P00359

Name	Glyceraldehyde-3-phosphate dehydrogenase 3 (GAPDH 3) (EC 1.2.1.12)
Uniprot ID	P00359
Systematic gene name	YGR192C
Standard gene name	TDH3
Gene names	TDH3 GPD3 YGR192C G7576
Description from SGD	YGR192C TDH3 SGDID:S000003424, Chr VII from 883810-882812, Genome Release 64-3-1, reverse complement, Verified ORF, "Glyceraldehyde-3-phosphate dehydrogenase (GAPDH), isozyme 3; involved in glycolysis and gluconeogenesis; tetramer that catalyzes the reaction of glyceraldehyde-3-phosphate to 1,3 bis-phosphoglycerate; detected in the cytoplasm and cell wall; GAPDH-derived antimicrobial peptides secreted by S. cerevisiae are active against a wide variety of wine-related yeasts and bacteria; binds AU-rich RNA"
Protein length	332
Download	sequence (fasta, from Uniprot), modifications (csv format)
Database links	Uniprot, SGD, TheCellVision.org, FungiDB

MVRVAINGFG RIGRLVMRIA LSRPNVEVVA LNDPFITNDY AAYMFKYDST
HGRYAGEVSH DDKHIIVDGK KIATYQERDP ANLPWGSSNV DIAIDSTGVF
KELDTAQKHI DAGAKKVVIT APSSTAPMFV MGVNEEKYTS DLKIVSNASC
TTNCLAPLAK VINDAFGIEE GLMTTVHSLT ATQKTVDGPS HKDWRGGRTA
SGNIIPSSTG AAKAVGKVLP ELQGKLTGMA FRVPTVDVSV VDLTVKLNKE
TTYDEIKKVV KAAAEGKLKG VLGYTEDAVV SSDFLGDSHS SIFDASAGIQ
LSPKFVKLVS WYDNEYGYST RVVDLVEHVA KA

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[7, Glyc]	Zielinska, D.F.,  Gnad, F.,  Schropp, K.,  Wiśniewski, J.R.,  Mann, M. (2012). Mapping N-glycosylation sites across seven evolutionarily distant species reveals a divergent substrate proteome despite a common core machinery. Mol Cell 46: 542-548. (Publication) (All modifications)
[22, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[22, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[22, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[22, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[22, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[37, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[46, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[46, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[49, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[54, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[54, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[54, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[59, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[59, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[59, Phos]	Guo X, Niemi NM, Coon JJ, Pagliarini DJ (2017a) Integrative proteomics and biochemical analyses define Ptc6p as the Saccharomyces cerevisiae pyruvate dehydrogenase phosphatase. J Biol Chem 292:11751–11759. (Publication) (All modifications)
[59, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[59, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[59, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[59, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[59, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[63, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[63, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[63, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[63, Ubi]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[70, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[70, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[71, K-bz]	Wang, D., Yan, F., Wu, P., Ge, K., Li, M., Li, T., Gao, Y., Peng, C., Chen, Y. (2022). Global profiling of regulatory elements in the histone benzoylation pathway. Nature Communications 13(1):1369 (Publication) (All modifications)
[74, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[87, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[88, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[88, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[88, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[88, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[101, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[101, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[101, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[108, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[108, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[108, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[108, Ubi]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[108, Ubi]	Fang, N.N.,  Chan, G.T.,  Zhu, M.,  Comyn, S.A.,  Persaud, A.,  Deshaies, R.J.,  Rotin, D.,  Gsponer, J.,  Mayor, T. (2014). Rsp5/Nedd4 is the main ubiquitin ligase that targets cytosolic misfolded proteins following heat stress. Nature Cell Biology 16(12): 1227-1237. (Publication) (All modifications)
[108, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[115, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[116, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[116, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[120, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[120, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[123, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[123, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[123, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[123, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[123, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[124, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[124, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[124, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[124, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[125, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[125, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[125, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[125, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[137, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[137, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[137, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[137, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[138, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[138, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[140, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[140, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[143, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[143, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[143, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[146, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[146, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[146, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[146, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[146, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[146, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[146, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[147, Glyc]	Cao, L.,  Yu, L.,  Guo, Z.,  Shen, A.,  Guo, Y.,  Liang, X. (2014). N-Glycosylation site analysis of proteins from Saccharomyces cerevisiae by using hydrophilic interaction liquid chromatography-based enrichment, parallel deglycosylation, and mass spectrometry. J Proteome Res 13: 1485-1493. (Publication) (All modifications)
[149, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[149, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[149, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[149, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[149, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[149, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[149, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[149, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[149, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[151, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[151, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[151, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[151, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[151, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[151, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[151, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[151, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[152, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[152, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[152, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[152, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[152, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[152, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[152, Phos]	Rødkær, S.V.,  Pultz, D.,  Brusch, M.,  Bennetzen, M.V.,  Falkenby, L.G.,  Andersen, J.S.,  Færgeman, N.J. (2014). Quantitative proteomics identifies unanticipated regulators of nitrogen- and glucose starvation. Mol Biosyst 10: 2176-2188. (Publication) (All modifications)
[152, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[174, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[174, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[175, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[175, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[175, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[175, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[178, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[178, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[178, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[178, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[178, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[180, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[180, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[180, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[180, Phos]	Rødkær, S.V.,  Pultz, D.,  Brusch, M.,  Bennetzen, M.V.,  Falkenby, L.G.,  Andersen, J.S.,  Færgeman, N.J. (2014). Quantitative proteomics identifies unanticipated regulators of nitrogen- and glucose starvation. Mol Biosyst 10: 2176-2188. (Publication) (All modifications)
[180, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[182, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[182, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[182, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[182, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[182, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[184, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[184, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[184, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[185, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[185, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[185, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[190, Phos]	Guo X, Niemi NM, Hutchins PD, et al (2017b) Ptc7p dephosphorylates select mitochondrial proteins to enhance metabolic function. Cell Reports 18:307–313. (Publication) (All modifications)
[190, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[190, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[190, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[190, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[190, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[190, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[190, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[192, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[192, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[192, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[192, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[192, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[199, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[199, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[199, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[199, Phos]	Chen, Y.C.,  Jiang, P.H.,  Chen, H.M.,  Chen, C.H.,  Wang, Y.T.,  Chen, Y.J.,  Yu, C.J.,  Teng, S.C. (2018a). Glucose intake hampers PKA-regulated HSP90 chaperone activity. Elife 7: e39925. (Publication) (All modifications)
[199, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[199, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[199, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[199, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[199, Phos]	Rødkær, S.V.,  Pultz, D.,  Brusch, M.,  Bennetzen, M.V.,  Falkenby, L.G.,  Andersen, J.S.,  Færgeman, N.J. (2014). Quantitative proteomics identifies unanticipated regulators of nitrogen- and glucose starvation. Mol Biosyst 10: 2176-2188. (Publication) (All modifications)
[199, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[201, Phos]	Guo X, Niemi NM, Hutchins PD, et al (2017b) Ptc7p dephosphorylates select mitochondrial proteins to enhance metabolic function. Cell Reports 18:307–313. (Publication) (All modifications)
[201, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[201, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[201, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[201, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[201, Phos]	Chen, Y.C.,  Jiang, P.H.,  Chen, H.M.,  Chen, C.H.,  Wang, Y.T.,  Chen, Y.J.,  Yu, C.J.,  Teng, S.C. (2018a). Glucose intake hampers PKA-regulated HSP90 chaperone activity. Elife 7: e39925. (Publication) (All modifications)
[201, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[201, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[201, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[201, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[201, Phos]	Schmitt, K.,  Smolinski, N.,  Neumann, P.,  Schmaul, S.,  Hofer-Pretz, V.,  Braus, G.H.,  Valerius, O. (2017). Asc1p/RACK1 connects ribosomes to eukaryotic phosphosignaling. Mol Cell Biol 37: e00279-16. (Publication) (All modifications)
[201, Phos]	Rødkær, S.V.,  Pultz, D.,  Brusch, M.,  Bennetzen, M.V.,  Falkenby, L.G.,  Andersen, J.S.,  Færgeman, N.J. (2014). Quantitative proteomics identifies unanticipated regulators of nitrogen- and glucose starvation. Mol Biosyst 10: 2176-2188. (Publication) (All modifications)
[201, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[207, Phos]	Guo X, Niemi NM, Hutchins PD, et al (2017b) Ptc7p dephosphorylates select mitochondrial proteins to enhance metabolic function. Cell Reports 18:307–313. (Publication) (All modifications)
[207, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[207, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[207, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[207, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[207, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[208, Phos]	Guo X, Niemi NM, Hutchins PD, et al (2017b) Ptc7p dephosphorylates select mitochondrial proteins to enhance metabolic function. Cell Reports 18:307–313. (Publication) (All modifications)
[208, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[208, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[208, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[208, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[208, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[208, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[208, Phos]	Rødkær, S.V.,  Pultz, D.,  Brusch, M.,  Bennetzen, M.V.,  Falkenby, L.G.,  Andersen, J.S.,  Færgeman, N.J. (2014). Quantitative proteomics identifies unanticipated regulators of nitrogen- and glucose starvation. Mol Biosyst 10: 2176-2188. (Publication) (All modifications)
[208, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[209, Phos]	Studer RA, Rodriguez-Mias RA, Haas KM, et al (2016) Evolution of protein phosphorylation across 18 fungal species. Science 354:229–232. (Publication) (All modifications)
[209, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[209, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[209, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[209, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[209, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[213, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[213, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[213, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[213, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[213, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[217, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[217, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[217, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[217, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[217, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[225, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[225, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[225, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[225, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[227, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[227, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[227, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[227, Phos]	Chen, Y.C.,  Jiang, P.H.,  Chen, H.M.,  Chen, C.H.,  Wang, Y.T.,  Chen, Y.J.,  Yu, C.J.,  Teng, S.C. (2018a). Glucose intake hampers PKA-regulated HSP90 chaperone activity. Elife 7: e39925. (Publication) (All modifications)
[227, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[227, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[227, Phos]	Soulard, A.,  Cremonesi, A.,  Moes, S.,  Schütz, F.,  Jenö, P.,  Hall, M.N. (2010). The rapamycin-sensitive phosphoproteome reveals that TOR controls protein kinase A toward some but not all substrates. Molecular Biology of the Cell 21(19): 3475-3486. (Publication) (All modifications)
[227, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[227, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[235, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[235, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[235, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[235, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[235, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[239, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[239, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[239, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[239, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[246, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[246, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[246, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[249, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[249, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[249, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[249, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[249, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[252, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[252, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[252, Phos]	MacGilvray, M.E., Shishkova, E., Place, M., Wagner, E.R., Coon, J.J., Gasch, A.P. (2020). Phosphoproteome response to dithiothreitol reveals unique versus shared features of Saccharomyces cerevisiae stress responses. Journal of Proteome Research 19(8): 3405-3417. (Publication) (All modifications)
[252, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[252, Phos]	Swaney, D.L.,  Beltrao, P.,  Starita, L.,  Guo, A.,  Rush, J.,  Fields, S.,  Krogan, N.J.,  Villén, J. (2013). Global analysis of phosphorylation and ubiquitylation cross-talk in protein degradation. Nature Methods 10(7): 676-682. (Publication) (All modifications)
[252, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[253, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[253, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[257, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[257, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[257, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[257, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[257, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[258, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[258, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[261, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[261, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[261, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[267, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[267, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[282, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[288, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[291, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[291, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[296, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[296, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[302, Phos]	Lanz MC, Yugandhar K, Gupta S, Sanford EJ, Faça VM, Vega S, Joiner AMN, Fromme JC, Yu H, Smolka MB (2021). In-depth and 3-dimensional exploration of the budding yeast phosphoproteome. EMBO Reports, e51121. (Publication) (All modifications)
[302, Phos]	Vlastaridis P, Kyriakidou P, Chaliotis A, et al (2017) Estimating the total number of phosphoproteins and phosphorylation sites in eukaryotic proteomes. GigaScience 6:1–11. (Publication) (All modifications)
[302, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[302, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[302, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[307, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[307, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)
[310, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[310, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[310, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[310, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[312, Phos]	Bai Y, Chen B, Li M, et al (2017) FPD: A comprehensive phosphorylation database in fungi. Fungal Biology 121:869–875. (Publication) (All modifications)
[312, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[312, Phos]	Albuquerque, C.P., Smolka, M.B., Payne, S.H., Bafna, V., Eng, J., Zhou, H. (2008). A multidimensional chromatography technology for in-depth phosphoproteome analysis. Molecular and Cellular Proteomics 7(7):1389-1396. (Publication) (All modifications)
[312, Phos]	Frankovsky, J., Vozáriková, V., Nosek, J., Tomáška, Ľ. (2021a). Mitochondrial protein phosphorylation in yeast revisited.Mitochondrion 57:148-162. (Publication) (All modifications)
[318, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[319, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[319, Phos]	Holt, L.J.,  Tuch, B.B.,  Villén, J.,  Johnson, A.D.,  Gygi, S.P.,  Morgan, D.O. (2009). Global analysis of Cdk1 substrate phosphorylation sites provides insights into evolution. Science 325(5948): 1682-1686. (Publication) (All modifications)
[320, Phos]	Zhou, X., Li, W., Liu, Y., Amon, A. (2021. Cross-compartment signal propagation in the mitotic exit network. Elife 10:e63645. (Publication) (All modifications)
[331, K-succ]	Weinert, B.T., Schölz, C., Wagner, S.A., et al. (2013). Lysine succinylation is a frequently occurring modification in prokaryotes and eukaryotes and extensively overlaps with acetylation. Cell Reports, 4(4), 842-851. (Publication) (All modifications)
[331, K-succ]	Frankovsky, J., Keresztesová, B., Bellová, J., et al. (2021). The yeast mitochondrial succinylome: Implications for regulation of mitochondrial nucleoids. Journal of Biological Chemistry, 297(4): 101155. (Publication) (All modifications)
[331, K-acetyl]	Henriksen, P., Wagner, S. A., Weinert, B. T., et al. (2012). Proteome-wide analysis of lysine acetylation suggests its broad regulatory scope in Saccharomyces cerevisiae. Molecular & Cellular Proteomics, 11(11), 1510-1522. (Publication) (All modifications)
[331, Ubi]	Back, S., Gorman, A.W., Vogel, C., Silva, G.M. (2019). Site-specific K63 ubiquitinomics provides insights into translation regulation under stress. Journal of Proteome Research 18(1): 309-318. (Publication) (All modifications)
[331, SUMO]	Bhagwat, N.R., Owens, S.N., Ito, M., Boinapalli, J.V,, Poa, P., Ditzel, A., Kopparapu, S., Mahalawat, M., Davies, O.R., Collins, S.R., Johnson, J.R., Krogan, N.J., Hunter, N. (2021). SUMO is a pervasive regulator of meiosis. Elife 10:e57720. (Publication) (All modifications)