Separation-of-function mutants of yeast Ku80 reveal a Yku80p-Sir4p interaction involved in telomeric silencing

yKu70/yKu80 and Rif1 regulate silencing differentially at telomeres in Candida glabrata

Candida glabrata, a common opportunistic fungal pathogen, adheres efficiently to mammalian epithelial cells in culture. This interaction in vitro depends mainly on the adhesin Epa1, one of a large family of cell wall proteins. Most of the EPA genes are located in subtelomeric regions, where they are transcriptionally repressed by silencing. In order to better characterize the transcriptional regulation of the EPA family, we have assessed the importance of C. glabrata orthologues of known regulators of subtelomeric silencing in Saccharomyces cerevisiae. To this end, we used a series of strains containing insertions of the reporter URA3 gene within different intergenic regions throughout four telomeres of C. glabrata. Using these reporter strains, we have assessed the roles of SIR2, SIR3, SIR4, HDF1 (yKu70), HDF2 (yKu80), and RIF1 in mediating silencing at four C. glabrata telomeres. We found that, whereas the SIR proteins are absolutely required for silencing of the reporter genes and the native subtelomeric EPA genes, the Rif1 and the Ku proteins regulate silencing at only a subset of the analyzed telomeres. We also mapped a cis element adjacent to the EPA3 locus that can silence a reporter gene when placed at a distance of 31 kb from the telomere. Our data show that silencing of the C. glabrata telomeres varies from telomere to telomere. In addition, recruitment of silencing proteins to the subtelomeres is likely, for certain telomeres, to depend both on the telomeric repeats and on particular discrete silencing elements.

The DNA end-binding protein Ku regulates silencing at the internal HML and HMR loci in Saccharomyces cerevisiae

Heterochromatin resides near yeast telomeres and at the cryptic mating-type loci, HML and HMR, where it silences transcription of the alpha- and a-mating-type genes, respectively. Ku is a conserved DNA end-binding protein that binds telomeres and regulates silencing in yeast. The role of Ku in silencing is thought to be limited to telomeric silencing. Here, we tested whether Ku contributes to silencing at HML or HMR. Mutant analysis revealed that yKu70 and Sir1 act collectively to silence the mating-type genes at HML and HMR. In addition, loss of yKu70 function leads to expression of different reporter genes inserted at HMR. Quantitative chromatin-immunoprecipitation experiments revealed that yKu70 binds to HML and HMR and that binding of Ku to these internal loci is dependent on Sir4. The interaction between yKu70 and Sir4 was characterized further and found to be dependent on Sir2 but not on Sir1, Sir3, or yKu80. These observations reveal that, in addition to its ability to bind telomeric DNA ends and aid in the silencing of genes at telomeres, Ku binds to internal silent loci via protein-protein interactions and contributes to the efficient silencing of these loci.

The Ku complex in silencing the cryptic mating-type loci of Saccharomyces cerevisiae

Sir1 establishes transcriptional silencing at the cryptic mating-type loci HMR and HML (HM loci) by recruiting the three other Sir proteins, Sir2, -3, and -4, that function directly in silenced chromatin. However, SIR1-independent mechanisms also contribute to recruiting the Sir2-4 proteins to the HM loci. A screen to elucidate SIR1-independent mechanisms that establish HMR silencing identified a mutation in YKU80. The role for Ku in silencing both HMR and HML was masked by SIR1. Ku's role in silencing the HM loci was distinct from its shared role with the nuclear architecture protein Esc1 in tethering the HM loci and telomeres to the nuclear periphery. The ability of high-copy SIR4 to rescue HMR silencing defects in sir1Delta cells required Ku, and chromatin immunoprecipitation (ChIP) experiments provided evidence that Ku contributed to Sir4's physical association with the HM loci in vivo. Additional ChIP experiments provided evidence that Ku functioned directly at the HM loci. Thus Ku and Sir1 had overlapping roles in silencing the HM loci.

Composition of plant telomeres

Telomeres are essential elements of eukaryotic chromosomes that differentiate native chromosome ends from deleterious DNA double-strand breaks (DSBs). This is achieved by assembling chromosome termini in elaborate high-order nucleoprotein structures that in most organisms encompass telomeric DNA, specific telomere-associated proteins as well as general chromatin and DNA repair factors. Although the individual components of telomeric chromatin are evolutionary highly conserved, cross species comparisons have revealed a remarkable flexibility in their utilization at telomeres. This review outlines the strategies used for chromosome end protection and maintenance in mammals, yeast and flies and discusses current progress in deciphering telomere structure in plants.

Distinct faces of the Ku heterodimer mediate DNA repair and telomeric functions

The Ku heterodimer, comprised of Ku70 and Ku80 subunits, is a conserved complex involved in nonhomologous end-joining (NHEJ). However, it also functions in maintenance of telomeres, chromosome termini normally resistant to end-joining events. To elucidate the spatial organization of these functions, we rationally guided Ku mutagenesis in yeast with real-valued evolutionary trace (rvET). This revealed two ancestrally related alpha-helices: one on the Ku70 surface that is required in yeast for NHEJ, and a second on the Ku80 surface that is required in yeast for telomeric heterochromatin formation. When bound to a DNA end, the surface containing the NHEJ-specific Ku70 helix is oriented toward the DNA terminus, whereas the surface containing the telomeric function-specific Ku80 helix faces inward, toward telomeric chromatin, when bound to a telomere. We propose a 'two-face' model for Ku and that divergent evolution of these faces allowed Ku's dual role in NHEJ and telomere maintenance.

Telomere-length regulation in inter-ecotype crosses of Arabidopsis

Telomeres, the nucleoprotein complexes at the ends of eukaryotic chromosomes, are maintained at a species-specific equilibrium length. Arabidopsis thaliana is a self-fertilizing plant and different geographical isolates or ecotypes show differing telomere-lengths. We have exploited this telomere-length polymorphism between Arabidopsis ecotypes to investigate the genetic regulation of telomere length by analysing telomere lengths in 16 different inter-ecotype crosses between plants with differing telomere sizes. With two exceptions, the inter-ecotype hybrid plants present a new telomere-length set point, intermediate between that of the two parents. A regulation mechanism thus shortens the longer and lengthens the shorter telomeres.

Roles of nonhomologous end-joining pathways in surviving topoisomerase II-mediated DNA damage

Topoisomerase II is a target for clinically active anticancer drugs. Drugs targeting these enzymes act by preventing the religation of enzyme-DNA covalent complexes leading to protein-DNA adducts that include single- and double-strand breaks. In mammalian cells, nonhomologous repair pathways are critical for repairing topoisomerase II-mediated DNA damage. Because topoisomerase II-targeting agents, such as etoposide, can also induce chromosomal translocations that can lead to secondary malignancies, understanding nonhomologous repair of topoisomerase II-mediated DNA damage may help to define strategies that limit this critical side effect on an important class of anticancer agents. Using Saccharomyces cerevisiae as a model eukaryote, we have determined the contribution of genes required for nonhomologous end-joining (NHEJ) for repairing DNA damage arising from treatment with topoisomerase II poisons, such as etoposide and 4'-(9-acridinylamino)methanesulfon-m-anisidide (mAMSA). To increase cellular sensitivity to topoisomerase II poisons, we overexpressed either wild-type or drug-hypersensitive alleles of yeast topoisomerase II. Using this approach, we found that yku70 (hdf1), yku80 (hdf2), and other genes required for NHEJ were important for cell survival following exposure to etoposide. The clearest increase in sensitivity was observed with cells overexpressing an etoposide-hypersensitive allele of TOP2 (Ser740Trp). Hypersensitivity was also seen in some end-joining defective mutants exposed to the intercalating agent mAMSA, although the increase in sensitivity was less pronounced. To confirm that the increase in sensitivity was not solely due to the elevated expression of TOP2 or due to specific effects of the drug-hypersensitive TOP2 alleles, we also found that deletion of genes required for NHEJ increased the sensitivity of rad52 deletions to both etoposide and mAMSA. Taken together, these results show a clear role for NHEJ in the repair of DNA damage induced by topoisomerase II-targeting agents and suggest that this pathway may participate in translocations generated by drugs, such as etoposide.

The nuclear GTPase Gsp1p can affect proper telomeric function through the Sir4 protein inSaccharomyces cerevisiae

The small Ras-like GTPase Ran/Gsp1p is a highly conserved nuclear protein required for the nucleocytoplasmic trafficking of macromolecules. Recent findings suggest that the Ran/Gsp1p pathway may have additional roles in several aspects of nuclear structure and function, including spindle assembly, nuclear envelope formation, nuclear pore complex assembly and RNA processing. Here, we provide evidence that Gsp1p can regulate telomeric function in Saccharomyces cerevisiae. We show that overexpression of PRP20, encoding the Gsp1p GDP/GTP nuclear exchange factor, specifically weakens telomeric silencing without detectably affecting nucleocytoplasmic transport. In addition to this silencing defect, we show that Rap1p and Sir3p delocalize from their normal telomeric foci. Interestingly, Gsp1p was found to interact genetically and physically with the telomeric component Sir4p. Taken together, these results suggest that the GSP1 pathway could regulate proper telomeric function in yeast through Sir4p.

The Ctf18 RFC-like complex positions yeast telomeres but does not specify their replication time

Chromosome ends in Saccharomyces cerevisiae are positioned in clusters at the nuclear rim. We report that Ctf18, Ctf8, and Dcc1, the subunits of a Replication Factor C (RFC)-like complex, are essential for the perinuclear positioning of telomeres. In both yeast and mammalian cells, peripheral nuclear positioning of chromatin during G1 phase correlates with late DNA replication. We find that the mislocalized telomeres of ctf18 cells still replicate late, showing that late DNA replication does not require peripheral positioning during G1. The Ku and Sir complexes have been shown to act through separate pathways to position telomeres, but in the absence of Ctf18 neither pathway can act fully to maintain telomere position. Surprisingly CTF18 is not required for Ku or Sir4-mediated peripheral tethering of a nontelomeric chromosome locus. Our results suggest that the Ctf18 RFC-like complex modifies telomeric chromatin to make it competent for normal localization to the nuclear periphery.

Inactivation of Ku-mediated end joining suppresses mec1Delta lethality by depleting the ribonucleotide reductase inhibitor Sml1 through a pathway controlled by Tel1 kinase and the Mre11 complex

RAD53 and MEC1 are essential Saccharomyces cerevisiae genes required for the DNA replication and DNA damage checkpoint responses. Their lethality can be suppressed by increasing the intracellular pool of deoxynucleotide triphosphates. We report that deletion of YKU70 or YKU80 suppresses mec1Delta, but not rad53Delta, lethality. We show that suppression of mec1Delta lethality is not due to Ku--associated telomeric defects but rather results from the inability of Ku- cells to efficiently repair DNA double strand breaks by nonhomologous end joining. Consistent with these results, mec1Delta lethality is also suppressed by lif1Delta, which like yku70Delta and yku80Delta, prevents nonhomologous end joining. The viability of yku70Delta mec1Delta and yku80Delta mec1Delta cells depends on the ATM-related Tel1 kinase, the Mre11-Rad50-Xrs2 complex, and the DNA damage checkpoint protein Rad9. We further report that this Mec1-independent pathway converges with the Rad53/Dun1-regulated checkpoint kinase cascade and leads to the degradation of the ribonucleotide reductase inhibitor Sml1.

Mutations of the Yku80 C terminus and Xrs2 FHA domain specifically block yeast nonhomologous end joining

The nonhomologous end-joining (NHEJ) pathway of DNA double-strand break repair requires three protein complexes in Saccharomyces cerevisiae: MRX (Mre11-Rad50-Xrs2), Ku (Ku70-Ku80), and DNA ligase IV (Dnl4-Lif1-Nej1). Much is known about the interactions that mediate the formation of each complex, but little is known about how they act together during repair. A comprehensive yeast two-hybrid screen of the NHEJ factors of S. cerevisiae revealed all known interactions within the MRX, Ku, and DNA ligase IV complexes, as well as three additional, weaker interactions between Yku80-Dnl4, Xrs2-Lif1, and Mre11-Yku80. Individual and combined deletions of the Yku80 C terminus and the Xrs2 forkhead-associated (FHA) domain were designed based on the latter two-hybrid results. These deletions synergistically blocked NHEJ but not the telomere and recombination functions of Ku and MRX, confirming that these protein regions are functionally important specifically for NHEJ. Further mutational analysis of Yku80 identified a putative C-terminal amphipathic alpha-helix that is both required for its NHEJ function and strikingly similar to a DNA-dependent protein kinase interaction motif in human Ku80. These results identify a novel role in yeast NHEJ for the poorly characterized Ku80 C-terminal and Xrs2 FHA domains, and they suggest that redundant binding of DNA ligase IV facilitates completion of this DNA repair event.

Ku: A multifunctional protein involved in telomere maintenance

The DNA-binding protein Ku plays a critical role in a variety of cellular processes, including the repair of double-stranded DNA breaks and V(D)J recombination. Paradoxically, while Ku is required for double-stranded break repair by non-homologous end-joining, in many organisms, Ku is also associated with telomeres. Although telomeres are naturally occurring double-stranded DNA breaks, one of their first identified functions is to protect chromosomes from end-to-end fusions, a process that is promoted by non-homologous end-joining. While located at telomeres, Ku appears to play several important roles, including: (1) regulating telomere addition, (2) protecting telomeres from recombination and nucleolytic degradation, (3) promoting transcriptional silencing of telomere-proximal genes and (4) nuclear positioning of telomeres. Here, we review the role of Ku at telomeres in the model organism, Saccharomyces cerevisiae and compare and contrast it to the roles of Ku at telomeres in other organisms.

PUSHING THE ENVELOPE: Structure, Function, and Dynamics of the Nuclear Periphery

The nuclear envelope (NE) is a highly specialized membrane that delineates the eukaryotic cell nucleus. It is composed of the inner and outer nuclear membranes, nuclear pore complexes (NPCs) and, in metazoa, the lamina. The NE not only regulates the trafficking of macromolecules between nucleoplasm and cytosol but also provides anchoring sites for chromatin and the cytoskeleton. Through these interactions, the NE helps position the nucleus within the cell and chromosomes within the nucleus, thereby regulating the expression of certain genes. The NE is not static, rather it is continuously remodeled during cell division. The most dramatic example of NE reorganization occurs during mitosis in metazoa when the NE undergoes a complete cycle of disassembly and reformation. Despite the importance of the NE for eukaryotic cell life, relatively little is known about its biogenesis or many of its functions. We thus are far from understanding the molecular etiology of a diverse group of NE-associated diseases.

Sir-mediated repression can occur independently of chromosomal and subnuclear contexts

Epigenetic mechanisms silence the HM mating-type loci in budding yeast. These loci are tightly linked to telomeres, which are also repressed and held together in clusters at the nuclear periphery, much like mammalian heterochromatin. Yeast telomere anchoring can occur in the absence of silent chromatin through the DNA end binding factor Ku. Here we examine whether silent chromatin binds the nuclear periphery independently of telomeres and whether silencing persists in the absence of anchorage. HMR was excised from the chromosome by inducible site-specific recombination and tracked by real-time fluorescence microscopy. Silent rings associate with the nuclear envelope, while nonsilent rings move freely throughout the nucleus. Silent chromatin anchorage requires the action of either Ku or Esc1. In the absence of both proteins, rings move throughout the nucleoplasm yet remain silent. Thus, transcriptional repression can be sustained without perinuclear anchoring.

Non-homologous end-joining factors of Saccharomyces cerevisiae

DNA double-strand breaks (DSB) are considered to be a severe form of DNA damage, because if left unrepaired, they can cause a cell death and, if misrepaired, they can lead to genomic instability and, ultimately, the development of cancer in multicellular organisms. The budding yeast Saccharomyces cerevisiae repairs DSB primarily by homologous recombination (HR), despite the presence of the KU70, KU80, DNA ligase IV and XRCC4 homologues, essential factors of the mammalian non-homologous end-joining (NHEJ) machinery. S. cerevisiae, however, lacks clear DNA-PKcs and ARTEMIS homologues, two important additional components of mammalian NHEJ. On the other hand, S. cerevisiae is endowed with a regulatory NHEJ component, Nej1, which has not yet been found in other organisms. Furthermore, there is evidence in budding yeast for a requirement for the Mre11/Rad50/Xrs2 complex for NHEJ, which does not appear to be the case either in Schizosaccharomyces pombe or in mammals. Here, we comprehensively describe the functions of all the S. cerevisiae NHEJ components identified so far and present current knowledge about the NHEJ process in this organism. In addition, this review depicts S. cerevisiae as a powerful model system for investigating the utilization of either NHEJ or HR in DSB repair.

Functional links between telomeres and proteins of the DNA-damage response

In response to DNA damage, cells engage a complex set of events that together comprise the DNA-damage response (DDR). These events bring about the repair of the damage and also slow down or halt cell cycle progression until the damage has been removed. In stark contrast, the ends of linear chromosomes, telomeres, are generally not perceived as DNA damage by the cell even though they terminate the DNA double-helix. Nevertheless, it has become clear over the past few years that many proteins involved in the DDR, particularly those involved in responding to DNA double-strand breaks, also play key roles in telomere maintenance. In this review, we discuss the current knowledge of both the telomere and the DDR, and then propose an integrated model for the events associated with the metabolism of DNA ends in these two distinct physiological contexts.

Separation of silencing from perinuclear anchoring functions in yeast Ku80, Sir4 and Esc1 proteins

In budding yeast, the nuclear periphery forms a subcompartment in which telomeres cluster and SIR proteins concentrate. To identify the proteins that mediate chromatin anchorage to the nuclear envelope, candidates were fused to LexA and targeted to an internal GFP-tagged chromosomal locus. Their ability to shift the locus from a random to a peripheral subnuclear position was monitored in living cells. Using fusions that cannot silence, we identify YKu80 and a 312-aa domain of Sir4 (Sir4(PAD)) as minimal anchoring elements, each able to relocalize an internal chromosomal locus to the nuclear periphery. Sir4(PAD)-mediated tethering requires either the Ku complex or Esc1, an acidic protein that is localized to the inner face of the nuclear envelope even in the absence of Ku, Sir4 or Nup133. Finally, we demonstrate that Ku- and Esc1-dependent pathways mediate natural telomere anchoring in vivo. These data provide the first unambiguous identification of protein interactions that are both necessary and sufficient to localize chromatin to the nuclear envelope.