Decline of Leaf Hydraulic Conductance with Dehydration: Relationship to Leaf Size and Venation Architecture

Scoffoni, Christine; Rawls, Michael; McKown, Athena D.; Cochard, Hervé; Sack, Lawren

doi:10.1104/pp.111.173856

Cited by 349 publications

(388 citation statements)

References 102 publications

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“…However, despite the strong potential importance of such trends, there have not been any previous conclusive tests for the scaling of vein traits with leaf size across species. Data from three previous studies with ten or fewer species showed a negative scaling of major vein density with leaf size, and minor vein density was independent of leaf size 8,12,13 . A further study using automated analyses of low-resolution images reported vein density to be independent of leaf size across 339 species 14 ; however, that study measured only a fraction of the vein system and did not distinguish among vein orders 14 and thus, did not allow a conclusive test of general scaling of vein traits.…”

mentioning

confidence: 74%

“…However, the scaling of major vein density provides a direct, hydraulically based mechanism. Modelling and experiments showed that such higher major vein density in smaller leaves in principle provides redundant 'superhighways' for water transport that contribute to drought tolerance by routing water around blockages caused by drought-induced xylem embolism, and additionally protect the hydraulic system from vein damage 8,13 .…”

Section: Discussionmentioning

confidence: 99%

“…Notably, the dicotyledon developmental programme allows for not only large, competitive leaves, but a dramatic range of leaf sizes with a wide spectrum of total vein densities and photosynthetic rates 16 . For example, a large leaf may be selected for a plant of a moist area, for effective light capture and photosynthesis relative to biomass allocation 44 , and a small leaf may be selected in drought-tolerant species 8 ; both may have high minor vein densities, enabling high photosynthetic rates when water is available. The potential of angiosperms to vary strongly in vein density enables dominance in a far greater range of habitats than other plant lineages 3,6,48 , especially as leaf size can adapt independently to optimise other ecological benefits against costs 6,7,44 .…”

Section: Discussionmentioning

confidence: 99%

“…Across species, leaf venation shows enormous structural diversity, the more remarkable because of its shared development and functions. The functional consequences of leaf venation have attracted increasing interest in a widening range of fields, because vein traits, including vein diameters and densities ( = length per leaf area), as well as leaf size are key determinants of plant performance and indeed of shifts in the lineages that dominated the world vegetation through deep time [1][2][3][4][5][6][7][8][9] .…”

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confidence: 99%

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Developmentally based scaling of leaf venation architecture explains global ecological patterns

et al. 2012

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Leaf size and venation show remarkable diversity across dicotyledons, and are key determinants of plant adaptation in ecosystems past and present. Here we present global scaling relationships of venation traits with leaf size. Across a new database for 485 globally distributed species, larger leaves had major veins of larger diameter, but lower length per leaf area, whereas minor vein traits were independent of leaf size. These scaling relationships allow estimation of intact leaf size from fragments, to improve hindcasting of past climate and biodiversity from fossil remains. The vein scaling relationships can be explained by a uniquely synthetic model for leaf anatomy and development derived from published data for numerous species. Vein scaling relationships can explain the global biogeographical trend for smaller leaves in drier areas, the greater construction cost of larger leaves and the ability of angiosperms to develop larger and more densely vascularised lamina to outcompete earlier-evolved plant lineages.

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mentioning

confidence: 74%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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Developmentally based scaling of leaf venation architecture explains global ecological patterns

et al. 2012

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“…Furthermore, we might also expect species exhibiting marked resistance to hydraulic dysfunction to exhibit greater redundancy (Scoffoni et al. 2011), and therefore, poor coordination between liquid‐ and gas‐phase conductive capacities.…”

Section: Discussionmentioning

confidence: 99%

Weak coordination among petiole, leaf, vein, and gas‐exchange traits across Australian angiosperm species and its possible implications

Gleason

Blackman

Chang

et al. 2015

Ecology and Evolution

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Close coordination between leaf gas exchange and maximal hydraulic supply has been reported across diverse plant life forms. However, it has also been suggested that this relationship may become weak or break down completely within the angiosperms. We examined coordination between hydraulic, leaf vein, and gas‐exchange traits across a diverse group of 35 evergreen Australian angiosperms, spanning a large range in leaf structure and habitat. Leaf‐specific conductance was calculated from petiole vessel anatomy and was also measured directly using the rehydration technique. Leaf vein density (thought to be a determinant of gas exchange rate), maximal stomatal conductance, and net CO 2 assimilation rate were also measured for most species (n = 19–35). Vein density was not correlated with leaf‐specific conductance (either calculated or measured), stomatal conductance, nor maximal net CO 2 assimilation, with r 2 values ranging from 0.00 to 0.11, P values from 0.909 to 0.102, and n values from 19 to 35 in all cases. Leaf‐specific conductance calculated from petiole anatomy was weakly correlated with maximal stomatal conductance (r 2 = 0.16; P = 0.022; n = 32), whereas the direct measurement of leaf‐specific conductance was weakly correlated with net maximal CO 2 assimilation (r 2 = 0.21; P = 0.005; n = 35). Calculated leaf‐specific conductance, xylem ultrastructure, and leaf vein density do not appear to be reliable proxy traits for assessing differences in rates of gas exchange or growth across diverse sets of evergreen angiosperms.

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Evolution of leaf structure and drought tolerance in species of Californian Ceanothus

Fletcher

Cui

Callahan

et al. 2018

American J of Botany

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The study of these mechanisms and their evolution gains in urgency because in many ecosystems plant drought tolerance is of major and growing importance for survival (Sheffield and Wood, 2008). California is projected to become drier and to increase by several degrees in mean annual temperature by the end of the 21st century, affecting seasonal water availability, and contributing to summer drought (

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Decline of Leaf Hydraulic Conductance with Dehydration: Relationship to Leaf Size and Venation Architecture

Cited by 349 publications

References 102 publications

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Weak coordination among petiole, leaf, vein, and gas‐exchange traits across Australian angiosperm species and its possible implications

Evolution of leaf structure and drought tolerance in species of Californian Ceanothus

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