MUS81 Generates a Subset of MLH1-MLH3–Independent Crossovers in Mammalian Meiosis

Abstract

Two eukaryotic pathways for processing double-strand breaks (DSBs) as crossovers have been described, one dependent on the MutL homologs Mlh1 and Mlh3, and the other on the structure-specific endonuclease Mus81. Mammalian MUS81 has been implicated in maintenance of genomic stability in somatic cells; however, little is known about its role during meiosis. Mus81-deficient mice were originally reported as being viable and fertile, with normal meiotic progression; however, a more detailed examination of meiotic progression in Mus81-null animals and WT controls reveals significant meiotic defects in the mutants. These include smaller testis size, a depletion of mature epididymal sperm, significantly upregulated accumulation of MLH1 on chromosomes from pachytene meiocytes in an interference-independent fashion, and a subset of meiotic DSBs that fail to be repaired. Interestingly, chiasmata numbers in spermatocytes from Mus81^−/− animals are normal, suggesting additional integrated mechanisms controlling the two distinct crossover pathways. This study is the first in-depth analysis of meiotic progression in Mus81-nullizygous mice, and our results implicate the MUS81 pathway as a regulator of crossover frequency and placement in mammals. Failure to undergo faithful meiotic chromosome segregation during mammalian meiosis can result in aneuploidy in the offspring and is a major cause of pregnancy loss and birth defects in humans. One essential component of meiotic prophase I is the exchange of genetic information between maternal and paternal chromosomes, known as recombination or crossing over, and is mediated, at least in part, by the mismatch repair proteins MSH4–MSH5 and MLH1–MLH3. A distinct subset of crossovers in lower organisms is generated by an alternate pathway involving Mus81 endonuclease. Previous studies into the impact of Mus81 mutations in mice revealed no adverse effect on the fertility of these animals. In this study, we report subtle, yet significant, defects in meiotic progression in male and female Mus81 mice, coupled with intriguing results showing that MUS81 protein is essential for crossover control in mammals. MUS81 appears to be required for correct localization of MLH1–MLH3 complexes to paired homologous chromosomes, however, not for the maintenance of physical crossovers, visualized as chiasmata. These results show a complex interplay between the MUS81 and MLH1–MLH3 pathways for generation of crossovers and, as such, are critical to the further understanding of the intricacies of crossover control with a view to reducing meiotic error rate in humans.