Abstract
Meiotic recombination ensures the correct segregation of homologous chromosomes during gamete formation and contributes to DNA diversity through both large-scale reciprocal crossovers and very localised gene conversion events, also known as noncrossovers. Considerable progress has been made in understanding factors such as PRDM9 and SNP variants that influence the initiation of recombination at human hotspots but very little is known about factors acting downstream. To address this, we simultaneously analysed both types of recombinant molecule in sperm DNA at six highly active hotspots, and looked for disparity in the transmission of allelic variants indicative of any cis-acting influences. At two of the hotspots we identified a novel form of biased transmission that was exclusive to the noncrossover class of recombinant, and which presumably arises through differences between crossovers and noncrossovers in heteroduplex formation and biased mismatch repair. This form of biased gene conversion is not predicted to influence hotspot activity as previously noted for SNPs that affect recombination initiation, but does constitute a powerful and previously undetected source of recombination-driven meiotic drive that by extrapolation may affect thousands of recombination hotspots throughout the human genome. Intriguingly, at both of the hotspots described here, this drive favours strong (G/C) over weak (A/T) base pairs as might be predicted from the well-established correlations between high GC content and recombination activity in mammalian genomes.
Highlights
During meiosis, homologous chromosomes have to find each other and engage in recombination to segregate accurately
Hotspot activity is regulated in trans by the protein ‘‘PR-domain containing 9’’ (PRDM9) [5,6,7,8,9], whose DNA binding domain consists of tandem-repeat zincfingers (ZnFs) encoded by a minisatellite
Meiosis is an essential feature of sexual reproduction that maintains chromosome number over generations
Summary
Homologous chromosomes have to find each other and engage in recombination to segregate accurately. DNA double-stranded breaks (DSBs) are introduced by SPO11, and subsequently repaired using the homologue instead of the identical sister-chromatid as a template (reviewed in [1]). This tethering of homologous chromosomes provides the necessary connection for accurate reductional segregation. Hotspot activity is regulated in trans by the protein ‘‘PR-domain containing 9’’ (PRDM9) [5,6,7,8,9], whose DNA binding domain consists of tandem-repeat zincfingers (ZnFs) encoded by a minisatellite. PRDM9 might function by triggering chromatin remodelling via histone 3 lysine 4 trimethylation, allowing SPO11 to introduce DSBs and initiate recombination [12,13]
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