Abstract
Recombination is an essential process in eukaryotes, which increases diversity by disrupting genetic linkage between loci and ensures the proper segregation of chromosomes during meiosis. In the human genome, recombination events are clustered in hotspots, whose location is determined by the PRDM9 protein. There is evidence that the location of hotspots evolves rapidly, as a consequence of changes in PRDM9 DNA-binding domain. However, the reasons for these changes and the rate at which they occur are not known. In this study, we investigated the evolution of human hotspot loci and of PRDM9 target motifs, both in modern and archaic human lineages (Denisovan) to quantify the dynamic of hotspot turnover during the recent period of human evolution. We show that present-day human hotspots are young: they have been active only during the last 10% of the time since the divergence from chimpanzee, starting to be operating shortly before the split between Denisovans and modern humans. Surprisingly, however, our analyses indicate that Denisovan recombination hotspots did not overlap with modern human ones, despite sharing similar PRDM9 target motifs. We further show that high-affinity PRDM9 target motifs are subject to a strong self-destructive drive, known as biased gene conversion (BGC), which should lead to the loss of the majority of them in the next 3 MYR. This depletion of PRDM9 genomic targets is expected to decrease fitness, and thereby to favor new PRDM9 alleles binding different motifs. Our refined estimates of the age and life expectancy of human hotspots provide empirical evidence in support of the Red Queen hypothesis of recombination hotspots evolution.
Highlights
Meiotic recombination is a highly regulated process, initiated by the programmed formation of double-strand breaks (DSBs)
Recombination plays a central role by ensuring the proper segregation of chromosomes during meiosis and increasing genetic diversity at the population scale
To gain insight into the processes driving the evolution of recombination hotspots we analyzed the recent history of human hotspots, using the genome of a closely related archaic hominid, Denisovan
Summary
Meiotic recombination is a highly regulated process, initiated by the programmed formation of double-strand breaks (DSBs). The set of recombination hotspots that are the most frequently used can be inferred from patterns of linkage disequilibrium [3] or of genetic admixture [16] These analyses revealed that more than 90% of recombination hotspots are shared between European and African populations [16]. This strong overlap is due to the fact that the same major allele of PRDM9 (allele A) is present at high frequency both in European and African populations [11] This A allele presents affinity for the 13-bp motif CCTCCCTNNCCAC, which was initially identified on the basis of its enrichment within human recombination hotspots [17] (we will hereafter refer to this sequence motif as HM – for human hotspot motif)
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