Control of the yeast telomeric senescence survival pathways of recombination by the Mec1 and Mec3 DNA damage sensors and RPA

Nathalie Grandin and Michel Charbonneau^*

UMR CNRS no. 5161, Ecole Normale Supérieure de Lyon IFR128 BioSciences Gerland, 69364 Lyon, France

^*To whom correspondence should be addressed at Ecole Normale Supérieure de Lyon, UMR CNRS 5161 46, allée d'Italie, 69364 Lyon, France. Tel: +33 47272 8170; Fax: +33 47272 8080; Email: Michel.CHARBONNEAU{at}ens-lyon.fr

Received August 17, 2006. Revised November 16, 2006. Accepted November 17, 2006.

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Saccharomyces cerevisiae telomerase-negative cells undergo homologousrecombination on subtelomeric or TG_1–3 telomeric sequences,thus allowing Type I or Type II post-senescence survival, respectively.Here, we find that the DNA damage sensors, Mec1, Mec3 and Rad24control Type II recombination, while the Rad9 adaptor proteinand the Rad53 and Chk1 effector kinases have no effect on survivortype selection. Therefore, the Mec1 and Mec3 checkpoint complexescontrol telomeric recombination independently of their rolesin generating and amplifying the Mec1-Rad53-Chk1 kinase cascade.rfa1-t11 mutant cells, bearing a mutation in Replication ProteinA (RPA) conferring a defect in recruiting Mec1-Ddc2, were alsodeficient in both types of telomeric recombination. Importantly,expression of an Rfa1-t11-Ddc2 hybrid fusion protein restoredcheckpoint-dependent arrest, but did not rescue defective telomericrecombination. Therefore, the Rfa1-t11-associated defect intelomeric recombination is not solely due to its failure torecruit Mec1. We have also isolated novel alleles of RFA1 thatwere deficient in Type I but not in Type II recombination andproficient in checkpoint control. Therefore, the checkpointand recombination functions of RPA can be genetically separated,as can the RPA-mediated control of the two types of telomericrecombination.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Telomeres, the ends of eukaryotic linear chromosomes, are requiredfor overall genome stability. Telomeric DNA is made of tandemarrays of TG-rich nucleotide repeats of variable length dependingon the organisms ( $~$ 300 bp in the yeast Saccharomyces cerevisiae,5–15 kb in humans) and kept at a constant value in a givenorganism. Telomeric proteins, organized around telomeric DNA,provide both telomere end protection and processes for accessof telomerase during telomere replication (1,2). Telomere lengthhomeostasis is crucial for two main reasons. First, removalof the terminal primer at the end of lagging-strand during DNAsynthesis leaves a small gap that cannot be filled in, a phenomenonknown as the ‘end-replication problem’ [e.g. seeRef. (3)]. Telomere replication, by a specialized reverse transcriptase,telomerase (4), solves this problem by maintaining telomeresat a constant length. Second, maintenance of telomeric tractsof a minimal size is needed for recruitment by telomeric DNAsequences of specialized telomeric proteins. The major functionof telomere end protection proteins is to prevent inappropriateaccess of DNA repair or modification proteins, such as exonucleases.The processes underlying telomere replication and telomere endprotection are intimately linked (5). For instance, in yeastand humans, both telomere erosion and telomere uncapping cantrigger telomeric senescence (6,7). Classically, inactivationof telomerase or of the yeast EST proteins trigger telomericsenescence during which telomeres shorten critically so as tolead to cell death after $~$ 75–100 generations (8,9). Telomericsenescence activates the DNA damage checkpoint that ultimatelyleads to a cell cycle arrest of the senescing cells at the G₂/Mtransition (10).

In recent years, increasing interest has been focused on a telomerase-independentmechanism for maintaining telomeric repeats that relies on homologousrecombination between the repeated telomeric DNA sequences (11,12).This pathway, first discovered in S. cerevisiae (13), allowssenescing cells deficient in telomerase function, such as estor tlc1 mutants (8,9), to maintain indefinitely functional telomeres,and, hence, viability, in the absence of telomerase. These mechanismsare receiving much attention at the moment due to the recentfinding that they are also operating in some human tumor cells,in which they are known as the alternative lengthening of telomeres(ALT) pathway (14). In S. cerevisiae, the rare cells escapingtelomeric senescence, termed post-senescence survivors, usetwo distinct pathways of recombination, based on the initialobservation that Rad52, essential for recombination (15), wasneeded for this telomerase-independent maintenance of telomeres(13). In telomerase-negative, otherwise wild-type, cells, afirst class of survivors (of type I), relying on Rad51, werefound to amplify the subtelomeric Y' elements and had very shortterminal tracts of TG_1–3 DNA, while Rad50-dependent typeII survivors amplified the terminal TG_1–3 sequences withno evidence for rearrangement of Y' elements (11,13,16). Inthe yeast Kluveromyces lactis, small rolling circles of single-or double-stranded telomeric DNA resulting from the resolutionof an intratelomeric invasion provide one mechanism that isresponsible for the generation of the long type II telomeres(12,17). Very recently, extra-chromosomal circles of DNA havealso been identified in both type I and type II post-senescentsurvivor S. cerevisiae cells (18). In addition to these recombination-dependentpathways of survival to telomeric senescence, S. cerevisiaetelomerase-negative cells have also been shown to utilize recombination-independentpathways that involved repair of DNA double-strand break bypalindromic DNA structures (19).

A number of factors have been found to affect the selectionof the survivor type in S. cerevisiae. In most of these cases,factors affecting telomere end protection or the processingof damaged telomeric DNA were implicated (11,20,21). Interestingly,the checkpoint proteins of the phosphatidyl-inositol 3-kinase-likefamily, Mec1 and Tel1 (homologues to the human ATR and ATM,respectively), have been recently found to be required for typeII recombination in S. cerevisiae (22). Here, we focused ourattention on the role of Mec1, as well as that of other checkpointproteins, in survivor type selection. We also document the roleof Replication Protein A (RPA) in telomeric recombination byanalyzing a particular allele of its larger subunit, rfa1-t11,previously reported to be defective in recruiting Mec1/ATR andDdc2/ATRIP at sites of damaged DNA (23), as well as in recombination(24). Finally, we have isolated separation-of-function rfa1mutants that exhibit checkpoint proficiency but telomeric recombinationdefects.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Yeast strains and plasmids
All strains used in this study were in the BF264-15D geneticbackground used in our laboratory (25). The rfa1::KanMX4/RFA1,chk1::KanMX4, ddc1::KanMX4, rad51::KanMX4 and rad59::KanMX4strains were purchased at Euroscarf (Frankfurt, Germany). Therfa1-t11 allele, from the Kolodner lab (24), was integratedat the RFA1 locus after cutting with NheI. In all experimentsrfa1-t11 was integrated at the RFA1 locus, after cutting withNheI. The mec1::TRP1 sml1::KanMX4 and rad53::TRP1 sml1::KanMX4mutant strains are from the Hartwell and Emili laboratories(26,27). The tlc1::LEU2 was from the Gottschling laboratory(28). The rad50::hisG-URA3-hisG strain was from the Haber laboratory(29). The rad9::LEU2 and cdc13-1 strains are from the Hartwelllaboratory (30). The clb2::LEU2 strain was from the Reed laboratory(31). The mec3::TRP1 strain was from the Lucchini laboratory(32). The rad17::URA3 and rad24::URA3 strains were from theFriedberg laboratory (33). Yeast cells were grown in yeast extract-peptone-dextrose(YEPD) medium at 30°C unless otherwise indicated. The integrativeTRP1-based pRS304 RAD53-2 HA construct (containing the last344 nt, out of 2463 nt total of RAD53), a generous gift fromAndrew Emili (26,27), was used as such and also subcloned intoYIp211 (integrative URA3 plasmid) and integrated at the RAD53locus after cutting with HpaI. The integrative YIp-352-mec1-kd(URA3) construct, containing the last $~$ 2.3 kb, out of $~$ 7.1 kbtotal, of MEC1 in which two substitutions in the kinase domain[D-A at position 2224 and N-K at position 2229 had been introduced(34,35), a kind gift from Akira Matsuura (35)], was integratedat the MEC1 locus after cutting with NruI. Actual introductionof the mutations was verified by sequencing the sequence ofinterest at the MEC1 locus. CLB2, CLB2-2 HA and RAD52 were expressedeither from an integrative, centromeric (CEN) or episomal (2µ) plasmid under the control of their own respective promoters.

Analysis of telomere organization and structure
Genomic DNAs were prepared, separated in a 0.9% agarose gel(in TBE) run in TBE buffer overnight and, after denaturation,transferred onto nitrocellulose membrane and immobilized bybaking at 80°C for 1 h, as described previously (25). Themembrane was then pre-hybridized in 6x SSC, 0.1% SDS, 1% non-fatmilk and hybridized with a 270 bp TG_1–3 ³²P-labeled telomericprobe. Following digestion with XhoI, to cut within the Y' regionsof chromosomes (36), telomere tracts of wild-type cells appearas a broad-band of $~$ 1.2–1.3 kb, which represents the averagelength of most chromosomes, those containing Y' subtelomericregions. From non-Y' chromosomes, XhoI cutting typically generatesfragments migrating at $~$ 2.1, 2.3, 3.3 and 3.9 kb in Southerns.In senescing cells, the disappearance of the non-Y' fragmentsattests to the fact that survivors have arisen by homologousrecombination [see, for instance, Ref. (16)]. In some experiments,genomic DNA was digested with a mixture of four restrictionenzymes (AluI, HaeIII, HinfI and MspI) using a 4 bp recognitionsequence and the Southern revealed with a TG_1–3 probe.Since these enzymes cut within telomeric Y' sequences but notwithin the TG_1–3 sequences, they are currently used toconfirm identification of type II telomeres (16). In some cases,a ³²P-labeled Y' probe was used. Results were analyzed usinga Storm PhosphorImager (Amersham Biosciences) and ImageQuant.

Analysis of the kinetics of senescence/survival and of growth rates
Telomerase-negative cells undergo senescence in 75–100generations (9). In all kinetics, senescence of tlc1 ${Delta}$ haploidmutant cells, and of their derivatives, was initiated afterthe tlc1 ${Delta}$ /TLC1⁺ diploids or their derivatives were induced tosporulate. In the ‘liquid assays’, selected sporesof the desired genotype were individually propagated for over100 generations as exponentially growing liquid cultures thatwere, under standard conditions, diluted to 10⁵ cells/ml everyday. In some experiments, wherever indicated, liquid culturesof senescing cells were diluted to 10⁶ or 10⁷ cells/ml everyday, as described previously (31). Under such conditions, telomericsenescence took place in the liquid culture, thus resultingin a mixture of both possible survivor types and allowing theconversion from types I to types II that normally occurs intelomerase-negative cells, due to a selective growth advantageof types II (16). In ‘streak assays’, which allowedthe detection of both type I and type II survivors, re-streakingof single colonies on a YEPD agar-based plate was repeated every48 h (typically, cells underwent $~$ 25 generations per streakoutor passage at 29°C) to allow loss of viability and appearanceof survivors (16,37). The occurrence of senescence was determinedfrom analyzing the progression with time of the growth rateor from the appearance of post-senescence survivors on the plates,as well as from the analysis of telomere structure by Southernblotting with a telomeric probe, as described above.

Construction of fusion proteins
Plasmids expressing the Rfa1-t11-Rad52, Rfa1-t11-Ddc2 and Rfa1-t11-HAin-frame fusion proteins were constructed by cloning in a single-copy,centromeric, plasmid the entire ORF of the first part of thehybrid protein plus upstream promoter sequences, in front ofthe ORF, (which included its natural stop codon) of the secondpart of the hybrid protein, as described previously (38). Thecodon for the first amino acid of the second protein in thehybrid construct was directly following the codon for the lastamino acid of the first protein, in reading frame with it.

Construction of checkpoint-proficient, recombination-deficient alleles of RFA1
The entire RFA1 ORF plus 267 bp upstream of the ATG and 306bp downstream of the stop codon were amplified by PCR underthe following mutagenic conditions. The concentration of dNTPswas either kept as in standard conditions (200 µM each)or one of the dNTP concentration changed to 500 µM, thoseof the other three were kept to 200 µM and, in both cases,the concentration of MgCl₂ was changed from 1.5 to 3.0 or 4.0mM. Standard Taq polymerase and PCR buffer (Invitrogen) wereused. Following a 30-cycle amplification, the PCR products werecleaned and, according to the gap repair method, transformeddirectly into rfa1::Kan-MX4 YCp33-RFA1-URA3 (including promotersequences, ORF and post-stop sequences) strains, together withanother centromeric LEU2 plasmid (YCp111) made linear by digestionwith NdeI and carrying RFA1 flanking regions at each extremity:region –267 to +166 (position of an endogenous NdeI site)at one end, and region +2000 to +2169 (position of another endogenousNdeI site) (the TAA stop codon starts at position +1861) atthe other end. Thus, sequences upstream and downstream of RFA1were available for homologous recombination, while all of RFA1ORF (with the exception of the first 166 bp) were availablefor PCR-based mutagenesis. Cells were plated onto leucine-lackingmedium at 25°C. Around 10 000 transformants grew up whichwere transferred to leucine-lacking liquid medium and then platedon 5-FOA-containing medium at 25°C in order to force theloss of the YCp33-RFA1-URA3 plasmid. Growing colonies were thenre-streaked on YEPD medium and then analyzed for possible defectsin telomeric recombination, as explained above, after introduction,by crossing, of a telomerase-negative (tlc1 ${Delta}$ ) mutation. Selectedmutants were again crossed to a cdc13-1 strain that also containedRAD53-2 HA integrated at the RAD53 genomic locus and checkpointactivation assessed by analyzing Rad53 phosphorylation followingimmunoprecipitation and western blotting using anti-HA antibodies,as explained below.

Immunoprecipitation and immunoblotting
Proteins were immunoprecipitated from yeast cell extracts andseparated by electrophoresis, as described previously (39).All strains analyzed harbored a chromosomal copy of RAD53 taggedin 3' with 2 HA epitope, the corresponding integrative plasmidbeing a generous gift from Andrew Emili (26,27). Mouse monoclonalanti-HA raw ascites fluid (BabCo, 16B12, Eurogentec) and mouseanti-HA monoclonal 12CA5 antibody (Roche) were used for immunoprecipitationand western blotting, respectively. Monoclonal mouse anti-actinantibody (clone C4) from MP Biomedicals was purchased at ICNPharmaceutical. Blotted proteins were detected by chemifluorescencevia fluorescein-labeled anti-mouse secondary antibodies anda tertiary anti-fluorescein alkaline phosphatase conjugate (ECFwestern blotting kit, Amersham Biosciences) and signals analyzedusing a Storm PhosphorImager (Amersham Biosciences) and ImageQuant.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Checkpoint proteins affect recombination in survivors from telomerase-negative cells
A very small percentage of S. cerevisiae telomerase-negativecells (here we used tlc1 ${Delta}$ cells, deleted for the RNA subunitof telomerase, throughout) survive telomere erosion by performingrecombination between telomeric sequences (13). Two types ofrecombination can be generated (Figure 1A). Type I involvesrecombination between the homologous subtelomeric sequencesY' and, in telomerase-negative, otherwise wild-type, cells,is Rad51-dependent, while type II involves recombination betweenthe telomeric TG_1–3 sequences and is Rad50- and Rad59-dependent(11). It is currently agreed, as previously explained in detail(16,22), that the type I telomere pattern is most easily visualizedby XhoI digestion Southern blot analysis. XhoI cleaves 0.9 kbfrom the 3' end of the Y' element yielding a $~$ 1.3 kb terminalfragment corresponding to the distal part of the Y' elementplus the $~$ 0.3–0.4 kb of terminal TG_1–3 tracts (Figure 1A).In type I survivors, the TG_1–3 terminal tracts have becomeeroded and the XhoI-restricted terminal fragment is now $~$ 0.9–1.0kb long (Figure 1A). In contrast to type I survivors, type IIsurvivors exhibit many XhoI fragments of different sizes [Figure 1A;(16,22)]. The terminal part of the Y' elements contain shortTG_1–3 tracts, allowing type I survivors to be also convenientlydetectable with a TG_1–3 probe [Figure 1A; (16)]. Althoughtype II survivors grow better than type I survivors, $~$ 90% oftlc1 ${Delta}$ surviving cells display type I telomeres when grown onsolid (agar-based) media [Figure 1A; (16)]. On the other hand,and most importantly for the experiments described below, whentlc1 ${Delta}$ surviving cells are grown in liquid medium, 100% type IIcells are typically recovered (Figure 1A), because, due to theirfaster growth, which is similar to that of wild-type cells,they quickly overtake the population of type I survivors (16).

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Figure 1 (A) Survivors from telomerase-negative (tlc1) cells show two distinct patterns. Genomic DNAs from wild-type cells (no recombination, lane 1), type II (lane 2) and type I (lane 3) senescing tlc1 ${Delta}$ cells were digested with XhoI and the Southern blot revealed with a TG_1–3 ³²P-labeled probe. In both types of survivors, the disappearance of the non-Y' fragments (migrating at $~$ 2.1, 2.3, 3.3 and 3.9 kb) attests to the occurrence of homologous recombination. In type II survivors, XhoI cutting reveals amplification of very long and heterogeneous TG_1–3 sequences (lane 2), located more distal than the single XhoI site that is present at the distal part of Y' sequences (16). In contrast, in type I survivors telomere erosion is evident after XhoI cutting (lane 3) in comparison with the mean size of the terminal telomere tracts in wild type corresponding to the broad band at $~$ 1.2 kb (lane 1), the amplified Y' sequences being located more proximal than the XhoI site, as schematically represented. (B) Mec3 inhibits the generation of type II survivors in liquid assays. Individual spores from tlc1 ${Delta}$ mec3 ${Delta}$ strains were grown in liquid YEPD for $~$ 130 generations, at 29°C, with a daily dilution of 10⁵ cells/ml (see Materials and Methods). The conversion from types I to types II that is readily seen in liquid culture of telomerase-negative, otherwise wild-type, cells (16) was largely inhibited in the absence of Mec3. Thus, the samples shown in lanes 12 and 13 were the only two ones, among the 15 ones shown here, to exhibit many XhoI fragments of different sizes, which entitle them as type II survivors, those amplifying the TG_1–3 tracts. tlc1 ${Delta}$ MEC3⁺ cells generated 100% type II survivors (data not shown), like shown for wild-type cells in (A) above. Analysis of telomere structure, as described above in (A), allowed to classify these 15 tlc1 ${Delta}$ mec3 ${Delta}$ spores according to the type of recombination accomplished, I or II, as labeled below each lane.

Telomerase-negative cells also bearing a null mutation in theMEC3 checkpoint gene had difficulties in generating type IIcells, even in liquid medium. Thus, when grown in liquid richmedium for about 130 generations (crisis occurs $~$ 80–100generations after inactivation of telomerase), only $~$ 20% of tlc1 ${Delta}$ mec3 ${Delta}$ cells displayed type II telomeres versus 100% of type IIfor the tlc1 ${Delta}$ MEC3⁺ control (Table 1; Figure 1B). We verifiedthat in the mec3 ${Delta}$ background type II survivors also grew betterthan type I survivors (data not shown). The Mec3 complex (Ddc1and Rad17 are the other two components) represents, togetherwith the Mec1–Ddc2 complex, DNA damage sensors (40,41).The Mec1 and Mec3 complexes are recruited independently to DNAdouble-strand breaks (42,43). Interestingly, telomerase-negativecells bearing a mec1 ${Delta}$ mutation have been previously shown tobe deficient in type II recombination (22). To better documentthe relationships between telomeric recombination and the DNAdamage checkpoint, we next constructed additional checkpoint-negativetelomerase-negative double mutants and analyzed their patternof telomeric recombination after extended propagation in liquidcultures. Among these, tlc1 ${Delta}$ rad17 ${Delta}$ , tlc1 ${Delta}$ rad24 ${Delta}$ and tlc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ , similarly to tlc1 ${Delta}$ mec3 ${Delta}$ , had difficulties in generatingtype II survivors after crisis. On the other hand, tlc1 ${Delta}$ rad9 ${Delta}$ ,tlc1 ${Delta}$ rad53 ${Delta}$ sml1 ${Delta}$ and tlc1 ${Delta}$ chk1 ${Delta}$ were fully proficient in typeII recombination (Table 1). It should be noted that Rad24 isrequired for the loading of the Mec3–Ddc1–Rad17complex (44,45). The Rad9 checkpoint adaptor and the Rad53 andChk1 effector kinases are subsequently activated after the Mec1and Mec3 complexes have bound damaged DNA (40,41). It appears,therefore, that among the different classes of checkpoint proteins,only the DNA damage sensors have an effect on the type of telomericrecombination. In agreement with the finding above that in mutantsof the Mec3 complex type II recombination, although diminished,was still possible, we recovered 100% type II survivors afterRAD51 had been deleted in the tlc1 ${Delta}$ rad17 ${Delta}$ mutant (Table 3).

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Table 1 Survival type frequencies in checkpoint-defective telomerase-negative double mutants^a

Mec1 is, together with Tel1 (homologues of ATR and ATM in humans,respectively), a protein kinase of the phosphatidyl-inositol3-kinase-like family (46). In budding yeast, phosphorylationof target checkpoint proteins by Mec1 is necessary for initiatingthe DNA damage response (26,34,47–49). To know whetherMec1 protein kinase activity was required for the control oftype II telomeric recombination described above, we used a kinase-deadmec1 (mec1-kd) mutant (34,35). After verifying by sequencingactual introduction of the mec1-kd mutation at the MEC1 locusin our wild-type background, as well as associated-hypersensitivityto the genotoxic agent methyl methane sulfonate (MMS) and concomitantfailure to activate endogenous Rad53-HA (data not shown), weconstructed the tlc1 ${Delta}$ mec1-kd sml1 ${Delta}$ mutant strain and analyzedits survivor type during post-senescence. Only around one-thirdof the tlc1 ${Delta}$ mec1-kd sml1 ${Delta}$ senescing cells generated type II survivorsin liquid cultures, in contrast with the usual 100% type IIin the tlc1 ${Delta}$ MEC1⁺ control (data not shown). We conclude that,in this assay, the mec1-kd mutation behaves like a null mec1mutation and, therefore, the control of telomeric recombinationnecessitates Mec1 protein kinase activity.

Overexpression of CLB2 rescues the defect in type II recombination conferred by a mutation in the Mec3 complex
A null mutation in CLB2, coding for the major S. cerevisiaeB-type cyclin, as well as temperature-sensitive mutations inCDC28 (Cdk1), were recently found to confer a defect in typeII telomeric recombination (31), similar to those found herefor mec1 ${Delta}$ and mec3 ${Delta}$ mutants. We reasoned that both mechanismsmight be related and set out to establish a functional linkbetween the two events. To this end, we overexpressed CLB2 froman episomal plasmid (under the control of its native promoter)in tlc1 ${Delta}$ ddc1 ${Delta}$ double mutants. As expected, because Ddc1 is acomponent of the Mec3 complex, tlc1 ${Delta}$ ddc1 ${Delta}$ mutants were deficientin type II recombination (Table 2; Figure 2A). We noted thatin these experiments with CLB2 overexpression, some of the samplesdid not exhibit as clear-cut type I characteristics as usual(Figure 2A). This may have been due to the fact that these cellswere cultivated on selective medium to maintain the plasmidwithin the cells, thereby generating poorer growth and lessefficient recombination. However, under identical conditions,overexpression of CLB2 could rescue the defect conferred byddc1 ${Delta}$ in telomerase-negative cells to the same extent as it didin rescuing the defect of CLB2-deleted telomerase-negative cells(Table 2; Figure 2A). We therefore conclude that the defectin type II recombination conferred by a mutation in the Mec3complex might be functionally related to that conferred by adeficit in Cdc28-Clb2.

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Figure 2 Overexpression of CLB2, the major B-type mitotic cyclin gene, rescues type II telomeric recombination in tlc1 ${Delta}$ ddc1 ${Delta}$ mutant cells. (A) Telomerase-negative cells (tlc1) bearing a null mutation in either CLB2 (clb2) or DDC1 (ddc1), as indicated, and also overexpressing or not CLB2 (2 µ plasmid, under endogenous promoter) were propagated in liquid cultures for $~$ 130 generations, from the time the strains were created, at 29°C. As usual, this procedure resulted in the generation of 100% type II survivors in telomerase-negative cells (tlc1) due to the growth advantage of types II over types I in liquid cultures (survivor type has been labeled below each lane). tlc1 ${Delta}$ clb2 ${Delta}$ mutants were defective in generating type II survivors, as reported previously (31), as were tlc1 ${Delta}$ ddc1 ${Delta}$ mutants. Overexpression of CLB2 partially corrected that defect in both tlc1 ${Delta}$ clb2 ${Delta}$ and tlc1 ${Delta}$ ddc1 ${Delta}$ . It is important to note that tlc1 ${Delta}$ clb2 ${Delta}$ mutants were somewhat sick and grew poorly, hence the difficulty in obtaining optimal amounts of DNA for nice signals. XhoI cutting and a TG_1–3 ³²P-labeled probe were used. (B) Endogenous Clb2 levels remain unchanged in the absence of DDC1. Cell extracts from pre-senescent telomerase-negative cells bearing or not a mutation in DDC1, both harvesting CLB2-HA integrated at CLB2 locus, were immuno-precipitated with anti-HA antibody and processed for western blotting with anti-HA antibody. Various dilutions of samples were loaded, as indicated, in order to better appreciate possible variations in Clb2 levels. Quantification was done using ImageQuant. (C) Overproduced Clb2 levels are slightly decreased when DDC1 has been deleted. Immuno-precipated CLB2-HA, expressed from a multi-copy (episomal) plasmid under the control of native promoter in pre-senescent tlc1 ${Delta}$ clb2 ${Delta}$ and tlc1 ${Delta}$ ddc1 ${Delta}$ mutants to serve as a control for the experiment shown above in (A), was detected as described above. The fate of these six individual clones after post-senescence recombination had occurred was followed by Southern (XhoI cutting, TG_1–3 ³²P-labeled probe). For each strain, two type II and one type I survivors were recorded, as shown in the lower panel.

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Table 2 Effect of CLB2 overexpression on survival type frequencies^a

Possible cell cycle alterations in Clb2 levels could be invokedto explain the type II recombination defects in telomerase-negativecells bearing a mutation in the Mec3–Ddc1–Rad17complex. To evaluate this possibilty, we measured Clb2 levelsby immunoprecipitation of endogenous CLB2-HA in the tlc1 ${Delta}$ ddc1 ${Delta}$ and tlc1 ${Delta}$ mutants. Clb2 levels did not vary in the absence ofDdc1 (Figure 2B). We also assessed CLB2-HA levels followingoverexpression from a multi-copy plasmid, the same conditionsas those used for determining the survivor type in these mutants(Figure 2A). Similar levels of overproduced Clb2 from one isolateto the other in both strains (Figure 2C) indicated that, underthese experimental conditions, comparing the survivor type invarious mutants, as shown in Figure 2A, is technically relevant.This was expected as in the multi-copy plasmid, CLB2-HA wasunder the control of its native promoter, like in the integrativeplasmid. In addition, we observed that Clb2 levels were slightlydecreased in the absence of Ddc1 (Figure 2B). This may reflecta slight effect of the ddc1 ${Delta}$ mutation on endogenous Clb2 levels,but detectable only at higher levels of expression for reasonsof increased sensitivity. Alternatively, this may reflect theexsitence of a mechanism of control of CLB2 expression in thischeckpoint-deficient mutant.

We next evaluated the possibility that the type II defect observedin telomerase-negative cells bearing a mutation in the Mec3–Ddc1–Rad17complex might in fact reflect alterations in the type I recombinationmachinery. For instance, it was possible that the intracellularlevels of Rad51, (which controls type I recombination) wereincreased in these mutants and that this could affect telomericrecombination. To test this hypothesis, we overexpressed RAD51(from a multi-copy, episomal, plasmid) in various strains andanalyzed the pattern of telomeric recombination. This had novisible effect as tlc1 ${Delta}$ single mutants overexpressing RAD51 stillcontinued to produce 100% type II survivors, while overexpressionof RAD51 in tlc1 ${Delta}$ rad17 ${Delta}$ double mutants did not alter their rateof type II defect (data not shown). It is therefore unlikelythat the type II defect conferred by a mutation in the Mec3–Ddc1–Rad17complex is due to this complex somehow inhibiting Rad51 at thetelomeres.

RPA controls both types of telomeric recombination
RPA, a single-stranded DNA-binding protein essential for DNAreplication, has been implicated in a number of DNA metabolismreactions (50,51). RPA is generally considered to be the initialsensor of DNA damage (23,52), but, because some studies havefound that Rad51 (53) or Mre11 (54) were recruited first atDNA double-strand breaks, the issue is still the matter of debate(50). RPA has been evolutionary conserved and, in humans, consists,of three subunits, RPA70, RPA32 and RPA14, homologues in S.cerevisiae to Rfa1, Rfa2 and Rfa3, respectively. In yeast andhumans, RPA binds single-stranded DNA generated after resectionof DNA double-strand breaks, then Ddc2/ATRIP, thereby loadingthe Mec1–ATR complex and activating the checkpoint (23).Numerous mutants of RFA1, mainly, have been isolated based ontheir sensitivity to genotoxic stress, defects in various typesof recombination or in DNA replication. Because RPA has beenrecently shown to recruit Ddc2-Mec1 at sites of DNA damage,a function lost in the rfa1-t11 mutant (23), we chose to usethe rfa1-t11 (K45E) mutant to further document the mec1 ${Delta}$ -inducedtelomeric recombination defect described above. Moreover, rfa1-t11-induceddefects in recombination and adaptation to DNA damage have beendescribed (15,24,50,55). As detailed in Table 3 (see also Figure 3),telomerase-negative cells bearing the rfa1-t11 mutation wereseverely affected in telomeric recombination events. Incidentally,survivors (all of type I) from tlc1 ${Delta}$ rfa1-t11 mutants appearedwhen the liquid cultures were propagated using a lower dilution[10⁷ cells/ml every 24 h; Table 3; the rate of dilution hasrecently been proven to be important in such experiments; Ref.(31)]. However, intriguingly, deletion of RAD51 (essential fortype I recombination in telomerase-negative, otherwise wild-type,cells) in tlc1 ${Delta}$ rfa1-t11 mutants still allowed the productionof survivors (Table 3). Although we have not directly testedwhether Y' elements were amplified in these tlc1 ${Delta}$ rfa1-t11 mutants,the absence of any amplification of TG_1–3 sequences (Figure 3,last lane), together with the existence of only two types oftelomeric sequences being amplified in telomerase-negative cells,namely Y' and TG_1–3 (16), most probably identify thesesurvivors as type I survivors. The complete absence of any survivorin senescing tlc1 ${Delta}$ rfa1-t11 rad59 ${Delta}$ mutants indicated that thisrfa1-t11-associated type I recombination (atypically) reliedon the Rad59 pathway (Table 3).

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Figure 3 Effects of the recombination-deficient, checkpoint-deficient rfa1-t11 mutation on telomeric recombination. Analysis of telomere organization and structure by Southern blotting (see Materials and Methods), in the strains (of the indicated relevant genotype), plus a wild-type non-senescing control strain (wt, lane 1). Mutant cells were propagated in liquid cultures, at 29°C, until senescence took place and beyond (a total of $~$ 130 generations), with a daily dilution of 10⁷ cells/ml. The survivor type, determined according to criteria described in Materials and Methods and in Figure 1A, is indicated under each lane. XhoI cutting and a TG_1–3 ³²P-labeled probe were used.

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Table 3 Pattern of telomeric recombination in telomerase-negative rfa1-t11 mutants^a

Targeting Rad52 at Rfa1-t11 binding sites restores type I, but not type II, recombination
Some aspects of type II recombination are still very mysteriousbecause the Rad51 recombinase, essential for strand invasion,is dispensable during these homologous recombination processes(11,15,17). Interactions between RPA and Rad51 (and Rad52) arerelatively well understood (15,50). On the other hand, the putativerole of RPA in type II telomeric recombination is totally unknown.As Rad52 participates in -and is essential for- both type Iand type II recombination (13,16,56), we set out to determinewhether targeting Rad52 at the sites for binding of the recombination-deficientRfa1-t11 protein would have the same effect on these two typesof recombination. Expression of fusion (hybrid) proteins hasbeen shown to represent a valuable tool to decipher telomericpathways (38,57). Here, we constructed an rfa1-t11-RAD52 chimericgene and expressed it, together with the appropriate controlconstructs, in tlc1 ${Delta}$ rfa1-t11 mutants. Survivors from tlc1 ${Delta}$ rfa1-t11p-rfa1-t11-RAD52 were generated, in the liquid assay, whiletlc1 ${Delta}$ rfa1-t11 mutants did not generate survivors at all underidentical conditions (Figure 4B). Under the usual criteria,these survivors appeared to be of type I, with the reserve,however, that bands in the 2.0–3.0 kb range were stillpresent in some isolates (Figure 4A, left panel). In both typesof survivors, the disappearance of the non-Y' fragments (migratingat $~$ 2.1, 2.3, 3.3 and 3.9 kb) attests to the occurrence of homologousrecombination (16). Since in tlc1 ${Delta}$ rfa1-t11 p-rfa1-t11-RAD52cells, some of these bands were still visible, we set out tofurther characterize these survivors. To this end, the sameblot as that shown in Figure 4A (left panel) was reprobed withan Y' probe. The telomeric fragments migrating at $~$ 1.1 kb, representativeof type I recombination (Figure 1A), were heavily labeled overthe background (Figure 4A, left panel). We also digested thegenomic DNA from the tlc1 ${Delta}$ rfa1-t11 p-rfa1-t11-RAD52 cells witha mixture of four base cutter restriction enzymes that is sometimesused to identify type II recombination on the TG_1–3 substrate[(16); see also Materials and Methods]. This also identifiedthese survivors as type I survivors (Figure 4A, middle panel).Finally, the survivors from the tlc1 ${Delta}$ rfa1-t11 p-rfa1-t11-RAD52strain depended on Rad51 for their maintenance (Figure 4B),as do normal survivors from telomerase-negative, otherwise wild-type,cells. Therefore the Rfa1-t11-Rad52 fusion protein does rescuetelomeric recombination but leaves cells with an rfa1-t11-associatedspecific defect in type II recombination.

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Figure 4 Targeting Rad52 at the sites of DNA damage restores type I, but not type II, recombination in tlc1 ${Delta}$ rfa1-t11 mutants. (A) Pattern of telomeric recombination in tlc1 ${Delta}$ rfa1-t11 cells carrying the rfa1-t11-RAD52 fusion construct on a centromeric plasmid. Left two panels: Seven different isolates from tlc1 ${Delta}$ rfa1-t11 p-rfa1-t11-RAD52 (lanes 3–9 in both panels) plus a wild-type, non senescing, strain (lane 1 in both panels) and a tlc1 ${Delta}$ strain having recombined with a type I (lane 2 in both panels) are illustrated. Cells were grown in liquid cultures for about 200 generations, at 29°C, after the senescence crisis and processed for Southern blot analysis using either a telomeric TG_1–3 (leftmost panel) or Y' probe (rightmost panel) following DNA digestion with XhoI in both cases. In leftmost panel, non-recombining DNA fragments, that appear to be non-Y' fragments have been labeled with a black dot on the leftmost panel. These bands were not detected when the blot was re-probed with a probe detecting Y' sequences (rightmost panel). Middle panel: Genomic DNAs from the same cells as those shown above in the left two panels were digested with a mixture of restriction enzymes (AluI, HaeIII, HinfI and MspI) using a 4 bp recognition sequence and the Southern revealed with a TG_1–3 probe. This allowed to discriminate between type I and type II recombination because these enzymes do not cut within TG_1–3 sequences (16). The slow migrating bands (labeled with the black dots in the leftmost panel) were no longer visible on the four base cutter blot, indicating that these bands are not the result of some limited type II recombination. DNAs from type II (lane 1) or type I (lane 11) survivors from a tlc1 ${Delta}$ strain are shown for comparison. Right panel: Overexpression of RAD52, from a 2 µ episomal plasmid under the control of native promoter also rescued telomeric recombination in tlc1 ${Delta}$ rfa1-t11 cells. Only type I survivors were recovered. (B) tlc1 ${Delta}$ rfa1-t11 cells expressing the rfa1-t11-RAD52 fusion from a centromeric plasmid (or the rfa1-t11-HA control or plasmid alone), as indicated, or expressing RAD52 from a low-copy (centromeric) plasmid (row 3) or from a multi-copy (episomal) plasmid (row 6), were propagated in liquid cultures for 10 days, at 29°C, with a dilution to 10⁶ cells/ml every 24 h, before re-streaking on plates to assess survival. Both YCp-rfa1-t11-RAD52 and YEp-RAD52 (but not YCp-RAD52) restored telomeric recombination, which, in both cases, was of type I (data not shown). No survivors were generated in the absence of RAD51 (row 5). Therefore, type I recombination in tlc1 ${Delta}$ rfa1-t11 p-rfa1-t11-RAD52 cells is conventional in the sense that it is Rad51-dependent.

To try to confirm these findings above, we also performed experimentswith RAD52 expressed from a plasmid. Interestingly, overexpressionof RAD52 from a multi-copy (episomal) plasmid also rescued therecombination defect in tlc1 ${Delta}$ rfa1-t11 cells, only type I butnot type II, like the Rfa1-t11-Rad52 fusion protein (Figure 4A and B).Importantly, slight overexpression of RAD52 from a centromericplasmid (the same sort as that used for the rfa1-t11-RAD52 fusionexperiments described above) did not rescue the recombinationdefect in tlc1 ${Delta}$ rfa1-t11 cells (Figure 4B). Therefore, in theexperiments with the rfa1-t11-RAD52 fusion, the effect of Rad52on telomeric recombination is really due to targeting to rfa1-t11'sbinding sites and not merely to moderate increase in its intracellularamounts. In summary, targeting of Rad52 to Rfa1-t11's bindingsites with two different strategies produce the same phenotype,namely selective rescue of telomeric recombination.

An Rfa1–t11–Ddc2 fusion protein restores the checkpoint function of rfa1-t11 cells but not its recombination function
RPA and Rad52 are likely to interact functionally and physically,thereby modulating the interactions between RPA and Rad51 duringrepair of double-strand breaks by homologous recombination (15,50),as well as during type I telomeric recombination, as seen above.Since in wild-type cells, RPA recruits Mec1-Ddc2 at the sitesof DNA double-strand breaks, an event that is defective in rfa1-t11mutant cells (23), and since mec1 ${Delta}$ cells are defective in typeII recombination [(22); present data], we next wanted to determinewhether failure of the Rfa1-Ddc2 interaction in rfa1-t11 wasresponsible for the type II recombination defect in this mutant.Because we were confident that fusion proteins implicating Rfa1-t11could be reliable, as seen above, we decided to use an Rfa1–t11–Ddc2fusion protein to target Mec1-Ddc2 at the sites of telomericdamage. First, we determined whether the hybrid protein couldrescue the checkpoint defect of the rfa1-t11 mutation in thecdc13-1 background (58). We did not expect to rescue the lethalityconferred by the absence of DDC2 (59–61) with this chimericprotein, but only aimed at trying to restore Rfa1-t11's defectin Ddc2 binding without interfering with other Ddc2 functions.Consequently, these experiments were performed in a DDC2⁺ background.cdc13-1 rfa1-t11 cells expressing the rfa1-t11-DDC2 fusion constructclearly grew less at 29°C than when expressing the plasmidalone, but still grew better than cdc13-1 cells, thereby suggestingpartial re-establishment of a functional DNA damage checkpoint(Figure 5A).

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Figure 5 Restoration of rfa1-t11 checkpoint defect by targeting of Ddc2 does not correct the rfa1-t11-induced defect in telomeric recombination. (A) Growth of cdc13-1 rfa1-t11 strains transformed each with a centromeric plasmid expressing the indicated fusion construct at 29°C. Growth of checkpoint-proficient cdc13-1 (lane 1) and checkpoint-deficient cdc13-1 rad9 ${Delta}$ (lane 2) mutants is shown for comparison. Rescue of the checkpoint defect of cdc13-1 rfa1-t11 by plasmid bearing rfa1-t11-DDC2 is suggested by re-acquisition of the cdc13-1-induced growth arrest at 29°C. See text for explanations. (B) Activation of Rad53 assessed by visualizing electrophoretic mobility alterations after western-blot analysis of immunoprecipitated cell extracts using anti-HA antibodies. Strains of the indicated relevant genotype were grown at the temperature of 24 or 34°C (permissive or fully restrictive for growth of cdc13-1 cells, respectively). The non-phosphorylated Rad53 band, as well as the first two bands of phosphorylated Rad53, representing the first two levels of activation of Rad53, are indicated by bars in the right margin. Additional bands representing higher levels of activation of Rad53 could also be detected in the cdc13-1 control (lane 2 of 34°C). All strains carried endogenous RAD53-HA integrated at the RAD53 locus. See text for explanations. (C) The rfa1-t11-DDC2 fusion construct (expressed from a centromeric plasmid) did not restore defective recombination in tlc1 ${Delta}$ rfa1-t11 mutant cells. Cells were propagated in liquid cultures for 10 days, at 29°C, with a dilution of the cultures to 10⁶ cells/ml every 24 h. tlc1 ${Delta}$ rfa1-t11expressing p-rfa1-t11-HA were used as a control.

Improved growth of cdc13-1 cells can result not only from checkpointinactivation, but also from diminished amounts of damaged DNA,such as in exo1 ${Delta}$ mutants, for instance (62). Since RPA is likelyto readily affect processing of damaged DNA and to control exonucleases,we set out to assess checkpoint activation in a different manner.The phosphorylation state of Rad53, an event that reflects itsactivation (63,64), was visualized by western blotting usinganti-HA antibodies in strains in which a RAD53-HA fusion genehad been introduced at the RAD53 locus. As expected, Rad53 wasmassively phosphorylated in cdc13-1 mutant cells at 34°C,but not at 24°C, and this signal was absent in cdc13-1 rad9 ${Delta}$ cells at either temperature (Figure 5B). In cdc13-1 rfa1-t11cells, Rad53 phosphorylation was intermediate between thesetwo fully active and inactive states (Figure 5B), in agreementwith the previous finding that the rfa1-t11 allele is not completelydefective in checkpoint activation (58). Importantly, Rad53exhibited a higher degree of phosphorylation in cdc13-1 rfa1-t11cells bearing the rfa1-t11-DDC2 construct than in cdc13-1 rfa1-t11cells expressing the control fusions or plasmid alone (Figure 5B).Indeed, an additional Rad53 shifted band was present in theformer sample compared with the control samples (Figure 5B).Increased Rad53 activation in cells expressing the Rfa1–t11–Ddc2fusion was also evident from the observation of a decrease inthe intensity of the Rad53 lower band (Figure 5B). Altogether,these data indicated that the Rfa1–t11–Ddc2 fusionprotein is capable of restoring, at least partially, the DNAdamage checkpoint.

We next asked whether the rfa1-11-DDC2 construct could curethe rfa1-t11-associated telomeric recombination defects. tlc1 ${Delta}$ rfa1-t11 cells bearing the rfa1-t11-DDC2 construct were unableto generate any survivors at all (Figure 5C), as observed intlc1 ${Delta}$ rfa1-t11 cells under identical conditions (Table 3; Figure 4B).Thus, partial rescue of Rfa1-t11's checkpoint defect by theRfa1–t11–Ddc2 fusion protein does not result inconcomitant rescue of telomeric recombination. At this point,we hypothesized that the interaction between RPA and Mec1-Ddc2might be important for operating some processes only of typeII recombination. We therefore set out to provide rfa1-t11 mutantswith a functional Rad52 machinery and determine whether therfa1-t11-DDC2 fusion could now make type II recombination work.tlc1 ${Delta}$ rfa1-t11 cells co-expressing RAD52 and the rfa1-t11-DDC2fusion could generate type I survivors, as observed above withthe rfa1-t11-RAD52 construct alone, but were still unable toproduce type II survivors (data not shown). These data suggestthat the telomeric recombination defect conferred by rfa1-t11does not result from improper recruitment of Ddc2-Mec1 at damagedtelomeres. Moreover, a functional interaction between RPA andthe Mec1-Ddc2 checkpoint complex does not appear to play anyrole in promoting the functioning of the Rad51-dispensable typeII recombination, even when functional Rad52 is present.

RPA might compete with Cdc13 for the occupancy of the telomeric TG_1-3 substrate
cdc13-1, a temperature-sensitive mutation in CDC13, coding fora single-stranded telomeric DNA-binding protein exhibiting affinityexclusively for TG_1–3 sequences (65), generates largestretches of single-stranded telomeric DNA at semi-permissiveand restrictive temperatures (30). We reasoned that making moretelomeric TG_1–3 substrate available within the cell mightrescue the type II recombination defect conferred by the rfa1-t11mutation. Although a null mutation in RAD17 (coding for a memberof the Mec3 complex) affects type II recombination in a tlc1 ${Delta}$ background, as seen above, it had no apparent effect on typeII recombination in the cdc13-1 tlc1 ${Delta}$ background (Table 3; Figure 6),in agreement with previous results (6). We next conducted similarexperiments using the rfa1-t11 mutation. In the cdc13-1 tlc1 ${Delta}$ rfa1-t11 strain, survivors were generated at the 10⁵ cells/mldilution (Table 3). By Southern analysis, telomeres of the cdc13-1tlc1 ${Delta}$ rfa1-t11 strain were of type II (Figure 6A). Therefore,presumably, the increase in single-stranded telomeric DNA provokedby the cdc13-1 mutation compensates for the defects conferredby the mec3 ${Delta}$ , rad17 ${Delta}$ and rfa1-t11 mutations in type II recombinationby providing more TG_1–3 substrate normally masked by Cdc13,as previously proposed (6). Interestingly, the cdc13-1 tlc1 ${Delta}$ rfa1-t11 rad17 ${Delta}$ survivors displayed type I telomeres (Figure 6).The most likely explanation is that the rfa1-t11 and rad17 ${Delta}$ mutationimpinge on type II recombination in an additive manner, actingin parallel pathways, such that type I recombination remainsthe only possible mechanism.

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Figure 6 The cdc13-1 mutation corrects the rad17 ${Delta}$ - and rfa1-t11-induced defects in telomeric recombination. (A) Telomere structure and organization of one or several representative survivors of the indicated relevant genotype. Survivor type after culturing in liquid medium for around 150 generations, as determined by usual criteria (see Materials and Methods and Figure 1A), is indicated for each strain below each lane. In all three panels, lane 1 is from a wild-type (wt) non-senescing control. See text for explanations. (B) Strains of the indicated relevant genotype were grown for 12 days in liquid cultures at 25°C and diluted every 24 h to 10⁵ cells/ml. Every day, cells were spotted on agar plates to assess survival. After post-senescence survival had been attained for all strains, on day 12, cells were prepared for determination of survivor type, indicated for each strain on the right, by Southern (data not shown). In both A and B, XhoI cutting and a TG_1–3 ³²P-labeled probe were used.

We next asked whether Mec1 was acting through the RPA pathwayor the Mec3-Ddc1-Rad17 pathway. To answer this question, weset out to analyze the effects of combining the mec1 ${Delta}$ sml1 ${Delta}$ andrad17 ${Delta}$ mutations, as well as the mec1 ${Delta}$ sml1 ${Delta}$ and rfa1-t11 mutations,both in a cdc13-1 tlc1 ${Delta}$ background, and asked which one of thesemutants would behave like the cdc13-1 tlc1 ${Delta}$ rfa1-t11 rad17 ${Delta}$ mutantin which cdc13-1-induced type II recombination is no longerpossible, as seen above. The cdc13-1 tlc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ rad17 ${Delta}$ mutantgenerated type II survivors, just like the cdc13-1 tlc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ control (Figure 6A, middle panel). Unfortunately, we couldnot analyze the cdc13-1 tlc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ rfa1-t11 survivors becausethis strain was inviable. However, the finding that combiningthe mec1 ${Delta}$ sml1 ${Delta}$ and rad17 ${Delta}$ mutations now results in type II recombination,unlike that of combining the rad17 ${Delta}$ and rfa1-t11 mutations (Figure 6A,left panel), strongly suggests that Mec1 functions in the samepathway as the Mec3–Ddc1–Rad17 complex, or at leastin an overlapping pathway, in these processes.

We attempted to use the same logic to determine in which pathwayof telomeric recombination control Clb2 was acting. To thisend, various mutant strains combining a clb2 ${Delta}$ mutation and themec1 ${Delta}$ sml1 ${Delta}$ , rfa1-t11 or rad17 ${Delta}$ mutations, all in the cdc13-1 tlc1 ${Delta}$ background, were constructed. The analysis of the type of telomericrecombination in these mutants, shown in Figure 6A, indicatedthat they all generated type II survivors. This data suggeststhat the Clb2 pathway may overlap with both the RPA, Mec1 andMec3 pathways.

RPA's checkpoint and recombination functions are genetically separable
The finding above that Rfa1-t11 with a partially restored checkpointfunction still conferred complete defect in telomeric recombinationsuggested that these two functions of RPA might be distinct.To address this point, we set out to isolate rfa1 mutants that,unlike rfa1-t11, which is deficient in both the checkpoint andrecombination functions, would be defective in either one (seeMaterials and Methods). We could isolate four rfa1 mutants,that we call rfa1-1, rfa1-9, rfa1-10 and rfa1-11, that wereaffected in telomere recombination but remained checkpoint-proficient,on the basis of their ability to activate Rad53 at a level similarto that in cdc13-1 RFA1 cells (Figure 7A and C; rfa1-12, anothermutant isolated in the same screen is shown as a checkpoint-proficient,recombination-proficient allele). In agreement with this observation,these rfa1 mutants did not exhibit significant hypersensitivityto MMS (Figure 7B). Interestingly, these mutants were specificallydeficient in type I recombination, as they produced 100% typeII survivors in the ‘streak assay’ (Figure 7C),a situation in which, in most strain backgrounds, includingours, $~$ 90% of the survivors are of type I when grown on agar-basedmedium (6,16).

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Figure 7 Four novel rfa1 mutants, rfa1-1, rfa1-9, rfa1-10 and rfa1-11, that are deficient in telomeric recombination are nevertheless checkpoint-proficient. (A) Activation of Rad53, a protein kinase with a pivotal role in the DNA damage response, was measured in these four mutants, in the cdc13-1 background (lanes 3–6) as well as in negative controls (cdc13-1 rad9 ${Delta}$ , lane 2 and cdc13-1 rfa1-t11, lane 9) and positive controls (checkpoint-proficient cdc13-1 mutants, lane 1 and cdc13-1 rfa1-t11 expressing RFA1, lane 8), as described in the legend to Figure 5B). rfa1-12 (lane 7) is another mutant isolated in the same mutagenic screen. (B) rfa1-9, rfa1-10, rfa1-11 and rfa1-12 mutants are not hypersensitive to a genotoxic stress, unlike rfa1-t11 and ddc1 ${Delta}$ mutants. 10-fold serial dilutions (from left to right in each row) of cultures of the relevant indicated genotype that have been treated (in liquid) by MMS, as indicated, prior to spotting on agar plates. (C) tlc1 rfa1 mutants were continuously grown, at 29°C, on agar-based medium immediately after sporulation of the diploids. Cells were re-streaked every 48 h and allowed to reach senescence, after which cells were processed for genomic DNA preparation and determination of the survivor type (‘streak assay’, see Materials and Methods), an assay in which the vast majority of survivors is of type I (see text for explanations). The rfa1-1, rfa1-9, rfa1-10 and rfa1-11, but not rfa1-12, mutants were deficient in generating type I survivors in this assay. XhoI cutting and a TG_1–3 ³²P-labeled probe were used.

DNA sequencing revealed that rfa1-1 and rfa1-9 contained multiplepoint mutations (Table 4). We have not been able so far to identifythe mutations responsible for the phenotypes of the correspondingmutants.

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Table 4 Sequence analysis of the amino acid changes in the rfa1-1 and rfa1-9 alleles

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Telomere length homeostasis is critical to the maintenance ofa stable genome (2,3). In the absence of telomerase, telomeresprogressively shorten, thus losing their protective proteins,and eventually fuse together and break during chromosome segregation,leading to death by senescence (8). Rare cells survive thistelomeric senescence by performing recombination between telomericor subtelomeric sequences (11). In budding yeast, telomericrecombination can be affected by mutations in DNA polymerases,a helicase, an exonuclease, a linker histone, telomere end protectionproteins, telomere length control proteins, checkpoint proteinkinases, cyclin-dependent kinase, non homologous end joininggenes and by mating type (11,20–22,31,37,66–68).The present data reveal that, upon loss of telomerase function,the DNA damage sensors Mec1, Rad24 and Mec3 can affect telomererecombination in a pathway distinct from that initiating theMec1-Rad53-Chk1 kinase cascade normally culminating, upon DNAdamage, in cell cycle arrest. This study has also provided insightsinto how the evolutionary conserved DNA repair/replication/checkpointRPA complex is involved in promoting cell proliferation by controllingtelomeric recombination.

Control of telomeric recombination by DNA damage checkpoint proteins
Here, we find that a subset of checkpoint proteins, namely Mec1[also found in a previous study, Ref. (22)], Mec3-Ddc1-Rad17and Rad24, are required for optimal operation of type II telomericrecombination. On the other hand, inactivation of, either RAD9,RAD53 or CHK1 had no impact on telomeric recombination. Inactivationof one of the latter genes totally or partially (Rad53 and Chk1function in parallel pathways both requiring Rad9) preventsactivation of the whole DNA damage response. In particular,the kinase cascade that goes from Mec1 to Rad53 and Chk1 is,of course, interrupted (40,41). Therefore, the whole checkpointresponse is not required for the correct control of telomericrecombination by checkpoint proteins. Mec1 kinase activity,which is absolutely necessary for the functioning of the downstreamcheckpoint components (26,48), was indispensable for these events.This observation leaves open the possibility that Mec1 couldact in these pathways by phosphorylating a member of the MRX(Mre11–Rad50–Xrs2) complex or Rad59, as proposedpreviously (22). In the present situation, the Mec1-dependentDNA damage checkpoint response was shown to branch out earlyduring the process of damage recognition, initiating two separatepathways, one that results in the activation of the kinase cascadeand cell cycle arrest, the second one that activates type IIrecombination. This is not unprecedented as, for instance, mec1 ${Delta}$ tel1 ${Delta}$ double mutants underwent telomeric senescence (69), whilesingle or double mutants of the downstream checkpoint componentsdo not. We propose that Mec1 and Mec3, once loaded onto damagedDNA, affect its conformation. They might, for instance, bendit so as to create conformations compatible with access of proteinssubsequently needed for type II recombinational events, suchas Mre11, Rad50, Xrs2, Rad59 or other as yet unidentified proteins.

Recently, rad24 ${Delta}$ mutants were shown to exhibit a marked delayin the processing and repair of broken ends at a DNA double-strandbreak, independently of their defect in G₂/M arrest (70). Theresulting low survival, not observed in rad9 ${Delta}$ , chk1 ${Delta}$ and pds1 ${Delta}$ mutants, was also observed in rad17 ${Delta}$ , mec3 ${Delta}$ , mec1 ${Delta}$ , and noticeably,in rad53 ${Delta}$ dun1 ${Delta}$ mutants (70). On this basis, the mechanisms describedhere by which Rad24, Mec1 and Mec3, but not Rad53, control telomericrecombination appear to differ from the mechanisms of resectionof sequences at a broken end described by Aylon and Kupiec (70).Moreover, in the study by Aylon and Kupiec (70), Rad51-dependentevents of recombination were analyzed, whereas in the presentstudy the defects conferred by the rad24 ${Delta}$ , mec3 ${Delta}$ and mec1 ${Delta}$ mutationsconcerned a pathway of recombination which, in telomerase-negative,otherwise wild-type, cells, is completely Rad51-independent(71). At telomeres, some checkpoint proteins have also beenshown to affect the processing of single-stranded DNA that isproduced after cdc13-1-induced telomeric damage (72). It hasnow been established that Mec1, Rad53 and Rad9 inhibit degradationof telomeric DNA by preventing formation of abnormal single-strandedDNA in these cells, while, on the opposite, Mec3, Rad17 andRad24 promote degradation of telomeric DNA (73). In fact, humanRad1 and Rad9 (homologues to S. cerevisiae Rad17 and Ddc1) haveindeed been shown to possess exonuclease activity (74). Therefore,a member of the Mec3 DNA damage sensor complex could potentiallybe involved in controlling telomeric recombination via processingdamaged structures specifically used for Rad50-, Rad59-dependentrecombination.

Although Rad9 also accumulates at double-strand breaks in aMec1-dependent manner (75), the rad9 ${Delta}$ mutation, unlike the mec1 ${Delta}$ mutation, was not found here to affect telomeric recombination.However, it should be noticed that another study found thatRad9 focus formation was only partially affected in mec1 ${Delta}$ mutants(54). In fission yeast, Crb2 (the homologue of S. cerevisiaeRad9) also physically associated with double-strand breaks (76).Recruitment of Crb2 could be accomplished in the absence ofRad1 and Rad3, (respectively, Rad17 and Mec1 in S. cerevisiae)but necessitated their presence to remain attached (76). Therefore,the physical presence of a checkpoint protein at the sites ofdamaged DNA is not a sufficient criterion to take into accountas determining a positive action on type II recombination. TheMec1 and Mec3 DNA damage sensors may therefore be endowed withspecific properties that entitle them to affect type II recombination.

In telomerase-negative, otherwise wild-type, cells, type IIrecombination takes place on TG_1–3 repeats and is operatedvia the MRX complex, Rad59 and Rad52 (11,56,71). Type II recombinationis interesting on a mechanistic point of view because it doesnot require the intervention of the Rad51 recombinase, the onlyprotein capable of strand invasion during homologous recombination.Rolling-circle replication primed by an intrachromosomal telomericD-loop has been proposed as the basis for type II recombination(11,12,17,71,77). The observation made here that cdc13-1 rescuesthe rad17 ${Delta}$ -induced defect in type II recombination demonstratesthe possibility of efficient recombination on TG_1–3 sequencesin the absence of the Mec3 complex. This strongly argues thatthe unusual predominance of type I survivors in tlc1 ${Delta}$ mec3 ${Delta}$ cellsis due to the impairment of the Rad50 pathway in the absenceof Mec3 rather than to an impairment of recombination per se.Noticeably, type II recombination in tlc1 ${Delta}$ rad17 ${Delta}$ was restoredafter RAD51 had been deleted, leaving open the possibility thatRad51 might inhibit type II recombination in wild-type cellsand that deletion of a member of the Mec3 complex might affecttelomeric recombination through changing Rad51 levels. However,control experiments indicated that variations in Rad51 levels,induced by overexpressing RAD51, had no effect on telomericrecombination and were, therefore, probably not responsiblefor the observed defect in type II recombination in these mutants.Since Rad52 is essential for type II recombination, unlike MRXand Rad59, which can substitute for each other in this process(56,71,78), it has been speculated that Rad52 might performthe annealing activity involved in D-loop formation (78). Clearly,however, Rad52 cannot be the defective target in mec1 ${Delta}$ and mec3 ${Delta}$ mutants, as if this was the case, then these mutants would alsobe deficient in type I recombination, Rad52 being essentialfor both types of recombin

Nucleic Acids Research

Molecular Biology

Control of the yeast telomeric senescence survival pathways of recombination by the Mec1 and Mec3 DNA damage sensors and RPA