The ARD1 gene of yeast functions in the switch between the mitotic cell cycle and alternative developmental pathways.Whiteway M., Szostak J.W.View abstractCited forNUCLEOTIDE SEQUENCE [GENOMIC DNA]CategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCCell 43:483-492 (1985)Cited in1
Complete nucleotide sequence of Saccharomyces cerevisiae chromosome VIII.Johnston M., Andrews S., Brinkman R., Cooper J., Ding H., Dover J., Du Z., Favello A., Fulton L.[...], Vaudin M.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]StrainATCC 204508 / S288cCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCScience 265:2077-2082 (1994)Cited in99+
The reference genome sequence of Saccharomyces cerevisiae: Then and now.Engel S.R., Dietrich F.S., Fisk D.G., Binkley G., Balakrishnan R., Costanzo M.C., Dwight S.S., Hitz B.C., Karra K.[...], Cherry J.M.View abstractCited forGENOME REANNOTATIONStrainATCC 204508 / S288cCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCG3 (Bethesda) 4:389-398 (2014)Cited in99+
Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae.Hu Y., Rolfs A., Bhullar B., Murthy T.V.S., Zhu C., Berger M.F., Camargo A.A., Kelley F., McCarron S.[...], LaBaer J.View abstractCited forNUCLEOTIDE SEQUENCE [GENOMIC DNA]StrainATCC 204508 / S288cCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCGenome Res. 17:536-543 (2007)Cited in99+
Identification and characterization of genes and mutants for an N-terminal acetyltransferase from yeast.Mullen J.R., Kayne P.S., Moerschell R.P., Tsunasawa S., Gribskov M., Colavito-Shepanski M., Grunstein M., Sherman F., Sternglanz R.View abstractCited forFUNCTION, CATALYTIC ACTIVITY, CHARACTERIZATIONCategoryFunctionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCEMBO J. 8:2067-2075 (1989)Cited in2Mapped to1
ARD1 and NAT1 proteins form a complex that has N-terminal acetyltransferase activity.Park E.C., Szostak J.W.View abstractCited forFUNCTION, CATALYTIC ACTIVITY, INTERACTION WITH NAT1, SELF-ASSOCIATIONCategoriesFunction, InteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCEMBO J. 11:2087-2093 (1992)Cited in2Mapped to1
The yeast N(alpha)-acetyltransferase NatA is quantitatively anchored to the ribosome and interacts with nascent polypeptides.Gautschi M., Just S., Mun A., Ross S., Rucknagel P., Dubaquie Y., Ehrenhofer-Murray A., Rospert S.View abstractCited forIDENTIFICATION IN THE NATA COMPLEXCategoryInteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Cell. Biol. 23:7403-7414 (2003)Cited in3Mapped to6
Global analysis of protein localization in budding yeast.Huh W.-K., Falvo J.V., Gerke L.C., Carroll A.S., Howson R.W., Weissman J.S., O'Shea E.K.View abstractCited forSUBCELLULAR LOCATION [LARGE SCALE ANALYSIS]CategorySubcellular LocationSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 425:686-691 (2003)Cited in99+Mapped to99+
Global analysis of protein expression in yeast.Ghaemmaghami S., Huh W.-K., Bower K., Howson R.W., Belle A., Dephoure N., O'Shea E.K., Weissman J.S.View abstractCited forLEVEL OF PROTEIN EXPRESSION [LARGE SCALE ANALYSIS]CategoryExpressionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 425:737-741 (2003)Cited in99+
TEL+CEN antagonism on plasmids involves telomere repeat sequences tracts and gene products that interact with chromosomal telomeres.Enomoto S., Longtine M.S., Berman J.View abstractAnnotationRegulatory Role|Mutants/Phenotypes|Primary Literature|Function/ProcessCategoryFunctionSourceSGD: S000001055PubMedEurope PMCChromosoma 103:237-250 (1994)Mapped to1
The yeast ARD1 gene product is required for repression of cryptic mating- type information at the HML locus.Whiteway M., Freedman R., Van Arsdell S., Szostak J.W., Thorner J.View abstractAnnotationRegulatory Role|Other Features|Mutants/Phenotypes|Primary Literature|Function/ProcessCategoriesFunction, Phenotypes & VariantsSourceSGD: S000001055PubMedEurope PMCMol Cell Biol 7:3713-3722 (1987)Mapped to1
Structure and Mechanism of Acetylation by the N-Terminal Dual Enzyme NatA/Naa50 Complex.Deng S., Magin R.S., Wei X., Pan B., Petersson E.J., Marmorstein R.View abstractAnnotationStructure and mechanism of acetylation by the N-terminal dual enzyme NatA/Naa50 complex has been reported.CategoryFunction, StructureSourceGeneRif: 856404, PDB: 6O07PubMedEurope PMCStructure 27:1057-1070.e4 (2019)Mapped to13
Ribosome-NatA architecture reveals that rRNA expansion segments coordinate N-terminal acetylation.Knorr A.G., Schmidt C., Tesina P., Berninghausen O., Becker T., Beatrix B., Beckmann R.View abstractCategoryStructureSourcePDB: 6HD5, PDB: 6HD7PubMedEurope PMCNat Struct Mol Biol 26:35-39 (2019)Mapped to43
Functional Metabolomics Describes the Yeast Biosynthetic Regulome.Mulleder M., Calvani E., Alam M.T., Wang R.K., Eckerstorfer F., Zelezniak A., Ralser M.View abstractAnnotationPrimary LiteratureCategoryFunctionSourceSGD: S000001055PubMedEurope PMCCell 167:553-565.e12 (2016)Mapped to99+
Proteomic and genomic characterization of a yeast model for Ogden syndrome.Dorfel M.J., Fang H., Crain J., Klingener M., Weiser J., Lyon G.J.View abstractAnnotationPrimary LiteratureCategoriesFunction, Phenotypes & VariantsSourceSGD: S000001055PubMedEurope PMCYeast 34:19-37 (2017)Mapped to2
Numerous proteins with unique characteristics are degraded by the 26S proteasome following monoubiquitination.Braten O., Livneh I., Ziv T., Admon A., Kehat I., Caspi L.H., Gonen H., Bercovich B., Godzik A.[...], Ciechanover A.View abstractAnnotationS000001055CategoriesFunction, PTM / ProcessingSourceSGD: S000001055PubMedEurope PMCProc Natl Acad Sci U S A 113:E4639-47 (2016)Mapped to3
Protein N-terminal Acetylation by the NatA Complex Is Critical for Selective Mitochondrial Degradation.Eiyama A., Okamoto K.View abstractAnnotationPrimary LiteratureCategoryFunctionSourceSGD: S000001055PubMedEurope PMCJ Biol Chem 290:25034-25044 (2015)Mapped to3
Finding pathway-modulating genes from a novel Ontology Fingerprint-derived gene network.Qin T., Matmati N., Tsoi L.C., Mohanty B.K., Gao N., Tang J., Lawson A.B., Hannun Y.A., Zheng W.J.View abstractAnnotationS000001055CategoriesFunction, Phenotypes & VariantsSourceSGD: S000001055PubMedEurope PMCNucleic Acids Res 42:e138-e138 (2014)Mapped to14
A Saccharomyces cerevisiae model reveals in vivo functional impairment of the Ogden syndrome N-terminal acetyltransferase NAA10 Ser37Pro mutant.Van Damme P., Stove S.I., Glomnes N., Gevaert K., Arnesen T.View abstractAnnotationPrimary LiteratureCategoriesFunction, Phenotypes & VariantsSourceSGD: S000001055PubMedEurope PMCMol Cell Proteomics 13:2031-2041 (2014)Mapped to6
A multistep genomic screen identifies new genes required for repair of DNA double-strand breaks in Saccharomyces cerevisiae.McKinney J.S., Sethi S., Tripp J.D., Nguyen T.N., Sanderson B.A., Westmoreland J.W., Resnick M.A., Lewis L.K.View abstractAnnotationPrimary LiteratureCategoryFunctionSourceSGD: S000001055PubMedEurope PMCBMC Genomics 14:251-251 (2013)Mapped to99+
Identification and analysis of the acetylated status of poplar proteins reveals analogous N-terminal protein processing mechanisms with other eukaryotes.Liu C.C., Zhu H.Y., Dong X.M., Ning D.L., Wang H.X., Li W.H., Yang C.P., Wang B.C.View abstractAnnotationS000001055CategoryPTM / ProcessingSourceSGD: S000001055PubMedEurope PMCPLoS One 8:e58681-e58681 (2013)Mapped to1
N-acetylation and phosphorylation of Sec complex subunits in the ER membrane.Soromani C., Zeng N., Hollemeyer K., Heinzle E., Klein M.C., Tretter T., Seaman M.N., Romisch K.View abstractAnnotationPrimary LiteratureCategoryPTM / ProcessingSourceSGD: S000001055PubMedEurope PMCBMC Cell Biol 13:34-34 (2012)Mapped to3
Protein N-terminal acetyltransferases act as N-terminal propionyltransferases in vitro and in vivo.Foyn H., Van Damme P., Stove S.I., Glomnes N., Evjenth R., Gevaert K., Arnesen T.View abstractAnnotationCross-species Expression|Strains/Constructs|Mutants/Phenotypes|Non-Fungal Related Genes/Proteins|Primary LiteratureCategoryPTM / ProcessingSourceSGD: S000001055PubMedEurope PMCMol Cell Proteomics 12:42-54 (2013)Mapped to21
Recruitment of Rpd3 to the telomere depends on the protein arginine methyltransferase Hmt1.Milliman E.J., Yadav N., Chen Y.C., Muddukrishna B., Karunanithi S., Yu M.C.View abstractAnnotationS000001055CategoryFunctionSourceSGD: S000001055PubMedEurope PMCPLoS One 7:e44656-e44656 (2012)Mapped to17
Dissecting DNA damage response pathways by analysing protein localization and abundance changes during DNA replication stress.Tkach J.M., Yimit A., Lee A.Y., Riffle M., Costanzo M., Jaschob D., Hendry J.A., Ou J., Moffat J.[...], Brown G.W.View abstractAnnotationPrimary LiteratureCategorySubcellular LocationSourceSGD: S000001055PubMedEurope PMCNat. Cell Biol. 14:966-976 (2012)Cited in8Mapped to99+