Maintenance of Double-Stranded Telomeric Repeats as the Critical Determinant for Cell Viability in Yeast Cells Lacking Ku

The Saccharomyces cerevisiae Ku complex, while important fornonhomologous DNA end joining, is also necessary for maintainingwild-type telomere length and a normal chromosomal DNA end structure.Yeast cells lacking Ku can grow at 23°C but are unable todo so at elevated temperatures due to an activation of DNA damagecheckpoints. To gain insights into the mechanisms affected bytemperature in such strains, we isolated and characterized anew allele of the YKU70 gene, yku70-30^ts. By several criteria,the Yku70-30p protein is functional at 23°C and nonfunctionalat 37°C. The analyses of telomeric repeat maintenance aswell as the terminal DNA end structure in strains harboringthis allele alone or in strains with a combination of othermutations affecting telomere maintenance show that the alteredDNA end structure in yeast cells lacking Ku is not generatedin a telomerase-dependent fashion. Moreover, the single-strandedG-rich DNA on such telomeres is not detected by DNA damage checkpointsto arrest cell growth, provided that there are sufficient double-strandedtelomeric repeats present. The results also demonstrate thatmutations in genes negatively affecting G-strand synthesis (e.g.,RIF1) or C-strand synthesis (e.g., the DNA polymerase ${alpha}$ gene)allow for the maintenance of longer telomeric repeat tractsin cells lacking Ku. Finally, extending telomeric repeat tractsin such cells at least temporarily suppresses checkpoint activationand growth defects at higher temperatures. Thus, we hypothesizethat an aspect of the coordinated synthesis of double-strandedtelomeric repeats is sensitive to elevated temperatures.

INTRODUCTION

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Introduction

DNA double-strand breaks (DSBs) belong to the most disruptiveforms of DNA damage. If left unrepaired, they lead to brokenchromosomes, which can cause cell death. On the other hand,incorrectly repaired DSBs can give rise to chromosomal aberrationssuch as rearrangements, deletions, and chromosome fusions (reviewedin references 17, 34, and 61). In a cell with DSBs, surveillancemechanisms called DNA damage checkpoints are activated in orderto prevent DNA replication and/or cell division before the damageis repaired (79, 85). DNA damage checkpoints are likely to beresponsible for activating the repair mechanisms, and they arethought to provide cells with time to complete the repair processby slowing down cell cycle progression.

Telomeres are special functional complexes at the ends of eukaryoticchromosomes. Unlike DNA DSBs, the ends of eukaryotic chromosomesare stable and do not activate the DNA damage checkpoints. Thus,telomeres protect the chromosome ends from fusion and degradationand allow the cell to differentiate a chromosomal DSB from anatural end (48, 52, 57, 70). In the vast majority of eukaryotes,including yeast and mammals, telomeres consist of simple repeatedDNA sequences and their associated proteins. The strand running5' to 3' toward the end contains clusters of three or four guaninesand is commonly referred to as the G-rich strand (81). For example,in the yeast Saccharomyces cerevisiae, telomeric DNA consistsof $~$ 300 bp of C_1-3A/TG_1-3 sequences (76, 77, 84). In organismswhere the DNA structure of the very end of the chromosome isknown, the G-rich strand is extended to form a single-strandtail (38, 41, 51, 54). In budding yeast, long overhangs of theG-rich strand are only detected during S phase (21, 82) andthe exact end structure outside of S phase is currently unknown.However, the assays used to analyze end structures in yeastexclude the possibility of G-strand or C-strand extensions ofmore than 20 bases (82).

In addition to the end protection function, telomeres are essentialfor ensuring the complete replication of the chromosomes (32,78, 84). In most eukaryotes, the end replication problem issolved by telomerase. This ribonucleoprotein complex extendsthe G-rich strand of the telomere using telomeric repeats encodedwithin the RNA component of the enzyme as a template (33, 71).In yeast, the telomerase RNA component is encoded by the TLC1gene (73), while the product of the EST2 gene provides the DNApolymerase activity (15, 45). Mutations in either of these geneslead to a gradual loss of telomeric DNA and cause a loss ofcell viability during vegetative subculturing (15, 45, 73).

The Ku complex is present in most eukaryotic organisms and iscomposed of an $~$ 70-kDa subunit (Ku70) and an $~$ 80-kDa subunit (Ku80),forming a heterodimer (reviewed in references 23 and 25). Invitro, this heterodimer binds DNA ends in a sequence-independentmanner, and Ku has been shown to be directly involved in nonhomologousend joining (NHEJ), a DNA DSB repair mechanism present in bothyeast and mammals (reviewed in reference 25). NHEJ consistsof a direct ligation of two DNA ends, and in this mechanismKu is believed to bind to DNA ends to prevent DNA degradation,facilitate alignment of the broken ends, and recruit DNA ligasesand other factors (29, 53, 60, 66, 74). Surprisingly, it hasalso been shown that Ku is physically associated with yeastand mammalian telomeric DNA (31, 39) and that this associationis important for telomere homeostasis and genome stability (16,69).

In budding yeast, inactivation of the Ku complex, referred toas Yku and consisting of the Yku70p and Yku80p proteins, hasseveral consequences for telomere maintenance and cell growth.Telomeric DNA is dramatically shortened, and the terminal DNAstructure maintains long extensions of the G-rich strand throughoutthe cell cycle (9, 31, 63, 64). Furthermore, telomeric silencingis diminished in Yku^- cells (10, 31, 42, 58), and the subnuclearlocalization of telomeres is modified (42). Finally, Yku^- cellsare unable to grow at elevated temperatures (9, 26). Recentevidence suggests that this temperature sensitivity phenotypeis related to a telomere defect rather than an inability torepair spontaneous DSBs generated in vivo. First, temperature-resistantsubclones of Yku^- mutant cells seem to maintain their telomeresby recombinational mechanisms (27). This result suggests thattelomere maintenance by recombinational mechanisms allows growthof Yku^- cells at elevated temperatures, whereas telomerase-basedmaintenance does not. Second, a deletion of the last 25 aminoacids from Yku70p results in telomere maintenance defects andtemperature sensitivity, whereas the cells are fully proficientfor NHEJ (22). Finally, overexpression of telomerase subunitsin Yku^- cells restores viability at 37°C and suppressesthe DNA damage checkpoint activation that occurs in these mutants(58, 75). In Yku^- cells incubated at 37°C, checkpoint activationis dependent on the RAD9 gene product (5, 75), a factor thathas emerged as a candidate DNA damage sensor (18, 28, 50). Oncethe damage is recognized, a set of protein kinases, includingMec1p and Rad53p, are activated (reviewed in references 47 and79). These kinases transduce the signal and regulate cellularresponses by phosphorylating appropriate target proteins involvedin the control of cell cycle transitions, the transcriptionalinduction of repair genes, the activation of repair proteins,or the chromatin structure (reviewed in references 47 and 79).At the level of transcriptional activation, it has been shownthat the Rad53p kinase regulates cellular deoxynucleoside triphosphate(dNTP) pools via the transcriptional induction of the genesencoding subunits of ribonucleotide reductase (RNR genes) (3,40). The demonstration that Rad53p activation and transcriptionalinduction of the RNR genes occur in Yku^- cells confirmed thatthe DNA damage checkpoint is activated in these cells (5, 75).

The precise role of Yku in telomere maintenance and the reasonsfor checkpoint activation and growth arrest of Yku^- cells atelevated temperatures have remained enigmatic. To address thesequestions, we identified and analyzed a temperature-sensitive(TS) allele of the YKU70 gene. Having used this allele as wellas other strategies to modify telomere lengths in Yku^- cells,we report here that, despite the presence of constitutive G-richoverhangs, Yku^- cells with long telomeres can grow normallyat elevated temperatures. In all conditions tested, DNA damagecheckpoint activation and absence of growth at 37°C qualitativelycorrelated with short telomeres. This new allele also allowedus to demonstrate that telomerase is not involved in the initialgeneration of the G-rich overhangs. Furthermore, a mutationin the gene encoding DNA polymerase ${alpha}$ (Pol ${alpha}$ ) that compromisesC-strand synthesis suppresses the telomere length phenotypein Yku^- cells. These results suggest that, in Yku^- cells, theability to coordinately generate a minimal amount of double-strandedtelomeric repeats at 37°C is compromised. This defect apparentlyleads first to DNA damage checkpoint activation and ultimatelyto permanent cell cycle arrest and cell death.

MATERIALS AND METHODS

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Materials and Methods

Yeast strains and plasmids. BY4705a (MATa ade2 ${Delta}$ hisG his3 ${Delta}$ 200 leu2 ${Delta}$ 0 lys2 ${Delta}$ 0 met15 ${Delta}$ 0 trp1 ${Delta}$ 63 ura3 ${Delta}$ 0)and isogenic derivatives were used for all experiments, exceptwhen stated otherwise. BY4705a was derived from BY4705 (12)by HO-mediated switching of the mating type (A. Wolf and D.Gottschling, personal communication). To generate strain BYyku70 ${Delta}$ ,the entire coding region of the YKU70 gene (-19 to +1841 withrespect to the initiation codon) was replaced by the LEU2 genein BY4705a. BYyku70 ${Delta}$ /rif1 ${Delta}$ was created by replacing the RIF1 gene(-1 to +5752 with respect to the initiation codon) by URA3 instrain BYyku70 ${Delta}$ . BYyku70 ${Delta}$ /rad9 ${Delta}$ was generated by replacing theRAD9 gene (-10 to +3940 with respect to the initiation codon)by HIS3 in strain BYyku70 ${Delta}$ . These strains were transformed witheither an empty pRS314 vector (72), plasmid pKu70 (see below),or pKu70-30^ts (see below) by standard methods (30). Strain SGY51(mata yku70 ${Delta}$ ::LEU2 tlc1 ${Delta}$ ::LEU2 his3 lys2 trp1 ${Delta}$ 63 ura3 ADE2 MET15or met15) harboring plasmids pKu70-30^ts and pAZ1 (7) (see below)was generated by crossing strain BYyku70 ${Delta}$ , containing pKu70-30^ts,with RWY10 (mat ${alpha}$ ura3-52 lys2-801 ade2-101 trp1- ${Delta}$ 63 his3- ${Delta}$ 200 leu2- ${Delta}$ 1tlc1 ${Delta}$ ::LEU2 VR-ADE2-TEL), carrying pAZ1. tlc1 ${Delta}$ /yku70 ${Delta}$ spores containingboth plasmids (pKu70-30^ts and pAZ1) were selected, and strainslacking TLC1 were recovered by selecting against the presenceof pAZ1 on fluoroorotic acid (FOA) media (8). Strain SGY53 (matatlc1 ${Delta}$ ::LEU2 yku70 ${Delta}$ ::LEU2 rif1 ${Delta}$ ::kanMX4 his3 lys2 trp1 ${Delta}$ 63 ura3 ADE2MET15 or met15), harboring plasmids pKu70-30^ts and pAZ1, wascreated by replacing the RIF1 gene with the kanMX4 marker instrain SGY51. To generate strain SGY56 (MATa/ ${alpha}$ pol1-17/POL1 yku70 ${Delta}$ ::URA3/YKU70),strain RWY121 (MATa ura3-52 trp1-289 ade2-101 gal2 can1 hispol1-17 bar1 ${Delta}$ ::kanMX) (2) was crossed with BYyku70 ${Delta}$ URA (MAT ${alpha}$ ade2 ${Delta}$ hisGhis3 ${Delta}$ 200 leu2 ${Delta}$ 0 lys2 ${Delta}$ 0 met15 ${Delta}$ 0 trp1 ${Delta}$ 63 ura3 ${Delta}$ 0 yku70 ${Delta}$ ::URA3). The SGY56diploid was sporulated and microdissected to generate the mutantstrains presented in Fig. 2B.

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FIG. 2. (A) Telomerase does not contribute significantly to the creation of G-rich overhangs in Yku^- mutants. Strain SGY51 (yku70 ${Delta}$ tlc1 ${Delta}$ pKu70-30^ts) and the same strain carrying in addition a plasmid-borne copy of TLC1(pAZ1) were grown at 23°C and then shifted for 8 h to 37°C. DNA was extracted, digested with XhoI, and analyzed by in-gel hybridization as described for Fig. 1B. Top, native gel; bottom, the same gel hybridized after denaturation. Lane M, end-labeled 1-kb ladder DNA serving as a size standard; lanes ss and ds, DNA with telomeric TG_1-3 repeats in single-stranded and double-stranded forms, respectively. Note that in yku70-30^ts cells telomere shortening occurs during the 30 generations of growth at 23°C that were necessary to produce the yku70-30^ts tlc1 ${Delta}$ strain. (B) Telomere length analysis for pol1-17 yku70 ${Delta}$ double mutants. Strain SGY56 (MATa/ ${alpha}$ pol1-17/POL1 yku70 ${Delta}$ ::URA3/YKU70) was sporulated and microdissected. Spores derived from a tetratype were grown, and total genomic DNA was extracted and digested with XhoI. The denatured gel from an in-gel analysis using the CA probe is shown. Lane M, end-labeled 1-kb ladder DNA serving as a size standard; lane 1, yku70 ${Delta}$ pol1-17 cells grown at 23°C; lane 2, the same strain as in lane 1 after a shift to 30°C for 16 h; lane 3, YKU70 POL1 wt cells grown at 23°C; lane 4, the same strain as in lane 3 after a shift to 30°C for 16 h; lane 5, yku70 ${Delta}$ POL1 cells grown at 23°C; lane 6, the same strain as in lane 5 after a shift to 30°C for 16 h; lane 7, YKU70 pol1-17 cells grown at 23°C; lane 8, the same strain as in lane 7 after a shift to 30°C for 16 h.

Telomeric silencing was tested with strain UCC3505 (MATa ura3-52lys2-80 ade2-101 trp1 ${Delta}$ 63 his3 ${Delta}$ 200 leu2- ${Delta}$ 1 ppr1 ${Delta}$ ::HIS3 adh4::URA3-TEL-VIILVR-ADE2-TEL) (73), in which the YKU70 gene was replaced by theLEU2 marker; the resulting strain was referred to as UCC3505/yku70.

All deletions in strains were achieved by PCR-mediated genedisruption (6) and were verified by Southern blotting and determinationof the corresponding phenotypes (data not shown).

pAZ1 is a pRS316(URA3 CEN3 ARSH4)-based plasmid (72) that containsa 5.5-kb genomic DNA fragment spanning the entire TLC1 locus(7). The pKu70 plasmid is pRS314(TRP1 CEN6 ARSH4) containingthe wild-type (wt) YKU70 gene (nucleotides -386 to +1921 withrespect to the initiation codon) under the control of its nativepromoter. The pKu70-GR plasmid was constructed in the followingway. Nucleotides -385 to -3 with respect to the initiation codonof the YKU70 gene were amplified by PCR. XhoI and EcoRI recognitionsites were appended to the upstream and downstream primers,respectively. The PCR product was cloned in pRS314 into thesame sites to generate pKu70-G. One hundred twelve nucleotidesdownstream of the stop codon of the YKU70 gene were amplifiedby PCR, and EcoRI and BamHI recognition sites were appendedto the upstream and downstream primers, respectively. This PCRproduct was cloned in pKu70-G at the same sites to generatepKu70-GR. The resulting plasmid was digested with EcoRI beforetransformation.

Yeast growth conditions. Yeast strains were grown in standard media at various temperatures(67). For the determination of population doublings (numbersof generations), cell concentrations were measured by densitometryat 660 nm. Cells were diluted to 3 x 10⁵ to 1 x 10⁶ cells/mlin synthetic complete (SC)-Leu-Trp and regrown to 1 x 10⁷ to2 x 10⁷ cells/ml.

Construction and selection of the yku70-30^ts allele. The YKU70 gene (nucleotides -350 to + 1921 with respect to theinitiation codon) was randomly mutagenized by PCR in a buffercontaining 10 mM Tris (pH 9), 50 mM KCl, 0.2 mM dATP, 0.2 mMdGTP, 1 mM dCTP, 1 mM dTTP, 7 mM MgCl₂, and 1.5 U of Taq DNApolymerase. The PCR product was gel purified and cotransformedwith EcoRI-linearized pKu70-GR into strain UCC3505/yku70 ${Delta}$ , andtransformants were selected on SC-Trp (gap repair method). Cellpatches for 7,500 transformants were rereplica plated on SC-Trpor FOA-Trp media and incubated for 3 days at 23 or 37°C.Strains displaying the desired phenotypes (see Results) wereused for plasmid rescue into Escherichia coli, and the insertsin the recovered plasmids were sequenced. The yku70-30^ts alleleencodes the following mutations: Thr134Ser, Leu170Phe, and Phe215Ile.The pRS314 vector containing this allele is referred to as pKu70-30^ts.Currently, we do not know whether all three mutations are necessaryto confer the TS character of this allele.

Nucleic acid methods. Southern blotting and in-gel hybridization analyses were performedusing the CA oligonucleotide probe (CA probe) described previously(21). To determine the lengths of terminal restriction fragments,genomic DNA was digested with XhoI and separated by electrophoresison 1% agarose gel. The DNA was then blotted onto a nylon membraneand probed with a 600-bp KpnI fragment derived from the telomere-proximalside of the subtelomeric Y' element (46) (Y' probe). Blots werescanned with a Packard InstantImager, and the sizes of the terminalrestriction fragments (TRFs) were determined with the Imagersoftware. Broad peaks corresponding to the TRFs were visualizedwith the software, and the migration distances of the tops,middles, and bottoms of the peaks with respect to the wellswere defined. The migration distances were then converted bythe software to DNA sizes by using the parameters determinedby the migration of the molecular size markers (100-bp ladder;AP Biotech). The XhoI restriction site situated in the Y' subtelomericelement is 870 bp from the start of the telomeric TG_1-3 sequences(46). Consequently, the apparent lengths of telomeric repeatswere determined by subtracting 870 bp from the lengths determinedfor the TRFs.

For RNA analysis by Northern blotting, cells were grown to mid-logphase at 23 or 37°C for various numbers of generations andtotal RNA was isolated by glass bead-mediated cell disruptionin LETS buffer (0.01 M Tris [pH 7.5], 0.1 M LiCl, 0.01 M EDTA,0.2% sodium dodecyl sulfate) (67). Standard techniques wereused for gel electrophoresis (68). RNA (25 µg/sample)was blotted to a Hybond N+ membrane (Amersham Pharmacia Biotech)and hybridized according to the manufacturer's instructions.RNA blots were probed sequentially with ³²P-labeled DNA fragmentsspecific for the RNR2, RNR3, and RNR4 genes, as described previously(14). A probe specific for the RNA of the yeast ACT1 gene wasused as an RNA loading control. The blots were scanned witha Molecular Dynamics PhosphorImager, and the radioactive signalswere quantified with ImageQuant software. The RNR transcriptlevels were arbitrarily set at 1 in the wt cells grown at 23°C,and RNR levels in Yku^- mutants were normalized accordingly.

RESULTS

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Results

Identification of a TS allele of YKU70. The ability to repress the transcription of telomere-proximalgenes as well as viability at elevated temperature are drasticallyreduced in cells devoid of Yku (9, 10, 26, 31, 42, 58). We usedthese two properties to select for TS alleles of the YKU70 gene.The whole YKU70 gene was mutagenized by random PCR and expressedin a yku70 ${Delta}$ haploid strain (see Materials and Methods). We screenedfor mutants that could silence telomere-proximal reporter genesat 23°C and that showed reduced cell viability at 37°C.To assay telomere-proximal silencing, we monitored the expressionof the ADE2 gene inserted near the telomeric repeats of chromosomeV-R and the expression of the URA3 gene inserted near the telomericrepeats of chromosome VII-L (73). In cells with a wt alleleof YKU70, the reporter genes were repressed and cells accumulateda red pigment (ADE2 assay; Fig. 1A, top). In addition, due torepression of the telomeric URA3 gene in wt cells, most cellswere able to grow on medium containing 5-FOA, a drug toxic forcells expressing URA3 (URA3 assay; Fig. 1A, bottom). As previouslyreported, a strong derepression of these loci was observed inyku70 ${Delta}$ cells, leading to white patches in the ADE2 assay andsignificantly reduced growth in the URA3 assay, even at 23°C(Fig. 1A). Cells harboring the yku70-30^ts allele, one of thealleles recovered in our screen, behaved very similarly to wtcells when grown at 23°C: they displayed accumulation ofred pigment in the ADE2 assay and good viability in the URA3assay (Fig. 1A). However, compared to YKU70 cells, pKu70-30^ts-harboringcells displayed an important reduction in viability at 37°C(Fig. 1A).

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FIG. 1. (A) Identification of a TS allele of YKU70. The entire YKU70 gene was randomly mutagenized, and the mutant alleles were expressed in a yku70 ${Delta}$ strain carrying the ADE2 and URA3 genes as reporter genes for telomere position effect (strain UCC3505/yku70 ${Delta}$ ). Cells containing an empty vector (yku70 ${Delta}$ ) or the vector containing the wt YKU70 gene (pKu70; YKU70) were used as controls for silencing status and growth at high temperature. Patches of cells were grown at 23°C on SC-Trp and then rereplica plated on the same medium at 37°C (ADE2 assay, top), or on FOA-Trp at 23 and 37°C (URA3 assay, bottom) and incubated for 3 days. (B) yku70-30^ts cells grown at 37°C exhibit telomeric single-stranded G-rich DNA. Strain BYyku70 ${Delta}$ transformed with the indicated plasmids was grown in liquid culture at 23°C and then shifted to 37°C for 8 h. Genomic DNA was extracted and digested with XhoI, and telomeres were analyzed for G tails by nondenaturing in-gel hybridization with a CA oligonucleotide probe (top). To control for DNA loading, the DNA was denatured in the gel and rehybridized to the same probe (bottom). Lane M, end-labeled 1-kb ladder DNA serving as a size standard; lanes ss and ds, DNA with telomeric TG_1-3 repeats in single-stranded and double-stranded forms, respectively, as described previously (21).

The telomeric end structure is modified in yku70 ${Delta}$ cells, and,in contrast to what is found for wt cells, long overhangs ofthe G-rich strand are present throughout the cell cycle (31,63). As a further test for the temperature sensitivity of theyku70-30^ts allele, the telomeric DNA end structure present incells harboring the yku70-30^ts allele was analyzed for cellsgrown at 23°C or shifted to 37°C for 8 h (about twogenerations). G-rich overhangs were then probed by in-gel hybridization.As shown in Fig. 1B, the amount of single-stranded G-rich overhangsdetected on telomeres derived from yku70-30^ts cells grown at23°C is comparable to that detected on telomeres derivedfrom YKU70 cells. However, after two generations of growth at37°C, a strong signal for G-rich extensions is detected.The intensity of the signal is comparable to that of the onedetected in DNA derived from yku70 ${Delta}$ cells (Fig. 1B, compare lanes2 and 6). To control for DNA loading, the DNA was denaturedin gel and rehybridized to the same probe (Fig. 1B, bottom).

These results indicate that, when cells harboring the yku70-30^tsallele are grown at 23°C, the repression of telomere-proximalgenes is normal (Fig. 1A). In addition telomere lengths as wellas the telomeric DNA end structure are indistinguishable fromthose found in wt cells (Fig. 1B). However, the function ofYku in maintaining a normal telomeric end structure is lostwhen yku70-30^ts cells are incubated at 37°C (Fig. 1B), thecells lose the ability to form colonies, and the ability torepress telomere-proximal genes is reduced (Fig. 1A). Furthermore,in an HO endonuclease cleavage assay developed by Haber andcoworkers to measure NHEJ efficiency (43, 56), cells harboringthe yku70-30^ts allele are at least 10-fold more sensitive thanwt cells to HO expression when the assay is performed at 37°C,while displaying the same resistance as wt cells at 23°C(data not shown). Thus, for all the phenotypes analyzed, cellsharboring the yku70-30^ts allele behave as if the Yku complexis functional at 23°C but nonfunctional at 37°C.

Telomerase is not involved in the initial generation of G-rich overhangs after loss of Yku function. Yku^- cells possess overhangs of the G-rich strand of >30bases throughout the cell cycle (31, 63). One obvious candidatefor the creation of these single-stranded extensions was telomerase.However, because of the nearly synthetic-lethal interactionbetween Yku and telomerase (31, 58), it was impossible to testdirectly the importance of this enzyme in the creation of theG-rich overhangs. The yku70-30^ts allele allowed us to addressthis question. A deletion of TLC1, the gene encoding the RNAcomponent of telomerase, was introduced in a strain harboringthe yku70-30^ts allele as the sole source of Yku70p (see Materialsand Methods). This strain survives due to the presence of TLC1on a URA3/CEN plasmid and/or by growth at 23°C, the permissivetemperature for the yku70-30^ts allele. Cells lacking TLC1 wereselected for by growth on FOA-Trp media at 23°C. The FOA-resistantcells lack functional telomerase by two criteria. First, thecells lost viability after subculturing for about 40 to 60 generationsat 23°C (data not shown). Second, compared to telomeresderived from TLC1 yku70-30^ts cells, the lengths of the telomeresderived from tlc1 ${Delta}$ yku70-30^ts cells were reduced in cells grownfor about 25 generations in the absence of TLC1 (Fig. 2A, bottom,compare lanes 1 and 3). The Yku complex was inactivated in thesecells by shifting the culture to 37°C for 8 h, which issufficient to inhibit Yku function in these cells (Fig. 1B).As controls, telomerase-positive cells were also shifted to37°C for the same amount of time. Total genomic DNA wasextracted, and the G-strand overhangs were analyzed by in-gelhybridization. The signal for single-stranded G-rich DNA detectedon telomeres derived from tlc1 ${Delta}$ yku70-30^ts cells is comparableto the one detected on telomeres from TLC1 yku70-30^ts cells(Fig. 2A, top, compare lanes 2 and 4). This result indicatesthat at least part of the initial creation of the G-rich overhangsobserved in Yku^- mutants is independent of telomerase.

Cells harboring specific TS alleles of the gene encoding thecatalytic subunit of Pol ${alpha}$ , such as pol1-17, also have an alteredtelomeric end structure (2). As in Yku^- mutants, the G-strandoverhangs in Pol ${alpha}$ mutants are initially formed in a telomerase-independentmanner. However, in contrast to Yku^- mutants, pol1-17 mutantsdisplay a telomerase-dependent telomere elongation during outgrowthat a semipermissive temperature rather than telomere shortening(1, 2). In light of these observations, we were interested toaddress the relationship between Yku and Pol ${alpha}$ with respect totelomere length maintenance. To test this, pol1-17 yku70 ${Delta}$ doublemutants were created by sporulating diploid strain SGY56 (seeMaterials and Methods) and tetrad dissection. Telomere lengthin cell cultures derived from all four spores of a tetratypewas determined (Fig. 2B). Compared to those in the yku70 ${Delta}$ mutants,the telomeres in the pol1-17 yku70 ${Delta}$ double mutant are elongated,even when the cells are grown at 23°C, a temperature atwhich the pol1-17 mutation by itself only causes a modest phenotype(Fig. 2B, compare lanes 1 and 5). Telomere lengths are evenmore increased when the double mutants are grown at 30°C,the semipermissive temperature for the pol1-17 mutants (Fig.2B, compare lanes 1 and 2). Thus, the defect in pol1-17 cellscauses telomere elongation even if combined with a Yku^- mutation.

For Yku^- cells, the lengths of telomeric repeats correlate with the capacity to grow at elevated temperature. Despite the presence of G-rich overhangs, the number of thetelomeric repeats, and hence telomere length, were not diminishedsignificantly in yku70-30^ts cells grown for two generationsat 37°C (Fig. 1B). Furthermore, as shown in Fig. 1A (ADE2assay), the viability of yku70-30^ts cells at 37°C was notaffected to the same extent as that of yku70 ${Delta}$ cells. However,in initial experiments we observed that yku70-30^ts cells losetelomeric repeats and viability after more-prolonged exposuresto high temperature (see below and data not shown). These observationssuggested a possible correlation between the length of the telomericrepeats and the viability of Yku^- cells at 37°C. To explorethis possibility, we measured these two parameters during outgrowthof Yku^- mutants. In these analyses, cells devoid of Yku (yku70 ${Delta}$ strains) and strains harboring the yku70-30^ts allele were used.Furthermore, a deletion of the RIF1 gene was introduced intothose strains to generate yku70 ${Delta}$ rif1 ${Delta}$ and yku70-30^ts rif1 ${Delta}$ doublemutants. The RIF1 gene encodes a protein that localizes to telomeres,where it acts as an inhibitor of telomere elongation (55). Asa result, rif1 ${Delta}$ cells have elongated telomeres (36).

These different strains were grown in liquid medium at 23°Cand then shifted to 37°C for 2.5 or 6 generations (or untilloss of growth), and the viability at 37°C was assessedby plating 10-fold serial dilutions of the cultures at 37°C(Fig. 3A). Growth capacity was qualitatively assayed on platesbased on sizes of colonies on the spots with diluted culturesand on which single-cell-derived colonies can be visualized.Cells were classified into three categories: (i) pregrowth andculture conditions allowed the formation of individual coloniessimilar to wt, (ii) individual colonies were smaller than wt(microcolonies) yet clearly visible, and (iii) individual microcoloniesfailed to form in spots of the diluted culture. We note thatcells from some cultures incapable of forming microcolonieswere able to form lawns at low dilutions. In parallel, aliquotsof the same cultures used to determine viability were used toisolate genomic DNA and measure telomere repeat lengths at eachtime point by Southern blotting (Fig. 3B; all the data are summarizedin Table 1). Thus, the DNA was digested with the XhoI restrictionenzyme and the telomeric restriction fragments were detectedwith a telomere-proximal Y' probe. Grown at 23°C, the differentstrains used here displayed telomeric repeat lengths of about275 bp for wt, 130 bp for yku70 ${Delta}$ , 250 bp for yku70 ${Delta}$ rif1 ${Delta}$ , 265bp for yku70-30^ts, and 620 bp for yku70-30^ts rif1 ${Delta}$ cells (Fig.3B, lanes 23°; Table 1). A strain with a deletion of RIF1alone (YKU70 rif1 ${Delta}$ ) had telomere lengths very similar to thosefor the yku70-30^ts rif1 ${Delta}$ strain grown at 23°C and displayedthe growth characteristics of a wt strain in all conditionstested (data not shown). All strains form normal-size colonieswhen pregrown at 23°C and then incubated on plates at 23°C(Fig. 3A, top row).

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FIG. 3. (A) Effects of deleting the RIF1 gene on growth of Yku^- mutants at elevated temperatures. Cells with the indicated genotypes were grown at 23°C to mid-log phase and then diluted into prewarmed medium and regrown for 2.5 or 6 generations at 37°C. Following the growth period in liquid medium, 10-fold serial dilutions of the cells were spotted on SC-Trp and the plates were incubated for 3 days at 37°C. As controls, 10-fold serial dilutions of the cultures prior to the shift to 37°C were also spotted onto SC-Trp and incubated at 23 (top row) or 37°C (second row from top). (B) Telomere lengths in the strains analyzed in panel A. Genomic DNAs from the cultures tested in panel A were digested with XhoI, and the TRFs were detected by standard Southern blotting using a probe that is specific for telomere-proximal Y' sequences. Lane M, end-labeled 100-bp ladder DNA serving as a size standard. G, generations. (C) In Yku^- cells, deletion of the RIF1 gene does not restore a normal terminal DNA structure on telomeres. Aliquots of the genomic DNAs tested in Fig. 3B were analyzed by in-gel hybridization as for Fig. 1B. G-rich overhangs were detected with a CA probe (top). The rehybridization of the gel after denaturation (bottom) indicates that similar amounts of DNA were loaded in each lane.

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TABLE 1. Telomere lengths and growth phenotypes of Yku mutants

Yku70 ${Delta}$ cells grown for 2.5 generations in liquid medium at 37°Cdo not grow further when incubated at the same temperature onplates (Fig. 3A, first column from left) or in liquid culture(data not shown). Interestingly, yku70 ${Delta}$ cells that have elongatedtelomeres conferred by the RIF1 deletion show an important growthrecovery at the same time point, without however being ableto form wt size colonies (Fig. 3A, second column). The Southernanalysis revealed that culturing at 37°C resulted in a gradualtelomere shortening. From 250 bp, the length at 23°C, thelengths of telomeric repeats were decreased to reach a meanof 205 bp after 2.5 generations and 155 bp after 6 generationsat 37°C (Fig. 3B). After six generations of pregrowth inliquid medium at 37°C, the cells were not able to form colonieson the plates. The profile of viability and telomere loss forcells harboring the yku70-30^ts allele was very comparable theone for yku70 ${Delta}$ rif1 ${Delta}$ cells. A shift to 37°C produced a rapidtelomere shortening accompanied by a marked decrease in viability(Fig. 3). The yku70-30^ts rif1 ${Delta}$ cells, which have the most-elongatedtelomeres of all the Yku^- mutants tested, showed an interestingphenotype. Even after six generations of growth at 37°C,these yku70-30^ts rif1 ${Delta}$ cells showed no growth defect and formedwt size colonies when plated at 37°C (Fig. 3A, fourth column).At this time point, these cells possessed a mean telomere lengthof 465 bp, more than twice the lengths of telomeres in yku70-30^tsand yku70 ${Delta}$ rif1 ${Delta}$ cells at the same time point (Fig. 3B).

These results were in agreement with a model in which the viabilityof Yku^- cells at 37°C is dictated by the overall lengthsof telomeric repeats. However it was possible that the gainof viability caused by the deletion of the RIF1 gene was dueto a correction of the aberrant terminal structure present inYku^- cells. Thus, we analyzed the G-strand overhangs in yku70 ${Delta}$ rif1 ${Delta}$ and yku70-30^ts rif1 ${Delta}$ cells (Fig. 3C) at each of the timepoints where viability was tested. Comparable signals for G-strandoverhangs were detected on telomeres derived from yku70 ${Delta}$ cellsand yku70 ${Delta}$ rif1 ${Delta}$ cells (Fig. 3C, top, compare lanes 1 and 2 and3 and 4). Also, G-strand overhangs are clearly detectable ontelomeres derived from yku70-30^ts rif1 ${Delta}$ cells shifted to 37°Cfor 2.5 or 6 generations (Fig. 3C, lanes 10 and 11). These resultsdemonstrate that a deletion of the RIF1 gene does not restorea normal terminal DNA structure to telomeres in Yku^- cells andshow that the aberrant end structure present on telomeres ofYku^- cells per se does not interfere with growth at high temperatures.

The DNA damage checkpoint is activated in Yku^- mutants with short telomeres. When incubated at 37°C, Yku^- cells arrest in the G₂/M phaseof the cell cycle (5, 26). This arrest is dependent on the Rad9pprotein, a component of the DNA damage checkpoint (5, 75), suggestingthat DNA damage is detected in Yku^- mutants grown at high temperature.Because Yku^- mutants with elongated telomeres gain viabilityat elevated temperature (Fig. 3A), we wondered whether activationof the DNA damage checkpoint was correlated with overall telomerelength, rather than DNA end structure (see above). The DNA damagecheckpoint response is initiated by recognition and/or processingof the damage, and it has been proposed that several proteinsare involved in these processes. These include the Rad17p, Rad24p,Mec3p, Ddc1p, Rad9p, and Lcd1/Ddc2p proteins, all of them beingessential for efficient checkpoint functions in both the G₁and G₂/M phases of the cell cycle (47, 59, 79). Once the damageis recognized, the Mec1p and Rad53p kinases are activated andphosphorylate appropriate substrates. One of the downstreameffects in response to DNA damage is the induction of ribonucleotidereductase gene (RNR) transcription (3, 24). Since this transcriptionalinduction is under the control of the DNA damage checkpointsignaling pathway, a measurement of the RNR transcript levelsreflects the checkpoint activation status. We used this assayto monitor checkpoint activation in cells derived from the samecultures used to assay cellular viability as well as telomerelength and structure (Fig. 3). Total RNA was prepared, and thelevels of transcripts specific for the RNR2, RNR3, and RNR4genes were detected and quantified by Northern analysis (Fig.4 and data not shown). The RNR transcript levels in the wild-typecells grown at 23°C were arbitrarily set at 1, and levelsin Yku^- mutants were normalized accordingly. A robust transcriptionalactivation of the RNR genes is detected in yku70 ${Delta}$ cells grownfor 2.5 generations at 37°C (Fig. 4, first column from left).Interestingly, the checkpoint activation is delayed in yku70 ${Delta}$ rif1 ${Delta}$ and yku70-30^ts mutants. In these strains, the highest transcriptionalactivation observed required six generations of growth at 37°C(Fig. 4, second and third columns). In yku70-30^ts rif1 ${Delta}$ cells,which have extremely elongated telomeres and no observable growthdefect after six generations at 37°C, only a marginal activationof RNR transcription is detectable (Fig. 4, fourth column).Furthermore, the transcriptional activation of RNR genes inyku70-30^ts cells is almost completely abolished by deletionof the RAD9 gene (Fig. 4, fifth column), indicating that thedetected transcriptional induction of the RNR genes is due toRAD9-dependent DNA damage checkpoint activation. Deletion ofRAD9 does not, however, rescue the growth defect of yku70-30^tscells at 37°C (data not shown). This result suggests thatthe growth arrest at 37°C in these cells is not solely dueto a prolonged cell cycle arrest.

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FIG. 4. DNA damage checkpoint activation in Yku^- cells correlates with short telomeres. Total RNA was extracted from the cells tested in Fig. 3A and transferred to nylon membranes. The membranes were successively probed to detect RNR2, RNR3, and actin transcripts. To correct for RNA loading, the signals specific for the RNR transcripts were normalized to the actin signal. The RNR transcript levels were arbitrarily set at 1 in the wt cells grown at 23°C, and RNR transcript levels in Yku^- mutants were determined accordingly. The migration positions of the 25S rRNA (3,392 nucleotides) and 18S rRNA (1,798 nucleotides) are indicated as molecular weight references. G, generations.

It has been shown that overexpression of telomerase subunitEst2p or TLC1 suppresses checkpoint activation and restoresviability at high temperature in Yku^- cells without apparentlymodifying telomere length (75). To explain these observations,it has been proposed that, in the absence of Yku, componentsof yeast telomerase could play a telomere-capping function importantfor viability at high temperatures (75). To explore this possibility,we asked if inactivation of telomerase in Yku^- mutants withelongated telomeres would also cause a major capping defectthat would result in a dramatic and immediate decrease in viabilitysuch as is observed for telomerase^- Yku^- cells. We used strainSGY53 (tlc1 ${Delta}$ yku70 ${Delta}$ rif1 ${Delta}$ ) containing both pKu70-30^ts and pAZ1(TLC1)in these assays. In this strain, telomeres are elongated dueto the rif1 deletion (Fig. 3). By a passage on FOA-Trp mediaat 23°C, we selected an SGY53 strain that contained pKu70-30^tsas the sole source of Yku. This strain (tlc1 ${Delta}$ yku70 ${Delta}$ rif1 ${Delta}$ pKu70-30^ts)and the strain still containing the wt TLC1 gene (tlc1 ${Delta}$ yku70 ${Delta}$ rif1 ${Delta}$ pKu70-30^ts pAZ1[TLC1]) were then grown in liquid mediumat 23°C, and viability of the Yku^- mutant strains was determinedby plating 10-fold serial dilutions of the cultures at 37°C.As shown in Fig. 5, the combined absence of telomerase and Ykuin this strain with elongated telomeres reduced viability at37°C only modestly, in contrast to the lethality observedwith yku70 ${Delta}$ tlc1 ${Delta}$ strains. This result suggests that telomeraseinactivation does not modify the capping status of telomeresin Yku^- mutants, provided that there is a significant numberof telomeric repeats present.

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FIG. 5. A combined absence of telomerase and Yku does not lead to immediate growth arrest in cells with elongated telomeric repeat tracts. Strain SGY53 (yku70 ${Delta}$ tlc1 ${Delta}$ rif1 ${Delta}$ pKu70-30^ts) and the same strain carrying in addition a plasmid-borne copy of TLC1(pAZ1) were grown at 23°C in liquid medium. To assess viability of these strains, 10-fold serial dilutions of the cells were spotted on SC-Trp plates and incubated at 23 or 37°C. tlc1 ${Delta}$ (a) and -(b), two independent clones of the strain without pAZ1.

DISCUSSION

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Discussion

Yeast cells devoid of Yku exhibit excess of single-strandedG-rich DNA at their telomeres (31, 63). One obvious candidatefor the creation of these overhangs was telomerase. The yku70-30TS allele of the YKU70 gene described in this study allowedus to determine that, upon loss of Yku function, telomeraseper se is not an essential factor for the creation of the overhangs(Fig. 2A). These data are consistent with our earlier findings,which indicated that the cell cycle-dependent occurrence ofG-rich overhangs at yeast telomeres can also be detected incells lacking telomerase (21, 80). It is therefore possiblethat the overhangs observed in Yku^- mutants are generated viathe same mechanisms as the S-phase-specific overhangs in wtcells but would become permanent in Yku^- mutants.

Such single-stranded DNA overhangs are important determinantsfor recognition as DNA damage (43). Once such DNA sensed, thecell cycle is arrested and the damage is repaired. Curiously,the constitutive telomeric overhangs observed in Yku^- cellsappear not to cause a cell cycle arrest, at least when the cellsare incubated at 23°C (75). However, Yku^- cells are unableto grow at 37°C, and it was possible that, at this temperature,the single-stranded overhangs were recognized as damage andthe DNA damage checkpoints were activated. This argument iscomplicated by the fact that, in Yku^- cells, the double-strandedtracts of telomeric repeats are extremely short (9, 64), andany failure of mechanisms to maintain that double-stranded portionmay have the same effect, independently of the presence of theoverhangs. To address the question as to whether the overhangsare responsible for temperature sensitivity of Yku^- cells at37°C, we created situations in which the double-strandedtracts were elongated to at least wt levels but in which theterminal structure still comprised the overhangs. We used thefact that a deletion of the gene encoding the Rif1p protein,which is part of the telomeric chromatin complex, induces alengthening of the telomeric repeat tracts (11, 36, 55, 83).Thus, yku70 ${Delta}$ rif1 ${Delta}$ cells incubated at 23°C harbor telomerictracts that are comparable in length to those found in wt cellsor yku70-30^ts cells (Table 1). The telomeric DNA end structurein these cells did, however, comprise single-stranded overhangs,indicative of an absence of Yku function (Fig. 3C), and thesecells were able to form colonies at 37°C when there wasno preexposure to 37°C (Fig. 3A). Similarly, yku70-30^tsrif1 ${Delta}$ cells were able to form wt size colonies at 37°C onplates, even after a pregrowth of six generations at 37°Cin liquid media, after which G-strand extensions are detectable(Fig. 3). Thus, clearly the inability to from colonies at 37°Cdid not correlate with the presence of the G-strand overhangs.In these experiments, we also assessed the activation of theRAD9-dependent DNA damage checkpoint by analyzing RNR transcriptlevels on Northern blots after an incubation of the variouscells at 37°C (Fig. 4). For all situations tested, we observedthat, if the preincubation of the cells in liquid media hadno effect on RNR transcript levels, the cells were able to formcolonies on plates incubated at 37°C and, conversely, ifthe RNR transcript levels were induced, no more colony formationon plates was discernible. For example, yku70 ${Delta}$ rif1 ${Delta}$ cells oryku70-30^ts cells incubated in liquid media at 37°C for 2.5generations displayed G-strand overhangs and virtually no RNRgene induction and were able to form colonies on the platesafterward (Fig. 3A and 4). In these same cells, after six generationsof growth at 37°C, the detection of single-stranded overhangsis unchanged, yet RNR transcript levels are induced and thecells are not able to form colonies anymore. We conclude thatthe altered terminal DNA structure found in Yku^- cells aloneis not sufficient to induce DNA damage checkpoint activationand is not the cause for the growth arrest of such cells at37°C. Consistent with these results, the altered DNA endstructure in Yku^- cells remains unchanged when single telomerasesubunits are expressed, yet such cells are also able to growat 37°C (75).

However, our experiments demonstrate that the apparent lengthsof the TRFs correlated with suppression of checkpoint activationand the capacity to grow at 37°C (Fig. 3 and 4 and Table1). For example, at 23°C, yku70 ${Delta}$ rif1 ${Delta}$ and yku70-30^ts cellsmaintain telomeres of about wt lengths. Without preincubationat 37°C or after a pregrowth for only two generations at37°C the telomeres are longer than those found in yku70 ${Delta}$ cells and these cells are still able to form colonies on platesincubated at 37°C. However, during growth at 37°C, telomericrepeats are being lost and, after about six generations of growth,the lengths reach levels that are quite comparable to thosein yku70 ${Delta}$ cells grown at 23°C (Table 1). Importantly, afterthese six generations of preincubation at 37°C, these samecells are not able to form colonies anymore at 37°C. Mostsignificantly, yku70-30^ts rif1 ${Delta}$ cells harbor elongated telomerescomparable in length to those of rif1 ${Delta}$ cells at 23°C (Fig.3B, Table 1, and data not shown). Such yku70-30^ts rif1 ${Delta}$ cellsare able to form normal colonies, even after pregrowth for sixgenerations at 37°C (Fig. 3A). Again, telomeric repeatsare being lost during growth at 37°C, but the average lengthof the telomeres after six generations of growth still was significantlylarger than that in yku70 ${Delta}$ cells (465 versus 130 bp; Table 1).Thus, in all cases investigated here, the apparent lengths oftelomeric tracts, and in particular the sizes of the shortesttelomeres, correlated with RNR transcript induction and theability to form colonies at 37°C.

Recent evidence suggests that Yku itself may be important forrecruitment or activation of telomerase (62). In all of ourexperiments, we observed progressive losses of telomeric repeatswhen Yku^- cells were shifted to 37°C. Using gels such asthat shown in Fig. 3B, we estimate that the loss rates afterabolition of Yku function are about 10 to 15 bp/generation,even in the presence of telomerase. These loss rates are abouttwo- to threefold higher than those occurring due to an absenceof telomerase (44, 49, 73). Moreover, yku70 ${Delta}$ rif1 ${Delta}$ strains harbortelomeres of almost normal length, and yku70 ${Delta}$ cells are ableto maintain very short telomeric repeats, when these strainsare grown at 23°C. These data lend support to the idea thatYku is involved in protecting yeast chromosome ends from sequencelosses other than or in addition to those occurring due to alack in G-strand synthesis alone.

Thus, our results are consistent with the hypothesis that, inYku^- cells, some aspect of the mechanisms involved in maintaininga minimal tract of double-stranded telomeric repeats is TS.Recently, it has been postulated that factors involved in lagging-strandsynthesis are important for telomere length regulation and new-telomeresynthesis (2, 19, 65). For example, a mutation in the gene encodingPol ${alpha}$ (pol1-17) will lead to extensive, but transient, G-richoverhangs at telomeres and an overall lengthening in telomericrepeats (2, 13). This same mutation can at least partially restorethe telomere-shortening phenotype of Yku^- cells (Fig. 2B). Whileit is unclear how the pol1-17 mutation eventually leads to telomericrepeat expansion, our results do suggest that, in the absenceof Yku, C-strand synthesis is a crucial determinant for maintaininga functional repeat tract. Therefore, we favor the idea thatYku has a function in telomere replication. In the absence ofYku, the telomeric C-rich strand may be incompletely replicatedand the naturally transient extensions would become permanent.In this situation, in order to compensate for incomplete C-strandreplication and the resulting increased rates of loss of telomericsequences, a more active G-strand elongation by telomerase wouldbe required to generate stable telomeres. When telomeric repeattracts are still relatively long, the Rif-mediated inhibitionof telomere extension could prevent sufficient Yku-independentelongation, leading to a rapid overall telomere shortening.However, at least at 23°C, once the telomeres reach veryshort lengths, this cis inhibition would drop to a level thatallows the Yku-independent telomere-lengthening process to counteractfurther losses.

In this scenario, Yku could play a stabilizing role in the setupof the complete terminal complex required for the elongationof both telomeric strands. This idea would explain why bothmutations relieving inhibition of G-strand synthesis (rif1 ${Delta}$ )and mutations affecting actual C-strand synthesis (pol1-17)can suppress the telomere length deficiency in cells lackingYku. This stabilizing activity of Yku would explain why Yku-independenttelomere maintenance, while in principle possible, is inefficientat 23°C, leading to very short telomeres and incompletesynthesis of the C-rich strand, and is unable to maintain aminimal double-stranded telomeric repeat tract at 37°C.

Formally, we cannot rule out the possibility that very shorttelomeres combined with an altered DNA end structure triggera reorganization of the global telomere architecture towarda capped state that is TS. Upon shift to higher temperatures,the capping function would be lost and the ends would be recognizedas DSBs. However, we were unable to uncover such an unstablecapping state in cells with elongated telomeres (Fig. 5). Thus,in both scenarios, ultimately it is the ability to maintaina critical minimal amount of double-stranded telomeric repeatswhich is the critical determinant for the growth propertiesof Yku^- mutants at high temperature.

Cells suffering damage to their DNA activate DNA damage checkpointsin order to slow down cell cycle progression and turn on repairmechanisms. Surprisingly, Yku^- cells preincubated at 37°Cin which the RAD9-dependent checkpoint is activated are unableto form colonies, even when plates are incubated at 23°C(data not shown). Thus, despite activation of the DNA damagecheckpoints, massive cell death or permanent cell cycle arrestoccurs when Yku^- cells are incubated for prolonged periods at37°C. This suggests that the incurred damages are too importantto be repaired or that, because the chromosome ends are nowrecognized as DSBs, they are repaired as such and telomere-telomerefusions and other aberrant chromosome rearrangement events occur.Eventually, such events could lead to unrecoverable chromosomalaberrations, which would be responsible for cell death.

In summary, we found that, in the absence of the Yku complex,yeast telomeres acquire extensions of the G-rich strand independentlyof a functional telomerase and that the DNA damage checkpointmachinery is not activated by these extensions if a minimaltract of double-stranded telomeric repeats is maintained. However,upon a shift to 37°C, Yku^- cells suffer increased overalltelomere attrition, which is detrimental to cell viability.While some telomeric repeats can still be detected on chromosomalDNA derived from Yku^- cells grown at 37°C, all the dataare also consistent with the hypothesis that some chromosomeends have lost the repeats altogether. Recent results derivedfrom the analysis of DNA isolated from telomerase^- cells undergoingsenescence support a similar conclusion (35, 37). Finally, ourresults further support the notion that the regulation and coordinationof the synthesis of the G-rich strand by telomerase with thatof the C-rich strand are important for maintaining a functionaltelomeric repeat tract. The Ku complex can also be detectedon telomeres of mammalian cells (4, 39). In this context, Kuhas been postulated to suppress genomic instability, includingtelomere fusions, and oncogenesis in mice (20). Moreover, recentlyit was reported that mammalian cells lacking Ku have shortenedtelomeres as well (16). Although there are differences in theterminal DNA structures between yeast and mammalian cells, arole for Ku in the efficient replication of both strands oftelomeric repeats is consistent with the findings for both systems.Since the maintenance of functional telomeres is an essentialprocess for cell viability and since deficiencies in this processincrease susceptibility to cell transformation, the resultspresented here may be of importance for the understanding ofcomplete telomere replication in mammalian cells as well.

ACKNOWLEDGMENTS

We thank D. Gottschling, S. Elledge, J. Haber, S.-E. Lee, S.Labbé, and V. Lundblad for providing yeast strains andplasmids. We also thank Stéphanie Larose for her helpwith RNA preparations. Members of the Wellinger lab are thankedfor their continued intellectual input, and K. Runge is thankedfor his insightful comments on the manuscript.

This work was supported by CCS research grant 010049 from theNational Cancer Institute of Canada (NCIC) and a core facilitygroup grant by the Canadian Institutes of Health Research (MGC-48372).R.J.W. is a Chercheur-National of the FRSQ.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, Faculty of Medicine, Université de Sherbrooke, 3001 12 Ave. N., Sherbrooke, Quebec J1H 5N4, Canada. Phone: (819) 564-5214. Fax: (819) 564-5392. E-mail: R.Wellin{at}courrier.usherb.ca.

Present address: Wellcome/CRC Institute, Cambridge University,Cambridge CB2 1QR, United Kingdom.

REFERENCES

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