Hydraulic efficiency and coordination with xylem resistance to cavitation, leaf function, and growth performance among eight unrelated Populus deltoides×Populus nigra hybrids

摘要

Tests were carried out to determine whether variations in the hydraulic architecture of eight Populus deltoides×Populus nigra genotypes could be related to variations in leaf function and growth performance. Measurements were performed in a coppice plantation on 1-year-old shoots under optimal irrigation. Hydraulic architecture was characterized through estimates of hydraulic efficiency (the ratio of conducting sapwood area to leaf area, A_X:A_L; leaf- and xylem-specific hydraulic conductance of defoliated shoots, k_SL and k_SS, respectively; apparent whole-plant leaf-specific hydraulic conductance, k_plant) and xylem safety (water potential inducing 50% loss in hydraulic conductance). The eight genotypes spanned a significant range of k_SL from 2.63 kg s−1 m−2 MPa−1 to 4.18 kg s−1 m−2 MPa−1, variations being mostly driven by k_SS rather than A_X:A_L. There was a strong trade-off between hydraulic efficiency and xylem safety. Values of k_SL correlated positively with k_plant, indicating that high-pressure flowmeter (HPFM) measurements of stem hydraulic efficiency accurately reflected whole-plant water transport efficiency of field-grown plants at maximum transpiration rate. No clear relationship could be found between hydraulic efficiency and either net CO₂ assimilation rates, water-use efficiency estimates (intrinsic water-use efficiency and carbon isotope discrimination against 13C), or stomatal characteristics (stomatal density and stomatal pore area index). Estimates of hydraulic efficiency were negatively associated with relative growth rate. This unusual pattern, combined with the trade-off observed between hydraulic efficiency and xylem safety, provides the rationale for the positive link already reported between relative growth rate and xylem safety among the same eight P. deltoides×P. nigra genotypes.