Modifications of plant hydraulics and shoot resistances (R-shoot) induced by water withholding followed by rewatering, and their relationships with plant water status, leaf gas exchange and water use efficiency at the leaf level, were investigated in pot-grown and field-grown, own-rooted Syrah grapevines in an arid climate. Water stress induced anisohydric behavior, gradually reducing stomatal conductance (g(s)) and leaf photosynthesis (A) in response to decreasing midday stem water potential (psi(s)). Water stress also rapidly increased intrinsic water-use efficiency (A/g(s)); this effect persisted for many days after rewatering. Whole-plant (K-plant), canopy (K-canopy), shoot (Kshoot) and leaf (K-leaf) hydraulic conductances decreased during water stress, in tune with the gradual decrease in psi(s), leaf gas exchange and whole plant water use. Water-stressed vines also had a lower psi gradient between stem and leaf (Delta psi(l)), which was correlated with lower leaf transpiration rate (E). E and Delta psi(l) increased with increasing vapour pressure deficit (VPD) in non-stressed control vines but not in stressed vines. Perfusion of xylem-mobile dye showed that water flow to petioles and leaves was substantially reduced or even stopped under moderate and severe drought stress. Leaf blade hydraulic resistance accounted for most of the total shoot resistance. However, hydraulic conductance of the whole root system (K-root) was not significantly reduced until water stress became very severe in pot-grown vines. Significant correlations between K-plant, K-canopy and psi(s), K-canopy and leaf gas exchange, K-leaf and psi(s), and Kleaf and A support a link between water supply, leaf water status and gas exchange. Upon re-watering,psi(s) recovered faster than gas exchange and leaf-shoot hydraulics. A gradual recovery of hydraulic functionality of plant organs was also observed, the leaves being the last to recover after rewatering. In pot-grown vines, K-canopy recovered rather quickly following restoration of psi(s), although gas exchange recovery did not directly depend on recovery of K-canopy. In field-grown vines, recovery of water status, gas exchange and hydraulic functionality was slower than in pot-grown plants, and low gs after rewatering was related to sustained decreased K-plant, K-canopy and K-shoot and lower water transport to leaves. These results suggest that caution should be exercised when scaling up conclusions from experiments with small pot-grown plants to field conditions.

• 出版日期2017-9