A Role for MMS4 in the Processing of Recombination Intermediates During Meiosis in Saccharomyces cerevisiae

A Role for MMS4 in the Processing of Recombination Intermediates During Meiosis in Saccharomyces cerevisiae

Teresa de los Santos^a, Josef Loidl^b, Brittany Larkin^a, and Nancy M. Hollingsworth^a
^a Department of Biochemistry and Cell Biology, Institute for Cell and Developmental Biology, State University of New York, Stony Brook, New York 11794-5215
^b Department of Cytology and Genetics, Institute of Botany, University of Vienna, A-1030, Vienna, Austria

Corresponding author: Nancy M. Hollingsworth, 314 Life Sciences Bldg., Department of Biochemistry and Cell Biology, State University of New York, Stony Brook, NY 11794-5215., nhollin{at}notes.cc.sunysb.edu (E-mail)

Communicating editor: M. LICHTEN

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The MMS4 gene of Saccharomyces cerevisiae was originally identifieddue to its sensitivity to MMS in vegetative cells. Subsequentstudies have confirmed a role for MMS4 in DNA metabolism ofvegetative cells. In addition, mms4 diploids were observed tosporulate poorly. This work demonstrates that the mms4 sporulationdefect is due to triggering of the meiotic recombination checkpoint.Genetic, physical, and cytological analyses suggest that MMS4functions after the single end invasion step of meiotic recombination.In spo13 diploids, red1, but not mek1, is epistatic to mms4for sporulation and spore viability, suggesting that MMS4 maybe required only when homologs are capable of undergoing synapsis.MMS4 and MUS81 are in the same epistasis group for spore viability,consistent with biochemical data that show that the two proteinsfunction in a complex. In contrast, MMS4 functions independentlyof MSH5 in the production of viable spores. We propose thatMMS4 is required for the processing of specific recombinationintermediates during meiosis.

THE key step in meiosis is the segregation of homologous chromosomesto opposite poles at the first meiotic division (MI). For properchromosome disjunction at MI to occur, nonsister chromatidsof each pair of homologs must be connected by crossovers (manifestedcytologically by chiasmata; BASCOM-SLACK et al. 1997 ). Creatingcrossovers functional for disjunction requires coordinationbetween the recombination machinery and a tripartite proteinaceousstructure, called the synaptonemal complex (SC), which is formedbetween homologous chromosomes.

Many steps in the pathway of recombination predicted by thedouble-strand-break (DSB) model (SZOSTAK et al. 1983 ) havenow been detected at the molecular level (reviewed in SMITHand NICOLAS 1998 ). Furthermore, gene products that are requiredfor many of these steps have been identified. Meiotic recombinationis initiated in Saccharomyces cerevisiae by DSBs introducedinto the DNA by a topoisomerase-like protein, Spo11p (KLAPHOLZet al. 1985 ; BERGERAT et al. 1997 ; KEENEY et al. 1997 ).The Spo11 protein is conserved throughout evolution and phenotypesof spo11 mutants in worms, fruit flies, plants, and mice suggestthat its function is conserved as well (DERNBURG et al. 1998; MCKIM and HAYASHI-HAGIHARA 1998 ; BAUDAT et al. 2000 ; ROMANIENKO and CAMERINI-OTERO 2000 ; GRELON et al. 2001 ; MAHADEVAIAH et al. 2001 ). In addition to SPO11, several othergenes are required for DSB formation, although their roles inthis process remain obscure (SMITH and NICOLAS 1998 ). The 5'ends of the breaks are resected to produce 3' single-strandedtails, a process that requires MRE11, RAD50, and SAE2/COM1 (CAOet al. 1990 ; MCKEE and KLECKNER 1997A ; NAIRZ and KLEIN 1997; PRINZ et al. 1997 ; TSUBOUCHI and OGAWA 1998 ). The meiosis-specificRecA ortholog Dmc1p then directs invasion of single strandsinto duplexes of homologous nonsister chromatids (BISHOP etal. 1992 ; SCHWACHA and KLECKNER 1997 ). The detection of thesesingle end invasion (SEI) intermediates has recently been published(HUNTER and KLECKNER 2001 ). Further processing of these recombinationintermediates results in the formation of double Holliday junctions(HJs; SCHWACHA and KLECKNER 1995 ; ALLERS and LICHTEN 2001). For crossovers to occur, the two HJs must be resolved inopposite directions. The bias toward crossing over is promotedby a complex formed between two meiosis-specific MutS orthologs,Msh4p and Msh5p (ROSS-MACDONALD and ROEDER 1994 ; HOLLINGSWORTHet al. 1995 ; POCHART et al. 1997 ). Finally, HJs must be cutand the appropriate strands ligated so that nonsister chromatidsare no longer covalently attached.

Synapsis between homologous chromosomes in yeast begins whensister chromatids condense upon protein cores called axial elements(AEs), which are composed, at least in part, of three meiosis-specificproteins, Mek1p, Red1p, and Hop1p (reviewed by ROEDER 1997). Unstable DNA-DNA interactions between homologous chromosomesallow for connections between nonsister chromatids, which arethen stabilized by formation of DSBs and consequent recombination(KLECKNER 1996 ). At these sites of axial association, proteinssuch as Zip3 and Zip2 are bound and appear to nucleate the insertionof Zip1, a structural component of the central region of theSC (SYM and ROEDER 1995 ; CHUA and ROEDER 1998 ; AGARWAL andROEDER 2000 ).

It is clear that in yeast there is an intimate connection betweensynapsis and recombination. Mutants that fail to initiate recombinationalso fail to form SCs (ROEDER 1997 ). In addition, only thosecrossovers that occur in the presence of SCs allow proper disjunctionof homologs at MI (ENGEBRECHT et al. 1990 ). In terms of segregation,the formation of the AE appears to play a more crucial rolethan the formation of the central region. zip1 mutants formAEs that are aligned and connected by axial associations butlack the central region (SYM et al. 1993 ). Crossing over isreduced only two- to threefold with a twofold reduction in sporeviability (SYM and ROEDER 1994 ). In contrast, mutations incomponents of the AEs (HOP1, RED1, and MEK1) result in largedecreases in spore viability due to massive nondisjunction (HOLLINGSWORTHand BYERS 1989 ; ROCKMILL and ROEDER 1990 , ROCKMILL and ROEDER1991 ; LEEM and OGAWA 1992 ). Crossing over is reduced, butnot eliminated, in these mutants (HOLLINGSWORTH and BYERS 1989; ROCKMILL and ROEDER 1990 , 1991; MAO-DRAAYER et al. 1996). In red1 and hop1 diploids, those crossovers that do occurdo not function in promoting proper MI segregation (ROCKMILLand ROEDER 1990 ; B. BAUMGARTNER and N. M. HOLLINGSWORTH, unpublishedresults).

In an attempt to connect components of the AEs with proteinsinvolved directly in recombination, a twohybrid screen was performedusing MEK1 as bait. MEK1 encodes a meiosis-specific threonine/serineprotein kinase (ROCKMILL and ROEDER 1991 ; LEEM and OGAWA 1992). In addition to spore viability, MEK1 is required for wild-typelevels of recombination, sister chromatid cohesion, SC formation,correct partner choice, and the meiotic recombination checkpoint(ROCKMILL and ROEDER 1991 ; LEEM and OGAWA 1992 ; XU et al.1997 ; BAILIS and ROEDER 1998 ; THOMPSON and STAHL 1999 ).The meiotic recombination checkpoint blocks cells in prophaseif they contain aberrant recombination intermediates (ROEDERand BAILIS 2000 ). Kinase activity is required for MEK1 functionand Red1p has been shown to be a MEK1-dependent phosphoprotein(BAILIS and ROEDER 1998 ; DE LOS SANTOS and HOLLINGSWORTH 1999). The phosphorylation of Red1p by Mek1p is required for themeiotic recombination checkpoint as well as for facilitatingthe interaction of Red1p with Hop1p (BAILIS and ROEDER 1998; DE LOS SANTOS and HOLLINGSWORTH 1999 ).

Our screen identified MMS4 as a two-hybrid interacting proteinwith Mek1p. The mms4 mutant has previously been found to besensitive to alkylating agents such as MMS, weakly sensitiveto ultraviolet (UV) light, and resistant to X rays. In addition,mms4 mutants exhibit a weak mutator phenotype and a sporulationdefect (PRAKASH and PRAKASH 1977 ; XIAO et al. 1998 ; MULLENet al. 2001 ). The interaction between MMS4 and MEK1 suggestedthat MMS4 plays a role in recombination during meiosis. Meioticphenotypes for mms4 diploids were therefore examined to seeif the sporulation defect is the result of aberrant recombinationtriggering the meiotic recombination checkpoint. Our work supportsthis idea and suggests that MMS4 is required for the processingof recombination intermediates during meiosis.

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.

Yeast strains:
Strains are listed in Table 1. Liquid and solid media wereas described (VERSHON et al. 1992 ; DE LOS SANTOS and HOLLINGSWORTH1999 ). Because ade2 strains do not sporulate well under ourconditions, all diploids homozygous for ade2 were convertedto Ade⁺ either by transformation with an ADE2-integrating plasmidor by using ADE2-marked alleles for mutagenesis. Deletions weremade in the SK1 haploid strains, RKY1145 and S2683 (DE LOS SANTOSand HOLLINGSWORTH 1999 ), which were then mated to form diploids.MMS4 was deleted using the mms4 ${Delta}$ ::hisG-URA3-hisG allele in pWX1604(provided by W. Xiao, University of Saskatchewan). NH274 wasconverted to NH274F by recombining out the URA3 gene in eachhaploid parent using 5-fluoroorotic acid (BOEKE et al. 1984), followed by mating to form the diploid. REC104 was deletedusing pNH131 (HOLLINGSWORTH and JOHNSON 1993 ); RED1 was disruptedusing pNH119 (HOLLINGSWORTH and JOHNSON 1993 ); MEK1 was deletedusing pTS1 (DE LOS SANTOS and HOLLINGSWORTH 1999 ); PCH2 wasdeleted using pSS52 provided by G. S. Roeder (Yale University; SAN-SEGUNDO and ROEDER 1999 ); and MSH5 was disrupted usingpCH2 (POCHART et al. 1997 ). The MUS81 gene was deleted by PCRusing the method of LONGTINE et al. 1998 . PCR was also usedto delete MMS4 from the haploid parents of NKY1551, which weresubsequently mated to form NH301.

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Table 1. S. cerevisiae strains

NH298 was generated by a cross between two slow-sporulatingstrains, BR1373-6DSF ${alpha}$ AA, provided by J. Engebrecht (SUNY, StonyBrook), and 5787-21-4 (HOLLINGSWORTH and BYERS 1989 ). SPO11was deleted using pGB324 (GIROUX et al. 1989 ) provided by G.S. Roeder (Yale University); RED1 was deleted using pNH234 (WOLTERINGet al. 2000 ); MEK1 was deleted using pNH169 (HOLLINGSWORTHand PONTE 1997 ); and DMC1 was deleted using pMDE379 (DRESSERet al. 1997 ) provided by M. Dresser (University of Oklahoma).NH298::pBB9, NH246::pRS306, and NH331 were converted to Spo13⁺by transformation with pNH20-5 (HOLLINGSWORTH and BYERS 1989).

Time courses:
Cells were sporulated as described in DE LOS SANTOS and HOLLINGSWORTH(1999). SK1 strains were sporulated in 2% potassium acetatewhile non-SK1 strains were sporulated in SPM (HOLLINGSWORTHand JOHNSON 1993 ). Meiotic progression was monitored by fixingcells with 3.7% formaldehyde and staining them with 4',6-diamidino-2-phenylindole(DAPI) as described in WOLTERING et al. 2000 . At 33°,varying numbers of immature asci were observed from experimentto experiment. Therefore, only mature asci were scored whenassessing sporulation. For analysis of DSBs and crossovers,DNA was digested in plugs as described in WOLTERING et al.2000 . The gels were prepared for hybridization and probed asdescribed by MCKEE and KLECKNER 1997B . The DSB fragments andcrossover bands were quantitated as described in WOLTERINGet al. 2000 . Electron microscopic analysis of spread chromosomeswas performed as described in WOLTERING et al. 2000 .

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

mms4 diploids arrest in prophase:
To determine whether the sporulation defect of mms4 is due todefects in meiosis as opposed to defects in the ability to formspores, meiotic time-course experiments were performed in theisogenic SK1 diploids NH144 (MMS4/MMS4) and NH274F (mms4/mms4).Meiotic divisions were monitored by counting the number of nucleiin each cell. Binucleate cells have completed MI while tetranucleatecells have completed MII. The time course was performed at 33°,a temperature at which the mms4 sporulation phenotype is mostsevere in the SK1 strain background (MMS4, 75.6% ± 6.0vs. 1.3 ± 3.3 for mms4, n = 6). The wild-type cells beganto enter meiosis I about 4 hr after shift to sporulation mediumand $~$ 70% of the cells had completed at least one division by10 hr. In contrast, <10% of the mms4 cells progressed throughMI at 10 hr (Fig 1A). Scoring the number of nuclei in the mms4cells after 10–12 hr is technically difficult becausethe pattern of DAPI staining becomes highly fragmented. MULLENet al. 2001 have shown that mms4 diploids arrest at the mononucleatestage in the W303 background.

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Figure 1. Time-course analyses of various SK1 strains. SK1 diploids were transferred to sporulation medium and shifted to 33°. To monitor meiotic progression (A–C), cells were fixed with formaldehyde, 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 timepoint. To monitor viability (D), appropriate dilutions of each diploid were plated on YPAD. Each timepoint is normalized to the viability at the 0 timepoint for that strain. (A) MMS4 (NH144), mms4 ${Delta}$ (NH274F), rec104 (DW11), and rec104 mms4 ${Delta}$ (NH349); (B) MMS4 (NH144), mms4 ${Delta}$ (NH274F), pch2 (NH341), and pch2 mms-4 ${Delta}$ (NH340); (C) MMS4 (NH144), mms4 ${Delta}$ (NH274F), mek1 mms4 ${Delta}$ (NH280Fade2:: pRS402), and red1 mms4 ${Delta}$ (NH287); (D) MMS4 (NH-144) and mms4 ${Delta}$ (NH274F).

The mms4 prophase arrest is dependent upon recombination:
The mms4 prophase arrest may result from defects in either DNAreplication or recombination. If the arrest is dependent uponrecombination, then preventing recombination should suppressthe meiotic progression defect. REC104 is a meiosis-specificgene required for meiotic recombination (GALBRAITH and MALONE1992 ). REC104 was deleted from the mms4 SK1 diploid and theresulting strain (NH349) was assayed for meiotic progressionat 33°. Both the rec104 and rec104 mms4 diploids enteredmeiosis I between 2 and 4 hr after transfer to sporulation mediumand produced equivalent numbers of tetranucleate cells (Fig 1A).The diploids containing rec104 progressed through the firstmeiotic division earlier than the wild-type strain, consistentwith previous results (GALBRAITH et al. 1997 ).

The mms4 prophase arrest requires components of the meiotic recombination checkpoint:
The dependence of the mms4 prophase arrest on recombinationsuggests that aberrant or unresolved recombination intermediatesare being formed in the absence of MMS4, thereby triggeringthe meiotic recombination checkpoint (ROEDER and BAILIS 2000). To test this hypothesis, mms4 was combined with various checkpointmutants for epistasis analysis in the SK1 background. PCH2 isa meiosis-specific gene required for the prophase arrest/delayexhibited by mutants such as zip1 and dmc1 (SAN-SEGUNDO andROEDER 1999 ). At 33°, deletion of PCH2 in our SK1 strainsresulted in a delay in the onset of meiosis of $~$ 2 hr. Althoughby 12 hr only 58% of the pch2 cells had completed at least onedivision (compared to 90% for NH144; Fig 1B), by 26 hr, 61%of the pch2 cells had formed mature asci, nearly equivalentto the 70% observed for the wild type. The pch2 mutation partiallyrescued the meiotic progression defect of mms4 (Fig 1B). By12 hr, only 5% of the mms4 cells had progressed beyond MI, comparedto 47% for the mms4 pch2 diploid. The mms4 sporulation defectwas only weakly suppressed by pch2, however (0% for mms4 vs.4% for mms4 pch2).

MEK1 is believed to activate the meiotic recombination checkpointby phosphorylating Red1p in response to the formation of meioticDSBs (BAILIS and ROEDER 2000 ). Deletion of MEK1 or RED1 hasbeen shown to suppress the prophase arrest or delay conferredby a variety of mutants, including dmc1, zip1, and sae2/com1(XU et al. 1997 ; WOLTERING et al. 2000 ). Meiotic time-courseexperiments in the SK1 background at 33° demonstrated thatboth red1 and mek1 completely suppress the meiotic progressiondefect of mms4 (Fig 1C).

mms4 SK1 diploids exhibit reduced viability when returned to growth:
DSBs induced by meiotic recombination can be repaired by returningcells to growth in vegetative medium. Mutants unable to repairmeiotic DSBs exhibit a decrease in cell viability when returnedto growth (ARBEL et al. 1999 ). The viability of mms4 in returnto growth experiments is greatly reduced as a function of timein sporulation medium (Fig 1D). In contrast to the wild-typestrain where viability was relatively unaffected, only 3% ofthe mms4 cells were viable after 26 hr at 33°.

mms4 diploids have decreased levels of spore viability in the SK1 background:
The severity of the mms4 meiotic progression defect is dependentupon temperature in the SK1 background. Although very few matureasci are observed if the cells are sporulated at 33°, highernumbers of mature asci can be obtained by sporulating the mms4diploid at 30° (MMS4, 82.2% ± 7.8 vs. mms4, 11.5%± 6.6, n = 10). Dissection of mature asci from cellssporulated at 30° demonstrated a decrease in spore viabilityin the absence of MMS4. While 96.6% (644 asci) of the sporesfrom NH144 were viable, only 50.9% (892 asci) of the sporesfrom the mms4 diploid formed colonies.

The decrease in spore viability is not due simply to chromosome nondisjunction:
A number of mutants that reduce spore viability two- to threefold,similar to mms4 (e.g., zip1, zip2, mer3, msh4, msh5), have previouslybeen identified (ROSS-MACDONALD and ROEDER 1994 ; SYM and ROEDER1994 ; HOLLINGSWORTH et al. 1995 ; CHUA and ROEDER 1998 ; NAKAGAWA and OGAWA 1999 ). The spore inviability of these mutantscan be accounted for by MI chromosome nondisjunction. To seewhether mms4 is causing meiotic chromosome missegregation, thedistribution of viable spores in tetrads was examined.

A hallmark of MI nondisjunction is a decrease in the numberof 4⁺:0^- viable-spore tetrads with a corresponding increasein the 2⁺:2^- and 0⁺:4^- classes (for example, see HOLLINGSWORTHet al. 1995 ). This pattern was not observed for mms4 (Fig 2).Although the number of 4⁺:0^- tetrads is greatly reduced, allof the other tetrad classes were increased, including 3⁺:1^-and 1⁺:3^- asci. The mms4 pattern is similar, but not identical,to one predicted by random spore death ( ${chi}$ ², P < 0.001; Fig 2).Another indicator of MI nondisjunction is a bias towardsister spores in two-viable-spore tetrads. Sister spores canbe distinguished from nonsister spores using tightly centromere-linkedmarkers such as ARG4. Out of 249 two-viable-spore tetrads producedby the mms4 diploid, only 39% were either +:+ or -:- at theARG4 locus, indicating a lack of bias for sister spores. Anothertype of chromosome missegregation that can occur is precocioussister chromatid separation. These events result in three-viable-sporetetrads in which one spore is disomic. Disomy for chromosomeIII can be detected because the cells are nonmaters. The mms4diploid produced 211 three-viable-spore tetrads. Of these, onlyone contained two mating and one nonmating spore. Precocioussister chromatid separation is therefore not occurring at highfrequency in the mms4 diploid.

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Figure 2. Distribution of viable spores in tetrads of MMS4/MMS4 and mms4 ${Delta}$ /mms4 ${Delta}$ diploids. NH144 and NH274 were sporulated on plates at 30° for 3 days and the resulting tetrads were dissected. A total of 644 and 892 asci were analyzed for NH144 and NH274, respectively. The NH144 data include 337 tetrads originally published in HOLLINGSWORTH et al. 1995

. Shaded bars indicate the percentage of each tetrad type expected, assuming 50.9% viability and random lethality.

Recombination is initiated at wild-type levels in the mms4 SK1 diploid:
Interhomolog recombination was assayed genetically using dissectedtetrads from the SK1 diploids, NH144 (MMS4) and NH274 (mms4).In four-viable-spore tetrads, the mms4 diploid exhibited higherlevels of gene conversion at all three loci analyzed, althoughonly the value at HIS4 was statistically significant (Table 2A).Recently it has been discovered that recombination frequenciescan be altered depending upon whether a strain is auxotrophicfor various nutrients (ABDULLAH and BORTS 2001 ). Although inthis experiment, the mms4 strain is Ura⁺ while the wild-typestrain is Ura^-, the observed differences in gene conversionare likely to be real. Identical results were obtained whenMUS81 (the gene encoding the protein partner of MMS4; see below)was deleted in the isogenic strain background using the kanamycin-resistancegene instead of URA3. In this experiment, both strains wereUra^- (B. LARKIN and N. M. HOLLINGSWORTH, unpublished data).

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Table 2. Recombination in mms4 diploids

In contrast to the increase in gene conversion, a 1.3-fold reductionin crossing over in the MAT-HIS4 interval was observed in themms4 diploid when four-viable-spore asci were analyzed (Table 2A).Crossing over was also examined in three-viable-spore tetradsby inferring the genotype of the dead spores on the basis ofthe assumption that HIS4 and MAT segregated 2⁺:2^- . One explanationfor the mms4 distribution of viable spores in tetrads is thatcrossovers are initiated normally, but "half-crossover" eventsresult in the repair of only one chromatid while the unrepairedbroken chromosome creates a dead spore (CHAMBERS et al. 1996). The dead spore in a three-viable-spore tetrad would thereforecontain one broken recombinant chromosome while asci with two,three, or four dead spores would contain two, three, or fourdifferent broken chromosomes that segregated to different spores.This model predicts that crossover recombinants should be enrichedin three-viable-spore asci. Comparison of the MAT-HIS4 map distancesin the three- and four-viable-spore tetrads from the MMS4 diploidrevealed no difference (Table 2A). In contrast, the three-viable-sporetetrads from the mms4 diploid exhibited 37.6 cM between MATand HIS4 compared to just 30.6 cM for the four-viable-sporetetrads from the same strain (Table 2A). These data furthersupport the idea that a wild-type number of recombination eventsare initiated in the absence of MMS4 but that processing ofthe recombinants is faulty. For those cells that are able toescape the checkpoint, reduced spore viability may occur asa result of failure to repair one side of the DSB break (seeDISCUSSION).

The tetrad dissection data may be biased because only a smallfraction of the mms4 cells are able to form asci. To eliminatethis bias, heteroallelic recombination was monitored in thewild-type and mms4 diploids using return-to-growth experiments.The same leu2 heteroalleles assayed by tetrad dissection wereanalyzed. The mms4 mutant reproducibly exhibits a slight delayin the onset of gene conversion but the kinetics and level ofrecombinants mirrors the MMS4 diploid until 8 hr after the inductionof meiosis (Fig 3). After 8 hr, the level of recombinants inthe wild type remains constant while the mms4 level drops (Fig 3).This decrease coincides with the onset of the first meioticdivision in the mms4 strain (data not shown). We conclude thata wild-type number of recombination events are initiated inmms4 cells, but that in many cells the chromosomes are not properlyrepaired, thereby resulting in cell death.

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Figure 3. Heteroallelic recombination measured by return-to-growth in MMS4 and mms4 SK1 diploids. NH144 (MMS4/MMS4) and NH274F (mms4 ${Delta}$ /mms4 ${Delta}$ ) were transferred to sporulation medium at 33° and appropriate dilutions were plated onto SD-leu and YPAD at different timepoints. The averages of two or three single colonies are plotted for NH144 and NH274F, respectively.

Double-strand breaks are made and processed in mms4 mutants:
Meiotic recombination is initiated by the introduction of DSBs,which are then resected to create 3' single-stranded tails.DSB formation was assayed in isogenic MMS4 (NKY1551) and mms4(NH301) SK1 diploids using the well-characterized HIS4/LEU2recombination hotspot (for example, see MCKEE and KLECKNER1997A ). DNA was isolated from the wild-type and mms4 diploidsat different times after transfer to sporulation medium. Thetwo predicted DSB fragments of 3.9 and 6.8 kb were observedin the wild-type and mms4 diploids. The bands were diffuse,indicating that the ends of the fragments are being processedto create single-stranded tails of heterogeneous lengths (Fig 4A).The time at which the maximum number of DSBs was observedwas delayed $~$ 2 hr in the mms4 mutant. By 10 hr, the majorityof DSB fragments had disappeared in wild type, while for mms4 ${Delta}$ the DSB fragments did not disappear until 12 hr (Fig 4B).

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Figure 4. The effects of mms4 ${Delta}$ on meiosis-specific double-strand breaks at the HIS4/LEU2 hotspot. (A) DNA was isolated from NKY1551 (MMS4/MMS4) or NH301 (mms4 ${Delta}$ /mms4 ${Delta}$ ) taken at different times after transfer to sporulation medium at 33°. DNA was digested with PstI and fractionated on a 0.6% agarose gel. The gel was probed with a 1.8-kb PstI/BglII fragment from pNKY291, which detects two meiosis-specific DSB fragments of 3.9 kb (DSB I) and 6.2 kb (DSB II). (B) Quantitation of the amount of the 3.9-kb DSB fragment as a function of time.

DSB formation was also examined at the naturally occurring YCR048whotspot on chromosome III in the SK1 strains NH144 (MMS4/MMS4)and NH274F (mms4 ${Delta}$ /mms4 ${Delta}$ ) sporulated at 33° (WU and LICHTEN1994 ). At this locus, the kinetics of DSB formation and disappearancewere equivalent for mms4 ${Delta}$ and wild type. However, a twofold increasein the number of DSBs was observed in mms4 compared to wildtype (data not shown). DSBs were also analyzed in the isogenicdiploids, NH280F::pRS402 (mek1 mms4 ${Delta}$ ) and NH287 (red1 mms4 ${Delta}$ ).In both strains DSBs were observed (data not shown), indicatingthat red1 and mek1 do not suppress the meiotic recombinationcheckpoint triggered by mms4 ${Delta}$ simply by preventing DSBs, consistentwith previous observations in the literature (XU et al. 1997).

Crossovers are reduced approximately twofold in mms4 SKI diploids:
Because the genetic data measuring crossovers could be biasedby the small number of mms4 cells able to form asci, a physicalanalysis was used as an alternative way of monitoring crossingover. Crossing over was assayed at the HIS4/LEU2 hotspot thatwas used for analyzing DSB formation (STORLAZZI et al. 1995). DNA was isolated from NKY1551 (MMS4/MMS4) and NH301 (mms4 ${Delta}$ /mms4 ${Delta}$ )at 2-hr intervals after the induction of meiosis. DNA was digestedwith XhoI, which produces recombinant bands of 18.5 and 13.8kb (R1 and R2, respectively, in Fig 5; STORLAZZI et al. 1995). Crossovers were detected in both strains starting at 6 hr.The wild-type cells entered MI beginning at 6 hr in this timecourse (data not shown). Quantitation of the two mms4 recombinantbands, R1 and R2, at the 10-hr time point revealed that theycontained 4.9 and 2.1% of the total DNA, respectively (Fig 5B).This represents a twofold reduction in crossing over comparedto wild type.

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Figure 5. The effect of mms4 ${Delta}$ on meiotic crossing over at the HIS4/LEU2 hotspot. (A) DNA was isolated from NKY1551 (MMS4/MMS4) and NH301 (mms4 ${Delta}$ /mms4 ${Delta}$ ) at different times after transfer to sporulation medium at 33°. DNA was digested with XhoI and fractionated on a 0.6% gel. The gel was probed with pNKY155, which detects two parental bands (P1, 19.9 kb; P2, 12.4 kb) and two recombinant bands (R1, 18.5 kb; R2, 13.8 kb). (B) Quantitation as a function of time of R1 or R2 as a percentage of the total DNA.

mms4 SK1 diploids exhibit aberrant synapsis and a delay in pachytene:
To determine the effects of deletion of MMS4 on chromosome synapsis,nuclei from NH144 (MMS4/MMS4) and NH274F (mms4 ${Delta}$ mms4 ${Delta}$ ) were spreadfrom cells taken at different times after transfer to sporulationmedium at 33° and the chromosomes were examined by electronmicroscopy. The extent of synapsis observed between mms4 nucleiwas highly variable, ranging from short fragments of SC to reasonablycomplete SC. Even those mms4 nuclei classified as having completeSCs were not equivalent to wild type, however. The mms4 SCstend to be clumped and the spreads contain polycomplexes, asign that synapsis is not proceeding normally (Fig 6, a–c).Specifically, many SCs appeared locally split with axial elementsoften thickened at these sites. Also, entangled SCs were seen,which may be due to failure to resolve interlocking or to involvementof split axes in nonhomologous associations. The mms4 cellsexhibited a long delay in pachytene. The peak number of cellscontaining complete SCs occurred at 4 hr in wild type with only5% of the cells containing complete SCs by 5.5 hr. In contrast,cells with complete SCs in the mms4 diploid peaked at 5.5 hrand SCs persisted until 10 hr (Fig 6E).

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Figure 6. Time course of synapsis in SK1 wild-type and mms4 diploids. NH144 (MMS4/MMS4; d) and NH274F (mms4 ${Delta}$ /mms4 ${Delta}$ ; a–c) were sporulated at 33° for 5.5 hr and nuclei were spread and examined by electron microscopy. Arrowheads indicate polycomplexes and arrows indicate aberrant SCs. (e) Quantitation of cells exhibiting complete SCs. NH144 and NH274F were sporulated at 33° and cells were taken at various timepoints and spread for electron microscopy. The number of nuclei containing complete SCs was scored for at least 100 cells for each strain.

The mms4 sporulation and spore viability defects are not rescued by spo13:
The spo13 mutation results in a single meiotic division, therebyproducing two diploid spores (KLAPHOLZ and ESPOSITO 1980 ).Because there is only one division, the requirement for crossingover to promote segregation at MI is removed. A number of meioticmutants that decrease spore viability in wild-type meioses generateviable spores in the presence of spo13 (PETES et al. 1991 ).Mutants that are rescued by spo13 tend to be defective in theinitiation of recombination (e.g., spo11, mei4, rad50) or insynapsis (hop1, red1). In contrast, mutants that are blockedafter the initiation of recombination and that trigger the meioticrecombination checkpoint (e.g., rad50S) are not rescued by spo13(ALANI et al. 1990 ).The mms4 ${Delta}$ spo13 diploid (NH299) was createdin a slow-sporulating strain background, and sporulation andspore viability were compared with the isogenic spo13 strain,NH298. A 15-fold decrease in the frequency of mature dyads wasobserved in NH299 compared to NH298. Spore viability was reduced2.8-fold by mms4 (Table 3).

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Table 3. Sporulation and spore viabilities in non-SK1 spo13 diploids

To ensure that mms4 defects in sporulation and spore viabilitywere due to recombination in this strain background, a mutationin SPO11 was introduced. The spo11 spo13 diploid produced wild-typelevels of dyads and 92.9% of the spores were viable (Table 3).The spo11 mms4 spo13 strain was phenotypically identical tothe spo11 spo13 strain (Table 3), providing a second demonstrationthat preventing recombination suppresses the mms4 meiotic mutantphenotypes.

mms4 has variable effects on interhomolog recombination in non-SK1 strains:
Crossing over was examined in four intervals in non-SK1 spo13diploids. Because spo13 does not rescue the mms4 spore inviability,these data represent a selected set of dyads, those capableof forming mature asci containing two viable spores. Variableeffects of mms4 on crossing over were seen. In the MAT-CENIIIand ARG4-THR1 intervals on chromosomes III and VIII, respectively,crossing over was reduced 2.5-fold. In contrast, no differencewas seen in the CENIII-LEU2 interval, while the map distancebetween LEU2 and HIS4 was increased 1.8-fold in the mms4 diploid(Table 2B).

red1 and mek1 differentially affect the ability to rescue the sporulation and spore viability defects of mms4 spo13 diploids in slow-sporulating strains:
Although abrogation of the meiotic recombination checkpointallows mms4 cells to proceed through the meiotic divisions,the question remains as to whether mms4 recombination intermediatesare repaired before the chromosomes segregate or not. Analysisof the spore viability of the SK1 pch2 mms4 asci indicates thatthe chromosomes have not been repaired when the meiotic recombinationcheckpoint is eliminated by mutation of PCH2. Dissection ofasci sporulated at 30° showed that while the pch2 strain,NH341, produced 97.4% viable spores (48 asci), the pch2 mms4diploid (NH340) produced the same number of viable spores (30.2%,122 asci) as mms4 alone (33.3%, 48 asci for NH274F). Therefore,although the mms4 cell cycle progression defect is amelioratedby pch2, the DNA damage occurring due to a lack of mms4 is stillpresent.

Because mek1 and red1 cause a more severe spore viability phenotypethan mms4 in a two-division meiosis, one cannot assess whetherthe DNA damage arising from a lack of MMS4 is present in thespores from strains where MEK1 or RED1 has been deleted. Sincered1 and mek1 give high spore viability in the spo13 background,we assayed sporulation and spore viability in red1 mms4 spo13and mek1 mms4 spo13 strains. In our slow-sporulating spo13 strainbackground, mek1 mutants sporulated as well as spo13 alone andproduced 90.4% viable spores (Table 3). Deletion of MEK1 inthe mms4 spo13 strain created a strain that resembled mms4 spo13rather than mek1 spo13, producing few mature asci and only 18.9%viable spores (Table 3). A different result was obtained inepistasis experiments using red1. Like mek1, deletion of RED1has no effect on sporulation and produces high levels of viablespores in the presence of spo13 (Table 3). A partial rescueof the mms4 spo13 sporulation and spore viability phenotypeswas observed when RED1 was absent. Sporulation and spore viabilityin the red1 mms4 spo13 diploid were increased 7.6- and 2.8-fold,respectively, compared to mms4 spo13 (Table 3). The absenceof MMS4 is therefore more deleterious if recombination is occurringin the presence of RED1.

red1 and mek1 similarly rescue the sporulation defects of dmc1 spo13 diploids:
Deletion of DMC1 in spo13 SK1 strains causes sporulation andspore viability defects that can be suppressed by mutation ofRED1 (BISHOP et al. 1999 ). Similar results were obtained fordmc1 in our spo13 non-SK1 strain background. While dmc1 aloneproduced only 6.4% dyads, the red1 dmc1 strain sporulated atlevels equivalent to wild type (Table 3). The dmc1 spo13 diploidproduced 72.1% viable spores, consistent with previous resultsfor dmc1 in a slow-sporulating strain background (ROCKMILL andROEDER 1994 ). The dmc1 spo13 spore viability was also improvedby addition of red1 (Table 3; ${chi}$ ², P < 0.001). The effectsof mek1 on sporulation and spore viability of dmc1 spo13 areindistinguishable from those of red1 (Table 3). The fact thatonly red1 can suppress mms4 while both red1 and mek1 can suppressdmc1 suggests that the mechanism of red1 suppression differsfor the two mutants.

mms4 and msh5 are in different epistasis groups with regard to spore viability:
Deletion of MSH5 in SK1 results in 37.5% viable spores (HOLLINGSWORTHet al. 1995 ). This frequency of viable spores is similar tothat observed in mms4 and could arise by three possible mechanisms:

msh5and mms4 act on the same pathway for spore viability. Thismodelpredicts that the msh5 mms4 diploid will produce the samefrequencyof viable spores as msh5 or mms4 alone.
msh5 and mms4 acton parallel pathways to promote crossing over.In this case,viable spores should be eliminated in the doublemutant. Thesetwo possibilities seem unlikely given that sporeinviabilityof msh5 can be attributed to meiosis I nondisjunction,whichdoes not appear to be increased by mms4.
The msh5 and mms4effects on spore viability are independentof each other.

A msh5 mms4 SK1 diploid (NH370) was created and sporulated and365 tetrads were dissected. The spore viability of mms4 msh5is 21.8%, similar to the 19.1% predicted if the two genes actindependently. The percentage of four-viable-spore tetrads observedfor msh5 is 19.5 (HOLLINGSWORTH et al. 1995 ) compared to 14.0for mms4. The mms4 msh5 diploid produced 3.3% tetrads in whichall four spores were viable, comparable to the 2.7% predictedif the genes act independently. MSH5 and MMS4 therefore playdifferent roles during meiosis in the production of viable spores.

MMS4 is in the same epistasis group as MUS81 for spore viability:
Recently mms4 was discovered to function in the same epistasisgroup as mus81 for the vegetative phenotypes of UV and MMS sensitivity(MULLEN et al. 2001 ). Like mms4, mus81 diploids exhibit reducedsporulation and produce only 40.0% viable spores in the SK1strain background (INTERTHAL and HEYER 2000 ). To determinewhether mus81 and mms4 function in the same epistasis groupfor spore viability, mus81 was deleted in our SK1 strains. Deletionof MUS81 produced 40.5% viable spores (1357 asci). Dissectionof the mus81 mms4 diploid, NH372, produced 45.4% viable spores(66 asci). This value is similar to both single mutants, indicatingthat mms4 and mus81 act in the same pathway during meiosis toproduce viable spores.

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

MMS4 was originally identified as a mutant specifically sensitiveto MMS in vegetative cells (PRAKASH and PRAKASH 1977 ). XIAOet al. 1998 later showed that the mms4 sensitivity extendsto a variety of alkylating agents and also that mms4 has a weakspontaneous mutator phenotype. Recently MMS4 was identifiedas a mutant that causes a synthetic lethal phenotype in combinationwith a deletion of SGS1, the RecQ helicase ortholog in S. cerevisiaerequired for genomic stability (MULLEN et al. 2001 ). All ofthese results indicate that MMS4 has a function in DNA metabolismin vegetative cells. The work presented here demonstrates animportant role for MMS4 in meiotic DNA metabolism as well.

A number of experiments indicate that MMS4 acts sometime downstreamof the initiation of recombination. First, wild-type levelsof meiosis-specific DSBs are observed in mms4 diploids. Second,the mms4 sporulation and spore inviability phenotypes are notrescued by the single division meiosis conferred by spo13. Third,in dissected tetrads and return-to-growth experiments, the levelsof interhomolog gene conversion are equivalent or elevated relativeto wild type, indicating that wild-type levels of heteroduplexDNA have been formed. Finally, consistent with a post-initiationdefect, the mms4 sporulation defect is due to activation ofthe meiotic recombination checkpoint. Preventing the formationof DSBs is sufficient to suppress the meiotic progression andsporulation defects of mms4. Furthermore, mutation of severalmeiosis-specific components of the meiotic recombination checkpointallows mms4 cells to progress through the meiotic divisions.The extent of the mms4 prophase arrest is dependent upon temperaturein the SK1 background, a phenomenon previously observed forother mutants that trigger this checkpoint (NAKAGAWA and OGAWA1999 ; V. BOERNER and N. KLECKNER, personal communication).

The meiotic recombination checkpoint is activated by mutationsdefective at a variety of different stages of recombination.The earliest block occurs in rad50S, mre11S, and sae2/com1 mutants,which produce DSBs that fail to get processed (XU et al. 1997; USUI et al. 2001 ). As a result, DSB fragments appear asdiscrete bands and accumulate with time. The DSB fragments inmms4 are heterogeneous, an indication that they are gettingprocessed and do not accumulate. MMS4 therefore functions downstreamof DSB resection.

A second stage of recombination that triggers the checkpointis revealed by dmc1 mutants. DMC1 encodes a meiosis-specificortholog of the bacterial RecA strand transfer protein. In dmc1mutants, DSBs are hyperresected and persist because they areunable to efficiently invade the homologous chromosome withoutDMC1 (BISHOP et al. 1992 ; HUNTER and KLECKNER 2001 ). Thesporulation and spore inviability of dmc1 can be suppressedif a second RecA ortholog, Rad51p, is activated by overexpressionof RAD54 (BISHOP et al. 1999 ). Overexpression of RAD54 hasno effect on the mms4 sporulation defect (T. DE LOS SANTOS andN. M. HOLLINGSWORTH, unpublished data), suggesting that MMS4is acting after strand invasion. An alternative route for therepair of dmc1 DSBs utilizes sister chromatid recombination.In a typical diploid meiosis, constraints that promote recombinationbetween homologs as opposed to sister chromatids are imposed.When these constraints are released, either by return to growthor by mutation of the axial element component, RED1, the DSBspresent in dmc1 are repaired (SCHWACHA and KLECKNER 1997 ; ARBEL et al. 1999 ; BISHOP et al. 1999 ). An increase in theratio of intersister joint molecules compared to interhomologjoint molecules has been directly observed in red1 mutants (SCHWACHAand KLECKNER 1997 ). We assume that the suppression of the dmc1arrest by mek1 (XU et al. 1997 ; this work) is due to a similarchange in chromosome bias because mek1 and red1 exhibit similarphenotypes with respect to reduced levels of sister chromatidcohesion as well as a change in partner choice toward sisterchromatids (BAILIS and ROEDER 1998 ; THOMPSON and STAHL 1999).

MMS4 differs from DMC1 in that it appears to function downstreamof the decision for partner choice (and therefore strand invasion).In haploid or diploid dmc1 strains induced in meiosis and thenreturned to growth, viability remains high throughout the timecourse. This result is due to repair of the dmc1 DSBs usingRAD54-dependent recombination between sister chromatids (ARBELet al. 1999 ). In rad54 strains, there is no intersister recombinationand so rad54 haploids lose viability in meiotic time coursesbut rad54 diploids do not (repair can occur using the homologouschromosome). A dmc1 rad54 diploid shows low viability becauseneither homologs nor sister chromatids can be used to repairthe DSBs (ARBEL et al. 1999 ). The viability of mms4 diploidsis similar to that observed for the dmc1 rad54 diploid. Thisfinding implies either that MMS4 is required for repair of DSBsusing both sisters and homologs or, alternatively, that theblock to recombination in mms4 occurs after the decision ofwhich chromatid to use in recombination has been made.

Unlike dmc1 spo13, the sporulation and spore viability defectsof mms4 spo13 can be partially rescued only by red1, and notby mek1. This result further argues against the idea that sisterchromatid recombination is repairing the mms4 DSBs since mek1and red1 mutants appear to similarly relieve the constraintsagainst sister chromatid exchange. A major phenotypic differencebetween red1 and mek1 in slow-sporulating strain backgroundsis that red1 mutants make no axial elements or SC while substantialamounts of SC are present in the absence of MEK1 (ROCKMILL andROEDER 1990 , ROCKMILL and ROEDER 1991 ). In addition, mek1mutants generate more viable spores, presumably because crossoversare being generated in the context of the SC and are thereforemore effective for disjunction. In contrast, in the SK1 backgroundwhere mek1 produces <1% viable spores, the synapsis defectof mek1 is much more severe (J. LOIDL, unpublished results).When our slow-sporulating spo13 strains were converted to Spo13⁺,mek1 produced 23% viable spores compared to just 3% for red1(data not shown). These results suggest that SC formation isoccurring in our slow-sporulating mek1 strains. It is possible,therefore, that recombination occurring in the presence of theSC creates recombination intermediates that require MMS4 forcompletion while those occurring in the absence of the SC canutilize alternative pathways such as synthesis-dependent strandannealing (PAQUES and HABER 1999 ).

An alternative explanation for the difference between the abilityof mek1 and red1 to rescue the mms4 spore inviability in thespo13 background would be if MMS4 required MEK1 for activation,perhaps by a phosphorylation event. This idea seems unlikelygiven that the mek1 spo13 diploid produces highly viable spores.If Mek1p was necessary to phosphorylate Mms4, then the mek1mutant should contain unprocessed recombination intermediatesand therefore broken chromosomes, which is clearly not the case.

What, then, is the function of MMS4 during meiotic recombination?An important clue lies in the biochemical activity of the protein,which has recently been elucidated by Brill and colleagues.Previously MULLEN et al. 2001 showed that Mms4p physicallyinteracts with a second protein, Mus81p. Genetic evidence supportsthe notion that MMS4 and MUS81 function together because mus81mms4 double mutants are phenotypically identical to either singlemutant (MULLEN et al. 2001 ; this work). Mus81p shares homologywith Rad1p, a protein involved in nucleotide excision repair(INTERTHAL and HEYER 2000 ; MULLEN et al. 2001 ). Like Mus81,Rad1 acts in a complex with a second protein, Rad10. The Rad1/10complex is a duplex 3' single-stranded junction-specific endonuclease(BARDWELL et al. 1994 ). A preferred substrate for Rad1/10 isa simple Y form. In contrast, a preferred substrate for Mms4/Mus81is a branched structure in which only the 3' end is single stranded(Fig 7A; KALIRAMAN et al. 2001 ).

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Figure 7. Model for MMS4 function in meiotic recombination. (A) Structure of a preferred substrate for Mms4/Mus81 in vitro (KALIRAMAN et al. 2001

). (B) Schematic diagram of the strand-displacement and annealing model adapted from ALLERS and LICHTEN (2001). Asterisks indicate the junctions at which Mms4/Mus81 is proposed to cleave. Newly synthesized DNA is indicated by a dotted line. Arrowheads indicate 3' ends.

If one assumes that the preferred substrate of Mms4/Mus81 invitro is similar to the structure cleaved in vivo, the questionremains as to how this structure could be generated during meioticrecombination. One possibility would be if there was heterologyon one of the 3' ends of the break so that it was unable toanneal properly, thereby creating a 3' flap (KALIRAMAN et al.2001 ). This model is inconsistent with the finding that mms4still exhibits a sporulation-defective phenotype in HO-deriveddiploids where the number of mismatches is very low (N. M. HOLLINGSWORTH,unpublished data). We propose instead that MMS4 is requiredfor an alternative pathway of meiotic DSB repair recently postulatedby ALLERS and LICHTEN 2001 . This pathway of "strand displacementand annealing" initiates with a SEI (Fig 7B). DNA synthesisextends the length of the invading strand, which then dissociatesfrom the nonsister chromatid and anneals to the resected 3'end on the other side of the break. If extension of the invadingstrand creates a single-stranded tail that is longer than theresected end on the other side of the break, a 3' "flap" willresult after the two strands anneal (Fig 7B). The resultingstructure looks identical to the preferred substrate for Mms4/Mus81in vitro. We propose that Mms4/Mus81 is required to cleave thisflap so that one side of the break can be repaired by ligation.Failure to remove this flap would result in one broken chromatid,while resolution of the double Holliday junctions on the otherside of the break would create an intact chromatid.

ALLERS and LICHTEN 2001 proposed the strand displacement andannealing model to account for a class of joint molecules, whichthey observed during meiotic recombination, that cannot be explainedby the canonical DSB repair model. This class of joint molecules(JM2) contains double Holliday junctions downstream of heteroduplexDNA instead of flanking it. A testable prediction of our modelis that the number of JM2 molecules should be reduced in anmms4 mutant.

In addition to the biochemistry, genetic and cytological datasupport our model for MMS4 function. We propose that the majorityof cells are arrested in prophase because unprocessed 3' flapstrigger the meiotic recombination checkpoint. For those cellsthat escape the checkpoint and form asci, spore viability isdecreased due to the formation of half crossovers. Tetrads containingmore than one dead spore could occur if more than one pair ofhomologs sustain a half crossover and the broken chromatidssegregate into different spores. As predicted by the half-crossovermodel, recombinants are enriched in mms4 asci with only threeviable spores (CHAMBERS et al. 1996 ). A similar result is seenin the three-viable-spore tetrads from mus81 diploids, arguingagainst this observation being a statistical fluke (B. LARKINand N. M. HOLLINGSWORTH, unpublished data). Also consistentwith the half-crossover model is the fact that crossovers arereduced twofold by physical analyses. A similar reasoning hasbeen used to explain the presence of recombinants in rad52 diploids(HABER and HEARN 1985 ; BORTS et al. 1986 ) where it is known,in meiosis, that rad52 mutants are unable to progress from SEIinvasion intermediates to double HJs (N. HUNTER and N. KLECKNER,personal communication). The mms4 interval-specific effectson crossing over could be explained if the ratio of crossoversarising from canonical DSB repair vs. the strand displacementmechanism varies with different regions of the chromosomes.Cytologically, the synapsis defect of mms4 appears as thoughit is occurring in late zygotene/early pachytene, the time atwhich SEI intermediates are being processed (HUNTER and KLECKNER2001 ).

Another appealing aspect of our model is that it can explainthe red1 suppression of the mms4 sporulation/spore viabilityphenotypes. In the absence of RED1, the ratio of resection onone side of the break to the new synthesis occurring on theinvading strand at the other side may be altered such that theresected end is always longer than the end of the invading strand.Alternatively, the strand displacement pathway of recombinationmay not occur in the absence of synapsis, in which case therewould be no requirement for MMS4. Our model is also compatiblewith the observation that MMS4 and MSH5 act independently ofeach other since the spore inviability of mms4 comes from brokenchromosomes resulting from failure to repair one side of theDSB, whereas the msh5 spore inviability is due to aneuploidyresulting from MI nondisjunction.

ACKNOWLEDGMENTS

We thank JoAnne Engebrecht, Neil Hunter, and Aaron Neiman forcomments on the manuscript. Rhona Borts, Steve Brill, JoAnneEngebrecht, Jim Haber, Neil Hunter, Michael Lichten, Aaron Neiman,and Frank Stahl provided helpful discussions. Steve Brill, JimHaber, and Neil Hunter generously communicated results priorto publication. In particular we acknowledge Rhona Borts forthe half-crossover idea and Neil Hunter for the suggestion thatoverreplication is responsible for creating the 3' tail cleavedby Mms4p. Doug Bishop, Mike Dresser, JoAnne Engebrecht, BobMalone, Shirleen Roeder, Rolf Sternglanz, and Wei Xiao providedstrains and/or plasmids. We thank Lihong Wan for her help withtetrad dissection and Bridget Baumgartner, Cindy Lee, Lisa Ponte,and Dana Woltering for excellent technical support. This workwas supported in part by a grant from the National Institutesof Health (GM-50717) and by Research grant no. 1-FY00-193 fromthe March of Dimes Birth Defects Foundation to N.M. H.J.L. wassupported by the Austrian Science Fund (grant S 8202).

Note added in proof: BODDY et al. (M. N. BODDY, P.-H. L. GAILLARD,W. H. MCDONALD, P. SHANAHAN, J. R. YATES 3rd and P. RUSSELL,2001, Mus81-Eme1 are essential components of a Holliday junctionresolvase. Cell 107: 537–548) have recently describedthe biochemical activities of the Mus81/Eme1 complex from Schizosaccharomycespombe. Eme1 is thought to be a homolog of Mms4 (BODDY et al.2001; S. BRILL, personal communication). The authors suggestthat Mus81/Eme1 acts as a Holliday junction resolvase in therepair of stalled replication forks and during meiotic recombination.A similar model for human Mus81 activity has also been proposed(CHEN, X-B., R. MELCHIONNA, C.-M. DENIS, P.-H. L. GAILLARD,A. BLASINA, I. VAN DE WEYER, M. N. BODDY, P. RUSSELL, J. VIALARDand C. H. MCGOWAN, 2001, Human Mus81-associated endonucleasecleaves Holliday junctions in vitro. Mol. Cell 8: 1117–1127).Our experiments show that there is only a twofold reductionin meiotic crossovers in the absence of MMS4. This indicatesthat, at least in Saccharomyces cerevisiae, the Mus81/Mms4 complexdoes not function as the unique Holliday junction resolvaseduring meiotic recombination.

Manuscript received May 30, 2001; Accepted for publication September 24, 2001.

LITERATURE CITED

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MATERIALS AND METHODS
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DISCUSSION
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