Fast dehydration reduces bundle sheath conductance in C maize and sorghum.

In the face of anthropogenic warming, drought poses an escalating threat to food production. C plants offer promise in addressing this threat. C leaves operate a biochemical CO concentrating mechanism that exchanges metabolites between two partially isolated compartments (mesophyll and bundle sheath), which confers high-productivity potential in hot climates boosting water use efficiency. However, when C leaves experience dehydration, photosynthesis plummets. This paper explores the physiological mechanisms behind this decline. In a fast dehydration experiment, we measured the fluxes and isotopic composition of water and CO in the gas exchanged by leaves, and we interpreted results using a novel biochemical model and analysis of elasticity. Our findings show that, while CO supply to the mesophyll and to the bundle sheath persisted during dehydration, there was a decrease in CO conductance at the bundle sheath-mesophyll interface. We interpret this as causing a slowdown of intercellular metabolite exchange - an essential feature of C photosynthesis. This would impede the supply of reducing power to the bundle sheath, leading to phosphoglycerate accumulation and feedback inhibition of Rubisco carboxylation. The interplay between this rapid sensitivity and the effectiveness of coping strategies that C plants deploy may be an overlooked driver of their competitive performance.