Gene
fcer1g
- ID
- ZDB-GENE-061130-3
- Name
- Fc epsilon receptor IgFc epsilon receptor Ig
- Symbol
- fcer1g Nomenclature History
- Previous Names
-
- FcRgamma
- Type
- protein_coding_gene
- Location
- Chr: 7 Mapping Details/Browsers
- Description
- Predicted to enable IgE receptor activity. Predicted to act upstream of or within cell surface receptor signaling pathway. Predicted to be located in plasma membrane. Predicted to be part of Fc-epsilon receptor I complex. Is expressed in head; immune system; liver; myeloid cell; and pleuroperitoneal region. Orthologous to human FCER1G (Fc epsilon receptor Ig).
- Genome Resources
- Note
- None
- Comparative Information
-
- All Expression Data
- 3 figures from 2 publications
- Cross-Species Comparison
- High Throughput Data
- Thisse Expression Data
- No data available
Wild Type Expression Summary
- All Phenotype Data
- No data available
- Cross-Species Comparison
- Alliance
Phenotype Summary
Mutations
No data available
Human Disease
Domain, Family, and Site Summary
Domain Details Per Protein
| Protein | Additional Resources | Length | High affinity immunoglobulin epsilon receptor subunit gamma | T-cell surface glycoprotein CD3 zeta subunit/High affinity IgE receptor gamma subunit |
|---|---|---|---|---|
| UniProtKB:A0A0R4IN58 | InterPro | 95 |
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| Type | Name | Annotation Method | Has Havana Data | Length (nt) | Analysis |
|---|---|---|---|---|---|
| mRNA |
fcer1g-201
(1)
|
Ensembl | 491 nt |
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Interactions and Pathways
No data available
Plasmids
No data available
No data available
| Relationship | Marker Type | Marker | Accession Numbers | Citations |
|---|---|---|---|---|
| Contained in | BAC | CH73-41H24 | ZFIN Curated Data |
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| Type | Accession # | Sequence | Length (nt/aa) | Analysis |
|---|---|---|---|---|
| RNA | RefSeq:NM_001100106 (1) | 481 nt | ||
| Genomic | GenBank:BX324220 (1) | 150315 nt | ||
| Polypeptide | UniProtKB:A0A0R4IN58 (1) | 95 aa |
- Sobah, M.L., Liongue, C., Ward, A.C. (2024) Stat3 regulates developmental hematopoiesis and impacts myeloid cell function via canonical and non-canonical modalities. Journal of Innate Immunity. 16(1):262-282
- Mu, X., Qi, S., Wang, H., Yuan, L., Wang, C., Li, Y., Qiu, J. (2022) Bisphenol analogues induced metabolic effects through eliciting intestinal cell heterogeneous response. Environment International. 165:107287
- Walton, E.M., Cronan, M.R., Cambier, C.J., Rossi, A., Marass, M., Foglia, M.D., Brewer, W.J., Poss, K.D., Stainier, D.Y.R., Bertozzi, C.R., Tobin, D.M. (2018) Cyclopropane Modification of Trehalose Dimycolate Drives Granuloma Angiogenesis and Mycobacterial Growth through Vegf Signaling. Cell Host & Microbe. 24:514-525.e6
- Carmona, S.J., Teichmann, S.A., Ferreira, L., Macaulay, I.C., Stubbington, M.J., Cvejic, A., Gfeller, D. (2017) Single-cell transcriptome analysis of fish immune cells provides insight into the evolution of vertebrate immune cell types. Genome research. 27(3):451-461
- Da'as, S., Teh, E.M., Dobson, J.T., Nasrallah, G.K., McBride, E.R., Wang, H., Neuberg, D.S., Marshall, J.S., Lin, T.J., and Berman, J.N. (2011) Zebrafish mast cells possess an FcepsilonRI-like receptor and participate in innate and adaptive immune responses. Developmental and comparative immunology. 35(1):125-134
- Yoder, J.A., Orcutt, T.M., Traver, D., and Litman, G.W. (2007) Structural characteristics of zebrafish orthologs of adaptor molecules that associate with transmembrane immune receptors. Gene. 401(1-2):154-164
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