Desert dogma revisited: coupling of stomatal conductance and photosynthesis in the desert shrub, <i>Larrea tridentata</i>

TitleDesert dogma revisited: coupling of stomatal conductance and photosynthesis in the desert shrub, Larrea tridentata
Publication TypeJournal Article
Year of Publication2002
AuthorsOgle K., Reynolds J.F.
JournalPlant, Cell and Environment
Date Published2002
Call Number00791
Keywordsarticle, articles, journal, journals, Larrea, evapotranspiration, Larrea, photosynthesis, Larrea, transpiration, Larrea,gas-exchange, model, A-Season, model, Ball-Berry, model, Larrea, model, Leuning, model, Pitman, photosynthesis, Larrea, physiology, Larrea
AbstractThe success of the desert shrub Larrea tridentata (creosotebush) has been largely attributed to temperature acclimation and stomatal control of photosynthesis (A) under drought stress. However, there is a paucity of field data on these relationships. To address this void, we conducted a joint field and modeling study that encompassed a diverse set of environmental conditions. At a Larrea-dominated site in southern New Mexico we manipulated soil moisture during the growing season over a 2-year period and measured plant pre-dawn water potential (Øpd), stomatal conductance (g) and A of individual shrubs. We used these data to develop a semi-mechanistic photosynthesis model (A-Season) that explicitly couples internal CO2 (Ci) and g. Vapor pressure deficit (VPD) and Øpd affect instantaneous g in a manner that is consistent with a biophysical model of stomatal regulation of leaf water potential. Ci is modeled as a function of g, derived from a simplification of a typical A-Ci curve. After incorporating the effects of growing temperature on stomatal behavior, the model was able to capture the large diurnal fluctuations in A, g and Ci and the observed hysteresis in g versus Ci dynamics. Our field data and application of the A-Season model suggest that dogma attributed to Larrea's success is supported with regard to stomatal responses to VPD and Øpd but not for mechanisms of temperature acclimation and CO2 demand.
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