Ophiocordyceps australis 1348a (Ghana)

General Properties

Protein ID	OphauG2\|5330
Gene name
Location	Contig_486:1359..3798
Strand	+
Gene length (bp)	2439
Transcript length (bp)	2088
Coding sequence length (bp)	2088
Protein length (aa)	696

PFAM Domains

PFAM Domain ID	Short name	Long name	E-value	Start	End
PF13086	AAA_11	AAA domain	1.3E-59	207	422
PF13087	AAA_12	AAA domain	2.9E-54	450	660
PF13604	AAA_30	AAA domain	1.8E-11	207	418
PF13245	AAA_19	AAA domain	6.0E-08	212	418
PF04851	ResIII	Type III restriction enzyme, res subunit	1.9E-05	208	389
PF09848	DUF2075	Schlafen group 3, DNA/RNA helicase domain	1.2E-04	224	394

Swissprot hits

[Show all]

Swissprot ID	Swissprot Description	Start	End	E-value
sp\|O94247\|HCS1_SCHPO	DNA polymerase alpha-associated DNA helicase A OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=hcs1 PE=3 SV=1	6	681	0.0E+00
sp\|P34243\|HCS1_YEAST	DNA polymerase alpha-associated DNA helicase A OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=HCS1 PE=1 SV=1	8	688	1.0E-146
sp\|P38935\|SMBP2_HUMAN	DNA-binding protein SMUBP-2 OS=Homo sapiens GN=IGHMBP2 PE=1 SV=3	1	684	3.0E-146
sp\|Q60560\|SMBP2_MESAU	DNA-binding protein SMUBP-2 OS=Mesocricetus auratus GN=IGHMBP2 PE=1 SV=1	1	684	2.0E-143
sp\|P40694\|SMBP2_MOUSE	DNA-binding protein SMUBP-2 OS=Mus musculus GN=Ighmbp2 PE=1 SV=1	1	684	3.0E-142

[Show all]

[Show less]

Swissprot ID	Swissprot Description	Start	End	E-value
sp\|O94247\|HCS1_SCHPO	DNA polymerase alpha-associated DNA helicase A OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=hcs1 PE=3 SV=1	6	681	0.0E+00
sp\|P34243\|HCS1_YEAST	DNA polymerase alpha-associated DNA helicase A OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=HCS1 PE=1 SV=1	8	688	1.0E-146
sp\|P38935\|SMBP2_HUMAN	DNA-binding protein SMUBP-2 OS=Homo sapiens GN=IGHMBP2 PE=1 SV=3	1	684	3.0E-146
sp\|Q60560\|SMBP2_MESAU	DNA-binding protein SMUBP-2 OS=Mesocricetus auratus GN=IGHMBP2 PE=1 SV=1	1	684	2.0E-143
sp\|P40694\|SMBP2_MOUSE	DNA-binding protein SMUBP-2 OS=Mus musculus GN=Ighmbp2 PE=1 SV=1	1	684	3.0E-142
sp\|Q9EQN5\|SMBP2_RAT	DNA-binding protein SMUBP-2 OS=Rattus norvegicus GN=Ighmbp2 PE=1 SV=1	1	684	4.0E-142
sp\|Q57568\|Y104_METJA	Uncharacterized ATP-dependent helicase MJ0104 OS=Methanocaldococcus jannaschii (strain ATCC 43067 / DSM 2661 / JAL-1 / JCM 10045 / NBRC 100440) GN=MJ0104 PE=3 SV=1	61	680	4.0E-74
sp\|Q09820\|RENT1_SCHPO	ATP-dependent helicase upf1 OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=upf1 PE=3 SV=2	185	677	1.0E-53
sp\|Q9HEH1\|RENT1_NEUCR	Regulator of nonsense transcripts 1 homolog OS=Neurospora crassa (strain ATCC 24698 / 74-OR23-1A / CBS 708.71 / DSM 1257 / FGSC 987) GN=2E4.130 PE=3 SV=1	208	665	6.0E-53
sp\|Q9VYS3\|RENT1_DROME	Regulator of nonsense transcripts 1 homolog OS=Drosophila melanogaster GN=Upf1 PE=1 SV=2	208	680	2.0E-52
sp\|Q9EPU0\|RENT1_MOUSE	Regulator of nonsense transcripts 1 OS=Mus musculus GN=Upf1 PE=1 SV=2	208	665	4.0E-52
sp\|Q92900\|RENT1_HUMAN	Regulator of nonsense transcripts 1 OS=Homo sapiens GN=UPF1 PE=1 SV=2	208	665	5.0E-52
sp\|Q9FJR0\|RENT1_ARATH	Regulator of nonsense transcripts 1 homolog OS=Arabidopsis thaliana GN=UPF1 PE=1 SV=2	208	665	2.0E-51
sp\|P30771\|NAM7_YEAST	ATP-dependent helicase NAM7 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=NAM7 PE=1 SV=1	206	678	4.0E-48
sp\|Q54I89\|RENT1_DICDI	Regulator of nonsense transcripts 1 OS=Dictyostelium discoideum GN=upf1 PE=3 SV=1	208	665	3.0E-47
sp\|Q98TR3\|RENT1_TAKRU	Putative regulator of nonsense transcripts 1 OS=Takifugu rubripes GN=rent1 PE=3 SV=1	208	665	1.0E-43
sp\|O76512\|RENT1_CAEEL	Regulator of nonsense transcripts 1 OS=Caenorhabditis elegans GN=smg-2 PE=1 SV=1	208	665	5.0E-43
sp\|Q8QHA5\|DNA2_XENLA	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Xenopus laevis GN=dna2 PE=1 SV=1	208	665	2.0E-42
sp\|P38859\|DNA2_YEAST	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=DNA2 PE=1 SV=1	205	680	7.0E-40
sp\|P32644\|ECM32_YEAST	Putative ATP-dependent RNA helicase ECM32 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=ECM32 PE=1 SV=1	199	690	2.0E-39
sp\|E1BMP7\|DNA2_BOVIN	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Bos taurus GN=DNA2 PE=3 SV=3	182	665	2.0E-39
sp\|P51530\|DNA2_HUMAN	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Homo sapiens GN=DNA2 PE=1 SV=3	208	658	3.0E-39
sp\|Q92355\|SEN1_SCHPO	Helicase sen1 OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=sen1 PE=1 SV=1	208	663	1.0E-38
sp\|Q7Z333\|SETX_HUMAN	Probable helicase senataxin OS=Homo sapiens GN=SETX PE=1 SV=4	208	679	3.0E-38
sp\|A2AKX3\|SETX_MOUSE	Probable helicase senataxin OS=Mus musculus GN=Setx PE=1 SV=1	208	679	5.0E-38
sp\|D3ZG52\|DNA2_RAT	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Rattus norvegicus GN=Dna2 PE=3 SV=1	208	665	9.0E-38
sp\|Q6ZQJ5\|DNA2_MOUSE	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Mus musculus GN=Dna2 PE=1 SV=2	208	665	2.0E-37
sp\|Q00416\|SEN1_YEAST	Helicase SEN1 OS=Saccharomyces cerevisiae (strain ATCC 204508 / S288c) GN=SEN1 PE=1 SV=2	60	682	4.0E-37
sp\|O94387\|YGSA_SCHPO	Uncharacterized ATP-dependent helicase C29A10.10c OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=SPBC29A10.10c PE=3 SV=1	60	669	3.0E-36
sp\|B6SFA4\|MAA3_ARATH	Probable helicase MAGATAMA 3 OS=Arabidopsis thaliana GN=MAA3 PE=2 SV=1	242	663	8.0E-36
sp\|Q5ZKG3\|DNA2_CHICK	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Gallus gallus GN=DNA2 PE=2 SV=2	208	658	1.0E-35
sp\|E9QAM5\|HELZ2_MOUSE	Helicase with zinc finger domain 2 OS=Mus musculus GN=Helz2 PE=1 SV=1	208	683	2.0E-34
sp\|Q86AS0\|Y4399_DICDI	Probable helicase DDB_G0274399 OS=Dictyostelium discoideum GN=DDB_G0274399 PE=3 SV=1	252	678	1.0E-33
sp\|Q9BXT6\|M10L1_HUMAN	Putative helicase Mov10l1 OS=Homo sapiens GN=MOV10L1 PE=2 SV=1	191	669	5.0E-30
sp\|Q8GYD9\|SDE3_ARATH	Probable RNA helicase SDE3 OS=Arabidopsis thaliana GN=SDE3 PE=1 SV=1	204	671	9.0E-30
sp\|Q9URU2\|DNA2_SCHPO	DNA replication ATP-dependent helicase/nuclease dna2 OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=dna2 PE=1 SV=2	207	678	1.0E-29
sp\|Q9BYK8\|HELZ2_HUMAN	Helicase with zinc finger domain 2 OS=Homo sapiens GN=HELZ2 PE=1 SV=6	178	683	1.0E-29
sp\|Q99MV5\|M10L1_MOUSE	Putative helicase Mov10l1 OS=Mus musculus GN=Mov10l1 PE=1 SV=1	202	669	3.0E-29
sp\|Q5ZKD7\|MOV10_CHICK	Putative helicase MOV-10 OS=Gallus gallus GN=MOV10 PE=2 SV=1	203	684	9.0E-26
sp\|Q0VGT4\|ZGRF1_MOUSE	Protein ZGRF1 OS=Mus musculus GN=Zgrf1 PE=1 SV=2	211	682	2.0E-25
sp\|P23249\|MOV10_MOUSE	Putative helicase MOV-10 OS=Mus musculus GN=Mov10 PE=1 SV=2	227	681	2.0E-25
sp\|Q0V8H6\|MOV10_BOVIN	Putative helicase MOV-10 OS=Bos taurus GN=MOV10 PE=2 SV=1	227	681	2.0E-25
sp\|Q6J5K9\|ARMI_DROME	Probable RNA helicase armi OS=Drosophila melanogaster GN=armi PE=1 SV=4	199	659	8.0E-25
sp\|Q86YA3\|ZGRF1_HUMAN	Protein ZGRF1 OS=Homo sapiens GN=ZGRF1 PE=2 SV=3	225	659	2.0E-23
sp\|Q9HCE1\|MOV10_HUMAN	Putative helicase MOV-10 OS=Homo sapiens GN=MOV10 PE=1 SV=2	187	681	1.0E-22
sp\|Q1LXK4\|M10B1_DANRE	Putative helicase mov-10-B.1 OS=Danio rerio GN=mov10b.1 PE=2 SV=2	227	676	2.0E-21
sp\|Q8R151\|ZNFX1_MOUSE	NFX1-type zinc finger-containing protein 1 OS=Mus musculus GN=Znfx1 PE=1 SV=3	313	665	2.0E-20
sp\|Q9P2E3\|ZNFX1_HUMAN	NFX1-type zinc finger-containing protein 1 OS=Homo sapiens GN=ZNFX1 PE=2 SV=2	313	665	3.0E-20
sp\|P42694\|HELZ_HUMAN	Probable helicase with zinc finger domain OS=Homo sapiens GN=HELZ PE=1 SV=2	184	684	1.0E-18
sp\|F6QXW0\|DNA2_XENTR	DNA replication ATP-dependent helicase/nuclease DNA2 OS=Xenopus tropicalis GN=dna2 PE=3 SV=1	444	665	1.0E-18
sp\|Q6DFV5\|HELZ_MOUSE	Probable helicase with zinc finger domain OS=Mus musculus GN=Helz PE=1 SV=2	184	684	2.0E-18
sp\|Q6NYU2\|HELZ_DANRE	Probable helicase with zinc finger domain OS=Danio rerio GN=helz PE=2 SV=1	184	683	7.0E-18
sp\|Q1LXK5\|M10B2_DANRE	Putative helicase mov-10-B.2 OS=Danio rerio GN=mov10b.2 PE=3 SV=1	227	693	1.0E-17
sp\|O74465\|HRR1_SCHPO	Helicase required for RNAi-mediated heterochromatin assembly 1 OS=Schizosaccharomyces pombe (strain 972 / ATCC 24843) GN=hrr1 PE=1 SV=2	340	667	5.0E-17
sp\|Q09449\|YQ12_CAEEL	Uncharacterized ATP-dependent helicase C05C10.2 OS=Caenorhabditis elegans GN=C05C10.2 PE=3 SV=1	469	669	1.0E-10

[Show less]

GO

GO Term	Description	Terminal node
GO:0003677	DNA binding	Yes
GO:0004386	helicase activity	Yes
GO:0016787	hydrolase activity	Yes
GO:0005524	ATP binding	Yes
GO:0035639	purine ribonucleoside triphosphate binding	No
GO:0140640	catalytic activity, acting on a nucleic acid	No
GO:0000166	nucleotide binding	No
GO:0043167	ion binding	No
GO:0003676	nucleic acid binding	No
GO:0043168	anion binding	No
GO:1901363	heterocyclic compound binding	No
GO:0032553	ribonucleotide binding	No
GO:1901265	nucleoside phosphate binding	No
GO:0017076	purine nucleotide binding	No
GO:0030554	adenyl nucleotide binding	No
GO:0140657	ATP-dependent activity	No
GO:0005488	binding	No
GO:0036094	small molecule binding	No
GO:0003674	molecular_function	No
GO:0097159	organic cyclic compound binding	No
GO:0032559	adenyl ribonucleotide binding	No
GO:0097367	carbohydrate derivative binding	No
GO:0003824	catalytic activity	No
GO:0032555	purine ribonucleotide binding	No

SignalP

[Help with interpreting these statistics]

SignalP signal predicted	Location (based on Ymax)	D score (significance: > 0.45)
No	1 - 12	0.45

Transmembrane Domains

(None)

Transcription Factor Class

(None)

Expression data

No expression data available for this genome

Sequences

Type of sequence	Sequence
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	>OphauG2\|5330 MAPISIPDFATAQLALLDDELQAQVAESSSLIASHAPASLQRAGLALTSLVVNARRTGFGGRTVVDLGPDAATAT TSHLPEHGIRPGDIVLVAEQPAGSAKKREAQELQRRGVRGVVVKVLRASLCVALDEGKDDEAGLTTRLWVVKLAD EVTYRRMNLTMEKLQKMDPSQYSAMIRVLFGLSTPSPVAPDLSQDEQVGKIEWIDATLNDSQKDAIRFALASREI ALIHGPPGTGKTHTLIELILQLRKRGQRILVCGPSNISVDNIVERLAPHKVPMLRLGHPARLLPSVVSHSLDVLT QTSEAGAIVKDVRSEMDLKQASIKKTKSGKERRAIYADLKELRKEYRLREKNCVSSLVRGTKVVLATLHGAGGAQ LRSEAFDLVIIDEASQALEAQCWVPLLAAKKVVCAGDHLQLPPTIKSTNSKLKPQDIETRGKATQELPIKGINLA TTLFDRLLALHGPSIKRMLTTQYRMHDKIMRFPSNELYDAKLVAADAVKHRLLRDLNYPVDDNQDTTEPLIFIDT QGGDFAERSHDEKDDADSVRKTKASLHGDSKSNDMEASLVKQHVKQLIDAGVHAEDIAVVTPYNAQLALLAPLKE QFPGIELGSVDGFQGREKEAVIVSLVRSNAEGEVGFLGEKRRLNVAMTRPKRSLTVIGDSETVGRGSTFLKRWME FLEDQADLRYPDLSAVSREG*
Coding	>OphauG2\|5330 ATGGCCCCCATTTCCATTCCCGACTTCGCCACGGCTCAGCTCGCCCTGCTCGACGACGAGCTCCAAGCCCAAGTC GCCGAGTCGAGCTCCCTCATTGCATCCCATGCCCCCGCTTCTCTGCAGCGCGCCGGTCTTGCCCTGACCTCTCTT GTCGTCAACGCGCGCCGCACCGGCTTTGGCGGCCGCACCGTGGTTGATCTCGGCCCCGATGCTGCCACGGCAACC ACCTCTCACTTGCCCGAGCATGGCATCCGTCCCGGAGACATTGTCCTCGTCGCTGAGCAGCCCGCCGGCAGCGCC AAGAAACGCGAGGCTCAGGAGCTGCAGCGCCGAGGCGTCAGAGGCGTCGTCGTCAAGGTGCTAAGAGCCTCCCTG TGCGTCGCCCTCGACGAGGGCAAAGACGATGAAGCCGGCTTGACCACCAGGCTTTGGGTCGTCAAGTTGGCCGAC GAAGTGACATATCGCCGAATGAACCTCACCATGGAGAAGCTGCAGAAAATGGACCCTTCTCAGTACTCTGCCATG ATCAGGGTTCTATTCGGCCTGTCCACCCCCTCCCCCGTTGCGCCCGATCTGAGCCAGGACGAGCAAGTTGGAAAA ATCGAGTGGATAGATGCTACGCTCAACGACTCCCAAAAGGACGCCATTCGCTTCGCCCTGGCCTCTCGCGAAATT GCCCTCATTCATGGGCCGCCAGGAACCGGGAAAACTCACACCCTCATCGAGCTTATTCTACAACTGCGGAAGCGC GGGCAGAGAATCTTGGTGTGCGGTCCGTCAAATATCTCTGTTGACAACATTGTCGAGCGGCTGGCGCCCCATAAA GTGCCCATGCTGCGTCTCGGTCATCCGGCTCGTCTCCTCCCGTCAGTCGTCAGTCACTCTCTCGATGTGCTGACA CAGACTTCAGAGGCCGGTGCCATAGTCAAAGACGTGCGCTCCGAGATGGACTTGAAACAAGCCTCGATAAAGAAA ACCAAGAGCGGAAAGGAGCGGCGAGCAATCTACGCCGACCTCAAGGAACTGAGAAAAGAGTACCGCCTTCGCGAA AAAAACTGTGTCAGCAGCCTGGTGCGAGGAACAAAGGTTGTTCTTGCCACTCTCCATGGCGCTGGCGGAGCTCAG TTGCGCAGTGAAGCATTCGACCTTGTCATTATCGACGAGGCTAGCCAAGCCCTCGAGGCTCAATGCTGGGTGCCT CTGCTAGCAGCGAAAAAAGTTGTATGTGCCGGTGATCATCTCCAACTGCCACCAACCATCAAGTCGACCAATTCC AAGCTCAAGCCGCAGGACATAGAGACTCGGGGCAAAGCGACGCAGGAGCTACCAATCAAGGGCATCAACCTTGCC ACGACGCTCTTTGACCGTCTCTTGGCTCTCCACGGGCCCTCAATCAAGCGCATGCTGACAACCCAGTATCGAATG CATGACAAAATTATGCGGTTCCCCTCCAACGAGCTATACGATGCAAAGCTTGTTGCTGCCGACGCCGTCAAGCAT CGTCTCCTGCGAGACTTGAACTACCCTGTCGACGACAATCAAGATACCACGGAACCCCTCATTTTTATTGATACG CAGGGCGGTGACTTTGCGGAGAGGAGTCATGATGAAAAGGACGACGCTGACAGCGTCCGCAAGACCAAGGCAAGC TTACACGGCGACAGCAAAAGCAATGACATGGAGGCATCTCTAGTGAAGCAGCATGTCAAGCAACTGATTGATGCC GGAGTGCATGCAGAAGATATTGCCGTTGTGACTCCCTATAATGCCCAGCTTGCGCTGCTGGCACCACTCAAGGAG CAATTTCCTGGCATAGAGCTTGGAAGCGTCGACGGCTTCCAGGGCCGCGAAAAGGAAGCTGTCATTGTCAGTCTT GTGCGGAGCAATGCCGAGGGAGAGGTTGGCTTCCTGGGAGAAAAGCGGCGGTTGAACGTTGCAATGACACGCCCC AAACGATCACTAACTGTCATTGGCGACTCGGAAACGGTGGGCAGGGGCAGTACTTTCCTCAAGCGATGGATGGAG TTTCTAGAAGATCAGGCCGATCTGCGATATCCCGACCTCTCAGCCGTGAGCCGAGAGGGCTAG
Transcript	>OphauG2\|5330 ATGGCCCCCATTTCCATTCCCGACTTCGCCACGGCTCAGCTCGCCCTGCTCGACGACGAGCTCCAAGCCCAAGTC GCCGAGTCGAGCTCCCTCATTGCATCCCATGCCCCCGCTTCTCTGCAGCGCGCCGGTCTTGCCCTGACCTCTCTT GTCGTCAACGCGCGCCGCACCGGCTTTGGCGGCCGCACCGTGGTTGATCTCGGCCCCGATGCTGCCACGGCAACC ACCTCTCACTTGCCCGAGCATGGCATCCGTCCCGGAGACATTGTCCTCGTCGCTGAGCAGCCCGCCGGCAGCGCC AAGAAACGCGAGGCTCAGGAGCTGCAGCGCCGAGGCGTCAGAGGCGTCGTCGTCAAGGTGCTAAGAGCCTCCCTG TGCGTCGCCCTCGACGAGGGCAAAGACGATGAAGCCGGCTTGACCACCAGGCTTTGGGTCGTCAAGTTGGCCGAC GAAGTGACATATCGCCGAATGAACCTCACCATGGAGAAGCTGCAGAAAATGGACCCTTCTCAGTACTCTGCCATG ATCAGGGTTCTATTCGGCCTGTCCACCCCCTCCCCCGTTGCGCCCGATCTGAGCCAGGACGAGCAAGTTGGAAAA ATCGAGTGGATAGATGCTACGCTCAACGACTCCCAAAAGGACGCCATTCGCTTCGCCCTGGCCTCTCGCGAAATT GCCCTCATTCATGGGCCGCCAGGAACCGGGAAAACTCACACCCTCATCGAGCTTATTCTACAACTGCGGAAGCGC GGGCAGAGAATCTTGGTGTGCGGTCCGTCAAATATCTCTGTTGACAACATTGTCGAGCGGCTGGCGCCCCATAAA GTGCCCATGCTGCGTCTCGGTCATCCGGCTCGTCTCCTCCCGTCAGTCGTCAGTCACTCTCTCGATGTGCTGACA CAGACTTCAGAGGCCGGTGCCATAGTCAAAGACGTGCGCTCCGAGATGGACTTGAAACAAGCCTCGATAAAGAAA ACCAAGAGCGGAAAGGAGCGGCGAGCAATCTACGCCGACCTCAAGGAACTGAGAAAAGAGTACCGCCTTCGCGAA AAAAACTGTGTCAGCAGCCTGGTGCGAGGAACAAAGGTTGTTCTTGCCACTCTCCATGGCGCTGGCGGAGCTCAG TTGCGCAGTGAAGCATTCGACCTTGTCATTATCGACGAGGCTAGCCAAGCCCTCGAGGCTCAATGCTGGGTGCCT CTGCTAGCAGCGAAAAAAGTTGTATGTGCCGGTGATCATCTCCAACTGCCACCAACCATCAAGTCGACCAATTCC AAGCTCAAGCCGCAGGACATAGAGACTCGGGGCAAAGCGACGCAGGAGCTACCAATCAAGGGCATCAACCTTGCC ACGACGCTCTTTGACCGTCTCTTGGCTCTCCACGGGCCCTCAATCAAGCGCATGCTGACAACCCAGTATCGAATG CATGACAAAATTATGCGGTTCCCCTCCAACGAGCTATACGATGCAAAGCTTGTTGCTGCCGACGCCGTCAAGCAT CGTCTCCTGCGAGACTTGAACTACCCTGTCGACGACAATCAAGATACCACGGAACCCCTCATTTTTATTGATACG CAGGGCGGTGACTTTGCGGAGAGGAGTCATGATGAAAAGGACGACGCTGACAGCGTCCGCAAGACCAAGGCAAGC TTACACGGCGACAGCAAAAGCAATGACATGGAGGCATCTCTAGTGAAGCAGCATGTCAAGCAACTGATTGATGCC GGAGTGCATGCAGAAGATATTGCCGTTGTGACTCCCTATAATGCCCAGCTTGCGCTGCTGGCACCACTCAAGGAG CAATTTCCTGGCATAGAGCTTGGAAGCGTCGACGGCTTCCAGGGCCGCGAAAAGGAAGCTGTCATTGTCAGTCTT GTGCGGAGCAATGCCGAGGGAGAGGTTGGCTTCCTGGGAGAAAAGCGGCGGTTGAACGTTGCAATGACACGCCCC AAACGATCACTAACTGTCATTGGCGACTCGGAAACGGTGGGCAGGGGCAGTACTTTCCTCAAGCGATGGATGGAG TTTCTAGAAGATCAGGCCGATCTGCGATATCCCGACCTCTCAGCCGTGAGCCGAGAGGGCTAG
Gene	>OphauG2\|5330 ATGGCCCCCATTTCCATTCCCGACTTCGCCACGGCTCAGCTCGCCCTGCTCGACGACGAGCTCCAAGCCCAAGTC GCCGAGTCGAGCTCCCTCATTGCATCCCATGCCCCCGCTTCTCTGCAGCGCGCCGGTCTTGCCCTGACCTCTCTT GTCGTCAACGCGCGCCGCACCGGCTTTGGCGGCCGCACCGTGGTTGATCTCGGCCCCGATGCTGCCACGGCAACC ACCTCTCACTTGCCCGAGCATGGCATCCGTCCCGGAGACATTGTCCTCGTCGCTGAGCAGCCCGCCGGCAGCGCC AAGAAACGCGAGGCTCAGGAGCTGCAGCGCCGAGGCGTCAGAGGCGTCGTCGTCAAGGTGCTAAGAGCCTCCCTG TGCGTCGCCCTCGACGAGGGCAAAGACGATGAAGCCGGCTTGACCACCAGGCTTTGGGTCGTCAAGTTGGCCGAC GAAGTGACATATCGCCGGTATGCTCGTTCTTCTTCGTCCTTGTGCCAACCTCTTCCTCATGCTATCTGGCTCCCT CAACTAACGCGTCTCCCGTCTTCCATCCAATGCTCCCAGAATGAACCTCACCATGGAGAAGCTGCAGAAAATGGA CCCTTCTCAGTACTCTGCCATGATCAGGGTTCTATTCGGCCTGTCCACCCCCTCCCCCGTTGCGCCCGATCTGAG CCAGGACGAGCAAGTTGGAAAAATCGAGTGGATAGATGCTACGCTCAACGACTCCCAAAAGGACGCCATTCGCTT CGCCCTGGCCTCTCGCGAAATTGCCCTCATTCATGGGCCGCCAGGAGTGTGTGCCTCACCACCACAAGTGGCCAA CCGCCGCTGACATTGCCCTCTCCTAGACCGGGAAAACTCACACCCTCATCGAGCTTATTCTACAACTGCGGAAGC GCGGGCAGAGAATCTTGGTGTGCGGTCCGTCAAATATCTCTGTTGACAACATTGTCGAGCGGCTGGCGCCCCATA AAGTGCCCATGCTGCGTCTCGGTCATCCGGCTCGTCTCCTCCCGTCAGTCGTCAGTCACTCTCTCGATGTGCTGA CACAGACTTCAGAGGCCGGTGCCATAGTCAAAGACGTGCGCTCCGAGATGGACTTGAAACAAGCCTCGATAAAGA AAACCAAGAGCGGAAAGGAGCGGCGAGCAATCTACGCCGACCTCAAGGAACTGAGAAAAGAGTACCGCCTTCGCG AAAAAAACTGTGTCAGCAGCCTGGTGCGAGGAACAAAGGTTGTTCTTGCCACTCTCCATGGCGCTGGCGGAGCTC AGTTGCGCAGTGAAGCATTCGACCTTGTCATTATCGACGAGGCTAGCCAAGCCCTCGAGGCTCAATGCTGGGTGC CTCTGCTAGCAGCGAAAAAAGTTGTATGTGCCGGTGATCATCTCCAACTGCCACCAACCATCAAGTCGACCAATT CCAAGCTCAAGCCGCAGGACATAGAGACTCGGGGCAAAGCGACGCAGGAGCTACCAATCAAGGGCATCAACCTTG CCACGACGCTCTTTGACCGTCTCTTGGCTCTCCACGGGCCCTCAATCAAGCGCATGCTGACAACCCAGTATCGAA TGCATGACAAAATTATGCGGTTCCCCTCCAACGAGCTATACGATGCAAAGCTTGTTGCTGCCGACGCCGTCAAGC ATCGTCTCCTGCGAGACTTGAACTACCCTGTCGACGACAATCAAGATACCACGGAACCCCTCATTTTTATTGATA CGCAGGGCGGTGACTTTGCGGAGAGGAGTCATGATGAAAAGGACGACGCTGACAGCGTCCGCAAGACCAAGGCAA GCTTACACGGCGACAGCAAAAGCAATGACATGGAGGCATCTCTAGTGAAGCAGCATGTCAAGCAACTGATTGATG CCGGAGTGCATGCAGAAGATATTGCCGTTGTGACTCCCTATAATGCCCAGGTAGCGTGTTGCAAGCCGGGTCTCG CCACAGATTCTTATGCTGACCCGACTTGCCCGCCATAGCTTGCGCTGCTGGCACCACTCAAGGAGCAATTTCCTG GCATAGAGCTTGGAAGCGTCGACGGCTTCCAGGGCCGCGAAAAGGAAGCTGTCATTGTCAGTCTTGTGCGGAGCA ATGCCGAGGGAGAGGTTGGCTTCCTGGGAGAAAAGCGGCGGTTGAACGGTTAGTGGCTGTTGTGTCGTGTCGTGT CTTAAAATTGTTTATTGTTAACGACAGACTAGTTGCAATGACACGCCCCAAACGATCACTAACTGTCATTGGCGA CTCGGAAACGGTGGGCAGGTAAGGGAAAAAGGCCCATGTAAACAAAGATTTGCCCGTCACCAGACTAATGTGTTG AATTCATCGTGTGTTGGTAGGGGCAGTACTTTCCTCAAGCGATGGATGGAGTTTCTAGAAGATCAGGCCGATCTG CGATATCCCGACCTCTCAGCCGTGAGCCGAGAGGGCTAG

Fungal Genomics

General Properties

PFAM Domains

Swissprot hits

GO

SignalP

Transmembrane Domains

Transcription Factor Class

Expression data

Sequences