Leaf hydraulic conductance and mesophyll conductance are not closely related within a single species |
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Authors: | Karen E. Loucos Kevin A. Simonin Margaret M. Barbour |
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Affiliation: | 1. Centre for Carbon, Water and Food, Faculty of Agriculture and Environment, The University of Sydney, New South Wales, Australia;2. Department of Biology, San Francisco State University, San Francisco, CA, USA |
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Abstract: | Stomata represent one resistor in a series of resistances for carbon and water exchange between the leaf and the atmosphere; the remaining resistors occurring within the leaf, commonly represented as mesophyll conductance to CO2, gm, and leaf hydraulic conductance, kLeaf. Recent studies have proposed that gm and kLeaf may be coordinated across species because of shared pathways. We assessed the correlation between gm and kLeaf within cotton, under growth CO2 partial pressure and irradiance treatments and also with short‐term variation in irradiance and humidity. gm was estimated using two isotopic techniques that allowed partitioning of total gm (Δ13C‐gm) into cell wall plus plasma membrane conductance (Δ18O‐gm) and chloroplast membrane conductance (gcm). A weak correlation was found between Δ13C‐gm and kLeaf only when measured under growth conditions. However, Δ18O‐gm was related to kLeaf under both short‐term environmental variation and growth conditions. Partitioning gm showed that gcm was not affected by short‐term changes in irradiance or correlated with kLeaf, but was strongly reduced at high growth CO2 partial pressure. Thus, simultaneous measurements of gm, kLeaf and gcm suggest independent regulation of carbon and water transport across the chloroplast membrane with limited coordinated regulation across the cell wall and plasma membrane. |
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Keywords: | Gossypium hirsutum carbon transport mesophyll conductance to CO2 stable isotopes water transport |
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