In Saccharomyces cerevisiae, transcriptional silencing occurs at three classes of genomic regions: near the telomeres, at the silent mating type loci, and within the ribosomal DNA (rDNA) repeats. In all three cases, silencing depends upon several factors, including specific types of histone modifications. In this work we have investigated the roles in silencing for Spt10 and Spt21, two proteins previously shown to control transcription of particular histone genes. Building on a recent study showing that Spt10 is required for telomeric silencing, our results show that in both spt10 and spt21 mutants, silencing is reduced near telomeres and at HML␣, while it is increased at the rDNA. Both spt10 and spt21 mutations cause modest effects on Sir protein recruitment and histone modifications at telomeric regions, and they cause significant changes in chromatin structure, as judged by its accessibility to dam methylase. These silencing and chromatin changes are not seen upon deletion of HTA2-HTB2, the primary histone locus regulated by Spt10 and Spt21. These results suggest that Spt10 and Spt21 control silencing in S. cerevisiae by altering chromatin structure through roles beyond the control of histone gene expression.Changes in chromatin state modulate gene expression. These changes can involve alterations in the composition of bound proteins, the positions or presence of nucleosomes, the array of covalent modifications on histones, or higher-order chromatin structure (reviewed in references 11, 41, and 60). In Saccharomyces cerevisiae, one form of specialized chromatin structure exists in silenced regions, where genomic regions are packaged into a repressive state characterized by hypoacetylated histone proteins (reviewed in references 17 and 59). In these regions, gene expression is silenced as a consequence of location, largely independent of promoter composition (59).In S. cerevisiae, silencing occurs at three loci: subtelomeric regions (telomere position effect [TPE]), the silent mating type loci HMRa and HML␣, and the ribosomal DNA (rDNA) repeats (reviewed in references 7 and 59). Silencing at telomeres and silencing at the mating type loci show many similarities, including a requirement for the silent information regulator (Sir) proteins Sir2, Sir3, and Sir4. At the silent mating type loci, Sir1 plays an additional role in facilitating recruitment of the other Sir proteins, though it is not essential for silencing (54,78). Silencing at the rDNA locus is unique in that Sir2 is the only Sir protein required for silencing. Furthermore, at the rDNA, sir4⌬ mutants show an increase in silencing (66).Silencing occurs in three steps: nucleation, spreading, and limitation of spreading. Nucleation is seeded by sequencespecific DNA binding complexes, including Rap1 at telomeres (45, 49) and Rap1, Abf1, and ORC at the silent mating type loci (44,49,78). These complexes recruit Sir2, Sir3, and Sir4. Sir complex binding is facilitated by hypoacetylation of the histone H3 and H4 tails, which is accomplished by the NAD ϩ -depe...
