Quantitative Analysis of the High Temperature-induced Glycolytic Flux Increase in Saccharomyces cerevisiae Reveals Dominant Metabolic Regulation

A major challenge in systems biology lies in the integration of processes occurring at different levels, such as transcription, translation, and metabolism, to understand the functioning of a living cell in its environment. We studied the high temperature-induced glycolytic flux increase in Saccharo...

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Bibliographic Details
Published in:The Journal of biological chemistry 2008-08, Vol.283 (35), p.23524-23532
Main Authors: Postmus, Jarne, Canelas, André B., Bouwman, Jildau, Bakker, Barbara M., van Gulik, Walter, de Mattos, M. Joost Teixeira, Brul, Stanley, Smits, Gertien J.
Format: Article
Language:English
Subjects:
Adaptation, Physiological - physiology
Enzymes - biosynthesis
Enzymes - genetics
Gene Expression Regulation, Enzymologic - physiology
Gene Expression Regulation, Fungal - physiology
Glycolysis - physiology
Hot Temperature
Metabolism and Bioenergetics
Saccharomyces cerevisiae - enzymology
Saccharomyces cerevisiae - genetics
Saccharomyces cerevisiae Proteins - biosynthesis
Saccharomyces cerevisiae Proteins - genetics
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Summary:A major challenge in systems biology lies in the integration of processes occurring at different levels, such as transcription, translation, and metabolism, to understand the functioning of a living cell in its environment. We studied the high temperature-induced glycolytic flux increase in Saccharomyces cerevisiae and investigated the regulatory mechanisms underlying this increase. We used glucose-limited chemostat cultures to separate regulatory effects of temperature from effects on growth rate. Growth at increased temperature (38 °C versus 30 °C) resulted in a strongly increased glycolytic flux, accompanied by a switch from respiration to a partially fermentative metabolism. We observed an increased flux through all enzymes, ranging from 5- to 10-fold. We quantified the contributions of direct temperature effects on enzyme activities, the gene expression cascade and shifts in the metabolic network, to the increased flux through each enzyme. To do this we adapted flux regulation analysis. We show that the direct effect of temperature on enzyme kinetics can be included as a separate term. Together with hierarchical regulation and metabolic regulation, this term explains the total flux change between two steady states. Surprisingly, the effect of the cultivation temperature on enzyme catalytic capacity, both directly through the Arrhenius effect and indirectly through adapted gene expression, is only a moderate contribution to the increased glycolytic flux for most enzymes. The changes in flux are therefore largely caused by changes in the interaction of the enzymes with substrates, products, and effectors.
ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M802908200