The multi-KH domain protein of Saccharomyces cerevisiae Scp160p contributes to the regulation of telomeric silencing

Multi-KH domain proteins are highly evolutionarily conserved proteins that associate to polyribosomes and participate in RNA metabolism. Recent evidence indicates that multi-KH domain proteins also contribute to the structural organization of heterochromatin both in mammals and Drosophila. Here, we show that the multi-KH domain protein of Saccharomyces cerevisiae, Scp160p, contributes to silencing at telomeres and at the mating-type locus, but not to ribosomal silencing. The contribution of Scp160p to silencing is independent of its binding to the ribosome as deletion of the last two KH domains, which mediate ribosomal binding, has no effect on silencing. Disruption of SCP160 increases cell ploidy but this effect is also independent of the contribution of Scp160p to telomeric silencing as strong relief of silencing is observed in Deltascp160 cells with normal ploidy and, vice versa, Deltascp160 cells with highly increased ploidy show no significant silencing defects. The TPE phenotype of Deltascp160 cells associates to a decreased Sir3p deposition at telomeres and, in good agreement, silencing is rescued by SIR3 overexpression and in a Deltarif1Deltarif2 mutant. Scp160p shows a distinct perinuclear localization that is independent of its ability to bind ribosomes. Moreover, telomere clustering at the nuclear envelope is perturbed in Deltascp160 cells and disruption of the histone deacetylase RPD3, which is known to improve telomere clustering, rescues telomeric silencing in Deltascp160 cells. These results are discussed in the context of a model in which Scp160p contributes to silencing by helping telomere clustering.     

A methyltransferase targeting assay reveals silencer-telomere interactions in budding yeast

We have designed a modified version of the Dam identification technique and used it to probe higher-order chromatin structure in Saccharomyces cerevisiae. We fused the bacterial DNA methyltransferase Dam to the DNA-binding domain of TetR and targeted the resulting chimera to Tet operators inserted in the yeast genome at the repressed locus HML. We then monitored the methylation status of HML and other sequences by a quantitative technique combining methylation-sensitive restriction and real-time PCR. As expected, we found that TetR-Dam efficiently methylated HML in cis. More strikingly, when TetR-Dam was present at HML, we observed increased methylation in the III-L subtelomeric region but not in intervening sequences. This effect was lost when the HML silencers were inactivated by mutations. When the HM silencers and the Tet operators were transferred to a plasmid, strong methylation was clearly observed not only in the III-L subtelomeric region but also at other telomeres. These data indicate that HM silencers can specifically associate with telomeres, even those located on different chromosomes.     

Dot1 and histone H3K79 methylation in natural telomeric and HM silencing

The expression of genes residing near telomeres is attenuated through telomere position-effect variegation (TPEV). By using a URA3 reporter located at TEL-VII-L of Saccharomyces cerevisiae, it was proposed that the disruptor of telomeric silencing-1 (Dot1) regulates TPEV by catalyzing H3K79 methylation. URA3 reporter assays also indicated that H3K79 methylation is required for HM silencing. Surprisingly, a genome-wide expression analysis of H3K79 methylation-defective mutants identified only a few telomeric genes, such as COS12 at TEL-VII-L, to be subject to H3K79 methylation-dependent natural silencing. Consistently, loss of Dot1 did not globally alter Sir2 or Sir3 occupancy in subtelomeric regions, but only led to some telomere-specific changes. Furthermore, H3K79 methylation by Dot1 did not play a role in the maintenance of natural HML silencing. Therefore, commonly used URA3 reporter assays may not report on natural PEV, and therefore, studies concerning the epigenetic mechanism of silencing in yeast should also employ assays reporting on natural gene expression patterns.     

Efficient production of a ring derivative of chromosome III by the mating-type switching mechanism in Saccharomyces cerevisiae.

The mating-type switches in the yeast Saccharomyces cerevisiae occur by unidirectional transposition of replicas of unexpressed genetic information, residing at HML or HMR, into the mating-type locus (MAT). The source loci, HML and HMR, remain unchanged. Interestingly, when the HM cassettes are expressed, as in marl strains, the HML and HMR cassettes can also efficiently switch, apparently by obtaining genetic information from either of the other two cassettes (Klar et al., Cell 25:517-524, 1981). We have isolated a novel chromosome III rearrangement in heterothallic (marl ho) strains, which is also produced efficiently in marl HO cells, presumably the consequence of a recombination event between HML and HMR. The fusion results in the loss of sequences which are located distal to HML and to HMR and produces a ring derivative of chromosome III. Cells containing such a ring chromosome are viable as haploids; apparently, no essential loci are located distal to the HM loci. The fusion cassette behaves as a standard HM locus with respect to both regulation by the MAR/SIR control and its role in switching MAT.