Abstract
In most species, crossovers (COs) are essential for the accurate segregation of homologous chromosomes at the first meiotic division. Their number and location are tightly regulated. Here, we report a detailed, genome-wide characterization of the rate and localization of COs in Arabidopsis thaliana, in male and female meiosis. We observed dramatic differences between male and female meiosis which included: (i) genetic map length; 575 cM versus 332 cM respectively; (ii) CO distribution patterns: male CO rates were very high at both ends of each chromosome, whereas female CO rates were very low; (iii) correlations between CO rates and various chromosome features: female CO rates correlated strongly and negatively with GC content and gene density but positively with transposable elements (TEs) density, whereas male CO rates correlated positively with the CpG ratio. However, except for CpG, the correlations could be explained by the unequal repartition of these sequences along the Arabidopsis chromosome. For both male and female meiosis, the number of COs per chromosome correlates with chromosome size expressed either in base pairs or as synaptonemal complex length. Finally, we show that interference modulates the CO distribution both in male and female meiosis.
Highlights
Crossovers (COs) are recombination events characterized by a reciprocal exchange of genetic material
While A. thaliana is a hermaphrodite plant with male and female meiosis occurring in the same flower and with the same genome, we observed dramatic differences in the distribution and the rate of crossovers along chromosomes in male and female meiosis
Male CO rates are very high at both ends of each chromosome, whereas female CO rates are very low
Summary
Crossovers (COs) are recombination events characterized by a reciprocal exchange of genetic material. Variations in CO rates correlate with several other genomic features such as transposable elements (TE) density, the CpG ratio, gene density, nucleotide polymorphisms or chromosomal architecture properties like distance to telomeres or centromeres [11,18,19,20,21]. None of these other characteristics are systematically correlated with CO rate variation across every species. The various features that correlate with this non-homogeneity in CO rates may have causal relationships or may be only incidentally related
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