In recent decades, climate change has led to more frequent and severe drought events, causing serious consequences such as increased forest mortality and significant crop yield losses.... Show moreIn recent decades, climate change has led to more frequent and severe drought events, causing serious consequences such as increased forest mortality and significant crop yield losses. Understanding how drought affects plants, especially economically important herbaceous species, is crucial for predicting and developing drought-resistant crops. To address this issue, this study analyzed a comprehensive dataset of anatomical and hydraulic traits in different genotypes of Arabidopsis thaliana and tomato, including both wild-type and transgenic mutants. The study also investigated the expression of four well-known drought marker genes associated with ABA-dependent and ABA-independent pathways and the impact of overexpressing the JUNGBRUNNEN1 (JUB1) gene on drought response. The findings revealed that each genotype had a unique set of traits to cope with drought, which could be categorized into two response strategies. One group enhanced their drought resistance through traits like a more negative stem P50, thicker intervessel pit membranes, a more lignified inflorescence stem, and a gradual reduction of the low initial stomatal conductance during drought. This strategy enabled them to maintain a relatively high and stable leaf water potential (Ψl). The second group, represented by JUB1 overexpression genotypes, relied primarily on maintaining a high Ψl which is possibly due to osmoprotectant accumulation in leaves, while the other traits have not been recorded. Overall, this research demonstrated the adaptive capabilities of herbaceous plants to drought conditions, highlighting the intraspecific variation in drought responses that underscores the need for a detailed assessment of drought-responsive traits to improve crop yield in a warming world. Show less
Aim The influence of soil properties on photosynthetic traits in higher plants is poorly quantified in comparison with that of climate.We address this situation by quantifying the unique and joint... Show moreAim The influence of soil properties on photosynthetic traits in higher plants is poorly quantified in comparison with that of climate.We address this situation by quantifying the unique and joint contributions to global leaf-trait variation from soils and climate. Location Terrestrial ecosystems world-wide. Methods Using a trait dataset comprising 1509 species from 288 sites, with climate and soil data derived from global datasets, we quantified the effects of 20 soil and 26 climate variables on light-saturated photosynthetic rate (Aarea), stomatal conductance (gs), leaf nitrogen and phosphorus (Narea and Parea) and specific leaf area (SLA) using mixed regression models and multivariate analyses. Results Soil variables were stronger predictors of leaf traits than climatic variables, except for SLA. On average, Narea, Parea and Aarea increased and SLA decreased with increasing soil pH and with increasing site aridity. gs declined and Parea increased with soil available P (Pavail). Narea was unrelated to total soil N. Joint effects of soil and climate dominated over their unique effects on Narea and Parea, while unique effects of soils dominated for Aarea and gs. Path analysis indicated that variation in Aarea reflected the combined independent influences of Narea and gs, the former promoted by high pH and aridity and the latter by low Pavail. Main conclusions Three environmental variables were key for explaining variation in leaf traits: soil pH and Pavail, and the climatic moisture index (the ratio ofprecipitation to potential evapotranspiration). Although the reliability of global soil datasets lags behind that of climate datasets, our results nonetheless provide compelling evidence that both can be jointly used in broad-scale analyses, and that effects uniquely attributable to soil properties are important determinants of leaf photosynthetic traits and rates. A significant future challenge is to better disentangle the covarying physiological, ecological Show less