Natural variation modifies centromere proximal meiotic crossover frequency and segregation distortion in Arabidopsis thaliana

Background: Centromeres mediate chromosome segregation during cell division. In plants, centromeres are loaded with CENH3-variant nucleosomes, which direct kinetochore formation and spindle microtubule interaction. Plant centromeres are frequently composed of megabase-scale satellite repeat arrays, or retrotransposon nests. In monocentric genomes, such as Arabidopsis thaliana, extended regions of pericentromeric heterochromatin surround the CENH3-occupied satellite arrays. A zone of suppressed meiotic crossover recombination contains the centromere and extends into the pericentromeres. Here, we explore how Arabidopsis natural genetic variation influences centromere-proximal crossover frequency, and segregation distortion through meiosis, when homologous centromeres are structurally heterozygous. Results: We used fluorescent crossover reporters to survey the effect of natural variation on centromere-proximal recombination in twelve F1 hybrids, capturing Arabidopsis Eurasian and relict diversity. The majority of F1 hybrids showed either elevated or suppressed centromere-proximal crossovers (49 of 60), relative to inbreds. We relate hybrid crossover frequencies to patterns of centromeric structural variation, and in a subset of accessions, to epigenetic patterns of CENH3 loading and DNA methylation. The fluorescent reporters also allow segregation distortion through meiosis to be compared between inbred and hybrid strains. We observed a minority of hybrids (18 of 60) with distorted segregation through meiosis compared to inbreds, with and without simultaneous change to centromere-proximal crossover frequency. Conclusions: We reveal a complex relationship between centromere structural variation, epigenetic state, crossover recombination, and segregation distortion. We propose a model for how Arabidopsis centromere structural heterozygosity may cause segregation distortion during female meiosis.