTAGGTTGCGCGCTCCTTATGAGAATCTAATGCCTGATGATCTGTCGCTGTCTCCCATCACCCCCAGATGGGACCGTCTAGTTGCAGGAAAACAAGCTCAGGGCTCCCACTGATTCTACATTATGGTGAGTTGTRTAATTATTTCATTATATATTACAATGTAATAATAATAGAAATAAAGTGCACAATAAATGTAATGCACTTGAATCATCCCGAAACCATCCCCCCCCCCTGGTCCGTGGAAAAATTGTCTTCCACGAAACCGGTCCCTGGTGCCAAAAAGGTTGGGGACCACTG
103 >MER1B Nonautonomous DNA transposon
104 CAGGGGTCCCCAACCCCCGGGCCGCGGACCGGTACCGGTCCGTGGCCTGTTAGGAACYGGGCTGCACAGCAGGAGGTGAGCGGCGGGCGAGTGAGCATTACCGCCTGAGCTCCGCCTCCTGTCAGATCAGCGGCGGCATTAGATTCTCATAGGAGCGCGAACCCTATTGTGAACTGCGCATGCGAGGGATCTAGGTTGCGCACTCCTTATGAGAATCTAATGCCTGATGATCTGAGGTGGAACAGTTTCATCCCGAAACCATCCCCGCCCCCCGGTCCGTGGAAAAATTGTCTTCCACGAAACCGGTCCCTGGTGCCAAAAAGGTTGGGGACCACTG
105 >MER2 Nonautonomous DNA transposon
106 CAGTCGYCCCTCCGTATCCGTGYGTTCCACATCCGTGGATTCAACCAACCGCGGATCGAAAATATTCAGGYAAAAAATTGYATGGTTGCGTCTGTACTGAACATGTACAGACTTTTTTNCTTGTCATTATTCCCTAAACAATACAGTATAACAACTATTTACATAGCATTTACATTGTATTAGGTATTATAAGTAATCTAGAGATGATTTAAAGTATACGGGAGGATGTGCGTAGGTTATATGCAAATACTACGCCATTTTATATCAGGGACTTGAGCATCCGCGGATTTTGGTATCTGCGGGGGGTCCTGGAACCAATCCCCCACGGATACCGAGGGATYACTG
107 >MER3 Nonautonomous DNA transposon
108 CAGCGCTGTCCAATAGAACTTTCTGTGGTGATGGAAATGTTCTATATCTGCGCTGTCCAATACGGTAGCCACTAGCCACATGTGGCTAYTGAGCACTTGAAATGTGGYTAGTGCGACTGAGGAACTGAATTTTTAATTTTATTTAATTTTAATTAATTTAAATTTAAATAGCCACATGTGGCTAGTGGCTACCATATTGGACAGCGCAG
109 >MER4A a consensus
110 TGTGAAAGGAAAATAAATCTCGGGRCCCCMAAATCACTAAGCCAAAGGGAAAAGTCAAGCTGGGAACTGCGTYAGGCAAACCTGCCTCCCATTTTATTCCTAAATAAGATAGCTACAAAGATAAAAGGCTACATACCTCTCTCACAATTTYCYACAAGGAAATTCCTTGCGGACCTCAAGATCTTTACCCTAAAACAGTTCTGYTGAMYTTCACCTTGGCAWTGYAAATGGRTACAGGACAAAGGTACAGAACTGAAAGTCATCCCTCTGCTCACCTGAGACAAATGCATATCTGATTGCTTCCTCTGCCCTATTGTTTATGTAAAAATGCAGATTCACTGAGCCAGACTMAATTGTGTATTCAGTGAAARGCTGATCARRGACTCAAAAGAATGMAGCCWTTTGTCTCTTATCTACCTATGACCTGGAAGCCCCTRCTTCGAGTTGTCCCGCCTTTCCAGACCGAACCAATGTACATCTTACATATATTGATTGATGTCTCATGTCTCCCTAAAATGTATAAAASCAAGCTGTRCCCCGACCACCTTGGGCACATGTCGTCAGGACCTCCTGAGGCTGTGTCACGGGTGCGTCCTTAACCTTGGCAAAATAAACTTTCTAAATTGAYTGAGACCTGTCTCAGATACTTTTGGGTTCACA
111 >MER4B a consensus
112 TGTAAACCAAAAATAAAATTCTAAGKCCCCCAACCGTCTGAATGGACYCCTCCTCTYGGCCAAGGGCAYTCCAAAGYTAACCTGRAAAACTAGTTCAGGCCATGATGGGAAGTGGGGGTCGGACACGCCTCATTATACCYTCCYYCTTCTGGAATTCAGGCACAACTGACCAGCATTAACATCAACACAGACNTTAAGTCTGATAAGAAACAGTTTACAAYCTRTTCTCTCTGAAGCCTGCTANCTGAARGCTTCATCTGCACGATAAAACTTGGTCTCCGCAACCCCTTATNTCATAACCCGGACATTCCTTTCCATTGATCTYAANTCTTCAACCARTTGCCAATCAGAAAATCTTTGAATCTACCTATGACCTGGAAGCCCCCGCTTCGAGTTGTCCCGCCTTTCCGGACCGAACCAATGTACATCTTACATGTATTTGATTGATGCCTCATGTCTCCCTAAAATGTATAAAASCAAGCTGTRCCCCGACCACCTTGGGCACATGTKGTCAGGACCTCCTGAGGCTGTGTCACGGGTGCGTCCTTAACCTTGGCAAAATAAACTTTCTAAATTGAYTGAGACCTGTCTCAGATACTTTTGGGTTCACA
113 >MER4C a consensus
114 GTTRGNGTTRGNGATTGCNNNTGTGAAAGGAAAATAAAAACTTGGGACCCNAATTCACTNTGCCAAAAGGAAAAAATTAAGCTGAAANCTGAGTCATGCAAGAAACTGCCTTTCCTTTTNTTCCTAAGCAGATANCTACAGATAAAAGGTTAAATATCTCCACAGRCAGTGACTCTATGTTCACCTTYCYTATGTAAAGTGKCGATTTACTGAGCACGMKAKGRATAGATAATTGACTATTCCCCTACCTGCTCCTTTTCTCTTGCAACATGTGGATTACCAYAMCCTYYYTCTTTCCCCTCCAGCCTACYTTTCCCNTTTAAATATTGAAGCCCTCAAANTCATCNCTGGAGAAAGGCACAGACCACAGAMTSTTTYTGTRAYTYCGTGTTTCTCCTNGGCATGTCCTTAACNTTGGCAAAATAAACTNCTAAATCGATTGAGACCTGTYTCAGAYACWTTTKGGTTTACA
115 >MER5a a consensus
116 CAGTGGTTCTCAAAGTGTGGTCCCCGGACCAGCAGCATCAGCATCACCTGGGAACTTGTTAGAAATGCAGATTCTCGGGCCCCACCCCAGACCTACTGAATCAGAAACTCTGGGRGTGGGGCCCAGCAATCTGTGTTTTAACAAGCYCTCCAGGTGATTCTGATGCATGCTCAAGTTTGAGAACCACTG
117 >MER5b a consensus
118 CAGTGGTTCTCAACCYTGGCTGCAYATTAGAATCACCTGGGGAGYTTTTAAAAATCCNGATGCCCGGGCCACACCCCAGACCAATTAAATCAGAATCTCTGGRGGTGGGACCCAGGCATCAGTATTTTTTAAARCTCYYCAGGTGATTCCAATGTGCAGCCAAGGTTGAGAACCACTG
119 >MER6 Nonautonomous DNA transposon
120 CAGCAGGTCCTCGAATAACGCCGTTTCATTCAACGTCGTTTCGTTATAACGYTGATGAGRAAAAAAATCGATTCCCGGCCGGGGCCACTGTCTGTGTGGAGTTTGCACGTTCTCCCCATGTCTGCGTGGGTTTTCTCCAGGTACTCCGGTTTCCTYCCACATCCCAAAGATGTGCACGTTAGGTTCAYTGGCGTGTCTACATGGTCCCAGTCTGAGTGAGTGTGNNTGTGTGTGTGAGTGTGCCCTGCGATGGGATGGCGTCCTGTCCAGGGNTGGYTCCCGCCTTGCGCCCTGAGCTGCCGGGATAGGCTCTGGCCACCCGTGACCCTGAAMTGGAATAAGTGNRTTGRAAAATGAATRAATGAATGARTACGAATTATTATAAAATAAAAATTTGTAAAGTCTATGNTAATCTTACACATACATGACAATACATGAAATGGTAAGAAAGTGATCAGTGAGCCTGCCATATATGTTATTGCTTGTTTCTGAACTGAGTGGTGGGAGGAGGTGTTCCTAACAATGTTCACTTTGCAGACATTTATTTCTTTATTTAATCCATTATCACTATGACCACTGTCATTCAGTKATTCWCCAAAAATTGGGTAAATAATTATCWTRYTTGTTTTTATTAATCTTTCTTAAATGTATGTATAGCTCACATTTATTTCAGTGTTTAATATTAGAAGTGTTTTGGGTCTTTATTTAGAAGTTTGGTGATGTTTTTGTGACCAGAAATATGCCATAGGAACTTAACTCTTGTTTATATCAATTAGCCTRTGGTAAAATTGGTTTCGTTATACGTCGTTTCACTTAAAGTCGCAGTTTCCAAGAACCTATCAACGACGTTAAGTGAGGACTTACTG
121 >MER7A Nonautonomous DNA transposon
122 CAGTCATGCGTCGCTTAACGACGGGGATACGTTCTGAGAAATGCGTCATTAGGCAATTTCGTTGTGCGAACATCATAGAGTGTACTTACACAAACCTAGATGGTATAGCCTACTACACACCTAGGCTATRTGGTATAGCCTATTGCTCCTAGGCTACAAACCTGTACAGCATGTTACTGTACTGAATACTGTAGGCAATTGTAACACAATGGTAAGTATTTGTGTATCTAAACATAGAAAAGGTACAGTAAAAATACGGTATTATAATCTTATGGGACCACCGTCGTATATGTGGTCCATCGTTGACCGAAACGTCGTTATGCAGCGCATGACTG
123 >MER7B Nonautonomous DNA transposon
124 CAGTCATGCGTCGCTTAACGACGGGGATACGTTCTGAGAAATGCGTCATTAGGCAATTTCGTTGTGCGAACATCATAGAGTGTACTTACACAAACCTAGATGGTATAGCCTACTACACACCTAGGCTATRTGGTATAGCCTATTGCTCCTAGGCTACAAACCTGTACAGCATGTTACTGTACTGAATACTGTAGGCAATTGTAACACAATGGTAAGTATTTGTGTATCTAAACATAGAAAAGGTACAGTAAAAATACGGTATAAAAGATAAAAAATGGTACACCTGTATAGRGCACTTACCATGAATGGAGCTTGCAGGACTGGAAGTTGCTCTGGGTGAGTCAGTGAGTGAGTGGTGAGTGAATGTGAAGGCCTAGGACATTACTGTACACTACTGTAGACTTTATAAACACTGTACACTTAGGCTATACTAAWTTTATWWWWWWWWWWWWWYTTTTTCAGCAATAAATTAACCATAGCTTACTGTAACTTTTTTACTTTATAAACTTTTGCATTTTTAACTTTTGACTCTTTTGTAATAACACTTAGCTTAAAACACAAACACATTGTACAGCTGTACAAAAATATTTTCTTTCTTTATATCCTTATTCTATAAGCTTTTTTCTATTTWWAAATTTTTWATTTTTTTATTTTTTAAAANATTTTTGTTAAAAACTAAGACACAAACACACACATTAGCCTAGGCCTACACAGGGTCAGGATCATYAATATCACTGTCTTCCGCCTCCACATTTTGTCCCACTGGAAGGTCTTCAGGGGCAATAACATGCATGGAGCTGTCATCTCCTATGATAACGATGCYTTCTTCTGGAATATCTCCTGAAGGACCTGCCTGAGNCTGTTTTACAGTTAACTTTTTTTTTTAATAAGTAGAAGGAGTAYACTCTAAAATAATAATAAAAAGTATAGTATAGTAAATACATAAACCAGTAACATAGTCATTTATTATCACTATCAAGTATTATGTACTGTACATAATTGTATGTGCTATACTTTTATACAACTGGCAGCGCAGTAGGTTTGTTTACACCAGCATCGCCACAAACGCGTGAGTAMTGAGTRATATGTTGCACTACAACGTCACTAGGCGATAGGAATTTTTCAGCTCCATTATAATCTTATGGGACCACCGTCGTATATGTGGTCCATCGTTGACCGAAACGTCGTTATGCAGCGCATGACTG
125 >MER8 Nonautonomous DNA transposon
126 CAGTTGTCCCTCTGTATANNCGGGGGATTGGTTCCAGGACCCYTGTGTATACMAAAATCCGCGCATACTCAAGTCCCGAAGTCGGCCCTGCGGAACCCACGNATATGAAAAGTCGGCCCTCCATATATACGGGTTTCGCATCCCGCGAATACTGTATTTTCAATCCGCGTTTGATTGAAAAAAATCCGCGTATAAGTGGACCCACGCAGTTCAAACCCGTGTTGTTCAAGGGTCAACTG
127 >MER9 a consensus
128 TGCGAGACCAGCTCGACTGGGGACAGCCTAACCCAGTGGCACTAGAGGAATTAAAGACACACACACAGAAATATAGAGGTGTAAAGTGGGAAATCAGGGCCTCACAGCCTTCAGAGCTGAGAGCCCCAAACAGAGATTACCCATGTATTTATTAACAGCAAGCCAGTCATTAGCATTGTTTCTATAGATACTCGATTAACTAAAAGTATCCCTTATGGGAAAAGAAGGGATGGGCCGAAATGAAGGGGTGGGTCTGGCTAGTTATCTGCAGCAGGAACATGCCCTTAAGGCACAGATTGCTCATGCTATTGTTCATGGTTTAAGAACGCCTTTAAGCGGTTTTCCGACCTGGGTGGGCCAGGTGTTCCTTGTCCTCATTCCAGTAAACCCACAACCTTCCAGCGTGGGCGTTANGGCCATCATGAACATGTCACAGTGCTGCAGAGATTTTGTTTATGGCCAGTTTTGGGGCCAGTTTATGGCCAGATTTGGGGGGGCCTGTTCCCAACA
129 >MER11A a consensus
130 AGGTGTTGCGGGAAGTCAGGGACCCCGAATGRAGGGACCGGCTGRAGCCATGGCAGARGAACGTRRATTGTGAAGATTTCATGGACATTTATCGGTTCCCAAATTAATACTTTTATAATTTCTTATGCCTGTCTTTACTTTAATCTCTTAATCCTGTTATCTTCGTAAGCTGAGGATGTATGTCACCTCAGGACCACTGTGATAATTGTGTTAACTGTACAAATTGATTGTAAAACGTGTGTTTGAACAATATGAAATCAGTGCACCTTGAAAAAGAACAGAATAACAGCRATTTTTAGGGAACAAGGGAAGACAACCATAAGGTCTGACTGCCTGCAGGGTCGGGCAAAAAGAGCCATATTTTTCTTCTTGCAGAGAGCCTATAAATGGACATGCAAGTAGGGAAGATATCGCTAAATTCTTTTCCTAGCAAGGAATATTAATATTAATACCCTGGGAAAGGAATGCATTCCTGGGGGGAGGTCTATAAACGGCCGCTCTGGGAATGTCTGTCTTATGTGGTTGAGATAAGGACTGAGATACGCCCTGGTCTCCTGCAGTACCCTCAGGCTTACTAGGGTGGGGAAAAACTCCACCCTGGTAAATTTGTGGTCAGACCGGTTCTCTGCTCTCGAACCCTGTTTTCTGTTGTTTAAGATGTTTATCAAGATAATATGTGCACCGCTGAACATAGACCCTTATCAGTAGTTCTGTTTTTGCCCTTTGCCTTGTGATCTTTGTTGGACCCTTATCAGTGGTTCTGCTTTTGCCCTTTGTCCTGTTCCCTCAGAAGCATGTGATCTTTGTTAGACCCTTATTAGTAGTTCTGCTTTTTGCCCTTTGAAGCATGTGATCTTTGTACCCACTCCCTGTTCTTACACCCCCTCCCCTTTTGAAACCCTTAATAAAAAACTTGCTGGTTTGAGGCTCAGGTGGGCATCACAGTCCTACCGATATGTGATGTCACCCCCGGCGGCCCAGCTGTAAAATTCCTCTCTTTATACTGTCTCTCTTTATTTCTCAGCCGGCCGACACTTAGGGAAAATAGAAAGAACCTACGTTGAAATATTGGGGGCGGGTTCCCCCGATACTAATTNTCTT
131 >MER11B a consensus
132 TGCAAGTAGGGAAGATATCGCTAAATTCTTTTCCCAGCAAGGAATATTAATAATTAATAGCCCTGGGAAAAGAATGCATTCCTAGGGGGAGGTCTCTRAAATGGCCGCTCTGGGAATGTCTGTCTTATGTGGTTGTAGATAAGGGATGAAATACGCCCTGGTCTCCTGCAGCACCCCCAGGCTTACTAGGATGGTGGGAAATTCCAGCCTGGTAAATTTTAGTCAGACCGGTTCTCTGCTCTCGAACCCTGTCTCCTGTTAAGATGTTATCAATGATAATGCGTGCCCGAAACCTCATTAGCAATTTTAATTTCGCCTCCATCCCTGTGGTCCTGTGATCTCGCCCTGCCTCCATTTGCCTTGTGATATTTTATTGCCCTGTGAAGTATGTGATCTCTGTGACCCACACCCTGTTCGTACACTCCCTCCCCTTTTAAAATCCCTAATAAAAACTTGCTGGTTTGACGGCTCGGGGGGCATCACGGAACCTACCGACATGTGATGTCTCCCCCGGACGCCCAGCTTTAAAATTTCTCTCTTTTGTACTCTKTCCCTTTATTTCTCAGRCCGGCCGACACTTAGGGAAAATAGAAAAGAACCTACGTGAAATATTGGGGCTGGTTCCCCCGATACTAATTNTCTT
133 >MER20 Nonautonomous DNA transposon
134 CAGTGGTTCTCAACCGGGGGTGATTTTGCCCCCCAGGGGACATTTGGCAATGTCTGGAGACATTTTTGGTTGTCACAACTGGGGGGGGGGRATGCTACTGGCATCTAGTGGGTAGAGGCCAGGGATGCTGCTAAACATCCTACAATGCACAGGACAGCCCCCACAACAAAGAATTATCCGGCCCAAAATGTCGATAGTGCCAAGGTTGAGAAACCCTG
135 >MER21 a consensus
136 GCCCTYCTRTTKCAGRAAAACCTCTCTCAAACCATGTTTTYCCTCTGCTSTCATACCACGACAACAGTCGTCAACACAGAAGACTTCTGTGACCAAATGTGTGGAGGATTTTCCCCACACACCAAGCAGCAGACACCAGCTGGGCGTCCTCCAAYTCAGTTCCGACACTGTCTACCTGGAGATAGCGTCAGATCCCACAGGTTGAGGTCTCAGTCCCCAAGACTGNCCCCACCTTCAGAYACAGTTGCAAGYCCGGGYCTCTGGAACTTCTGACCAACTGGCTTCAARTTGGGGTTCCCACGACACCTCTTTAGGTTCGAYTAATTTGCTAGAGTGGYTCACAAAACTCARRGAAACACTTATTAWGTTTACTGGTTTATTAATAGATGATATTTCAAAGGATACAGATGAAGAGATACATACGGGGCGGTCTGGAAGRKCCCAGCGCAGGAGCTTCCGTCYTGATAGRRTTGGGGTTACACCCTCCAGATTCTTCACCTTCTGTYAGCCTCCACGTGTTCAGCTCTCCAGAAGCTCYCTGAACCCTGTCCTTTGGGCCTTTTATGGAGAYCTCATTGGNTGTCCATGACTGAAGCATGGACGAYTGNNAWAATGTGATTGGRCAAAAAGGGTCTGATCTAATCCCAGCAAGGYCTGTCCAGATTCTTCTTGGTCTCTTTGTGCAGCATTCCTTCCTCCAGGGTATGGGGCAGGACCYCCTCTGGAATGAGGGTCTTACGACCCACAATCAGATTATAGAGTCCTGCCTTGGGCGGMTGAAARGAGGRCARGAGAAGGYCAGAGARATATTCTGTTTCCTGAGGCCTAAAGCACCTCTACATTATAGCGAAAGACTGTAACCATGGTCATGTGAGTTATGGACAAGAACCATGGACAAAAACACATATACAATCATATCCCACCTCCCAACGC
137 >MER21B a consensus
138 TCAACACACAACACTTCTGTCACCAAACGTGTGGRRRTTTTTCCCCACACACAAACAAKTCTTCAGTTCTGCGGCGGACACCARCTGGGTGTCCTCCAATTCARTTCAGTTCTGACACTAWCTACCTRGAGATAGCGTCAGATCCCACAGGTTTAAGGGCTCAGTCCCACAAGACTGCCCCCACTTCAGATRCCAGTCGCAAGTCTRGGTTKTCACCCGTACTTCTGACCAACTGGCTATAAATTGTTCCCACGACCCCTCTTTAGGTTCGATTAATTTGCTAGAATRGCTCACARAACTCAGGGAAACACTTATATTTAYCGGTTTATTATAAAGGATATTACAAAGGATACAGATGAACAACCAGATGAAGAGATRCATAGGGCGAGGTMTGGGAGAGTCCNGGGNNCAGGAGCTTCCGTGCCCTCTCTGGSTNNRCCACCTTCCWGGCACCTCCACGTGTTCACCAACCCGGAAGCTCTCCGAACCCTGTCCTTTTGGGTTTTTATGGAGGCTTCATTACGTAGGCATGAYTGATTACATCANTGGCCATTGATTATCAACTCAACCTYCAGCYCCTCTCCYCTCCCCAGAGGTTGGAGGGTGGGGCTGAAAGTTCCAACCYTCTAATCTGCCTTGGTCTTTCTRGCGACCAGCYCCCATCCWGRAGCNTNCTAGGGGCTGCCCRCCAKGAGTCGMCTCATTAGMACAAAAGRNCRTYNCTATTACCCAGGARATTCCAAGGGTTTTAGGAGYTCTGTGTCAGGAACCGGGGTCAAAGACCAAATATTAGAT
139 >MER22 Human SSTI moderately repetitive DNA sequence family
140 GAGCTCTGGGCTTCCATACCTGTGTGGGACAGGGAAGCTCTCTCGGTCTCCATGGCCCAAGTGATGGCTGCACGCTCGGTCCAGGAAGAGGCGGAGGAAGCCCACCGCTCCTGACATTGGCCTTCTAGGAAAGGCGGTGTTGCATCCCACCTGCACTTCCTCTCTGATTCTTGAGGGCCAACCGCTTCCTCCGCTCCTGGGGAAAGTGCCTTCTAGCACCGAATCTTTTGGCTGCCACGGATGTCAGGGAGCCAACGGGACTGGGTTTTGGCTGGGTGCAGGGGAGGTTGCGTCAGGGGTACTAGCCGGCGGCGGGCTGGGGGTGGGGTGTACTTTGTCCAAACTCCCGGCTCCTCTGGCGGGCCTCCCTGAACGTGGCGTGGACTCGCGCACAGGCCCTGTCTCGCAGGTTTTCAGGTGCGCTTGGCTTTTCCTCCGCTTTGTGGGGCAGGTCTCCAGTGCCCCCGGCGCACGCCTGGACATCACTGTCCGTCTCGTCGTCGCCCCTACGGCCTCAAAGACACACGCTGCCTGCATGTGCTCTTGGGGGACGACAGTGCACATGTGGACACACTGGCTCCAGCTCGGACTCGCCTCTGTCTCTCTTTGCCCGTGTCGCCGGAAGCCGCCTCGGGTTGCCGGAGCCCTCGGGCCTTGGAGATGAAGGCAGGCCCCTGCTCCTGCCAGGAAGGAGGGAGGCAGTGGGCTCATGGGTCGGTGCCTTTGCAGCCGACAGCACGTGCGGCCCTGGGGATCTTCCTGTGCCCCGGCGAGACCCTTTCCGCCTCACTGCATTGGAACCCCATTCCCGATCACCCGCTGGGATCCATCATCGGACTCCAAGAGGAGTCCGCGCAGCCAGCCGGCACCCCGAAGCTCCTCCTTCAGCGGGAACCGAAGCAGAAGAGCGATCAAGGAGGTCCTCACCACAGGACTCCTATGGGTCCGACCCTGGGTCTCCCGCAGGCCCCTCTGGCAGTCCTCTTCCCACCCGCCGCCTCGGCTTCGCCGCCGCCGCCGCAACCTCCAGCACCGCCCCCCAGGCCCCGCAGCCGCCGTCGCCGCCATTTTTTAAAGGGTCGCAGCCTGACTCTGCGGAGTAAGGGGGGGTGGAGCGGGGGAGTCGCTCGCCAGCATGCGCGAGCCCGAGCCGCCGCTTGGGTCACAGTGAAAGCCACCGTTGCCCGGGGATGGGTCCCTGACACTTGGGGAAGTAGGAGCCCTGTGTGATCGTGCGTCTGAGTCTGGGCTGAGACCAGTCCTGGCCAGGGCAGTTACCAGGACGGTCTCGGAGGCCGGGATTCGCGGAGGGTCCAGCAGCAGGAAGAAACCCCAGGAGGAAGAAACCTCAGACAGATCGCCGGCGAGGCAGCGCGGGATCCCAGCCTCAGGCGTGCGCGGACGGTGTGCGGGTGAGTCTCCCCAAAAGTGGAGCCCTTGTGATGACGAGCACAGGTCCGCCTGCGTGCCCGTGGGCGGCTCTCTCACCGGTGGCTCTCAGTCGCGGAGAGCAGAACCCGCAGCTTCAGGGGCTGCTGCGGGAGGGTGTTCCCTGCTGTACGT
141 >MER25 Older LINE1 5' end region - a consensus
142 ACAAANTAGGGAAAAATGGCGGATAGGAGGCAGGACTAAATTGCAGCTCCCACTCGGATGGACAGAGCAGCATGTGGAGACTCACATCGTGAACTTTTGCTCCAAGAACCACCGCAGGAATATAYCAAGAAAGCCGAGAGAATYCACAGACCCTCTGAAGGAAGCAGATTGCTCCTGCARGAYCCAGGAAACGGCCCAAAAACTGTGAGTGCCCAAAGTGTGAGAAGGGRAAAATCTGCCCCCGAACACACATCCTYACTGGGGAACCTGAAGATCCAGATCACAGGAGAAGGATTTGACCTTACCTGGAGCTGAGACAATTTAGAGGGCCGAGCAAAATACAGGGGTAGAGGAAGCAGCGGGAAAAGCCCCGTGGGCACTCCCAGTCYYYAGNNAARCCCAGGGAAGCCATTTCTGACTTATCTCACAGGGGTCCCTTGGGAGGGCAGCCGGAGGAACTGGGAAAGGGSCACAGGGAAAAGAAAACCTCCAGCTGAACTTTGTAATAATTCCGACCGAKAGAGAAATTTCCTGGCCAGAACTMAGGGCAGGGCGRCGKAAGTGCTGGTGGGAGACCAGAAGTGCTGTTGGGGGGGACACGGTRGGAGTGAGACYTGCCTTTTGAGCTGCATGGGAGCTGGGTGAGGCCTGTNACTGCCAGCTTTCCCCCACTTYCCTGGTGACCTGCATGACACAGAAGAGGCAGCCATAATCCCCCTGGGAACGTAACTCCATTRGCCTGGGAACTACACCCCCATCCCTCACAGTAGCCGCAGCAAGCCCCGCCCAAGGAGACTCTGAGCTCAGACATGCCTAACCCTGCCCCCACCTGATGGTCTTTCTCTACCCACCCTGGTAGCCGAAGACAAAAGACATAAWCTCTTGGGAGCTCTAYGGCCCCACCCATCGCCTGAGAAACWGAAATAYTTAYCYWGGCMAMCTTAGGGCAAGCTTRTATCCWCCCTATACTRTCGCAGCTGATGCCCTCTTGAAAGCGCCACCTCTTGGCTGGAGGCCAACCAACTCAAGACATTACAGCAAYTCAYRACAGAATAACCCTGCCCCTARRRAAGGAGAAAACGACAGCTATCACCACTGCCTGCAACATCCTGGCTAACCAGAGGTCCTGAGTCTGTCCACGTGAYAASTTCACTRCTAKYATAACCAGCATTCGAGAAARCCAGCACACTAAGTCTATCTACAACCAAGGAATCTCACAGAGTCTAYTTCACTCCCCTGCCACCTCCATCAGAGCTGGTGCTGGTATTCACCGCTGRGAGACTTGAAGACAGGTCACATCACWGGATYCYTTGCAGACATTCCCCAGYACCAGCCCGGAGTCTGGTAGCTCCACTGGGTGGCTAGAYCCAGAAGAGCAATAACGATCACTGYAGTCCGGCTCTCAGGAAGTCCCATTCCTAGGRGAAGGGGGAGAGCACCACATCAAGGGAACACCCTGTGGGACAAAAGAATCTGAACGGCAGSCCTTGAGTCCCAGATCTTYCCTCTGACATAGCCTACCCAAATGAGAAGGAACCAGAAAAAYAATTCTGGTAATATGACAAAACAAGGTTCTTTAACACCCCCAAAARATCACACTAGCTCACCAGCAATGGATCCAAACCAAGAAGAAATCYCTGAATTGCCAGAAAAAGAATTCAGAAGGTCGATTATTAAGCTACTCAAGGAGGCACCGAGGAAGGTGAANACCAACTTAAAGAAANTTANAATATAATACAGGATATGAATGRARAAATCTYCAGWGAAANAGATAGCATAAAKAAAAAACAATCAMAACTTCWGGAAATCGAAGYACACTTATAGAAATGCGAAATGCWCTGGAAAGTCTCARCAATAGAATNGAACAAGCAGAAGAAAGAACTTCAGAGCTCGAAGACAAGGYTTTCAAATTAACCCAATCCGACAAAGACAAAGAAAAAAGAATAAGAAAATATGAACAAAGCCTCCAAGAAGTCTGGGATTATGTTAAACGACCAAACCTAAGAATAATCGGCGTTCCTGAGNAAGAAGAGAAATCTAAAAGTTTGGAAAACTTATTCGNGGAAATAATCGAGGAAAACTTCCCCGRCSTTGCTARAGAYCTAGAYATCCAAMTACAAAGAAGCTCWAWRAACA
143 >MER28 Nonautonomous DNA transposon
144 CAGTTGACCCTTGAACAACATGGGTTTGAACTGCGTGGRTCCACTTATACGCGGATTTTCTTCCATCTCTGCCACCCTGAGACAGCAAGACCAACCCCTCCTCCTCCTCAGCCTACTCAACNTGAAGACGANGAGGATGAAGACCTTTATGATGATCCACTTCCACTTAATGAATAGTAAATATATTTTCTCTTCCTTATGATTTTCTTAATAACATTTTCTTTTCTCTAGCTTACTTTATTGTAAGAATACGGTATATAATACATATAACATACAAAATATGTGTTAATCGACTGTTTATGTTATCGGTAAGGCTTCCAGTCAACAGTAGGCTATTAGTAGTTAAGTTTTKGGGGAGTCAAAAGTTATACGTGGATTTTTNACTGCGCGGGGGGTCAGCGCCCCTAACCCCCGCGTTGTTCAAGGGTCAACTG
145 >MER30 Nonautonomous DNA transposon
146 CAGGGGTGTCCAATCTTTTGGCTTCCCTGGGCCACACTGGAAGAAGAAGAATTGTCTTGGGCCACACATAAAATACACTAACACTAACGATAGCTGATGAGCTWAAAAAAAAAAAAMAATCCCAMAAAAATCTCATAATGTTTTAAGAAAGTTTACGAATTTGTGTTGGGCCGCATTCAAAGCCATCCTGGGCCGCGTGCGGCCCGCGGGCCGCGGGTTGGACAAGCTTG
147 >MER31 a consensus
148 CACCCTGCGTATCTGAYCAGGTTCCTCARTCTCCGCCGTCCCCCAGGTAATGTTTGRTCACCTGGCCTGCCTTCAGCTAGAATCCTRTTAGGTCAGTTTAGCAGAATCTCCTTACTCCTGATGTTTCCTCTTRGTAATTTTCCATCCACTGCCCCCGYACTCTGCTCYTTGGCTATAAATCCCCACTTGTCCTTGCTRTATTCGGAGTTGAGYCCAATCTCTCTCCCCTACCGYAAGACYCCATTGCAGTGGTCCCTGTAYCTRTCGNRATGGTCCTGAATAAAGTCTKCCTTACCATGCTTTAACAAGTRTYATTGAAWAATTTTTTTT
149 >MER33 Nonautonomous DNA transposon
150 CTGCGCTGTCCAATACGGTAGCCACTAGCCACATGTGGCTATTGAGCACTTGAAATGTGGCTAGTCCAAATTGAGATRTGCTGTAAGTRTAAAATATACACCAGATTTCAAAGACTTAGTACGAAAAAAAGAATGTAAAATATCTCATTAATAATTTTTATATTGATTACATGTTRAAATGATAATATTTTGGATATATTRGGTTAAATAAAATATATTATTAAAATTAATTTCACCTGTTTCTTTTTACTTTTATTAATGTGGCTACTAGAAAATTTAAAATTACATATGTGGCTCGCATTRTATTTCTATTGGACAACGCTG
151 >MER34 a consensus
152 TAGGGGAGTGAGAGATCACCTCCAACCCTCCCTCCCCTTTGCTCTTATGTGGGCTCTTTGGTGAATCTAGGAACCAAATTGACACAAGGCAGATTAACAAGAGAAAAGCATACAAATTTCATTAGTTTTACATGTGCATAGGAAYCCTCACAAAAGTCAAGYCCAGAGAAGCGGCCAAAGTAAGATGCYTTTATACTTTTTNNACAAAGNACAATAARYTNNRRAARTGTCAGAAGAAAGGGGATCTGGCTAGGGGCAGTAAATTTCTCGCGGAGTCATTAGGAGAAAAGTGTGTGTGTTGGGGTGTAAACTTAGTGGAAGATAACGGTTACTTCGGAAAGTATATTCAGGTCCAAAGCAGCCCCCAGTTTCGTCTCTGGTGATAGGTGCTATTTTCTCCCTCTGGTAAGGGACGGGTACTCCAGAGGAATCCTGGAGGAAGCTTTATGCGCTTGCTGCATGCAGGAAGAGATAGGTCATCAAACCTTTTCTGAAACTACAATTTCTCCAATATTTTCAACTCGAAATAATCAATGTACCAATTCCATATATTTTTGGGATGGCACATCCATCAGTCCTTC
153 >MER35 a consensus
154 GATGTGGCGTTTGAGTGGACACGGGGGAAGAAACAAGTAATATGAATAACATGGTGAGACAGAAAGAGTTGTGGACAGAGCTGTGGGAAATATGAGAGATAAGGAGAGAGATACTGAAAAGAGCGTTAAGAGAGATGAAGATAGGGTGTCTGGCCCATGAAGGCCCTCGTGAAGAGCAATGCTGAATAGATGAATGAACCTCAATGCCCAGCAGTGGTGGGATGAAAAGGGGATCCTGTGCAGAAACCACACTACCCATCAGAGAAGCAACTCTGCTCGTTTCCCCTTGA
155 >MER39 a consensus
156 GGGCATTANNNCTGTAGGGGCAGAAAGGTGTGATNCCTTCCCTACCCATCATAAGGGTCACGGCNNACACTCCTATAATAAAANAYAGGTTAGCAAGAGAAAAGCATAAYAGATTTATTTAATCAAAGTTTTATGTGACATGRGAGCCTTCAGAAATGAAGACMCAAAKACTCAGGGAAAACTCTATTTTTATGYTTAGATTTGATGAAGAATGGANAGCTGCGCAGAAATGTGATTRGACAAAAGGGGWATGATCTAATGGTMATARACTGRGTGTGGRAACCCAGCAAGGCTTGTCTGTTCGTATTCTTCTTGGTCTMTCTGTGCGGCATTCCTTCCTCCCGGGTATAGGGCGGGACCCCTTCTGGAATGAGGGTCTTATGACCTACWATCAGACGAGATAGGTCAGAWAATTTCTTTACGGSCAGCYCYAAGACAGAAAGGCGGGKRAWGATTAGAGGGCNAGAGAAGGTCAGAAAATGANNTTCTGTTTYCTGAGGNCTGCTTCTGAGGCTTAGAGCGCCCCAACATTNTAACAAAAGNCTGTCCNTCACCTTTACCGCTCTGAAGCTGTTCCAAAGCTGCTACATGAACCAAGGACAAAAAGCCANATANTTCAACAAAAGATATNCTTATNGTTTTAGTCACTCAGGAAACAGCAAGGCTTATAGGAGCTGAGAACCCGGAATTATG
157 >MER41 Medium reiteration sequence MER41
158 AACCTGCCAAGAACAGAAACTGGCAGAATCTGTCACAAGAAAAAGTCCCAATCAGACTTCAAGAGAGGGTTCTTGGATCTTGTGCAAGAAAGAATTCATGGGGAGTCTGAGTAAAGTGAAAGCAAGTTTATTAAGAAAGAGGAATAAGAGAATGGCTACTCCAAAGACAGAGCAGCCCTGAGGGCTGCTGGTTGCCTATTTTTATGGTTATTTCTTGATTATATGCTAAGCAAGGGGTGCATTATTTAAGCCTCCCCTTTTTAGGCCATATGGGGTTATATCCTGATGTTACTATGGCATTTGTAAACTATTATGGTGCTGGTGGGAGTGTAGCAGTGAGGACGACCAGCAGTCACTCCCATGGCCATATTGGTTTTGGTGGGTTTTAGCCGGCTTCTTTCTGCAACCTGTTTTATCAGCAAGGTTTTAAGGACCTGTATCTTGTGCTGACCTCTTATCTCATCCTGTGACTTAGAATGCCTTAACTGTCTGAGGATGCAGCCCAGTAGGTTTCAGCCTTATTTTACTCAGCTCCTATTCAGGATGAAGTTGCTCTAGTTCATATGTCTTAGACATTTCCTCCTTCCCTTT
159 >MER42a MER42 repetitive sequence: subfamily MER42a - a consensus
160 ATGTAYAGKAGGATTGATCAAATAAGTAAACGTATTNAAGATAATGGGAGCCAGGTTTCTCACTGTCGGAGAAGGGAGTTACAAATATGGAAAGGGRGAAGRCTAGAATGAACCCTGTGGTATTRGATTRGAATTGGAGGTATCAGTRTGAACTCATGRTTTTTAATATAYRYRYRYRYRTTTTTCCTAGTCCTGTCCACTGAGAGGGCCTAGAAGCAACGACACCCCAGTAGCAACGAGCACACCTAGCACCCAGATCTTGGTTTCTAATACCATTCTCCAATAAAAGGAACCAGGGCTCCTTGGAGAAATGGCTGATTCTAGGACTAGGGCAGGAAATATACAAGATGAGCCTGGAACATCTTGTARTGCCAGAAAATAAGGAAGTGCTCAAAAAACGATRRGGGTATGTCAAARGGACACAGAAGCCAACTGAAAGAGCTCCCAATGGCCAAAGCTGGAACAATTTGAGCAACAAAATAAATTATRGTAGTATTGGATTATAACTCAAAGTATAAAATAAATATCCATGAGTTCATACTAATACAAATAAATGATTAAATAAATAAATAAATTGAGAARATAAATAAGTCTTTCTTGCAGAAGAATTTCAAATAATTTATGTAGATARCCTCCCCTCAAGGAAGTGGAGCGTAAYTCCCCACTCCTTAAGTGTGGGATGGRTATAGTGACTTCCTTCYAGAAAGNATAGTNTAGGACGGAARAAAAAGTAAATTTACAGTAGAGAAACCTGACAAACACTACCTTAGCCARRTAATCAARGTTAGCATCAACGATAATARGTCATGYTGATARTATATANCCTTRATATGATGTGATAAGAATGGCACTTTACCTCCGTGGTCTTCCTCCCAAAAACCCATAACCCCAGTCTAATCATRAGAAAATATCAGACAAATTCCAACTGAGGRACATTCTACAAAATACCTGACCAGTACTCCTCAAAACTGTCAAGGTCATCAAAAACAAGRAAAGTCTGAGAAACTGTCACAGCYAARAGGAGCCTAARGAGACATGACAACTAAATGTAATGTGGTATCCTGRATGGGATCCTGGAACAGAAAAAGGACATTAGGTAAAAACTAAGGAAATMTGAATAAAGTATGTACTTTAGTTAATAATAATGTATCAATATTGGTTTATTAGTTGTGACAAATGTACYATANTAATGTAAGATGTTAAYARTAGGGGAAACTGGATGTGGGGTAYATGGGAACTCTCTGTACTATTTTTGCAACTTTCCTGTAAATCTAAAACTATTTTAAAATAAAAT
161 >MER42c MER42 repetitive sequence: subfamily MER42c - a consensus
162 ATGTAYAGKAGGATTGATCAAATAAGTAAACGTATTNAAGATAATGGGAGCCAGGTTTCTCACTGTCGGAGAAGGGAGTTACAAATATGGAAAGGGRGAAGRCTAGAATGAACCCTGTGGTATTRGATTRGAATTGGAGGTATCAGTRTGAACTCATGRTTTTTAATATAYRYRYRYRYRTTTTTCCTAGTCCTGTCCACTGAGAGGGCCTAGAAGCAACGACACCCCAGTAGCAACGAGCACACCTAGCACCCAGATCTTGGTTTCTAAATACCATTCTCCACTAAAAGGAACCAGGGCTCCTTGGAGAAATGGCTGATTCTAGGACTAGGGCAGGAAATGTACAAGATGAGCCTGGAACATCTTGTTRTGCCAGAAAATAAGGAAGTGCTCAAAAAACGATRRGGGCATRTCAAAAGGACACAGAAGCCAGCTTGAAGGGGCTCCCACTGGCCAAATCTGGGACAATTTGAGCATCAAAATAAATAATRGTAGTAATGGATTATAACTCATTGAATAAAATAAATATCCATGAGTTCATACTAATATAAATAAATGAATAAAAWAAATAAATGAGAARGGAAAGCTCTTCTTACAGTNGAATGCCAANTAATAAATNTAGAARGAATAATAATAGAAAAATCACCATTAGGCAAAYACCGCAGTAATAACTGTTTYAGGCAAGATCCATCGATAGATGCTMTAATTAGTGGGCGAAARTTTGATGAGAAACGGRATATTTGCATAGTCTCAAAGTATCTCCTCACAAGATATTTATTAATTACAAAGGGAAAAAYAGTGACTTTACAGTAGAGAAACCTGGCAGACACCACCTTAACCAAGTGATCAARGTTANCATCACCAAAAATGAGACAAAYTGACATCATGCGCYNCCTGATRTGATGCGCCGAGAAGAACAACATSGCTTCTGTGATATTCCTGCCAAAGATGCATAACCTGAATCTAATCATRAGAAAATATCAGACAAACCCAAATTGAGGGACAKTCTACAAAATAACTGGNCTGTACTCATCAAAARTGTCAAGGTCATAAAAGACAARGAAAGACTGAGGAACTTTCTACNTTTGACGGAAGACTAGARNCATGACAACTAAATGCAACGCGGGATTCTGRANTGGATCCTGGRTCGAGAAATAGTGGGAGTTTKTAYCTATAAAGGACATTATTGGGACANTTGRCGAAATTTGAATANGGTCTGNAGATTAGATAATAGTATTGTATCAATGTTAATTTCCTGATTTTGATAATTGTAYTGTGGTTATGTAAGAGAATGTCCTTGTTTTTAGGAAANACACACTGAAGTATTTAGGGGTAAAAGGNCATSATGTCTGCAACTTACTCTCAAATRGTTCAGRAAAAAAAATNNATATAYATAARYAGAGAATGATAAAGCAAATGCGGYAAAATGTTAACAATTGGTGAATCTGGGTGAAGGGTATACGGGWGTTCTTTGTACTATTCTTGCAACTTTTCTGTAAGTTTGAAATTACTTCAAAATAAA
163 >MER43 Homo sapiens clone DOE1-35 MER repetitive sequence - a consensus
164 CCCAAGCCCAGTAACGCTGTGGCTCTTGCAGACTCNTAGAGGTACTGCCTTNRTGGTCTTGGATAAGATCTGGAAGAATTCCCTGGATTACCAGGCAGAGACTCTTGTTCTCTTCCCTTACTTTCTCCCAAACAAACAAATGGAGTCTCTCTCTCTNTCTGTGCTGAGCTGCCTAGANCTGNGGGWGGGGTGACACAAGCACCCCTGTGGCCACCACCACTGGGACTGTGCTGGGTCAGACCTGAAGCCAGCACAGCATTGGGTCTCACCCA
165 >MER44A Nonautonomous DNA transposon
166 CAGTAGTCCCCCCTTATCCGCGGGGGATACGTTCCAAGACCCCCAGTGGATGCCTGAAACCACAGATAGTACCGAACCCTATATATACTATGTTTTTTCCTATATATATATACCTATGATAAAGTTTAATTTATAAATTAGGCACAGTAAGAGATTAACAATAACTAATAAAATAGAACAATTATAACAATATACCGTAATAAAAGTTATGTGAATGTGGTCTCTTTCTCTCAAAATATCTTATTGTACTGTACTCACCTATTTTCGGACCGCGGTTGACCATGGGTAACTGAAACTRCGGAAAGTGAAACCGCGGATAAGGRGGGACTACTG
167 >MER44C Nonautonomous DNA transposon
168 CAGTAGTCCCCCCTTATCCACGGGGGATACGTTCCAAGACCCCCAGTGGATGCCTGAAACCACGGATAGTACCGAACCCTATTGCTATCAGTCTTTTGGAACATGTTTCTGTTCATGTCTTCTGCCCACAAATTTAATGCCTCTTCCACCTCAACTAAACACGTATCATGCACTCCGGCCATCACTTTTGCAGTTTGAGGTATGACATCAAAACTAGCATGAATTTATTTTTCCTTCTTCACAATTCCAAAGATGGAAGATTCTTTCTTACCGTAGATCTTAGCAACCTCAGCATACGATTATTTTTCYTTTCTTTTTAAGTCAAGAACTTTCACCTTTTCGCTTAAAGGAAGCACTTTACAGCTTCTYTTTGGCATGTCCGAATTGCCACCAACACTACTCTTGTGCTTTTGGGCCATTATTAAGTAAAACGGGAGTTACTTGAACACAAGCACTGTGATACCAAGACAGTCGGTCTGATAACTGAGATGGCTACTAAGTGATTAACAGGCAGGTAGCGTANACGGCGTGGATACGCTGGACAAAGGGATGATTCACATCCCGGATGGGACGGCGCGAAATTTCATCACGCTACTCAGAACGGCGCGYAATTTAAAACTTATGAATTGTTTATTTCTGNAATTTTCAATTTAATATTTTCGGACCGCAGTTGACCACGGGTAACTGAAACCACAGAAAGTRAAACCACGGATAAGGGGGGACTGCTG
169 >MER45 Nonautonomous DNA transposon
170 CAGGACCGGCTACATAATTTGCGGGRCCCAGTGCAAAATGAAAATGCGGGGCCCCTTGTTCAAAAATTATTAAGAATTTCAAGACGGCGACAGCAGAGCATTAAACCAAGCACGGGGCCCTTCTRAGCGCGGGGCCCTGTGTGACTGCACAGGTCGCACGCCCATGAAGCCGGCCCTG
171 >MER46 Nonautonomous DNA transposon
172 CAGGTTGAGTATCCCTTATCCAAAATGCTTGGGACCAGAAGTGTTTCGGATTTCGGATTTTTGGATTTTGGAATATTTGCATTATACTTACCGGTTGAGCATCCCAAATCTGAAAATCCGAAATCCAAAACGCTCCAATGAGCATTTCCTTTGAGCGTCATGTCGGCGYTCAAAAAGTTTCGGATTTTGGAGCATTTCGGATTTCGGATTTTCGGATTWGGGATGCTCAAYCTG
173 >LOR1 Human low copy repetitive sequence - a consensus
174 TGTTACTGAACACCAGGGGTTCGGTCTAGGTCCTGCTGCTCGCCACACAGAAAGCCAATCACTGAGACAATAAGTATTGCCAAGGAAGAAGGCTTTAATCGGGTGCTGCAGCCGAGGAGACGGGAGATCAGTCTCAAATCCATCTCCCTGACCGACTAAAATTAGGGGTTTATATAGCAGGGAAGAAATGTAACCGTGTGTGGGAAAACAGGAATTAGGGAGGGGTAAGGAAGAGAATTTGGTCAACAGGAAGCAGGTGGTCAGTTAGGCAATCATGATGGGTGAGGGGTCTGACGTCTCATTGTCCGGATGCAGTGATCTGGTAAGTTTCAGCTCCTTGATACTATCTGGGAGGCCTGATGGTTGGTTTCCTGAAAAAGGAACTCAGATAAGACAAATGTAACTTTCTCGAGTTTTAAGACTGGGAGAATCARTTTCTATGTTTATTCAAAGAAACCATAAACATCAGTTCTATGGGACAATTGGGTCAGTTTCAATTG
175 >SVA Composite retroposon
176 CTCCCTCTCCCTCACCCTCTCCCCATGGTCTCCCTCTCCCTCTCTTTCCACGGTCTCCCTCTGATGCCGAGCCGAAGCTGGACGGTACTGCTGCCATCTCGGCTCACTGCAACCTCCCTGCCTGATTCTCCTGCCTCAGCTTGCCGAGTGCCTGCGATTGCAGGCGCGCGCCGCCACGCCTGACTGGTTTTCGTATTTTGTTAGTGGAGACGGGGTTTCGCTGTGTTGGCCGGGCTGGTCTCCAGCTCCTAACCGCGAGTGATCCACCAGCCTCGGCCTCCCGAGGTGCTGGGATTGCAGACGGAGTCTCGTTCACTCAGTGCTCAATGATGCCCAGGCTGGAGTGCAGTGGCGTGATCTCGGCTCGCTACAACCTCCACCTCCCAGCAGCCTGCCTTGGCCTCCCAAAGTGCCGAGATTGCAGCCTCTGCCCGGCCGCCACCCCGTCTGGGAAGTGAGGAGTGTCTCCGCCTGGCCACCCATCGTCTGGGATGTGAGGAGCGTCTCTGCCCTGCCGCCCATCGTCTGAGATGTGGGGAGCACCTCTGCCCGGCCGCCCCGTCCGGGATGTGAGGAGCGTCGCTGCCCGGCCGCCCCGTCTGAGAAGTGAGGAGACCCTCTGCCTGGCAACCGCTCCATCTGAGAAGTGAGGAGCCCCTCCGCCCGGCAGCCGCCCTGTCTGAGAAGTGAGGAGCCCCTCCGCCCAGCAGCCACCTGGTCCGGGAGGGAGGTGGGGGGGTCAGCCCCCCGCCCGGCCAGCCGCCCCGTCCGGGAGGGAGGTGGGGGGGTCAGCCCCCAGCCCGGCCAGCCGCCCCGTCCGGGAAGTGAGGGGCGCCTCTGCCCGGCCGCCCCTACTGGGAAGTGAGGAGCCACTTTGCCCGGCCAGCCACTCTGTCCGGGAGGGAGGTGGGGGGGTCAGCCCCCCGCCCGGCCAGCCGCCCCGTCCGGGAGGGAGGTGGGGGGATCAGCCCCCCGCCCAGCCAGCCGCCCCGTCCGGGAGGGAGGTGGGGGGGTCAGCCCCCCGCCCGGCCAGCCGCCCTGTCCGGGAGGTGAGGGGCGCCTCTGCCCGGCCGCGCCTACTGGAAAGTGAGGAGCCCCTCTGCCCGGCCACCACCCCGTCTGGGAGGTGTGCCCAACAGCTCATTGAGAAGGGGCCATGATGACAATGGCGGTTTTGTGGAATAGAAAGGGGGGAAAGGTGGGGAAAAGATTGAGAAATCGGATGGTTGCCGTGTCTGTGTAGAAAGAGGTAGACCTGGGAGACTTTTCATTTTGTTCTGTACTAAGAAAAATTCTTCTGCCTTGGGATCCTGTTGATCGGTGACCTTACCCCCAACCCTGTGCTCTCTGAAACATGTGCTGTATCCACTCAGGGTTGAATGGATTAAGAGCGGTGCAAGATGTGCTTTGTTAAACAGATGCTTGAAGGCAGCATGCTCCTTAAGAGTCATCACCACTCCCTAATCTCAAGTACCCAGGGACACAAACACTGCGGAAGGCCGCAGGGTCCTCTGCCTAGGAAAACCAGAGACCTTTGTTCACTTGTTTATCTGCTGACCTTCCCTCCACTATTGTCCTGTGACCCTGCCAAATCCCCCTCTGTGAGAAACACCCAAGAATGATCAATAAAAAAAAAAAAA
177 >ALR Human alpha repetitive DNA - a consensus
178 AATTCTCAGTAACTTCCTTGTGTTGTGTGTATTCAACTCACAGAGTTGAACGATCCTTTACACAGAGCAGACTTGAAACACTCTTTTTGTGGAATTTGCAAGTGGAGATTTCAGCCGCTTTGAGGTCAATGGTAGAATAGGAAATATCTTCCTATAGAAACTAGACAGAAT
179 >MSR1 Human 37 BP minisatellite repeats, specific to chromosome 19
180 AGTCAAGACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCAAGAACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCAAGAACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCAAGACCCCCCAGCCCCTCCTCCCTCAGACTCATGAGTCCAGACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCCAGACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCCAGACCCCCAGCCCCTCCTCCCTCAGACCCAGGAGTCCAGGCCCCACCCCTC
181 >TAR1 Human telomere associated repeat sequence, complete sequence
182 GATCAACAGTGAGGAGGTCCCACAAGGCTAAGTGGGGCAAGTCGGGGACCTAAGGCAGTAGCAGGAAAACCAAAGAAAACAGGCGGAGACTTGAGACAGAGGCAGGAATGTGAAGAAGTCCAAAATAAAAATCCCTGCACAGGACTCTTAGGCTGTTATCATGCACTATCAGCCTACTCCTCCCTATTTTTGTACAATAAGCTCTTTACACTGTATTTCTTTTCAATGAAGTTATCTTCCATCTTTGTACTGCCTCTTGGTGAAAAGCTGTCTTCCAAGTTAATAACTGGGACATCAGCTCTCTGCAGTAATAGCTCCTTTTCAGTTTTAATTTGCAGAACTGATGGGGATTAATAACTGGCGCTCTGACTTTAAGTGGTGCAGGAGGCGGCCAGTAGGGGACGCCAGCCGTTACGCCGGGAGCAAGAGGGCCCTGCGTAGTCCCCATCTGCCTGCATGTGGCGTGCAGCCACGACAATGGCAGCAAGAGGGCCCGGCAGTGTGCCCAGCTGCCAGCAGGCGGGTGTGCTGCCACTATAATGTGAGGAAGAGGGCCCTGCAATGTCCCTAGCTGCCAGCAGGCGGCGTGCCACCACTATACTGCGAGCAAGAGAGCCCTGCCGTGCCCCGGCGCCAGCAGGGGGCGCTGGACAGCACTGTAAGCAAGAGGGCCCTGCAGTTGTCCTAGTCGCCAGTAGGGGACGCAATGGCAGAGCACCGTGGGCAAGCTGGTCCTGTAGTGCCCGGCTGCAAGCAGGGGGCGCCCGAAACGGGCTTTTCAGATTACTCAGGTTCCACTCGTCTCTGCGCCGCCGGGGACGTGTGTCTCTGCGCGTGCACCGCGCCACCCCCGCGCTCCCCGCCCGGCGGCGCGCGACTGTGCGACTGCAACACTCCCCGCCACCCTCAGCCCAGCGACGTGCGTCTCTGCGCCTGCGCCGCGCCTCACTCCCGCCCGCTCAGCGACCCCTCCCTTCCGGGGAGGCGCCGGCGTGCGTCTACGCCCTGCGCCGCGTCTCCCCAACAGCGGCGCGCCTCTCTGCGCCTGCGCCGGCGCGCCGCGCCTCTCTGCGCCTGCGCCGGCGCGCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCCCCGCGCCTCTCTGCGCCTGCGCCGGCGCGCCGCCTTTGCGAGGGCGGAGTTGCGTTCTCTTTAGCACACACCCGGAGAGCATCGCGAGGGCGGAGCTGCGTTCTCCTCTGCACAGACTTCGGGGGTATTGCGAAGGCGGAGCAGAGTTCTTCTCAGGTCAGACCCGGGCGGGCGGGCTGAGGGCACTGCGAGGGTGGAGCTGCGTTCTGTTCAGCACAGACGTGGGGGGCACCGTAAAGGCGGAGCAGCATTCTTCTCAGCACAGACGTTGGGGGTACTGCCTGCCTTTGGGATAACTCGGGGCCGCATCGAGGGTGAATAAAATCTTTCCCGTTTGCTGCCCTGAATAATCAAGGTCAGAGACCAGTTAGAACGGTTTAGTGTGGAAAGCGGGAAACGAAAAGCCTCTCTGAATCCTGCGCACCGAGATTCTCCCAAGGCAAGGCGAGGGGCTGTATTGCAGGGTTCAAGTGCAGCGTCAGAACTCAAATGCAGCATTCCTAATGCACACATGACACCCTAAATATAACAGGCATATTACTCATGGAGGGTTAGGGTTCAGGTTCGGGTTCGGGTTCGGGTTCGGGTT
183 >CER Human D22Z3 repetitive DNA (centromeric DNA)
184 CTGCAGAACACTACTTCCAGGGTCTAAATGTCTGTCCTTCACATAGGATTCCAGAACACTGCTACGAGAGTGTGAATGTTTGTCCTTCACATAGCATTTCACAACTGCCATGGTCTGAATGGTTGTCCCTCACATAGTATTCCAGAACACTGCTATGAGGGTCTGAATGTTTGTACCTCACATAGGATTCCAGAACACTGCTATGAGGGTCTGAATGTTTGTACCTCACATAGGATTCCAGAACACTGCTATGAGTGTTTGAAAGTTTGTCCCTCACATAGGATTCCAGAAGACTGCTGCTGGGGTCTGAATGTCTGTCCCTCACATCGGATTCCAGAACCCTGCTGCTGGGGTTTGAATGTCTGTCCCTCACATAGAATTC
185 >BSR Human beta satellite DNA - a consensus
186 GATCAGTGCAGAGATATGTCACAATGCCCCTGTAGGCAGAGCCTAGACAAGAGTTACATCACCTGGGT
187 >HSATII Human satellite II DNA
188 ANTCCATTCGGGTCCATTCGATGATGATCACACTGGATTTCATTCCATAATTCTATTCG
189 >HSATI Human satellite I DNA HinfI fragment
190 GANTCNGCTCNNGACACAACTCTCTGAGCCTTCGGTGACCTTTCNGTCTNGTGTAANNGCACTCNTGTCYYCCTGGCAGCAGTTGGACCTCGCGATGTGGATTGTGCCCTCACCCAGCNNTNTTTATGCCCTNTCNCCATGGTGACNGGATTAGGGGTCTCCTGCTCTTCNNTCCTAAGGACCACTGTCTGTGCTGTGTCTTTCAAAGGTCAGAAGAGATTGNACCTTTGTGTTTTTATTTTCCCTGTGTTTGCTTTTTCTCNNTGGGGAACCTGTGTTGCTGCTTTGAAGGTATATTCATACTGGCCNNTCANNTGNNCAACATCNNCAAANTNACTAGTTANGGCTTTCAAAATATGNTATTTCAAAAAATTANCCGTCTGTATTTTCCATATGCAGTTATAAGTAGGTTTCATCGGTTATGTTTTATTCCTCAGTTTATACATTTGATTATTGTACCAAGCAGAGTACCTTTGAAATTTTTTTTCATTTAAAAAATATGGATCTTTAAAAAAAAATTATATATGATATATATTACATGTTATGTGCTATGCCTTATNTGTAACATATAACCTCATATATTTTNTATGTCATAGTATATAATATTTATCCTGTGTCATCTTATATATAC
191 >R66 A 66bp tandem repeat - a consensus
192 ACAGAGTGCTGATTGGTGCRTTTACAAACCTTTAGCTAGACACAGAGCGCTGATTGGTGCGTTTTT
193 >SAR Human satellite I DNA
194 ACATAAAATATCAAAGTACATCAAATATATATTTTATTCTGT
195 >SN5 Human centromeric SN5 satellite DNA sequence
196 CTTCCCTTCAGGGACCTCAAAGTGACCAGCTTCCCCTTGAAGAATGACTCTCCAAGGCCCAGGAGCCCAGCTTCTGGGCCTCCAAGCCAGGCCATCTGGCGAGGGAGTCGGTGGACGTGCCCTGGCTTCTTCCATGTTGAGTTGGTACTACCCACCAAGGGGGGTAGAGAGGCGAGCAGATGTTGTCTCTGGCCTGTGTCTTGTTATCATGGTGCTGACTAGGCCTGGTACAGGGCCCTGATGGGGTTGTCCTGGGTGGTCACGGGGGTGATGAGAAGAAGATGCAGAATGGATTGCTGTGAGGATGAATGAGACGACTGTCAGTACAGACAGGCACACGGTGAAGTGTTCAGGGATTCCCCTCAGTAGCTGCCCAGACCCAAAACCTGACTCCTGAGTCACGTTACTGTCCCACTATACGTTAAGAGGAGGGAAAGCTGGGTCGCGCAGGTCCC
197 >HY3 Ro(hY3) pseudogene - a consensus
198 TAGTCAANTGAAGCAGCGGGAGTGGAGAAGGAACAAAGAAATTTGTAACTGGTTGTGATCAATTAGTTGTAAACANCGCTGCACTCCAACCAGCC
199 >HIR Human HINF family repeat DNA
200 GATTCCCAGGTGCACAGAGATCCTAATCCGCATCCATCGAAATCTCACAAAGTGTCCATAAATCACTCAGGGAGGGCCCCCATGGATACAGGGCCGTAGTAGGATGCTCCTATAGTGGGCATTAATATGAGAATGACCGAAAAGTGCATTTAGGACCATATTATAATTTTCGGGTTCCCAGGTGCACGTTTCCAATAACCAGGTGCACGGATGTATAGGGTCCCCCCCATGGATAGAGGTCCGTGTTAGGGTGCTCCATATCGGGCATGAATATCAGGAACACCGGCATGTGCACTTAGGACCATGTTTTAATTTTTCA
201 > satellites 2 and 3
202 GGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAAT
203 >IVR Repetitive sequence from human involucrin gene - a consensus
204 CAGGAGGGGCAGCTGAAGCACCTGGAGCAG
205 >7SK Human family A3 repeated element DNA; 7SK RNA pseudogene
206 GATGTGAGGGCAATCTGGCTGCGACATCTGTCCCCACTGATTACCAGGGTTGATTCGGCTGATCTGGCTGGCTAGGCGGGTCTCCTCTTCCTCCCTCAGCCCTCCATGTGTGTACCTCCTGAAGCGGACTGGTCTTCAGTCAAGGGTAGACGAGTAGCTGTGCTCCCCTGCTAGAACCTCCAAACAAGCTCTC
207 >KER Human K element interspersed repeat DNA
208 AGCTCATCTGTCCACTGAAGATGCTTGGACAGAGTTAGGAATGCTTCCTGGGAGAGGTAACATTTGAGACTTTCCTGGAAGAATGGTCAGAGTAAACCAAGTAAGTAGGAATGGAAAGAGGATGGGAGGCCCCAGCTTCCCAGAGGCATAAGGTGAGGANGNCCCTATGCATTCAGATGTGGCCCACCCTGGGGTCTGGTGGACTAAAGNCTTGGACACCCCAGATCAGCCTTAGTGGGATGAGGCAGGAAAGACAGCTGAGGGTCAGAACCCAGGCAGGTCCAATGCCAGGGTGGGCATTTCGAGTTGGTGAGACATTTCACCCTGGTGCCAAGCT
209 >XTR Repetitive element X-2 from human alpha-fetoprotein gene
210 TTAATTTGAGAGAAATTAATTATTCTGCAACTTAGGGACAAGTCATGTCTTTGAATATTCTGTAGTTTGAGGAGAATATTTGTTATATTTGCAAAATAAAA
211 >XBR Xba repetitive element copy A, from human alpha-fetoprotein gene
212 AATTGATAGGTCACGTTCTCACTCTATTTGCCTTTAAGGGAAGAAAGCAATCAAGTTAATATGTTTTCCTTCATTGTATAGTATGTAACTACGGACACTATTAGAGGAGGGATTTGTGTAGCACTTAGGACATTATACTTGATAATTTCCAAGGGTCTTTCTAGATTTAAAAGTCTGATTCTAACGTAGTAATAAAAATAAAGGCCCAATTTTCTCTTTAATATTGCCTGAAGATATTACTCTATTATTGCATTAAAATTAAACATTCACACATTGTTTGCACTGCTAAATAAAATTATGTAA
213 >MARINER1 Human mariner
214 TTAGGTCGGTRCAAAAGTAATTRCGGTTTTTGCAYTGTTGGAATTTGYCATTTGATATTGGAATACATTCTTAAATAAATGTGGTTATGTTATACATCATTTTAATGGGCATTTCTCGCTTTACGTTTTTTTGCTAATGACTTATTACTTGCTGTTTATTTKRTGTTTATTTTAGACTATGNAAATGATGTTAGACAAAAAGCARATTCGAGCGATTTTCTTATTCAAGKTCAAAMTGRRTCGTAAAGCGGCGGAGACAACTCGCAACATCAGCAACGCATTTGGCCCAGGAACTGCTAATAAACATACAGTGCAGTGGTGGTTCAAGAAGTTTTNCAAAGGAGACGAGAGCCTTGAAGATGAGGAGTGTAATGACGGGCCATCAGAAGTTGACAACGACCAGTTGAGAGCAATCATCGAARYCGATCCTCTTACAACTANACGAGAAGTTGCTGAAGAACTCGACGTTGACCATTCTACGGTCGTTCGGCATTTGAAGCAAATTGGRAAGNAAAAACTCGATAAGTGGGTGCCTCATAAAGTGAGCAAAACTTTTTNAAATTGTCATTTTAAAGTGTCATCTCTTATTCTATGCAATAACAACGAACCATTTCTTGATCAGATTGTGACGTAGAACGAAAAGTGGATTTTATACGACAACCGGCGACGACCAGCTCAGTGGTTGGACCGAAAGAAGCTCCAAAGCACTTCCCAAAGCCAAACTTGCACCAAAAAAGTCGCGGTCGCGGTCTGGTGGTCTGCTGCCAGTGTGATCCACCACAGCTTTCTGAATCCTGGCAAAACCATTACATCTGAGAAGTATCTTCAGCAAATTGATGAGATGCACCAAAAACTGCAATGCCTGCACCTGGCATTGGTCAACAGAAAGGGCCCAATTCTTCTCCACGACAACGCCCGACCGCACGTYGCACAACCAACGCTTCAAAAGTTGAATAAATTGGGCTACGAACTTTTGCCTCATCCGCCATATTCACCTGACCTCTCGCCAACAAACTACCACTTCTTCAAGCATCTCGTCAACTTTTTGCAGGGAAAACGCTTCCACAACCAGCAGGATGCAGAAAATGCTTTCCAAGAGTTCGTCGAATCCCAAAGCACGGATTTTTATGCTACAGGAATAAACAAACTTATTTCTCGTTGGCAAAAATGTGTTGATTGTAATGGTTCCTATTTTGATTAATAAAGATGTGYTTGAGCCTAGTTATGATTATGATTTAATGGCCAAAACCACAATTACTTTTGCACCAACCTAA
215 >Made1 Human mariner derived element 1 - a consensus
216 TTAGGTTGGTGCAAAAGTAATTGCGGTTTTTGCCATTACTTTYAATGGCAAAAACCGCAATTACTTTTGCACCAACCTAA
217 >Tigger1 Autonomous DNA transposon
218 CAGGCATACCTCGTTTTATTGCGCTTCGCTTTATTGCGCTTCGCAGATACTGCGTTTTTTACAAATTGAAGGTTTGTGGCAACCCTGCGTTGAGCAAGTCTGTCGGCGCCATTTTTCCAACAGCATGTGCTCACTTCGTGTCTCTGTGTCACATTTTGGTAATTCTCGCAATATTTCAAACTTTTTCATTATTATTATATCTGTTATGGTGATCTGTGATCAGTGATCTTTGATGTTACTATTGTAATTGTTTTGGGGTGCCACGAACCGCACCCATATAAGACGGCGAACTTAATCGATAAATGTTGTGTGTGTTCTGACTGCTCCACCGACCGGCCGTTCCCCCGTCTCTCTCCCTCTCYTCGGGCCTCCCTATTCCCTGAGACACAACAATATTGAAATTAGGCCAATTAATAACCCTACAATGGCCTCTAAGTGTTCAAGTGAAAGGAAGAGTMRCACATCTCTCACTTTAAATCAAAAGCTAGAAATGATTAAGCTTAGTGAGGAAGGCATGTCAAAAGCCGAGATAGGCCAAAAGCTAGGCCTCTTGCGCCAAACAGTTAGCCAAGTTGTGAATGCAAAGGAAAAGTTCTTGAAGGAAATTAAAAGTGCTACTCCAGTGAACACACGAATGATAAGAAAGYAAAACAGCCTTATTGCTGATATGGAGAAAGTTTTAGTGGTCTGGATAGAAGATCAAACCAGCCACAAYATTCCCTTAAGCCAAAGCCTAATCCAGAGCAAGGCCCTAACTCTCTTCAATTCTATGAAGGCTGAGAGAGGTGAGGAAGCTGCAGAAGAAAAGTTTGAAGCTAGCAGAGGTTGGTTCATGAGGTTTAAGGAAAGAAGCCATCTCCATAACATAAAAGTGCAAGGTGAAGCAGCAAGTGCTGATGTAGAAGCTGCAGCAAGTTATCCAGAAGATCTAGCTAAGATCAYTGATGAAGGTGGCTACACTAAACAACAGATTTTCARTGTAGATGAAACAGCCTTCTATTGGAAGAAGATGCCATCTAGGACTTTCATAGCTAGAGAGGAGAAGTCAATGCCTGGCTTCAAAGCTTCAAAGGACAGGCTGACTCTCTTGTTAGGGGCTAATGCAGCTGGTGACTTTAAGTTGAAGCCAATGCTCATTTACCATTCTGAAAATCCTAGAGCCCTTAAGAATTATGCTAAATCTACTCTGCCTGTGCTCTATAAATGGAACAACAAAGCCTGGATGACAGCACATCTGTTTACAGCATGGTTTACTGAATATTTTAAGCCCACTGTTGAGACCTACTGCTCAGAAAAAAAGATTCCTTTCAAAATATTACTGCTCATTGACAACGCACCTGGTCACCCAAGAGCTCTGATGGAGATGTACAAGGAGATTAATGTTGTTTTCATGCCTGCTAACACAACATCCATTCTGCAGCCCATGGATCAAGGAGTAATTTCGACTTTCAAGTCTTATTATTTAAGAAATACATTTTATAAGGCTATAGCTGCCATAGATAGTGATTCCTCTGATGGATCTGGGCAAAGTAAATTGAAAACCTTCTGGAAAGGATTCACCATTCTAGATGCCATTAAGAACATTCGTGATTCATGGGAGGAGGTCAAAATATCAACATTAACAGGAGTTTGGAAGAAGTTGATTCCAACCCTCATGGATGACTTTGAGGGGTTYAAGACTTCAGTGGAGGAAGTAACTGCAGATGTGGTGGAAATAGCAAGAGAACTAGAATTAGAAGTGGAGCCTGAAGATGTGACTGAATTGCTGCAATCTCATGATAAAACTTGAACGGATGAGGAGTTGCTTCTTATGGATGAGCAAAGAAAGTGGTTTCTTGAGATGGAATCTACTCCTGGTGAAGATGCTGTGAACATTGTTGAAATGACAACAAAGGATTTAGAATATTACATAAACTTAGTTGATAAAGCAGCGGCAGGGTTTGAGAGGATTGACTCCAATTTTGAAAGAAGTTCTACTGTGGGTAAAATGCTGTCAAACAGCATCACATGCTACAGAGAAATCTTTCATGAAAGGAAGAGTCAATTGATGCGGCAAACTTCATTGTTGTCTTATTTTAAGAAATTGCCACAGCCACCCCAACCTTCAGCAACCACCACCCTGATCAGTCAGCAGCCATCAACATCAAGGCAAGACCCTCCACCAGCAAAAAGATTACGACTCGCTGAAGGCTCAGATGATCGTTAGCATTTTTTAGCAATAAAGTATTTTTAAATTAAGGTATGTACATTGTTTTTTAGACATAATGCTATTGCACACTTAATAGACTACAGTATAGCGTAAACATAACTTTTATATGCACTGGGAAACCAAAAAATTCGTGTGACTCGCTTTATTGCGATATTCGCTTTATTGCGGTGGTCTGGAACCGAACCCGCAATATCTCCGAGGTATGCCTG
219 >Tigger2 Autonomous DNA transposon
220 CAGTTGACCCTTGAACAACACGGGTTTGAACTGCGCGGGTCCACTTATACGTGRATTTTTTYCAATAAATATATTGGAAAAAWTTYTGGAGATTTGCAACAATTTGAAAAAACTCGCAGACGAACCGCGTAGCCTAGAAATATTGAAAAAATTAAGAAAAAGGTATGTCATGAATGTATAAAATATATGTAGATACTAGTCTATTTTATCATTTACTACCATAAAATAYACACAAANCTATTATAAAAAGTTAAAATTTATCAAAACTTAYAYAYAYACTTACAGACTGTACGTGGTACCATTCGAAGTNGAGAGAAATATAAACAAACNTAAAGATGCAGTATTAAATCACAACTGCGTAAAATTAACTGTAGTACATACTATACTACCGTAATAATTTTGTAGCCACCTCCTGTTGCTATTGCAGCGAGCTCAAGTGTTGTGAGTACCTGCTTAAAACGCTSKGTGATGCTAATCATCTCCGCGCGAGCAGTTYATCTCTCCAGTAAATTGCGTATTGCAGTAAAAAGTGATCTCTCACGGTTCTCGCGTATTTTTCATTGTGTTTARTGCAATATTGTAAACCTTGAATAACACCATGGGACCCATACGAAGTGCCACTAGTGATGCTGGAAGTGCTCCCAAGAAGCAGAGAAAAGTCATGACATTACAAGAAAAAGTTGAATTGCTTGATATGTACCATAGATTGAGGTCTGCAGCTGGGGTTGCCTGCCATTTCAAGAYAGATGAATCCGGCGTAAGGACCGTTGTMAAAAAAGAAAAGGAAATTCGTGAARACCGTCGCTGCAGTTATGCCCAGCAGGCACAAAAACTTGTNACTTTTTGCGAAATACCTTTTTATGTTGTATTGAAAATGCAGCTTTTNTGTGGGTGCAGGATTGCTATAAGAAAGGMATACCTANAGACTCTAATATGATTAGAGAAAAAGCGAAGTCATTATGTGANNACTTAAAGCAAAARRAAGATGAMRGATCTAAAGCTGGANAATTTAATGCCAGCAAAKGATGGTTTGACAATTTTAGAAAGARGTWTGGCTTAAAAAATKTCAAGAKAACAGGAGAAGCASYTTCTGCTGACCAAGAGACAGCAGACGAGTTNCCAGATGCCATTAACAAAATCATTGAGGAGAAAGGATATCTGCCTGAACAGGTTTTTAATGCAGATGARAGTGCCCTATTCTGGGGGGAAAAAATGCCACAAAGRACATTTATTAGTAAGNAAGAGAAGCGAGCACCAGGATTTAAGGCARGAAGGGATAGGCTAACTCTACTGTTTTGTGCAAATGCAGTTAGGTTTATGATCAGGACTGCCCTTATCTATAAAGCTGCTAACCCCCGAGCCTTGAAGGGAAAAGATAAACGCCAGCTGCCAGTCTTTTGGTTGTACAACAAGAAGGCCTGGACAACGAGAACCCTTTTTCTGGATTGGTTCCATTKATGCTTTGTCCCTGAWGTCAGGAAGTACCTTGCCAGTAAGRGACTGCCTTTTAAAGTTCTTTTGATATTGGACAATGCCCYTGGCCACCCAGAACCCCATGAGTTCAACACCGAAGGTGTCGAAGTGGTCTACTTGCCCCCAAACACAACGTCTCTAATTCAGCCTCTAGATCAGGGGGTCATAAGGACCTTTAAGGCTCATTACACACGGTACTCTATGGAAAGGATTGTCAACGCTATGGAAGAGAACCCCGATAGARAGAACATCATGAAAGTCTGGAAGGATTACACCATTGAAGATGCCATTGTTRTTATAGAAAAAGCCGTGAAAGCCATCAAGCCCAAAACAGTAAATTCCTGCTGGAGAAAACTGTGTCCAGATGTTGTACATGACTTCACAGGATTTACGACAGAGCCAATCAAGGAAATCATGAAAGAGATTGTGGATATGGCAAAAAAGTTGGGGGGTAAAGGGTTTCAAGATGCGAATCTTGGAGAAATTCAAGAGCWAATAGACACCACACCAGAGGAATTAACAGAAGACGACTTGATGGAGATGAGTGCTTCCGAACCAGTGCCAGACGATGAGGAAGAAGACATNGAAGAAGCAGTGCCAGAAAACAAATTGACATTAGACAATCTRGGCAGAAGGGTTCCAATTATTCAAGACTGCTTTTGACTTCTTTTACAACATGGACCCTTCTATGATACGGGCACTGAAACTAAAGCAAACAGTGGAAGAAGGATTGGTAYTATACAGAAACATTTTTAGAGAAATGAAAAGGCAAAAAYRTCAGACAGAAATTACGATGTATTTCCGTAAAGTTACACCGAGTGTGCCTGCCTCTCCTGCCTCCCCTTCCACCTCCTCCACCTCTTCCACCTCTGCCACCCTGAGACAGCAAGACCAACCCCTCCTCCTCCTCAGCCTWCTCAATGTGAAGACGACGAGGATGAAGACCTTTATGATGATCCACTTCCACTTAATGAATAGTAAATATATTTTCTCTTCCTTATGATTTTCTTAATAACATTTTCTTTTCTCTAGCTTACTTTATTGTAAGAATACGGTATATAATACATATAACATACAAAATATGTGTTAATCGACTGTTTATGTTATCGGTAAGGCTTCCAGTCAACAGTAGGCTATTAGTAGTTAAGTTTTKGGGGAGTCAAAAGTTATACGTGGATTTTTNACTGCGCGGGGGGTCAGCGCCCCTAACCCCCGCGTTGTTCAAGGGTCAACTG
221 >PTR5 Human PTR5 mRNA for repetitive sequence
222 GAATTCCGAAGCTTTGTTCTTTAGCTCTTTGCAATAAATCTTGCTGCTGCTCACTCTTTGGGTCCACACTGCCTTTACGAGCTGTAACACTCACCGCGAAGGTCTGCAGCTTCACTCCTGAAGCCAGTGAGACCACGAACCCACCAGGAGGAACAAACAACTCCAGATGTGCTGCCTTAAGAGCTGTAACACTCACCGCGAAGGTCTGCAGCTTCAGTCCTAAGCCAGCAAGACCACGAACCCACCAGAAGGAAGAAACTCTGAACACATCCAAACATCAGAAGGAACAAACTCTGGACATGCCGCCTTTAAGAACTGTGACACTCACCACGAGGGTCCGTGGCTTCATTCTTGAAGTCAGTGAGACCAAGAACCCACCAATTCCAGACACATTTTGGCAACCACAAAGGGACTATCACCTATTGCCAAGCGGTGAGACTATCGCCAAGTGGTGAGACCATCGTCTATCGCTGAGCAGCAAAACAATCGCCTATCGCCAAGCAAATCGAAGCCATCAAGCTACAGATGGTCTTACAAATGGAACCCCAAATGAGTTCAACTAACAACTTCTACCGAGGACCCCTGGACCGACCCGCTGGCACTTCCACTGGCCTAGAGAGTTCCCCCTTGAGACACTACAACTGCAGGGCCCCTTCTTCACTTCTATCCAGCAGGAAGTAGCTAGAGCAGTCATCGGCCAAATTCCCAACAGCAGTTGGGGTGTCCTGTTTAGAGGGGGGATTGAGAGGTGGCAGTGTGCTGGCAGCCCTCGCAGCCCTCGCTCACTCTTGGCTCCTCCTCGGCCTTGGCGCCCACTCTGGCCATGCTTAAGGAGCCCTTCAGCCTGCCACTGCACTGTGGGAACACTGGCCAAGGCCAGAGCCAGCTCACTCAGCTTGTGGGGAAGTGTGGAGGGAGAGGCGCAGGCGGGAACTGGGGCTCGATGCGGCGCTTGCGGGCCAGCGTGAGTTCCGGTGGTTGGTGGCTTGGCGGGCCCCAGACTCGGAGCGGCTGGCCTGCCCTGCTGGCCCCAGGCAGTGAGGGGCTTAGCACCCAGGCCAGCAGCTGTGGATGGTGCGCTGAGTCTCCCAGCAGTGCTGGCCCACCCCACCAGCACTGCACTCGATTTCTCGCCAGGCCTTAGCTGCCTCCCCGCAGGCAGGCCTTGGGACCTGCAGCCCACCATGCCTGAGTCTCCCCTGCTGCCGCCGTGGGCTCCTGCGTGGCCCAAGCCTCCCCGACGAGCACTGCCCCCTGCTCCCCGGTGCCTGGTCCCATCGACCCCAAGGGCTGAGGAGTGCAGGTGCATGCTGCGGGACTGGCAGGCAGCTCCACCTGCGGCCCCATGCAGGAAGCCAGCTGGGCTCCTGAGTCTGGTGGGGACTTGGAGAATTTTTATGTCTAGCTAAGGGATTGTAAATACACCAATCAGCACTCTGTATCTAGCTCAAGGATTGTAAATACACCAATCAGCACCCTGTGTCTAGCTCAGGGTTTGTCAATGCACCAATCGGCACTCTGTATCTAGTTAATCTGGTGGGGAGTTGGAGAATCTTTATGTCTAGCTAAGGGATTGTAAATACACCAATCAGCACTCTGTATCTAGCTCAAGGTTTGTAAACACACCAATCAGAACCCTGTGTCTAGCTCAGGGTTTGTGAATGCACCAATCAGCACTCTGTATCTAGTTAATCTGGTGGGGACTTGGAGAATCTTTATGTCTAGCTAAGGGATTGTGAATGCACCAATCGGCACTCTGTATCTAGCTCAAGGTTGTAAATGGACCAATCAGCACTCTATGTCTAGCTCAGTGTTTGTAAATACACCAATCGACACTCTATCTAGCTAATCTAGTGGGGACGTGGAGAACTTTTGTGTCTAACTCAGGGATTGTAAATGCACCAATCAGAACCCTGTCAAAATGGACCAATAGCTCTCTGTAAAACAGACTGACTTTCTGTAAAATGGACCAATCAGCAGGATGTGGGTGGGGCCAGATAAGAGAAGAAAAGCAGGCTGCCTGAGCCAGCAGTGGCAACCCGCTTGGGTCCCCTTCCACACTGTGGAAGCTTTGTTCTTTCGCTCTTTGCAATAAATCTTGCTGCTGCTCACTCTTTGGGTCCACACTGCCTTTATGAGCTGTAACACTCACCGCGAAGGTCTGCAGCTTCATCTGAAGCAGCGAGACACGAACCCACCAGGAGGAACAAACAACTCCGATGCGCTGCCTTAAGAGCTGTAACACCGCGAGGTCTCGAGCTTCACTCCTGAGCCAGCAAGACCACAAACCCACCAGAAGGAAGAAACTCAGGAAAACAGCCGAACATCAGAAGGAATAAACTCTGGACACACCACCTTTAAGAACTGTGACACTCGCTGCGAGCGTCTGTGGCTTCATTCTTGAAGTCAGTGAGACCAAGAACCCACCAATTCTGGAC
223 >PAB Human pseudoautosomal boundary-like sequence.
224 CCTTACCAGCCCCCTACTGTGGCAGGCCAGGTCCCACTAACACAGGCCTCCATAACAACTGTTTCAGCTCTGACTGAGTGGTTAAGTTAAATACTAAAAGCCGAGAGAGCCAGTCCCCTTATACAGAGGCTGGAATGTAACAAAAGCCCACCAAGAGTTTTGCCTAGGCCTTTCCTGGGCCTTGAAGCATGACAAAATAACAAAAGAATTCTTAACAGAATCTATTTAGGATTAAACAAGTTTTACTGGGGGTTCTGAAGAAACTCCCCAGTCCTCCACAAACAAGTTTACTGGGGTCTGAAAGAACTCCCCAAACCTCCATGATTTAGCAGGAGACAAGATAAGGGTAATCACCCCAGCACCTGGACCCAGCTAGATTTAGTCAATTTACTGAGGCTACAAAGGAAGGTCTTCAGGACTCAGACCTCAGTTATAGATTAGAAGAAGTTAATCACTTATGTCTTTAGATGATTGCACACTTACACATAGACATATAGCTTAGAAGGTGTATAAGCTCTGGAAAACTTTGTAATTTTGAGTTGGTCTGGTGATATTTTCCAGGCCTTCTCCCTATACCCGGTTACAGAAATAAAAACTTTCTTCCTCCCCAGTTCATCTGCATCTTGTTAATGGGCTGCCAGAAATAGCAGCCCAACCCTCAGTTAGGTCTGGGAACACTACCCCCCAACACACACACACACAC
225 >TARE Transposable element
226 GAATTCCGCGCCCGTCCCGTCGCCGCCGCCGCCGCCGCAGACCCCTCGGTCTTGCTATGTCGAGCTCACCCGTGAAGCGTCAGAGGATGGAGTCCGCGCTGGACCAGCTCAAGCAGTTCACCACCGTGGTGGCCGACACGGGCGACTTCCACGCCATCGACGAGTACAAGCCCCAGGATGCTACCACCAACCCGTCCCTGATCCTGGCCGCAGCACAGATGCCCGCTTACCAGGAGCTGGTGGAGGAGGCGATTGCCTATGGCCGGAAGCTGGGCGGGTCACAAGAGGACCAGATTAAAAATGCTATTGATAAACTTTTTGTGTTGTTTGGAGCAGAAATACTAAAGAAGATTCCGGGCCGAGTATCCACAGAAGTAGACGCAAGGCTCTCCTTTGATAAAGATGCGATGGTGGCCAGAGCCAGGCGGCTCATCGAGCTCTACAAGGAAGCTGGGATCAGCAAGGACCGA
227 >A Primate simple repeat pattern
228 AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
229 >C Primate simple repeat pattern
230 CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
231 >AC Primate simple repeat pattern
232 ACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACA
233 >AT Primate simple repeat pattern
234 ATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATA
235 >AG Primate simple repeat pattern
236 AGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGA
237 >CG Primate simple repeat pattern
238 CGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGC
239 >GCC Primate simple repeat pattern
240 GCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCC
241 >TAA Primate simple repeat pattern
242 TAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAA
243 >CAA Primate simple repeat pattern
244 CAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAACAA
245 >GCA Primate simple repeat pattern
246 GCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCA
247 >CTA Primate simple repeat pattern
248 CTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTACTA
249 >GGA Primate simple repeat pattern
250 GGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGAGGA
251 >GAA Primate simple repeat pattern
252 GAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGAA
253 >TCA Primate simple repeat pattern
254 TCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCATCA
255 >CCA Primate simple repeat pattern
256 CCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCACCA
257 >TAGA Primate simple repeat pattern
258 TAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGATAGAT
259 >CAAA Primate simple repeat pattern
260 CAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAACAAAC
261 >TAAA Primate simple repeat pattern
262 TAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAATAAAT
263 >GAAA Primate simple repeat pattern
264 GAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAGAAAG
265 >TCCA Primate simple repeat pattern
266 TCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCATCCAT
267 >CGAA Primate simple repeat pattern
268 CGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAACGAAC
269 >TGAA Primate simple repeat pattern
270 TGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAATGAAT
271 >CGGA Primate simple repeat pattern
272 CGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGACGGAC
273 >GGAA Primate simple repeat pattern
274 GGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAG
275 >TACA Primate simple repeat pattern
276 TACATACATACATACATACATACATACATACATACATACATACATACATACATACATACATACATACAT
277 >TCAA Primate simple repeat pattern
278 TCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAATCAAT
279 >GACA Primate simple repeat pattern
280 GACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAGACAG
281 >CCTA Primate simple repeat pattern
282 CCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTACCTAC
283 >GCCC Primate simple repeat pattern
284 GCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCGCCCG
285 >TTAA Primate simple repeat pattern
286 TTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAAT
287 >GGGA Primate simple repeat pattern
288 GGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAGGGAG
289 >GGCA Primate simple repeat pattern
290 GGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAGGCAG
291 >GCCA Primate simple repeat pattern
292 GCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAGCCAG
293 >CAAAA Primate simple repeat pattern
294 CAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAAACAAA
295 >TGGAA Primate simple repeat pattern
296 TGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGA
297 >TAAAA Primate simple repeat pattern
298 TAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAAATAAA
299 >GCCCA Primate simple repeat pattern
300 GCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCCAGCCC
301 >GCTCA Primate simple repeat pattern
302 GCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTCAGCTC
303 >GAAAA Primate simple repeat pattern
304 GAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAAAGAAA
305 >TACAA Primate simple repeat pattern
306 TACAATACAATACAATACAATACAATACAATACAATACAATACAATACAATACAATACAATACAATACA
307 >CTCCA Primate simple repeat pattern
308 CTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCCACTCC
309 >TCTAA Primate simple repeat pattern
310 TCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTAATCTA
311 >TAGAA Primate simple repeat pattern
312 TAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGAATAGA
313 >GGAGA Primate simple repeat pattern
314 GGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAGAGGAG
315 >TTAAA Primate simple repeat pattern
316 TTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAAATTAA
317 >GCCCC Primate simple repeat pattern
318 GCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCCCGCCC
319 >GCGCA Primate simple repeat pattern
320 GCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGCAGCGC
321 >GGGGA Primate simple repeat pattern
322 GGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGGAGGGG
323 >GGCCC Primate simple repeat pattern
324 GGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCCCGGCC
325 >TCCCA Primate simple repeat pattern
326 TCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCCATCCC
327 >CCCCA Primate simple repeat pattern
328 CCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCCACCCC
329 >CCCTAA Primate simple repeat pattern
330 CCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCCTAACCC
331 >CCCGAA Primate simple repeat pattern
332 CCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCCGAACCC
333 >TATACA Primate simple repeat pattern
334 TATACATATACATATACATATACATATACATATACATATACATATACATATACATATACATATACATAT
335 >TCACCA Primate simple repeat pattern
336 TCACCATCACCATCACCATCACCATCACCATCACCATCACCATCACCATCACCATCACCATCACCATCA
337 >CCCCAA Primate simple repeat pattern
338 CCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCCCAACCC
339 >CAAAAA Primate simple repeat pattern
340 CAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAAAAACAA
341 >CCCTCA Primate simple repeat pattern
342 CCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCCTCACCC
343 >GCCCCC Primate simple repeat pattern
344 GCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCCCCCGCC
345 >GAAAAA Primate simple repeat pattern
346 GAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAAAAAGAA
347 >GGAGAA Primate simple repeat pattern
348 GGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGAGAAGGA
349 >CCCCCA Primate simple repeat pattern
350 CCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCCCCACCC
351 >TAAAAA Primate simple repeat pattern
352 TAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAAAAATAA
353 >GGGAGA Primate simple repeat pattern
354 GGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGGAGAGGG
355 >GCCCCA Primate simple repeat pattern
356 GCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCCCCAGCC
357 >GGGGGA Primate simple repeat pattern
358 GGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGGGGAGGG
359 >GAGACA Primate simple repeat pattern
360 GAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAGACAGAG
361 >A Primate simple repeat pattern
362 TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT
363 >C Primate simple repeat pattern
364 GGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGG
365 >AC Primate simple repeat pattern
366 TGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGT
367 >AT Primate simple repeat pattern
368 TATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATATAT
369 >AG Primate simple repeat pattern
370 TCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCT
371 >CG Primate simple repeat pattern
372 GCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCG
373 >GCC Primate simple repeat pattern
374 GGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGCGGC
375 >TAA Primate simple repeat pattern
376 TTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTA
377 >CAA Primate simple repeat pattern
378 TTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTG
379 >GCA Primate simple repeat pattern
380 TGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGCTGC
381 >CTA Primate simple repeat pattern
382 TAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAGTAG
383 >GGA Primate simple repeat pattern
384 TCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCCTCC
385 >GAA Primate simple repeat pattern
386 TTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTCTTC
387 >TCA Primate simple repeat pattern
388 TGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGATGA
389 >CCA Primate simple repeat pattern
390 TGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGGTGG
391 >TAGA Primate simple repeat pattern
392 ATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTA
393 >CAAA Primate simple repeat pattern
394 GTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTG
395 >TAAA Primate simple repeat pattern
396 ATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTATTTA
397 >GAAA Primate simple repeat pattern
398 CTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTC
399 >TCCA Primate simple repeat pattern
400 ATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGATGGA
401 >CGAA Primate simple repeat pattern
402 GTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCGTTCG
403 >TGAA Primate simple repeat pattern
404 ATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCATTCA
405 >CGGA Primate simple repeat pattern
406 GTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCGTCCG
407 >GGAA Primate simple repeat pattern
408 CTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCC
409 >TACA Primate simple repeat pattern
410 ATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTATGTA
411 >TCAA Primate simple repeat pattern
412 ATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGATTGA
413 >GACA Primate simple repeat pattern
414 CTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTCTGTC
415 >CCTA Primate simple repeat pattern
416 GTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGGTAGG
417 >GCCC Primate simple repeat pattern
418 CGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGCGGGC
419 >TTAA Primate simple repeat pattern
420 ATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAATTAA
421 >GGGA Primate simple repeat pattern
422 CTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCCTCCC
423 >GGCA Primate simple repeat pattern
424 CTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCCTGCC
425 >GCCA Primate simple repeat pattern
426 CTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGCTGGC
427 >CAAAA Primate simple repeat pattern
428 TTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTGTTTTG
429 >TGGAA Primate simple repeat pattern
430 TCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCATTCCA
431 >TAAAA Primate simple repeat pattern
432 TTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTATTTTA
433 >GCCCA Primate simple repeat pattern
434 GGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGCTGGGC
435 >GCTCA Primate simple repeat pattern
436 GAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGCTGAGC
437 >GAAAA Primate simple repeat pattern
438 TTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTCTTTTC
439 >TACAA Primate simple repeat pattern
440 TGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTATTGTA
441 >CTCCA Primate simple repeat pattern
442 GGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAGTGGAG
443 >TCTAA Primate simple repeat pattern
444 TAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGATTAGA
445 >TAGAA Primate simple repeat pattern
446 TCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTATTCTA
447 >GGAGA Primate simple repeat pattern
448 CTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCCTCTCC
449 >TTAAA Primate simple repeat pattern
450 TTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAATTTAA
451 >GCCCC Primate simple repeat pattern
452 GGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGCGGGGC
453 >GCGCA Primate simple repeat pattern
454 GCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGCTGCGC
455 >GGGGA Primate simple repeat pattern
456 CCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCCTCCCC
457 >GGCCC Primate simple repeat pattern
458 GGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCCGGGCC
459 >TCCCA Primate simple repeat pattern
460 GGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGATGGGA
461 >CCCCA Primate simple repeat pattern
462 GGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGGTGGGG
463 >CCCTAA Primate simple repeat pattern
464 GGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGGTTAGGG
465 >CCCGAA Primate simple repeat pattern
466 GGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGGTTCGGG
467 >TATACA Primate simple repeat pattern
468 ATATGTATATGTATATGTATATGTATATGTATATGTATATGTATATGTATATGTATATGTATATGTATA
469 >TCACCA Primate simple repeat pattern
470 TGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGATGGTGA
471 >CCCCAA Primate simple repeat pattern
472 GGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGGTTGGGG
473 >CAAAAA Primate simple repeat pattern
474 TTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTGTTTTTG
475 >CCCTCA Primate simple repeat pattern
476 GGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGGTGAGGG
477 >GCCCCC Primate simple repeat pattern
478 GGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGCGGGGGC
479 >GAAAAA Primate simple repeat pattern
480 TTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTCTTTTTC
481 >GGAGAA Primate simple repeat pattern
482 TCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCCTTCTCC
483 >CCCCCA Primate simple repeat pattern
484 GGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGGTGGGGG
485 >TAAAAA Primate simple repeat pattern
486 TTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTATTTTTA
487 >GGGAGA Primate simple repeat pattern
488 CCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCCTCTCCC
489 >GCCCCA Primate simple repeat pattern
490 GGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGCTGGGGC
491 >GGGGGA Primate simple repeat pattern
492 CCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCCTCCCCC
493 >GAGACA Primate simple repeat pattern
494 CTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTCTGTCTC