Abstract:Crop reproductive success is significantly challenged by heatwaves, which are increasing in frequency and severity globally. Heat-induced male sterility is mainly due to aborted pollen development, but it is not clear whether this is through direct or systemic effects. Here, long-term mild heat (LTMH) treatment, mimicking a heatwave, was applied locally to tomato flowers or whole plants and followed up by cytological, transcriptomic, and biochemical analyses. By analyzing pollen viability, LTMH was shown to ac… Show more
“…Altogether these results show that short-term heat stress causes transient defects during early microspore development leading to a temporal period of male sterility in tomato. Similarly, early microspore development was found to be the developmental stage most sensitive to long-term mild heat treatment in a previous study on tomato ( Xu et al., 2022 ).…”
Susceptibility of the reproductive system to temperature fluctuations is a recurrent problem for crop production under a changing climate. The damage is complex as multiple processes in male and female gamete formation are affected, but in general, particularly pollen production is impaired. Here, the impact of short periods of elevated temperature on male meiosis of tomato (Solanum lycopersicon L.) is reported. Meiocytes in early stage flower buds exposed to heat stress (>35°C) exhibit impaired homolog synapsis resulting in partial to complete omission of chiasmata formation. In the absence of chiasmata, univalents segregate randomly developing unbalanced tetrads and polyads resulting in aneuploid spores. However, most heat-stressed meiotic buds primarily contain balanced dyads, indicating a propensity to execute meiotic restitution. With most meiocytes exhibiting a complete loss of chiasma formation and concomitantly showing a mitotic-like division, heat stress triggers first division restitution resulting in clonal spores. These findings corroborate with the plasticity of male meiosis under heat and establish a natural route for the induction of sexual polyploidization in plants and the engineering of clonal seed.
“…Altogether these results show that short-term heat stress causes transient defects during early microspore development leading to a temporal period of male sterility in tomato. Similarly, early microspore development was found to be the developmental stage most sensitive to long-term mild heat treatment in a previous study on tomato ( Xu et al., 2022 ).…”
Susceptibility of the reproductive system to temperature fluctuations is a recurrent problem for crop production under a changing climate. The damage is complex as multiple processes in male and female gamete formation are affected, but in general, particularly pollen production is impaired. Here, the impact of short periods of elevated temperature on male meiosis of tomato (Solanum lycopersicon L.) is reported. Meiocytes in early stage flower buds exposed to heat stress (>35°C) exhibit impaired homolog synapsis resulting in partial to complete omission of chiasmata formation. In the absence of chiasmata, univalents segregate randomly developing unbalanced tetrads and polyads resulting in aneuploid spores. However, most heat-stressed meiotic buds primarily contain balanced dyads, indicating a propensity to execute meiotic restitution. With most meiocytes exhibiting a complete loss of chiasma formation and concomitantly showing a mitotic-like division, heat stress triggers first division restitution resulting in clonal spores. These findings corroborate with the plasticity of male meiosis under heat and establish a natural route for the induction of sexual polyploidization in plants and the engineering of clonal seed.
Early pollen development is a bottleneck for plant fertility in heatwave conditions, thus affecting yield stability. Mechanisms that protect this process and explain variation in tolerance level between genotypes are poorly understood. Here we show that sepal transpiration in young, still closed, flower buds reduces the impact of heat on developing tomato pollen and that this mechanism is enhanced by the major tomato pollen thermotolerance QTL, qPV11. By direct measurement of the flower bud core temperature and transpiration we show this process, which we term 'flower bud cooling', depends on heat-induced opening of sepal stomata and that the transpiration enhancing effect of qPV11 requires functional stomatal regulation and is specific to the sepals. Large-scale evaluation of populations in both a production field and greenhouse showed that qPV11 improves pollen viability and fruit set in heatwave-affected complex cultivation environments. These findings highlight enhanced flower bud cooling as a naturally evolved protection mechanism against heatwaves and qPV11 as genetic component in the differential regulation of transpiration between reproductive and vegetative tissues and candidate variant for the breeding of climate-resilient tomato cultivars.
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