Abstract
Recent work indicates that allelic incompatibility in the mouse PRDM9 (Meisetz) gene can cause hybrid male sterility, contributing to genetic isolation and potentially speciation. The only phenotype of mouse PRDM9 knockouts is a meiosis I block that causes sterility in both sexes. The PRDM9 gene encodes a protein with histone H3(K4) trimethyltransferase activity, a KRAB domain, and a DNA-binding domain consisting of multiple tandem C2H2 zinc finger (ZF) domains. We have analyzed human coding polymorphism and interspecies evolutionary changes in the PRDM9 gene. The ZF domains of PRDM9 are evolving very rapidly, with compelling evidence of positive selection in primates. Positively selected amino acids are predominantly those known to make nucleotide specific contacts in C2H2 zinc fingers. These results suggest that PRDM9 is subject to recurrent selection to change DNA-binding specificity. The human PRDM9 protein is highly polymorphic in its ZF domains and nearly all polymorphisms affect the same nucleotide contact residues that are subject to positive selection. ZF domain nucleotide sequences are strongly homogenized within species, indicating that interfinger recombination contributes to their evolution. PRDM9 has previously been assumed to be a transcription factor required to induce meiosis specific genes, a role that is inconsistent with its molecular evolution. We suggest instead that PRDM9 is involved in some aspect of centromere segregation conflict and that rapidly evolving centromeric DNA drives changes in PRDM9 DNA-binding domains.
Highlights
Allelic incompatibility at the mouse PRDM9 (Meisetz) locus can cause hybrid male sterility due to failure in spermatogenesis [1]
Because of its histone modifying activity and DNA-binding domains, it has been assumed that PRDM9 encodes a transcription factor that regulates other genes important for germ line meiosis but there is no direct evidence for such a role
We report analysis of molecular evolution of the PRDM9 gene based on sequence comparisons between primate species and on human polymorphisms
Summary
Allelic incompatibility at the mouse PRDM9 (Meisetz) locus can cause hybrid male sterility due to failure in spermatogenesis [1]. Rare dominant nonsynonymous mutations in human PRDM9 may cause failure in spermatogenesis (azoospermia, [2]), suggesting similar allelic incompatibility in humans. These data support a role for PRDM9 in an early stage of pre-zygotic hybrid incompatibility, consistent with a role in speciation [1,3]. Because of its histone modifying activity and DNA-binding domains, it has been assumed that PRDM9 encodes a transcription factor that regulates other genes important for germ line meiosis but there is no direct evidence for such a role
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