Meiotic recombination spans almost entire chromosome arms in a fully monoarmed karyotype of an African annual killifish Nothobranchius virgatus

During meiosis, homologous chromosomes pair to form synaptonemal complexes (SCs) and exchange genetic material through a process known as meiotic recombination. First, programmed DNA double-strand breaks form, followed by the assembly of recombination foci on SCs. These foci mark the sites of recombination intermediates and future crossovers. Distributions of recombination foci along SCs have been studied in many eukaryotes, revealing the interplay between recombination patterns and genome evolution. However, in fish, data on recombination patterns are scarce, and, for the majority of groups, completely absent. Here, we measure the positions of MLH1 foci in 3,504 SCs from 219 male meiotic cells of an African annual killifish Nothobranchius virgatus, a representative of a genus with remarkable karyotype and genome diversity, and present a detailed statistical analysis of its recombination patterns. We found that, in contrast to the several other fish species characterised to date, recombination in N. virgatus occurs across almost entire chromosome arms, excluding (peri)centromeres and telomeres. In the longest SCs, we observed a proximal and a distal peak of the recombination focus frequency and explained the peaks by chromosome pairing dynamics. We also revealed the typical positions of focus pairs, demonstrated interference between foci, with the minimal interfocus distance of 4 m, and described regions of the total recombination suppression near centromeres and telomeres. In sum, our study provides a detailed analysis of recombination patterns in a killifish with a fully acrocentric karyotype and contributes to cytogenomic and statistical methodology for future exploration of meiotic recombination patterns.