Abstract

Rising temperatures due to the current climate crisis will soon have devastating impacts on crop performance and resilience. In particular, CO2 assimilation is dramatically limited at high temperatures. CO2 assimilation is accomplished by rubisco, which is inhibited by the binding of inhibitory sugar phosphates to its active site. Plants therefore utilize the essential chaperone rubisco activase (RCA) to remove these inhibitors and enable continued CO2 fixation. However, RCA does not function at moderately high temperatures (42°C), resulting in impaired rubisco activity and reduced CO2 assimilation. We set out to understand temperature-dependent RCA regulation in four different C4 plants, with a focus on the crop plants maize (two cultivars) and sorghum, as well as the model grass Setaria viridis (setaria) using gas exchange measurements, which confirm that CO2 assimilation is limited by carboxylation in these organisms at high temperatures (42°C). All three species express distinct complements of RCA isoforms and each species alters the isoform and proteoform abundances in response to heat; however, the changes are species-specific. We also examine whether the heat-mediated inactivation of RCA is due to biochemical regulation rather than simple thermal denaturation. We reveal that biochemical regulation affects RCA function differently in different C4 species, and differences are apparent even between different cultivars of the same species. Our results suggest that each grass evolved different strategies to maintain RCA function during stress and we conclude that a successful engineering approach aimed at improving carbon capture in C4 grasses will need to accommodate these individual regulatory mechanisms.

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