A WD Repeat Protein, Rec14, Essential for Meiotic Recombination in Schizosaccharomyces pombe

Mutations in the Schizosaccharomyces pombe rec14 gene reduce meiotic recombination by as much as a factor of 1000 in the three intervals tested on chromosomes I and III. A DNA clone complementing the rec14 mutation was shown by genetic and physical analysis to contain the rec14 gene, which was functional in plasmid-borne inserts as small as 1.4 kb. The rec14 gene contains two exons separated by a 53-bp intron, which was confirmed by analysis of rec14 transcripts. The spliced transcript encodes a protein product of 302 amino acids, which contains six WD repeat motifs found in the G-beta transducin family of proteins and other proteins, including the Saccharomyces cerevisiae Ski8 (Rec103) protein. Although the rec14 transcripts were present in mitotically dividing cells, rec14 mutations had no detectable effect on mitotic recombination. The pattern of expression of rec14 differs from that of previously analyzed S. pombe rec genes. Based upon mutant phenotypes and amino acid sequence similarities, we propose that S. pombe Rec14 is a functional homologue of S. cerevisiae Rec103.

The Schizosaccharomyces pombe rec16 Gene Product Regulates Multiple Meiotic Events

Previously isolated meiotic recombination (rec) mutants of Schizosaccharomyces pombe define 16 complementation groups. The rec genes cloned and sequenced to date reveal little amino acid sequence identity to other reported proteins. We examined the rec mutants for alterations in meiotic events other than recombination to gain insight into the rec gene functions and to assess whether they affect recombination directly or indirectly. While mutations in the rec6–12, 14, 15 and 19 genes appeared to affect only meiotic recombination, a mutation in rec16 delayed meiotic DNA synthesis and, in some instances, reduced its amount; mitotic DNA synthesis was not detectably altered, indicating that the rec16 effect is limited to meiosis. In the rec16 mutant some meiotically induced transcripts (e.g., rec7 and 15) were significantly reduced in abundance, whereas others (e.g., rec10 and exo1) were induced and degraded with normal timing and extent during meiosis, indicating that the rec16 mutation leaves the basic meiotic program intact. These results indicate that the rec genes other than rec16 have their primary effect on meiotic recombination. In contrast, the rec16 gene product is essential for normal meiotic replication, recombination, and induction of some transcripts. These meiotic events may be coupled via a dependence of recombination and transcription on replication or via a cascade of gene expression.

Meiotically induced rec7 and rec8 genes of Schizosaccharomyces pombe.

The Schizosaccharomyces pombe rec7 and rec8 genes, which are required for meiotic intragenic recombination but not for mitotic recombination, have been cloned and their DNA sequences determined. Genetic and physical analyses demonstrated that the cloned fragments contained the rec genes rather than rec mutation suppressors. A 1.6-kb DNA fragment contained a functional rec7 gene, and a 2.1-kb fragment contained a functional rec8 gene. The nucleotide sequences of these fragments revealed open reading frames predicting 249 amino acids for the rec7 gene product and 393 amino acids for the rec8 gene product. Northern hybridization analysis showed that both rec gene mRNAs were detectable only at 2-3 hr after induction of meiosis. The absence of these mRNAs in mitosis and their disappearance at 4 hr and later in meiosis suggest that the rec7 and rec8 gene products may be involved primarily in the early steps of meiotic recombination in S. pombe.

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 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.

Seventeen complementation groups of mutations decreasing meiotic recombination in Schizosaccharomyces pombe.

We have analyzed 43 recessive mutations reducing meiotic intragenic recombination in Schizosaccharomyces pombe. These mutations were isolated by a screen for reduced plasmid-by-chromosome recombination at the ade6 locus. Sixteen of the mutations define 10 new complementation groups, bringing to 17 the number of genes identified to be involved in meiotic recombination. The mutations were grouped into three discrete classes depending on the severity of the recombination deficiency in crosses involving the ade6-M26 recombination hotspot. Class I mutations caused at least a 1000-fold reduction in M26-stimulated intragenic recombination at the ade6 locus. Class II mutations reduced M26-stimulated recombination approximately 100-fold. Class III mutations caused a 3-10-fold reduction in either M26-stimulated or non-hotspot recombination. We obtained multiple alleles of class I and class II mutations, suggesting that we may be nearing saturation for mutations of this type. As a first step toward mapping, we used mitotic segregation to assign fourteen of the rec genes to chromosomes. Mutations in the six rec genes tested also caused a decrease in intragenic recombination at the ura4 locus; five of these mutations also reduced intergenic recombination between the pro2 and arg3 genes. These results indicate that these multiple rec gene products are required for high level meiotic recombination throughout the S. pombe genome.

Isolation of mutants defective in early steps of meiotic recombination in the yeast Saccharomyces cerevisiae.

Using a selection based upon the ability of early Rec- mutations (e.g., rad50) to rescue the meiotic lethality of a rad52 spo13 strain, we have isolated 177 mutants. Analysis of 56 of these has generated alleles of the known Rec genes SPO11, ME14 and MER1, as well as defining five new genes: REC102, REC104, REC107, REC113 and REC114. Mutations in all of the new genes appear to specifically affect meiosis; they do not have any detectable mitotic phenotype. Mutations in REC102, REC104 and REC107 reduce meiotic recombination several hundred fold. No alleles of RED1 or HOP1 were isolated, consistent with the proposal that these genes may be primarily involved with chromosome pairing and not exchange.