Hydraulic Sensitivity and Stomatal Regulation of Two Desert Riparian Species

Characterizing plant response to water stresses is among the keys to understanding ecosystem functions. Despite increasing recognition of plant hydraulic and stomatal dynamics not captured by isohydricity, defined as the sensitivity of leaf water potential psi(l) to soil water potential, it remains unclear which plant traits are critical to improved representation of plant hydraulic and stomatal dynamics beyond isohydricity, especially in dryland ecosystems. Here, we examine eco-physiological responses of two typical desert riparian species, Populus euphratica and Tamarix ramosissima, to hydro-meteorological variations. Based on measured hydraulic traits, variations of psi(l), leaf gas exchange, groundwater table, and soil moisture across vertical profiles, we investigated how subsurface hydraulic conditions control plant hydraulic sensitivity and stomatal regulation. We found both species exhibited anisohydric behaviors, which, however, were attributed to drying soil at different depths because of root distributions. The similar anisohydric behaviors also led to distinct stomatal regulation, due to the impact of atmospheric dryness decoupled from soil moisture and different sensitivities of stomatal conductance (g(s)) to psi(l). The latter was found to be dynamic throughout the growing season, which dominated the seasonal variation of g(s) and thus should not be neglected. The results suggest similar anisohydric behaviors could imply diverging hydraulic behaviors as the evaporate demand and flow regime change. Root morphological trait and stomatal sensitivity to psi(l) are identified as keys to characterize responses to water stresses in desert riparian ecosystems. Our findings highlight that improved measurements and representations of these traits could contribute to better assessments of dryland ecosystem functions.

Automated summary

Studying the eco-physiological responses of two desert riparian species, the researchers found that root morphological traits and stomatal sensitivity to leaf water potential are key factors in characterizing water stress responses in dryland ecosystems. Improved measurements and representations of these traits could contribute to better assessments of dryland ecosystem functions.