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ABSTRACTAs the single link between leaves and the rest of the plant, petioles must develop conductive tissues according to the water influx and sugar outflow of the leaf lamina. A scaling relationship between leaf area and anatomical traits of xylem and phloem is expected to improve the efficiency of these tissues. However, the different constraints compromising the functionality of both tissues (e.g., risk of cavitation) must not be disregarded. Additionally, deciduous and evergreen plants may have different strategies to produce and package their petiole conduits to cope with environmental restrictions. We explored in 33 oak species the relationships between petiole anatomical traits, leaf area, stomatal conductance, and photosynthesis rate. Results showed allometric scaling between anatomical structure of xylem and phloem with leaf area. We also found correlations between photosynthesis rate, stomatal conductance, and anatomical traits in the petiole. The main novelty is how oaks present a different strategy depending on the leaf habit. Deciduous species tend to increase their diameters to achieve greater leaf‐specific conductivity. By contrast, evergreen oaks develop larger xylem conductive areas for a given leaf area than deciduous ones. This trade‐off between safety‐efficiency in petioles has never been attributed to the leaf habit of the species.
580, 570, photosynthesis, conductive tissues, petioles, leaf tissue analysis, Plant Transpiration, Phloem, Plant Leaves, Quercus, stomatal conductance, Xylem, Plant Stomata, Photosynthesis, leaf habit, hydraulic conductivity
580, 570, photosynthesis, conductive tissues, petioles, leaf tissue analysis, Plant Transpiration, Phloem, Plant Leaves, Quercus, stomatal conductance, Xylem, Plant Stomata, Photosynthesis, leaf habit, hydraulic conductivity
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