Basic Information

Insect: Lucilia sericata
Gene Symbol: ewg
Assembly: GCA_015586225.1
Location: NW:301707-337053[+]

Transcription Factor Domain

TF Family: Nrf1
Domain: Nrf1_DNA-bind domain
PFAM: PF10491
TF Group: Basic Domians group
Description: In Drosophila, the erect wing (ewg) protein is required for proper development of the central nervous system and the indirect flight muscles. The fly ewg gene encodes a novel DNA-binding domain that is also found in four genes previously identified in sea urchin, chicken, zebrafish, and human [1]. Nuclear respiratory factor-1 is a transcriptional activator that has been implicated in the nuclear control of respiratory chain expression in vertebrates. The first 26 amino acids of nuclear respiratory factor-1 are required for the binding of dynein light chain. The interaction with dynein light chain is observed for both ewg and Nrf-1, transcription factors that are structurally and functionally similar between humans and Drosophila [2]. The highest level of expression of both ewg and Nrf-1 was found in the central nervous system, somites, first branchial arch, optic vesicle, and otic vesicle. In the mouse Nrf-1 protein, Swiss-Prot:Q8C4C0 there is also an NLS domain at 88-116, and a DNA binding and dimerisation domain at 127-282. Ewg is a site-specific transcriptional activator, and evolutionarily conserved regions of ewg contribute both positively and negatively to transcriptional activity [3].
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 3.5e-109 5e-105 349.6 0.1 1 212 78 288 78 289 0.98

2 2 1 1.4e+04 -20.7 29.6 86 94 452 460 386 516 0.54

#	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	3.5e-109	5e-105	349.6	0.1	1	212	78	288	78	289	0.98
2	2	1	1.4e+04	-20.7	29.6	86	94	452	460	386	516	0.54

Sequence Information

Coding Sequence: ATGAATGTGACTACTATATCGACGGGTACGCATGCTACCCAGGCGGCAGTCGAGAGTATAACCAATGTCAAACACCAACAACAGACCTATAAAATAGAAATGCTCGAGGACAGTTTGGCAtccgatgatgatgacgatgatttgATTAGCAGCGATGGCAGCATGTTTGATGAAACTGAACTAACACATATTGCAGTGCAAGATGATTTAGCCAATCAATTGGCAGCTGCCGGACCAGTGGGTGTAGCTGCTGCAGCGGCTATAGCCTCGTCTAAGAAACGTAAAAGACAACATTCGTTTGAAACGAATCCTTCGGTACGTAAAAGGCAACAGAATAGATTACTGCGCAAATTGCGTGGCATAATCTATGAGTTTACTGGTCGCGTGGGCAAACAGGCTGTGGTGTTGGTAGCTACACCGGGTAAACCCAATACCAGCTATAAAGTTTTTGGTGCCAAACCACTAGAGGATGTAGTGCGTaatcttaaaaatattgttatggATGAGCTGGAAAATGCTTTAGCCCAACAAGCACCACCCCCACCACAAGAGGATCCCTCATTATTTGAACTGCCACCTCTAATCATCGATGGTATACCAACACCTGTGGAAAAAATGACACAGGCTCAGCTAAGAGCTTTCATACCATTGATGTTAAAGTACTCCACTGGTAGAGGTAAACCAGGTTGGGGACGTGAAGCCACCAGACCACCATGGTGGCCTAAAGAATTGCCCTGGGCTAATGTACGCATGGATGCCAGATCTGAAGATGATAAACAAAAgatttcCTGGACTCATGCTTTGCGAAAAATTGTCATCAATTGTTATAAATATCACGGCCGCGAAGATCTCTTGCCCACATTTGCCGATGAAGAGGAAAAAGTCAGCCAAATGATCTCACACGAAGAGGAAGAGGAGGAAGAAGAGGTGATTGTACAGCCTGTTAGTAATCAAGCCACTACTATACAAACTATACACACAACCAATGCGCCCACAAATACTACAACTAATGTAAGGCAACAAGTAAATGTGGTTAAAATAAATAGTTCAGGAACTGTAATAACCACAACAAATCCACATAATCCAAATAATCCTGGACCCACCATTATACAAAGTACGAATGATCAACATATAACAACAACGGCACGTTTGCCAGCATCGACAAAGATTGAATTGTGTCCTGCGCCAATGGCACAGATAACACAACAACAgcatcatcaacagcaacagcagcagcaacaacatcagcagcaacaacaacagcagcagcaacaacaacagcagcaacaacaacagcagcagcaactgcaacaacagcatcaacaacagcaacaacaacagcagcaacaacagcagcagcaacaacagcagcagcaacaacaacagcatcatcaacaacaacatcagcagcagcaacatcatcaAATACAAACCACAAATGTGACTTCTCAACAGTTGGCCAATGCCCAAGTTTGCATAGAACCCATGACCTTGGGAGATGTTGATTATACCACCCAAACGGTGTTATCCACCATACAAAATGCTGACGGCACTGTTTCGCTTATACAAGTTGATCCTAATAATCCTATTATTACATTACCGGATGGTACCACAGCCCAAGTCCAGGGTGTTGCAACGCTGCATCAGGGCGAAGGTGGTGCCACTATTCAAACTGTTCAAAGTCTGGGTGATGTTAATGGTCATGAAAATATGACTGTTGATTTGACCGAAGCTACAGTGGCTCAAGATGGTCAGATTTATATAACGGCCGAGGATGGTCAAGGTTATCCAGTGTCCGTTAGTAATATGATTACATTACCGGTATCAGCATCCATGTATCAATCAATGATGGCCAATATccaacaaatacatacaaatagcGATGGCACAGTGTGTATAACACCAATGCAGGTTGAAAATGGTGATCAATTAGAAGCCATCACTGTTTCACCCGGCATGCATCAAATGATGATACAAGGTGCTCCAGGACAAGAGCCTCAAGTATTGCAGGTGGTAAGTCTTAAAGATGCCACATTACTCTCCAAAGCCATGGAAGCCATAACAAGTGGTAATTGCAAGGCTGACGATACTATTATAATggaacaataa
Protein Sequence: MNVTTISTGTHATQAAVESITNVKHQQQTYKIEMLEDSLASDDDDDDLISSDGSMFDETELTHIAVQDDLANQLAAAGPVGVAAAAAIASSKKRKRQHSFETNPSVRKRQQNRLLRKLRGIIYEFTGRVGKQAVVLVATPGKPNTSYKVFGAKPLEDVVRNLKNIVMDELENALAQQAPPPPQEDPSLFELPPLIIDGIPTPVEKMTQAQLRAFIPLMLKYSTGRGKPGWGREATRPPWWPKELPWANVRMDARSEDDKQKISWTHALRKIVINCYKYHGREDLLPTFADEEEKVSQMISHEEEEEEEEVIVQPVSNQATTIQTIHTTNAPTNTTTNVRQQVNVVKINSSGTVITTTNPHNPNNPGPTIIQSTNDQHITTTARLPASTKIELCPAPMAQITQQQHHQQQQQQQQHQQQQQQQQQQQQQQQQQQQQLQQQHQQQQQQQQQQQQQQQQQQQQQQHHQQQHQQQQHHQIQTTNVTSQQLANAQVCIEPMTLGDVDYTTQTVLSTIQNADGTVSLIQVDPNNPIITLPDGTTAQVQGVATLHQGEGGATIQTVQSLGDVNGHENMTVDLTEATVAQDGQIYITAEDGQGYPVSVSNMITLPVSASMYQSMMANIQQIHTNSDGTVCITPMQVENGDQLEAITVSPGMHQMMIQGAPGQEPQVLQVVSLKDATLLSKAMEAITSGNCKADDTIIMEQ

Similar Transcription Factors

Sequence clustering based on sequence similarity using MMseqs2

100% Identity: iTF_01399206; iTF_00655074; iTF_00258604; iTF_01427215; iTF_00370708; iTF_01137716; iTF_01236397; iTF_00997455; iTF_01237394; iTF_01398171; iTF_00759831; iTF_01165274; iTF_00892453;
90% Identity: iTF_00655074; iTF_00258604; iTF_01399206; iTF_00997455; iTF_01427215; iTF_01237394; iTF_01236397; iTF_01137716; iTF_00759831; iTF_01398171;
80% Identity: -