Fungal Genomics

at Utrecht University

General Properties

Protein IDOphio5|1932
Gene name
Locationscaffold_175:11490..15878
Strand-
Gene length (bp)4388
Transcript length (bp)3111
Coding sequence length (bp)3108
Protein length (aa) 1036

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PFAM Domains

PFAM Domain ID Short name Long name E-value Start End
PF12632 Vezatin Mysoin-binding motif of peroxisomes 1.7E-68 302 582
PF00705 PCNA_N Proliferating cell nuclear antigen, N-terminal domain 5.1E-55 778 900
PF02747 PCNA_C Proliferating cell nuclear antigen, C-terminal domain 4.7E-47 904 1031

Swissprot hits

[Show all]
Swissprot ID Swissprot Description Start End E-value
sp|Q03392|PCNA_SCHPO Proliferating cell nuclear antigen OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=pcn1 PE=1 SV=1 778 1036 4.0E-119
sp|O82797|PCNA_TOBAC Proliferating cell nuclear antigen OS=Nicotiana tabacum GN=PCNA PE=2 SV=1 778 1036 9.0E-96
sp|Q43266|PCNA_MAIZE Proliferating cell nuclear antigen OS=Zea mays GN=PCNA PE=2 SV=1 778 1036 2.0E-95
sp|Q00268|PCNA1_DAUCA Proliferating cell nuclear antigen OS=Daucus carota PE=3 SV=1 778 1036 5.0E-95
sp|Q00265|PCNA2_DAUCA Proliferating cell nuclear antigen large form OS=Daucus carota PE=2 SV=1 778 1036 5.0E-95
[Show all]
[Show less]
Swissprot ID Swissprot Description Start End E-value
sp|Q03392|PCNA_SCHPO Proliferating cell nuclear antigen OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=pcn1 PE=1 SV=1 778 1036 4.0E-119
sp|O82797|PCNA_TOBAC Proliferating cell nuclear antigen OS=Nicotiana tabacum GN=PCNA PE=2 SV=1 778 1036 9.0E-96
sp|Q43266|PCNA_MAIZE Proliferating cell nuclear antigen OS=Zea mays GN=PCNA PE=2 SV=1 778 1036 2.0E-95
sp|Q00268|PCNA1_DAUCA Proliferating cell nuclear antigen OS=Daucus carota PE=3 SV=1 778 1036 5.0E-95
sp|Q00265|PCNA2_DAUCA Proliferating cell nuclear antigen large form OS=Daucus carota PE=2 SV=1 778 1036 5.0E-95
sp|P24314|PCNA_CATRO Proliferating cell nuclear antigen OS=Catharanthus roseus PE=2 SV=1 778 1036 9.0E-95
sp|Q43124|PCNA_BRANA Proliferating cell nuclear antigen OS=Brassica napus PE=2 SV=1 778 1036 2.0E-94
sp|Q9M7Q7|PCNA1_ARATH Proliferating cellular nuclear antigen 1 OS=Arabidopsis thaliana GN=PCNA PE=1 SV=2 778 1036 2.0E-94
sp|P17070|PCNA_ORYSJ Proliferating cell nuclear antigen OS=Oryza sativa subsp. japonica GN=Os02g0805200 PE=2 SV=2 778 1036 9.0E-94
sp|Q9ZW35|PCNA2_ARATH Proliferating cell nuclear antigen 2 OS=Arabidopsis thaliana GN=PCNA2 PE=1 SV=1 778 1036 1.0E-93
sp|Q9MAY3|PCNA_POPNI Proliferating cell nuclear antigen OS=Populus nigra GN=PCNA PE=2 SV=1 778 1036 3.0E-91
sp|O82134|PCNA_PEA Proliferating cell nuclear antigen OS=Pisum sativum GN=PCNA PE=2 SV=1 778 1036 3.0E-91
sp|P17917|PCNA_DROME Proliferating cell nuclear antigen OS=Drosophila melanogaster GN=PCNA PE=1 SV=2 778 1036 6.0E-91
sp|P12004|PCNA_HUMAN Proliferating cell nuclear antigen OS=Homo sapiens GN=PCNA PE=1 SV=1 778 1036 1.0E-89
sp|P61258|PCNA_MACFA Proliferating cell nuclear antigen OS=Macaca fascicularis GN=PCNA PE=2 SV=1 778 1036 1.0E-89
sp|P57761|PCNA_CRIGR Proliferating cell nuclear antigen OS=Cricetulus griseus GN=PCNA PE=1 SV=1 778 1036 6.0E-89
sp|Q3ZBW4|PCNA_BOVIN Proliferating cell nuclear antigen OS=Bos taurus GN=PCNA PE=2 SV=1 778 1036 7.0E-89
sp|Q9DEA3|PCNA_CHICK Proliferating cell nuclear antigen OS=Gallus gallus GN=PCNA PE=1 SV=1 778 1036 8.0E-89
sp|P04961|PCNA_RAT Proliferating cell nuclear antigen OS=Rattus norvegicus GN=Pcna PE=1 SV=1 778 1036 2.0E-88
sp|Q9DDF1|PCNA_COTJA Proliferating cell nuclear antigen OS=Coturnix coturnix japonica GN=PCNA PE=2 SV=1 778 1036 4.0E-88
sp|P17918|PCNA_MOUSE Proliferating cell nuclear antigen OS=Mus musculus GN=Pcna PE=1 SV=2 778 1036 7.0E-88
sp|O01377|PCNA_BOMMO Proliferating cell nuclear antigen OS=Bombyx mori GN=PCNA PE=2 SV=1 778 1036 3.0E-87
sp|O16852|PCNA_SARCR Proliferating cell nuclear antigen OS=Sarcophaga crassipalpis GN=PCNA PE=3 SV=1 778 1036 4.0E-86
sp|Q9PTP1|PCNA_DANRE Proliferating cell nuclear antigen OS=Danio rerio GN=pcna PE=1 SV=2 778 1035 2.0E-85
sp|Q6B6N4|PCNA_HAPBU Proliferating cell nuclear antigen OS=Haplochromis burtoni GN=pcna PE=2 SV=1 778 1035 4.0E-85
sp|P18248|PCNA_XENLA Proliferating cell nuclear antigen OS=Xenopus laevis GN=pcna PE=2 SV=1 778 1036 7.0E-85
sp|P53358|PCNA_STYCL Proliferating cell nuclear antigen OS=Styela clava GN=PCNA PE=2 SV=1 778 1036 1.0E-83
sp|Q9W644|PCNA_ANGJA Proliferating cell nuclear antigen OS=Anguilla japonica GN=pcna PE=2 SV=1 778 1035 1.0E-82
sp|P22177|PCNA_SOYBN Proliferating cell nuclear antigen (Fragment) OS=Glycine max PE=2 SV=1 808 1036 3.0E-80
sp|P15873|PCNA_YEAST Proliferating cell nuclear antigen OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=POL30 PE=1 SV=1 778 1036 7.0E-74
sp|O02115|PCNA_CAEEL Proliferating cell nuclear antigen OS=Caenorhabditis elegans GN=pcn-1 PE=1 SV=3 778 1036 4.0E-73
sp|Q54K47|PCNA_DICDI Proliferating cell nuclear antigen OS=Dictyostelium discoideum GN=pcna PE=3 SV=1 778 1032 1.0E-69
sp|P11038|PCNA_NPVAC Probable DNA polymerase sliding clamp OS=Autographa californica nuclear polyhedrosis virus GN=PCNA PE=2 SV=1 778 1036 9.0E-61
sp|P31008|PCNA_PLAFK Proliferating cell nuclear antigen OS=Plasmodium falciparum (isolate K1 / Thailand) GN=PCNA PE=3 SV=1 778 1030 8.0E-51
sp|P61074|PCNA_PLAF7 Proliferating cell nuclear antigen OS=Plasmodium falciparum (isolate 3D7) GN=PCNA PE=3 SV=1 778 1030 8.0E-51
sp|Q84513|PCNA1_PBCV1 Probable DNA polymerase sliding clamp 1 OS=Paramecium bursaria Chlorella virus 1 GN=A193L PE=3 SV=1 778 1030 1.0E-37
sp|A6UQZ4|PCNA_METVS DNA polymerase sliding clamp OS=Methanococcus vannielii (strain SB / ATCC 35089 / DSM 1224) GN=pcn PE=3 SV=1 789 1032 1.0E-30
sp|O10308|PCNA_NPVOP Probable DNA polymerase sliding clamp OS=Orgyia pseudotsugata multicapsid polyhedrosis virus GN=PCNA PE=3 SV=1 790 1032 6.0E-30
sp|Q57697|PCNA_METJA DNA polymerase sliding clamp OS=Methanocaldococcus jannaschii (strain ATCC 43067 / DSM 2661 / JAL-1 / JCM 10045 / NBRC 100440) GN=pcn PE=3 SV=1 778 1032 8.0E-29
sp|A9A8V2|PCNA_METM6 DNA polymerase sliding clamp OS=Methanococcus maripaludis (strain C6 / ATCC BAA-1332) GN=pcn PE=3 SV=1 789 1032 2.0E-27
sp|Q6LWJ8|PCNA_METMP DNA polymerase sliding clamp OS=Methanococcus maripaludis (strain S2 / LL) GN=pcn PE=3 SV=1 789 1032 4.0E-27
sp|A6VHX7|PCNA_METM7 DNA polymerase sliding clamp OS=Methanococcus maripaludis (strain C7 / ATCC BAA-1331) GN=pcn PE=3 SV=1 789 1032 6.0E-27
sp|A4G0K8|PCNA_METM5 DNA polymerase sliding clamp OS=Methanococcus maripaludis (strain C5 / ATCC BAA-1333) GN=pcn PE=3 SV=1 789 1032 2.0E-26
sp|A6UUW0|PCNA_META3 DNA polymerase sliding clamp OS=Methanococcus aeolicus (strain Nankai-3 / ATCC BAA-1280) GN=pcn PE=3 SV=1 778 1032 1.0E-23
sp|A0RXH7|PCNA_CENSY DNA polymerase sliding clamp OS=Cenarchaeum symbiosum (strain A) GN=pcn PE=3 SV=1 779 1032 9.0E-23
sp|O41056|PCNA2_PBCV1 Probable DNA polymerase sliding clamp 2 OS=Paramecium bursaria Chlorella virus 1 GN=A574L PE=3 SV=1 777 1035 2.0E-21
sp|A5UMB4|PCNA_METS3 DNA polymerase sliding clamp OS=Methanobrevibacter smithii (strain PS / ATCC 35061 / DSM 861) GN=pcn PE=3 SV=1 778 1036 6.0E-21
sp|O27367|PCNA_METTH DNA polymerase sliding clamp OS=Methanothermobacter thermautotrophicus (strain ATCC 29096 / DSM 1053 / JCM 10044 / NBRC 100330 / Delta H) GN=pcn PE=3 SV=1 778 1036 8.0E-21
sp|A9A2X4|PCNA_NITMS DNA polymerase sliding clamp OS=Nitrosopumilus maritimus (strain SCM1) GN=pcn PE=3 SV=1 781 1032 8.0E-21
sp|O58398|PCNA_PYRHO DNA polymerase sliding clamp OS=Pyrococcus horikoshii (strain ATCC 700860 / DSM 12428 / JCM 9974 / NBRC 100139 / OT-3) GN=pcn PE=3 SV=1 779 1032 8.0E-19
sp|Q8ZTY0|PCNA1_PYRAE DNA polymerase sliding clamp 1 OS=Pyrobaculum aerophilum (strain ATCC 51768 / IM2 / DSM 7523 / JCM 9630 / NBRC 100827) GN=pcn1 PE=3 SV=1 792 1032 3.0E-18
sp|P57762|PCNA1_SULOH DNA polymerase sliding clamp 1 OS=Sulfurisphaera ohwakuensis GN=pcn1 PE=3 SV=1 789 1032 4.0E-18
sp|Q2NE55|PCNA_METST DNA polymerase sliding clamp OS=Methanosphaera stadtmanae (strain ATCC 43021 / DSM 3091 / JCM 11832 / MCB-3) GN=pcn PE=3 SV=1 778 1036 7.0E-18
sp|Q9UYX8|PCNA_PYRAB DNA polymerase sliding clamp OS=Pyrococcus abyssi (strain GE5 / Orsay) GN=pcn PE=1 SV=1 779 1032 2.0E-17
sp|Q975N2|PCNA1_SULTO DNA polymerase sliding clamp 1 OS=Sulfolobus tokodaii (strain DSM 16993 / JCM 10545 / NBRC 100140 / 7) GN=pcn1 PE=1 SV=1 789 1032 1.0E-16
sp|O73947|PCNA_PYRFU DNA polymerase sliding clamp OS=Pyrococcus furiosus (strain ATCC 43587 / DSM 3638 / JCM 8422 / Vc1) GN=pcn PE=1 SV=2 779 1032 1.0E-16
sp|Q9UWR9|PCNA_THEFM DNA polymerase sliding clamp OS=Thermococcus fumicolans GN=pcn PE=3 SV=1 779 1034 3.0E-16
sp|A1RXU8|PCNA_THEPD DNA polymerase sliding clamp OS=Thermofilum pendens (strain Hrk 5) GN=pcn PE=3 SV=1 790 1032 3.0E-16
sp|P57765|PCNA3_SULSO DNA polymerase sliding clamp 3 OS=Sulfolobus solfataricus (strain ATCC 35092 / DSM 1617 / JCM 11322 / P2) GN=pcn3 PE=1 SV=1 784 1032 1.0E-15
sp|Q4JAI6|PCNA1_SULAC DNA polymerase sliding clamp 1 OS=Sulfolobus acidocaldarius (strain ATCC 33909 / DSM 639 / JCM 8929 / NBRC 15157 / NCIMB 11770) GN=pcn1 PE=3 SV=2 789 1032 2.0E-15
sp|Q8TWK3|PCNA_METKA DNA polymerase sliding clamp OS=Methanopyrus kandleri (strain AV19 / DSM 6324 / JCM 9639 / NBRC 100938) GN=pcn PE=3 SV=1 778 1032 2.0E-15
sp|C5A5N6|PCNA_THEGJ DNA polymerase sliding clamp OS=Thermococcus gammatolerans (strain DSM 15229 / JCM 11827 / EJ3) GN=pcn PE=3 SV=1 779 1032 3.0E-15
sp|A0B7Y8|PCNA_METTP DNA polymerase sliding clamp OS=Methanosaeta thermophila (strain DSM 6194 / JCM 14653 / NBRC 101360 / PT) GN=pcn PE=3 SV=1 778 1035 6.0E-15
sp|Q3IU15|PCNA_NATPD DNA polymerase sliding clamp OS=Natronomonas pharaonis (strain ATCC 35678 / DSM 2160) GN=pcn PE=3 SV=1 786 1032 1.0E-14
sp|Q5JF32|PCNA1_THEKO DNA polymerase sliding clamp 1 OS=Thermococcus kodakarensis (strain ATCC BAA-918 / JCM 12380 / KOD1) GN=pcn1 PE=1 SV=1 779 1032 1.0E-14
sp|B9LU30|PCNA_HALLT DNA polymerase sliding clamp OS=Halorubrum lacusprofundi (strain ATCC 49239 / DSM 5036 / JCM 8891 / ACAM 34) GN=pcn PE=3 SV=1 786 1032 2.0E-14
sp|Q74MV1|PCNA_NANEQ DNA polymerase sliding clamp OS=Nanoarchaeum equitans (strain Kin4-M) GN=pcn PE=3 SV=2 786 1031 2.0E-13
sp|Q7T6Y0|PCNA_MIMIV Probable DNA polymerase sliding clamp OS=Acanthamoeba polyphaga mimivirus GN=PCNA PE=3 SV=2 808 1030 2.0E-13
sp|O29912|PCNA_ARCFU DNA polymerase sliding clamp OS=Archaeoglobus fulgidus (strain ATCC 49558 / VC-16 / DSM 4304 / JCM 9628 / NBRC 100126) GN=pcn PE=1 SV=1 788 1035 2.0E-13
sp|Q9YEZ5|PCNA3_AERPE DNA polymerase sliding clamp 3 OS=Aeropyrum pernix (strain ATCC 700893 / DSM 11879 / JCM 9820 / NBRC 100138 / K1) GN=pcn3 PE=3 SV=2 778 1032 4.0E-13
sp|Q9HN45|PCNA_HALSA DNA polymerase sliding clamp OS=Halobacterium salinarum (strain ATCC 700922 / JCM 11081 / NRC-1) GN=pcn PE=3 SV=1 786 1032 1.0E-12
sp|B0R7F7|PCNA_HALS3 DNA polymerase sliding clamp OS=Halobacterium salinarum (strain ATCC 29341 / DSM 671 / R1) GN=pcn PE=3 SV=1 786 1032 1.0E-12
sp|B6YVZ1|PCNA_THEON DNA polymerase sliding clamp OS=Thermococcus onnurineus (strain NA1) GN=pcn PE=3 SV=1 779 1034 2.0E-12
sp|Q973F5|PCNA3_SULTO DNA polymerase sliding clamp 3 OS=Sulfolobus tokodaii (strain DSM 16993 / JCM 10545 / NBRC 100140 / 7) GN=pcn3 PE=1 SV=1 779 1031 4.0E-12
sp|Q5JFD3|PCNA2_THEKO DNA polymerase sliding clamp 2 OS=Thermococcus kodakarensis (strain ATCC BAA-918 / JCM 12380 / KOD1) GN=pcn2 PE=1 SV=1 779 1032 6.0E-12
sp|Q18E60|PCNA_HALWD DNA polymerase sliding clamp OS=Haloquadratum walsbyi (strain DSM 16790 / HBSQ001) GN=pcn PE=3 SV=1 786 1032 8.0E-12
sp|Q46E39|PCNA_METBF DNA polymerase sliding clamp OS=Methanosarcina barkeri (strain Fusaro / DSM 804) GN=pcn PE=3 SV=1 785 1032 1.0E-11
sp|Q9P9H8|PCNA_HALMA DNA polymerase sliding clamp OS=Haloarcula marismortui (strain ATCC 43049 / DSM 3752 / JCM 8966 / VKM B-1809) GN=pcn PE=3 SV=2 786 1035 1.0E-11
sp|C6A1Y5|PCNA_THESM DNA polymerase sliding clamp OS=Thermococcus sibiricus (strain MM 739 / DSM 12597) GN=pcn PE=3 SV=1 779 1032 4.0E-11
sp|Q97Z84|PCNA2_SULSO DNA polymerase sliding clamp 2 OS=Sulfolobus solfataricus (strain ATCC 35092 / DSM 1617 / JCM 11322 / P2) GN=pcn2 PE=1 SV=2 779 1031 5.0E-11
sp|Q8PX25|PCNA_METMA DNA polymerase sliding clamp OS=Methanosarcina mazei (strain ATCC BAA-159 / DSM 3647 / Goe1 / Go1 / JCM 11833 / OCM 88) GN=pcn PE=3 SV=1 785 1032 2.0E-10
sp|Q8TUF7|PCNA_METAC DNA polymerase sliding clamp OS=Methanosarcina acetivorans (strain ATCC 35395 / DSM 2834 / JCM 12185 / C2A) GN=pcn PE=3 SV=1 785 1032 5.0E-10
sp|Q9YFT8|PCNA1_AERPE DNA polymerase sliding clamp 1 OS=Aeropyrum pernix (strain ATCC 700893 / DSM 11879 / JCM 9820 / NBRC 100138 / K1) GN=pcn1 PE=3 SV=2 785 1033 5.0E-10
sp|Q2FNX1|PCNA_METHJ DNA polymerase sliding clamp OS=Methanospirillum hungatei JF-1 (strain ATCC 27890 / DSM 864 / NBRC 100397 / JF-1) GN=pcn PE=3 SV=1 778 1032 1.0E-09
sp|A7I849|PCNA_METB6 DNA polymerase sliding clamp OS=Methanoregula boonei (strain 6A8) GN=pcn PE=3 SV=1 778 1032 2.0E-09
sp|Q4J9A8|PCNA2_SULAC DNA polymerase sliding clamp 2 OS=Sulfolobus acidocaldarius (strain ATCC 33909 / DSM 639 / JCM 8929 / NBRC 15157 / NCIMB 11770) GN=pcn2 PE=3 SV=1 795 1031 6.0E-09
sp|Q12U18|PCNA_METBU DNA polymerase sliding clamp OS=Methanococcoides burtonii (strain DSM 6242 / NBRC 107633 / OCM 468 / ACE-M) GN=pcn PE=3 SV=1 778 1032 2.0E-08
sp|Q9HJQ0|PCNA_THEAC DNA polymerase sliding clamp OS=Thermoplasma acidophilum (strain ATCC 25905 / DSM 1728 / JCM 9062 / NBRC 15155 / AMRC-C165) GN=pcn PE=3 SV=1 778 1032 8.0E-08
sp|Q979S2|PCNA_THEVO DNA polymerase sliding clamp OS=Thermoplasma volcanium (strain ATCC 51530 / DSM 4299 / JCM 9571 / NBRC 15438 / GSS1) GN=pcn PE=3 SV=2 789 1032 4.0E-07
sp|A3CVJ2|PCNA_METMJ DNA polymerase sliding clamp OS=Methanoculleus marisnigri (strain ATCC 35101 / DSM 1498 / JR1) GN=pcn PE=3 SV=1 778 1032 1.0E-06
sp|P57763|PCNA2_SULOH DNA polymerase sliding clamp 2 OS=Sulfurisphaera ohwakuensis GN=pcn2 PE=3 SV=1 778 1032 4.0E-06
sp|B8GG80|PCNA_METPE DNA polymerase sliding clamp OS=Methanosphaerula palustris (strain ATCC BAA-1556 / DSM 19958 / E1-9c) GN=pcn PE=3 SV=1 778 1032 4.0E-06
sp|Q975M2|PCNA2_SULTO DNA polymerase sliding clamp 2 OS=Sulfolobus tokodaii (strain DSM 16993 / JCM 10545 / NBRC 100140 / 7) GN=pcn2 PE=1 SV=1 778 1032 7.0E-06
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GO

GO Term Description Terminal node
GO:0006275 regulation of DNA replication Yes
GO:0017022 myosin binding Yes
GO:0003677 DNA binding Yes
GO:0008150 biological_process No
GO:0008092 cytoskeletal protein binding No
GO:0060255 regulation of macromolecule metabolic process No
GO:0019222 regulation of metabolic process No
GO:0050794 regulation of cellular process No
GO:0031323 regulation of cellular metabolic process No
GO:0005515 protein binding No
GO:0065007 biological regulation No
GO:0003676 nucleic acid binding No
GO:0003674 molecular_function No
GO:0019219 regulation of nucleobase-containing compound metabolic process No
GO:0051171 regulation of nitrogen compound metabolic process No
GO:0005488 binding No
GO:1901363 heterocyclic compound binding No
GO:0080090 regulation of primary metabolic process No
GO:0051052 regulation of DNA metabolic process No
GO:0097159 organic cyclic compound binding No
GO:0050789 regulation of biological process No

SignalP

[Help with interpreting these statistics]
SignalP signal predicted Location
(based on Ymax)
D score
(significance: > 0.45)
No 1 - 67 0.45

Transmembrane Domains

Domain # Start End Length
1 293 312 19
2 325 342 17

Transcription Factor Class

(None)

Expression data

Analysis 1: Expression analysis during behavioral modification. Published in De Bekker et al., 2017.

Click here for more information

Sequences

Type of sequenceSequence
Locus Download genbank file of locus
The gene with 5 kb flanks (if sufficient flanking sequence is available). For use in cloning design programs. NOTE: features (genes or exons) that are only partially contained within the sequence are completely excluded.
Protein >Ophio5|1932
MGRAEVRRAVGTSQCSTENSGQDDSSGLHRPVSGEAVLARPRAKSTRARSAKSRGSAKTSSDVPRLARKRKAQGT
DRLRLGSLLPCSFLFLSSERARSTDSAPLSSAPESLLGASSAIPWRCEAPDLLAPVPRSMEPVVYQETPLAEYLR
DGGDGSDAEWAAGDSPPLRTPPSPSTLPSPPYSPSPIASFAPFAPSGRPLVKRRFRVHPPPALRPAEPHSASVLG
AIRRKLWAALATSIDHSDNAKFLEQFRYTIIASQLLSGHSISSHRPLASGPAAPTVDDRDQLLLSTEGVIVPVLG
ALAIAALLSWLRGSGALSNMTRKRIVLVLSVLAVSAFLGRVHMRRQWLRYRREQTLSEMTALVSTSRDFDSATEA
TLSLVQEVELVSRGYRISAPLPPISRLEDRSQSRKCVRLRKVLKDSLGDALTKYIQASNVVKGFSEQTELEKYYD
LYDVGDFDMSDALQGYCETEFEDPESVRSLKILTARFHTTRKMIFCALLALDANGEAIELLRWGAAYEALRGLNT
TTKACYDRMRAMLSEEETFPVPPSPKGPMSPSRERWRSRWRKLDSLSTGIRGLQAKLHLLREESDRALDGSDDIS
QLGPHLTSQYESIGVDLRQLMAAWEEGKAALALGIDRNEKRLSSMSSVLSPTGSLSGLTTVDEGGDAADALKALT
GESPPPSDSDMPEVLEAVARPRPRSLLTREERIVKMREDREQKAQARQQLDATRGMLRELESVISLRPRSRLSAP
PLRGGRARDLARGGTYSAVYGLWTADEMLEARLEQANILKKLVDSIKDLVQDCNFDCNDSGIALQAMDNSHVALV
SMMLKAEGFSPYRCDRNIPLGVNLASLTKVLRAAQNEDILTLKAQDAPDVLNLVFESSENDRISEYDLKLMDIDQ
EHLGIPDTEYAASITMPAAEFRRICTDLAAMSESVSIEASKDGIKFACNGDIGNGSVVLRSHTNVDKPELNIDID
LTEPVSLTFSLKYLVNFCKASTLSNTVKLCLSSEVPLLVEYNLSGSSYLRFYLAPKIGDEE
Coding >Ophio5|1932
ATGGGACGTGCCGAGGTGCGGCGCGCCGTCGGTACGTCTCAGTGCTCCACCGAGAACTCGGGGCAAGATGACAGT
TCCGGTCTGCATCGACCCGTTTCCGGTGAGGCTGTACTTGCTCGACCGCGCGCGAAAAGTACCCGAGCTAGATCG
GCCAAGTCTCGCGGATCCGCTAAAACGTCTAGCGACGTGCCTCGATTAGCCCGCAAGCGGAAGGCTCAAGGGACA
GATCGGCTTAGGCTCGGCTCTCTTCTTCCTTGTTCCTTTTTGTTTCTCAGTAGCGAGCGAGCACGCAGCACCGAT
TCGGCGCCTCTCTCTTCCGCTCCCGAATCGTTGCTTGGCGCTTCCTCCGCGATTCCATGGCGCTGCGAGGCCCCT
GACCTACTCGCTCCTGTTCCACGCTCCATGGAGCCCGTCGTGTACCAGGAGACGCCCCTGGCCGAATATCTGCGA
GATGGAGGAGACGGGTCAGACGCAGAATGGGCTGCCGGTGACAGCCCGCCTCTGCGAACCCCCCCGTCCCCCTCG
ACGTTGCCGTCGCCGCCTTACAGTCCTTCGCCCATAGCGTCCTTTGCGCCCTTTGCGCCCTCCGGTCGTCCGCTG
GTGAAGCGCCGGTTCCGCGTCCACCCGCCACCCGCCTTACGGCCGGCCGAGCCGCACTCCGCCTCGGTCTTGGGG
GCCATCAGGAGGAAACTATGGGCTGCCCTGGCCACGAGCATCGATCACTCCGACAATGCCAAGTTCCTCGAACAG
TTTCGGTATACCATCATTGCCTCGCAGCTGCTGAGCGGGCACTCCATCTCGAGCCATCGTCCGCTGGCTTCCGGC
CCCGCCGCGCCGACCGTCGATGACCGAGACCAGCTGCTCCTCTCTACCGAGGGCGTCATAGTCCCCGTGCTGGGC
GCCCTGGCCATCGCCGCCCTCTTGAGCTGGCTCCGTGGCAGCGGCGCGCTTTCCAACATGACCCGGAAGCGCATC
GTTCTCGTCCTCTCCGTTCTCGCTGTCTCGGCTTTCCTGGGCCGCGTCCACATGAGGCGGCAGTGGCTGCGCTAT
CGTCGGGAGCAGACCCTGTCTGAGATGACGGCCTTGGTGTCCACCTCGCGCGATTTCGACAGCGCCACCGAAGCC
ACCCTGTCACTGGTTCAAGAGGTGGAGCTGGTCTCGCGCGGCTATCGAATCAGTGCTCCTTTGCCTCCCATCAGC
CGGCTCGAGGACCGCAGCCAGAGTCGGAAGTGCGTTCGCCTGCGCAAGGTGCTCAAAGACTCCCTGGGTGACGCT
CTCACCAAGTATATCCAAGCGTCCAACGTCGTCAAAGGCTTCTCCGAACAGACTGAGCTCGAAAAGTACTACGAT
TTGTACGATGTAGGCGACTTTGACATGTCCGATGCCCTTCAGGGCTACTGCGAGACCGAGTTCGAGGACCCGGAG
TCGGTGCGGAGCCTCAAGATCCTGACGGCCCGCTTCCATACGACACGGAAGATGATCTTCTGCGCGCTGCTGGCC
CTAGATGCCAACGGCGAGGCCATCGAGCTGCTCCGTTGGGGCGCCGCGTACGAGGCACTTCGGGGTCTAAACACC
ACCACCAAGGCCTGCTACGACAGGATGCGGGCGATGCTGAGCGAGGAAGAGACTTTCCCTGTGCCGCCCTCCCCC
AAGGGACCCATGTCGCCGAGCAGGGAGCGATGGCGCTCGCGGTGGCGGAAGCTGGATTCGCTATCGACCGGGATA
CGAGGCCTGCAGGCCAAGCTCCATCTTTTGAGGGAGGAGTCAGACAGGGCCTTGGACGGGTCCGACGACATCTCG
CAGCTGGGGCCGCACCTAACGTCTCAGTACGAGTCCATCGGCGTCGACCTCCGGCAGCTCATGGCGGCATGGGAA
GAAGGCAAGGCTGCACTGGCTCTCGGCATCGACAGAAACGAGAAGAGGTTGTCGTCGATGAGCTCAGTGCTGTCG
CCGACGGGATCCCTGAGCGGACTGACGACGGTAGACGAGGGCGGCGACGCGGCGGATGCGCTCAAGGCGCTGACG
GGCGAGTCGCCGCCGCCATCGGACTCGGATATGCCCGAGGTGCTAGAGGCGGTGGCTCGGCCGCGGCCACGAAGC
CTGCTGACACGGGAAGAGCGCATCGTCAAGATGAGGGAGGATAGGGAGCAAAAGGCGCAGGCCCGCCAGCAACTC
GACGCCACACGCGGCATGCTGCGCGAGCTGGAGAGCGTCATCAGCCTGCGGCCGCGGAGCCGGCTCAGCGCACCC
CCGCTCAGAGGCGGACGGGCCCGCGATTTGGCGCGAGGCGGGACATATTCCGCCGTGTACGGACTCTGGACGGCT
GACGAAATGTTGGAGGCACGGCTCGAGCAGGCTAACATCCTCAAAAAGTTGGTCGACTCCATCAAGGATCTCGTT
CAGGACTGCAACTTCGATTGCAATGACTCGGGCATTGCGCTCCAGGCCATGGACAACTCGCACGTCGCCCTCGTG
TCCATGATGCTAAAGGCAGAAGGCTTCTCGCCCTATCGGTGCGATCGCAACATTCCGCTGGGCGTCAATCTGGCG
TCCCTGACCAAGGTCCTGCGCGCGGCGCAAAACGAGGACATCCTGACACTCAAGGCGCAGGACGCGCCCGACGTG
CTCAACTTGGTGTTTGAGAGCAGCGAGAACGACCGGATCAGCGAGTACGACCTGAAGCTCATGGACATTGACCAG
GAGCACCTGGGCATCCCAGACACTGAGTACGCGGCCTCGATCACGATGCCGGCCGCCGAGTTCCGGAGGATCTGC
ACTGATCTGGCTGCCATGTCCGAATCGGTGAGCATCGAGGCTAGCAAGGACGGCATCAAGTTTGCGTGCAACGGC
GACATTGGCAACGGCTCCGTCGTCCTCCGGAGTCACACCAACGTGGACAAGCCCGAGCTCAACATTGACATCGAC
CTGACGGAGCCCGTCTCCCTGACGTTTTCGCTCAAGTACCTTGTCAATTTCTGCAAGGCCTCGACTCTTTCCAAC
ACGGTCAAGCTCTGCCTGTCGAGCGAAGTGCCACTGCTGGTCGAGTACAACCTGTCGGGCAGCAGCTACTTGCGC
TTCTATCTGGCGCCCAAGATTGGCGACGAAGAG
Transcript >Ophio5|1932
ATGGGACGTGCCGAGGTGCGGCGCGCCGTCGGTACGTCTCAGTGCTCCACCGAGAACTCGGGGCAAGATGACAGT
TCCGGTCTGCATCGACCCGTTTCCGGTGAGGCTGTACTTGCTCGACCGCGCGCGAAAAGTACCCGAGCTAGATCG
GCCAAGTCTCGCGGATCCGCTAAAACGTCTAGCGACGTGCCTCGATTAGCCCGCAAGCGGAAGGCTCAAGGGACA
GATCGGCTTAGGCTCGGCTCTCTTCTTCCTTGTTCCTTTTTGTTTCTCAGTAGCGAGCGAGCACGCAGCACCGAT
TCGGCGCCTCTCTCTTCCGCTCCCGAATCGTTGCTTGGCGCTTCCTCCGCGATTCCATGGCGCTGCGAGGCCCCT
GACCTACTCGCTCCTGTTCCACGCTCCATGGAGCCCGTCGTGTACCAGGAGACGCCCCTGGCCGAATATCTGCGA
GATGGAGGAGACGGGTCAGACGCAGAATGGGCTGCCGGTGACAGCCCGCCTCTGCGAACCCCCCCGTCCCCCTCG
ACGTTGCCGTCGCCGCCTTACAGTCCTTCGCCCATAGCGTCCTTTGCGCCCTTTGCGCCCTCCGGTCGTCCGCTG
GTGAAGCGCCGGTTCCGCGTCCACCCGCCACCCGCCTTACGGCCGGCCGAGCCGCACTCCGCCTCGGTCTTGGGG
GCCATCAGGAGGAAACTATGGGCTGCCCTGGCCACGAGCATCGATCACTCCGACAATGCCAAGTTCCTCGAACAG
TTTCGGTATACCATCATTGCCTCGCAGCTGCTGAGCGGGCACTCCATCTCGAGCCATCGTCCGCTGGCTTCCGGC
CCCGCCGCGCCGACCGTCGATGACCGAGACCAGCTGCTCCTCTCTACCGAGGGCGTCATAGTCCCCGTGCTGGGC
GCCCTGGCCATCGCCGCCCTCTTGAGCTGGCTCCGTGGCAGCGGCGCGCTTTCCAACATGACCCGGAAGCGCATC
GTTCTCGTCCTCTCCGTTCTCGCTGTCTCGGCTTTCCTGGGCCGCGTCCACATGAGGCGGCAGTGGCTGCGCTAT
CGTCGGGAGCAGACCCTGTCTGAGATGACGGCCTTGGTGTCCACCTCGCGCGATTTCGACAGCGCCACCGAAGCC
ACCCTGTCACTGGTTCAAGAGGTGGAGCTGGTCTCGCGCGGCTATCGAATCAGTGCTCCTTTGCCTCCCATCAGC
CGGCTCGAGGACCGCAGCCAGAGTCGGAAGTGCGTTCGCCTGCGCAAGGTGCTCAAAGACTCCCTGGGTGACGCT
CTCACCAAGTATATCCAAGCGTCCAACGTCGTCAAAGGCTTCTCCGAACAGACTGAGCTCGAAAAGTACTACGAT
TTGTACGATGTAGGCGACTTTGACATGTCCGATGCCCTTCAGGGCTACTGCGAGACCGAGTTCGAGGACCCGGAG
TCGGTGCGGAGCCTCAAGATCCTGACGGCCCGCTTCCATACGACACGGAAGATGATCTTCTGCGCGCTGCTGGCC
CTAGATGCCAACGGCGAGGCCATCGAGCTGCTCCGTTGGGGCGCCGCGTACGAGGCACTTCGGGGTCTAAACACC
ACCACCAAGGCCTGCTACGACAGGATGCGGGCGATGCTGAGCGAGGAAGAGACTTTCCCTGTGCCGCCCTCCCCC
AAGGGACCCATGTCGCCGAGCAGGGAGCGATGGCGCTCGCGGTGGCGGAAGCTGGATTCGCTATCGACCGGGATA
CGAGGCCTGCAGGCCAAGCTCCATCTTTTGAGGGAGGAGTCAGACAGGGCCTTGGACGGGTCCGACGACATCTCG
CAGCTGGGGCCGCACCTAACGTCTCAGTACGAGTCCATCGGCGTCGACCTCCGGCAGCTCATGGCGGCATGGGAA
GAAGGCAAGGCTGCACTGGCTCTCGGCATCGACAGAAACGAGAAGAGGTTGTCGTCGATGAGCTCAGTGCTGTCG
CCGACGGGATCCCTGAGCGGACTGACGACGGTAGACGAGGGCGGCGACGCGGCGGATGCGCTCAAGGCGCTGACG
GGCGAGTCGCCGCCGCCATCGGACTCGGATATGCCCGAGGTGCTAGAGGCGGTGGCTCGGCCGCGGCCACGAAGC
CTGCTGACACGGGAAGAGCGCATCGTCAAGATGAGGGAGGATAGGGAGCAAAAGGCGCAGGCCCGCCAGCAACTC
GACGCCACACGCGGCATGCTGCGCGAGCTGGAGAGCGTCATCAGCCTGCGGCCGCGGAGCCGGCTCAGCGCACCC
CCGCTCAGAGGCGGACGGGCCCGCGATTTGGCGCGAGGCGGGACATATTCCGCCGTGTACGGACTCTGGACGGCT
GACGAAATGTTGGAGGCACGGCTCGAGCAGGCTAACATCCTCAAAAAGTTGGTCGACTCCATCAAGGATCTCGTT
CAGGACTGCAACTTCGATTGCAATGACTCGGGCATTGCGCTCCAGGCCATGGACAACTCGCACGTCGCCCTCGTG
TCCATGATGCTAAAGGCAGAAGGCTTCTCGCCCTATCGGTGCGATCGCAACATTCCGCTGGGCGTCAATCTGGCG
TCCCTGACCAAGGTCCTGCGCGCGGCGCAAAACGAGGACATCCTGACACTCAAGGCGCAGGACGCGCCCGACGTG
CTCAACTTGGTGTTTGAGAGCAGCGAGAACGACCGGATCAGCGAGTACGACCTGAAGCTCATGGACATTGACCAG
GAGCACCTGGGCATCCCAGACACTGAGTACGCGGCCTCGATCACGATGCCGGCCGCCGAGTTCCGGAGGATCTGC
ACTGATCTGGCTGCCATGTCCGAATCGGTGAGCATCGAGGCTAGCAAGGACGGCATCAAGTTTGCGTGCAACGGC
GACATTGGCAACGGCTCCGTCGTCCTCCGGAGTCACACCAACGTGGACAAGCCCGAGCTCAACATTGACATCGAC
CTGACGGAGCCCGTCTCCCTGACGTTTTCGCTCAAGTACCTTGTCAATTTCTGCAAGGCCTCGACTCTTTCCAAC
ACGGTCAAGCTCTGCCTGTCGAGCGAAGTGCCACTGCTGGTCGAGTACAACCTGTCGGGCAGCAGCTACTTGCGC
TTCTATCTGGCGCCCAAGATTGGCGACGAAGAGTAA
Gene >Ophio5|1932
ATGGTATGCGTATTTCCCCCGCAAATTTGGGCCGCAAGGTACTTTGGCCTCTTGTTGACGACGACGGCTTCCCAC
TCGAAAGGGACGTGCCGAGGTGCGGCGCGCCGTCGGTACGTCTCAGTGCTCCACCGAGAACTCGGGGCAAGATGA
CAGTTCCGGTCTGCATCGACCCGTTTCCGGTGAGGCTGTACTTGCTCGACCGCGCGCGAAAAGTACCCGAGCTAG
ATCGGCCAAGTCTCGCGGATCCGCTAAAACGTCTAGCGACGTGCCTCGATTAGCCCGCAAGCGGAAGGCTCAAGG
GACAGATCGGCTTAGGCTCGGCTCTCTTCTTCCTTGTTCCTTTTTGTTTCTCAGTAGGTGAGCACAAAGCGCTAC
ATGACAGTCGCACAGGATAAACACCGACGCTCGCAACAATGACGGTCTCGTTATAGCGAGCGAGCACGCAGCACC
GATTCGGCGCCTCTCTCTTCCGCTCCCGAATCGTTGCTTGGCGCTTCCTCCGCGATTCCATGGCGCTGCGAGGCC
CCTGACCTACTCGCTCCTGTTCCACGCTCCATGGAGCCCGTCGTGTACCAGGAGACGCCCCTGGCCGAATATCTG
CGAGGTGTGCTGTCTTGTCTCCCCCCCCCGGGGCCGTGTCCGCTGACGGAATATGAAGATGGAGGAGACGGGTCA
GACGCAGAATGGGCTGCCGGTGACAGCCCGCCTCTGCGAACCCCCCCGTCCCCCTCGACGTTGCCGTCGCCGCCT
TACAGTCCTTCGCCCATAGCGTCCTTTGCGCCCTTTGCGCCCTCCGGTCGTCCGCTGGTGAAGCGCCGGTTCCGC
GTCCACCCGCCACCCGCCTTACGGCCGGCCGAGCCGCACTCCGCCTCGGTCTTGGGGGCCATCAGGAGGAAACTA
TGGGTGCGATTCGCCCTCATAATCTTTGCTCGTCTTCTCTTAAGCCGTCGCTAATTCTGAACGACAGGCTGCCCT
GGCCACGAGCATCGATCACTCCGACAATGCCAAGTTCCTCGAACAGTTTCGGTATACCATCATTGCCTCGCAGCT
GCTGAGCGGGCACTCCATCTCGAGCCATCGTCCGCTGGCTTCCGGCCCCGCCGCGCCGACCGTCGATGACCGAGA
CCAGCTGCTCCTCTCTACCGAGGGCGTCATAGTCCCCGTGCTGGGCGCCCTGGCCATCGCCGCCCTCTTGAGCTG
GCTCCGTGGCAGCGGCGCGCTTTCCAACATGACCCGGAAGCGCATCGTTCTCGTCCTCTCCGTTCTCGCTGTCTC
GGCTTTCCTGGGCCGCGTCCACATGAGGCGGCAGTGGCTGCGCTATCGTCGGGAGCAGACCCTGTCTGAGATGAC
GGCCTTGGTGTCCACCTCGCGCGATTTCGACAGCGCCACCGAAGCCACCCTGTCACTGGTTCAAGAGGTGGAGCT
GGTCTCGCGCGGCTATCGAATGTTGGTCTCGCCAGGGCGTGTCGTTCATTGTCTCAACGGCTGACGCCTCTTGGC
AGCAGTGCTCCTTTGCCTCCCATCAGCCGGCTCGAGGACCGCAGCCAGAGTCGGAAGTGCGTTCGCCTGCGCAAG
GTGCTCAAAGACTCCCTGGGTGACGCTCTCACCAAGTATATCCAAGCGTCCAACGTCGTCAAAGGCTTCTCCGAA
CAGACTGAGCTCGAAAAGTACTACGATTTGTACGATGTAGGCGACTTTGACATGTCCGATGCCCTTCAGGGCTAC
TGCGAGACCGAGTTCGAGGACCCGGAGTCGGTGCGGAGCCTCAAGATCCTGACGGCCCGCTTCCATACGACACGG
AAGATGATCTTCTGCGCGCTGCTGGCCCTAGATGCCAACGGCGAGGCCATCGAGCTGCTCCGTTGGGGCGCCGCG
TACGAGGCACTTCGGGGTCTAAACACCACCACCAAGGCCTGCTACGACAGGATGCGGGCGATGCTGAGCGAGGAA
GAGAGTAGGCGTCCACCGTTCCGAGCTCGCCCTTGCTGACATGGACACTGACCCGACCGCCTTCGTAGCTTTCCC
TGTGCCGCCCTCCCCCAAGGGACCCATGTCGCCGAGCAGGGAGCGATGGCGCTCGCGGTGGCGGAAGCTGGATTC
GCTATCGACCGGGATACGAGGCCTGCAGGCCAAGCTCCATCTTTTGAGGGAGGAGTCAGACAGGGCCTTGGACGG
GTCCGACGACATCTCGCAGCTGGGGCCGCACCTAACGTCTCAGTACGAGTCCATCGGCGTCGACCTCCGGCAGCT
CATGGCGGCATGGGAAGAAGGCAAGGCTGCACTGGCTCTCGGCATCGACAGAAACGAGAAGAGGTTGTCGTCGAT
GAGCTCAGTGCTGTCGCCGACGGGATCCCTGAGCGGACTGACGACGGTAGACGAGGGCGGCGACGCGGCGGATGC
GCTCAAGGCGCTGACGGGCGAGTCGCCGCCGCCATCGGACTCGGATATGCCCGAGGTGCTAGAGGCGGTGGCTCG
GCCGCGGCCACGAAGCCTGCTGACACGGGAAGAGCGCATCGTCAAGATGAGGGAGGATAGGGAGCAAAAGGCGCA
GGCCCGCCAGCAACTCGACGCCACACGCGGCATGCTGCGCGAGCTGGAGAGCGTCATCAGCCTGCGGCCGCGGAG
CCGGCTCAGCGCACCCCCGCTCAGAGGCGGACGGGTAGCGTCGATGTGACGACAGCTTTTGTTTCTGCGGCACTT
CATCTTCTTCTTCTCTATGTCCTTGTTTTGCCACTTGTACACACACCAGGCCCGCGATTTGGCGCGAGGCGGGAC
ATATTCCGCCGTGTACGGACTCTGGACGGGTTGGATGTCCGAGGGGGGCGCTGGGTACCTATGCTGGGACAATTT
TTTTTTCCTTTGTGTCGATTTTCCTTTGACTGTACGGGGAGATGAATTTTGGCATATAGGTTAATAGACAGCAGC
AAATCAACGGTTTCATGCCTCAATGCTTGATACCGTCACCTCAGCCTCAATTTGCTTCTTGAGTGCAACGGTCGC
GGGAAAACAAATCTCCGGCCGGCCAAGCCCCGCCACGCGACGCGTCGAGCCGGCGCGTGTAAAGTGCCTCCCCGC
CCTTTCTTTCTCCTGCTGCCGCTTCTTTTTTTCCACCGCGACTTGACTTGGACATTTACCCTTTCATAGACCGGA
GAGACACAAACGTTCATCCTTGTGCTGATTGTCCCCCGAGCCTCGCAAAGCCGCTTCGCCAATCCGCTATCCGCC
TTCTCCCCCTACCTTGTGTCTGACTCTCTCTCCGGTCTTGTCTTTGGCCCTCTCCGGGAGCTTTCTTGACCCGCC
TCCTCGTGTCGACCACGCGACGTCGAGGTCATCTTCTCACCTTGTTCTCATAATACCCCATCTTGGCACTTTCCA
GCTGACGGTTGGTCCTTTGCGTTGGCCTACCATCGCCAAGCAAAAGGCTGACAGCGCCGCGCAGAAATGTTGGAG
GCACGGCTCGAGCAGGCTAACATCCTCAAAAAGGTTATTCCCCCCTTTTCCTCTCCCCGTTCGCGTCTCGGCACA
GCTGACAGGCGCCCGCAGTTGGTCGACTCCATCAAGGATCTCGTTCAGGACTGCAACTTCGATTGCAATGACTCG
GGCATTGCGCTCCAGGCCATGGACAACTCGCACGTCGCCCTCGTGTCCATGATGCTAAAGGCAGAAGGCTTCTCG
CCCTATCGGTGCGATCGCAACATTCCGCTGGGCGTCAATCTGGCGTCCCTGACCAAGGTCCTGCGCGCGGCGCAA
AACGAGGACATCCTGACACTCAAGGCGCAGGACGCGCCCGACGTGCTCAACTTGGTGTTTGAGAGCAGCGAGAAC
GACCGGATCAGCGAGTACGACCTGAAGCTCATGGACATTGACCAGGAGCACCTGGGCATCCCAGACACTGAGTAC
GCGGCCTCGATCACGATGCCGGCCGCCGAGTTCCGGAGGATCTGCACTGATCTGGCTGCCATGTCCGAATCGGGT
ACGATCATTTTAGACATGTCTCCGGCCGCCGATGGCTGACTTTGTTCCAGTGAGCATCGAGGCTAGCAAGGACGG
CATCAAGTTTGCGTGCAACGGCGACATTGGCAACGGCTCCGTCGTCCTCCGGAGTCACACCAACGTGGACAAGCC
CGAGCTCAACATTGACATCGACCTGACGGAGCCCGTCTCCCTGACGTTTTCGCTCAAGTACCTTGTCAATTTCTG
CAAGGCCTCGACTCTTTCCAACACGGTCAAGCTCTGCCTGTCGAGCGAAGTGCCACTGCTGGTCGAGTACAACCT
GTCGGGCAGCAGCTACTTGCGCTTCTATCTGGCGCCCAAGGTGCGTCGTTGTCTTCCGTTTTCGTCTTCCATCTT
TAACCGTTGGCGCTCTGCAGATTGGCGACGAAGAGTAA

© 2022 - Robin Ohm - Utrecht University - The Netherlands

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