The ‘hydrology’ of leaves: co‐ordination of structure and function in temperate woody species

Sack, Lawren; Cowan, Peter D.; Jaikumar, Nikhil S.; Holbrook, N. Michèle

doi:10.1046/j.0016-8025.2003.01058.x

Cited by 682 publications

(818 citation statements)

References 99 publications

(172 reference statements)

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“…Across plant species, R leaf is negatively coordinated with peak rates of gas exchange (Aasamaa et al, 2001;Sack et al, 2003b). The importance of the vein system in determining R leaf , as found in this study, suggests potentially important functional consequences at the whole-leaf and plant level for the diversity of leaf venation architecture in angiosperms (Roth-Nebelsick et al, 2001), i.e.…”

Section: Leaf Hydraulic Designmentioning

confidence: 64%

“…The hydraulic resistance remaining was considered that of the major veins (R major veins ), and R minor veins was calculated as R venation ÿ R major veins . Because the petiole must be severed and recut so that it can be sealed to the flow meter, R petiole was estimated using the resistance of the petiole segment divided by its length and then multiplied by the intact petiole length, as estimated using regressions of petiole length versus leaf area (Sack et al, 2003b). Estimates of R petiole were normalized by leaf area to have the same units as R lamina .…”

Section: Partitioning Of Leaf Hydraulic Resistancementioning

confidence: 99%

“…The leaf hydraulic resistance (R leaf ) constitutes a significant hydraulic bottleneck, correlates with leaf structure, and apparently constrains gas exchange (Tyree and Zimmermann, 2002;Sack et al, 2003b;Sack and Tyree, 2004). R leaf is an aggregate measure; once past the petiole, water flows through a reticulate network of veins, across the bundle sheath cells, and through or around mesophyll cells before evaporation and diffusion from the stomata (Esau, 1965).…”

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Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

2004

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Leaves constitute a substantial fraction of the total resistance to water flow through plants. A key question is how hydraulic resistance within the leaf is distributed among petiole, major veins, minor veins, and the pathways downstream of the veins. We partitioned the leaf hydraulic resistance (R leaf ) for sugar maple (Acer saccharum) and red oak (Quercus rubra) by measuring the resistance to water flow through leaves before and after cutting specific vein orders. Simulations using an electronic circuit analog with resistors arranged in a hierarchical reticulate network justified the partitioning of total R leaf into component additive resistances. On average 64% and 74% of the R leaf was situated within the leaf xylem for sugar maple and red oak, respectively. Substantial resistance-32% and 49%-was in the minor venation, 18% and 21% in the major venation, and 14% and 4% in the petiole. The large number of parallel paths (i.e. a large transfer surface) for water leaving the minor veins through the bundle sheath and out of the leaf resulted in the pathways outside the venation comprising only 36% and 26% of R leaf . Changing leaf temperature during measurement of R leaf for intact leaves resulted in a temperature response beyond that expected from changes in viscosity. The extra response was not found for leaves with veins cut, indicating that water crosses cell membranes after it leaves the xylem. The large proportion of resistance in the venation can explain why stomata respond to leaf xylem damage and cavitation. The hydraulic importance of the leaf vein system suggests that the diversity of vein system architectures observed in angiosperms may reflect variation in whole-leaf hydraulic capacity.Water flow through the leaf is one of the most important but least understood components of the whole-plant hydraulic system. The leaf hydraulic resistance (R leaf ) constitutes a significant hydraulic bottleneck, correlates with leaf structure, and apparently constrains gas exchange (Tyree and Zimmermann, 2002;Sack et al., 2003b;Sack and Tyree, 2004). R leaf is an aggregate measure; once past the petiole, water flows through a reticulate network of veins, across the bundle sheath cells, and through or around mesophyll cells before evaporation and diffusion from the stomata (Esau, 1965). Recent work has focused primarily on measurement of R leaf and its functional correlates. Few studies have attempted to determine quantitatively how the various components of the water flow pathway through the leaf contribute to its total resistance.Partitioning of R leaf is a crucial step for understanding leaf hydraulic design. Cavitation in the leaf vein xylem can substantially increase R leaf , as can physical damage to major veins; both drive reductions of leaf water potential and gas exchange Nardini et al., 2001Cochard et al., 2002;Huve et al., 2002;Sack et al., 2003a). These observations suggest that a large proportion of R leaf is situated in the veins. However, a number of studies have reported that most of the leaf resista...

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Section: Leaf Hydraulic Designmentioning

confidence: 64%

Section: Partitioning Of Leaf Hydraulic Resistancementioning

confidence: 99%

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confidence: 99%

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Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

2004

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“…However, we note that a lower K stem does not necessarily imply a lower K plant ; indeed, a higher leaf hydraulic conductance (K leaf ) can easily compensate. Recent work has shown the leaf is a critical bottleneck in the whole-plant hydraulic pathway, accounting for greater than 30 per cent of whole plant resistance, and that leaves have steeper hydraulic vulnerability curves than stem [96]. Consequently, K leaf is a strong determinant of K plant , especially when leaves begin to dehydrate during transpiration or incipient drought [97][98][99][100][101].…”

Section: Hydraulic Feedbacks On Leaf Physiologymentioning

confidence: 99%

Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics

Osborne

Sack²

2012

Phil. Trans. R. Soc. B

183

193

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C 4 photosynthesis has evolved more than 60 times as a carbon-concentrating mechanism to augment the ancestral C 3 photosynthetic pathway. The rate and the efficiency of photosynthesis are greater in the C 4 than C 3 type under atmospheric CO 2 depletion, high light and temperature, suggesting these factors as important selective agents. This hypothesis is consistent with comparative analyses of grasses, which indicate repeated evolutionary transitions from shaded forest to open habitats. However, such environmental transitions also impact strongly on plant -water relations. We hypothesize that excessive demand for water transport associated with low CO 2 , high light and temperature would have selected for C 4 photosynthesis not only to increase the efficiency and rate of photosynthesis, but also as a water-conserving mechanism. Our proposal is supported by evidence from the literature and physiological models. The C 4 pathway allows high rates of photosynthesis at low stomatal conductance, even given low atmospheric CO 2 . The resultant decrease in transpiration protects the hydraulic system, allowing stomata to remain open and photosynthesis to be sustained for longer under drying atmospheric and soil conditions. The evolution of C 4 photosynthesis therefore simultaneously improved plant carbon and water relations, conferring strong benefits as atmospheric CO 2 declined and ecological demand for water rose.

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“…Mesophyll tissue thickness and the ratio of spongy to palisade mesophyll tissue thickness are also both correlated with K leaf (for a comprehensive review of anatomical determinants of K leaf , see Sack et al, 2015). Additionally, across species, mesophyll anatomy, venation architecture, stomatal conductance, and K leaf tend to be intercorrelated (Sack et al, 2003;Aasamaa et al, 2005;Brodribb and Jordan, 2008;Carins Murphy et al, 2012Brodribb et al, 2013;Feild and Brodribb, 2013). Thus, many of the key anatomical traits that may influence K ox tend to be highly correlated across species , making it difficult to infer causal relationships.…”

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How Does Leaf Anatomy Influence Water Transport outside the Xylem?

et al. 2015

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Leaves are arguably the most complex and important physicobiological systems in the ecosphere. Yet, water transport outside the leaf xylem remains poorly understood, despite its impacts on stomatal function and photosynthesis. We applied anatomical measurements from 14 diverse species to a novel model of water flow in an areole (the smallest region bounded by minor veins) to predict the impact of anatomical variation across species on outside-xylem hydraulic conductance (K ox ). Several predictions verified previous correlational studies: (1) vein length per unit area is the strongest anatomical determinant of K ox , due to effects on hydraulic pathlength and bundle sheath (BS) surface area; (2) palisade mesophyll remains well hydrated in hypostomatous species, which may benefit photosynthesis, (3) BS extensions enhance K ox ; and (4) the upper and lower epidermis are hydraulically sequestered from one another despite their proximity. Our findings also provided novel insights: (5) the BS contributes a minority of outside-xylem resistance; (6) vapor transport contributes up to two-thirds of K ox ; (7) K ox is strongly enhanced by the proximity of veins to lower epidermis; and (8) K ox is strongly influenced by spongy mesophyll anatomy, decreasing with protoplast size and increasing with airspace fraction and cell wall thickness. Correlations between anatomy and K ox across species sometimes diverged from predicted causal effects, demonstrating the need for integrative models to resolve causation. For example, (9) K ox was enhanced far more in heterobaric species than predicted by their having BS extensions. Our approach provides detailed insights into the role of anatomical variation in leaf function.

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The ‘hydrology’ of leaves: co‐ordination of structure and function in temperate woody species

Cited by 682 publications

References 99 publications

Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics

How Does Leaf Anatomy Influence Water Transport outside the Xylem?

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The ‘hydrology’ of leaves: co‐ordination of structure and function in temperate woody species

Cited by 682 publications

References 99 publications

Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

Hydraulic Analysis of Water Flow through Leaves of Sugar Maple and Red Oak

Evolution of C 4 plants: a new hypothesis for an interaction of CO 2 and water relations mediated by plant hydraulics

How Does Leaf Anatomy Influence Water Transport outside the Xylem?

Contact Info

Product

Resources

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Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics