Abstract
BackgroundPlants respond to changes in vapour pressure deficit (VPD) between the leaf and the atmosphere through changes in stomatal response, which can consequently affect transpiration, photosynthesis, and leaf-level water use efficiencies. With projected warmer air temperatures, changes in rainfall distribution and altered VPD in future climates, it is important to understand the potential effect of VPD on leaf-level physiology of field-grown crops. The aim of this study was to assess the impact of altered VPD on leaf-level physiology of field-grown cotton to improve the current understanding of the plant-by-environment interaction, thereby contributing to validation and improvement of physiological and yield response models. Different VPD environments in the field were generated by planting cotton on three dates within the sowing window (early-season (S1) = 5th October 2011; mid-season (S2) = 9th November 2011; and late-season (S3) = 30th November 2011). VPD was also modified by altering crop irrigations.ResultsVPDL accounted for the largest proportion of the explained variation in both stomatal conductance (32%∼39%) and photosynthetic (16%∼29%) responses of cotton. Generally, smaller percentages of variation were attributed to other main factors such as the individual plant (Plant), and accumulated temperature stress hours (ASH; a measure of plant water status over time) and interactive factors, including leaf vapour pressure deficit (VPDL) × Plant and Plant × ASH; however, a proportion of variation was unexplained. In addition, the Asat/E (instantaneous transpiration efficiency, ITE) model developed based on cotton grown in the glasshouse was applied to cotton grown in the field. We found that the modelled Asat/E and field-measured Asat/E were very similar, suggesting that the mechanistic basis for ITE was similar in both environments.ConclusionsThis study highlights the importance of accounting for VPD in climate change research, given that stomata are highly responsive to changes in VPD. This experiment provides a basis for physiology and production models, particularly in terms of cotton response to projected climatic environments.
Highlights
With global warming, there are likely to be increases in both daytime and night-time temperatures, with nighttime temperatures warming more quickly than daytime temperatures (Cox et al 2020; IPCC 2014, 2021)
Treatment effects on cotton physiology Using the variable vapour pressure deficit (VPD) data set, gs-sat and Photosynthetic rate at saturating light (Asat) declined in response to rising V PDL
Summary statistics demonstrated that sowing time and water treatments generated variation in VPD and temperature, which enable a broad range of environmental conditions under which gas exchange responses of cotton were measured
Summary
There are likely to be increases in both daytime and night-time temperatures, with nighttime temperatures warming more quickly than daytime temperatures (Cox et al 2020; IPCC 2014, 2021). Greater transpiration rates at high VPD will lead to increased water consumption by plants during the season, and it is necessary to understand the impacts of VPD on the physiology of field-grown cotton, in conjunction with developing genotypes that use less water in high VPD environments (Devi and Reddy 2018; Shekoofa et al 2021). With projected warmer air temperatures, changes in rainfall distribution and altered VPD in future climates, it is important to understand the potential effect of VPD on leaf-level physiology of field-grown crops. The aim of this study was to assess the impact of altered VPD on leaf-level physiology of field-grown cotton to improve the current understanding of the plant-by-environment interaction, thereby contributing to validation and improvement of physiological and yield response models.
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