cDNA cloning of mouse ret proto-oncogene and its sequence similarity to the cadherin superfamily.Iwamoto T., Taniguchi M., Asai N., Ohkusu K., Nakashima I., Takahashi M.View abstractCited forNUCLEOTIDE SEQUENCE [MRNA] (ISOFORM 1)CategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCOncogene 8:1087-1091 (1993)Cited in1Mapped to1
Molecular characterization of mouse neuro-2a c-ret proto-oncogene.Phua C.Y.D., Too H.P.Cited forNUCLEOTIDE SEQUENCE [MRNA] (ISOFORM 1)CategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)Submission Submitted to EMBL/GenBank/DDBJ databases (NOV-1999)Cited in1
No title available.Wang Y.-Z., Yoong L.-F., Too H.-P.Cited forNUCLEOTIDE SEQUENCE [MRNA] (ISOFORM 2)StrainBALB/cJCategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)Submission Submitted to EMBL/GenBank/DDBJ databases (JUN-2003)Cited in1
The transcriptional landscape of the mammalian genome.Carninci P., Kasukawa T., Katayama S., Gough J., Frith M.C., Maeda N., Oyama R., Ravasi T., Lenhard B.[...], Hayashizaki Y.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE MRNA] (ISOFORM 2)StrainC57BL/6JTissueSpinal ganglionCategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCScience 309:1559-1563 (2005)Cited in99+16Mapped to99+
The status, quality, and expansion of the NIH full-length cDNA project: the Mammalian Gene Collection (MGC).The MGC Project TeamView abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE MRNA] (ISOFORM 2)StrainC57BL/6JTissueBrainCategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCGenome Res. 14:2121-2127 (2004)Cited in99+99+
Direct association between the Ret receptor tyrosine kinase and the Src homology 2-containing adapter protein Grb7.Pandey A., Liu X., Dixon J.E., Di Fiore P.P., Dixit V.M.View abstractCited forINTERACTION WITH GRB7 AND PLCG1CategoriesInteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Biol. Chem. 271:10607-10610 (1996)Cited in3Mapped to11
Novel p62dok family members, dok-4 and dok-5, are substrates of the c-Ret receptor tyrosine kinase and mediate neuronal differentiation.Grimm J., Sachs M., Britsch S., Di Cesare S., Schwarz-Romond T., Alitalo K., Birchmeier W.View abstractCited forINTERACTION WITH DOK2; DOK4 AND DOK5, PHOSPHORYLATION, MUTAGENESIS OF TYR-1063CategoriesPTM / Processing, Interaction, Phenotypes & VariantsSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Cell Biol. 154:345-354 (2001)Cited in4Mapped to55
Neural cells in the esophagus respond to glial cell line-derived neurotrophic factor and neurturin, and are RET-dependent.Yan H., Bergner A.J., Enomoto H., Milbrandt J., Newgreen D.F., Young H.M.View abstractCited forFUNCTIONCategoriesFunctionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCDev. Biol. 272:118-133 (2004)Cited in3Mapped to4
Tyrosine kinase receptor RET is a key regulator of Peyer's patch organogenesis.Veiga-Fernandes H., Coles M.C., Foster K.E., Patel A., Williams A., Natarajan D., Barlow A., Pachnis V., Kioussis D.View abstractCited forFUNCTION IN PEYER'S PATCH ORGANOGENESISCategoriesFunctionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 446:547-551 (2007)Cited in2Mapped to25
CD2AP and Cbl-3/Cbl-c constitute a critical checkpoint in the regulation of ret signal transduction.Tsui C.C., Pierchala B.A.View abstractCited forINTERACTION WITH CD2AP AND CBLC, TISSUE SPECIFICITYCategoriesExpression, InteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Neurosci. 28:8789-8800 (2008)Cited in8Mapped to6
RET signaling is required for survival and normal function of nonpeptidergic nociceptors.Golden J.P., Hoshi M., Nassar M.A., Enomoto H., Wood J.N., Milbrandt J., Gereau R.W. IV, Johnson E.M. Jr., Jain S.View abstractCited forFUNCTION IN NOCICEPTORS REGULATION, DISRUPTION PHENOTYPECategoriesFunction, Phenotypes & VariantsSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Neurosci. 30:3983-3994 (2010)Cited in1Mapped to20
A novel RET inhibitor with potent efficacy against medullary thyroid cancer in vivo.Samadi A.K., Mukerji R., Shah A., Timmermann B.N., Cohen M.S.View abstractCited forACTIVITY REGULATIONCategoriesFunctionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCSurgery 148:1228-1236 (2010)Cited in2Mapped to2
Non-homeostatic body weight regulation through a brainstem-restricted receptor for GDF15.Hsu J.Y., Crawley S., Chen M., Ayupova D.A., Lindhout D.A., Higbee J., Kutach A., Joo W., Gao Z.[...], Allan B.B.View abstractCited forTISSUE SPECIFICITYCategoriesExpressionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 550:255-259 (2017)Cited in7Mapped to6
Non-homeostatic body weight regulation through a brainstem-restricted receptor for GDF15.Hsu J.Y., Crawley S., Chen M., Ayupova D.A., Lindhout D.A., Higbee J., Kutach A., Joo W., Gao Z.[...], Allan B.B.View abstractCited forERRATUM OF PUBMED:28953886SourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 551:398-398 (2017)Cited in7
GFRAL is the receptor for GDF15 and is required for the anti-obesity effects of the ligand.Yang L., Chang C.C., Sun Z., Madsen D., Zhu H., Padkjaer S.B., Wu X., Huang T., Hultman K.[...], Joergensen S.B.View abstractCited forFUNCTION, INTERACTION WITH GFRALCategoriesFunction, InteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNat. Med. 23:1158-1166 (2017)Cited in9Mapped to1
Structural basis for the specific recognition of RET by the Dok1 phosphotyrosine binding domain.Shi N., Ye S., Bartlam M., Yang M., Wu J., Liu Y., Sun F., Han X., Peng X.[...], Rao Z.View abstractCited forX-RAY CRYSTALLOGRAPHY (2.50 ANGSTROMS) OF 1055-1067, PHOSPHORYLATION AT TYR-1063CategoriesPTM / Processing, StructureSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Biol. Chem. 279:4962-4969 (2004)Cited in2Mapped to5