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Meiotic recombination dynamics in plants with repeat-based holocentromeres shed light on the primary drivers of crossover patterning

Marco Castellani, Meng Zhang, Gokilavani Thangavel, Yennifer Mata‐Sucre, Thomas Lux, José Antonio Campoy, Magdalena Marek, Bruno Hüettel, Hequan Sun, Klaus Mayer, Korbinian Schneeberger, André Marques

2024Nature Plants32 citationsDOIOpen Access PDF

Abstract

Centromeres strongly affect (epi)genomic architecture and meiotic recombination dynamics, influencing the overall distribution and frequency of crossovers. Here we show how recombination is regulated and distributed in the holocentric plant Rhynchospora breviuscula, a species with diffused centromeres. Combining immunocytochemistry, chromatin analysis and high-throughput single-pollen sequencing, we discovered that crossover frequency is distally biased, in sharp contrast to the diffused distribution of hundreds of centromeric units and (epi)genomic features. Remarkably, we found that crossovers were abolished inside centromeric units but not in their proximity, indicating the absence of a canonical centromere effect. We further propose that telomere-led synapsis of homologues is the feature that best explains the observed recombination landscape. Our results hint at the primary influence of mechanistic features of meiotic pairing and synapsis rather than (epi)genomic features and centromere organization in determining the distally biased crossover distribution in R. breviuscula, whereas centromeres and (epi)genetic properties only affect crossover positioning locally.

Topics & Concepts

SynapsisCentromereMeiosisBiologyRecombinationGeneticsChromatinEvolutionary biologyChromosomal crossoverCrossoverChromosomeGeneComputer scienceArtificial intelligencePhotosynthetic Processes and MechanismsChromosomal and Genetic VariationsPlant Reproductive Biology
Meiotic recombination dynamics in plants with repeat-based holocentromeres shed light on the primary drivers of crossover patterning | Litcius