Meiotic recombination initiates with DNA double-strand breaks (DSBs) repaired as either crossovers (COs) or non-crossovers. Across eukaryotes, MSH4/MSH5 (MutS{gamma}) licenses DSB repair intermediates, directing repair into the class I CO pathway via recruitment of MLH1/MLH3 (MutL{gamma}). In mammals, excess MutS{gamma} sites relative to final MutL{gamma} foci suggest additional MutS{gamma} functions, including directing repair through the minor class II CO pathway. We investigated the role of a mammalian-specific 38-amino acid C-terminal domain of MSH5 using mice lacking this domain (Msh5{Delta}C/{Delta}C). Spermatocytes and oocytes load MSH4 normally to achieve CO licensing in zygonema, but these numbers decline precipitously in pachynema, leading to dramatically reduced MutL{gamma} foci and associated pro-CO factors HEI10 and CNTD1. Despite this, licensing factors RNF212B and MutS{gamma}-associated kinase CDK4 remain persistently upregulated in pachynema. Strikingly, the switch from licensing-associated CDK4 to CO-site-associated CDK2 fails to occur in Msh5{Delta}C/{Delta}C mice, even at residual class I CO events. The result is rapid germ cell death prior to prophase I completion in both sexes. Thus, the loss of the MSH5 C-terminus functionally uncouples the regulatory proteins that define the stepwise patterning of class I COs. Our findings reveal novel early roles for the C-terminus of mammalian MSH5 in converting licensed DSB repair intermediates to designated class I COs.
Carr, K. D., Adjei-Boadu, M. S., O'Donnell, E., Horan, T. S., Wood, A. J., Zhang, Y., Edelmann, W., Carro, M. d. l. M., Cohen, P.
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