The Fission Yeast Crb2/Chk1 Pathway Coordinates the DNA Damage and Spindle Checkpoint in Response to Replication Stress Induced by Topoisomerase I Inhibitor

Living organisms experience constant threats that challengetheir genome stability. The DNA damage checkpoint pathway coordinatescell cycle progression with DNA repair when DNA is damaged,thus ensuring faithful transmission of the genome. The spindleassembly checkpoint inhibits chromosome segregation until allchromosomes are properly attached to the spindle, ensuring accuratepartition of the genetic material. Both the DNA damage and spindlecheckpoint pathways participate in genome integrity. However,no clear connection between these two pathways has been described.Here, we analyze mutants in the BRCT domains of fission yeastCrb2, which mediates Chk1 activation, and provide evidence fora novel function of the Chk1 pathway. When the Crb2 mutantsexperience damaged replication forks upon inhibition of thereligation activity of topoisomerase I, the Chk1 DNA damagepathway induces sustained activation of the spindle checkpoint,which in turn delays metaphase-to-anaphase transition in a Mad2-dependentfashion. This new pathway enhances cell survival and genomestability when cells undergo replicative stress in the absenceof a proficient G₂/M DNA damage checkpoint.

INTRODUCTION

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Introduction

Accurate transmission of genetic information to daughter cellsrequires checkpoint pathways monitoring completion of DNA replicationand DNA damage and correct attachment of replicated chromosomesto the mitotic spindle. These pathways are highly conservedthrough evolution.

Double-strand breaks (DSBs) are the most dangerous threat tothe integrity of the genome. They can be repaired either bynonhomologous end joining or by homology-dependent repair mechanismssuch as homologous recombination, break-induced replication,single-strand annealing, and synthesis-dependent strand annealing(22, 31, 42). DSBs can arise spontaneously during DNA replication,or they can be induced by exogenous treatments such as ionizingradiation (IR).

Treatment of cells with inhibitors of the topoisomerase I enzyme(Top1), such as the anticancer drug camptothecin (CPT), leadsto single-strand breaks by trapping Top1-DNA intermediates andinhibiting the enzyme's religation activity. Such protein-DNAcomplexes are converted into DSBs upon DNA replication (32).In fission yeast as well as in vertebrates, exposure to bothIR and CPT results in activation of the DNA damage checkpointpathway in which the Chk1 kinase acts as a downstream effector(18, 43, 46-48, 50).

Fission yeast Chk1 kinase is activated in response to damagedDNA in late S and G₂ phases of the cell cycle and delays mitoticentry by maintaining the Cdc2-cyclin B complex as inactive.Upregulation of Chk1 activity occurs through phosphorylationat S345 by the Rad3 kinase (6, 19), a member of the phosphatidylinositol3-kinase-like family and a homologue to vertebrate ATR (1).Rad3-dependent activation of Chk1 requires the checkpoint mediatorCrb2, a protein sharing sequence and functional similarity withbudding yeast Rad9 and human proteins 53BP1 and BRCA1 (34, 49).The sequence similarity concerns the C-terminal BRCT domains,which are protein-protein interaction domains (5), and the twotandem Tudor folds in the central part of the proteins, whichare protein-protein and protein-DNA interaction domains (8,15). It has been shown that 53BP1 recruitment to DSBs dependson the interaction between its Tudor domains and the methylatedK 79 of histone H3, which becomes accessible for the interactionat the sites of DSBs (15). Recent work has demonstrated thatthe Crb2 BRCT domains, similarly to Rad9 BRCT domains, are requiredfor homo-oligomerization of the protein. In fission yeast, Crb2homo-oligomerization is needed for Rad3-dependent Chk1 activation.Crb2 is recruited to DNA repair foci induced by DSBs in an apparentlyBRCT domain-dependent fashion. Moreover, Crb2 recruitment tofoci depends on histone H2A phosphorylation by the Rad3 or Tel1kinases (9, 29) and on histone H4-K20 residue methylation bySet9 (36).

Crb2 is also involved in regulation of homologous recombinationin the G₂ phase by modulating the activity of Rqh1 helicase.This function is mediated by the Cdc2-cyclin B-dependent phosphorylationof Crb2 at residue T215, an event occurring at mid-mitosis inan unperturbed cell cycle. T215 phosphorylation allows furtherphosphorylation of Crb2 by the Rad3 kinase in response to DNAdamage (7, 10). Furthermore, deletion of crb2 renders cellssensitive to chronic hydroxyurea (HU) treatment, a drug thatinhibits the ribonucleotide reductase and induces stalling ofDNA replication forks (39, 49). This phenotype is not due tocheckpoint failure, since in fission yeast, stalled replicationforks activate the Cds1 rather than the Chk1 pathway (44). Sensitivityto HU may result from a role of Crb2 in processing DNA structuresthat result from damaged replication forks, a process sometimestermed "recovery."

The spindle assembly checkpoint blocks chromosome segregationuntil proper attachment of chromosomes to the mitotic spindleis achieved. This checkpoint acts by inhibiting the anaphase-promotingcomplex (APC), a multisubunit E3 ubiquitin ligase required topromote degradation of both cyclin B and cohesin. Inhibitionoccurs by preventing APC association with Slp1/Cdc20, a taskperformed by the checkpoint protein Mad2 (2). In fission yeast,as well as in others organisms, Mad2 inhibition of APC requiresMad3 and the upstream checkpoint kinase Mps1 (14, 24).

To better understand the function of Crb2, we undertook a functionalanalysis of crb2 mutant alleles which are defective in Chk1activation when DNA is damaged. This analysis provides evidencethat the Crb2/Chk1 pathway causes the spindle checkpoint todelay metaphase-to-anaphase transition when cells enter mitosiswith abnormal DNA structures resulting from damaged replicationforks. This function enhances cell survival and ensures genomestability in the absence of a proficient G₂/M damage checkpoint.

MATERIALS AND METHODS

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Materials and Methods

Fission yeast physiological and genetic methods. Strains used in this study are listed in Table 1. Additionalstrains were obtained by standard genetic crosses followed bytetrad analysis using the listed strains. Genetic proceduresand media were as described previously (13, 26). Overexpressionof proteins from the nmt1 promoter was induced by first growingcells in selective medium with 5 µg/ml of thiamine (promoteroff) and then washing and inoculating cells in thiamine-freemedium (promoter on) (21). Mutagenesis of the pRSP HISCrb2 plasmidwas carried out in vitro with 1 M hydroxylamine-clorohydrate(Sigma) according to a method described previously (38). Mutagenizedplasmids were transformed in the SP808 strain, and transformantswere selected on medium containing thiamine and then replicaplated on thiamine-free medium with phloxine B to select forviable clones.

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TABLE 1. S. pombe strains used in this study

crb2(1-669) and crb2(1-533) alleles were generated by mutatingG to T at position 2008 or at position 1600, respectively, usingthe Altered Sites II in vitro mutagenesis system (Promega).These mutations result in the creation of a stop codon at positions670 and 534, respectively. Mutant alleles were integrated atthe genomic locus using the pop-in/pop-out method.

Synchronization in G₂ phase of cells harboring the cdc25-22mutation was performed by shifting cultures in early log phasegrown at 25°C for 3.5 h to 36.5°C. Cells were then releasedinto cell cycle at 25°C with or without 20 µM CPT(Sigma). To synchronize in early S phase, cells were treatedwith 12 mM HU (Sigma) for 4 h. Cells were then washed twicein medium lacking HU and released into cell cycle without orwith 20 µM CPT. Two to four independent experiments wereperformed for each strain.

Genotoxic sensitivity of strains was tested by drop assay. Cellswere grown in yeast extract-adenine medium and diluted to 1.3x 10⁶ cells/ml, and 7.5 µl of sequential fourfold dilutionswere spotted onto the appropriate plates. To determine UV andIR sensitivities, plates were irradiated with a 254-nm lightsource in a Stratalinker (Stratagene) or with a Cs¹³⁷ gammasource at a dose rate of 0.16 Gy/s, respectively. Plates wereincubated at 30°C for 3 to 4 days and then photographed.

Survival curves for CPT were performed by exposing asynchronouscultures grown to 4 x 10⁶ cells/ml to 20 µM CPT at 30°C.Starting at time zero, cells were counted, diluted, and platedfor survival estimation. Survival curves for IR were performedby cumulative irradiation of 10⁸ cells in 1 ml of distilledwater collected from an asynchronous culture in log phase. Aftereach irradiation, an aliquot of cells was diluted and platedfor survival estimation. Three to five independent experimentshave been performed for each strain.

Determination of chromosome loss rates after CPT treatment wasdone as described previously (40). Three to five independentexperiments have been performed for each strain.

Microscopy. Plates were photographed under a phase-contrast microscope withplan objective using a SONY 3 charge-coupled-device camera.All microphotographs were taken using a Leica Microsystems DMRDmicroscope with a x100 oil immersion objective and a PrincetonCoolSnap fx cooled charge-coupled-device camera. The light sourcefor fluorescence excitation was an HBO 100 W Hg arc lamp. Thepercentage of cells passing mitosis was scored after DAPI (4',6'-diamino-2-phenylindole;Sigma) staining of cells fixed in 70% ethanol. Pictures of cellsstained with DAPI were taken when the binning was set at 1.For observation of living cells expressing green fluorescentprotein (GFP)-tagged proteins, the exposure time was 5 s andbinning was set at 2. Image capture software used was MetaView(Universal Imaging), whereas image processing software usedwas Metamorph Offline (Universal Imaging). The latter was usedto count cell types on pictures. About 200 cells were countedfor each time point.

Protein methods. Proteins were extracted after harvesting cells with ice-coldstop buffer as previously described (39). Protein concentrationwas determined by Bradford assay. Sodium dodecyl sulfate-polyacrylamidegel electrophoresis and Western blotting were standard. Monoclonalanti-His antibodies (QIAGEN) or anti-hemagglutinin (HA) antibodies(clone 12CA5; Roche) were used to probe membranes. Chemiluminescentdetection of horseradish peroxidase (HRP)-conjugated secondaryantibodies was carried out using Renaissance reagents (DuPontNEN).

RESULTS

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Results

Isolation of crb2 alleles that do not arrest cell cycle progression when overexpressed. We used strain SP808 (Table 1) transformed with plasmid pRSPHISCrb2 to overexpress the Crb2 protein tagged at the N terminuswith 10 His residues. Induction of the nmt1 promoter occursat about 16 h of growth without thiamine. At 20 h, cell survivalis about 30% (Fig. 1A), and cells are elongated with a singlemedial nucleus (Fig. 1B, left) and have a DNA content of 2C(not shown). The tagged Crb2 protein is clearly detected inWestern analysis using anti-His-tag antibodies (Fig. 1C). Similarphenotypes were observed when untagged wild-type Crb2 proteinwas overexpressed (not shown). Thus, similar to Chk1, overexpressionof Crb2 blocks cell cycle progression and results in cell deathassociated with a cdc terminal phenotype (11).

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FIG. 1. Mutations in the Crb2 BRCT domains abolish cell cycle arrest upon Crb2 overexpression. (A) Survival of cells overexpressing HIS-Crb2PH protein (pRSP HISCrb2PH – thiamine) compared to cells overexpressing wild-type HIS-Crb2 (pRSP HISCrb2 – thiamine). (B) DAPI staining of cells overexpressing HIS-Crb2 (left panel) or HIS-Crb2PH (right panel) protein. (C) HIS-Crb2 and HIS-Crb2PH proteins are overexpressed at similar levels. (D) Overexpression (– thiamine) of HIS-Crb2PH, HIS-Crb2(1-669), and HIS-Crb2(1-533) proteins does not arrest cell growth. The Crb2(1-669) protein lacks the last BRCT domain, while Crb2(1-533) lacks both BRCT domains.

To isolate crb2 mutants that are unable to block cell cycleprogression when overexpressed, we transformed the SP808 strainwith random mutagenized plasmid pRSP HISCrb2 and selected fortransformants on plates containing thiamine. After replica platingon selective medium lacking thiamine (Crb2 induced), we isolatedseveral clones which did not exhibit the cdc terminal phenotypeassociated with Crb2 overexpression. We focused on one cloneharboring a plasmid overexpressing full-length HISCrb2 protein(pRSP HISCrb2PH). The plasmid was recovered and retransformedin SP808 cells to confirm the absence of cell cycle arrest (Fig.1A). Cells overexpressing the mutant protein Crb2PH have a wild-typephenotype (Fig. 1B, right). Protein analysis confirmed thatthe mutated plasmid overexpresses the HISCrb2PH protein at alevel comparable with that of the wild-type pRSP HISCrb2 plasmid(Fig. 1C).

Sequence analysis revealed that the mutated plasmid has twopoint mutations in the crb2 gene changing P629 to S and H632to Y (allele crb2PH). The mutations are located in a conservedregion of the first BRCT domain and concern two residues conservedin the budding yeast protein Rad9 (P1098 and H1101). ResidueP629 is also conserved in the first BRCT domain of the humanprotein 53BP1 (P1824) (5).

Next, we constructed plasmids expressing the truncated Crb2proteins Crb2(1-669) and Crb2(1-533), which lack the secondor both BRCT domains, respectively. Neither of these two alleleswas able to induce cell cycle arrest when overexpressed (Fig.1D). Thus, either both BRCT domains or the second BRCT alonewas required for the overexpression phenotype. However, consideringthat mutations P629S and H632Y in the first BRCT domain alsoabolish the overexpression phenotype, the former possibilityseems more likely.

Analysis of crb2 mutants integrated at the genomic locus. We produced three mutant strains carrying the mutant allelescrb2PH, crb2(1-669), and crb2(1-533) and analyzed their phenotypesin response to genotoxic treatments. All strains behave likethe crb2 null strain when exposed to UV and IR. However, theyare significantly more resistant than the ${Delta}$ crb2 strain when treatedwith CPT, methyl methanesulfonate (MMS), and HU (Fig. 2A).

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FIG. 2. Drop test analysis of DNA damage sensitivity of crb2 mutants integrated at the genomic locus. (A) crb2PH, crb2(1-669), and crb2(1-533) are as sensitive as ${Delta}$ crb2 cells to IR and UV irradiations but are significantly more resistant to CPT and to chronic exposure to low concentrations of HU and MMS. (B) Survival curves of ${Delta}$ crb2 and crb2PH strains to IR. (C) Chk1-HA phosphorylation after IR in wild-type (crb2⁺) and crb2PH cells.

Figure 2B shows that strain crb2PH is as sensitive as ${Delta}$ crb2 whenexponentially growing cultures are IR irradiated. Analysis ofChk1 phosphorylation indicates that crb2PH cells, like ${Delta}$ crb2cells (not shown), do not activate Chk1 upon irradiation (Fig.2C). Crb2 mutants treated with the different genotoxic reagentsin asynchronous culture also did not activate Chk1 (not shown).Thus, when integrated at the genomic locus, the crb2PH allelebehaves like allele crb2(1-533), indicating that it has nonfunctionalBRCT domains. These observations are consistent with the recentpublished finding that the BRCT domains are required for efficientG₂/M DNA damage checkpoint signaling to Chk1 (9).

CPT resistance of crb2PH cells is independent of the functional G₂/M DNA damage checkpoint. CPT treatment induces DNA damage when cells pass through S phasewhich activates the Chk1 pathway (47). CPT-induced DNA damageoccurs during DNA replication when the trapped Top1 cleavagecomplexes collide with the replication forks, leading to theformation of DSBs (32). Because of better understanding of CPT-inducedDNA damage compared to HU and MMS, we focused on the CPT resistanceof the crb2PH allele.

To ensure that CPT resistance of crb2PH cells is not due toChk1 activation, we analyzed cultures synchronized in the G₂phase using the cdc25-22 allele. Synchronized cells were releasedinto cell cycle in the presence or absence of CPT. Synchronizationand cell cycle progression were followed by fluorescence-activatedcell sorter analysis (not shown) and by DAPI staining of cellsevery 30 min starting at release (Fig. 3A). Aliquots of cultureswere also processed every 30 min from time zero to analyze expressionand phosphorylation of Chk1, which is HA tagged in the usedstrains (Fig. 3A). While the cdc25 crb2⁺ strain delays the G₂phase, cdc25 crb2PH cultures treated with CPT only show a slightdelay in the appearance of cells with two nuclei in the secondcell cycle after release (compare time point 210 between untreatedand treated synchronized cultures in Fig. 3A). However, phosphorylationof Chk1 upon CPT treatment, which, as expected, was easily detectablein the cdc25 crb2⁺ strain, was completely absent in cdc25 crb2PHcells (Fig. 3A). The ${Delta}$ crb2 mutant did not exhibit any cell cycledelay or Chk1 phosphorylation upon CPT treatment (not shown).

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FIG. 3. Analysis of CPT response in synchronized wild-type (crb2⁺) and crb2PH cells. (A) Cell cycle progression and Chk1 phosphorylation of cdc25 crb2⁺ and cdc25 crb2PH strains expressing Chk1HA synchronized in G₂ and released into cell cycle without (left panels) or with (right panels) CPT. (B) Cell cycle progression and Chk1 phosphorylation of crb2⁺ and crb2PH strains expressing Chk1HA synchronized in early S phase and released into the cell cycle with (black circles) or without (black squares) CPT.

We confirmed these results using a different synchronizationprotocol that allows for analysis of the effects of the treatmentin the first cell cycle following release. Cells were synchronizedin early S phase by HU treatment for 4 h and then released intocell cycle in the absence or presence of CPT (time zero). Cellcycle progression was monitored by fluorescence-activated cellsorter analysis (not shown) and DAPI staining of cells every15 min starting at time zero. Chk1 protein was analyzed every30 min starting at time zero. As expected, wild-type (crb2⁺)cells delay cell cycle progression when treated with CPT andhave phosphorylated Chk1 kinase (Fig. 3B). In contrast, no Chk1phosphorylation is detected in the crb2PH strain exposed toCPT. However, crb2PH cells have a small delay in cell cycleprogression after CPT treatment (Fig. 3B). This small delay,which was also observed after synchronization with the cdc25allele (Fig. 3A), is reproducible and occurs at the metaphase-to-anaphasetransition (see below and see Fig. 5 and 6). Note that as aresult of the HU block-and-release protocol, low levels of Chk1phosphorylation are detected in the untreated wild-type strainbut not in the crb2PH mutant (Fig. 3B). This difference couldexplain why the crb2PH cells cycle slightly faster than wild-typecells even in the absence of CPT.

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FIG. 5. crb2PH cells delay metaphase-to-anaphase transition after CPT treatment. (A) Survival of wild-type (crb2⁺), ${Delta}$ crb2, and crb2PH strains following synchronization in early S phase by HU treatment in the absence (black squares) or presence (black circles) of CPT. (B) Strains expressing the fluorescent protein Cut12GFP were synchronized in early S phase and released into the cell cycle with (black circles) or without (black squares) CPT. Upper panels indicate the percentage of cells with two nuclei as judged by DAPI staining. Lower panels indicate the percentage of cells in prometaphase and metaphase as judged by the presence of two adjacent Cut12GFP spots. (C) Representative microphotographs of the indicated strains expressing Cut12GFP protein at 75 min after release into the cell cycle in the presence of CPT. (D) Separation of centromere 1 in crb2PH cells is delayed by the CPT treatment. The left panel shows the percentage of cells with two nuclei as judged by DAPI staining, while the right panel indicates the percentage of cells with unsplit centromere 1.

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FIG. 6. Analysis of the delay in metaphase-to-anaphase transition of the indicated strains expressing the fluorescent protein Cut12GFP. Cells were synchronized in early S phase and released into the cell cycle in the presence (black circles) or absence (black squares) of CPT. Left panels indicate the percentage of cells with two nuclei as judged by DAPI staining. Right panels indicate the percentage of cells in prometaphase and metaphase as judged by the presence of two adjacent Cut12GFP spots.

In conclusion, the crb2PH allele is unable to activate the G₂/MDNA damage checkpoint by promoting Chk1 phosphorylation whenDNA is damaged. However, at the same time, the Crb2PH proteinretains a function required to survive CPT treatment.

CPT resistance of crb2PH requires Chk1, Mad2, and Cds1 proteins. Having established that CPT resistance of crb2PH is independentof Chk1 phosphorylation, we asked if resistance requires thepresence of Chk1 protein. As shown in Fig. 4A, deletion of chk1in the crb2PH background renders cells sensitive to CPT. Importantly,strain ${Delta}$ chk1 crb2PH is as sensitive as ${Delta}$ crb2 to CPT. This indicatesthat the function retained by the Crb2PH protein mediating survivalunder CPT treatment requires the presence but not the phosphorylationof Chk1 kinase. Furthermore, the chk1S345A allele, in whichresidue 345 cannot be phosphorylated by the Rad3 kinase in responseto damaged DNA (6), is more resistant to CPT than the chk1 nullallele (Fig. 4A). Furthermore, double mutant strain chk1S345Acrb2PH is not more sensitive than each single mutant to thetreatment (Fig. 4A). All of these results are consistent withthe observation that crb2PH resistance to CPT requires the Chk1protein (Fig. 4A) but does not implicate G₂/M delay and Chk1phosphorylation by Rad3 (Fig. 3A and B).

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FIG. 4. Cell-killing experiments to analyze the genetic interaction between the crb2PH mutant and other checkpoint genes. (A) crb2PH, chk1S345A, and double mutant crb2PH chk1S345A are equally sensitive to CPT. (B) Double mutant ${Delta}$ mad2 crb2PH is as sensitive as ${Delta}$ crb2 to CPT. (C) Double mutant ${Delta}$ mad2 chk1S345A is as sensitive as ${Delta}$ chk1 to CPT. (D) Triple mutant ${Delta}$ mad2 crb2PH ${Delta}$ chk1 is not significantly more sensitive to CPT than control double mutants. (E) ${Delta}$ cds1 interacts synergistically with crb2PH. Double mutant ${Delta}$ cds1 crb2PH is as sensitive as ${Delta}$ rad3 to CPT. Error bars indicate standard errors of the means.

Next, we asked whether the spindle checkpoint is required forthe CPT resistance of crb2PH cells. Deletion of the spindlecheckpoint protein Mad2 renders wild-type cells only slightlysensitive to CPT (Fig. 4B). Moreover, mad2 deletion does notaffect the CPT sensitivity of ${Delta}$ crb2 cells (Fig. 4B). In contrast,mad2 deletion abolishes the CPT resistance of mutant crb2PH(Fig. 4B), rendering the crb2PH ${Delta}$ mad2 double mutant effectivelyas sensitive as ${Delta}$ crb2. This suggests that the function retainedby the Crb2PH protein requires Mad2. Similarly, mad2 interactsgenetically with the chk1S345A mutant. Thus, mad2 deletion abolishesthe CPT resistance of mutant chk1S345A but does not affect theCPT sensitivity of ${Delta}$ chk1 cells (Fig. 4C). Furthermore, we showthat triple mutant crb2PH ${Delta}$ chk1 ${Delta}$ mad2 is not more sensitive toCPT than the control double mutants (Fig. 4D), indicating thatMad2 and Chk1 act in the same pathway that allows CPT survivalof crb2PH cells.

Combining the crb2PH allele with additional mutants providedfurther evidence for a connection between the DNA damage andspindle checkpoint pathways. A genetic interaction resemblingthat with Mad2 was observed between the crb2 alleles and mph1deletion (not shown), which encodes the upstream kinase of thespindle checkpoint pathway (14).

Given that Cds1 kinase can act in response to S-phase DNA damage,we asked whether it is required for CPT survival of the crb2PHstrain. As shown in Fig. 4E, ${Delta}$ cds1 is only slightly sensitiveto CPT but shows a synergistic effect with the crb2PH mutation.This genetic interaction is likely due to a greater "requirement"for an intra-S DNA damage checkpoint in CPT-treated cells whichlack the G₂/M checkpoint pathway and thus enter the next S phasewith damaged chromosomes. This interpretation is consistentwith our observation that the crb2PH strain, similarly to ${Delta}$ crb2,passes mitosis with assembled Rad22 foci (not shown). Moreover, ${Delta}$ cds1 crb2PH cells are as sensitive as ${Delta}$ rad3 to CPT, corroboratingfurther the idea that survival of crb2PH cells depends on theability to perform a Rad3-dependent activation of Cds1 in thefollowing S phase (Fig. 4E). In contrast to rad3, deletion ofthe tel1 gene did not affect the CPT response in any of theanalyzed strains (Fig. 4E).

Mad2-dependent delay of metaphase-to-anaphase transition in crb2PH cells treated with CPT. The genetic interaction between crb2PH and ${Delta}$ mad2 prompted usto investigate the possibility that crb2PH cells have a metaphase-to-anaphasedelay following exposure to CPT. We constructed crb2 mutantsexpressing the Cut12GFP fusion protein that localizes at thespindle pole body. This protein allowed us to distinguish cellsthat have entered mitosis (two adjacent Cut12 spots) from cellsin interphase (one spot) and from cells that have passed metaphase(two distant spots) (4).

Cells were synchronized in early S phase by HU treatment for4 h and then released into cell cycle in the absence or presenceof CPT. First of all, survival of the strains was monitoredby plating the cells at the beginning of the experiment (time–4), at the moment of release (time zero), and every hourafter release (Fig. 5A). Note that in this experiment, bothcrb2 mutants are more sensitive than in the survival curvesshown in Fig. 4. This is likely due to the fact that in thisexperiment, differently from that shown in Fig. 4, cells arepassing into the S phase in a synchronized fashion when exposedto CPT. However, even in this experiment, the crb2PH mutantis significantly more resistant to CPT than ${Delta}$ crb2.

Every 15 min from time zero, the percentage of cells with twonuclei and the percentage of cells with two adjacent Cut12 spotswere monitored (Fig. 5B and C). As expected, the wild-type strain(crb2⁺) treated with CPT delays cell cycle progression as judgedby the delay in the appearance of cells with two nuclei andwith two adjacent Cut12GFP spots (Fig. 5B, left). In contrast,cell cycle progression did not differ between CPT-treated anduntreated ${Delta}$ crb2 cultures (Fig. 5B, center). As predicted, CPTtreatment altered cell cycle progression of the crb2PH mutant(Fig. 5B, right). The number of cells in prometaphase or metaphase(two adjacent Cut12GFP spots) at 75 min in the treated cultureis about 23%, while it drops to 13% in the untreated culture.We conclude that CPT treatment has no effect on the kineticsof mitosis entry of crb2PH cells but delays the metaphase-to-anaphasetransition by 15 min in the cells. In fission yeast, mitosistakes about 10% of mitotic cell cycle. In rich medium at 30°C,the generation time is 2.5 h, and thus, mitosis last about 15min. Thus, in the crb2PH strain treated with CPT, the 15-mindelay at mitosis is highly significant.

We confirmed the mitotic delay in crb2PH cells exposed to CPTby monitoring the separation of centromere 1 targeted by a fluorescentmarker (28). As shown in Fig. 5D, separation of centromere 1is delayed in crb2PH cells treated with CPT. Indeed, the percentageof cells with one fluorescent spot, which indicates the percentageof cells with unsplit centromere 1, is higher between 30 and60 min in the treated culture. In all experiments presentedin Fig. 5, the delay in the metaphase-to-anaphase transitionof the crb2PH strain correlates with the delay observed whenthe appearance of binucleated cells is monitored by DAPI staining.

Importantly, we show that the chk1S345A mutant (Fig. 6A) aswell as the chk1S345A crb2PH double mutant (Fig. 6B) have amitotic delay similarly to crb2PH after CPT exposure. In contrast, ${Delta}$ chk1 cells behave like ${Delta}$ crb2 cells and do not show mitotic delay(Fig. 6C); moreover, chk1 deletion abolishes the mitotic delayof crb2PH cells (Fig. 6D). The mitotic delay is also abolishedin the ${Delta}$ mad2 crb2PH double mutant, indicating that cells expressingthe Crb2PH protein delay metaphase-to-anaphase transition throughthe Mad2 pathway (Fig. 6E). Finally, Mad2 is required for themitotic delay observed in chk1S345A cells treated with CPT (Fig.6F). All of these results are in accordance with the geneticanalysis presented in Fig. 4 and indicate that the mitotic delayobserved in crb2PH cells treated with CPT requires Mad2 andthe Chk1 protein but not Chk1 phosphorylation at S345.

The function retained by the crb2PH cells allows accurate chromosome segregation following CPT treatment in the absence of a G₂/M DNA damage checkpoint. The above-described experiments established that the crb2PHallele enhances survival to CPT treatment by delaying the metaphase-to-anaphasetransition and that this delay is Mad2 dependent. To determinewhether this function contributes to genome stability, we measuredthe chromosome loss rate in wild-type, ${Delta}$ crb2, crb2PH, ${Delta}$ mad2, andcrb2PH ${Delta}$ mad2 cells after CPT treatment. For this experiment,mutant strains containing the ade6-M210 allele at the genomiclocus and the minichromosome Ch16 with the ade6-M216 allelewere constructed (30). These ade6 alleles complement each other,and thus, cells are ade⁺ and colonies are white on YE medium.Upon loss of Ch16, cells become ade^– and colonies arecolored red. We measured the rate of chromosome loss of thedifferent strains under normal growth conditions and after 4h of treatment with 20 µM CPT. As shown in Fig. 7, allmutants are similar to the wild type in the absence of CPT exposure.As expected, strain ${Delta}$ mad2, which has a functional G₂/M DNA damagecheckpoint, is similar to the wild type both in the absenceand presence of CPT treatment. Interestingly, while ${Delta}$ crb2 cellsexposed to CPT are more likely to lose the Ch16 than wild-typecells, exposed crb2PH cells behaved like wild-type cells. Incontrast, crb2PH ${Delta}$ mad2 cells behaved like ${Delta}$ crb2. Therefore, thefunction retained by allele crb2PH, which requires the spindlecheckpoint Mad2 protein, participates in genome stability. Theobservation that the rate of chromosome loss in crb2PH cellsis the same as that in the wild type indicates that this mutantis defective in neither microtubule-kinetochore attachment norsister chromatid dynamics. This is consistent with our findingsshowing that crb2PH cells are not CBZ sensitive and that theyhave normal silencing at centromere 1 (data not shown).

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FIG. 7. Chromosome stability in wild-type, ${Delta}$ crb2, crb2PH, ${Delta}$ mad2, and ${Delta}$ mad2 crb2PH mutants under normal growth conditions (white bars) and after 4 h of treatment with 20 µM of CPT (black bars). Error bars are the standard errors of the means.

DISCUSSION

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Discussion

Checkpoint pathways are surveillance systems that ensure genomeintegrity through ordered execution of cell cycle events whenthe cell cycle is subject to perturbations. Among checkpoints,the DNA damage surveillance system transiently halts cell cycleprogression in response to damaged DNA while the spindle checkpointprevents metaphase-to-anaphase transition until all chromosomesare correctly attached to the spindle. Here, we provide evidenceof a link between these two checkpoints that becomes apparentwhen cells experience damaged replication forks.

In fission yeast, mitotic entry is inhibited by the activationof the conserved Chk1 kinase in response to damaged DNA in lateS and G₂ phases of the cell cycle (20, 46). Furthermore, theChk1 pathway is activated in response to damaged replicationforks, a situation occurring either following treatment withCPT or by exposing cells to HU in the absence of the replicationcheckpoint kinase Cds1 (3, 17, 47). Crb2 is a BRCT domain-containingprotein that functions as a mediator for Chk1 activation (34,49).

The principal findings in this paper derive from studying mutantcrb2PH cells. We demonstrate that this mutant expresses a Crb2protein with nonfunctional BRCT domains that is deficient inthe G₂/M damage checkpoint. This is consistent with the reportedrequirement of Crb2 BRCT domains for Rad3-dependent Chk1 phosphorylationand subsequent G₂/M checkpoint activation (9, 25).

By comparing the CPT resistance of the crb2PH mutant to thatof crb2 null cells, we show that the Chk1 pathway, beside itsmajor role in the G₂/M damage checkpoint, acts on the spindlecheckpoint in response to DNA structures arising from damagedreplication forks. This function allows cells to delay the metaphase-to-anaphasetransition in a Mad2-dependent mechanism. Importantly, we showthat this function enhances not only cell survival but alsogenome stability in the presence of this type of DNA damage.

The effect of CPT treatment is well understood, while the effectsof chronic exposure to low doses of HU or MMS are not. The DSBsinduced by CPT are generated when replication forks collapseat the 5' end of the Top1-cleaved DNA present on the leadingstrand (32). It is possible that the replication stress inducedby chronic exposure to HU and MMS also results in damaged DNAarising from collapsed replication forks. In agreement withour results, a recently published paper suggested that Mad2is required for the DNA replication checkpoint (HU response)when the Cds1 kinase is compromised (41). This is consistentwith our model, since compromising Cds1 kinase leads to activationof the Chk1 pathway when cells are exposed to HU (17). Thismost likely occurs because HU-arrested replication forks cannotbe stabilized by Cds1 and thus collapse.

A similar role in response to collapsed replication forks hasbeen recently proposed for the Saccharomyces cerevisiae Chk1pathway (37). In budding yeast, differently from Schizosaccharomycespombe, the major role of the Chk1 pathway in response to damagedDNA detected in late S/G₂ is to block the transition from metaphaseto anaphase by stabilizing the Pds1 protein (securin). In fissionyeast, as well as in vertebrates, the major execution pointof the Chk1 pathway is the transition from G₂ to mitosis. However,our work with S. pombe demonstrates that this is not the solerole of the Chk1 pathway and that, similarly to budding yeast,it can delay the metaphase-to-anaphase transition when cellsaccumulate abnormal DNA structures resulting from damaged replicationforks. Thus, this function of the Chk1 pathway seems to be conserved.It is interesting that an interaction between the spindle polebody protein Sad1 and Crb2 has been observed in a two-hybridassay (23).

Our results indicate that the ability of the Chk1 pathway tosustain the spindle checkpoint in response to a damaged replicationfork implicates the N-terminal part of the Crb2 protein butnot the BRCT domains. It has been shown that the N-terminalpart of Crb2 contains the moieties for binding to Cut5 and Chk1(9). Therefore, the Crb2PH protein likely is able to bind bothCut5 and Chk1 in vivo. This would explain why Chk1 is requiredfor the observed resistance to CPT of crb2PH cells and for delayingthe metaphase-to-anaphase transition after treatment. Cut5 isan essential checkpoint protein that shares sequence and functionalsimilarities with mammalian TopBP1 protein (34, 35). It hasbeen recently shown that Cut5 forms a complex with the PCNA-likecheckpoint protein Rad9 during normal S phase and that thiscomplex allows Crb2 and Chk1 recruitment and activation in responseto replication fork collapse or IR treatment. Formation of thiscomplex requires Rad9 C-terminal phosphorylation at T412 andS423 by the Rad3 or Tel1 kinase. Activation of the checkpointin both cases leads to additional phosphorylation of Rad9 atT225 by Rad3. However, differently from IR, Rad9 phosphorylationat T225 is dependent on previous modification of T412 and S423when cells accumulate DSBs induced by damaged replication forks(12). Because all these events occur upstream of Crb2 and Chk1,it is possible that Crb2PH and Chk1 can still be recruited tothis complex upon CPT exposure but that Rad3-dependent activationof Chk1 is prevented because of a mutation in Crb2, resultingin entry into mitosis with damaged DNA. However, the formationof the complex might still function to delay metaphase-to-anaphasetransition in a Mad2-dependent fashion. Consistent with thisinterpretation, the role of Mad2 in the response to HU of Cds1-compromisedcells is Rad3 dependent (41).

Our model implies that the basal kinase activity of Chk1 mightbe sufficient to directly or indirectly target the spindle checkpointwhen cells accumulate damaged DNA arising from replicative stress.Note that following DNA damage, at least 40% of the total Chk1kinase does not undergo Rad3-dependent phosphorylation and upregulation.Thus, it is possible that in response to replication fork collapse,Chk1 is recruited by Crb2 in two different complexes, one thatdelays mitotic entry through Chk1 upregulation and another thatacts on the spindle checkpoint pathway and involves a nonphosphorylatedform of Chk1. This model is consistent with our finding thatthe relative CPT resistance of chk1S345A compared to the ${Delta}$ chk1allele is abolished by deleting the mad2 gene.

Similarly to fission yeast, vertebrate cells respond to CPTtreatment by activating the Chk1 pathway. The common use ofthis drug in cancer therapy underlines the interest in a detailedunderstanding of its actions. Tumor cells are often checkpointdefective and thus highly vulnerable to DNA-damaging agents.However, certain tumors are resistant to CPT treatment. Themechanisms underlying this resistance are different, rangingfrom insufficient accumulation of the drug over alterationsin Top1 to alterations in the cellular response to the Top1-CPTcomplexes (33). The work presented here opens the possibilitythat cells lacking the G₂/M DNA damage checkpoint may surviveCPT treatment because of sustained activation of the spindlecheckpoint.

ACKNOWLEDGMENTS

We thank all members of the laboratory, B. Arcangioli for helpfuldiscussion and critical reading of the manuscript, and T. Carr,I. Hagan, J. P. Javerzat, and N. Walworth for strains.

A.C. was supported by MRT and "Ligue National contre le Cancer"fellowships.

FOOTNOTES

* Corresponding author. Mailing address: CNRS UMR 2027—Institut Curie, B $a$ timent 110, Centre Universitaire d'Orsay, 91405 Orsay, France. Phone: (33) 01 69 86 31 39. Fax: (33) 01 69 86 94 29. E-mail: sfrances{at}curie.u-psud.fr.

REFERENCES

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