Basic Information

Insect: Tenodera sinensis
Gene Symbol: gcm
Assembly: GCA_030765045.1
Location: CM060962.1:317115450-317145554[+]

Transcription Factor Domain

TF Family: GCM
Domain: GCM domain
PFAM: PF03615
TF Group: Beta-Scaffold Factors
Description: GCM transcription factors are a family of proteins which contain a GCM motif. The GCM motif is a domain that has been identified in proteins belonging to a family of transcriptional regulators involved in fundamental developmental processes which comprise Drosophila melanogaster GCM and its mammalian homologues [PMID: 8962155, PMID: 9114061, PMID: 9580683, PMID: 10671510]. IN GCM transcription factors the N-terminal moiety contains a DNA-binding domain of 150 residues. Sequence conservation is highest in this GCM domain. In contrast, the C-terminal moiety contains one or two transactivating regions and is only poorly conserved.The GCM motif has been shown to be a DNA binding domain that recognises preferentially the nonpalindromic octamer 5'-ATGCGGGT-3' [PMID: 8962155, PMID: 9114061, PMID: 9580683]. The GCM motif contains many conserved basic amino acid residues, seven cysteine residues, and four histidine residues [PMID: 8962155]. The conserved cysteines are involved in shaping the overall conformation of the domain, in the process of DNA binding and in the redox regulation of DNA binding [PMID: 9580683]. The GCM domain as a new class of Zn-containing DNA-binding domain with no similarity to any other DNA-binding domain [PMID: 12682016]. The GCM domain consists of a large and a small domain tethered together by one of the two Zn ions present in the structure. The large and the small domains comprise five- and three-stranded beta-sheets, respectively, with three small helical segments packed against the same side of the two beta-sheets. The GCM domain exercises a novel mode of sequence-specific DNA recognition, where the five-stranded beta-pleated sheet inserts into the major groove of the DNA. Residues protruding from the edge strand of the beta-pleated sheet and the following loop and strand contact the bases and backbone of both DNA strands, providing specificity for its DNA target site.
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 8 0.00042 39 6.5 0.0 1 19 31 49 31 55 0.89

2 8 0.00028 26 7.0 0.0 1 19 90 108 90 114 0.89

3 8 0.00044 41 6.4 0.0 1 19 149 167 149 172 0.89

4 8 0.00028 26 7.0 0.0 1 19 177 195 177 201 0.89

5 8 0.00045 42 6.4 0.0 1 18 236 253 236 259 0.89

6 8 0.00045 42 6.4 0.0 1 18 267 284 267 290 0.89

7 8 0.00042 39 6.5 0.0 1 19 326 344 326 350 0.89

8 8 1.9e-79 1.7e-74 250.6 4.3 1 140 385 524 385 524 0.99

#	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	8	0.00042	39	6.5	0.0	1	19	31	49	31	55	0.89
2	8	0.00028	26	7.0	0.0	1	19	90	108	90	114	0.89
3	8	0.00044	41	6.4	0.0	1	19	149	167	149	172	0.89
4	8	0.00028	26	7.0	0.0	1	19	177	195	177	201	0.89
5	8	0.00045	42	6.4	0.0	1	18	236	253	236	259	0.89
6	8	0.00045	42	6.4	0.0	1	18	267	284	267	290	0.89
7	8	0.00042	39	6.5	0.0	1	19	326	344	326	350	0.89
8	8	1.9e-79	1.7e-74	250.6	4.3	1	140	385	524	385	524	0.99

Sequence Information

Coding Sequence: ATGAGCAACAGTCACTGCCGTCTGGCGACCAGCACCAGTCGACATCACCAGAACACTGACTGGGATATCAACGATACCAGCATCCCACGTTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGTAACAGTTCGACCTGTGGGAAGAGTGGGCAGACGGACACTGTGTAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCAGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGTAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTGTAACAGTTCGACCTGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGTAACAGTTCGACCGGTGGAACAGTTCGACCAGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGTAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTGGAACAGTTCGACCGGTGGGAAGAGTGAGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGTAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCTTGTTTCAGGTGGAACAGTTCGACCGGTGGGAAGAGTGGGCAGACGGACACTGTAGGCTGGTGTACCCTGCTAGCAGCGAGGAGGCCAAGAGACACGCTTCTGGTTGGGCAATGCGCAACACCAACAACCACAACGTGCACATCCTCAAGAAGTCCTGTCTAGGTGTGCTGGTGTGCTCTCTGAGGTGCGCACTCCCTTCTGGAGAGAAGGTTCATCTGAGACCTGCCATTTGCGACAAGGCACGCAAGAAACAGCAAGGTAAACCATGTCCAAACAGACAGTGCACAGGTCGACTGGAGATTTTGGCCTGTCGCGGACATTGTGGCTATCCCGTCACTCATTTTTGGAGACATACTGACCACGCAATATTCTTTCAGGCAAAAGGAGTGCACGACCATCCTCGGCCAGAAGCCAAATCTACGTCTGAAGCCAGAAGAAGTCTTGGTGCTGGACGGCGTGTGAGAGGTTTGGCGGTCCTGCTAGCTAGAGAAGCAGCCCTGGGATCTAAGGTAAGGAAATGTCATCTTGTAGAGTCTGTAGCCAGAAGAAGTCTTGGTGCTGGACGGCGTGTGAGAGGTTTGGCGGTCCTGCTAGCTAGAGAAGCAGCCCTGGGATCTAAGGTAAGGAAATGTCATCTTGTAGAGTCTGTAGCCAGAAGAAGTCTTGGTGCTGGACGGCGTGTGAGAGGTTTGGCGGTCCTGCTAGCTAGAGAAGCAGTCCTGGGATCTAAGGTAAGGAAATGTCATCTTGTAGAGTCTGTAGCCAGAAGAAGTCTTGGTGCTGGACGGCGTGTGAGAGGTTTGGCGGTCCTGCTAGCTAGAGAAGCAGTCCTGGGATCTAAGGTAAGGAAATGTCATCTTGTAGAGTCTGTAGCCAGAAGAAGTCTTGGTGCTGGACGGCGTGTGAGAGGTTTGGCGGTTCTGCTGGCTAGAGAAGCAGCCCTGGGATCTAAGCTGCTGTCGCTACGGGAGGGCAAGCGGACAGCTGGGGAACTAAACGCGGACTCAAACCCGAGGTCGCTATTGTGTCCGCTGGATCCTCCTCCGCCTCTCATATCTGATATGGAGAAAGGCTTCTCGTGTTCCTGTCCACCATTTGAATGCATCTGCAGCAGGAGCGCAGGATCAGGGAACCACAATCAGGGACAATTCCTACACAGTGTGCCAGGGGGCGGAACATGTTCACAATATCGCCATCATGGAGACCCTACTTACTGGCTACAAGAACAGCTCAACGCCTCCTCTGTGTTTCCTTTCCACGAGACTActcaaaacaacaataacaacaacactgGCTACTTGAGTAACAATATCAACCaccaggagcaggagcagcaacagcagcaacagcagcaacagtcCTATGACTTCCTTCCACTGGGCACCGAACTCTTCCAGCCCGAAGAAATCTTCCAACTCGACCAGCCACTCAAGACAGAGCAGCCAGAGGGGTACGTGAACACGATGCTACAGACAGCCTCCTCAGAGATGCCGACCAGATCGCCGCCCATGTTACTTGATCTGGGTAGTGGAACGATACATCGCAGCCCCGTCGTCGTCAAGCCCGAGGCGGAGTACTGGATGTTACCTGGGCCCTCCGGTACCACAGACACGGAGAGCAACAGCAACGGTTCACCCGTGCCCAGATTTCCTCTGTCGTGTTCCCCGGACACGGCGACCACCAACATAGCCGAACAGCTTCAGGTATGTTCTCACAGGCAGGACTCCTCTCTTCTTCAAAACGGTTCACCCGTGCCCAGATTTCCTCTGTCGTGTTCTCCGGACACGGCGACCACCAACATAGCCGAACAGCTTCAGGTATGTTCTCACAGGCAGGACTCCTCTCTTCTTCAAAACGGTTCACCCATGCCCAGATTTCCTCTGTCGTGTTCCCCGGACACGGTGACCACCAACATAGCCGAACAGCTTCAGGTATGTTCTCACAGGCAGGACTCCTCTCTTCTTCAAAACGGTTCACCCGTGCCCAGATTTCCTCTGTCGTGTTCCCCGGACACGGCGACCACCAACATAGCCGAACAGCTTCAGGCGACGATGGACGTTAGCAGGGACGGCGGTATCGAGTTCCTGGACGTTGGGCAGATGAGGCTGCTACCTCCTCCGCCTCCTCCACCCGCTCCAGCGCCACCCCTTCATCTTCACCAAGGGGACAGTGAGTCTAAGCTACATGGTGGAGGAATGCTGCAGCACTACGGAATGGACTGCGAGGACGCCTCTGCCAGACTGAAGGCTCCTCAGGATGATCCTCGGATGATGTACTACCTGCACTCTGGGAGGGAGTCATCGGGCAACATGATGGACAGTTACCAATATGTTGCTGATACCAAGAGTAATGACGAAAGTGGCTGTTTTGGTAGTGAACACTTGTTACCTCCCGTCAAAGTTGATCCTTCAGGAGTCATGGGATTCGTCGGTGTGGGCAGTGAGGATCACTTGGGACACTATGGGGATTATAGTGGGATGTATCCCACGGACAATCAGCATCAGCAAACTCAGGACCCTCTTGGGGATTTCAGACTGCACCTTCAGGTGGAAGGCTTTTCAAATGCCCAGTATCATCACCAACCTCATCAGAATCACACGCATCACCCACCTGCAACACATTTCCCTCACTGA
Protein Sequence: MSNSHCRLATSTSRHHQNTDWDINDTSIPRFDRWEEWADGHCRLVYLVSGVTVRPVGRVGRRTLCNSSTGGKSGQTDTVGWCTLFQVEQFDQWEEWADGHCRLVYLVSGVTVRPVGRVGRRTLCNSSTCGKSGQTDTVGWCTLFQVEQFDRWEEWADGHCRLVYLVSGVTVRPVEQFDQWEEWADGHCRLVYLVSGVTVRPVGRVGRRTLWNSSTGGKSEQTDTVGWCTLFQVEQFDRWEEWADGHCRLVYLVSGGTVRPVGRVEQFDRWEEWADGHCRLVYLVSGGTVRPVGRVGRRTLWNSSTGGKSGQTDTVGWCTLFQVEQFDRWEEWADGHCRLVYLVSGVTVRPVGRVGRRTLWNSSTGGKSGQTDTVGWCTLFQVEQFDRWEEWADGHCRLVYPASSEEAKRHASGWAMRNTNNHNVHILKKSCLGVLVCSLRCALPSGEKVHLRPAICDKARKKQQGKPCPNRQCTGRLEILACRGHCGYPVTHFWRHTDHAIFFQAKGVHDHPRPEAKSTSEARRSLGAGRRVRGLAVLLAREAALGSKVRKCHLVESVARRSLGAGRRVRGLAVLLAREAALGSKVRKCHLVESVARRSLGAGRRVRGLAVLLAREAVLGSKVRKCHLVESVARRSLGAGRRVRGLAVLLAREAVLGSKVRKCHLVESVARRSLGAGRRVRGLAVLLAREAALGSKLLSLREGKRTAGELNADSNPRSLLCPLDPPPPLISDMEKGFSCSCPPFECICSRSAGSGNHNQGQFLHSVPGGGTCSQYRHHGDPTYWLQEQLNASSVFPFHETTQNNNNNNTGYLSNNINHQEQEQQQQQQQQQSYDFLPLGTELFQPEEIFQLDQPLKTEQPEGYVNTMLQTASSEMPTRSPPMLLDLGSGTIHRSPVVVKPEAEYWMLPGPSGTTDTESNSNGSPVPRFPLSCSPDTATTNIAEQLQVCSHRQDSSLLQNGSPVPRFPLSCSPDTATTNIAEQLQVCSHRQDSSLLQNGSPMPRFPLSCSPDTVTTNIAEQLQVCSHRQDSSLLQNGSPVPRFPLSCSPDTATTNIAEQLQATMDVSRDGGIEFLDVGQMRLLPPPPPPPAPAPPLHLHQGDSESKLHGGGMLQHYGMDCEDASARLKAPQDDPRMMYYLHSGRESSGNMMDSYQYVADTKSNDESGCFGSEHLLPPVKVDPSGVMGFVGVGSEDHLGHYGDYSGMYPTDNQHQQTQDPLGDFRLHLQVEGFSNAQYHHQPHQNHTHHPPATHFPH

Similar Transcription Factors

Sequence clustering based on sequence similarity using MMseqs2

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