Leaf mesophyll conductance and leaf hydraulic conductance: an introduction to their measurement and coordination

Flexas, Jaume; Scoffoni, Christine; Gago, Jorge; Sack, Lawren

doi:10.1093/jxb/ert319

Cited by 190 publications

(217 citation statements)

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“…We note that there are a number of other methods in use for determining K leaf , such as the high-pressure flow method (Yang and Tyree, 1994), the rehydration kinetics method (Brodribb and Holbrook, 2003), and the vacuum pump method (Martre et al, 2001; for review of methods and their contrasting assumptions and difference in simulated flow pathways, see Sack and Tyree, 2005;Flexas et al, 2013). Although several studies have shown that the different methods tend to yield similar maximum K leaf values (Sack et al, 2002;Scoffoni et al, 2008), we highly recommend the use of the evaporative flux method for the most accurate representation of outside-xylem hydraulic pathways, since water movement in this method would most closely resemble that of a naturally transpiring leaf.…”

Section: Computing Integrated Leaf-level Hydraulic Conductancesmentioning

confidence: 99%

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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Section: Computing Integrated Leaf-level Hydraulic Conductancesmentioning

confidence: 99%

How Does Leaf Anatomy Influence Water Transport outside the Xylem?

et al. 2015

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“…Contrary to water transport systems, leaf vein systems show great variation in arrangement, density, vascular bundle features and xylem conduits within the bundles (Sack and Scoffoni, 2012). In grapevine, leaf water movement suggested to be influenced by mesophyll architecture which contributes to water flux in the mesophyll and water evaporation at the cell wall surface (Tomás, 2012;Flexas et al, 2013). On the other hand, Martorell et al (2015) found in two V. vinifera cultivars (Tempranillo and Grenache) that leaf vulnerability at 50 % and 80% loss of K leaf (P50 and P80) as well as the maximum K leaf decreased seasonally by more than 20%.…”

Section: Morpho-hydraulics and Water Transportmentioning

confidence: 99%

Modern viticulture in southern Europe: Vulnerabilities and strategies for adaptation to water scarcity

Costa

Vaz

Escalona

et al. 2016

Agricultural Water Management

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b s t r a c tWater is now considered the most important but vulnerable resource in the Mediterranean region. Nevertheless, irrigation expanded fast in the region (e.g. South Portugal and Spain) to mitigate environmental stress and to guarantee stable grape yield and quality. Sustainable wine production depends on sustainable water use in the wine's supply chain, from the vine to the bottle. Better understanding of grapevine stress physiology (e.g. water relations, temperature regulation, water use efficiency), more robust crop monitoring/phenotyping and implementation of best water management practices will help to mitigate climate effects and will enable significant water savings in the vineyard and winery. In this paper, we focused on the major vulnerabilities and opportunities of South European Mediterranean viticulture (e.g. in Portugal and Spain) and present a multi-level strategy (from plant to the consumer) to overcome region's weaknesses and support strategies for adaptation to water scarcity, promote sustainable water use and minimize the environmental impact of the sector. © 2015 Published by Elsevier B.V. The wine grape industry in south Mediterranean EuropeWorld's wine production are located in a wide geographical Q2and climatic range, often in mid-latitude regions characterized by climate variability and stressful environments, such as the Mediterranean region (Fraga et al., 2013;Lionello et al., 2014). The European Union , is the world's leader in wine production with about 50% of world's vine-growing area and about 60% of total volume of production (USDA, 2014). France, Italy, Spain, Germany and Portugal are the five leading EU wine producers and altogether they represent 90% of EU production (USDA, 2014). Spain has the largest vineyard area in the world (950,541 ha in 2014) with an increasing irrigated area (36% of the total, in 2014) (MAGRAMA, 2014) (Fig. 1). Portugal is the EU's 5th largest wine producer with a total of 6.7 Mhl in 2013 and it has a cultivated area estimated to be about 224,000 ha (IVV, 2015). In 2010, the irrigated area was estimated in 15% of the total area of vineyards (INE, 2010). However, irrigation continued expanding in the recent years in Portugal, in particular in the Alentejo region, and presently, the percentage of irrigated vines should be slightly higher and around 20%. * Corresponding author.E-mail address: miguelc@itqb.unl.pt (J.M. Costa).Mediterranean fresh water resources are under high pressure due to fast-growing population, increased water scarcity, extreme climate variability and intensive water use in agriculture, industry and tourism activities (Lange et al., 2005;Costa et al., 2007; EEA, 2012a,b; Lereboullet et al., 2013a,b;Blum, 2014). Water is now considered by EU experts as the most important but vulnerable resource in the Mediterranean region (EU-ERANETMED, 2014). In addition, climate scenarios for South Mediterranean Europe are not favourable for agriculture. The predicted lower precipitation, higher air and soil temperatures, more frequent and l...

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“…A positive relationship between g m and g s has been reported in several studies (Barbour et al, 2010;Gu et al, 2012;Flexas et al, 2013aFlexas et al, , 2013b, although two studies in wheat (Triticum aestivum) detected no relationship between g m and g s (Jahan et al, 2014;Barbour et al, 2016). It is not yet clear if the coordination between g m and g s is associated with the independent scaling of both diffusional conductances with the overall physiological activity of leaves or if there is an underlying mechanistic relationship we have yet to appreciate (e.g.…”

mentioning

confidence: 95%

“…It is not yet clear if the coordination between g m and g s is associated with the independent scaling of both diffusional conductances with the overall physiological activity of leaves or if there is an underlying mechanistic relationship we have yet to appreciate (e.g. reliance on the same aquaporins in both the diffusion path of CO 2 and the outside-xylem portion of hydraulic flow; Flexas et al, 2013b). Given the potential for coordination between g m and g s , the absolute value of g m may be less of a determinant to improving WUE than is the relative value of g m to g s (i.e.…”

mentioning

confidence: 99%

Variable Mesophyll Conductance among Soybean Cultivars Sets a Tradeoff between Photosynthesis and Water-Use-Efficiency

Tomeo

Rosenthal

2017

Plant Physiol.

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Photosynthetic efficiency is a critical determinant of crop yield potential, although it remains below the theoretical optimum in modern crop varieties. Enhancing mesophyll conductance (i.e. the rate of carbon dioxide diffusion from substomatal cavities to the sites of carboxylation) may increase photosynthetic and water use efficiencies. To improve water use efficiency, mesophyll conductance should be increased without concomitantly increasing stomatal conductance. Here, we partition the variance in mesophyll conductance to within-and among-cultivar components across soybean (Glycine max) grown under both controlled and field conditions and examine the covariation of mesophyll conductance with photosynthetic rate, stomatal conductance, water use efficiency, and leaf mass per area. We demonstrate that mesophyll conductance varies more than 2-fold and that 38% of this variation is due to cultivar identity. As expected, mesophyll conductance is positively correlated with photosynthetic rates. However, a strong positive correlation between mesophyll and stomatal conductance among cultivars apparently impedes positive scaling between mesophyll conductance and water use efficiency in soybean. Contrary to expectations, photosynthetic rates and mesophyll conductance both increased with increasing leaf mass per area. The presence of genetic variation for mesophyll conductance suggests that there is potential to increase photosynthesis and mesophyll conductance by selecting for greater leaf mass per area. Increasing water use efficiency, though, is unlikely unless there is simultaneous stabilizing selection on stomatal conductance.

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Leaf mesophyll conductance and leaf hydraulic conductance: an introduction to their measurement and coordination

Cited by 190 publications

References 123 publications

How Does Leaf Anatomy Influence Water Transport outside the Xylem?

How Does Leaf Anatomy Influence Water Transport outside the Xylem?

Modern viticulture in southern Europe: Vulnerabilities and strategies for adaptation to water scarcity

Variable Mesophyll Conductance among Soybean Cultivars Sets a Tradeoff between Photosynthesis and Water-Use-Efficiency

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