Increasing leaf hydraulic conductance with transpiration rate minimizes the water potential drawdown from stem to leaf

Kevin A. Simonin, Emily Burns, Brendan Choat, Margaret M. Barbour, Todd E. Dawson, Peter J. Franks

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Leaf hydraulic conductance (k leaf) is a central element in the regulation of leaf water balance but the properties of k leaf remain uncertain. Here, the evidence for the following two models for k leaf in well-hydrated plants is evaluated: (i) k leaf is constant or (ii) k leaf increases as transpiration rate (E) increases. The difference between stem and leaf water potential (ΔΨstem-leaf), stomatal conductance (g s), k leaf, and E over a diurnal cycle for three angiosperm and gymnosperm tree species growing in a common garden, and for Helianthus annuus plants grown under sub-ambient, ambient, and elevated atmospheric CO2 concentration were evaluated. Results show that for well-watered plants k leaf is positively dependent on E. Here, this property is termed the dynamic conductance, k leaf(E), which incorporates the inherent k leaf at zero E, which is distinguished as the static conductance, k leaf(0). Growth under different CO2 concentrations maintained the same relationship between k leaf and E, resulting in similar k leaf(0), while operating along different regions of the curve owing to the influence of CO2 on g s. The positive relationship between k leaf and E minimized variation in ΔΨstem-leaf. This enables leaves to minimize variation in Ψleaf and maximize g s and CO2 assimilation rate over the diurnal course of evaporative demand.
    Original languageEnglish
    Pages (from-to)1303-1315
    Number of pages13
    JournalJournal of Experimental Botany
    Volume66
    Issue number5
    DOIs
    Publication statusPublished - 2015

    Keywords

    • leaf water balance
    • plants
    • transpiration

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