| Popis: |
In the majority of bird species, recombination between the sex chromosome pairs in heterogametic females (ZW) is restricted to a small pseudoautosomal region (PAR), whereas recombination is ongoing along the entire Z chromosome in the homogametic males (ZZ). Recombination has a strong impact on the sequence evolution by affecting the extent of linkage, level of genetic diversity and efficacy of selection. Species within the Sylvioidea superfamily are unique among birds in having extended Z and W chromosomes (neo-sex chromosomes) formed by a fusion between the ancestral sex chromosomes and a part of chromosome 4A. So far the recombination landscape of the Sylvioidea neo-sex chromosomes remains unknown, despite its importance for understanding sequence evolution. Here, we use linkage mapping in a multi-generation pedigree to assemble, and assess the recombination rate along the entire Z chromosome of one Sylvioidea species, the great reed warbler (Acrocephalus arundinaceus). This resulted in an 87.54 Mbp and 90.19 cM large Z including the ancestral-Z, where the small PAR (0.89 Mbp) is located, and the added-Z. A striking result was an extreme variation in recombination rate along the Z in male great reed warblers with high rates at both telomeric ends, but an apparent lack of recombination over a substantial central section, covering 77% of the chromosome. This region showed a drastic loss of nucleotide diversity and accumulation of repeats compared to the highly recombining regions. Nonetheless, the evolutionary rate of genes (measured by dN/dS) did not differ between these regions, suggesting that the efficacy of selection on protein-coding sequences is not reduced by lack of recombination. |
