Mary Ann Osley

Hir Proteins Are Required for Position-Dependent Gene Silencing in Saccharomyces cerevisiae in the Absence of Chromatin Assembly Factor I

ABSTRACT Chromatin assembly factor I (CAF-I) is a three-subunit histone-binding complex conserved from the yeast Saccharomyces cerevisiae to humans. Yeast cells lacking CAF-I (cacΔ mutants) have defects in heterochromatic gene silencing. In this study, we showed that deletion of HIRgenes, which regulate histone gene expression, synergistically reduced gene silencing at telomeres and at the HM loci incacΔ mutants, although hirΔ mutants had no silencing defects when CAF-I was intact. Therefore, Hir proteins are required for an alternative silencing pathway that becomes important in the absence of CAF-I. Because Hir proteins regulate expression of histone genes, we tested the effects of histone gene deletion and overexpression on telomeric silencing and found that alterations in histone H3 and H4 levels or in core histone stoichiometry reduced silencing in cacΔ mutants but not in wild-type cells. We therefore propose that Hir proteins contribute to silencing indirectly via regulation of histone synthesis. However, deletion of combinations of CAC and HIR genes also affected the growth rate and in some cases caused partial temperature sensitivity, suggesting that global aspects of chromosome function may be affected by the loss of members of both gene families.

HIR1P AND HIR2P FUNCTION AS TRANSCRIPTIONAL COREPRESSORS TO REGULATE HISTONE GENE TRANSCRIPTION IN THE SACCHAROMYCES CEREVISIAE CELL CYCLE

The HIR/HPC (histone regulation/histone periodic control) negative regulators play important roles in the transcription of six of the eight core histone genes during the Saccharomyces cerevisiae cell cycle. The phenotypes of hir1 and hir2 mutants suggested that the wild-type HIR1 and HIR2 genes encode transcriptional repressors that function in the absence of direct DNA binding. When Hir1p and Hir2p were artificially tethered to yeast promoters, each protein repressed transcription, suggesting that they represent a new class of transcriptional corepressors. The two proteins might function as a complex in vivo: Hir2p required both Hir1p and another Hir protein, Hir3p, to repress transcription when it was tethered to an HTA1-lacZ reporter gene, and Hir1p and Hir2p could be coimmunoprecipitated from yeast cell extracts. Tethered Hir1p also directed the periodic transcription of the HTA1 gene and repressed HTA1 transcription in response to two cell cycle regulatory signals. Thus, it represents the first example of a transcriptional corepressor with a direct role in cell cycle-regulated transcription.

Characterization of HIR1 and HIR2, two genes required for regulation of histone gene transcription in Saccharomyces cerevisiae.

The products of the HIR1 and HIR2 genes have been defined genetically as repressors of histone gene transcription in S. cerevisiae. A mutation in either gene affects cell cycle regulation of three of the four histone gene loci; transcription of these loci occurs throughout the cell cycle and is no longer repressed in response to the inhibition of DNA replication. The same mutations also eliminate autogenous regulation of the HTA1-HTB1 locus by histones H2A and H2B. The HIR1 and HIR2 genes have been isolated, and their roles in the transcriptional regulation of the HTA1-HTB1 locus have been characterized. Neither gene encodes an essential protein, and null alleles derepress HTA1-HTB1 transcription. Both HIR genes are expressed constitutively under conditions that lead to repression or derepression of the HTA1 gene, and neither gene regulates the expression of the other. The sequence of the HIR1 gene predicts an 88-kDa protein with three repeats of a motif found in the G beta subunit of retinal transducin and in a yeast transcriptional repressor, Tup1. The sequence of the HIR2 gene predicts a protein of 98 kDa. Both gene products contain nuclear targeting signals, and the Hir2 protein is localized in the nucleus.

A Role for Transcriptional Repressors in Targeting the Yeast Swi/Snf Complex

Genetic and biochemical studies indicate that the evolutionarily conserved Swi/Snf complex acts at a subset of genes to help transcriptional activators function on chromatin templates. The mechanism by which this complex is targeted to specific chromosomal loci remains unknown. We show that Swi/Snf is required for expression of the yeast histone HTA1-HTB1 locus because of the role of Hir1p and Hir2p corepressors in negatively regulating transcription. Snf5p, Snf2p/Swi2p, and Swi3p, three components of the yeast Swi/Snf complex, coimmunoprecipitate with each Hir protein, and Snf5p is maximally associated with the HTA1-HTB1 promoter when the Hir-based repression system is intact and the Swi/Snf complex is functional. The data support a role for the Hir repressors in the gene-specific targeting of Swi/Snf.

Mutations in both the structured domain and N-terminus of histone H2B bypass the requirement for Swi-Snf in yeast.

The chromatin elements targeted by the ATPdependent, Swi–Snf nucleosome‐remodeling complex are unknown. To address this question, we generated mutations in yeast histone H2B that suppress phenotypes associated with the absence of Swi–Snf. Sin− (Swi–Snf‐independent) mutations occur in residues involved in H2A–H2B dimer formation, dimer–tetramer association, and in the H2B N‐terminus. The strongest and most pleiotropic Sin− mutation removed 20 amino acid residues from the H2B N‐terminus. This mutation allowed active chromatin to be formed at the SUC2 locus in a snf5Δ mutant and resulted in hyperactivated levels of SUC2 mRNA under inducing conditions. Thus, the H2B N‐terminus may be an important target of Swi–Snf in vivo. The GCN5 gene product, the catalytic subunit of several nuclear histone acetytransferase complexes that modify histone N‐termini, was also found to act in conjunction with Swi–Snf. The phenotypes of double gcn5Δsnf5Δ mutants suggest that histone acetylation may play both positive and negative roles in the activity of the Swi–Snf‐remodeling factor.

Functional analysis of histones H2A and H2B in transcriptional repression in Saccharomyces cerevisiae.

The presence of H2A-H2B dimers in nucleosomes can inhibit the binding of transcription factors to chromatin templates. To study the roles of histones H2A and H2B in transcriptional repression in vivo, mutant forms of these histones were analyzed in two different assay systems. Two repression domains were identified in H2A. One domain includes residues that fall in the beginning of the H2A-H2B dimerization region, and the second is in the H2A N terminus, a region of potential interactions with nonhistone proteins. The function of H2A and H2B in one repression assay was found to be dependent on three SPT (suppressor of Ty) genes whose products are important for chromatin-mediated repression. These results suggest that repressive chromatin structure may be established through the interactions of the Spt proteins with these histones. In contrast, other proteins, the products of the HIR (histone regulation) genes, may function to direct H2A and H2B to specific promoters.