Abstract
Drought is expected to increase in frequency and severity in many regions in the future, so it is important to improve our understanding of how drought affects plant functional traits and ecological interactions. Imposing experimental water deficits is key to gaining this understanding, but has been hindered by logistic difficulties in maintaining consistently low water availability for plants. Here, we describe a simple method for applying soil water deficits to potted plants in glasshouse experiments. We modified an existing method (the “Snow and Tingey system”) in order to apply a gradual, moderate water deficit to 50 plant species of different life forms (grasses, vines, shrubs, trees). The method requires less maintenance and manual handling compared to other water deficit methods, so it can be used for extended periods of time and is relatively inexpensive to implement. With only a few modifications, it is possible to easily establish and maintain soil water deficits of differing intensity and duration, as well as to incorporate interacting stress factors. We tested this method by measuring physiological responses to an applied water deficit in a subset of 11 tree/shrub species with a wide range of drought tolerances and water-use strategies. For this subgroup of species, stomatal conductance was 2–17 times lower in droughted plants than controls, although only half of the species (5 out of 11) experienced midday leaf water potentials that exceeded their turgor loss (i.e., wilting) point. Leaf temperatures were up to 8°C higher in droughted plants than controls, indicating that droughted plants are at greater risk of thermal damage, relative to unstressed plants. The largest leaf temperature differences (between droughted and well-watered plants) were in species with high rates of water loss. Rapid osmotic adjustment was observed in leaves of five species when drought stress was combined with an experimental heatwave. These results highlight the potential value of further ecological and physiological experiments utilizing this simple water deficit method to study plant responses to drought stress.
Highlights
Drought has been described as the most damaging climate hazard facing our global population (Kogan, 1997)
We designed glasshouse experiments to screen large numbers of plant species (>50 species) in order to identify droughttolerant species for urban plantings in Australian cities, though the drought method we describe can be used in a wide variety of contexts
We show how the gradual, moderate water deficit achieved with the “Snow and Tingey system” affected plant physiological responses in a subset of 11 tree/shrub species
Summary
Drought has been described as the most damaging climate hazard facing our global population (Kogan, 1997). It is expected to increase in frequency and severity in many regions in the future as a result of decreased precipitation and increased evaporation due to global climate change (IPCC, 2018; Naumann et al, 2018; Dey et al, 2019). Twothirds of the global population will be affected by increasing drought (Naumann et al, 2018), which threatens food security (FAO, 2018), forest health (Allen et al, 2010; Choat et al, 2018), and even the global beer supply (Xie et al, 2018). One invaluable and long-used method for examining plant drought responses is the experimental application of controlled water deficits in the glasshouse
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