Journal
FUNCTIONAL PLANT BIOLOGY
Volume 39, Issue 5, Pages 394-401Publisher
CSIRO PUBLISHING
DOI: 10.1071/FP12020
Keywords
intercellular spaces; leaf dry weight; leaf specific mass; leaf volume; Quercus ilex L.; vein density
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Hydraulic conductance (K-leaf) and morpho-anatomical parameters were measured in sun and shade Quercus ilex L. (holm oak) leaves. Sun leaves had lower surface area (A(leaf)) and volume (V-leaf) and higher specific mass (leaf mass per area, LMA) than shade leaves. Transpiration rate and K-leaf scaled by A(leaf) (K-leaf_area) were 2-fold higher in sun than in shade leaves. K-leaf_area was not correlated with vein density or stomatal density, which were found to be similar in the two leaf types. Values of K-leaf scaled by V-leaf or leaf dry weight (K-leaf_dw) were only 40% higher in sun than in shade leaves, suggesting that structural changes of Holm oak leaves acclimating to different light intensities enhance water transport to the unit evaporating leaf surface area, while maintaining more constant hydraulic supply to mesophyll cells and carbon costs of the water transport system. Sun leaves had higher K-leaf_dw and LMA than shade ones, indicating that high LMA resulted from resource allocation involved in both water transport and structural rigidity. Future studies of the intra- and inter-specific variability of mass-based hydraulic efficiency might provide important insights into leaf hydraulics and carbon economy. K-leaf_dw might prove to be an important driver of plant acclimation and adaptation to the environment.
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