Abstract
Heat-induced chalkiness of rice grains is a major concern for rice production, particularly with respect to climate change. Although the formation of chalkiness in the endosperm is suppressed by nitrogen, little is known about the cell-specific dynamics of this process. Here, using picolitre pressure-probe electrospray-ionization mass spectrometry together with transmission electron microscopy and turgor measurements, we examine heat-induced chalkiness in single endosperm cells of intact rice seeds produced under controlled environmental conditions. Exposure to heat stress decreased turgor pressure and increased the cytosolic accumulation of sugars, glutathione, and amino acids, particularly cysteine. Heat stress also led to a significant enlargement of the protein storage vacuoles but with little accumulation of storage proteins. Crucially, this heat-induced partial arrest of amyloplast development led to formation of chalkiness. Whilst increased nitrogen availability also resulted in increased accumulation of amino acids, there was no decrease in turgor pressure. The heat-induced accumulation of cysteine and glutathione was much less marked in the presence of nitrogen, and storage proteins were produced without chalkiness. These data provide important information on the cell dynamics of heat acclimation that underpin the formation of chalkiness in the rice endosperm. We conclude that rice seeds employ multiple strategies to mitigate the adverse effects of heat stress in a manner that is dependent on nitrogen availability, and that the regulation of protein synthesis may play a crucial role in optimizing organelle compartmentation during heat adaption.
Highlights
Grain chalkiness is a critical trait that determines the quality high temperature during the grain-filling stage (Tashiro and of rice (Hoshikawa, 1989)
We used our newly developed on-site cell-specific analysis combined with timecourse TEM observations to test our hypothesis regarding the heat-induced formation of rice chalkiness, in order to identify the exact source of the air spaces formed in the cells.We found that heat decreased the rate of protein synthesis in the cells as a seed survival strategy, and numerous enlarged protein storage vacuoles (PSVs) were preserved among the loosely packed starch granules in the cytosol, which resulted in the chalky appearance
Heat stress induces the formation of chalkiness in part of the rice endosperm (Hoshikawa, 1989;Tashiro andWardlaw, 1991), whilst N supply reduces chalkiness even at high temperature (Wakamatsu et al, 2008).The regulation of the rate of protein synthesis is predicted to be associated with the extent of formation of chalkiness through a disruption of both amyloplast and protein bodies (PBs) development, the exact metabolic changes occurring under heat conditions in terms of the structural modifications have not been directly determined
Summary
Grain chalkiness is a critical trait that determines the quality high temperature during the grain-filling stage (Tashiro and of rice (Hoshikawa, 1989). One of the major forms of chalky rice, called ‘white-back kernel’, which is frequently induced by exposure to high temperatures at the early ripening stage, exhibits chalkiness in the outer endosperm regions longitudinally aligned along the dorsal side of the kernels, where a greater abundance of protein bodies (PBs) are distributed than in the ventral side (Ellis et al, 1987; Hoshikawa, 1989).Whiteback kernel is known to be decreased by supplying nitrogen (N) prior to the onset of heat stress (Wakamatsu et al, 2008). Our current understanding of heat-induced rice chalkiness relies on analyses at the tissue level, and the underlying mechanisms in cellular metabolism that lead to the formation of air spaces remains unclear. The roles of N during the heat response have not been spatially addressed at the metabolite level
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