Yeast Ku protein plays a direct role in telomeric silencing and counteracts inhibition by rif proteins

The molecular biology of the SIR proteins

Silent or heritably repressed genes constitute the major fraction of genetic information in higher eukaryotic cells. Budding yeast has very little consecutively repressed DNA, but what exists has served as a paradigm for the molecular analysis of heterochromatin. The major structural constituents of repressed chromatin in yeast are the four core histones and three large chromatin factors called Silent information regulators 2, 3 and 4. How these components assemble DNA into a state that is refractory to transcription remains a mystery. Nonetheless, there have been many recent insights into their molecular structures. This review examines the impact of these results on our understanding of silencing function in budding yeast.

Transcriptional silencing: replication redux

Recent studies indicate that, contrary to long-held belief, DNA replication does not have a direct role in transcriptional silencing, but progression through S phase of the cell cycle is nevertheless required for the establishment of silent chromatin.

Prokaryotic homologs of the eukaryotic DNA-end-binding protein Ku, novel domains in the Ku protein and prediction of a prokaryotic double-strand break repair system

Homologs of the eukaryotic DNA-end-binding protein Ku were identified in several bacterial and one archeal genome using iterative database searches with sequence profiles. Identification of prokaryotic Ku homologs allowed the dissection of the Ku protein sequences into three distinct domains, the Ku core that is conserved in eukaryotes and prokaryotes, a derived von Willebrand A domain that is fused to the amino terminus of the core in eukaryotic Ku proteins, and the newly recognized helix-extension-helix (HEH) domain that is fused to the carboxyl terminus of the core in eukaryotes and in one of the Ku homologs from the Actinomycete Streptomyces coelicolor. The version of the HEH domain present in eukaryotic Ku proteins represents the previously described DNA-binding domain called SAP. The Ku homolog from S. coelicolor contains a distinct version of the HEH domain that belongs to a previously unnoticed family of nucleic-acid-binding domains, which also includes HEH domains from the bacterial transcription termination factor Rho, bacterial and eukaryotic lysyl-tRNA synthetases, bacteriophage T4 endonuclease VII, and several uncharacterized proteins. The distribution of the Ku homologs in bacteria coincides with that of the archeal-eukaryotic-type DNA primase and genes for prokaryotic Ku homologs form predicted operons with genes coding for an ATP-dependent DNA ligase and/or archeal-eukaryotic-type DNA primase. Some of these operons additionally encode an uncharacterized protein that may function as nuclease or an Slx1p-like predicted nuclease containing a URI domain. A hypothesis is proposed that the Ku homolog, together with the associated gene products, comprise a previously unrecognized prokaryotic system for repair of double-strand breaks in DNA.

Turning telomeres off and on

We envision multiple steps in telomere maintenance, based largely on genetic data from budding yeast. First, the telomere must unfold or open itself such that the free end is accessible to the appropriate enzymatic machinery. Second, telomerase must be recruited, together with the DNA replication machinery that synthesizes the C-rich strand. The processivity of telomerase is regulated both by a length-sensing feedback mechanism and by second-strand synthesis. Finally, the telosome refolds into a protective end structure. If telomerase is nonfunctional, recombination may occur once telomeres are open. Multiple pathways regulate these different steps, producing a highly dynamic chromosomal cap.

Telomeric chromatin: replicating and wrapping up chromosome ends

Recent advances in our understanding of the specialized chromatin structure at telomeres, the ends of eukaryotic chromosomes, have focused on three separate areas: replication of telomeres through the coordinated action of conventional DNA polymerases and the telomerase enzyme, protection of the chromosome end from DNA damage checkpoint sensors and DNA-repair processes, and the discovery of a novel deacetylase enzyme (Sir2p) required for the establishment and maintenance of telomeric heterochromatin. Although the number of proteins and the complexity of their interactions at telomeres continues to grow, a picture of at least some of the major players and mechanisms underlying telomere replication, end 'capping' and chromatin assembly is beginning to emerge.

Ku-deficient yeast strains exhibit alternative states of silencing competence

In Saccharomyces cerevisiae, efficient silencer function requires telomere proximity, i.e. compartments of the nucleoplasm enriched in silencing factors. Accordingly, silencers located far from telomeres function inefficiently. We show here that cells lacking yKu balance between two mitotically stable states of silencing competence. In one, a partial delocalization of telomeres and silencing factors throughout the nucleoplasm correlates with enhanced silencing at a non-telomeric locus, while in the other, telomeres retain their focal pattern of distribution and there is no repression at the non-telomeric locus, as observed in wild-type cells. The two states also differ in their level of residual telomeric silencing. These findings indicate the existence of a yKu-independent pathway of telomere clustering and Sir localization. Interestingly, this pathway appears to be under epigenetic control.

Cdc13 cooperates with the yeast Ku proteins and Stn1 to regulate telomerase recruitment

The Saccharomyces cerevisiae CDC13 protein binds single-strand telomeric DNA. Here we report the isolation of new mutant alleles of CDC13 that confer either abnormal telomere lengthening or telomere shortening. This deregulation not only depended on telomerase (Est2/TLC1) and Est1, a direct regulator of telomerase, but also on the yeast Ku proteins, yKu70/Hdf1 and yKu80/Hdf2, that have been previously implicated in DNA repair and telomere maintenance. Expression of a Cdc13-yKu70 fusion protein resulted in telomere elongation, similar to that produced by a Cdc13-Est1 fusion, thus suggesting that yKu70 might promote Cdc13-mediated telomerase recruitment. We also demonstrate that Stn1 is an inhibitor of telomerase recruitment by Cdc13, based both on STN1 overexpression and Cdc13-Stn1 fusion experiments. We propose that accurate regulation of telomerase recruitment by Cdc13 results from a coordinated balance between positive control by yKu70 and negative control by Stn1. Our results represent the first evidence of a direct control of the telomerase-loading function of Cdc13 by a double-strand telomeric DNA-binding complex.

DNA ends: maintenance of chromosome termini versus repair of double strand breaks

This review focuses on the factors that define the differences between the two types of DNA ends encountered by eukaryotic cells: telomeres and double strand breaks (DSBs). Although these two types of DNA termini are functionally distinct, recent studies have shown that a number of proteins is shared at telomeres and sites of DSB repair. The significance of these common components is discussed, as well as the types of DNA repair events that can compensate for a defective telomere.

A sense of the end

How a cell distinguishes a double-strand break from the end of a chromosome has long fascinated cell biologists. It was thought that the protection of chromosomal ends required either a telomere-specific complex or the looping back of the 3' TG-rich overhang to anneal with a homologous double-stranded repeat. These models must now accommodate the findings that complexes involved in nonhomologous end joining play important roles in normal telomere length maintenance, and that subtelomeric chromatin changes in response to the DNA damage checkpoint. A hypothetical chromatin assembly checkpoint may help to explain why telomeres and the double-strand break repair machinery share essential components.

The dynamics of yeast telomeres and silencing proteins through the cell cycle

Genes integrated near the telomeres of budding yeast have a variegated pattern of gene repression that is mediated by the silent information regulatory proteins Sir2p, Sir3p, and Sir4p. Immunolocalization and fluorescence in situ hybridization (FISH) reveal 6-10 perinuclear foci in which silencing proteins and subtelomeric sequences colocalize, suggesting that these are sites of Sir-mediated repression. Telomeres lacking subtelomeric repeat elements and the silent mating locus, HML, also localize to the periphery of the nucleus. Conditions that disrupt telomere proximal repression disrupt the focal staining pattern of Sir proteins, but not necessarily the localization of telomeric DNA. To monitor the telomere-associated pools of heterochromatin-binding proteins (Sir and Rap1 proteins) during mitotic cell division, we have performed immunofluorescence and telomeric FISH on populations of yeast cells synchronously traversing the cell cycle. We observe a partial release of Rap1p from telomeres in late G2/M, although telomeres appear to stay clustered during G2-phase and throughout mitosis. A partial release of Sir3p and Sir4p during mitosis also occurs. This is not observed upon HU arrest, although other types of DNA damage cause a dramatic relocalization of Sir and Rap1 proteins. The observed cell cycle dynamics were confirmed by direct epifluorescence of a GFP-Rap1p fusion. Using live GFP fluorescence we show that the diffuse mitotic distribution of GFP-Rap1p is restored to the interphase pattern of foci in early G1-phase.

The Sir proteins of Saccharomyces cerevisiae: mediators of transcriptional silencing and much more

The Sir2, Sir3, and Sir4 proteins of the yeast Saccharomyces cerevisiae elicit transcriptional silencing by forming repressive chromatin structures that are confined to specific chromosomal domains. Recent discoveries establish new and unexpected roles for the proteins in seemingly unrelated arenas of chromosome biology, including double-strand break repair, structure and function of the nucleolus, aging, cell cycle regulation, and checkpoint control.