Basic Information

Insect: Conops quadrifasciatus
Gene Symbol: Camta1
Assembly: GCA_949752815.1
Location: OX457077.1:1427132-1454816[+]

Transcription Factor Domain

TF Family: CG-1
Domain: CG-1 domain
PFAM: PF03859
TF Group: Unclassified Structure
Description: CG-1 domains are highly conserved domains of about 130 amino-acid residues containing a predicted bipartite NLS and named after a partial cDNA clone isolated from parsley encoding a sequence-specific DNA-binding protein [2]. CG-1 domains are associated with CAMTA proteins (for CAlModulin -binding Transcription Activator) that are transcription factors containing a calmodulin -binding domain and ankyrins (ANK) motifs [1].
Hmmscan Out: # of c-Evalue i-Evalue score bias hmm coord from hmm coord to ali coord from ali coord to env coord from env coord to acc

1 2 2.3e-45 6e-41 139.4 0.4 10 116 28 132 24 132 0.98

2 2 0.18 4.7e+03 -2.1 1.9 42 88 339 385 306 397 0.53

#	of	c-Evalue	i-Evalue	score	bias	hmm coord from	hmm coord to	ali coord from	ali coord to	env coord from	env coord to	acc
1	2	2.3e-45	6e-41	139.4	0.4	10	116	28	132	24	132	0.98
2	2	0.18	4.7e+03	-2.1	1.9	42	88	339	385	306	397	0.53

Sequence Information

Coding Sequence: ATGGGCGATGGCCTGATGGACGACAAACGTGGCGTTGCTGTGCATGTTTACGATGAACTTATCAATTTGTTTGCTATCCTTGAAgaaATTGCTGCGATTCTTATCAGCTTCGACAAACACAGCGAATGGCAATCCAAAGAAGTCAGAACGAGACCCAAAAGTGGTTCACTGCTGTTGTACTCGAGGAAAAAAGTGCGCTACCGACGCGACGGCTACTGCTGGAAGAAGCGCAAAGATGGCAAAACAACGCGTGAGGATCACATGAAGCTAAAAGTGCAAGGAACGGAAtGCATCTACGGCTGCTACGTCCACTCCGCCATTTTGCCCACTTTTCATCGCAGATGCTACTGGTTGTTGCAGAATCCGGACATAGTGCTAGTTCATTACCTGAATGTGCCCTACCCGGACGACAACAAAATGGCCGTCATCGCTCCCAGCATAACGCTCTGGGGCGACAAGAAGGAGTGGACGAAGGAGGAGCTGGTCAGTCAGCTGAAGCCCATGTTATCCACAGTTAACTCCGACGACGATTCAGATTCTGGCAATGACATCGAGATCTCGACCGCTGAGACGGTGGAGTCCATAGTTTGCCAACTCATGGAGAAGCAAAGACTGTCGCGTCAGGCTGCTTTGGTCAAACAGCTGGATTGTGGCTGCGCCGACTCGACGTGCCTGGACGGCAAGTCTTGCTCGCATCCGGTGATGCGGCGCACCGGTCTGCTGAAGAGCGTAACGGAGAAGCGCGCGCATCTGAGCGACAGCTACAATCATGCGGCGACAACTGCCCCGAATGTCGTGGTCGGGCCAAAGCTGTATTCGCGTTGGCCCGAGCGGCGATCACGTGATGCCAACATGGAGCCTCAACAGCACTACCAGCCATCGCCTCAtgctcagcagcagcaactgccTGCCGAAGCAGCAGTCAAATTCCAAATTGTACAATCGCAACACAACGAACATCAGCTGCATCATGCTTCATCAGCATCTtatcatcaacagcagcatcagcagcagcagcatcaacagcaacagcagcctTTTCGACAGCAGCATAATCAAAATGTcgtcaataataataataatcatgtCGTCGCACCTCATCATCAATTATTGGTCAgcagaaataatttaattatacagcatcatcatcagcagcagcagcaacaaagtCCGGCCAATTTCCATCAAGTCACCAACACAGCGGCGCCGTCAACACACGTCGCCGCAAACAATCAAACTAATCAAATAAATCTGCAACGATTCGTAGccaatcacaacaacagcaataacaataatttacaaataataaataataatcgcTTGCAAATAGCTAAGACAACGATtacggcagcagcaacaacagcaacagcaacagcagcagcagcaggggCAGGCGGGCTGGCAGGCGAACTAATTGGAAATCAAAACCGCATTTCGGCAAGCTCAAATAACTCCACTCATAAAGTTAACCGCAGGAGCAACGAATTAACATTGCCacctcagcagcagcaacaacaacaacaacagcagcaacagagcCCGTCGACGGATgcaaatgttataaataataataataataataatcatagcATCGGCAGTAGTCACTTCTCGTATAATGCTTCTCACACTATTTCTGCCCTGCACCAAGAAGAGCAGTATAaaatgcagcagcaacaacagcaacagcaccaacaactgcgacaaataaaaacagccagtacagagcagcagcagcaagagtGTGCGGAGGCAAGCGCCGGTGTTCAGCCCATGTGCATGTCGCCGGAGCATCAACCCTCAACGCCAATACACGCTGGTAAcagtggcaacaacaacaacaacaacaacaacaacaacaatcaacacCCACTCTTATTACTGGGCAGGAGTAAcagccaaaacaacaacaacaacaacaacaacaccagcaataATATGCAAACATCCTCGTCATGCTCTTCCAGCTCTTCGCCCGGAACTCTAACGTCCTCCTCATGCCATTCGGCATCACCAattattgatgatgatggcagtGTCAATCATCACACGGCCCAGTCCTCGTCACCCGCGTCACCCGCGTCATCGgcactatcatcatcatcatcatcttcgcCGACTTCTTCAGCGTCCGCAAAAACAGCATTACAAACAGAGAATCCAATTAGTTCCAATGAAAACCAAAAGTCTTCTTCAATTGATGCTGGCAATGTTTTgaaatcagcagcaacaacaactgagGTGTCACCTTCACTTGATGACAACGCCTCCAATAGCGGTTGCactatacaacaacaacaatcgaatATATCTTCCATAAATAATCGTATAGACTACAGGAACAACGACAACACAGCAGGCACTAACCTCTGCCATTCCCTGAGTACTTCCCAGGAAAACACCAGCTCCACCAACGAAGAAGCAGAGACCAGTCACGATGTGCTCTCGACCAGTTCTCATACCACAATTGACTTCGAATCGATGGAAACTAATATAGCAGCTGTGGGTGTTGGTGATGGAGCTGGCGCTGGACCTGATGACAATTCGATCGCCTCGCGTGAACTGCACGATGCGCTGGGATTTTTCAATGAAACGCTCGACTTGTCCCAGGAGGACATACAGCGTACACTAATCGCCAACTTACCATTTGCAACGGATGCACACGGCCGAGAGCAGCACAGCACCAGTCATGGTGACTGTCATGAGGCGGCTGGTGGCTGTGTTGGTGTCGATGCAACGCTACTGGACAACAGCAGCGTGACATTTATGCCGGACAGCATTTGTGTCGCCGATGCCAATGTGGTTATTTCTGCAGCGCGTGCCAGAAGCTGCCAACAAGCGGACGCGGCGAATGATGTCTTAGTGAATCTGGATGCTTTCGATATGTTAGTAGAGTTTCCAGAACTGGATCTGGATAACAAGCAAGCCCTGACTCATGCGAGTTTAGAACCAGGCGCCGCTCAAACGCAGCAGCTAGCTGCTAATGCGAGCAGCAGCGATGATGTCTTTGCCGCCATCATCAGCAGTGACGATGACATACAGCACTTGTACACCTTCGAGGCCGGCGAGGAGAAGAGTGGCGCTCTAAGCGACAGGAAACTGTTGAACATTTGTGACTTCAGTCCGGACTGGTCTTACCCGGAGGGTGGCGTCAAAGTGCTGGTTGCCGGTCCGTGGACCAACTCGAGCGCCTCGTATACCGTGCTCTTCGATTCATTGCCGGTGCCGACGATGCACGTGCAAGCGGGAGTGCTGCGCTGCTACTGTCCGGCGCACGAGATCGGGTTTGCTACGATGCAGGTGTCCTGCGATGGCTACATAATTTCCCATTCGGTGATGTTCGAATACAAGGTGTTACCTTGTCCGGAAGCTCCTTTCGATGCGTTATCCAGCGACTGCCTGTACAAATTCACATTATTCAATCGACTTTCTTCCATTgatgaaaaaatgcaaatcaaAACGGAGATGGCTGAGCAGCAGTCTctgtattcacaagctcattTTGAGGACAAACTCGTCGGTTACTGCAATCAGTTGATGAAGGCTACGTGGCGTCAGAATTTGGCCAGTACTAGCAGCTGGACCAGTGGCTTCAAGGGCATGACCTTACTGCATTTGGCTGCTGCGTTGGGTTATTCGAAATTAGTTTGCGCCATGTTTCATTGGCGCACAGAGAATCCGAATTTCATTTTGGAAACTGAAATCGATGCACTCAGCCAGGATATATACGGCTATACGCCGATGACGTGGGCGTGTGCACGCGGTCATACCGAAACCGCTCTTTTGCTCTACAAATGGAATCAAAATGCGCTGAAAATAAGAAACCACGCACAACAGACCCCGCTAGATATTGCCAATCTGAAGGGTCACAAAACTTTGCTGCAAGAGATCTATCATTTGGAGTGTGAACGACTAAGAAAAGGCCGGACCTCATCGTTGAGCAGTTTGTCggtaaattttaacaaaaataatCTGAgcgataataaaattaaagtcgAACAGTGTACAAGAGAGTTATTGTACGATGAGAACTTAAGAAACAATCTATTTGCTGGACAGGAAGCAACCTATGAAACGCCCCGTAGCCACGATGGTGTATTTCTGAGGCCCATAGCTGTGGCAAGCAATCAAAGTCCGCCCAATTATAGTCGCTTCTCGAAGCGTTCATCGGTTGATAGCGGCATCAATGTTGACATTCGTGCCAGGCCTAGCAAACCACTGAAGGACAGTGGTCCGCGTTTACAGAGCTTTGATGGACATGATAATTTCTCATTTGCTTTGGAAACGCCTCTGGATGCTTTTGGCACCACGAATGCGACGAATTCCTTGCTCTCGCCGTTGCGTAAAATGGATTTTGCACTATGCGAAGTGTCCACAGGCGACTCAAGTCCTTTAGCCCACAAAGAACACGACGACGATTCATCAACGCTTAATAATGACGACAATAGCTCGGAAGTTGTTTTAAGTTGTGAAACCGATGGCGTCGTAGGGGATTCCGATGCCAAAGTGTTAACATTGGCCGAACACATAATAGCCGCCATGCCGGAACGCATCAAGAATGAAGCTGATGAGATGATGGTGCTCGGCAGTCCTATGGCTGAAACACTGAACTCGGAGACCTCCGGCCTAAACGATAATTTCATGGACCCTTTGTTGGACTCGTTGCCGGGTGCCCATTTTGAGAACGACTTCAGTTTGGACTTCAATGATCATAGCTATCGTTATCATGACGTCAGCACGCCGTGTTCCAGCCTGAGTCCGGCCAGTTCAGGACCGTTGCAATCGCCGGCCAGTTATTCGCTGCTCGGCACCGATCCTTCCGTCAACTCGCCCAGTCCACCGCCGTCAACGAAGCAACTGACAGAATTCTTGCATGCCTCCAACAACAGCCAGTGTCCCTTCGAAACGGACTTCTCGCGCCTTACTCTAACTGACAGCGAACAGCGAGAACTGTACGAAGCTGCCAAGTGCATACAGAAAGCTTATCGTTCCTACAAAGGACGCCAGAAGCTGGAAGAGCAGAACAAGGAGCGTTCGGCTGCTATTGTCATCCAGAATTACTACCGGCGTTACAAGCAGTACGCTTACTACCGCCAAATGACTAGTGCTGCGTTGGTCATCCAGCACGGCTATCGCTCGTATTGCAGAAACAAGCGCTTCAAGAAGTCGCAGCACAGTGCGACCAATAGccgcagcagtagcagcagcctCAGCAGCCGCAACAATTCGAGCAGCACGTCGCAGTGTCTGTCTACGTACTATGATCATTACAGAAAcgaccagcagcaacaacagcaggatCTGCTCAACTCTCAGCCCAGCACACCCAAGGAGACCAGTCCATCGGGACCCTTAAAACGAACCTATTCACAATCAACGCAAAATCAAGCTGCCAGAAAAATCCAACAGTTTATGAGACAATCGAGAATCAAACTACAGAAAGAACGAGCCGAAAAAGAGAAGCTGGTGCACCAACGCAGGGCGGAATACCTTCAAAGCTTGCAGTTTCAAGGTCAACCGGAAACTGCTTGCAAACCAGAATTAAGTGAAAAACGCTGTGGCATGCGATGGCTGGCTGTCAGAAGAAGCGGGGGCGTCGTGCGCTTCAACCAGCCTATGATATCATCTTCGAATTCAGTGGAAGTGGACATTTTAGATGAAGCTCTGAAAAATGTTTCAGAAATCAATTGCTCGCTGGTGGTTCTGCGTTGCCGACGCACGCTGGGCTCCGCCGAGGTGTCCAATAAACTCAAATTGGCTAAAATGCTGAGATGCTGA
Protein Sequence: MGDGLMDDKRGVAVHVYDELINLFAILEEIAAILISFDKHSEWQSKEVRTRPKSGSLLLYSRKKVRYRRDGYCWKKRKDGKTTREDHMKLKVQGTECIYGCYVHSAILPTFHRRCYWLLQNPDIVLVHYLNVPYPDDNKMAVIAPSITLWGDKKEWTKEELVSQLKPMLSTVNSDDDSDSGNDIEISTAETVESIVCQLMEKQRLSRQAALVKQLDCGCADSTCLDGKSCSHPVMRRTGLLKSVTEKRAHLSDSYNHAATTAPNVVVGPKLYSRWPERRSRDANMEPQQHYQPSPHAQQQQLPAEAAVKFQIVQSQHNEHQLHHASSASYHQQQHQQQQHQQQQQPFRQQHNQNVVNNNNNHVVAPHHQLLVSRNNLIIQHHHQQQQQQSPANFHQVTNTAAPSTHVAANNQTNQINLQRFVANHNNSNNNNLQIINNNRLQIAKTTITAAATTATATAAAAGAGGLAGELIGNQNRISASSNNSTHKVNRRSNELTLPPQQQQQQQQQQQQSPSTDANVINNNNNNNHSIGSSHFSYNASHTISALHQEEQYKMQQQQQQQHQQLRQIKTASTEQQQQECAEASAGVQPMCMSPEHQPSTPIHAGNSGNNNNNNNNNNNQHPLLLLGRSNSQNNNNNNNNTSNNMQTSSSCSSSSSPGTLTSSSCHSASPIIDDDGSVNHHTAQSSSPASPASSALSSSSSSSPTSSASAKTALQTENPISSNENQKSSSIDAGNVLKSAATTTEVSPSLDDNASNSGCTIQQQQSNISSINNRIDYRNNDNTAGTNLCHSLSTSQENTSSTNEEAETSHDVLSTSSHTTIDFESMETNIAAVGVGDGAGAGPDDNSIASRELHDALGFFNETLDLSQEDIQRTLIANLPFATDAHGREQHSTSHGDCHEAAGGCVGVDATLLDNSSVTFMPDSICVADANVVISAARARSCQQADAANDVLVNLDAFDMLVEFPELDLDNKQALTHASLEPGAAQTQQLAANASSSDDVFAAIISSDDDIQHLYTFEAGEEKSGALSDRKLLNICDFSPDWSYPEGGVKVLVAGPWTNSSASYTVLFDSLPVPTMHVQAGVLRCYCPAHEIGFATMQVSCDGYIISHSVMFEYKVLPCPEAPFDALSSDCLYKFTLFNRLSSIDEKMQIKTEMAEQQSLYSQAHFEDKLVGYCNQLMKATWRQNLASTSSWTSGFKGMTLLHLAAALGYSKLVCAMFHWRTENPNFILETEIDALSQDIYGYTPMTWACARGHTETALLLYKWNQNALKIRNHAQQTPLDIANLKGHKTLLQEIYHLECERLRKGRTSSLSSLSVNFNKNNLSDNKIKVEQCTRELLYDENLRNNLFAGQEATYETPRSHDGVFLRPIAVASNQSPPNYSRFSKRSSVDSGINVDIRARPSKPLKDSGPRLQSFDGHDNFSFALETPLDAFGTTNATNSLLSPLRKMDFALCEVSTGDSSPLAHKEHDDDSSTLNNDDNSSEVVLSCETDGVVGDSDAKVLTLAEHIIAAMPERIKNEADEMMVLGSPMAETLNSETSGLNDNFMDPLLDSLPGAHFENDFSLDFNDHSYRYHDVSTPCSSLSPASSGPLQSPASYSLLGTDPSVNSPSPPPSTKQLTEFLHASNNSQCPFETDFSRLTLTDSEQRELYEAAKCIQKAYRSYKGRQKLEEQNKERSAAIVIQNYYRRYKQYAYYRQMTSAALVIQHGYRSYCRNKRFKKSQHSATNSRSSSSSLSSRNNSSSTSQCLSTYYDHYRNDQQQQQQDLLNSQPSTPKETSPSGPLKRTYSQSTQNQAARKIQQFMRQSRIKLQKERAEKEKLVHQRRAEYLQSLQFQGQPETACKPELSEKRCGMRWLAVRRSGGVVRFNQPMISSSNSVEVDILDEALKNVSEINCSLVVLRCRRTLGSAEVSNKLKLAKMLRC

Similar Transcription Factors

Sequence clustering based on sequence similarity using MMseqs2

100% Identity: -
90% Identity: -
80% Identity: -