Non-random clustering of stress-related genes during evolution of the S. cerevisiae genome.

BACKGROUND: Coordinately regulated genes often physically cluster in eukaryotic genomes, for reasons that remain unclear. RESULTS: Here we provide evidence that many S. cerevisiae genes induced by starvation and other stresses reside in non-random clusters, where transcription of these genes is repressed in the absence of stress. Most genes essential for growth or for rapid, post-transcriptional responses to stress in cycling cells map between these gene clusters. Genes that are transcriptionally induced by stresses include a large fraction of rapidly evolving paralogues of duplicated genes that arose during an ancient whole genome duplication event. Many of these rapidly evolving paralogues have acquired new or more specialized functions that are less essential for growth. The slowly evolving paralogues of these genes are less likely to be transcriptionally repressed in the absence of stress, and are frequently essential for growth or for rapid stress responses that may require constitutive expression of these genes in cycling cells. CONCLUSION: Our findings suggest that a fundamental organizing principle during evolution of the S. cerevisiae genome has been clustering of starvation and other stress-induced genes in chromosome regions that are transcriptionally repressed in the absence of stress, from which most genes essential for growth or rapid stress responses have been excluded. Chromatin-mediated repression of many stress-induced genes may have evolved since the whole genome duplication in parallel with functions for proteins encoded by these genes that are incompatible with growth. These functions likely provide fitness effects that escape detection in assays of reproductive capacity routinely employed to assess evolutionary fitness, or to identify genes that confer stress-resistance in cycling cells.

Evidence for ORC-dependent repression of budding yeast genes induced by starvation and other stresses.

The highly conserved origin recognition complex (ORC) is required for repressing genes in the silent mating type loci of budding yeast. Here we report that at a non-permissive temperature, the temperature-sensitive orc2-1 mutation induces the expression of more than 500 genes, the majority of which are also induced during starvation of wild-type cells. Many genes induced by starvation or by the orc2-1 mutation are also induced by inactivation of proteins required for chromatin-mediated repression of transcription. Genes induced by the orc2-1 mutation, starvation, or inactivation of repressor proteins, map near ORC-binding loci significantly more frequently compared to all genes. Genes repressed by starvation map near ORC-binding sites less frequently compared to all genes, which suggests they have been evolutionarily excluded from regions of repressive chromatin near ORC-binding sites. Deletion of sequences containing ORC-binding sites near the DAL2 and DAL4 genes in the DAL gene cluster, which are induced by either the orc2-1 mutation or by starvation, constitutively activates these genes and abolishes their activation by the orc2-1 mutation. Our findings suggest a role for ORC in the repression of a large number of budding yeast genes induced by starvation or other aspects of a deleterious environment.

A comparison of the aging and apoptotic transcriptome of Saccharomyces cerevisiae.

In this paper, we present the results of global transcript analysis by the microarray technique of senescent and apoptotic yeast cells. We compared young daughter and old mother cells isolated by elutriation centrifugation, and non-apoptotic and apoptotic cells induced either by a temperature shift of the cdc48(S565G) temperature-sensitive mutant or of the orc2-1 temperature-sensitive mutant. The majority of all genes found to be differentially regulated in these three physiological situations was upregulated, indicating that a cellular death process was initiated rather than an unspecific shut-down of gene expression due to immediate killing. The functional classes of genes upregulated in all three conditions were largely the same, although individual genes were in many cases not identical. The largest group of genes involved were nuclear genes coding for mitochondrial components or functions, which is understandable given the fact that apoptosis can be triggered by mitochondrially generated oxygen radicals and that mitochondria play an important role in the execution of apoptosis. Other functional classes consisted of genes involved in DNA damage response, in cell cycle regulation and checkpoints, in DNA repair, and in membrane lipid and cell wall synthesis. These functional classes represent the response of the cell to the known cellular insults, which occur during aging and apoptosis. As we have shown previously, final-stage senescent yeast mother cells (of the wild-type) are apoptotic.