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Phenotypic characterization of glucose repression mutants of Saccharomyces cerevisiae using experiments with 13 C‐labelled glucose
Author(s) -
Raghevendran Vijayendran,
Gombert Andreas Karoly,
Christensen Bjarke,
Kötter Peter,
Nielsen Jens
Publication year - 2004
Publication title -
yeast
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.923
H-Index - 102
eISSN - 1097-0061
pISSN - 0749-503X
DOI - 10.1002/yea.1136
Subject(s) - saccharomyces cerevisiae , biology , mutant , phenotype , yeast , functional genomics , gene , biochemistry , metabolic pathway , function (biology) , metabolic engineering , genetics , genome , genomics
In the field of metabolic engineering and functional genomics, methods for analysis of metabolic fluxes in the cell are attractive as they give an overview of the phenotypic response of the cells at the level of the active metabolic network. This is unlike several other high‐throughput experimental techniques, which do not provide information about the integrated response a specific genetic modification has on the cellular function. In this study we have performed phenotypic characterization of several mutants of the yeast Saccharomyces cerevisiae through the use of experiments with 13 C‐labelled glucose. Through GC–MS analysis of the 13 C incorporated into the amino acids of cellular proteins, it was possible to obtain quantitative information on the function of the central carbon metabolism in the different mutants. Traditionally, such labelling data have been used to quantify metabolic fluxes through the use of a suitable mathematical model, but here we show that the raw labelling data may also be used directly for phenotypic characterization of different mutant strains. Different glucose derepressed strains investigated employed are the disruption mutants reg1, hxk2, grr1, mig1 and mig1mig2 and the reference strain CEN.PK113‐7D. Principal components analysis of the summed fractional labelling data show that deleting the genes HXK2 and GRR1 results in similar phenotype at the fluxome level, with a partial alleviation of glucose repression on the respiratory metabolism. Furthermore, deletion of the genes MIG1, MIG1/MIG2 and REG1 did not result in a significant change in the phenotype at the fluxome level. Copyright © 2004 John Wiley & Sons, Ltd.