Increased contribution of wheat nocturnal transpiration to daily water use under drought

Increasing evidence suggests that in crops, nocturnal water use could represent 30% of daytime water consumption, particularly in semi‐arid and arid areas. This raises the questions of whether nocturnal transpiration rates (TR_N) are (1) less influenced by drought than daytime TR (TR_D), (2) increased by higher nocturnal vapor pressure deficit (VPD_N), which prevails in such environments and (3) involved in crop drought tolerance. In this investigation, we addressed those questions by subjecting two wheat genotypes differing in drought tolerance to progressive soil drying under two long‐term VPD_N regimes imposed under naturally fluctuating conditions. A first goal was to characterize the response curves of whole‐plant TR_N and TR_N/TR_D ratios to progressive soil drying. A second goal was to examine the effect of VPD_N increase on TR_N response to soil drying and on 13 other developmental traits. The study revealed that under drought, TR_N was not responsive to progressive soil drying and – intriguingly – that TR_N seemingly increased with drought under high VPD_N consistently for the drought‐sensitive genotype. Because TR_D was concomitantly decreasing with progressive drought, this resulted in TR_N representing up to 70% of TR_D at the end of the drydown. In addition, under drought, VPD_N increase was found not to influence traits such as leaf area or stomata density. Overall, those findings indicate that TR_N contribution to daily water use under drought might be much higher than previously thought, that it is controlled by specific mechanisms and that decreasing TR_N under drought might be a valuable trait for improving drought tolerance.