The Mus81/Mms4 Endonuclease Acts Independently of Double-Holliday Junction Resolution to Promote a Distinct Subset of Crossovers During Meiosis in Budding Yeast

The Mus81/Mms4 Endonuclease Acts Independently of Double-Holliday Junction Resolution to Promote a Distinct Subset of Crossovers During Meiosis in Budding Yeast

Teresa de los Santos^1,a, Neil Hunter^1,b, Cindy Lee^a, Brittany Larkin^a, Josef Loidl^c, and Nancy M. Hollingsworth^a
^a Institute for Cell and Developmental Biology, Biochemistry and Cell Biology, State University of New York, Stony Brook, New York 11794-5215,
^b Center for Genetics and Development, Departments of Microbiology and Molecular and Cellular Biology, Division of Biological Sciences, University of California, Davis, California 95616-8665
^c Cytology and Genetics, Institute of Botany, University of Vienna, A-1030, Vienna, Austria

Corresponding author: Nancy M. Hollingsworth, 314 Life Sciences Bldg., SUNY, Stony Brook, NY 11794-5215., nhollin{at}notes.cc.sunysb.edu (E-mail)

Communicating editor: A. P. MITCHELL

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Current models for meiotic recombination require that crossoversderive from the resolution of a double-Holliday junction (dHJ)intermediate. In prokaryotes, enzymes responsible for HJ resolutionare well characterized but the identification of a eukaryoticnuclear HJ resolvase has been elusive. Indirect evidence suggeststhat MUS81 from humans and fission yeast encodes a HJ resolvase.We provide three lines of evidence that Mus81/Mms4 is not themajor meiotic HJ resolvase in S. cerevisiae: (1) MUS81/MMS4is required to form only a distinct subset of crossovers; (2)rather than accumulating, dHJ intermediates are reduced in anmms4 mutant; and (3) expression of a bacterial HJ resolvasehas no suppressive effect on mus81 meiotic phenotypes. Our analysisalso reveals the existence of two distinct classes of crossoversin budding yeast. Class I is dependent upon MSH4/MSH5 and exhibitscrossover interference, while class II is dependent upon MUS81/MMS4and exhibits no interference. mms4 specifically reduces crossingover on small chromosomes, which are known to undergo less interference.The correlation between recombination rate and degree of interferenceto chromosome size may therefore be achieved by modulating thebalance between class I/class II crossovers.

DURING meiosis, homologous chromosomes become physically connectedby the formation of chiasmata. These connections are crucialfor the accurate segregation of homologs to opposite poles atthe first meiotic division (BASCOM-SLACK et al. 1997 ). Chiasmaformation involves reciprocal recombination, or crossing over,between homologous chromosomes. Examination of crossover distributionindicates that the processes involved are highly regulated.First, every chromosome pair receives at least one exchange,the obligatory event required for faithful segregation, andsecond, when multiple crossovers are present, they are morewidely spaced than predicted for a random distribution, a phenomenonknown as positive crossover interference (JONES 1984 ). In thebudding yeast Saccharomyces cerevisiae, the DNA events of meioticrecombination have been described using physical assays. Meioticrecombination is initiated via programmed double-strand breaks(DSBs; KEENEY 2001 ). The ends of a DSB are resected on their5'-strands to produce 3'-single-stranded tails, which then interactsequentially with a homologous chromosome to produce a single-endinvasion (SEI) and then a double-Holliday junction (dHJ; SCHWACHAand KLECKNER 1995 ; HUNTER and KLECKNER 2001 ). The formationof dHJs and their resolution by structure-specific endonucleasesare central posits of contemporary models of meiotic recombination(SZOSTAK et al. 1983 ). While a number of gene products havebeen implicated in the formation of DSBs, SEIs, and dHJs (e.g., SCHWACHA and KLECKNER 1995 ; HUNTER and KLECKNER 2001 ; KEENEY2001 ), to date, a gene(s) encoding a meiotic HJ resolvase inS. cerevisiae has yet to be identified.

Recently two groups have proposed that Mus81 is a part of aeukaryotic HJ resolvase (BODDY et al. 2001 ; CHEN et al. 2001). Mus81 is an evolutionarily conserved endonuclease with homologyto the XPF/Rad1 proteins that function in nucleotide excisionrepair (HABER and HEYER 2001 ). Genetic data have been interpretedas evidence that MUS81 has a role in the processing of stalledreplication forks in mitotically dividing cells, perhaps viathe resolution of HJs formed via fork regression. For example,in Schizosaccharomyces pombe and S. cerevisiae, mus81 is syntheticallylethal with rqh1 and sgs1, the respective RecQ helicase homologsof each species (BODDY et al. 2000 ; MULLEN et al. 2001 ).Genetic data have also been used to argue that MUS81 functionsas a HJ resolvase during meiosis in S. pombe: mus81 cells inducedto undergo meiosis produce highly inviable spores and this phenotypecan be partially suppressed by expression of a bacterial HJresolvase (BODDY et al. 2001 ).

Mus81 from both yeasts forms a complex with a second proteinthat is required for nuclease activity in vitro (Eme1 for S.pombe and Mms4 for S. cerevisiae; BODDY et al. 2001 ; KALIRAMANet al. 2001 ). These results likely reflect the requirementfor a heterodimeric complex in vivo as mus81 eme1 and mus81mms4 are phenotypically identical to either single mutant forall of the vegetative phenotypes that have been examined, aswell as for meiotic spore viability (BODDY et al. 2001 ; DELOS SANTOS et al. 2001 ; MULLEN et al. 2001 ). Phenotypic analysisof mms4 diploids during meiosis demonstrated only a modest reductionin crossing over, suggesting that, in S. cerevisiae, meioticHJ resolution is mostly independent of MMS4 (DE LOS SANTOS etal. 2001 ). Because Mms4 and Eme1 are at best weakly homologous,the possibility exists that MUS81 functions in S. cerevisiaemeiosis as an MMS4-independent HJ resolvase. In fact, HJ cuttingactivity has been observed in vitro for the Mus81 homolog, Rad1,in the absence of its partner protein, Rad10 (HABRAKEN et al.1994 ).

To test whether MUS81 and MMS4 function together in meiosis,and to further investigate the meiotic roles for these geneproducts, mus81 diploids were compared with isogenic mms4 andmus81 mms4 strains for a variety of meiotic phenotypes. Ourdata confirm that MUS81 and MMS4 act in the same pathway formeiotic recombination, presumably as a protein complex. Unexpectedly,we find that MMS4 is required for only a subset of crossoversthat appear to be more prominent between short chromosomes.In addition, crossovers are distributed normally along chromosomesin an mms4 mutant, indicating that crossovers subject to interferencedo not require MUS81/MMS4. mus81 phenotypes are not suppressedby the expression of the bacterial HJ resolvase, rusA, and physicalmonitoring of DNA events indicates that dHJ intermediates arereduced in the absence of MMS4. These data strongly argue thatdHJ resolution in budding yeast does not require MUS81/MMS4.

MATERIALS AND METHODS

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Plasmids:
Plasmids were constructed by standard procedures (MANIATIS etal. 1982 ) using the Escherichia coli strain BSJ72. The MEK1p-NLS-rusA-D70N-2HAallele was constructed by first amplifying the NLS-rusA-D70N-2HAgene from pREP-rusA-D70N (generously provided by P. Russell,Scripps Research Institute), using the polymerase chain reaction(PCR; BODDY et al. 2001 ). A SalI site was engineered afterthe stop codon of the gene. The resulting fragment was digestedwith NdeI and SalI and ligated to NdeI/SalI-digested pDW14 tomake pNH246 (DE LOS SANTOS and HOLLINGSWORTH 1999 ). Site-directedmutagenesis (Quikchange kit, Stratagene, La Jolla, CA) was usedto restore the aspartic acid at position 70 to generate a wild-typerusA allele in pNH246wt. To ensure that no mutations were introducedby the PCR, the entire open reading frame (ORF) and MEK1 promoterfragment were sequenced (Center for the Analysis and Synthesisof Macromolecules, SUNY, Stony Brook, NY). The SGS1p-rusA plasmid,pKR6980, was generously provided by Steve Brill (Rutgers University).To clone MUS81, a 3.4-kb fragment containing the MUS81 genewith 1 kb of upstream and 0.5 kb of downstream sequences wasamplified from genomic DNA. The fragment was digested with SalIand BamHI (engineered by PCR) and ligated into either pRS316or pRS315 to make pCL2 and pCL3, respectively. Site-directedmutagenesis changing the aspartic acids at positions 414 and415 to alanine was performed using pCL2 to make mus81-DD. Themus81 ${Delta}$ ::ARG4 mutation was constructed by first subcloning a 2.9-kbBamHI/HindIII fragment from pCL4 into BamHI/SalI pRS305 to makepDT6. A 1.3-kb BglII fragment within MUS81 was substituted fora 3.3-kb BamHI PCR fragment containing ARG4 to make pDT8.

Yeast strains:
Liquid and solid media were as described (VERSHON et al. 1992; DE LOS SANTOS and HOLLINGSWORTH 1999 ). All yeast strainsare derived from the SK1 strain background. The following strainsare homozygous isogenic derivatives of NH144:

NH371,mus81 ${Delta}$ ::kanMX4; NH274F, mms4 ${Delta}$ ::hisG; NH416, red1::LEU2mus81 ${Delta}$ ::kanMX4;NH396, mek1 ${Delta}$ ::LEU2 mus81 ${Delta}$ ::kanMX4; NH372F, mms4 ${Delta}$ ::hisGmus81 ${Delta}$ ::kanMX4.

The following are homozygous isogenic derivatives of NKY1551:

NH301, mms4 ${Delta}$ ::kanMX4; NH428, mus81 ${Delta}$ ::ARG4; NH445, mus81 ${Delta}$ ::ARG4mms4 ${Delta}$ ::kanMX4.

The following is an isogenic derivative of NHY290:

NHY1155, mms4 ${Delta}$ ::hphMX4.

The following are isogenic derivatives of NHY1296:

NHY1297,msh5 ${Delta}$ ::kanMX4; NHY1298, mms4 ${Delta}$ ::hphMX4; NHY1299, msh5 ${Delta}$ ::kanMX4mms4 ${Delta}$ ::hphMX4.

The following is an isogenic derivative of NHY957:

NH455, mms4 ${Delta}$ ::kanMX4.

Alleles marked with kanMX4 were disrupted by PCR using the methodof LONGTINE et al. 1998 . The mus81 ${Delta}$ ::ARG4 allele was introducedby transformation of a BamHI/XhoI fragment purified from pDT8.All gene disruptions were confirmed by Southern blot analysis(data not shown). Details of strain constructions are availableupon request.

Time courses:
Cells were sporulated as described in DE LOS SANTOS and HOLLINGSWORTH(1999). Meiotic progression was monitored by fixing cells with3.7% formaldehyde and staining them with 4',6-diamidino-2-phenylindole(DAPI) as described in WOLTERING et al. 2000 . Sporulationwas assessed by examining 200 cells using light microscopy todetermine the number of mature asci. For analysis of DSBs andcrossovers, DNA was digested in plugs as described in WOLTERINGet al. 2000 . The gels were prepared for hybridization and probedas described (MCKEE and KLECKNER 1997 ). The DSB fragments andcrossover bands were quantitated as described in WOLTERINGet al. 2000 . Joint molecule analysis was carried out as described(SCHWACHA and KLECKNER 1994 ; HUNTER and KLECKNER 2001 ). Electronmicroscopic analysis of spread chromosomes was performed asdescribed in WOLTERING et al. 2000 .

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Mus81 triggers the meiotic recombination checkpoint by the formation of unprocessed recombination intermediates:
Similar to mms4, the sporulation defect of mus81 has previouslybeen shown in the W303 genetic background to be due to a blockin prophase (MULLEN et al. 2001 ). This result, in conjunctionwith the observation that the spore viability of a mus81 mms4diploid resembles that of either mus81 or mms4 alone (DE LOSSANTOS et al. 2001 ), suggests that Mus81p and Mms4p functiontogether in meiotic cells. In SK1 strains the meiotic arrestsexhibited by mus81 and mms4 are not complete, thereby allowinga genetic test for gene interaction. The mus81 mms4 diploidsporulated at 33° exhibited a similar number of arrestedcells as mus81 or mms4 alone, indicating that the two genesact on the same pathway for meiotic progression (Fig 1A). Furthermore,the number of mature asci produced by the double mutant wasno more severe than that of either single mutant (wild type,73.2% ± 3.7; mus81, 2.2% ± 1.5; mms4, 3.8% ±2.2; mus81 mms4, 1.3% ± 1.0; n = 3). These observationssupport the idea that a complex containing Mus81 and Mms4 isnecessary for meiotic progression and sporulation.

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Figure 1. Time-course analyses of mus81 diploids. Isogenic SK1 diploids were transferred to sporulation medium and shifted to 33° (NH144, wild type; NH371, mus81; NH274F, mms4; NH372F, mus81 mms4; NH416, red1 mus81; NH396, mek1 mus81). (A) Meiotic progression for mus81 and mus-81 mms4. Cells were fixed and stained with DAPI and examined by fluorescence microscopy. Binucleate cells were classified as MI, tetranucleate cells as MII. A total of 200 cells were counted for each strain at each time point. (B) Meiotic progression for red1 mus81 and mek1 mus81. (C) Recombination between leu2 heteroalleles. Appropriate dilutions of each diploid from each time point were plated onto -leu and YPAD media, respectively. The number of Leu⁺ prototrophs was normalized to the total number of viable cells. (D) Cell viability. The viability of each diploid at each time point was normalized to the viability at the 0 time point for that strain. A, C, and D are from the same time course and represent the average of three independent colonies. B represents a separate time course in which the average of two single colonies for each strain was plotted.

In both S. cerevisiae and S. pombe, the mus81 sporulation andspore viability defects are dependent upon the initiation ofrecombination (BODDY et al. 2001 ; KALIRAMAN et al. 2001 ).It is therefore likely that the mus81 arrest is due to the presenceof aberrant or unprocessed recombination intermediates triggeringthe meiotic recombination checkpoint (reviewed in ROEDER andBAILIS 2000 ). This hypothesis was tested by assaying meioticprogression in mus81 strains in which meiosis-specific componentsof the checkpoint were mutated. RED1 and MEK1 encode proteinsthat localize to chromosome cores, which, in addition to synapsisand recombination, are required for the meiotic recombinationcheckpoint (SMITH and ROEDER 1997 ; XU et al. 1997 ; BAILISand ROEDER 1998 ). Mutation of RED1 completely suppressed themeiotic progression defect of mus8. mek1 also permitted meioticprogression of mus81 cells, although in this case the suppressionwas only partial (Fig 1B). Mutation of the PCH2 gene has noeffect on spore viability but suppresses or partially suppressesthe prophase arrest/delay caused by zip1, dmc1, and mms4 (SAN-SEGUNDOand ROEDER 1999 ; DE LOS SANTOS et al. 2001 ). Deletion ofPCH2 partially suppressed the prophase arrest/delay observedfor mus81 without improving spore viability (data not shown).

mus81 diploids exhibit high levels of meiotic heteroallelic recombination but decreased cell viability in return-to-growth experiments:
The ability of mus81 and mus81 mms4 cells to undergo meioticrecombination between leu2 heteroalleles was analyzed by assayingthe formation of Leu⁺ prototrophs as a function of time in sporulationmedium. Isogenic wild-type and mms4 diploids were included ascontrols. In all four strains, the frequency of Leu⁺ prototrophspeaked at 6 hr, although the absolute number of prototrophswas reduced two to fourfold in the three mutant diploids (Fig 1C).By 24 hr, the mutants exhibited five to sevenfold fewerprototrophs than did wild type. This experiment indicates thatheteroduplex formation is occurring at high frequency in themutant strains and that there is no synergistic effect on prototrophformation in the absence of both MUS81 and MMS4.

When cells are returned to growth, meiotically induced DSBsmust be repaired if cells are to be viable (ARBEL et al. 1999). The mus81 and mms4 diploids each exhibited a 10-fold decreasein cell viability in return-to-growth experiments, suggestinga role for these genes in DSB repair under return-to-growthconditions (Fig 1D). Alternatively, the lethality could ariseif cells try to progress through meiosis I (MI) with unrepairedchromosomes. To distinguish between these two possibilities,cell viability in meiotic time courses of mus81 in the presenceof ndt80 was measured. NDT80 encodes a transcription factorrequired for progression through MI (XU et al. 1995 ; CHU andHERSKOWITZ 1998 ). In return-to-growth experiments, cell viabilityis still reduced by mus81 in the presence of ndt80, demonstratingthat meiotic progression is not the source of the lethality(data not shown).

The mus81 mms4 diploid showed a synergistic 59-fold decreasein viability compared to that of either single mutant (Fig 1D).This decrease in cell viability, presumably as a result of beingunable to repair meiotically induced DSBs under return-to-growthconditions, is the only phenotype yet discovered that indicatesthat MMS4 and MUS81 may have independent function(s).

MUS81/MMS4 affect only a subset of crossovers in S. cerevisiae:
Genetic and physical assays were used to assess the effect ofmus81 and mms4 on the formation of meiotic crossovers. An SK1mus81 diploid (NH371) was sporulated at 30° and 1357 tetradswere dissected. Spore viability was 40.5%, consistent with previousresults (INTERTHAL and HEYER 2000 ; DE LOS SANTOS et al. 2001). Similar to mms4, the distribution of viable spores in tetradsresembles a random pattern (except for slightly more four- andzero-viable-spore tetrads than expected) and is not indicativeof meiosis I nondisjunction (DE LOS SANTOS et al. 2001 ; datanot shown). Tetrads producing four viable spores were examinedfor crossovers between HIS4 and MAT and for gene conversionat HIS4, LEU2, and ARG4. A small (1.6-fold), but statisticallysignificant, decrease in crossovers was observed in the mus81diploid (Table 1). Gene conversion was elevated at all threeloci, but the increase was statistically significant only atHIS4. These results strongly resemble those observed for mms4in the isogenic background (Table 1).

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Table 1. Recombination in mus81 and mms4 SK1 diploids

In the isogenic strains used for the experiment described above,only a single interval can be analyzed for crossovers. A morethorough analysis of the effects of mms4 on recombination wastherefore undertaken using a diploid SK1 strain, NHY957, thatis multiply marked on three different chromosomes. The wild-typeand mms4 diploids were sporulated at 30° and produced 93.2%(499 asci) and 45.4% (2849) viable spores, respectively. Tetradanalysis suggests a correlation between chromosome size andthe effect of mms4 on crossing over in four-viable-spore asci(Fig 2). Overall, crossing over in the intervals analyzed alongchromosome III ( $~$ 330 kb) is reduced 1.5-fold relative to wild-typelevels; on chromosome VIII ( $~$ 580 kb) and VII ( $~$ 1040 kb), crossingover is reduced 1.3- and 1.1-fold, respectively (Fig 2). Whenanalyzed individually, all of the intervals on chromosome IIIas well as one interval on chromosome VIII exhibited a statisticallysignificant, 1.4- to 1.7-fold decrease in the number of crossovers(Table 2). In contrast, the reductions in crossing over in thethree intervals on chromosome VII were not significantly differentfrom wild type. In addition, 6 out of 11 loci displayed significantincreases in gene conversion (Table 2).

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Figure 2. Crossover distribution in wild-type and mms4 ${Delta}$ tetrads. (A) Physical maps of test intervals. Gene order, relative interval size, and overall size of the chromosomes are shown. Shaded circles indicate centromere location; arrowheads represent telomeres. (B) Crossover frequency in mms4 ${Delta}$ as a function of chromosome size. Each data point represents the sum of the individual map distances for each chromosome, expressed as a percentage of the wild-type value.

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Table 2. Gene conversion and crossing over in wild-type and mms4 SK1 diploids

Crossover distribution in mms4 mutants:
MMS4 is required for the formation of a subset of crossoversthat appear to be more conspicuous along short chromosomes.To further characterize this phenomenon, we examined crossoverdistribution in tetrads producing four viable spores from wild-typeand mms4 strains. The intensity of interference between adjacentcrossovers can be measured in two ways: (1) the coefficientof coincidence, which is defined as the number of double crossovers(DCOs) observed divided by the number expected in the absenceof interference (STURTEVANT 1913 ; MULLER 1916 ) and (2) thenonparental ditype (NPD) ratio, which compares the observednumber of four-strand DCOs within a single interval with thenumber expected in the absence of interference (PAPAZIAN 1952; SNOW 1979 ). Both the coefficients of coincidence and theNPD ratios are very similar between the wild-type and mms4 diploids,indicating that MMS4-independent crossovers are distributednormally by interference (Table 3; data not shown).

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Table 3. Coefficients of coincidence in isogenic MMS4 and mms4 diploids

Physical monitoring of recombination events in mus81 and mms4 mutants:
The genetic data are based on a highly selected subset of cells(the $~$ 10% that form mature asci at 30°, of which only $~$ 10%make four viable spores). The small reduction on crossoversobserved genetically may, therefore, overestimate the numberof crossovers occurring in the population as a whole. This caveatwas addressed by detecting DSBs and crossovers by direct analysisof the DNA at the HIS4::LEU2 meiotic recombination hotspot onchromosome III (STORLAZZI et al. 1995 ). Although mms4 and mus81phenotypes with respect to DSBs are highly similar, they arenot identical (Fig 3). DSBs are slightly more delayed in mus81than in mms4 and DSBs tend to persist longer in mms4 than inmus81. Whether or not these subtle differences are meaningfulremains to be seen. No synergistic phenotypes were observedbetween the mus81 mms4 diploid and either single mutant (Fig 3).Crossing over was unaffected by the mutants in this experiment,although this result is somewhat variable. In some experimentswe have observed up to a 1.8-fold reduction in crossovers bythis assay (DE LOS SANTOS et al. 2001 ; see below). The variabilityis likely due to the fact that the effect on crossing over bymus81 and mms4 is relatively small (<2-fold) and the limitson the resolution of the quantitation. It is clear, however,that the bulk of meiotic crossovers do not require MUS81/MMS4.

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Figure 3. Effects of mus81 and mus81 mms4 on the formation of DSBs and crossovers at the HIS4/LEU2 recombination hotspot. DNA was isolated from wild type (NKY1551), mus81 ${Delta}$ (NH428), mus81 ${Delta}$ mms4 ${Delta}$ (NH445), and mms4 ${Delta}$ (NH301) at different times after transfer to sporulation medium at 33°. The bracket indicates DSBs. DNA was digested with XhoI and probed with a 0.6-kb EcoRI/XmnI fragment from pNKY155. The expected DSB and crossover (CO) fragments predicted by MCKEE and KLECKNER 1997

are indicated. Parental fragments are labeled P. The second crossover fragment is not resolved from the larger parental band. DSB and CO fragments were quantitated as described in DE LOS SANTOS et al. (2001). To enhance visibility, a longer exposure of the DSB part of the gel is shown.

Physical assays of recombination have been used to characterizeintermediate steps of recombination, which proceed via the formationof DNA joint molecules (SCHWACHA and KLECKNER 1995 ). First,one side of a resected DSB invades an intact homologous duplexand undergoes strand exchange to form a SEI. The second DSBend then interacts to form a dHJ. DNA synthesis and ligationmust accompany these transitions to produce dHJs with uninterruptedfull-length strands, as observed (SCHWACHA and KLECKNER 1995; ALLERS and LICHTEN 2001A ). Two recent studies have providedevidence that dHJs are the direct precursors of crossovers duringmeiosis (ALLERS and LICHTEN 2001A ; HUNTER and KLECKNER 2001). To determine the role of MUS81/MMS4 in joint molecule formationand resolution, we analyzed DSBs, SEIs, dHJs, and crossoversin wild-type (NHY290) and mms4 (NHY1155) cells at a modifiedversion of the HIS4::LEU2 locus (Fig 4; HUNTER and KLECKNER2001 ).

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Figure 4. Assay system for analysis of recombination intermediates. (A) Physical map of the modified HIS4/LEU2 locus (see HUNTER and KLECKNER 2001

, for details). Open reading frames and diagnostic restriction sites are shown. Parental homologs "Mom" and "Dad" are distinguished by XhoI restriction site polymorphisms (circled X's). The size and identity of signal detected by Southern hybridization with a unique probe (probe A, SCHWACHA and KLECKNER 1997

) are shown below. SEI 1 and 2 correspond to the prominent SEI species, SEI 3 and SEI 4, described in HUNTER and KLECKNER 2001

. IS-dHJs, intersister double HJs; IH-dHJs, interhomolog double HJs; Recs, interhomolog crossover recombinants. (B) Southern blots of one-dimensional gels from wild-type (NHY290) and mms4 ${Delta}$ (NHY1155) time courses. Joint molecule recombination intermediates (highlighted by bracket) were analyzed by two-dimensional (2D) gel electrophoresis and Southern hybridization, as shown in C. In this case, branched DNA species are retarded relative to linear molecules in the second dimension. DHJs are highlighted by a trident; the prominent interhomolog signal is flanked by the two weaker intersister species. SEIs are highlighted by a fork with three lines; the two prominent species correspond to SEI 1 and SEI 2.

In wild type, DSBs first appear 2 hr after transfer into sporulationmedium at 30°, peak at 4.5 hr, and have essentially disappearedby 7 hr (Fig 4 and Fig 5C, Fig I). Steady-state levels ofSEIs, interhomolog dHJs (IH-dHJs), and intersister dHJs (IS-dHJs)peak at $~$ 4.5 hr; crossovers (Recs) are first detected at 4.5hr and reach maximum levels at $~$ 8 hr (Fig 4 and Fig 5C, ii,iii, iv, and vi). The timing of DNA events is essentially identicalto that described by HUNTER and KLECKNER 2001 .

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Figure 5. Analysis of recombination intermediates in wild-type and mms4 ${Delta}$ diploids. (A and B) Top row, 2D gels showing representative time points; asterisks indicate time points in the second row. Third and fourth rows, DNA species quantitated as percentage of total hybridizing signal and plotted against time after transfer to sporulation medium. SEIs and dHJs are analyzed using 2D gels; DSBs and Recs are analyzed by 1D gel (see Fig 4B and Fig C). (C) Direct comparison of meiotic events in wild type and mms4 ${Delta}$ . Data are taken from A and B. In graph v, the ratio of signals, IH-dHJ/IS-dHJ, is plotted against time after transfer to sporulation medium. % MI/MII, percentage of cells that have completed one or both meiotic divisions as determined by DAPI staining. Dotted lines indicate discontinuities in the x-axes.

In mms4, DSB kinetics parallel those described previously (DELOS SANTOS et al. 2001 ); DSBs peak at essentially the samelevel as wild type but this peak occurs 2 hr later than thatof wild type and significant numbers of DSBs remain at latetimes. SEIs form at reduced levels ( $~$ 2-fold) and peak 2–3hr later than wild type. IH-dHJs are also reduced, perhaps toan even greater extent ( $~$ 3-fold), and appear with a similar delay.Formation of intersister dHJs is also delayed but in contrastto the interhomolog species, IS-dHJs form at high levels ( $~$ 1.25-foldreduction in peak steady-state levels and very similar areasunder the corresponding curves). This effect is seen most clearlywhen the ratios of interhomolog dHJs to intersister dHJs areplotted over time (Fig 5C, Fig V). Consistent with previousreports (SCHWACHA and KLECKNER 1997 ; HUNTER and KLECKNER 2001), dHJ formation in wild-type cells is heavily biased towardthe interhomolog species with an average ratio of 4.3. Interhomologbias is almost absent in mms4 cells, which have an average IH-dHJ/IS-dHJratio of 1.4-fold (in both cases, the first time point at whichdHJs are detectable is excluded from this average because levelsare very low and quantitation is likely to be inaccurate). Crossoverproducts appear at reduced levels (1.8-fold) and with a delayof $~$ 3 hr and finally, meiotic divisions are delayed but eventuallyoccur with reasonable efficiency as observed previously formms4 SK1 strains at 30° (DE LOS SANTOS et al. 2001 ; Fig 5C,vi and vii).

mus81 and mms4 have no effect on chromosome synapsis in the NKY1551 SK1 strain background:
Previously polycomplexes and other anomalies in the formationof synaptonemal complexes (SCs) were observed in the mms4 derivativeof NH144 (DE LOS SANTOS et al. 2001 ). Similar results wereobtained for mus81 in this strain background at 33° (datanot shown). These anomalies appear to be strain specific sincethey were rarely seen in the mus81, mms4, and mus81 mms4 derivativesof NKY1551 (data not shown). All four diploids exhibited SCsat the same early time point (4 hr) but, in the mus81, mms4,and mus81 mms4 diploids, SCs persisted until 7 hr in a subsetof cells; no SCs were observed in the wild type at such a latetime point (data not shown). Thus, entry into pachytene is notdelayed but exit from pachytene is retarded in the mutants,consistent with a delay in pachytene triggered by the meioticrecombination checkpoint. In addition to normal SCs, many nucleiwith faint and/or fragmented SCs were seen in the mutants at7 hr (data not shown). We assume that these SCs are in the processof disintegration after prolonged arrest at pachytene. Synapsisis therefore not affected by absence of MUS81 or MMS4.

MMS4/MUS81 and MSH4/MSH5 function independently with respect to both spore viability and crossing over:
The MSH4/MSH5 genes encode meiosis-specific MutS homologs that,like MUS81/MMS4, are required for full levels of crossing over(ROSS-MACDONALD and ROEDER 1994 ; HOLLINGSWORTH et al. 1995). The phenotypes of msh4/msh5 mutants are, however, distinctfrom those of mms4/mus81. For example, the spore lethality inmsh4/msh5 mutants can be attributed to homolog nondisjunction,which is not the case for mus81/mms4 (HOLLINGSWORTH et al. 1995; DE LOS SANTOS et al. 2001 ; this study). Also, interferenceis not observed between the crossovers that form in msh4/msh5(NOVAK et al. 2001 ; N. HUNTER, V. BOERNER, A. JAMBAHKAR andN. KLECKNER, unpublished results) whereas crossovers in mus81/mms4do show an interference distribution (this study). These observationssuggest the possibility that MUS81/MMS4 and MSH4/MSH5 promotedistinct classes of crossovers. Consistent with this idea, amus81 msh5 double mutant shows decreased spore viability relativeto either single mutant (wild type, 96.1%; msh5, 43.9%; mus81,35.6%; mus81 msh5, 19.5%). These data resemble those observedfor mms4 msh5 (DE LOS SANTOS et al. 2001 ). Physical analysisof crossing over at the HIS4::LEU2 locus reveals that crossingover in a mms4 msh5 double mutant is reduced $~$ 3-fold relativeto either of the single mutants (Fig 6). A residual amount ofcrossing over ( $~$ 6-fold reduced, relative to wild type) can stillbe detected in mms4 msh5 cells and may account for the residualspore viability observed for this strain. When taken togetherwith the results presented above, these data indicate that MUS81/MMS4and MSH4/MSH5 promote essentially independent classes of meioticcrossovers.

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Figure 6. Effects of msh5, mms4, and mms4 msh5 on the formation of crossovers at the modified HIS4/LEU2 recombination hotspot. (A) DNA was isolated from wild type (NKY1296), mms4 ${Delta}$ (NHY1298), msh5 ${Delta}$ mms4 ${Delta}$ (NHY1299), and msh5 ${Delta}$ (NHY1297) at different times after transfer to sporulation medium at 33°. The DNA was digested with XhoI and probed with a 0.6-kb AgeI/BglII fragment from pNH90. The expected crossover (CO) and parental (P) fragments predicted in Fig 4 are indicated. (B) The CO2 bands were quantitated as described in DE LOS SANTOS et al. (2001). Because of the bubble in the P2 band of the NHY1297 diploid, for quantitation purposes, the total DNA is defined as P1 + CO2.

Catalytic site residues are required for MUS81 function during meiosis:
MUS81 is proposed to resolve meiotic HJs in S. pombe, a functionfor which it is apparently not required in S. cerevisiae meiosis.The question then exists whether MUS81 acts in a fundamentallydifferent way, e.g., as a structural protein instead of an enzyme,during meiosis in budding yeast compared to fission yeast. Toaddress this, two conserved aspartic acid residues (D414A, D415A)in the Mus81 protein were changed to alanine. Recent experimentshave shown that the aspartic acid in the mammalian XPF proteinequivalent to D415 is part of the active site required for catalyticactivity (ENZLIN and SCHARER 2002 ). These mutations have beenshown to create a null allele in S. pombe and to abolish enzymaticactivity in both the S. pombe and human Mus81 complexes withoutaffecting protein stability (BODDY et al. 2001 ; CHEN et al.2001 ). The S. cerevisiae mus81-DD allele failed to complementboth the sporulation and spore viability defects of mus81, producing37.5% viable spores compared to 85.2% for the wild type. Thecatalytic activity of MUS81 is therefore required for meiosis.

Expression of the bacterial Holliday junction resolvase rusA fails to suppress the mus81 meiotic mutant phenotypes:
The spore inviability of S. pombe mus81 mutants can be partiallysuppressed by expression of the highly specific Holliday junctionresolvase, rusA. Although crossovers are detected in S. cerevisiaemus81 mutants, it is possible that failure to resolve a subsetof HJs results in triggering the meiotic recombination checkpointand decreased spore viability. In this case, overexpressionof rusA might suppress the mus81 meiotic defects in S. cerevisiae.This idea was tested by fusing the same NLS-rusA-2HA allele(hereafter referred to as rusA) used by BODDY et al. 2001 to the meiosis-specific MEK1 promoter on a high-copy-numberplasmid (pNH246wt). As a control, an allele containing a mutationin the catalytic site of the enzyme, rusA-D70N (pNH246), wasincluded (DOE et al. 2000 ). Western blot analysis using ${alpha}$ -HAantibodies confirmed that the rusA proteins were expressed at3 hr, prior to the time that crossovers are first observed (datanot shown). No improvement in either sporulation or spore viabilitywas observed in cells expressing either rusA protein (Table 4).The meiosis specificity of the expression of the MEK1p-rusAallele prohibits performing alternative assays in vegetativecells to determine whether or not rusA is active in buddingyeast. Suppression of the mus81 spore inviability was thereforerepeated with an untagged allele of rusA that is fused to theSGS1 promoter. This rusA plasmid suppresses the UV and camptothecinsensitivity of mms4 and is therefore functional in S. cerevisiae(S. BRILL, personal communication). Also, no suppression ofthe mus81 meiotic phenotypes was observed with this allele ofrusA (Table 4).

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Table 4. Sporulation and spore viability in mus81 diploids overexpressing rusA

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Mus81/Mms4 is not the major meiotic HJ resolvase in S. cerevisiae:
Mus81 was proposed to be a HJ resolvase in part on the basisof the observation that crude preparations of Mus81 from S.pombe and human cells cleave HJs in vitro (BODDY et al. 2001; CHEN et al. 2001 ). However, recent experiments using Mus81complexes, either purified to homogeneity from bacterial cellsor partially purified from human cells, indicate that the fissionyeast, budding yeast, and human enzymes all exhibit a preferencefor cleaving three-way junction and replication fork structuresover HJs (KALIRAMAN et al. 2001 ; CONSTANTINOU et al. 2002; DOE et al. 2002 ). In addition, those HJs cleaved by Mus81cannotbe religated, indicating that nonsymmetrical nicks are beinggenerated (BODDY et al. 2001 ; CONSTANTINOU et al. 2002 ).It has therefore been proposed that eukaryotes might resolveHJs in a different way from the paradigm established by bacterialHJ resolvases, such as ruvC and rusA, in which two symmetricalnicks are generated on strands of opposite polarity (WEST etal. 1984 ; BODDY et al. 2001 ). The finding of a ruvC-likeactivity from human cells, however, argues against this idea(CONSTANTINOU et al. 2002 ).

Several aspects of our data indicate that Mus81/Mms4 is notthe major meiotic HJ resolvase in S. cerevisiae. First, mus81and mms4 exhibit, at most, a twofold decrease in crossing overand this reduction appears to be limited to specific chromosomes.Second, double HJs do not accumulate in an mms4 mutant, as wouldbe expected for a mutant whose sole defect is the inabilityto resolve HJs. Finally, unlike fission yeast, expression ofa heterologous HJ resolvase has no suppressive effect on themus81 and mms4 meiotic phenotypes.

S. cerevisiae Mms4/Mus81 promotes a distinct set of meiotic crossovers:
The crossovers that form in an mms4 mutant are qualitativelynormal, being subject to interference. We have shown that themajority of these MMS4/MUS81-independent exchanges are facilitatedby the MSH5 gene product. In contrast to the mms4 phenotype,the residual crossovers that occur in msh4 or msh5 mutants donot show interference (NOVAK et al. 2001 ; N. HUNTER, V. BOERNER,A. JAMBAHKAR and N. KLECKNER, unpublished results). These factsare consistent with the idea that there are (at least) two classesof crossovers in S. cerevisiae: Class I crossovers exhibit aninterference distribution whereas class II crossovers do not(e.g., ZALEVSKY et al. 1999 ; COPENHAVER et al. 2002 ). Wecan now propose that the two classes of crossovers are promotedby biochemically distinct processes: class I by a Msh4/5-basedcomplex and class II by a Mms4/Mus81-based complex.

Both genetic and physical assays show that the decrease in crossingover in mus81 and mms4 mutants is modest (1.1- to 1.8-fold)and our analysis of crossover distribution implies that thatMus81/Mms4 promotes a specific subset of crossovers, as opposedto having a partial, but general, role in crossing over. Morespecifically, class II crossovers appear to be more prominentbetween shorter chromosomes, suggesting that recombination respondsto chromosome size by modulating the relative numbers of classI and class II crossovers. A strong prediction of the two-crossoverpathway model is that crossovers present in mms4 mutants shouldexhibit stronger interference than wild type. Our current dataset is too small to establish whether or not this is true, andtherefore models in which MUS81/MMS4 have a general role incrossing over cannot be ruled out. To prove the chromosome sizespecificity of mms4, the same genetic intervals need to be examinedin the context of short and long chromosomes for crossoversand interference. Experiments to do this using translocationchromosomes are currently underway.

Three aspects of meiotic recombination in wild-type S. cerevisiaehave been correlated with chromosome size. First, KABACK etal. 1989 have shown that recombination rate responds directlyto changes in chromosome size, with smaller chromosomes havinghigher rates of crossing over. Second, small chromosomes werefound to have less intense crossover interference than largeones (KABACK et al. 1999 ). Finally, the genome-wide analysisof meiotic DSB hotspots, performed by GERTON et al. 2000 ,indicates that recombination hotspots are denser along shortchromosomes. Taken together, these data suggest that chromosomesize-dependent changes in the rate of crossing over may resultfrom correlated modulation of both recombination initiation(DSB formation) and crossover interference. Our results suggestthat Mms4/Mus81 is central to this phenomenon.

Reconciling differences between mus81 meiotic phenotypes in S. cerevisiae and S. pombe:
In most organisms, including S. cerevisiae, homologous chromosomesbecome coaligned and physically associated along their lengthsvia the SC. A major SC component, Zip1, is required for theformation of crossovers that show an interference distribution(SYM and ROEDER 1994 ) and, moreover, epistasis analysis revealsthat ZIP1 and MSH4/5 promote the same set of crossovers (NOVAKet al. 2001 ). In contrast, there is no SC and no crossoverinterference in S. pombe (BAHLER et al. 1993 ; MUNZ 1994 )and, accordingly, ZIP1 and MSH4/5 homologs are absent from theS. pombe genome (VILLENEUVE and HILLERS 2001 ). We propose,therefore, that meiotic crossovers in S. pombe arise exclusivelyvia a SC-independent, MUS81-dependent pathway. The MUS81 pathwayalso operates in S. cerevisiae, but most crossovers arise viathe pathway defined by ZIP1 and MSH4/5 (Fig 7). The dependencyin S. pombe solely on the MUS81 pathway for crossovers may explainwhy the mus81 spore viability defect is so much more severein fission yeast compared to budding yeast (<0.1% vs. 40%).

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Figure 7. Model for two pathways of crossing over. Shaded lines indicate the condensed pairs of homologous sister chromatids. Vertical lines indicate synapsis. Open ovals indicate crossovers along the interference ZIP1/MSH5-dependent pathway. Solid bars indicate crossovers occurring along the noninterference MUS81/MMS4-dependent pathway.

Why does rusA suppress the mus81 spore inviability in S. pombebut not in S. cerevisiae? One explanation is that Mus81 complexesfunction differently in the two yeasts, i.e., as a HJ resolvasein S. pombe and a 3' flap endonuclease in S. cerevisiae. Thisargument is weakened by the recent observation that S. pombeMus81/Eme1 purified from bacterial cells exhibits the same preferencefor 3' flap and replication fork structures as Mus81/Mms4 (DOEet al. 2002 ). Another possibility is that rusA is able to cleave3' flaps in vivo. Although rusA is highly specific for HJ cleavagein vitro, how it acts when overexpressed in a eukaryotic nucleushas not been determined. In this case, rusA may not suppressmus81/mms4 in S. cerevisiae because access to the DNA is blockedby synapsis between homologous chromosomes. The sporulationand spore viability defects of mms4 can be partially suppressedby red1 but not mek1 (DE LOS SANTOS et al. 2001 ). One phenotypicdifference between red1 and mek1 is that mek1 mutants form someSC while red1 mutants do not (ROCKMILL and ROEDER 1990 , ROCKMILLand ROEDER 1991 ). We have argued that in an mms4 diploid, alternativepathways may resolve recombination intermediates in the absenceof synapsis, but that SC formation prevents such alternativeprocessing (DE LOS SANTOS et al. 2001). It is possible thatthe presence of SC also prevents rusA from acting. Since S.pombe chromosomes do not synapse, there is no barrier to rusAaction in this species.

The complementary situation appears to exist in nematodes. Crossingover in worms is likely to undergo interference (A. VILLENEUVE,personal communication) and is completely abolished by mutationof either msh-4 or msh-5 (ZALEVSKY et al. 1999 ; KELLY et al.2000 ). Therefore, by our model, C. elegans most closely resemblesan S. cerevisiae mms4/mus81 mutant (Fig 7). Although a Mus81homolog is present in nematodes (Saccharomyces Genome Database),it is lacking an N-terminal domain that is also absent fromS. pombe but is common to both mammalian and budding yeast Mus81(A. NEIMAN, personal communication). Mutation of conserved residueswithin this domain creates null alleles of MUS81 with regardto spore viability, suggesting this domain may be specificallyinvolved in the meiotic function of MUS81 (D. TURNEY and N.M. HOLLINGSWORTH, unpublished results). It will be interestingto discover whether or not mus81 mutants in nematodes have ameiotic phenotype.

Recombination intermediates and interference-mediated crossovers are delayed in the absence of MUS81 and MMS4:
Although physical analysis of recombination intermediates inmus81 ${Delta}$ and mms4 ${Delta}$ cells is not indicative of a problem with HJresolution, the progression of some meiotic events is clearlydifferent from wild type in several ways. For example, peaksteady-state levels of DSBs occur later than normal. This observationcould be explained in several different ways:

DSBs form laterdue to a delay in meiotic S-phase caused bymus81/mms4-relatedreplication problems. This possibility seemsunlikely, giventhat all of the mus81 and mms4 meiotic phenotypesare dependentupon the initiation of recombination (DE LOS SANTOSet al. 2001; KALIRAMAN et al. 2001 ).
DSBs are formed with normal timingbut some DSBs turn over fasterthan normal.
Fewer DSBs areformed.

In addition, some DSBs do not appear to turn over (or arisein some aberrant way, e.g., faulty processing of an intermediate).The fact that all ensuing events occur later than normal ismost consistent with a general delay in meiosis. However, SCsappear with normal timing in mus81/mms4 mutants, indicatingthat two key events of the meiotic program, homolog coalignmentand SC formation, are unaffected.

Although many crossovers in mms4 ${Delta}$ cells form and are subjectto an interference distribution, they arise later than normaldue to the mms4-induced delay in meiotic progression. Formationof crossover precursors, SEIs and dHJs, is similarly delayed.Perhaps correction of the problems along the MMS4/MUS81 pathwayis required before the events along the MSH4/5 pathway can proceed.

Model of MMS4/MUS81 function in S. cerevisiae:
Recently an alternative pathway for meiotic recombination wasproposed to account for the existence of recombination intermediatesthat do not conform to the predictions of the DSBR model (ALLERSand LICHTEN 2001B ). In the strand displacement-mediated crossovermodel, recombination is initiated by formation of a DSB followedby resection and invasion of the nonsister duplex. After DNAsynthesis extends the invading strand, it is partially displacedand anneals to the 3' ss tail on the other side of the break.If the extended sequence is longer than the 3' ss tail, a 3'flap may be generated (Fig 8B). Cleavage of the flap 5' to thejunction would allow the break to be fixed by extension andligation.

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Figure 8. Pathways of meiotic DSB repair. In all cases, recombination is initiated by the invasion of a resected 3' tail into the homologous duplex. (A) The canonical DSB repair model. After capture of the second end, ligation creates two HJs flanking regions of heteroduplex DNA. Resolution of the HJs in opposite ways (indicated by carets) generates two intact crossover chromosomes. (B) Strand displacement-mediated crossing over with a 3' flap. After DNA synthesis extends the invading strand, the strand is partially displaced and reanneals to the ss tail on the other side of the break. Overreplication creates a 3' flap that could be cleaved by Mus81/Mms4p (indicated by an asterisk). Resolution of the HJs generates an intact crossover chromatid and an unrepaired chromatid. (C) Strand displacement-mediated crossing over with a 5' flap. The overreplicated strand anneals completely to the other side of the break, thereby creating a 5' flap. Repair is achieved by cleavage of the flap and ligation. Resolution of the HJs generates two intact crossover chromatids. Dashed lines indicate newly synthesized DNA.

This type of 3' flap structure is an excellent substrate invitro for purified Mus81/Mms4 (KALIRAMAN et al. 2001 ). We thereforepropose that MUS81/MMS4 is required to process these flaps duringmeiotic recombination (DE LOS SANTOS et al. 2001 ). Failureto cleave the flaps results in unprocessed recombination intermediatesthat trigger the meiotic recombination checkpoint. The decreasein dHJs and SEIs observed in mms4 could be explained if a failureto process flaps at the annealing stage renders the intermediateslabile or causes them to be processed by a different mechanism.In some cases, resolution of the dHJs could result in one crossoverchromosome and one unrepaired chromatid that would be lethalto the spore (Fig 8B). This mechanism of lethality could explainthe near random distribution of viable spores in tetrads iflethality is dependent upon the number of unrepaired chromosomesthat segregate to any given spore.

For both mms4 and mus81, a slightly higher number of four-viable-sporetetrads are observed than are predicted by random death. Clearlyall of the chromatids in these asci are intact since all ofthe spores are viable. One way this could occur would be ifthe 3' flap is converted to a 5' flap, perhaps by branch migration(Fig 8C). The 5' flap could then be cleaved by a 5' flap endonuclease,allowing ligation and repair of the break. Because the heteroduplextracts would be longer, higher levels of gene conversion wouldbe predicted to occur. In fact, elevated levels of gene conversionwere observed for both mus81 and mms4 in four-viable-spore asci.If the four-viable-spore asci result from 5' flap processing,they should be eliminated by a second mutation in a gene encodingthe 5' flap endonuclease. RAD2 and RAD27 both encode 5' flapendonucleases (HABRAKEN et al. 1995 ; KAO et al. 2002 ). Sporeviability is unaffected by rad2 in either the presence or theabsence of MUS81 (N. M. HOLLINGSWORTH, unpublished results).The mus81 rad27 combination is synthetically lethal in vegetativecells (TONG et al. 2001 ; N. M. HOLLINGSWORTH, unpublished results).Therefore while the meiotic experiment could not be done, thisgenetic interaction suggests that MUS81/MMS4 and RAD27 act inalternative pathways of DNA repair in mitotically dividing cells.

Earlier we proposed that MUS81/MMS4 functions on a differentpathway for crossing over from that of MSH5. However, crossingover and spore viability are only reduced in the msh5 mms4/mus81double mutants; they are not eliminated. While the residualcrossovers in the double mutant could be explained by the presenceof a third pathway of crossing over, this result may also beexplained if MUS81/MMMS4 functions in the partial strand displacementand annealing pathway described above. MUS81/MMM4 is requiredonly for those intermediates in which the originally invadingend is overreplicated to make the 3' flap. If overreplicationoccurs in just a subset of intermediates along this pathway,intermediates without flaps that can be resolved normally inthe absence of MUS81/MMS4 to make crossovers may also be generated.

FOOTNOTES

¹ These authors contributed equally to this article.

ACKNOWLEDGMENTS

We thank Steve Brill, Michael Lichten, Aaron Neiman, Jim Haber,and Frank Stahl for helpful discussions. JoAnne Engebrecht andAaron Neiman provided useful comments on the manuscript. Wethank Paul Russell and Steve Brill for providing rusA plasmids.We are grateful to Lihong Wan for tetrad dissection and to DanaTurney for excellent technical support. This work was supportedin part by research grant 1-FY02-754 from the March of DimesBirth Defects Foundation and by a grant from the National Institutesof Health (GM-50717) to N.M.H. J.L. was supported by the AustrianScience Fund (grant S8202).

Manuscript received December 9, 2002; Accepted for publication January 31, 2003.

LITERATURE CITED

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MATERIALS AND METHODS
RESULTS
DISCUSSION
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