Combined Proteome and Metabolite-profiling Analyses Reveal Surprising Insights into Yeast Sulfur Metabolism

Metabolomics is considered as an emerging new tool for functional proteomics in the identification of new protein function or in projects aiming at modeling whole cell metabolism. When combined with proteome studies, metabolite-profiling analyses revealed unanticipated insights into the yeast sulfur...

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Veröffentlicht in:	The Journal of biological chemistry 2005-07, Vol.280 (26), p.24723-24730
Hauptverfasser:	Lafaye, Alexandra, Junot, Christophe, Pereira, Yannick, Lagniel, Gilles, Tabet, Jean-Claude, Ezan, Eric, Labarre, Jean
Format:	Artikel
Sprache:	eng
Schlagworte:	Cadmium - chemistry Cadmium Chloride - chemistry Chromatography, Liquid Cysteine - chemistry Dose-Response Relationship, Drug Fungal Proteins - chemistry Gene Expression Regulation, Fungal Genes, Fungal Glutathione - chemistry Glutathione - metabolism Kinetics Methionine - chemistry Methionine - pharmacology Models, Biological Proteomics - methods Saccharomyces cerevisiae - metabolism Saccharomyces cerevisiae Proteins - chemistry Sulfates - chemistry Sulfur - chemistry Sulfur - metabolism Time Factors
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container_title	The Journal of biological chemistry
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creator	Lafaye, Alexandra Junot, Christophe Pereira, Yannick Lagniel, Gilles Tabet, Jean-Claude Ezan, Eric Labarre, Jean
description	Metabolomics is considered as an emerging new tool for functional proteomics in the identification of new protein function or in projects aiming at modeling whole cell metabolism. When combined with proteome studies, metabolite-profiling analyses revealed unanticipated insights into the yeast sulfur pathway. In response to cadmium, the observed overproduction of glutathione, essential for the detoxification of the metal, can be entirely accounted for by a marked drop in sulfur-containing protein synthesis and a redirection of sulfur metabolite fluxes to the glutathione pathway. A kinetic analysis showed sequential and dramatic changes in intermediate sulfur metabolite pools within the first hours of the treatment. Strikingly, whereas proteome and metabolic data were positively correlated under cadmium conditions, proteome and metabolic data were negatively correlated during other growth conditions, i.e. methionine supplementation or sulfate starvation. These differences can be explained by alternative mechanisms in the regulation of Met4, the activator of the sulfur pathway. Whereas Met4 activity is controlled by the cellular cysteine content in response to sulfur source and availability, the present study suggests that Met4 activation under cadmium conditions is cysteine-independent. The results clearly indicate that the metabolic state of a cell cannot be safely predicted based solely on proteomic and/or gene expression data. Combined metabolome and proteome studies are necessary to draw a comprehensive and integrated view of cell metabolism.
doi_str_mv	10.1074/jbc.M502285200
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Whereas Met4 activity is controlled by the cellular cysteine content in response to sulfur source and availability, the present study suggests that Met4 activation under cadmium conditions is cysteine-independent. The results clearly indicate that the metabolic state of a cell cannot be safely predicted based solely on proteomic and/or gene expression data. 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Whereas Met4 activity is controlled by the cellular cysteine content in response to sulfur source and availability, the present study suggests that Met4 activation under cadmium conditions is cysteine-independent. The results clearly indicate that the metabolic state of a cell cannot be safely predicted based solely on proteomic and/or gene expression data. 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subjects	Cadmium - chemistry Cadmium Chloride - chemistry Chromatography, Liquid Cysteine - chemistry Dose-Response Relationship, Drug Fungal Proteins - chemistry Gene Expression Regulation, Fungal Genes, Fungal Glutathione - chemistry Glutathione - metabolism Kinetics Methionine - chemistry Methionine - pharmacology Models, Biological Proteomics - methods Saccharomyces cerevisiae - metabolism Saccharomyces cerevisiae Proteins - chemistry Sulfates - chemistry Sulfur - chemistry Sulfur - metabolism Time Factors
title	Combined Proteome and Metabolite-profiling Analyses Reveal Surprising Insights into Yeast Sulfur Metabolism
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