Basic Information

Insect: Villa cingulata
Gene Symbol: egg
Assembly: GCA_951394055.1
Location: OX596022.1:29988728-30001338[-]

Transcription Factor Domain

TF Family: MBD
Domain: MBD domain
PFAM: PF01429
TF Group: Unclassified Structure
Description: The Methyl-CpG binding domain (MBD) binds to DNA that contains one or more symmetrically methylated CpGs [2]. DNA methylation in animals is associated with alterations in chromatin structure and silencing of gene expression. MBD has negligible non-specific affinity for DNA. In vitro foot-printing with MeCP2 showed the MBD can protect a 12 nucleotide region surrounding a methyl CpG pair [2]. MBDs are found in several Methyl-CpG binding proteins and also DNA demethylase [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 2.9 3.1e+04 -4.1 0.0 46 57 694 705 694 709 0.85

2 2 6.7e-13 7.1e-09 36.4 0.0 6 73 1384 1444 1380 1447 0.89

#	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	2.9	3.1e+04	-4.1	0.0	46	57	694	705	694	709	0.85
2	2	6.7e-13	7.1e-09	36.4	0.0	6	73	1384	1444	1380	1447	0.89

Sequence Information

Coding Sequence: atggatACGTTCAATTCAATTATATCAGTATCAGGAACTAAAGattcaaatgaaataattaaaccTCCAAgtccaaaaaaacaaaaacttagtAAAGAAGTTAATGATAGTAATGGACAAAGTACAACATTTACATTAGAAACAAAATATGATGATGGTAAAACAAGTGAAAATAAAGACAGCCAAACATCAAtagaaattattgaattatttgATGAAAACATGCAGAAAGAAGCTGAATTGGATGAAAACATACAGAAGAAAGCTGAATTGGATGAAAACATACAGAAGAAAGCTGAATTGGATGAAAACAATGTATTAGATGAAGAGTCTATGgcaaatgataaaaataataagaaagacACATCTAAGAATTGTGAATTGACGACTGAAAATCATAATAAGGATCCTGATTCAGAAGAATCTAAGAAAATTgatattgtgaaaaatgatgaatttaataaaaataatgaaagtaaTATCGATCAAAATATAATCGAAATcgatagtgatgatgatgaatataaCAATGAAATGTCTAATGTTAATGAAGATTTAGAAATGAAAACTGATGAGTTTGATACATCTGATGTAgaaataattgatttttcaaatgaaaaagaTAATTCGGAAAAAGAGGAAGATCATAAAAAATCTTTGTCTACTAAGAATAAtttagaaacaaataaaaaaaattctgaatcaACTAATGAAGTAATCATTGTAATAGAAGGAAATGATCCAGAAACTGAAGAATCTGATAaaagtaatgaaaaaaatgatgaGTTACAAaagtcaaaagaaaaaattgaaaaaattggaaataatgaacatgatgataatgaattacaaaacaatatttcgaaagaagaaaatgatgataaaaaatcTTCATCTGTCgatgaaattaatttagaatcaaataaaaattctaagtcTACTGATGAAGAAATCATtgtaatagaagaaaatgatCCAGAAACTGAAGAAgctaatgaaaataatgaaaaaaatgataaatcgCAAAAAcatattacagaaaaaaaaattgaaaaaattggaaataatgaacatgatgataatgaattacaaaacaatatttcgaaagaagaaaatgatgataaaaaatcTTCATCTGTCgatgaaattaatttagaaacaaataaaaaaaattctgagaCTACTGATGAAGAAATCATtgtaatagaagaaaatgatCCAGAAACTGAAGAAgctaatgaaaataatgaaaaaaatgataaatcgCAAAAAcatattacagaaaaaaaaattgaaaaaattggaaataatgaacatgatgataatgaattacaaaacaatatttcgaaagaagaaaatgatgataaaaaatcTTCATCTGTCgatgaaattaatttagaatcaaataaaaattctaagtcTACTGATGAAGAAATCATtgtaatagaagaaaatgatCCAGAAACTGAAGAAgctaatgaaaataatgaaaaaaatgataaatcgCAAAAAcatattacagaaaaaaaaattgaaaaaattggaaataatgaacatgatgataatgaattacaaaacaatatttcgaaagaagaaaatgatgataaaaaatcTTCATCTGTtgatgaaattaatttagaaacaaataaaaaaaattctgagaCTACTGATCAAGAAGTAATtgtaatagaagaaaatgatCTAGATCCAGAGACGGAAACAAATGAGGAGAACGAAAAAAGTGATGATAAATCACAAAACAATAATTGTACAATTGCTGAAGATTGTGAAATAAAAGATAAAGAATCATCAtctgaaaaacaaataaatgaatcaaatattgattatgaaacaaataaaataattactgaGAAATCTTTATCTgatgataaaaatgaacaaaaaatggatgaaaaagaaacaattaatgatgatgaaaatgaaaaaaatgatcaTCAAGATAGtacaaacaatgaaaaaaacaatatcaaaattgataaaatagaGTCTAGTGGTAGTGATTTGAAAATAATAGATAGTTTCACATTGAATACTGATGATAATGATCAAGATATCGAATTTAATgaagatgaaaattatttaaatgcaaacaatttgaataatgatgatgaagaaaataatgataatgaaaatactTTAGAATTAGATGATGATATAGTAATGGCAGATGAAgataataattgtgaaaaaacTACTtacaatgaaataaaagaaaatgaaaaagacaATGATCAAAATAATAGTAATTCAGTAGACGATGCATTTGAAGATGAAAGTAATAAATGTgaagatgataaaaaaaatacatcagATAATAATTTAGAACCACAATTAATGGCGATGAGTGAAAGGCAAGTAGAAGAGAACGATACCGGCTATCAAATGGAAATGTATGATTATGATGAAGAAGACATTGAAGTCATTGaaatatttgatgatgatgaagaagaggaagataatgatgataatgaagtAACTATTACAGAAACAGatttatcaaattcaaaatctaTGGACGATATAAAAAAAGATGAAAGTGAAAATCAAGAAATAAATGAACATGAAGAAACGTATGCAGGATTAGAATTGTTTTACAATAAAGATTGTATTAATGCTGAATgcaataaaaaatcaaaaatttttgtaaaagcaTCAACATTTTCCatgaaattatttagaaaacCACTTAAAacaaaagtgaaaagaaaaattcattattgTTGTAAAGATTGCAATGATTTATCCCTTAAAAAACATAAGaATCTTTGTTGTAATTTACTAAGTTCTCAATGTATTCTGAATGAAGAACTACCAAGAAGGCATGAAATTGTTGAAATTTCAGATAGTAGCGATGAAGAAGATTCTGAAGATTATAATAATGATGATTTAAATCATGATACGAATAgtttaaatgaatttcaatctcatgcaaatgaaatatatcatggcttatattcaaattataaaccTCGAATAAAAGAGCTACCGCCATTAGATTTGAATATTACAGATGTAGATGATTTATCATGGCTACCTCCTGAAGGTGAAATATCTTTTCCACCGATTGAATtgcataaatattattatgcaGCAGAAAAACATTTAATTGATAAATGGTTAATCTGTAAGATAACTGAAATATCTAATCTAAAAAGTATGACATATTATaaagttgaatttgaaaatgtacaAACATTAGAGCCACGAATCGTTTCACCGAAACAACTTGCATACTTTGATCCACCATCAGTTCGTTTACCAGTCGGTTCACGTGTTATAGCACtttttgattcaaaaaaaataaataataaaatgaaaaatccctcgaaaaatgaatattatcctGGAATTGTTGCTGAAACGATGACAGCTAATAATCGATATAGaTATCTGGTATTTTTTGATGATGGTTACCCGCAATATgtttcacataaaaatattagatTAGTTTGTCattcatcaaaagaagtttggcATGATGTGCATTCAAATTGCAGAGAATTTTTCCGTACATATTTGACTGAATCTGAAAAGGATCGTCCAATTTTAGAAGTTAAAAAAGGACAAGCTCTTATGATTGAAATAAAtaATATGTGGTTTTGGGCAAAAGCTCTAGAAGTTGATTGCAGTATAGTTCTTATGCAAACAGCAAGTAAAAGCCGTTTAGAATGGTTTTATAGAGGATCAACAAGATTACATCCAGTGTATCAAGAGagatttcaagaaaaaaaaccAATTCGAATGTCACAACTAGCAAGAagAACAGAAAAACCATATATAAGATATATGCAAGAAAGTGGTACATCAATGtcgaattcaaataaaaattcaggatTTTTGGTACCATCAACACCAGTTAATAATAATCGATCTGTTGCTAAAAAGAGTGTATCAAAAGATTCTGTGAGTGTGGGAcaatcacaacaacaacaatggcAGCAATATCATCAATCACCATCGCAACCAgtcaaacatttaaataattccACAATATTTGTAGACGATGATAATAAAccaaaaggaaaaattatatattatgcagcTAAAAATGTATCATCGAAACAATTTATCAAACATGTTTGTGCACCATCatgtttaaattcaaaattcaatttaaaatcataCAGTCCATTAATAAAACCGCTTTTATCTGGTTGGGAAAGATTAATATAtaaagcaaaattaaaaaaatgggTGGTATATAGAGGACCATGTGGCCGTCTATTAAGAAACATGAAAGAAGTACATCAATATTTAAGAATAactgaaaacattttaaatgttgataattttgattttgatccaACAATAAATGTTATGGCTCAGTATTCTGTTGAAGAATGTTTTGTAGAAAAAATGGTTGAGgatatatctGAAGGAATTGAAAATATGCCTGTACCATGCattaattattatgataatacaGTACCACCGAATTGTACATATTCAACAGAACGAATTCCAACTGAAggtgtatttttaaatttagatccAGAATTTTTAGTTGGATGCGATTGTACTGATGATTGTTCGGATAAAACAAAATGTAGCTGCTGGCAATTAACTTTAGATGGAGCAAAATTCAATAATACAAATGTACCATCAGACAAAATCGGTTATTCGTATATGAGACTACCAGAACCGGTACCAACTGGAATATATGAATGCAATCAtagatGTAAATGCtctaaaaaatgtttaaatcgTGTCGTACAACATCCATTACAAATGAAACTTCAAGTTTTCAAAACATCGAATAGAGGATGGGGATTACGTTGCATTAATGATATACCAAAGGGAAGTTTCATATGCATTTACGCCGGGCATTTATTAACTGAACAAAATGCAAATGAGggtGGAGCAAATTTCGGTGATGAATATTTCGCTGAATTAGATTATATTGAAGTTGTTGAAAGATTGAAAGAAGGTTATGAATCAGATGTACAAGAAGATATCGATAGTGACGATGAAGTAGAAgAAAAAAATCAATGCAATGATTCCGATGAAGAATTTCGATCGCATAGCAAAATACAAGCAAAAACTCCATCAGTTCATACACGAATGCAAGCAAGAattgaaaaagagaaaaaaacaaatgatgACAATgacaacgatgatgatgatgatgaaggtAGAAGAAAAGTATTAAATTATGATGCAAACAAAAATACAACATTAGATAAAAATGGCGAgaatacaacaacaaaatacaaaTCTGTTCGAAAATTTTTCGGTAAAAACGAATATTGTTACGTTATGGATGCAAAATTAACTGGAAATATTGGTCGTTATTTCAATcATTCATGCTCACCAAATTTATTCGTTCAAAATGTATTTGTTGATACGCATGATTTACGTTTTCCATGGGTTGCATTCTTTGCATTACACAATATTAGAGCTGGAACAGAATTAACATGGAATTATAATTATGAAGTTGGTGTTGTTCCCGGTAAAGTATTATATTGTGAATGTGGTTCAGAAAATTGTAGAGGAAGGCTAttgtaa
Protein Sequence: MDTFNSIISVSGTKDSNEIIKPPSPKKQKLSKEVNDSNGQSTTFTLETKYDDGKTSENKDSQTSIEIIELFDENMQKEAELDENIQKKAELDENIQKKAELDENNVLDEESMANDKNNKKDTSKNCELTTENHNKDPDSEESKKIDIVKNDEFNKNNESNIDQNIIEIDSDDDEYNNEMSNVNEDLEMKTDEFDTSDVEIIDFSNEKDNSEKEEDHKKSLSTKNNLETNKKNSESTNEVIIVIEGNDPETEESDKSNEKNDELQKSKEKIEKIGNNEHDDNELQNNISKEENDDKKSSSVDEINLESNKNSKSTDEEIIVIEENDPETEEANENNEKNDKSQKHITEKKIEKIGNNEHDDNELQNNISKEENDDKKSSSVDEINLETNKKNSETTDEEIIVIEENDPETEEANENNEKNDKSQKHITEKKIEKIGNNEHDDNELQNNISKEENDDKKSSSVDEINLESNKNSKSTDEEIIVIEENDPETEEANENNEKNDKSQKHITEKKIEKIGNNEHDDNELQNNISKEENDDKKSSSVDEINLETNKKNSETTDQEVIVIEENDLDPETETNEENEKSDDKSQNNNCTIAEDCEIKDKESSSEKQINESNIDYETNKIITEKSLSDDKNEQKMDEKETINDDENEKNDHQDSTNNEKNNIKIDKIESSGSDLKIIDSFTLNTDDNDQDIEFNEDENYLNANNLNNDDEENNDNENTLELDDDIVMADEDNNCEKTTYNEIKENEKDNDQNNSNSVDDAFEDESNKCEDDKKNTSDNNLEPQLMAMSERQVEENDTGYQMEMYDYDEEDIEVIEIFDDDEEEEDNDDNEVTITETDLSNSKSMDDIKKDESENQEINEHEETYAGLELFYNKDCINAECNKKSKIFVKASTFSMKLFRKPLKTKVKRKIHYCCKDCNDLSLKKHKNLCCNLLSSQCILNEELPRRHEIVEISDSSDEEDSEDYNNDDLNHDTNSLNEFQSHANEIYHGLYSNYKPRIKELPPLDLNITDVDDLSWLPPEGEISFPPIELHKYYYAAEKHLIDKWLICKITEISNLKSMTYYKVEFENVQTLEPRIVSPKQLAYFDPPSVRLPVGSRVIALFDSKKINNKMKNPSKNEYYPGIVAETMTANNRYRYLVFFDDGYPQYVSHKNIRLVCHSSKEVWHDVHSNCREFFRTYLTESEKDRPILEVKKGQALMIEINNMWFWAKALEVDCSIVLMQTASKSRLEWFYRGSTRLHPVYQERFQEKKPIRMSQLARRTEKPYIRYMQESGTSMSNSNKNSGFLVPSTPVNNNRSVAKKSVSKDSVSVGQSQQQQWQQYHQSPSQPVKHLNNSTIFVDDDNKPKGKIIYYAAKNVSSKQFIKHVCAPSCLNSKFNLKSYSPLIKPLLSGWERLIYKAKLKKWVVYRGPCGRLLRNMKEVHQYLRITENILNVDNFDFDPTINVMAQYSVEECFVEKMVEDISEGIENMPVPCINYYDNTVPPNCTYSTERIPTEGVFLNLDPEFLVGCDCTDDCSDKTKCSCWQLTLDGAKFNNTNVPSDKIGYSYMRLPEPVPTGIYECNHRCKCSKKCLNRVVQHPLQMKLQVFKTSNRGWGLRCINDIPKGSFICIYAGHLLTEQNANEGGANFGDEYFAELDYIEVVERLKEGYESDVQEDIDSDDEVEEKNQCNDSDEEFRSHSKIQAKTPSVHTRMQARIEKEKKTNDDNDNDDDDDEGRRKVLNYDANKNTTLDKNGENTTTKYKSVRKFFGKNEYCYVMDAKLTGNIGRYFNHSCSPNLFVQNVFVDTHDLRFPWVAFFALHNIRAGTELTWNYNYEVGVVPGKVLYCECGSENCRGRLL

Similar Transcription Factors

Sequence clustering based on sequence similarity using MMseqs2

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