Meiotic crossover frequencies show wide variation among organisms. But most organisms maintain at least one crossover per homolog pair (obligate crossover). In Saccharomyces cerevisiae, previous studies have shown crossover frequencies are reduced in the mismatch repair related mutant mlh3 and enhanced in a meiotic checkpoint mutant pch2 by up to twofold at specific chromosomal loci, but both mutants maintain high spore viability. We analyzed meiotic recombination events genome-wide in mlh3, pch2, and mlh3 pch2 mutants to test the effect of variation in crossover frequency on obligate crossovers. mlh3 showed ~30% genome-wide reduction in crossovers (64 crossovers per meiosis) and loss of the obligate crossover, but nonexchange chromosomes were efficiently segregated. pch2 showed ~50% genome-wide increase in crossover frequency (137 crossovers per meiosis), elevated noncrossovers as well as loss of chromosome size dependent double-strand break formation. Meiotic defects associated with pch2 did not cause significant increase in nonexchange chromosome frequency. Crossovers were restored to wild-type frequency in the double mutant mlh3 pch2 (100 crossovers per meiosis), but obligate crossovers were compromised. Genetic interference was reduced in mlh3, pch2, and mlh3 pch2. Triple mutant analysis of mlh3 pch2 with other resolvase mutants showed that most of the crossovers in mlh3 pch2 are made through the Mus81-Mms4 pathway. These results are consistent with a requirement for increased crossover frequencies in the absence of genetic interference for obligate crossovers. In conclusion, these data suggest crossover frequencies and the strength of genetic interference in an organism are mutually optimized to ensure obligate crossovers.
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