Abstract
Mesophyll conductance (g(mCO2) ) is one of the most important components in plant photosynthesis. Tropospheric ozone (O(3) ) and drought impair physiological processes, causing damage to photosynthetic systems. However, the combined effects of O(3) and drought on g(mCO2) are still largely unclear. We investigated leaf gas exchange during mid-summer in three Mediterranean oaks exposed to O(3) (ambient [35.2 nmol mol(-1) as daily mean]; 1.4 × ambient) and water treatments (WW [well-watered] and WD [water-deficit]). We also examined if leaf traits (leaf mass per area [LMA], foliar abscisic acid concentration [ABA]) could influence the diffusion of CO(2) inside a leaf. The combination of O(3) and WD significantly decreased net photosynthetic rate (P(N) ) regardless of the species. The reduction of photosynthesis was associated with a decrease in g(mCO2) and stomatal conductance (g(sCO2) ) in evergreen Quercus ilex, while the two deciduous oaks (Q. pubescens, Q. robur) also showed a reduction of the maximum rate of carboxylation (V(cmax) ) and maximum electron transport rate (J(max) ) with decreased diffusive conductance parameters. The reduction of g(mCO2) was correlated with increased [ABA] in the three oaks, whereas there was a negative correlation between g(mCO2) with LMA in Q. pubescens. Interestingly, two deciduous oaks showed a weak or no significant correlation between g(sCO2) and ABA under high O(3) and WD due to impaired stomatal physiological behaviour, indicating that the reduction of P(N) was related to g(mCO2) rather than g(sCO2) . The results suggest that g(mCO2) plays an important role in plant carbon gain under concurrent increases in the severity of drought and O(3) pollution.