Molecular and genetic analysis of the yeast early meiotic recombination genes REC102 and REC107/MER2.

By selecting for mutations which could rescue the meiotic lethality of a rad52 spo13 strain, we isolated several new Rec genes required relatively early in the meiotic recombination process. This paper presents data to confirm that two of them, REC102 and REC107, are general, meiosis-specific recombination genes that have no detectable role during mitosis. Sequence analysis and genetic complementation indicate that REC107 is identical to the MER2 gene. No sequences related to REC102 have been found in the GenBank or EMBL collections. REC102 is expressed only in meiosis, prior to the reductional division, at about the time that genetic recombination occurs. Examination of the REC102 sequence indicates the presence of several sequences which may play a role in the regulation of its expression; however, the URS1 sequence commonly found in genes expressed early in meiosis is not present.     

Molecular and Genetic Analysis of Rec103, an Early Meiotic Recombination Gene in Yeast

In the yeast Saccharomyces cerevisiae at least 10 genes are required to begin meiotic recombination. A new early recombination gene REC103 is described in this paper. It was initially defined by the rec103-1 mutation found in a selection for mutations overcoming the spore inviability of a rad52 spo13 haploid strain. Mutations in REC103 also rescue rad52 in spo13 diploids. rec103 spo13 strains produce viable spores; these spores show no evidence of meiotic recombination. rec103 SPO13 diploids produce no viable spores, consistent with the loss of recombination. Mutations in REC103 do not affect mitotic recombination, growth, or repair. These phenotypes are identical to those conferred by mutations in several other early meiotic recombination genes (e.g., REC102, REC104, REC114, MEI4, MER2, and SPO11). REC103 maps to chromosome VII between ADE5 and RAD54. Cloning and sequencing of REC103 reveals that REC103 is identical to SKI8, a gene that depresses the expression of yeast double-stranded (``killer') (ds)RNA viruses. REC103/SKI8 is transcribed in mitotic cells and is induced ~15-fold in meiosis. REC103 has 26% amino acid identity to the Schizosaccharomyces pombe rec14(+) gene; mutations in both genes confer similar meiotic phenotypes, suggesting that they may play similar roles in meiotic recombination.     

Suppressor analysis of the Saccharomyces cerevisiae gene REC104 reveals a genetic interaction with REC102

REC104 is a gene required for the initiation of meiotic recombination in Saccharomyces cerevisiae. To better understand the role of REC104 in meiosis, we used an in vitro mutagenesis technique to create a set of temperature-conditional mutations in REC104 and used one ts allele (rec104-8) in a screen for high-copy suppressors. An increased dosage of the early exchange gene REC102 was found to suppress the conditional recombinational reduction in rec104-8 as well as in several other conditional rec104 alleles. However, no suppression was observed for a null allele of REC104, indicating that the suppression by REC102 is not "bypass" suppression. Overexpression of the early meiotic genes REC114, RAD50, HOP1, and RED1 fails to suppress any of the rec104 conditional alleles, indicating that the suppression might be specific to REC102.     

Analysis of Meiotic Recombination Pathways in the Yeast Saccharomyces Cerevisiae

In the yeast, Saccharomyces cerevisiae, several genes appear to act early in meiotic recombination. HOP1 and RED1 have been classified as such early genes. The data in this paper demonstrate that neither a red1 nor a hop1 mutation can rescue the inviable spores produced by a rad52 spo13 strain; this phenotype helps to distinguish these two genes from other early meiotic recombination genes such as SPO11, REC104, or MEI4. In contrast, either a red1 or a hop1 mutation can rescue a rad50S spo13 strain; this phenotype is similar to that conferred by mutations in the other early recombination genes (e.g., REC104). These two different results can be explained because the data presented here indicate that a rad50S mutation does not diminish meiotic intrachromosomal recombination, similar to the mutant phenotypes conferred by red1 or hop1. Of course, RED1 and HOP1 do act in the normal meiotic interchromosomal recombination pathway; they reduce interchromosomal recombination to ~10% of normal levels. We demonstrate that a mutation in a gene (REC104) required for initiation of exchange is completely epistatic to a mutation in RED1. Finally, mutations in either HOP1 or RED1 reduce the number of double-strand breaks observed at the HIS2 meiotic recombination hotspot.     

Characterization of REC104, a gene required for early meiotic recombination in the yeast Saccharomyces cerevisiae.

The REC104 gene was initially defined by mutations that rescued the inviability of a rad52 spo 13 haploid strain in meiosis. We have observed that rec104 mutant strains undergo essentially no induction of meiotic gene conversion, and we have not been able to detect any meiotic crossing over in such strains. The REC104 gene has no apparent role in mitosis, since mutations have no observable effect on growth, mitotic recombination, or DNA repair. The DNA sequence of REC104 reveals that it is a previously unknown gene with a coding region of 549-bp, and genetic mapping has localized the gene to chromosome VIII near FUR1. Expression of the REC104 gene is induced in meiosis, and it appears that the gene is not transcribed in mitotic cells. Possible roles for the REC104 gene product in meiosis are discussed.     

Characterization of REC104, a gene required for early meiotic recombination in the yeast Saccharomyces cerevisiae

The REC104 gene was initially defined by mutations that rescued the inviability of a rad52 spo13 haploid strain in meiosis. We have observed that rec104 mutant strains undergo essentially no induction of meiotic gene conversion, and we have not been able to detect any meiotic crossing over in such strains. The REC104 gene has no apparent role in mitosis, since mutations have no observable effect on growth, mitotic recombination, or DNA repair. The DNA sequence of REC104 reveals that it is a previously unknown gene with a coding region of 549-bp, and genetic mapping has localized the gene to chromosome VIll near FUR1. Expression of the REC104 gene is induced in meiosis, and it appears that the gene is not transcribed in mitotic cells. Possible roles for the REC104 gene product in meiosis are discussed. © 1993 Wiley-Liss, Inc.     

Coordination of the initiation of recombination and the reductional division in meiosis in Saccharomyces cerevisiae

Early exchange (EE) genes are required for the initiation of meiotic recombination in Saccharomyces cerevisiae. Cells with mutations in several EE genes undergo an earlier reductional division (MI), which suggests that the initiation of meiotic recombination is involved in determining proper timing of the division. The different effects of null mutations on the timing of reductional division allow EE genes to be assorted into three classes: mutations in RAD50 or REC102 that confer a very early reductional division; mutations in REC104 or REC114 that confer a division earlier than that of wild-type (WT) cells, but later than that of mutants of the first class; and mutations in MEI4 that do not significantly alter the timing of MI. The very early mutations are epistatic to mutations in the other two classes. We propose a model that accounts for the epistatic relationships and the communication between recombination initiation and the first division. Data in this article indicate that double-strand breaks (DSBs) are not the signal for the normal delay of reductional division; these experiments also confirm that MEI4 is required for the formation of meiotic DSBs. Finally, if a DSB is provided by the HO endonuclease, recombination can occur in the absence of MEI4 and REC104.     

Recombination and the Progression of Meiosis in Saccharomyces Cerevisiae

Recombination is an essential part of meiosis; in almost all organisms, including Saccharomyces cerevisiae, proper chromosome segregation and the viability of meiotic products is dependent upon normal levels of recombination. In this article we examine the kinetics of the meiotic divisions in four mutants defective in the initiation of recombination. We find that mutations in any of three Early Exchange genes (REC104, REC114 or REC102) confer a phenotype in which the reductional division occurs earlier than in an isogenic wild-type diploid. We also present data confirming previous reports that strains with a mutation in the Early Exchange gene MEI4 undergo the first division at about the same time as wild-type cells. The rec104 mutation is epistatic to the mei4 mutation for the timing of the first division. These observations suggest a possible relationship between the initiation of recombination and the timing of the reductional division. These data also allow these four Early Exchange genes examined to be distinguished in terms of their role in coordinating recombination with the reductional division.     

Functional interactions between SPO11 and REC102 during initiation of meiotic recombination in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, formation of the DNA double-strand breaks (DSBs) that initiate meiotic recombination requires the products of at least 10 genes. Spo11p is thought to be the catalytic subunit of the DNA cleaving activity, but the roles of the other proteins, and the interactions among them, are not well understood. This study demonstrates genetic and physical interactions between the products of SPO11 and another early meiotic gene required for DSB formation, REC102. We found that epitope-tagged versions of SPO11 and REC102 that by themselves were capable of supporting normal or nearly normal levels of meiotic recombination conferred a severe synthetic cold-sensitive phenotype when combined in the same cells. DSB formation, meiotic gene conversion, and spore viability were drastically reduced in the doubly tagged strain at a nonpermissive temperature. This conditional defect could be partially rescued by expression of untagged SPO11, but not by expression of untagged REC102, indicating that tagged REC102 is fully dominant for this synthetic phenotype. Both tagged and wild-type Spo11p co-immunoprecipitated with tagged Rec102p from meiotic cell extracts, indicating that these proteins are present in a common complex in vivo. Tagged Rec102p localized to the nucleus in whole cells and to chromatin on spread meiotic chromosomes. Our results are consistent with the idea that a multiprotein complex that includes Spo11p and Rec102p promotes meiotic DSB formation.     

Relationships between a Hyper-Rec Mutation (rem1 ) and Other Recombination and Repair Genes in Yeast

Mutations in the REM1 gene of Saccharomyces cerevisiae confer a semidominant hyper-recombination and hypermutable phenotype upon mitotic cells ( GOLIN and ESPOSITO 1977). These effects have not been observed in meiosis. We have examined the interactions of rem1 mutations with rad6-1, rad50 -1, rad52-1 or spo11 -1 mutations in order to understand the basis of the rem1 hyper-rec phenotype. The rad mutations have pleiotropic phenotypes; spo11 is only defective in sporulation and meiosis. The RAD6, RAD50 and SPO11 genes are not required for spontaneous mitotic recombination; mutations in the RAD52 gene cause a general spontaneous mitotic Rec- phenotype. Mutations in RAD50 , RAD52 or SPO11 eliminate meiotic recombination, and mutations in RAD6 prevent spore formation. Evidence for the involvement of RAD6 in meiotic recombination is less clear. Mutations in all three RAD genes confer sensitivity to X rays; the RAD6 gene is also required for UV damage repair. To test whether any of these functions might be involved in the hyper-rec phenotype conferred by rem1 mutations, double mutants were constructed. Double mutants of rem1 spo11 were viable and demonstrated rem1 levels of mitotic recombination, suggesting that the normal meiotic recombination system is not involved in producing the rem1 phenotype. The rem1 rad6 double mutant was also viable and had rem1 levels of mitotic recombination. Neither rem1 rad50 nor rem1 rad52 double mutants were viable. This suggests that rem1 causes its hyper-rec phenotype because it creates lesions in the DNA that are repaired using a recombination-repair system involving RAD50 and RAD52.     

The REC41 gene of Saccharomyces cerevisiae: isolation and genetic analysis

Recombination-deficient strains have been proven useful for the understanding of the genetic control of homologous recombination. As the genetic screens used to isolate recombination-deficient (rec(-)) yeast mutants have not been saturated, we sought to develop a simple colony color assay to identify mutants with low or elevated rates of recombination. Using this system we isolated a collection of rec(-) mutants. We report the characterization of the REC41 gene identified in this way. REC41 is required for normal levels of interplasmid recombination and gamma-ray induced mitotic interchromosomal recombination. The rec41-1 mutant failed to grow at 37 degrees C. Microscopic analysis of plated cells showed that 45-50% of them did not form visible colonies at permissive temperature. Haploid cells of the rec41 mutant show the same gamma-ray sensitivity as wild type ones. However, the diploid rec41 mutant shows gamma-ray sensitivity which is comparable with heterozygous REC41/rec41-1 diploid cells. This fact indicates semidominance of the rec41-1 mutation. Diploid strains homozygous for the rec41 rad52 mutations had the same gamma-ray sensitivity as single rad52 diploids and exhibited dramatically decreased growth rate. The expression of the HO gene does not lead to inviability of rec41 cells. The rec41 mutation has an effect on meiosis, likely meiotic recombination, even in the heterozygous state. We cloned the REC41 gene. Sequence analysis revealed that the REC41 gene is encoded by ORF YDR245w. Earlier, this ORF was attributed to MNN10, BED1, SLC2, CAX5 genes. Two multicopy plasmids with suppressers of the rec41-1 mutation (pm21 and pm32) were isolated. The deletion analysis showed that only DNA fragments with the CDC43 and HAC1 genes can partially complement the rec41-1 mutation.     

Identification of New Genes Required for Meiotic Recombination in Saccharomyces Cerevisiae

Mutants defective in meiotic recombination were isolated from a disomic haploid strain of Saccharomyces cerevisiae by examining recombination within the leu2 and his4 heteroalleles located on chromosome III. The mutants were classified into two new complementation groups (MRE2 and MRE11) and eight previously identified groups, which include SPO11, HOP1, REC114, MRE4/MEK1 and genes in the RAD52 epistasis group. All of the mutants, in which the mutations in the new complementation groups are homozygous and diploid, can undergo premeiotic DNA synthesis and produce spores. The spores are, however, not viable. The mre2 and mre11 mutants produce viable spores in a spo13 background, in which meiosis I is bypassed, suggesting that these mutants are blocked at an early step in meiotic recombination. The mre2 mutant does not exhibit any unusual phenotype during mitosis and it is, thus, considered to have a mutation in a meiosis-specific gene. By contrast, the mre11 mutant is sensitive to damage to DNA by methyl methanesulfonate and exhibits a hyperrecombination phenotype in mitosis. Among six alleles of HOP1 that were isolated, an unusual pattern of intragenic complementation was observed.     

Saccharomyces cerevisiae checkpoint genes MEC1, RAD17 and RAD24 are required for normal meiotic recombination partner choice.

Checkpoint gene function prevents meiotic progression when recombination is blocked by mutations in the recA homologue DMC1. Bypass of dmc1 arrest by mutation of the DNA damage checkpoint genes MEC1, RAD17, or RAD24 results in a dramatic loss of spore viability, suggesting that these genes play an important role in monitoring the progression of recombination. We show here that the role of mitotic checkpoint genes in meiosis is not limited to maintaining arrest in abnormal meioses; mec1-1, rad24, and rad17 single mutants have additional meiotic defects. All three mutants display Zip1 polycomplexes in two- to threefold more nuclei than observed in wild-type controls, suggesting that synapsis may be aberrant. Additionally, all three mutants exhibit elevated levels of ectopic recombination in a novel physical assay. rad17 mutants also alter the fraction of recombination events that are accompanied by an exchange of flanking markers. Crossovers are associated with up to 90% of recombination events for one pair of alleles in rad17, as compared with 65% in wild type. Meiotic progression is not required to allow ectopic recombination in rad17 mutants, as it still occurs at elevated levels in ndt80 mutants that arrest in prophase regardless of checkpoint signaling. These observations support the suggestion that MEC1, RAD17, and RAD24, in addition to their proposed monitoring function, act to promote normal meiotic recombination.     

Heteroduplex DNA Formation and Homolog Pairing in Yeast Meiotic Mutants

Previous studies of Saccharomyces cerevisiae have identified several meiosis-specific genes whose products are required for wild-type levels of meiotic recombination and for normal synaptonemal complex (SC) formation. Several of these mutants were examined in a physical assay designed to detect heteroduplex DNA (hDNA) intermediates in meiotic recombination. hDNA was not detected in the rec102, mei4 and hop1 mutants; it was observed at reduced levels in red1, mek1 and mer1 strains and at greater than the wild-type level in zip1. These results indicate that the REC102, MEI4, HOP1, RED1, MEK1 and MER1 gene products act before hDNA formation in the meiotic recombination pathway, whereas ZIP1 acts later. The same mutants assayed for hDNA formation were monitored for meiotic chromosome pairing by in situ hybridization of chromosome-specific DNA probes to spread meiotic nuclei. Homolog pairing occurs at wild-type levels in the zip1 and mek1 mutants, but is substantially reduced in mei4, rec102, hop1, red1 and mer1 strains. Even mutants that fail to recombine or to make any SC or sc precursors undergo a significant amount of meiotic chromosome pairing. The in situ hybridization procedure revealed defects in meiotic chromatin condensation in mer1, red1 and hop1 strains.     

A Conditional Allele of the Saccharomyces Cerevisiae Hop1 Gene Is Suppressed by Overexpression of Two Other Meiosis-Specific Genes: Red1 and Rec104

The HOP1 gene of Saccharomyces cerevisiae is believed to encode a protein component of the synaptonemal complex, the structure formed when homologous chromosomes synapse during meiotic prophase. Five new mutant alleles (three conditional, two nonconditional) of HOP1 were identified by screening EMS-mutagenized cells for a failure to complement the spore viability defect of a hop1 null allele. Two high copy plasmids were found that partially suppress the temperature-sensitive spore inviability phenotype of one of these alleles, hop1-628. The suppression is allele-specific; no effect of the plasmids is observed in hop1 null diploids. Mutation of either of the two suppressor genes results in recessive spore lethality, indicating that these genes play important roles during meiosis. The DNA sequence of one high copy suppressor gene matched that of RED1, a previously identified meiosis-specific gene. Our data strongly support the idea that RED1 protein is also a component of the synaptonemal complex and further suggest that the RED1 and HOP1 gene products may interact. The second suppressor maps to the right arm of chromosome VIII distal to CDC12 and is REC104, a meiosis-specific gene believed to act early in meiosis.     

Multiple mutant analysis of recombination in yeast

Summary. The RAD6, RAD50, and RAD52 loci have been identified as genes which code for functions which may act during meiotic recombination in yeast (Game et al.1980; Prakash et al. 1980). By use of the spol3-1 mutation,which allows sporulating cells to bypass the first meiotic division, the rad50-1 mutation has been directly implicated as a general meiotic Rec- mutation by examination of viable ascospores (Malone and Esposito 1981). Since the rad6-1 and rad52-1 mutations do not yield viable ascospores in the presence of spol3-1, multiple rad mutants have been constructed and analyzed. This analysis has demonstrated that in meiosis tad50-1 is epistatic to rad52-1, and rad6-1 is epistatic to rad50-1. This suggests that the order of action of these genes during meiosis is RAD6, RAD50, and then RAD52. The data for rad6-1 can be interpreted to suggest that RAD6 may not code for a recombination function,per se, although it may be required for recombination to occur. Analysis of mitotic recombination indicates that rad52-1 is epistatic to rad50-1 ; in mitosis; this is consistent with the hypothesis that the RAD50 gene codes for a recombination function required in meiosis but not in mitosis.     

Genetic control of recombination partner preference in yeast meiosis. Isolation and characterization of mutants elevated for meiotic unequal sister-chromatid recombination.

Meiotic exchange occurs preferentially between homologous chromatids, in contrast to mitotic recombination, which occurs primarily between sister chromatids. To identify functions that direct meiotic recombination events to homologues, we screened for mutants exhibiting an increase in meiotic unequal sister-chromatid recombination (SCR). The msc (meiotic sister-chromatid recombination) mutants were quantified in spo13 meiosis with respect to meiotic unequal SCR frequency, disome segregation pattern, sporulation frequency, and spore viability. Analysis of the msc mutants according to these criteria defines three classes. Mutants with a class I phenotype identified new alleles of the meiosis-specific genes RED1 and MEK1, the DNA damage checkpoint genes RAD24 and MEC3, and a previously unknown gene, MSC6. The genes RED1, MEK1, RAD24, RAD17, and MEC1 are required for meiotic prophase arrest induced by a dmc1 mutation, which defines a meiotic recombination checkpoint. Meiotic unequal SCR was also elevated in a rad17 mutant. Our observation that meiotic unequal SCR is elevated in meiotic recombination checkpoint mutants suggests that, in addition to their proposed monitoring function, these checkpoint genes function to direct meiotic recombination events to homologues. The mutants in class II, including a dmc1 mutant, confer a dominant meiotic lethal phenotype in diploid SPO13 meiosis in our strain background, and they identify alleles of UBR1, INP52, BUD3, PET122, ELA1, and MSC1-MSC3. These results suggest that DMC1 functions to bias the repair of meiosis-specific double-strand breaks to homologues. We hypothesize that the genes identified by the class II mutants function in or are regulators of the DMC1-promoted interhomologue recombination pathway. Class III mutants may be elevated for rates of both SCR and homologue exchange.     

Chromosome dynamics in rad12 mutants of Coprinus cinereus

We have characterized the phenotypes of three rad12 mutants of the basidiomycete Coprinus cinereus, which were isolated on the basis of sensitivity to ionizing radiation. Electron microscopic studies of meiotic nuclear spreads showed that all three rad12 mutants are defective in chromosomal synapsis. For rad12-1 and rad12-4, very limited assembly of the synaptonemal complex occurs. The phenotype of rad12-15 is less severe and longer stretches of synapsed chromosomes are formed. However, for all three alleles mutant nuclei arrest in a diffuse state with little synaptonemal complex structure. Observations made of spreads of acridine orange-stained meiotic nuclei correlated with the electron microscopic data. In rad12 strains, chromosomes condense but do not pair, and they later arrest in a decondensed state; very few rad12 cells enter metaphase I. Homozygous dikaryons of rad12 mutants produce fruiting bodies with significantly fewer basidiospores than are found in wild-type dikaryons. The viability of these spores is greatly reduced: all spores produced by rad12-1 and rad12-4 mushrooms fail to germinate, while only 16% of rad12-15 spores are viable. Recombination within the tract of the ribosomal RNA gene repeats was not significantly different in the mutants when compared with a wild-type congenic control. Quantitative measurements of oidial survival indicate that all three rad12 alleles are sensitive to gamma radiation but insensitive to UV radiation relative to wild-type strains.     

Hypersensitivity of Drosophila mei-41 mutants to hydroxyurea is associated with reduced mitotic chromosome stability

6 mutant alleles of the mei-41 locus in Drosophila melanogaster are shown to cause hypersensitivity to hydroxyurea in larvae. The strength of that sensitivity is directly correlated with the influence of the mutant alleles on meiosis in that: alleles exhibiting a strong meiotic effect (mei-41D2, mei-41D5, mei-41D7) are highly sensitive; alleles with negligible meiotic effects (mei-41(104)D1, mei-41(104)D2) are moderately sensitive and an allele which expresses meiotic effects only under restricted conditions (mei-41D9) has an intermediate sensitivity. This sensitivity is not a general feature of strong postreplication repair-deficient mutants, because mutants with that phenotype from other loci do not exhibit sensitivity (mus(2)205A1, mus(3)302D1, mus(3)310D1). The observed lethality is not due to hypersensitivity of DNA synthesis in mei-41 larvae to hydroxyurea as assayed by tritiated thymidine incorporation. Lethality is, however, potentially attributable to an abnormal enhancement of chromosomal aberrations by hydroxyurea in mutant mei-41 larvae. Both in vivo and in vitro exposure of neuroblast cells to hydroxyurea results in an increase in 3 types of aberrations which is several fold higher in mei-41 tissue. Since hydroxyurea disrupts DNA synthesis, these results further implicate the mei-41 locus in DNA metabolism and provide an additional tool for an elucidation of its function. The possible existence of additional genes of this nature is suggested by a more modest sensitivity to hydroxyurea which has been detected in two stocks carrying mutagen-sensitive alleles of alternate genes.