Mrc1 Is Required for Sister Chromatid Cohesion To Aid in Recombination Repair of Spontaneous Damage

The SRS2 gene of Saccharomyces cerevisiae encoding a 3' $->$ 5' DNAhelicase is part of the postreplication repair pathway and functionsto ensure proper repair of DNA damage arising during DNA replicationthrough pathways that do not involve homologous recombination.Through a synthetic gene array analysis, genes that are essentialwhen Srs2 is absent have been identified. Among these are MRC1,TOF1, and CSM3, which mediate the intra-S checkpoint response.srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality is due to inappropriate recombination,as the lethality can be suppressed by genetic elimination ofhomologous recombination. srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality is dependenton the role of Mrc1 in DNA replication but independent of therole of Mrc1 in a DNA damage checkpoint response. mrc1 ${Delta}$ , tof1 ${Delta}$ and csm3 ${Delta}$ mutants have sister chromatid cohesion defects, implicatingsister chromatid cohesion established at the replication forkas an important factor in promoting repair of stalled replicationforks through gap repair.

INTRODUCTION

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Introduction

The SRS2 gene of Saccharomyces cerevisiae encodes a DNA helicasewith a 3' $->$ 5' polarity (36). Genetic studies have placed SRS2in the postreplication DNA repair pathway (1, 25, 37). SRS2is not an essential gene but is required for complete meioticviability (1, 33). Mitotically, srs2 ${Delta}$ mutants have increasedspontaneous gene conversion rates but are only modestly sensitiveto DNA-damaging agents (1, 25, 37). These phenotypes suggestthat Srs2 is involved in regulating a cellular response to spontaneousDNA damage. Indeed, recent in vitro studies have confirmed aproposed negative regulation of recombination by Srs2 (23, 53).Srs2 can destabilize Rad51 nucleoprotein filaments, therebydestroying homologous recombination strand exchange intermediatesand allowing other repair pathways such as translesion synthesisor template switching to repair DNA gaps.

Although the Srs2 protein is not essential for wild-type yeastcells, in certain mutant strains the SRS2 gene is very importantor essential. The synthetic lethalities known for the srs2 ${Delta}$ mutantinclude sgs1 ${Delta}$ (9, 20), rad54 ${Delta}$ (1, 37), rad50 ${Delta}$ , mre11 ${Delta}$ , xrs2 ${Delta}$ (1,20, 37), top3 ${Delta}$ (6, 20), rad27 ${Delta}$ (5), and pol32 ${Delta}$ (13). In addition,there are haploid srs2 ${Delta}$ synthetic sickness interactions whichare enhanced to lethality in the diploid state. The most notableof these is the interaction with the rdh54 ${Delta}$ mutation (21, 38).Most of these lethalities are due to inappropriate or aberranthomologous recombination, as they can be suppressed by mutationof genes that encode products required for the early steps ofhomologous recombination. The exception to the list above isthe rad27 ${Delta}$ srs2 ${Delta}$ synthetic lethality, but as the rad27 ${Delta}$ singlemutant requires an intact homologous recombination pathway forsurvival, suppression cannot be tested (5).

SRS2 expression begins in late G₁ and peaks during S phase (12).Expression can be induced by DNA-damaging agents but only inthe G₂ phase of the cell cycle (12). These observations, alongwith genetic studies of the srs2 ${Delta}$ mutant and the biochemicalstudies of the protein, have led to the proposal that the Srs2protein functions during DNA replication to aid in the repairof single-strand gaps caused by replication fork stalling andto prevent the formation of toxic recombination intermediatesthat initiate at the sites of the single-strand gaps. Indeed,Srs2 protein is phosphorylated by DNA damage checkpoint kinasesin response to intra-S DNA damage (27). Moreover, srs2 ${Delta}$ mutantstrains do not activate the Rad53 checkpoint kinase in responseto intra-S DNA damage (27).

The mechanisms of gap filling and replication restart are notentirely known. Gap filling is proposed to occur through theaction of the error-free branch of the postreplication repairpathway (14, 41) and Srs2 is proposed to aid in promoting useof this pathway by antagonizing homologous recombination initiation.Gap filling may occur through translesion synthesis, templateswitching, or fork reversal or through homologous recombinationwith the sister chromatid. The last three mechanisms all proposeintermediates, which involve pairing of the newly replicatedDNA strands, with one newly replicated strand used as a templatefor replication of the blocked nascent strand. Since sisterstrands are involved, it might be expected that a structuremay be assembled at the site of the damage or stalled replicationfork to promote the sister chromatid interactions.

Sister chromatid cohesion is established during S phase as replicationpasses through a chromosomal region (18, 29, 40, 47, 49). Althoughfactors such as hemicatenes of the nascent sister strands (24,28, 42) and full intercatenation of sister chromatids may beinvolved in promoting sister chromatid cohesion, the actualcohesion is achieved through the binding of a protein cohesioncomplex containing Scc1, Scc3, Smc1, and Smc3 (10, 48). Timelydeposition of sister cohesion complex is essential for properchromatid cohesion and chromosome segregation in M phase (49).If cohesions are expressed in G₂, they may associate with thechromatids but do not provide the proper support for sisterchromatid cohesion and accurate segregation at mitosis (49).In addition to ensuring correct chromatid segregation in mitosis,cohesions are necessary for postreplication repair and genomicstability (43).

To further understand the role of Srs2 in promoting postreplicationrepair and replication fork restart, we have undertaken a large-scalescreen for novel srs2 ${Delta}$ synthetic lethal interactions (46). Amongthe synthetic lethal interactions that we identified were mrc1 ${Delta}$ ,tof1 ${Delta}$ and csm3 ${Delta}$ plus mutations in the Ctf18 RFC-like complex encompassingthe ctf18 ${Delta}$ , ctf8 ${Delta}$ , ctf4 ${Delta}$ , and dcc1 ${Delta}$ mutants. A recent paper witha microarray-based screen for srs2 ${Delta}$ synthetic lethal interactionsalso reported on the mrc1 ${Delta}$ , tof1 ${Delta}$ and cms3 ${Delta}$ group of mutants andthe ctf4 ${Delta}$ mutant (31). The Ctf18 RFC-like complex loads PCNAonto DNA (3). The Ctf18 RFC-like complex is proposed to havea specialized role in DNA replication during some type of polymeraseswitch to activate cohesion complexes associated with unreplicatedDNA to form sister chromatid cohesion interactions as the replicationfork passes through the associated cohesion complex (29).

Mrc1 and Tof1 are checkpoint proteins involved in transmittingthe DNA replication arrest signal to downstream effectors (2,8, 44). Mrc1 activates the Rad53 kinase in response to replicationstress and is itself phosphorylated by the Mec1 kinase. A secondrole for Mrc1 has recently been described. Mrc1 and Tof1 areassociated with undamaged replication forks and move with theforks (17, 32). The association is independent of the checkpointactivity but is thought to be the first sensor for stalled replicationforks to recruit Mec1 to sites of stalled replication. Tof1and Csm3 interact in a two-hybrid assay and by coimmunoprecipitation(15, 30), and csm3 ${Delta}$ mutants have mitotic phenotypes similar tothat of a tof1 ${Delta}$ mutant regarding activation of Rad53 kinase andcell cycle arrest following replication fork stalling (46).Thus, it is likely that Csm3 forms a complex with Tof1 at thereplication fork and that Csm3-Tof1 collaborates with Mrc1 tomediate Rad53 signaling.

In this paper we show that the srs2 ${Delta}$ mrc1 ${Delta}$ /tof1 ${Delta}$ /csm3 ${Delta}$ lethalityis due to aberrant homologous recombination and that this isalso the case for the srs2 ${Delta}$ lethality with the Ctf18 complexcomponents. Additionally, we show that mrc1 ${Delta}$ strains have a defectin sister chromatid cohesion and propose that attempted repairof replication fork damage through homologous recombinationrequires sister chromatid cohesion at the site of damage. Thesefindings suggest a model in which Mrc1 with Csm3-Tof1 sets upthe establishment of a cohesion complex at the site of damageon a stalled replication fork.

MATERIALS AND METHODS

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Materials and Methods

Synthetic genetic array analysis. Synthetic genetic array analysis was carried out as describedpreviously (45). Briefly, a MAT ${alpha}$ synthetic gene array startingstrain containing srs2 ${Delta}$ ::natR (MAT ${alpha}$ srs2 ${Delta}$ ::natR can ${Delta}$ 1::MFA1pr-HIS3his3 ${Delta}$ 1 leu2 ${Delta}$ 0 lys2 ${Delta}$ 0 ura3 ${Delta}$ 0) was used to identify viable gene deletionsthat show synthetic genetic interactions with srs2 ${Delta}$ . Each syntheticgene array screen was conducted three times, and the resultantdouble mutants were scored for synthetic genetic interactionsby both visual inspection and computer-based image analysis.The putative synthetic genetic interactions were confirmed byrandom spore analysis first, and the interactions that appearedto be inconclusive were tested by tetrad dissection as describedpreviously (46).

Strains. The strains used for genetic crosses were in the W303 RAD5 backgroundand carried the leu2-3,112 his3-11,15 trp1-1 ura3-1 ade2-1 can1-100markers. The strains used for recombination assays have beendescribed previously (22, 35). The mrc1 ${Delta}$ mutant was made by KanMX4disruption of the MRC1 coding region with a PCR product derivedwith primers 5'-GCTCTGTCGCCGAAAATTCCTATAATTCCAACGGAACTTATTGGACGTACGCTGCAGGTCGAC-3'and 5'-AAAGGATTTGATTATTGATGGATGTTTGAAAACGCCAACTAGTGAATCGATGAATTCGAGCTCG-3'.All strains are isogenic to W303 with the exception of someof the sister chromatid cohesion mutant strains. All strainswere grown at 30°C. The mrc1-AQ strain was a kind gift fromSteven Elledge.

Genetic methods. Methylmethane sulfonate (MMS) sensitivity was determined withfreshly made YPD plates containing 0.016% MMS. Overnight culturesof strains to be tested were serially diluted, and 3-µlaliquots of each dilution were applied to YPD and YPD-MMS plates.Growth was assessed after 1, 2, and 3 days at 30°C. Fluctuationtests were done by the median method (26) and were repeatedthree to five times for each genotype. Recombination rates andchromosome loss rates were determined by fluctuation tests aspreviously described (22, 35). All media were prepared as describedpreviously (22).

Assessing sister chromatid cohesion. yko ${Delta}$ ::kanMX alleles were amplified by PCR and introduced intostrains YPH1477 (Tet operator array located 35 kb from CEN5)(MATa ade2-1 trp1-1 can1-100 his3-11,15 leu2::LEU2tetR-GFP ura3::3xURA3tetO112PDS1-13Myc-TRP1), Y819 (Tet operator array located 12.7 kb fromCEN4) (MATa ade2-1 leu2-3,112 can1-100 ura3-1 trp1-1::lacO-TRP::lacO-LEU2his3-11,15::GFP-lacI-HIS3), and YPH1444 (Tet operator arraylocated 1.8 kb from CEN15) (MATa ade2 his3 trp1 ura3 leu2 can1lacI-NLS-GFP::HIS3 lacO::URA3::CEN15) by transformation (30).All mutants were verified by PCR assays.

YPH1477 Tet repressor-GFP/Tet operator repeat strains. Strains were grown logarithmically overnight in YPD, collectedby centrifugation, and resuspended in pH 3.9 YPD medium with2 µg of ${alpha}$ -factor per ml for 2 h at 30°C to arrest cellsin G₁. Cells were then collected by centrifugation and washedwith normal-pH YPD medium once before being arrested in G₂/Mwith 15 µg of nocodazole per ml for 1 h at 30°C. Cellpellets were then collected by centrifugation and fixed in 4%paraformaldehyde for 5 min, washed once with SK buffer (1 Msorbitol, 0.05 M K₂PO₄), and resuspended in SK for cohesionassessment. Cells were briefly sonicated prior to microscopicexamination for a cohesion defect. For the strains showing acohesion defect, the frequency of cells containing two greenfluorescent protein (GFP) dots was assayed in G₁-synchronizedcells in order to rule out the possibility of aneuploidy.

Y819 and YPH1444 Lac repressor-GFP/Lac operator repeat strains. Strains were grown logarithmically overnight in YPD, collectedby centrifugation, and resuspended in pH 3.9 YPD medium with2 µg of ${alpha}$ -factor per ml in G₁ for 1.5 h at 30°C. Cellswere then collected by centrifugation and washed with syntheticmedium lacking histidine and resuspended in pH 3.9 SC lackinghistidine with 2 µg of ${alpha}$ -factor per ml and 25 mM 3-aminotriazolefor 30 min at 30°C to induce the Lac repressor-GFP fusionprotein that is expressed from the HIS3 promoter. Cells werethen collected by centrifugation, washed, and resuspended inYPD with 15 µg of nocodazole per ml for 1 h at 30°Cto arrest cells in G₂/M. Cells were then fixed and processedfor the cohesion assay as described above.

Pds1 assay. Pds1 tagged with 13 Myc epitopes (Pds1-13Myc) was detected byindirect immunofluorescence in nocodazole-arrested and paraformaldehyde-fixedcells with anti-Myc antibodies (Roche) as described previously(30). The presence or absence of the Pds1-13Myc signal was determinedin cells containing two separated GFP dots to ensure that cellshad not initiated anaphase. Between 80 and 90% of cells withtwo GFP dots had high levels of Pds1 by this assay. At least20 two-dot cells were examined for each strain with the chromosomeV cohesion reporter (YPH1477 derivatives).

RESULTS

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Results

Synthetic lethality interactions with srs2 ${Delta}$ . To identify additional genes requiring SRS2 for viability, weperformed a synthetic genetic array analysis on an srs2 mutant(45, 46). In total, 26 genes were confirmed as positive by randomspore analysis and by tetrad analysis (Fig. 1). Most genes inthis list are involved in different DNA repair pathways in processingreplication fork stalling, consistent with SRS2's cellular rolein regulating the cellular response to spontaneous DNA damage(4). Strikingly, many genes involved in chromosome cohesionswere identified: MRC1, TOF1, CSM3, DCC1, CTF8, CTF18, and CTF4.Dcc1, Ctf8, and Ctf18 form an alternative RFC complex and functionin the establishment of chromosome cohesion (3). Mrc1 andTof1are associated with complexes at the replication fork, whichmay participate in both replication and the S-phase checkpoint(17, 32). The cohesion roles of MRC1 and TOF1 have recentlybeen identified (30, 54). CSM3 is a newly discovered gene requiredfor efficient cohesion. Csm3 interacts physically with Tof1(30) and also participates in the S-phase checkpoint (46).

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FIG. 1. SRS2 genetic interactions. Genome-wide synthetic genetic screens with srs2 ${Delta}$ identify genes involved in DNA repair and sister chromatid cohesion. The results of synthetic genetic array analysis with srs2 ${Delta}$ are presented as a genetic interaction map. Lines connecting genes represent synthetic lethality or synthetic slow growth. Colored circles designate the cellular role of the interacting genes.

Since Mrc1, Tof1, and Csm3 have multiple roles, it is importantto identify why they are essential when Srs2 is missing. Ctf4is another cohesion establishment factor, being essential incohesion and having some role in DNA replication (11). Thesesynthetic interactions suggest that spontaneous repair eventsoccurring in the absence of the Srs2 protein require sisterchromatid cohesion. Since homologous recombination is increasedin the absence of Srs due to the loss of the Srs2 Rad51 filament-destabilizingactivity, one possibility is that appropriate homologous recombinationrequires sister chromatid cohesion, even in haploid cells. Thecohesion roles of Mrc1, Tof1, and Csm3 could be linked to S-phasecheckpoint function in that they may aid in establishment ofcohesion at sites of replication stalling.

mrc1 ${Delta}$ /tof1 ${Delta}$ /csm3 ${Delta}$ lethality with srs2 ${Delta}$ is due to inappropriate homologous recombination. Since most of the srs2 ${Delta}$ synthetic lethal interactions are dueto excess or inappropriate homologous recombination, we testedwhether the srs2 ${Delta}$ synthetic lethality with mrc1 ${Delta}$ , tof1 ${Delta}$ , or csm3 ${Delta}$ arose from a similar homologous recombination problem by askingif loss of homologous recombination could suppress the syntheticlethality. As shown in Fig. 2A, rad51 ${Delta}$ suppresses srs2 ${Delta}$ in allthree mutant situations. Similar results were obtained witha rad52 ${Delta}$ mutation (data not shown). It can also be seen thatthe srs2 ${Delta}$ tof1 ${Delta}$ and srs2 ${Delta}$ csm3 ${Delta}$ double mutants are able to forma microcolony, while the srs2 ${Delta}$ mrc1 ${Delta}$ double mutant rarely grewfor more than eight generations. To test whether the srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality was due to loss of the Srs2 DNA helicaseactivity, we examined an srs2 allele that is mutated at theWalker A box and is specifically defective in the helicase activity(22a, 23). The srs2K41A mrc1 ${Delta}$ mutations are lethal (Fig. 2B),showing that a strain deficient in Mrc1 requires the Srs2 DNAhelicase activity for viability. Thus, some Srs2 function requiringATP hydrolysis becomes essential when Mrc1, Tof1, or Csm3 ismissing. We propose that this function is the Srs2 antirecombinaseactivity of Rad51 filament destabilization.

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FIG. 2. srs2 ${Delta}$ synthetic interaction with mrc1 ${Delta}$ , tof1 ${Delta}$ , and csm3 ${Delta}$ . (A) The srs2 ${Delta}$ synthetic interactions are suppressed by loss of homologous recombination with a rad51 ${Delta}$ mutation. Five tetrads from each cross are shown. The circles mark the double mutants srs2 ${Delta}$ mrc1 ${Delta}$ , srs2 ${Delta}$ tof1 ${Delta}$ , and srs2 ${Delta}$ csm3 ${Delta}$ . The squares mark the triple mutants srs2 ${Delta}$ mrc1 ${Delta}$ rad51 ${Delta}$ , srs2 ${Delta}$ tof1 ${Delta}$ rad51 ${Delta}$ , and srs2 ${Delta}$ csm3 ${Delta}$ rad51 ${Delta}$ . In each cross, the triple mutant grew better than the double mutant. The strains used were HKY1307-12C (srs2 ${Delta}$ rad51 ${Delta}$ ), HKY1253-15C (mrc1 ${Delta}$ ), HKY1375-1D (tof1 ${Delta}$ ), and HKY1374-2A (csm3 ${Delta}$ ). (B) The circles mark the double mutant srs2K41A mrc1 ${Delta}$ . The srs2K41A mutant is mutated in the Walker A box, is defective in ATP binding, and has no DNA helicase activity or Rad51 filament removal activity (52). The strains used were HKY1435 (srs2K41A) and HKY1336-9B (mrc1 ${Delta}$ ).

Recombination and genomic instability in the mrc1 ${Delta}$ mutant. Srs2 DNA helicase has been shown to reverse Rad51 filaments(23, 53). The helicase is thought to regulate the repair ofspontaneous damage by antagonizing Rad51 filaments and preventinghomologous recombination events. The observation that the srs2 ${Delta}$ mrc1 ${Delta}$ lethality is due to homologous recombination suggests thatexcess homologous recombination, even in a strain containingfunctional Srs2, would be deleterious. To test this, we inducedoverexpression of Rad51 from a GAL1 promoter, reasoning thatif there is excess Rad51 protein, the endogenous Srs2 proteinwould not be able to reverse all of the Rad51 filaments. Indeed,we observed that the mrc1 ${Delta}$ SRS2 strain showed reduced growthwhen RAD51 expression was increased (Fig. 3). This finding supportsthe hypothesis that recombination in an mrc1 ${Delta}$ strain can be detrimentalto cell growth. We suspect that Mrc1 has no role in the recombinationprocess per se, as mrc1 ${Delta}$ mutants show no increase in MMS sensitivity(data not shown), a phenotype associated with all known recombination-defectivemutants.

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FIG. 3. High-copy-number expression of Rad51 reduces the viability of an mrc1 ${Delta}$ strain. Transformants carrying a GAL1-RAD51 plasmid were streaked on SC-glucose or SC-galactose plates lacking leucine. The control galactose plate shows transformants with an empty GAL1 vector to verify that the mrc1 ${Delta}$ mutant was defective in growth on galactose-containing medium. The strains used were HKY1093-5A (MRC1) and HKY1235-15C (mrc1 ${Delta}$ ).

The mrc1 ${Delta}$ mutant grows slightly more slowly than an MRC1 strain(2). This could be the result of elevated recombination levels,which we have shown above to be deleterious. Therefore, we determinedthe recombination rate in a mrc1 ${Delta}$ haploid strain with a recombinationreporter for intrachromosomal gene conversion and for deletionsbetween direct repeats, which result primarily from single-strandannealing. mrc1 ${Delta}$ has wild-type levels of gene conversion, butdeletion events are increased sixfold (Fig. 4). These may reflectan increased occurrence of spontaneous double-strand breaks.We also determined genomic instability rates in a mrc1 ${Delta}$ diploidstrain, measuring spontaneous chromosome loss and recombination(22). We found little increase in the mrc1 ${Delta}$ mutant, with chromosomeloss being marginally increased 2.8-fold over that of the wildtype (from 2.0 x 10^–6 to 5.6 x 10^–6) and recombinationby mitotic crossing over and break-induced replication increased2.4-fold over that of the wild type (from 1.4 x 10^–5 to3.4 x 10^–5). Since chromosome loss was not increased inthe mrc1 ${Delta}$ mutant, the loss of Mrc1 at the replication fork doesnot lead to chromosome missegregation. Nonetheless, the increasein single-strand annealing suggests that there is a significantincrease in spontaneous double-strand breaks in the mrc1 ${Delta}$ mutant.Since Mrc1 has been reported to act at replication forks (17,32), the implication is that replication forks are more proneto breakage in the absence of Mrc1.

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FIG. 4. Intrachromasomal recombination assay. Each strain carried the recombination reporter leu2-ri::URA3::leu2-bsteii, which has a heteroallelic duplication of LEU2, with URA3 between the LEU2 genes. Gene conversion was determined by fluctuation tests, measuring Leu⁺ Ura⁺ rates. The deletion rate was determined by fluctuation tests, measuring fluoroorotic acid resistance rates. Each test was performed with nine colonies and done three times for each genotype, with three spore segregants for each genotype. The strains used were HKY1538-2C, HKY1538-6A, and HKY1538-10A for the wild type, HKY1505-1C, HKY1505-6B, and HKY1505-7B for mrc1 ${Delta}$ , HKY1538-1A, HKY1538-5C, and HKY1538-12A for mrc1-AQ, and HKY1323-1B and HKY1323-12D for srs2 ${Delta}$ .

mrc1 ${Delta}$ srs2 ${Delta}$ synthetic lethality is not due to a replication checkpoint defect. MRC1 has been proposed to function during DNA replication arrestto transmit the replication arrest signal to downstream effectors(17, 32). mrc1 ${Delta}$ mutants have a replication checkpoint defectin that Rad53 kinase is not fully activated in an mrc1 ${Delta}$ mutantwhen replication is inhibited by hydroxyurea treatment. To testif the replication checkpoint defect associated with mrc1 ${Delta}$ contributesto mrc1 ${Delta}$ srs2 ${Delta}$ lethality, we analyzed three different checkpoint-defectivestrains. First, we examined the phenotype of the srs2 ${Delta}$ rad53 ${Delta}$ sml1 ${Delta}$ mutant, reasoning that Rad53 is an essential factor inthe replication stress checkpoint response and acts downstreamof Mrc1 (2). We found that the srs2 ${Delta}$ rad53 ${Delta}$ sml1 ${Delta}$ mutant had nogrowth defect (Fig. 5A). Second, we tested whether the Mec1kinase was required for srs2 ${Delta}$ viability by asking if an srs2 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ strain was viable. We found that this strain had nogrowth defect (data not shown), further reinforcing the ideathat loss of Srs2 and the associated increase in recombinationare not in themselves lethal and do not elicit a DNA damagecheckpoint response.

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FIG. 5. srs2 ${Delta}$ interactions with replication checkpoint defective mutants. (A) Five tetrads are shown from each cross. The circles in the top panel, srs2 ${Delta}$ sml1-1 (HKY1369-2D) x rad53 ${Delta}$ sml1-1 (HKY987-2B), mark rad53 ${Delta}$ sml1-1 spore segregants. The squares in the top panel mark srs2 ${Delta}$ rad53 ${Delta}$ sml1-1 spore segregants. The circles in the lower panel, srs2 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ (HKY1494-7A) x mrc1 ${Delta}$ sml1 ${Delta}$ (HKY1239-26A), mark srs2 ${Delta}$ mrc1 ${Delta}$ sml1 ${Delta}$ spore segregants. The squares in the lower panel mark srs2 ${Delta}$ mrc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ spore segregants. (B) Five tetrads are shown from the cross srs2 ${Delta}$ (HKY1303-1B) x mrc1-AQ (HKY1534-3C). The circles mark mrc1-AQ segregants. The squares mark srs2 ${Delta}$ mrc1-AQ spore segregants. (C) Four tetrads are shown from the cross srs2 ${Delta}$ mad3 ${Delta}$ (HKY1371-7D) x mrc1 ${Delta}$ (HKY1235-21D). The circle marks an srs2 ${Delta}$ mrc1 ${Delta}$ spore segregant. The squares mark srs2 ${Delta}$ mrc1 ${Delta}$ mad3 ${Delta}$ spore segregants.

Third, we examined an allele of MRC1, mrc1-AQ, in which allthe TQ and SQ motifs that are phosphorylation targets of theMec1 kinase have been mutated to AQ residues. The Mrc1-AQ proteinstill associates with the replication fork but is deficientin the replication checkpoint response (32). The srs2 ${Delta}$ mrc1-AQdouble mutant had normal viability (Fig. 5B), showing that theessential function of Mrc1 in an srs2 ${Delta}$ strain is not the replicationcheckpoint response. Thus, Mrc1 must have another function thatis essential in an srs2 ${Delta}$ mutant. Even though Mrc1 and Srs2 havebeen implicated in the intra-S checkpoint response for induceddamage (2, 27, 44), these do not appear to be required underconditions of spontaneous damage. We suggest that it is theprocessing of damage intermediates through homologous recombinationthat requires the Mrc1 protein.

We then tested whether elimination of the Mec1 DNA damage checkpointfactor would rescue the srs2 ${Delta}$ mrc1 ${Delta}$ lethality. We observed thatthe srs2 ${Delta}$ mrc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ mutations were lethal (Fig. 5A), showingthat the srs2 ${Delta}$ mrc1 ${Delta}$ double mutant growth defect was not due toa checkpoint arrest. Microscopic inspection of the apparentlynongrowing colonies showed that the srs2 ${Delta}$ mrc1 ${Delta}$ mec1 ${Delta}$ sml1 ${Delta}$ segregantshave approximately two- to threefold more cells in the microscopiccolonies than the srs2 ${Delta}$ mrc1 ${Delta}$ sml1 ${Delta}$ segregants.

mrc1 ${Delta}$ srs2 ${Delta}$ synthetic lethality is not due to a spindle checkpoint defect. We were concerned that the srs2 ${Delta}$ mrc1 ${Delta}$ lethality might actuallyresult from a mitosis spindle checkpoint arrest. Therefore,we mutated the spindle checkpoint by introducing an mad3 ${Delta}$ mutationinto the srs2 ${Delta}$ mrc1 ${Delta}$ mutant and asked if this would relieve thelethal phenotype. As shown in Fig. 5C, loss of the spindle checkpointdoes not suppress the srs2 ${Delta}$ mrc1 ${Delta}$ lethality, suggesting that thislethality arises from a different defect.

mrc1 ${Delta}$ has a sister chromatid cohesion defect independent of checkpoint function. mrc1 ${Delta}$ has been identified as a synthetic lethal partner in screensfor synthetic lethal interactions with sister chromatid cohesionmutants (46, 54). Therefore, we examined the mrc1 ${Delta}$ and mrc1-AQmutants for sister chromatid cohesion. We observed that themrc1 ${Delta}$ mutant has a sister chromatid cohesion defect, while themrc1-AQ has no cohesion defect (Fig. 6). Moreover, the srs2 ${Delta}$ mutant does not have a sister chromatid cohesion defect in ourassays, nor does the rad51 ${Delta}$ mutant. Another group recently foundthat srs2 ${Delta}$ has a slight sister chromatid cohesion defect (54),which suggests that loss of Srs2 may make cells more susceptibleto improper cohesion complex assembly but that this effect maydepend on other genetic background effects.

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FIG. 6. Sister chromatid cohesion assays in mrc1 mutants. (A) Sister chromatid cohesion assays were performed for three separate chromosomal locations as marked in wild-type, mrc1 ${Delta}$ , and srs2 ${Delta}$ strains. The mean percentage of two GFP dots from 200 cells is shown. Each experiment was repeated three to four times with different transformants for each genotype. The strains used were YPH1477 (wild type), Y4986 and Y4987 (mrc1 ${Delta}$ ) and Y5168 (srs2 ${Delta}$ ) for chromosome V, Y819 (wt), Y4989 and Y4990 (mrc1 ${Delta}$ ), and Y5165 (srs2 ${Delta}$ ) for chromosome IV, and YPH1444 (wild type), Y4992 and Y4993 (mrc1 ${Delta}$ ), and Y5247 (sr2 ${Delta}$ ) for chromosome XV. (B) Sister chromatid cohesion on chromosome V was performed on the indicated strains, counting 200 cells each time in two independent experiments and for each genotype. The strains used were YPH1477 (wild type), Y4986 and Y4987 (mrc1 ${Delta}$ ), Y5168 (srs2 ${Delta}$ ), Y6234 (rad51 ${Delta}$ ), Y6344 (rad51 ${Delta}$ srs2 ${Delta}$ ), Y6187 (mrc1 ${Delta}$ rad51 ${Delta}$ ), Y6219 (mrc1 ${Delta}$ srs2 ${Delta}$ rad51 ${Delta}$ ), and Y6346 and Y6355 (mrc1-AQ).

Suppression of the mrc1 ${Delta}$ srs2 ${Delta}$ lethality does not suppress the sister chromatid cohesion defect. Since a rad51 ${Delta}$ mutation suppresses the srs2 ${Delta}$ mrc1 ${Delta}$ defect, it wasimportant to determine if the sister chromatid cohesion defectis also suppressed in this triple mutant. We found no effectof the rad51 ${Delta}$ mutation on sister chromatid cohesion in any background,including the srs2 ${Delta}$ mrc1 ${Delta}$ double mutant. Thus, suppression ofthe lethal phenotype is due to elimination of homologous recombinationin a cohesion-defective situation, and cells are viable whensister chromatid cohesion is reduced as long as homologous recombinationis controlled.

srs2 ${Delta}$ synthetic lethality with Ctf18-RFC complex genes is due to inappropriate recombination. Given the srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality and the sister chromatidcohesion defect in the mrc1 ${Delta}$ mutant, we further examined srs2 ${Delta}$ synthetic lethality with a collection of viable cohesion-defectivemutants. We tested each gene by crossing the mutant to an srs2 ${Delta}$ rad51 ${Delta}$ strain so that we could determine if any observed syntheticlethality was suppressible by loss of homologous recombination.We confirmed that srs2 ${Delta}$ was synthetically lethal or sick withctf4 ${Delta}$ , ctf8 ${Delta}$ , ctf18 ${Delta}$ , and dcc1 ${Delta}$ and found that the ctf4 ${Delta}$ , ctf8 ${Delta}$ , ctf18 ${Delta}$ ,and dcc1 ${Delta}$ synthetic interactions are suppressed by a rad51 ${Delta}$ mutation.An example of this suppression is shown for ctf18 ${Delta}$ in Fig. 7.Since the Ctf18-RFC complex has been linked to the establishmentof sister chromatid cohesion during replication (30), the syntheticlethality reinforces the proposal that an important aspect ofregulating homologous recombination in mitosis is to have therecombination occur between or within cohesed sister chromatids.Cohesion may prevent nonsister chromatids from engaging in promiscuoushomologous recombination and thus inhibit deleterious recombinationin the srs2 ${Delta}$ mutant.

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FIG. 7. srs2 ${Delta}$ synthetic sickness with ctf18 ${Delta}$ is relieved by loss of RAD51 function. Five tetrads are shown from the cross srs2 ${Delta}$ rad51 ${Delta}$ (HKY1403-1B) x rad18 ${Delta}$ . The circles mark srs2 ${Delta}$ ctf18 ${Delta}$ spore segregants. The squares mark srs2 ${Delta}$ ctf18 ${Delta}$ rad51 ${Delta}$ spore segregants.

DISCUSSION

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Discussion

We found that the srs2 ${Delta}$ mutant has several novel synthetic lethalinteractions, which include the mrc1 ${Delta}$ , tof1 ${Delta}$ , and csm3 ${Delta}$ mutations;these genes encode proteins that are proposed to form a complexthat acts during DNA replication at the replication fork. Mrc1and Tof1 have been shown directly to be associated with replicationforks (17, 32), and Csm3 has been shown to interact with Tof1by yeast two-hybrid analysis and by coimmunoprecipitation (15,46). Mrc1, Tof1, and Csm3 have been shown to be required forDNA damage checkpoint activation in response to replicationblocks (2, 8, 44, 46). Although Srs2 is required for full Rad53activation and regulation of S-phase progression in responseto induced intra-S damage, Srs2 is not essential for a normalS phase, and there is no spontaneous activation of Rad53 (27).Thus, it is unlikely that the srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethalityis due to a failure to activate Rad53 under normal growth conditions.

Moreover, an srs2 ${Delta}$ mutant does not require Rad53 for survivalin undamaged conditions and the mrc1 ${Delta}$ lethality with srs2 ${Delta}$ canbe separated from the function of Mrc1 in the checkpoint DNAdamage signaling. The role of Srs2 during S phase appears tobe the promotion of gap repair by the RAD18 postreplicationrepair pathway, through mechanisms that do not involve homologousrecombination and double-strand break formation. In the absenceof Srs2, more gaps are repaired by the homologous recombinationpathway. We do not know if the homologous recombination eventsare promoted by double-strand breaks or initiated by single-strandgaps. It is also possible that single-strand gaps are processedto double-strand breaks once a commitment to homologous recombinationis made by having a Rad51 filament form on the single-strandgap. Whatever the case, we believe that double-strand breaksare not formed in the srs2 ${Delta}$ mrc1 ${Delta}$ rad51 ${Delta}$ mutant, as this mutantdoes not show any cell cycle arrest or reduced growth comparedto mrc1 ${Delta}$ , srs2 ${Delta}$ , or rad51 ${Delta}$ single mutants.

We propose that the spontaneous lesions in the srs2 ${Delta}$ mrc1 ${Delta}$ mutantthat stall replication forks are channeled into a homologousrecombination repair pathway instead of a gap-filling pathwaydue to loss of the Srs2 antirecombinase action against Rad51.Normally, this would be tolerated, but when Mrc1 is also absent,this becomes a lethal situation. The lethality arises from attemptinghomologous recombination without the correct molecular scaffoldset up at the point of replication stalling. We suggest thatthis scaffold is sister chromatid cohesion that is establishedspecifically at a point of fork stalling. Sister chromatid cohesionmay stabilize the fork and may promote sister chromatid recombination,which would be necessary to reestablish a replication fork ifit becomes collapsed by a double-strand break. The increasedspontaneous deletion rate that we observed in the mrc1 ${Delta}$ mutantbut not the mrc1-AQ mutant (Fig. 4) indicates that more double-strandbreaks form in the absence of the Mrc1 protein. Although thislevel of double-strand breaks can be tolerated when Srs2 ispresent (although it probably accounts for the slower growthof the mrc1 ${Delta}$ deletion mutant), in its absence this becomes lethal.

We suggest that the role of Mrc1 and its functionally associatedpartners Tof1 and Csm3 is to recruit the Ctf18-RFC-like complexto the site of fork stalling. The Ctf18-RFC-like complex wouldthen recruit or activate a cohesion complex as replication occurs(29), even if the newly replicated DNA is gapped. This modelwould account for the srs2 ${Delta}$ synthetic lethality with ctf18 ${Delta}$ andcomponents of the Ctf18-RFC-like complex as well as syntheticsickness with structural maintenance of chromosome (SMC) mutantsdefective in condensin and cohesin subunits (31, 46). In thismodel, the double-strand breaks would not inhibit S-phase progression,and indeed double-strand breaks are not inhibitory to S-phaseprogression (A. Pellicioli and M. Foiani, personal communication).Rather, when they are engaged by the homologous recombinationpathway in G₂, sister chromatid cohesion is required for theirrepair (39, 49).

Inactivating homologous recombination rescues the srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality because the homologous recombination pathwayis no longer active and cells can now use the gap-filling pathwaysto repair the single-strand gaps. Thus, the postreplicationrepair pathway becomes a mechanism to avoid inappropriate homologousrecombination events that may result in genome instability.

Srs2 and Mrc1 are involved in the S-phase checkpoint pathway(2, 27, 44). The sister chromatid cohesion factor SMC1 has alsobeen linked to a branch of the S-phase checkpoint pathway involvingATM and NBS1 in mammalian cells (19, 55). Indeed, the yeastsmc1-259 mutation has been shown to affect DNA damage response,causing sensitivity to ionizing radiation, UV, and MMS treatment(19). However, the mammalian ATM serine target sites in SMC1are not present in the yeast Smc1 protein, so it is not knownif Smc1 of S. cerevisiae is involved in the S-phase checkpointpathway.

It is possible that the srs2 ${Delta}$ mrc1 ${Delta}$ synthetic lethality arisesfrom loss of two checkpoint signaling effectors that convergeon Smc1. We do not believe that this is the explanation forthe synthetic lethality. First, mrc1 ${Delta}$ shows a synthetic sickness,not lethality, with rad50 ${Delta}$ and xrs2 ${Delta}$ but not with mre11 ${Delta}$ (46).Rad50, Xrs2, and Mre11 form a complex in S. cerevisiae (16,51), and Mre11 is the key player in checkpoint signaling (7,34, 50). Second, in mammalian cells, the SMC1-dependent S-phasecheckpoint activation does not affect the ability of SMC1 tobind to chromatin (55), and both phosphorylated and unphosphorylatedSMC1 appear to be competent for sister chromatid cohesion (55).Third, loss of the Mec1 checkpoint signal does not rescue thesrs2 ${Delta}$ mrc1 ${Delta}$ growth defect. In this situation, the cells can growfor one to two additional generations but still cannot sustainfurther growth. Fourth, specific loss of the Mrc1 checkpointsignaling function does not lead to lethality in an srs2 ${Delta}$ mutant.

Thus, we propose that sister chromatid cohesion is set up ata site of DNA damage when the cell engages in mitotic homologousrecombination in the context of replication stalling. We donot know whether Mrc1 interacts with homologous recombinationcomponents or the Ctf18-RFC-like complex, nor do we know whenhomologous recombination occurs, in S phase or G₂, when gaprepair is inhibited. Nonetheless, our results highlight theimportance of the postreplication repair pathway in maintainingcell survival and repair of spontaneous lesions by the correctpathway to avoid genome instability and lethal homologous recombinationevents.

ACKNOWLEDGMENTS

We thank S. Elledge for the gift of the mrc1-AQ strain and GrantBrown, Giordano Liberi and Chiara Lucca for comments on themanuscript. The technical assistance of Anastasiya Epshteinis gratefully acknowledged.

This work was supported by Public Health Service grant GM53738from the National Institutes of Health (H.L.K.) and by grantsfrom the Canadian Institute of Health Research, Genome Canada,and Genome Ontario (C.B.).

FOOTNOTES

* Corresponding author. Mailing address: Department of Biochemistry, NYU Medical Center, 550 First Ave., New York, NY 10016. Phone: (212) 263-5778. Fax: (212) 263-8166. E-mail: hannah.klein{at}med.nyu.edu.

REFERENCES

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