Meiotic Recombination in Human and Dog : Targets, Consequences and Implications for Genome Evolution

Abstract: Understanding the mechanism of recombination has important implications for genome evolution and genomic variability. The work presented in this thesis studies the properties of recombination by investigating the effects it has on genome evolution in humans and dogs.Using alignments of human genes with chimpanzee and macaque orthologues we studied substitution patterns along the human lineage and scanned for evidence of positive selection. The properties mirror the situation in human non-coding sequences with the fixation bias ‘GC-biased gene conversion’ (gBGC) as a driving force in the most rapidly evolving regions. By assigning candidate genes to distinct classes of evolutionary forces we quantified the extent of those genes affected by gBGC to 20%. This suggests that human-specific characters can be prompted by the fixation bias of gBGC, which can be mistaken for selection.The gene PRDM9 controls recombination in most mammals, but is lacking in dogs. Using whole-genome alignments of dog with related species we examined the effects of PRDM9 inactivation. Additionally, we analyzed genomic variation in the genomes of several dog breeds. We identified that non-allelic homologous recombination (NAHR) via sequence identity, often GC-rich, creates structural variants of genomic regions. We show that these regions, which are also found in dog recombination hotspots, are a subset of unmethylated CpG-islands (CGIs). We inferred that CGIs have experienced a drastic increase in biased substitution rates, concurrent with a shift of recombination to target these regions. This enables recurrent episodes of gBGC to shape their distribution.The work presented in this thesis demonstrates the importance of meiotic recombination on patterns of molecular evolution and genomic variability in humans and dogs. Bioinformatic analyses identified mechanisms that regulate genome composition. gBGC is presented as an alternative to positive selection and is revealed as a major factor affecting allele configuration and the emergence of accelerated evolution on the human lineage. Characterization of recombination-induced sequence patterns highlights the potential of non-methylation and establishes unmethylated CGIs as targets of meiotic recombination in dogs. These observations describe recombination as an interesting process in genome evolution and provide further insights into the mechanisms of genomic variability.