Declining hydraulic efficiency as transpiring leaves desiccate: two types of response*

Abstract

The conductance of transpiring leaves to liquid water (K_leaf) was measured across a range of steady‐state leaf water potentials (Ψ_leaf). Manipulating the transpiration rate in excised leaves enabled us to vary Ψ_leaf in the range −0.1 MPa to less than −1.5 MPa while using a flowmeter to monitor the transpiration stream. Employing this technique to measure how desiccation affects K_leaf in 19 species, including lycophytes, ferns, gymnosperms and angiosperms, we found two characteristic responses. Three of the six angiosperm species sampled maintained a steady maximum K_leaf while Ψ_leaf remained above −1.2 MPa, although desiccation of leaves beyond this point resulted in a rapid decline in K_leaf. In all other species measured, declining Ψ_leaf led to a proportional decrease in K_leaf, such that midday Ψ_leaf of unstressed plants in the field was sufficient to depress K_leaf by an average of 37%. It was found that maximum K_leaf was strongly correlated with maximum CO₂ assimilation rate, while K_leaf = 0 occurred at a Ψ_leaf slightly less negative than at leaf turgor loss. A strong linear correlation across species between Ψ_leaf at turgor loss and Ψ_leaf at K_leaf = 0 raises the possibility that declining K_leaf was related to declining cell turgor in the leaf prior to the onset of vein cavitation. The vulnerability of leaves rehydrating after desiccation was compared with vulnerability of leaves during steady‐state evaporation, and differences between methods suggest that in many cases vein cavitation occurs only as K_leaf approaches zero.