Sir1p is one of four SIR (silent information regulator) proteins required for silencing the cryptic mating-type locus HMRa in the budding yeast Saccharomyces cerevisiae. A Sir1p interaction with Orc1p, the largest subunit of the origin recognition complex (ORC), is critical for Sir1p's ability to bind HMRa and function in the formation of silent chromatin. Here we show that a discrete domain within Sir1p, the ORC interaction region (OIR), was necessary and sufficient for a Sir1p-ORC interaction. The OIR contains the originally defined silencer recognition-defective region as well as additional amino acids. In addition, a Sir1p-Sir4p interaction required a larger region of Sir1p that included the OIR. Amino acid substitutions causing defects in either a Sir1p-Orc1p or a Sir1p-Sir4p interaction reduced HMRa silencing and Sir1p binding to HMRa in chromatin. These data support a model in which Sir1p's association with HMRa is mediated by separable Sir1p-ORC and Sir1p-Sir4p interactions requiring a common Sir1p domain, and they indicate that a Sir1p-ORC interaction is restricted to silencers, at least in part, through interactions with Sir4p.
The SIR1 gene is one of four specialized genes in Saccharomyces cerevisiae required for repressing transcription at the silent mating-type cassettes, HMLα and HMRa, by a mechanism known as silencing. Silencing requires the assembly of a specialized chromatin structure analogous to heterochromatin. FKH1 was isolated as a gene that, when expressed in multiple copies, could substitute for the function of SIR1 in silencing HMRa. FKH1 (Forkhead Homologue One) was named for its homology to the forkhead family of eukaryotic transcription factors classified on the basis of a conserved DNA binding domain. Deletion of FKH1 caused a defect in silencing HMRa, indicating that FKH1 has a positive role in silencing. Significantly, deletion of both FKH1 and its closest homologue in yeast, FKH2, caused a form of yeast pseudohyphal growth, indicating that the two genes have redundant functions in controlling yeast cell morphology. By several criteria, fkh1Δ fkh2Δ-induced pseudohyphal growth was distinct from the nutritionally induced form of pseudohyphal growth observed in some strains of S. cerevisiae. Although FKH2 is redundant with FKH1 in controlling pseudohyphal growth, the two genes have different functions in silencing HMRa. High-copy expression of CLB2, a G2/M-phase cyclin, prevented fkh1Δ fkh2Δ-induced pseudohyphal growth and modulated some of the fkhΔ-induced silencing phenotypes. Interestingly, deletions in either FKH1 or FKH2 alone caused subtle but opposite effects on cell-cycle progression and CLB2 mRNA expression, consistent with a role for each of these genes in modulating the cell cycle and having opposing effects on silencing. The differences between Fkh1p and Fkh2p in vivo were not attributable to differences in their DNA binding domains.
The yeast Sir1 protein's ability to bind and silence the cryptic mating-type locus HMRa requires a proteinprotein interaction between Sir1 and the origin recognition complex (ORC). A domain within the C-terminal half of Sir1, the Sir1 ORC interaction region (Sir1OIR), and the conserved bromo-adjacent homology (BAH) domain within Orc1, the largest subunit of ORC, mediate this interaction. The structure of the Sir1OIR-Orc1BAH complex is known. Sir1OIR and Orc1BAH interacted with a high affinity in vitro, but the Sir1OIR did not inhibit Sir1-dependent silencing when overproduced in vivo, suggesting that other regions of Sir1 helped it bind HMRa. Comparisons of diverged Sir1 proteins revealed two highly conserved regions, N1 and N2, within Sir1's poorly characterized N-terminal half. An N-terminal portion of Sir1 (residues 27 to 149 [Sir1 ]) is similar in sequence to the Sir1OIR; homology modeling predicted a structure for Sir1 27-149 in which N1 formed a submodule similar to the known Orc1BAH-interacting surface on Sir1. Consistent with these findings, two-hybrid assays indicated that the Sir1 N terminus could interact with BAH domains. Amino acid substitutions within or near N1 or N2 reduced full-length Sir1's ability to bind and silence HMRa and to interact with Orc1BAH in a two-hybrid assay. Purified recombinant Sir1 formed a large protease-resistant structure within which the Sir1OIR domain was protected, and Orc1BAH bound Sir1OIR more efficiently than full-length Sir1 in vitro. Thus, the Sir1 N terminus exhibited both positive and negative roles in the formation of a Sir1-ORC silencing complex. This functional duality might contribute to Sir1's selectivity for silencerbound ORCs in vivo.Chromatin, the protein-DNA complex that comprises eukaryotic chromosomes, varies substantially with chromosomal position, and this structural heterogeneity is fundamental to genome function. A central question in chromosome biology concerns the mechanisms that establish this structural variation in the genome. Silencing of the cryptic mating-type locus HMRa in budding yeast is a powerful model for examining mechanisms that target and confine the formation of a specialized form of chromatin to specific regions of the genome (20,46). Silencing is caused by the formation of "silent" chromatin that is analogous to metazoan heterochromatin, causing heritable, position-dependent transcriptional repression, delayed replication time, and inaccessibility of the chromosomal DNA to a variety of DNA-modifying enzymes (46). Silent chromatin is targeted to HMRa by protein-DNA and protein-protein interactions that require the origin recognition complex (ORC) (20), the evolutionarily conserved multisubunit protein complex best known for its role in the initiation of eukaryotic DNA replication (2). ORC, along with additional sequence-specific DNA-binding proteins Rap1 and Abf1, binds to a small, ϳ150-bp DNA sequence element called the HMR-E silencer. HMR-E is both necessary and sufficient to nucleate assembly of a silent chromatin domain that ...
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