Effects of the interaction between drought and shade on water relations, gas exchange and morphological traits in cork oak (Quercus suber L.) seedlings

The combined effect of drought and light on different physiological and biochemical traits was assessed in cork oak (Quercus suber L.) seedlings grown under two levels of light availability and submitted to a long-standing drought. Watering was withdrawn after germination and seedlings were allowed to dry to a water content of ca. 50% of field capacity. At this point, water-stressed seedlings were grown under moderate drought and two light regimes: high light (HL-50%) and low light (LL-2%). Soil water in control plants was kept close to field capacity (90-100%) for both light environments. Water-relations parameters derived from P-V curves, gas exchange and water status at predawn (Psi(pd)) were evaluated at twice during the experiment. Nitrogen and chlorophyll contents were determined in the same leaves used for the gas exchange measurements. In addition, maximum rate of carboxylation (V-cmax) and electronic transport (J(max)) were derived from A-C-i curves in well-watered seedlings. The variation on moisture availability during the experiment was the same under both light environments. In control plants, Psi(pd) was over -0.3 MPa at the two harvests, while stressed seedlings decreased to -0.9 MPa, with no differences between light treatments. Water stress decreased osmotic potentials at full (Psi pi(100)) and zero turgor (Psi pi(0)). The regressions between both potentials and Psi(pd) showed a higher intercept in shade grown seedlings. This fact will point out the higher osmoregulation capacity in sun seedlings whatever water availability. Nitrogen investment on a per leaf mass (N-mass), chlorophyll content (Chl(mass)) and SLA tended to show a typical pattern of sun-shade acclimation. Thus, the three parameters increased with shade. Only for N-mass there was a significant effect of watering, since water stress increased N-mass. LL plants showed a lower photosynthetic capacity in terms of maximum net photosynthesis at saturating light (A,.), which was related to a decrease in V-cmax and J(max). Both parameters varied with specific leaf area (SLA) in a similar way. The low-light environment brought about a higher nitrogen investment in chlorophyll, while under high-light environment the investment was higher in carboxylation (V-cmax) and electronic transport (F-max). Stomatal conductance to water vapour (g(w)) and A(max) were lower in low-light seedlings independently of watering. In addition, there was a trend to keep higher intrinsic water use efficiency (IWUE) under high light environment. The increase of IWUE under water stress was higher in HL seedlings. This was as consequence of the steeper decline in g(w) as Psi(pd) decreased. The decrease of A(max) with Psi(pd) occurred in a similar way in LL and HL seedlings. Thus, the HL seedlings tended to sustain a higher ability to increase IWUE than LL seedlings when they were submitted to the same water stress. (c) 2005 Elsevier B.V. All rights reserved.