Variability in temperature-independent transpiration responses to evaporative demand correlate with nighttime water use and its circadian control across diverse wheat populations

Bishal G. Tamang; Rémy Schoppach; Daniel Monnens; Brian J. Steffenson; James A. Anderson; Walid Sadok

doi:10.1007/s00425-019-03151-0

Variability in temperature-independent transpiration responses to evaporative demand correlate with nighttime water use and its circadian control across diverse wheat populations

Bishal G. Tamang, Rémy Schoppach, Daniel Monnens, Brian J. Steffenson, James A. Anderson, Walid Sadok

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Abstract

Main conclusion: Nocturnal transpiration, through its circadian control, plays a role in modulating daytime transpiration response to increasing evaporative demand, to potentially enable drought tolerance in wheat. Limiting plant transpiration rate (TR) in response to increasing vapor pressure deficit (VPD) has been suggested to enable drought tolerance through water conservation. However, there is very little information on the extent of diversity of TR response curves to “true” VPD (i.e., independent from temperature). Furthermore, new evidence indicate that water-saving could operate by modulating nocturnal TR (TR_N), and that this response might be coupled to daytime gas exchange. Based on 3 years of experimental data on a diverse group of 77 genotypes from 25 countries and 5 continents, a first goal of this study was to characterize the functional diversity in daytime TR responses to VPD and TR_N in wheat. A second objective was to test the hypothesis that these traits could be coupled through the circadian clock. Using a new gravimetric phenotyping platform that allowed for independent temperature and VPD control, we identified three and fourfold variation in daytime and nighttime responses, respectively. In addition, TR_N was found to be positively correlated with slopes of daytime TR responses to VPD, and we identified pre-dawn variation in TR_N that likely mediated this relationship. Furthermore, pre-dawn increase in TR_N positively correlated with the year of release among drought-tolerant Australian cultivars and with the VPD threshold at which they initiated water-saving. Overall, the study indicates a substantial diversity in TR responses to VPD that could be leveraged to enhance fitness under water-limited environments, and that TR_N and its circadian control may play an important role in the expression of water-saving.

Original language	English (US)
Pages (from-to)	115-127
Number of pages	13
Journal	Planta
Volume	250
Issue number	1
DOIs	https://doi.org/10.1007/s00425-019-03151-0
State	Published - Jul 1 2019

Bibliographical note

Funding Information:
regression (VPDTh, c). In all panels, light gray circle indicate genotypes with statistically significant pre-dawn TRN increase. Linear regression fits (equation), Pearson’s r, their P values and R2 are indicated in each panel. Error bars are for standard errors (±SE) Acknowledgements This work was supported by the Minnesota Agricultural Experiment Station (Project# MIN-13-095), the Minnesota Wheat Research & Promotion Council (Projects# 00062299 and 00070003), the Belgian National Fund for Scientific Research (FNRS, contract# 1.E038.13), and by the National Science Foundation/Civilian Research & Development Foundation (Award# OISE-16-62788-0).

Publisher Copyright:
© 2019, Springer-Verlag GmbH Germany, part of Springer Nature.

Keywords

Canopy conductance
Circadian clock
Drought tolerance
Gravimetric phenotyping
Nocturnal transpiration
Stomata conductance
Vapor pressure deficit
Wheat

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title = "Variability in temperature-independent transpiration responses to evaporative demand correlate with nighttime water use and its circadian control across diverse wheat populations",

abstract = "Main conclusion: Nocturnal transpiration, through its circadian control, plays a role in modulating daytime transpiration response to increasing evaporative demand, to potentially enable drought tolerance in wheat. Limiting plant transpiration rate (TR) in response to increasing vapor pressure deficit (VPD) has been suggested to enable drought tolerance through water conservation. However, there is very little information on the extent of diversity of TR response curves to “true” VPD (i.e., independent from temperature). Furthermore, new evidence indicate that water-saving could operate by modulating nocturnal TR (TRN), and that this response might be coupled to daytime gas exchange. Based on 3 years of experimental data on a diverse group of 77 genotypes from 25 countries and 5 continents, a first goal of this study was to characterize the functional diversity in daytime TR responses to VPD and TRN in wheat. A second objective was to test the hypothesis that these traits could be coupled through the circadian clock. Using a new gravimetric phenotyping platform that allowed for independent temperature and VPD control, we identified three and fourfold variation in daytime and nighttime responses, respectively. In addition, TRN was found to be positively correlated with slopes of daytime TR responses to VPD, and we identified pre-dawn variation in TRN that likely mediated this relationship. Furthermore, pre-dawn increase in TRN positively correlated with the year of release among drought-tolerant Australian cultivars and with the VPD threshold at which they initiated water-saving. Overall, the study indicates a substantial diversity in TR responses to VPD that could be leveraged to enhance fitness under water-limited environments, and that TRN and its circadian control may play an important role in the expression of water-saving.",

keywords = "Canopy conductance, Circadian clock, Drought tolerance, Gravimetric phenotyping, Nocturnal transpiration, Stomata conductance, Vapor pressure deficit, Wheat",

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note = "Funding Information: regression (VPDTh, c). In all panels, light gray circle indicate genotypes with statistically significant pre-dawn TRN increase. Linear regression fits (equation), Pearson{\textquoteright}s r, their P values and R2 are indicated in each panel. Error bars are for standard errors (±SE) Acknowledgements This work was supported by the Minnesota Agricultural Experiment Station (Project# MIN-13-095), the Minnesota Wheat Research & Promotion Council (Projects# 00062299 and 00070003), the Belgian National Fund for Scientific Research (FNRS, contract# 1.E038.13), and by the National Science Foundation/Civilian Research & Development Foundation (Award# OISE-16-62788-0). Publisher Copyright: {\textcopyright} 2019, Springer-Verlag GmbH Germany, part of Springer Nature.",

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T1 - Variability in temperature-independent transpiration responses to evaporative demand correlate with nighttime water use and its circadian control across diverse wheat populations

AU - Tamang, Bishal G.

AU - Schoppach, Rémy

AU - Monnens, Daniel

AU - Steffenson, Brian J.

AU - Anderson, James A.

AU - Sadok, Walid

N1 - Funding Information: regression (VPDTh, c). In all panels, light gray circle indicate genotypes with statistically significant pre-dawn TRN increase. Linear regression fits (equation), Pearson’s r, their P values and R2 are indicated in each panel. Error bars are for standard errors (±SE) Acknowledgements This work was supported by the Minnesota Agricultural Experiment Station (Project# MIN-13-095), the Minnesota Wheat Research & Promotion Council (Projects# 00062299 and 00070003), the Belgian National Fund for Scientific Research (FNRS, contract# 1.E038.13), and by the National Science Foundation/Civilian Research & Development Foundation (Award# OISE-16-62788-0). Publisher Copyright: © 2019, Springer-Verlag GmbH Germany, part of Springer Nature.

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N2 - Main conclusion: Nocturnal transpiration, through its circadian control, plays a role in modulating daytime transpiration response to increasing evaporative demand, to potentially enable drought tolerance in wheat. Limiting plant transpiration rate (TR) in response to increasing vapor pressure deficit (VPD) has been suggested to enable drought tolerance through water conservation. However, there is very little information on the extent of diversity of TR response curves to “true” VPD (i.e., independent from temperature). Furthermore, new evidence indicate that water-saving could operate by modulating nocturnal TR (TRN), and that this response might be coupled to daytime gas exchange. Based on 3 years of experimental data on a diverse group of 77 genotypes from 25 countries and 5 continents, a first goal of this study was to characterize the functional diversity in daytime TR responses to VPD and TRN in wheat. A second objective was to test the hypothesis that these traits could be coupled through the circadian clock. Using a new gravimetric phenotyping platform that allowed for independent temperature and VPD control, we identified three and fourfold variation in daytime and nighttime responses, respectively. In addition, TRN was found to be positively correlated with slopes of daytime TR responses to VPD, and we identified pre-dawn variation in TRN that likely mediated this relationship. Furthermore, pre-dawn increase in TRN positively correlated with the year of release among drought-tolerant Australian cultivars and with the VPD threshold at which they initiated water-saving. Overall, the study indicates a substantial diversity in TR responses to VPD that could be leveraged to enhance fitness under water-limited environments, and that TRN and its circadian control may play an important role in the expression of water-saving.

AB - Main conclusion: Nocturnal transpiration, through its circadian control, plays a role in modulating daytime transpiration response to increasing evaporative demand, to potentially enable drought tolerance in wheat. Limiting plant transpiration rate (TR) in response to increasing vapor pressure deficit (VPD) has been suggested to enable drought tolerance through water conservation. However, there is very little information on the extent of diversity of TR response curves to “true” VPD (i.e., independent from temperature). Furthermore, new evidence indicate that water-saving could operate by modulating nocturnal TR (TRN), and that this response might be coupled to daytime gas exchange. Based on 3 years of experimental data on a diverse group of 77 genotypes from 25 countries and 5 continents, a first goal of this study was to characterize the functional diversity in daytime TR responses to VPD and TRN in wheat. A second objective was to test the hypothesis that these traits could be coupled through the circadian clock. Using a new gravimetric phenotyping platform that allowed for independent temperature and VPD control, we identified three and fourfold variation in daytime and nighttime responses, respectively. In addition, TRN was found to be positively correlated with slopes of daytime TR responses to VPD, and we identified pre-dawn variation in TRN that likely mediated this relationship. Furthermore, pre-dawn increase in TRN positively correlated with the year of release among drought-tolerant Australian cultivars and with the VPD threshold at which they initiated water-saving. Overall, the study indicates a substantial diversity in TR responses to VPD that could be leveraged to enhance fitness under water-limited environments, and that TRN and its circadian control may play an important role in the expression of water-saving.

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KW - Gravimetric phenotyping

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KW - Stomata conductance

KW - Vapor pressure deficit

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Variability in temperature-independent transpiration responses to evaporative demand correlate with nighttime water use and its circadian control across diverse wheat populations

Abstract

Bibliographical note

Keywords

UN SDGs

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