Global analysis of the yeast osmotic stress response by quantitative proteomics

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Global analysis of the yeast osmotic stress response by quantitative proteomics. / Soufi, Boumediene; Kelstrup, Christian D; Stoehr, Gabriele; Fröhlich, Florian; Walther, Tobias C; Olsen, Jesper V.

In: Molecular BioSystems, Vol. 5, No. 11, 2009, p. 1337-46.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Soufi, B, Kelstrup, CD, Stoehr, G, Fröhlich, F, Walther, TC & Olsen, JV 2009, 'Global analysis of the yeast osmotic stress response by quantitative proteomics', Molecular BioSystems, vol. 5, no. 11, pp. 1337-46. https://doi.org/10.1039/b902256b

APA

Soufi, B., Kelstrup, C. D., Stoehr, G., Fröhlich, F., Walther, T. C., & Olsen, J. V. (2009). Global analysis of the yeast osmotic stress response by quantitative proteomics. Molecular BioSystems, 5(11), 1337-46. https://doi.org/10.1039/b902256b

Vancouver

Soufi B, Kelstrup CD, Stoehr G, Fröhlich F, Walther TC, Olsen JV. Global analysis of the yeast osmotic stress response by quantitative proteomics. Molecular BioSystems. 2009;5(11):1337-46. https://doi.org/10.1039/b902256b

Author

Soufi, Boumediene ; Kelstrup, Christian D ; Stoehr, Gabriele ; Fröhlich, Florian ; Walther, Tobias C ; Olsen, Jesper V. / Global analysis of the yeast osmotic stress response by quantitative proteomics. In: Molecular BioSystems. 2009 ; Vol. 5, No. 11. pp. 1337-46.

Bibtex

@article{f1d6f8e0e97011deba73000ea68e967b,
title = "Global analysis of the yeast osmotic stress response by quantitative proteomics",
abstract = "Information on extracellular signals and conditions is often transduced by biological systems using cascades of protein phosphorylation that affect the activity of enzymes, the localization of proteins and gene expression. A model to study signal transduction is the response of the yeast Saccharomyces cerevisiae to osmotic changes as it shares many central themes with information processing modules in higher eukaryotes. Despite considerable progress in our understanding of this pathway, the scale and dynamics of this system have not been addressed systematically yet. Here, we report a comprehensive, quantitative, and time-resolved analysis using high-resolution mass spectrometry of phospho-proteome and proteome changes in response to osmotic stress in yeast. We identified 5534 unique phosphopeptide variants and 3383 yeast proteins. More than 15% of the detected phosphorylation site status changed more than two-fold within 5 minutes of treatment. Many of the corresponding phosphoproteins are involved in the early response to environmental stress. Surprisingly, we find that 158 regulated phosphorylation sites are potential substrates of basophilic kinases as opposed to the classical proline-directed MAP kinase network implicated in stress response mechanisms such as p38 and HOG pathways. Proteome changes reveal an increase in abundance of more than one hundred proteins after 20 min of salt stress. Many of these are involved in the cellular response to increased osmolarity, which include proteins used for glycerol production that is up-regulated to counterbalance the increased osmolarity of the salt containing growth medium. Although the overall relationship between our proteome and published mRNA changes is poor we find an excellent correlation between the subset of osmotic shock up-regulated proteins and their corresponding mRNA changes.",
author = "Boumediene Soufi and Kelstrup, {Christian D} and Gabriele Stoehr and Florian Fr{\"o}hlich and Walther, {Tobias C} and Olsen, {Jesper V}",
year = "2009",
doi = "10.1039/b902256b",
language = "English",
volume = "5",
pages = "1337--46",
journal = "Molecular BioSystems",
issn = "1742-206X",
publisher = "Royal Society of Chemistry",
number = "11",

}

RIS

TY - JOUR

T1 - Global analysis of the yeast osmotic stress response by quantitative proteomics

AU - Soufi, Boumediene

AU - Kelstrup, Christian D

AU - Stoehr, Gabriele

AU - Fröhlich, Florian

AU - Walther, Tobias C

AU - Olsen, Jesper V

PY - 2009

Y1 - 2009

N2 - Information on extracellular signals and conditions is often transduced by biological systems using cascades of protein phosphorylation that affect the activity of enzymes, the localization of proteins and gene expression. A model to study signal transduction is the response of the yeast Saccharomyces cerevisiae to osmotic changes as it shares many central themes with information processing modules in higher eukaryotes. Despite considerable progress in our understanding of this pathway, the scale and dynamics of this system have not been addressed systematically yet. Here, we report a comprehensive, quantitative, and time-resolved analysis using high-resolution mass spectrometry of phospho-proteome and proteome changes in response to osmotic stress in yeast. We identified 5534 unique phosphopeptide variants and 3383 yeast proteins. More than 15% of the detected phosphorylation site status changed more than two-fold within 5 minutes of treatment. Many of the corresponding phosphoproteins are involved in the early response to environmental stress. Surprisingly, we find that 158 regulated phosphorylation sites are potential substrates of basophilic kinases as opposed to the classical proline-directed MAP kinase network implicated in stress response mechanisms such as p38 and HOG pathways. Proteome changes reveal an increase in abundance of more than one hundred proteins after 20 min of salt stress. Many of these are involved in the cellular response to increased osmolarity, which include proteins used for glycerol production that is up-regulated to counterbalance the increased osmolarity of the salt containing growth medium. Although the overall relationship between our proteome and published mRNA changes is poor we find an excellent correlation between the subset of osmotic shock up-regulated proteins and their corresponding mRNA changes.

AB - Information on extracellular signals and conditions is often transduced by biological systems using cascades of protein phosphorylation that affect the activity of enzymes, the localization of proteins and gene expression. A model to study signal transduction is the response of the yeast Saccharomyces cerevisiae to osmotic changes as it shares many central themes with information processing modules in higher eukaryotes. Despite considerable progress in our understanding of this pathway, the scale and dynamics of this system have not been addressed systematically yet. Here, we report a comprehensive, quantitative, and time-resolved analysis using high-resolution mass spectrometry of phospho-proteome and proteome changes in response to osmotic stress in yeast. We identified 5534 unique phosphopeptide variants and 3383 yeast proteins. More than 15% of the detected phosphorylation site status changed more than two-fold within 5 minutes of treatment. Many of the corresponding phosphoproteins are involved in the early response to environmental stress. Surprisingly, we find that 158 regulated phosphorylation sites are potential substrates of basophilic kinases as opposed to the classical proline-directed MAP kinase network implicated in stress response mechanisms such as p38 and HOG pathways. Proteome changes reveal an increase in abundance of more than one hundred proteins after 20 min of salt stress. Many of these are involved in the cellular response to increased osmolarity, which include proteins used for glycerol production that is up-regulated to counterbalance the increased osmolarity of the salt containing growth medium. Although the overall relationship between our proteome and published mRNA changes is poor we find an excellent correlation between the subset of osmotic shock up-regulated proteins and their corresponding mRNA changes.

U2 - 10.1039/b902256b

DO - 10.1039/b902256b

M3 - Journal article

C2 - 19823750

VL - 5

SP - 1337

EP - 1346

JO - Molecular BioSystems

JF - Molecular BioSystems

SN - 1742-206X

IS - 11

ER -

ID: 16275268