Elevated temperature increases meiotic crossover frequency via the interfering (Type I) pathway in Arabidopsis thaliana.

Jennifer L Modliszewski,Hongkuan Wang,Jiyue Huang,Hong Ma,Scott M Lewis,Ashley R Albright,Yingxiang Wang,Alexander R Bennett,Gregory P Copenhaver,Gregory S Barsh

doi:10.1371/journal.pgen.1007384

Jennifer L Modliszewski, Hongkuan Wang + Show 8 more

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https://doi.org/10.1371/journal.pgen.1007384

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Abstract

For most eukaryotes, sexual reproduction is a fundamental process that requires meiosis. In turn, meiosis typically depends on a reciprocal exchange of DNA between each pair of homologous chromosomes, known as a crossover (CO), to ensure proper chromosome segregation. The frequency and distribution of COs are regulated by intrinsic and extrinsic environmental factors, but much more is known about the molecular mechanisms governing the former compared to the latter. Here we show that elevated temperature induces meiotic hyper-recombination in Arabidopsis thaliana and we use genetic analysis with mutants in different recombination pathways to demonstrate that the extra COs are derived from the major Type I interference sensitive pathway. We also show that heat-induced COs are not the result of an increase in DNA double-strand breaks and that the hyper-recombinant phenotype is likely specific to thermal stress rather than a more generalized stress response. Taken together, these findings provide initial mechanistic insight into how environmental cues modulate plant meiotic recombination and may also offer practical applications.

Highlights

Reproducing species use a specialized form of cell division known as meiosis to create haploid gametes from diploid progenitor cells [1]
During meiosis, programmed Double Strand Breaks (DSBs) occur on each chromosome, which allows DNA to be exchanged between chromosome pairs, resulting in crossovers (COs)
The majority (~85%) of COs are derived from the Type I pathway in Arabidopsis and are sensitive to the placement of adjacent crossovers; Type II COs make up most of the remainder of COs and are not sensitive to the placement of adjacent COs [14,15]

Summary

Introduction

Reproducing species use a specialized form of cell division known as meiosis to create haploid gametes from diploid progenitor cells (or a similar genomic reduction in polyploids) [1]. A defining feature of meiosis is the exchange, or crossing-over, of DNA between homologous chromosomes. This exchange results in novel allelic combinations not present in either set of parental chromosomes. Crossovers (COs) are critical for stabilizing homologous chromosome pairing, ensuring proper segregation of homologous chromosomes during meiosis. In the absence of COs, chromosomes segregate randomly, resulting in imbalances in chromosome numbers in the gametes, and aneuploidy in progeny. Aneuploidy may affect the fertility of the organism and the viability and fertility of its offspring. The frequency and distribution of COs in the genome are genetically regulated

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