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ECOLI:MCP2
Contents
| Species (Taxon ID) | Escherichia coli (strain K12). (83333) | |
| Gene Name(s) | tar (synonyms: cheM) | |
| Protein Name(s) | Methyl-accepting chemotaxis protein II
MCP-II Aspartate chemoreceptor protein | |
| External Links | ||
| UniProt | P07017 | |
| EMBL | J01705 U00096 AP009048 | |
| PIR | F64951 | |
| RefSeq | NP_416400.1 YP_490148.1 | |
| PDB | 2ASR 2L9G | |
| PDBsum | 2ASR 2L9G | |
| DisProt | DP00294 | |
| ProteinModelPortal | P07017 | |
| SMR | P07017 | |
| DIP | DIP-10956N | |
| IntAct | P07017 | |
| STRING | 511145.b1886 | |
| MoonProt | P07017 | |
| PaxDb | P07017 | |
| PRIDE | P07017 | |
| EnsemblBacteria | AAC74956 BAA15702 | |
| GeneID | 12931387 946399 | |
| KEGG | ecj:Y75_p1862 eco:b1886 | |
| PATRIC | 32119099 | |
| EchoBASE | EB0981 | |
| EcoGene | EG10988 | |
| eggNOG | COG0840 | |
| HOGENOM | HOG000148074 | |
| InParanoid | P07017 | |
| KO | K05875 | |
| OMA | GDDANWE | |
| OrthoDB | EOG6G4VQG | |
| PhylomeDB | P07017 | |
| BioCyc | EcoCyc:TAR-MONOMER ECOL316407:JW1875-MONOMER | |
| EvolutionaryTrace | P07017 | |
| PRO | PR:P07017 | |
| Proteomes | UP000000318 UP000000625 | |
| Genevestigator | P07017 | |
| GO | GO:0005887 GO:0043424 GO:0004871 GO:0004888 GO:0006935 | |
| Gene3D | 1.20.120.30 | |
| InterPro | IPR004090 IPR003122 IPR004091 IPR003660 IPR004089 | |
| Pfam | PF00672 PF00015 PF02203 | |
| PRINTS | PR00260 | |
| SMART | SM00304 SM00283 SM00319 | |
| SUPFAM | SSF47170 | |
| PROSITE | PS00538 PS50111 PS50885 | |
Annotations
| Qualifier | GO ID | GO term name | Reference | ECO ID | ECO term name | with/from | Aspect | Extension | Notes | Status |
|---|---|---|---|---|---|---|---|---|---|---|
| GO:0051286 |
cell tip |
ECO:0000314 |
C |
Figure 2H. demonstrates that the largest clusters of the TAR chemotaxis proteins are predominately localized at the cell poles. |
complete | |||||
|
involved_in |
GO:0071230 |
cellular response to amino acid stimulus |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0007172 |
signal complex assembly |
ECO:0000314 |
direct assay evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0051260 |
protein homooligomerization |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
enables |
GO:0042803 |
protein homodimerization activity |
ECO:0000314 |
direct assay evidence used in manual assertion |
F |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000314 |
direct assay evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0098561 |
methyl accepting chemotaxis protein complex |
ECO:0000314 |
direct assay evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0050920 |
regulation of chemotaxis |
ECO:0000314 |
direct assay evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0009593 |
detection of chemical stimulus |
ECO:0000314 |
direct assay evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0098561 |
methyl accepting chemotaxis protein complex |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
enables |
GO:0042803 |
protein homodimerization activity |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
F |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:1901875 |
positive regulation of post-translational protein modification |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0006935 |
chemotaxis |
ECO:0000318 |
biological aspect of ancestor evidence used in manual assertion |
EcoGene:EG10987 |
P |
Seeded From UniProt |
complete | ||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000318 |
biological aspect of ancestor evidence used in manual assertion |
EcoGene:EG10988 |
C |
Seeded From UniProt |
complete | ||
|
enables |
GO:0004888 |
transmembrane signaling receptor activity |
ECO:0000318 |
biological aspect of ancestor evidence used in manual assertion |
EcoGene:EG10987 |
F |
Seeded From UniProt |
complete | ||
|
enables |
GO:0043424 |
protein histidine kinase binding |
ECO:0000314 |
direct assay evidence used in manual assertion |
F |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0006935 |
chemotaxis |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
P |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000314 |
direct assay evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000314 |
direct assay evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000245 |
automatically integrated combinatorial evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005887 |
integral component of plasma membrane |
ECO:0000245 |
automatically integrated combinatorial evidence used in manual assertion |
C |
Seeded From UniProt |
complete | |||
|
enables |
GO:0004888 |
transmembrane signaling receptor activity |
ECO:0000315 |
mutant phenotype evidence used in manual assertion |
F |
Seeded From UniProt |
complete | |||
|
enables |
GO:0004888 |
transmembrane signaling receptor activity |
ECO:0000256 |
match to sequence model evidence used in automatic assertion |
F |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0006935 |
chemotaxis |
ECO:0000256 |
match to sequence model evidence used in automatic assertion |
P |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0007165 |
signal transduction |
ECO:0000256 |
match to sequence model evidence used in automatic assertion |
InterPro:IPR003122 |
P |
Seeded From UniProt |
complete | ||
|
part_of |
GO:0016020 |
membrane |
ECO:0000256 |
match to sequence model evidence used in automatic assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0016021 |
integral component of membrane |
ECO:0000256 |
match to sequence model evidence used in automatic assertion |
C |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0016021 |
integral component of membrane |
ECO:0000322 |
imported manually asserted information used in automatic assertion |
C |
Seeded From UniProt |
complete | |||
|
involved_in |
GO:0006935 |
chemotaxis |
ECO:0000322 |
imported manually asserted information used in automatic assertion |
P |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0005886 |
plasma membrane |
ECO:0000322 |
imported manually asserted information used in automatic assertion |
UniProtKB-KW:KW-1003 |
C |
Seeded From UniProt |
complete | ||
|
involved_in |
GO:0007165 |
signal transduction |
ECO:0000322 |
imported manually asserted information used in automatic assertion |
P |
Seeded From UniProt |
complete | |||
|
part_of |
GO:0016020 |
membrane |
ECO:0000322 |
imported manually asserted information used in automatic assertion |
C |
Seeded From UniProt |
complete | |||
Notes
References
See Help:References for how to manage references in GONUTS.
- ↑ Greenfield, D et al. (2009) Self-organization of the Escherichia coli chemotaxis network imaged with super-resolution light microscopy. PLoS Biol. 7 e1000137 PubMed GONUTS page
- ↑ 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 Mowery, P et al. (2008) Different signaling roles of two conserved residues in the cytoplasmic hairpin tip of Tsr, the Escherichia coli serine chemoreceptor. J. Bacteriol. 190 8065-74 PubMed GONUTS page
- ↑ 3.0 3.1 3.2 3.3 Li, M & Hazelbauer, GL (2005) Adaptational assistance in clusters of bacterial chemoreceptors. Mol. Microbiol. 56 1617-26 PubMed GONUTS page
- ↑ 4.0 4.1 4.2 Gaudet, P et al. (2011) Phylogenetic-based propagation of functional annotations within the Gene Ontology consortium. Brief. Bioinformatics 12 449-62 PubMed GONUTS page
- ↑ Gegner, JA et al. (1992) Assembly of an MCP receptor, CheW, and kinase CheA complex in the bacterial chemotaxis signal transduction pathway. Cell 70 975-82 PubMed GONUTS page
- ↑ Silverman, M & Simon, M (1977) Chemotaxis in Escherichia coli: methylation of che gene products. Proc. Natl. Acad. Sci. U.S.A. 74 3317-21 PubMed GONUTS page
- ↑ Ridgway, HG et al. (1977) Localization of proteins controlling motility and chemotaxis in Escherichia coli. J. Bacteriol. 132 657-65 PubMed GONUTS page
- ↑ 8.0 8.1 Lynch, BA & Koshland, DE Jr (1991) Disulfide cross-linking studies of the transmembrane regions of the aspartate sensory receptor of Escherichia coli. Proc. Natl. Acad. Sci. U.S.A. 88 10402-6 PubMed GONUTS page
- ↑ Krikos, A et al. (1983) Sensory transducers of E. coli are composed of discrete structural and functional domains. Cell 33 615-22 PubMed GONUTS page
- ↑ Springer, MS et al. (1977) Sensory transduction in Escherichia coli: two complementary pathways of information processing that involve methylated proteins. Proc. Natl. Acad. Sci. U.S.A. 74 3312-6 PubMed GONUTS page
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