The nucleotide sequence of Saccharomyces cerevisiae chromosome IX.Churcher C.M., Bowman S., Badcock K., Bankier A.T., Brown D., Chillingworth T., Connor R., Devlin K., Gentles S.[...], Barrell B.G.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]StrainATCC 204508 / S288cCategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 387:84-87 (1997)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 / S288cCategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCG3 (Bethesda) 4:389-398 (2014)Cited in99+
MOB1, an essential yeast gene required for completion of mitosis and maintenance of ploidy.Luca F.C., Winey M.View abstractCited forIDENTIFICATION OF INTRONSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Biol. Cell 9:29-46 (1998)Cited in2Mapped to1
DBF2 protein kinase binds to and acts through the cell cycle-regulated MOB1 protein.Komarnitsky S.I., Chiang Y.-C., Luca F.C., Chen J., Toyn J.H., Winey M., Johnston L.H., Denis C.L.View abstractCited forINTERACTION WITH DBF2CategoriesInteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Cell. Biol. 18:2100-2107 (1998)Cited in2
Regulation of the localization of Dbf2 and Mob1 during cell division of Saccharomyces cerevisiae.Yoshida S., Toh-e A.View abstractCited forSUBCELLULAR LOCATIONCategoriesSubcellular LocationSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCGenes Genet. Syst. 76:141-147 (2001)Cited in2
Saccharomyces cerevisiae Mob1p is required for cytokinesis and mitotic exit.Luca F.C., Mody M., Kurischko C., Roof D.M., Giddings T.H., Winey M.View abstractCited forFUNCTION, SUBCELLULAR LOCATIONCategoriesFunction, Subcellular LocationSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Cell. Biol. 21:6972-6983 (2001)Cited in1Mapped to7
Protein kinase Cdc15 activates the Dbf2-Mob1 kinase complex.Mah A.S., Jang J., Deshaies R.J.View abstractCited forFUNCTION, INTERACTION WITH DBF2, PHOSPHORYLATION BY CDC15CategoriesFunction, PTM / Processing, InteractionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCProc. Natl. Acad. Sci. U.S.A. 98:7325-7330 (2001)Cited in3Mapped to2
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]CategoriesSubcellular 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]CategoriesExpressionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCNature 425:737-741 (2003)Cited in99+
The mitotic exit network Mob1p-Dbf2p kinase complex localizes to the nucleus and regulates passenger protein localization.Stoepel J., Ottey M.A., Kurischko C., Hieter P., Luca F.C.View abstractCited forFUNCTION, SUBCELLULAR LOCATIONCategoriesFunction, Subcellular LocationSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Biol. Cell 16:5465-5479 (2005)Cited in2Mapped to1
Large-scale phosphorylation analysis of alpha-factor-arrested Saccharomyces cerevisiae.Li X., Gerber S.A., Rudner A.D., Beausoleil S.A., Haas W., Villen J., Elias J.E., Gygi S.P.View abstractCited forIDENTIFICATION BY MASS SPECTROMETRY [LARGE SCALE ANALYSIS]StrainADR376CategoriesSequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Proteome Res. 6:1190-1197 (2007)Cited in99+
A multidimensional chromatography technology for in-depth phosphoproteome analysis.Albuquerque C.P., Smolka M.B., Payne S.H., Bafna V., Eng J., Zhou H.View abstractCited forPHOSPHORYLATION [LARGE SCALE ANALYSIS] AT SER-34; SER-36 AND SER-80, IDENTIFICATION BY MASS SPECTROMETRY [LARGE SCALE ANALYSIS]CategoriesPTM / Processing, SequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCMol. Cell. Proteomics 7:1389-1396 (2008)Cited in99+
Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution.Holt L.J., Tuch B.B., Villen J., Johnson A.D., Gygi S.P., Morgan D.O.View abstractCited forPHOSPHORYLATION [LARGE SCALE ANALYSIS] AT SER-34; SER-36; SER-80 AND SER-229, IDENTIFICATION BY MASS SPECTROMETRY [LARGE SCALE ANALYSIS]CategoriesPTM / Processing, SequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCScience 325:1682-1686 (2009)Cited in99+
Structural and functional analysis of Saccharomyces cerevisiae Mob1.Mrkobrada S., Boucher L., Ceccarelli D.F.J., Tyers M., Sicheri F.View abstractCited forX-RAY CRYSTALLOGRAPHY (2.0 ANGSTROMS) OF 79-314, MUTAGENESIS OF THR-105 AND SER-107, INTERACTION WITH MOB2CategoriesInteraction, Phenotypes & Variants, StructureSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Mol. Biol. 362:430-440 (2006)Cited in2
The identification of transposon-tagged mutations in essential genes that affect cell morphology in Saccharomyces cerevisiae.Chun K.T., Goebl M.G.View abstractAnnotationStrains/Constructs|Other Features|Mutants/Phenotypes|Techniques and Reagents|Primary LiteratureCategoriesFunction, Phenotypes & VariantsSourceSGD: S000001368PubMedEurope PMCGenetics 142:39-50 (1996)Mapped to1
Ndr/Lats Kinases Bind Specific Mob-Family Coactivators through a Conserved and Modular Interface.Parker B.W., Gogl G., Balint M., Hetenyi C., Remenyi A., Weiss E.L.View abstractCategoriesStructureSourcePDB: 5NCNPubMedEurope PMCBiochemistry 59:1688-1700 (2020)Mapped to5
Mechanics and regulation of cytokinesis in budding yeast.Bhavsar-Jog Y.P., Bi E.View abstractAnnotationS000001368SourceSGD: S000001368PubMedEurope PMCSemin Cell Dev Biol 66:107-118 (2017)Mapped to34
Regulation of Mitotic Exit in Saccharomyces cerevisiae.Baro B., Queralt E., Monje-Casas F.View abstractAnnotationReviewsCategoriesFunctionSourceSGD: S000001368PubMedEurope PMCMethods Mol Biol 1505:3-17 (2017)Mapped to23
MST1/MST2 Protein Kinases: Regulation and Physiologic Roles.Galan J.A., Avruch J.View abstractAnnotationReviewsCategoriesInteractionSourceSGD: S000001368PubMedEurope PMCBiochemistry 55:5507-5519 (2016)Mapped to4
Actomyosin ring driven cytokinesis in budding yeast.Meitinger F., Palani S.View abstractAnnotationReviewsSourceSGD: S000001368PubMedEurope PMCSemin Cell Dev Biol 53:19-27 (2016)Mapped to43
Coupling spindle position with mitotic exit in budding yeast: The multifaceted role of the small GTPase Tem1.Scarfone I., Piatti S.View abstractAnnotationReviewsCategoriesFunctionSourceSGD: S000001368PubMedEurope PMCSmall GTPases 6:196-201 (2015)Mapped to13
Cdc14 Early Anaphase Release, FEAR, Is Limited to the Nucleus and Dispensable for Efficient Mitotic Exit.Yellman C.M., Roeder G.S.View abstractAnnotationS000001368CategoriesFunctionSourceSGD: S000001368PubMedEurope PMCPLoS One 10:e0128604-e0128604 (2015)Mapped to13
An integrated overview of spatiotemporal organization and regulation in mitosis in terms of the proteins in the functional supercomplexes.Zheng Y., Guo J., Li X., Xie Y., Hou M., Fu X., Dai S., Diao R., Miao Y., Ren J.View abstractAnnotationReviewsCategoriesSubcellular LocationSourceSGD: S000001368PubMedEurope PMCFront Microbiol 5:573-573 (2014)Mapped to99+
The Mitotic Exit Network: new turns on old pathways.Hotz M., Barral Y.View abstractAnnotationReviewsCategoriesFunctionSourceSGD: S000001368PubMedEurope PMCTrends Cell Biol 24:145-152 (2014)Mapped to16
Dual Regulation of the mitotic exit network (MEN) by PP2A-Cdc55 phosphatase.Baro B., Rodriguez-Rodriguez J.A., Calabria I., Hernaez M.L., Gil C., Queralt E.View abstractAnnotationS000001368CategoriesFunction, PTM / ProcessingSourceSGD: S000001368PubMedEurope PMCPLoS Genet 9:e1003966-e1003966 (2013)Mapped to3