Litcius/Paper detail

Dark respiration explains nocturnal stomatal conductance in rice regardless of drought and nutrient stress

Yulin Yan, Youngryel Ryu, Benjamin Dechant, Bolun Li, Jongmin Kim

2023Plant Cell & Environment13 citationsDOI

Abstract

Abstract The ecological mechanism underlying nocturnal stomatal conductance ( g sn ) in C 3 and C 4 plants remains elusive. In this study, we proposed a ‘coordinated leaf trait’ hypothesis to explain g sn in rice plants. We conducted an open‐field experiment by applying drought, nutrient stress and the combined drought–nutrient stress. We found that g sn was neither strongly reduced by drought nor consistently increased by nutrient stress. With the aforementioned multiple abiotic stressors considered as random effects, g sn exhibited a strong positive correlation with dark respiration ( R n ). Notably, g sn primed early morning (5:00–7:00) photosynthesis through faster stomatal response time. This photosynthesis priming effect diminished after mid‐morning (9:00). Leaves were cooled by g sn ‐derived transpiration. However, our results clearly suggest that evaporative cooling did not reduce dark respiration cost. Our results indicate that g sn is more closely related to carbon respiration and assimilation than water and nutrient availability, and that dark respiration can explain considerable variation of g sn .

Topics & Concepts

PhotosynthesisRespirationTranspirationNutrientStomatal conductanceNocturnalAbiotic componentBiologyMorningAcclimatizationBotanyAgronomyHorticultureEnvironmental scienceEcologyPlant Water Relations and Carbon DynamicsPlant responses to elevated CO2Ecology and Vegetation Dynamics Studies