TitleNutritional homeostasis in batch and steady-state culture of yeast.
Publication TypeJournal Article
Year of Publication2004
AuthorsSaldanha, AJ, Brauer, MJ, Botstein, D
JournalMol Biol Cell
Volume15
Issue9
Pagination4089-104
Date Published2004 Sep
KeywordsAmino Acids, Cell Cycle, Culture Media, Gene Expression Profiling, Genes, Fungal, Genomics, Homeostasis, Leucine, Oligonucleotide Array Sequence Analysis, Phosphates, Ribosomal Proteins, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins, Sulfates, Uracil
Abstract

We studied the physiological response to limitation by diverse nutrients in batch and steady-state (chemostat) cultures of S. cerevisiae. We found that the global pattern of transcription in steady-state cultures in limiting phosphate or sulfate is essentially identical to that of batch cultures growing in the same medium just before the limiting nutrient is completely exhausted. The massive stress response and complete arrest of the cell cycle that occurs when nutrients are fully exhausted in batch cultures is not observed in the chemostat, indicating that the cells in the chemostat are "poor, not starving." Similar comparisons using leucine or uracil auxotrophs limited on leucine or uracil again showed patterns of gene expression in steady-state closely resembling those of corresponding batch cultures just before they exhaust the nutrient. Although there is also a strong stress response in the auxotrophic batch cultures, cell cycle arrest, if it occurs at all, is much less uniform. Many of the differences among the patterns of gene expression between the four nutrient limitations are interpretable in light of known involvement of the genes in stress responses or in the regulation or execution of particular metabolic pathways appropriate to the limiting nutrient. We conclude that cells adjust their growth rate to nutrient availability and maintain homeostasis in the same way in batch and steady state conditions; cells in steady-state cultures are in a physiological condition normally encountered in batch cultures.

Alternate JournalMol. Biol. Cell