Abstract
Whole-genome duplication through the formation of diploid gametes is a major route for polyploidization, speciation, and diversification in plants. The prevalence of polyploids in adverse climates led us to hypothesize that abiotic stress conditions can induce or stimulate diploid gamete production. In this study, we show that short periods of cold stress induce the production of diploid and polyploid pollen in Arabidopsis (Arabidopsis thaliana). Using a combination of cytological and genetic analyses, we demonstrate that cold stress alters the formation of radial microtubule arrays at telophase II and consequently leads to defects in postmeiotic cytokinesis and cell wall formation. As a result, cold-stressed male meiosis generates triads, dyads, and monads that contain binuclear and polynuclear microspores. Fusion of nuclei in binuclear and polynuclear microspores occurs spontaneously before pollen mitosis I and eventually leads to the formation of diploid and polyploid pollen grains. Using segregation analyses, we also found that the majority of cold-induced dyads and triads are genetically equivalent to a second division restitution and produce diploid gametes that are highly homozygous. In a broader perspective, these findings offer insights into the fundamental mechanisms that regulate male gametogenesis in plants and demonstrate that their sensitivity to environmental stress has evolutionary significance and agronomic relevance in terms of polyploidization.
Highlights
We show that short periods of cold stress induce the production of diploid and polyploid pollen in Arabidopsis (Arabidopsis thaliana)
We show that short periods of cold stress (1–40 h at 4°C–5°C) in flowering Arabidopsis plants induce restitution of the male meiotic cell division, leading to the formation of diploid, triploid, and tetraploid spores
We found that short periods of low temperature disrupt the organization and/or maintenance of the telophase II-specific internuclear radial microtubule arrays (RMAs), without affecting the segregation of meiotic chromosomes, and induce defects in internuclear organelle localization and callose deposition at the end of meiosis II (MII), typically leading to defects in postmeiotic cell plate formation and delaying the developmental progression of the meiocyte upon transfer to normal conditions (Fig. 8)
Summary
Whole-genome duplication through the formation of diploid gametes is a major route for polyploidization, speciation, and diversification in plants. Using a combination of cytological and genetic analyses, we demonstrate that cold stress alters the formation of radial microtubule arrays at telophase II and leads to defects in postmeiotic cytokinesis and cell wall formation. Cold-stressed male meiosis generates triads, dyads, and monads that contain binuclear and polynuclear microspores. We found that the majority of cold-induced dyads and triads are genetically equivalent to a second division restitution and produce diploid gametes that are highly homozygous. The spontaneous formation of polyploid species through whole-genome duplication is a major force driving diversification and speciation in plant evolution (Wang et al, 2004).
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