Predawn plant water potential does not necessarily equilibrate with soil water potential under well-watered conditions

Donovan, Lisa A.; Linton, Matthew J.; Richards, James H.

doi:10.1007/s004420100738

Cited by 211 publications

(154 citation statements)

References 61 publications

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“…High transpiration rate at night, by contrast, prevents overnight equilibration between plant and soil water potentials (38,39). In line with this interpretation, a significant, negative correlation was observed between the genotypic values of E n and predawn leaf water potential (Ψ pd ; SI Appendix, Table S4).…”

Section: Cuticular Water Losses: Tight Genetic Control For a Small Frsupporting

confidence: 63%

Reduced nighttime transpiration is a relevant breeding target for high water-use efficiency in grapevine

Coupel‐Ledru

Lebon

Christophe

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

121

101

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Increasing water scarcity challenges crop sustainability in many regions. As a consequence, the enhancement of transpiration efficiency (TE)-that is, the biomass produced per unit of water transpired-has become crucial in breeding programs. This could be achieved by reducing plant transpiration through a better closure of the stomatal pores at the leaf surface. However, this strategy generally also lowers growth, as stomatal opening is necessary for the capture of atmospheric CO 2 that feeds daytime photosynthesis. Here, we considered the reduction in transpiration rate at night (E n ) as a possible strategy to limit water use without altering growth. For this purpose, we carried out a genetic analysis for E n and TE in grapevine, a major crop in drought-prone areas. Using recently developed phenotyping facilities, potted plants of a cross between Syrah and Grenache cultivars were screened for 2 y under well-watered and moderate soil water deficit scenarios. High genetic variability was found for E n under both scenarios and was primarily associated with residual diffusion through the stomata. Five quantitative trait loci (QTLs) were detected that underlay genetic variability in E n . Interestingly, four of them colocalized with QTLs for TE. Moreover, genotypes with favorable alleles on these common QTLs exhibited reduced E n without altered growth. These results demonstrate the interest of breeding grapevine for lower water loss at night and pave the way to breeding other crops with this underexploited trait for higher TE.night transpiration | transpiration efficiency | growth | stomata | QTL

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Section: Cuticular Water Losses: Tight Genetic Control For a Small Frsupporting

confidence: 63%

Reduced nighttime transpiration is a relevant breeding target for high water-use efficiency in grapevine

Coupel‐Ledru

Lebon

Christophe

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

121

101

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“…The disequilibrium between plant and Y soil early in the season was probably attributable to nocturnal transpiration or incomplete overnight rehydration of the above-ground portion of the trees (Bucci et al 2005). It has been shown that nocturnal transpiration can prevent overnight equilibration between plant and Y soil (Donovan, Linton & Richards 2001, Donovan, Richards & Linton 2003Bucci et al 2004a). Later in the season, Y soil in the morning fell below that of B. crassa and B. salicifolius roots, the species with the shallowest roots (Fig.…”

Section: Discussionmentioning

confidence: 97%

Diurnal and seasonal variation in root xylem embolism in neotropical savanna woody species: impact on stomatal control of plant water status

Domec¹,

Fg²,

Bucci³

et al. 2005

Plant Cell & Environment

165

114

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“…The Ψ soil threshold for HR was reached approximately when upper Ψ soil approached predawn Ψ leaf , and thus the upper soil had become an effective competitor for water with the above-ground portion of the tree. A disequilibrium between Ψ soil and predawn Ψ leaf is not uncommon (Donovan, Linton & Richards 2001;Donovan, Richards & Linton 2003;Bucci et al 2004) and will certainly influence HR. If the rate of HR is regulated by competing water potential differences in the plant and soil systems, we should be able to alter the rates of HR by altering these Ψ driving forces.…”

Section: Discussionmentioning

confidence: 99%

Hydraulic redistribution in a Douglas‐fir forest: lessons from system manipulations

Brooks

Meinzer

Warren

et al. 2005

Plant Cell & Environment

130

134

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Hydraulic redistribution (HR) occurs in many ecosystems; however, key questions remain about its consequences at the ecosystem level. The objectives of the present study were to quantify seasonal variation in HR and its driving force, and to manipulate the soil-root system to elucidate physiological components controlling HR and utilization of redistributed water. In the upper soil layer of a young Douglas-fir forest, HR was negligible in early summer, but increased to 0.17 mm day − − − − 1 (20-60 cm layer) by late August when soil water potential was approximately − − − − 1 MPa. When maximum HR rates were observed, redistributed water replenished approximately 40% of the water depleted from the upper soil on a daily basis. Manipulations to the soil or to the soil/plant water potential driving force altered the rate of observed HR indicating that the rate of HR is controlled by a complex interplay between competing soil and plant water potential gradients and pathway resistances. Separating roots from the transpiring tree resulted in increased HR, and sap flow measurements on connected and disconnected roots showed reversal of water flow, a prerequisite for HR. Irrigating a small plot with deuterated water demonstrated that redistributed water was taken up by small understorey plants as far as 5 m from the watering source, and potentially further, but the utilization pattern was patchy. HR in the upper soil layers near the watering plot was twice that of the control HR. This increase in HR also increased the amount of water utilized by plants from the upper soil. These results indicate that the seasonal timing and magnitude of HR was strongly governed by the development of water potential differences within the soil, and the competing demand for water by the above ground portion of the tree.

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Predawn plant water potential does not necessarily equilibrate with soil water potential under well-watered conditions

Cited by 211 publications

References 61 publications

Reduced nighttime transpiration is a relevant breeding target for high water-use efficiency in grapevine

Reduced nighttime transpiration is a relevant breeding target for high water-use efficiency in grapevine

Diurnal and seasonal variation in root xylem embolism in neotropical savanna woody species: impact on stomatal control of plant water status

Hydraulic redistribution in a Douglas‐fir forest: lessons from system manipulations

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