Acclimation response of spring wheat in a free-air CO2 enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves

Gerard W. Wall; Neal R. Adam; Talbot J. Brooks; Bruce A. Kimball; Paul J. Pinter; Robert L. Lamorte; Floyd J. Adamsen; Douglas J. Hunsaker; Gabrielle Wechsung; Frank Wechsung; Susanne Grossman-Clarke; Steven W. Leavitt; Allan D. Matthias; Andrew N. Webber

doi:10.1023/A:1010646225929

Acclimation response of spring wheat in a free-air CO₂ enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves

Gerard W. Wall, Neal R. Adam, Talbot J. Brooks, Bruce A. Kimball, Paul J. Pinter, Robert L. Lamorte, Floyd J. Adamsen, Douglas J. Hunsaker, Gabrielle Wechsung, Frank Wechsung, Susanne Grossman-Clarke, Steven W. Leavitt, Allan D. Matthias, Andrew N. Webber

Research output: Contribution to journal › Article › peer-review

56 Scopus citations

Abstract

Atmospheric CO₂ concentration continues to rise. It is important, therefore, to determine what acclimatory changes will occur within the photosynthetic apparatus of wheat (Triticum aestivum L. cv. Yecora Rojo) grown in a future high-CO₂ world at ample and limited soil N contents. Wheat was grown in an open field exposed to the CO₂ concentration of ambient air [370 μmol (CO₂) mol^-1; Control] and air enriched to ∼200 μmol (CO₂) mol^-1 above ambient using a Free-Air CO₂ Enrichment (FACE) apparatus (main plot). A High (35 g m^-2) or Low (7 and 1.5 g m^-2 for 1996 and 1997, respectfully) level of N was applied to each half of the main CO₂ treatment plots (split-plot). Under High-N, FACE reduced stomatal conductance (g_s) by 30% at mid-morning (2 h prior to solar noon), 36% at midday (solar noon) and 27% at mid-afternoon (2.5 h after solar noon), whereas under Low-N, g_s was reduced by as much as 31% at mid-morning, 44% at midday and 28% at mid-afternoon compared with Control. But, no significant CO₂ × N interaction effects occurred. Across seasons and growth stages, daily accumulation of carbon (A′) was 27% greater in FACE than Control. High-N increased A′ by 18% compared with Low-N. In contrast to results for g_s, however, significant CO₂ × N interaction effects occurred because FACE increased A′ by 30% at High-N, but by only 23% at Low-N. FACE enhanced the seasonal accumulation of carbon (A″) by 29% during 1996 (moderate N-stress), but by only 21% during 1997 (severe N-stress). These results support the premise that in a future high-CO₂ world an acclimatory (down-regulation) response in the photosynthetic apparatus of field-grown wheat is anticipated. They also demonstrate, however, that the stimulatory effect of a rise in atmospheric CO₂ on carbon gain in wheat can be maintained if nutrients such as nitrogen are in ample supply.

Original language	English (US)
Pages (from-to)	79-95
Number of pages	17
Journal	Photosynthesis Research
Volume	66
Issue number	1-2
DOIs	https://doi.org/10.1023/A:1010646225929
State	Published - 2000

Keywords

Acclimation
CO
Climate change
Down-regulation
Global change
Photosynthesis
Stomatal conductance

ASJC Scopus subject areas

Biochemistry
Plant Science
Cell Biology

Access to Document

10.1023/A:1010646225929

Cite this

Wall, G. W., Adam, N. R., Brooks, T. J., Kimball, B. A., Pinter, P. J., Lamorte, R. L., Adamsen, F. J., Hunsaker, D. J., Wechsung, G., Wechsung, F., Grossman-Clarke, S., Leavitt, S. W., Matthias, A. D., & Webber, A. N. (2000). Acclimation response of spring wheat in a free-air CO₂ enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves. Photosynthesis Research, 66(1-2), 79-95. https://doi.org/10.1023/A:1010646225929

Wall, GW, Adam, NR, Brooks, TJ, Kimball, BA, Pinter, PJ, Lamorte, RL, Adamsen, FJ, Hunsaker, DJ, Wechsung, G, Wechsung, F, Grossman-Clarke, S, Leavitt, SW, Matthias, AD & Webber, AN 2000, 'Acclimation response of spring wheat in a free-air CO₂ enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves', Photosynthesis Research, vol. 66, no. 1-2, pp. 79-95. https://doi.org/10.1023/A:1010646225929

@article{245ba0736a5b494fb7a98b982631e3b1,

title = "Acclimation response of spring wheat in a free-air CO2 enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves",

abstract = "Atmospheric CO2 concentration continues to rise. It is important, therefore, to determine what acclimatory changes will occur within the photosynthetic apparatus of wheat (Triticum aestivum L. cv. Yecora Rojo) grown in a future high-CO2 world at ample and limited soil N contents. Wheat was grown in an open field exposed to the CO2 concentration of ambient air [370 μmol (CO2) mol-1; Control] and air enriched to ∼200 μmol (CO2) mol-1 above ambient using a Free-Air CO2 Enrichment (FACE) apparatus (main plot). A High (35 g m-2) or Low (7 and 1.5 g m-2 for 1996 and 1997, respectfully) level of N was applied to each half of the main CO2 treatment plots (split-plot). Under High-N, FACE reduced stomatal conductance (gs) by 30% at mid-morning (2 h prior to solar noon), 36% at midday (solar noon) and 27% at mid-afternoon (2.5 h after solar noon), whereas under Low-N, gs was reduced by as much as 31% at mid-morning, 44% at midday and 28% at mid-afternoon compared with Control. But, no significant CO2 × N interaction effects occurred. Across seasons and growth stages, daily accumulation of carbon (A′) was 27% greater in FACE than Control. High-N increased A′ by 18% compared with Low-N. In contrast to results for gs, however, significant CO2 × N interaction effects occurred because FACE increased A′ by 30% at High-N, but by only 23% at Low-N. FACE enhanced the seasonal accumulation of carbon (A″) by 29% during 1996 (moderate N-stress), but by only 21% during 1997 (severe N-stress). These results support the premise that in a future high-CO2 world an acclimatory (down-regulation) response in the photosynthetic apparatus of field-grown wheat is anticipated. They also demonstrate, however, that the stimulatory effect of a rise in atmospheric CO2 on carbon gain in wheat can be maintained if nutrients such as nitrogen are in ample supply.",

keywords = "Acclimation, CO, Climate change, Down-regulation, Global change, Photosynthesis, Stomatal conductance",

author = "Wall, {Gerard W.} and Adam, {Neal R.} and Brooks, {Talbot J.} and Kimball, {Bruce A.} and Pinter, {Paul J.} and Lamorte, {Robert L.} and Adamsen, {Floyd J.} and Hunsaker, {Douglas J.} and Gabrielle Wechsung and Frank Wechsung and Susanne Grossman-Clarke and Leavitt, {Steven W.} and Matthias, {Allan D.} and Webber, {Andrew N.}",

note = "Funding Information: This research was supported by Grant #DE-FG03-95ER-62072 from the Department of Energy Terrestrial Carbon Processes Research Program to the University of Arizona, Tucson and Maricopa, Arizona (S. Leavitt, T. Thompson, A. Matthias, R. Rauschkolb and H.Y. Cho are principal investigators) and by Interagency Agreement No. IBN-9652614 between the National Science Foundation and the USDA-ARS, US Water Conservation Laboratory as part of the NSF/DOE/NASA/USDA Joint Program on Terrestrial Ecology and Global Change (TECO II; G.W. Wall, F.J Adamsen, B.A. Kimball and A.N. Webber are principal investigators). Operational support was also provided by the USDA-ARS, US Water Conservation Laboratory, Phoenix, Arizona. We also acknowledge the helpful cooperation of Dr Roy Rauschkolb (deceased) and his staff at the Maricopa Agricultural Center. The FACE apparatus was furnished by Brookhaven National Laboratory, and we are grateful to Mr Keith Lewin, Dr John Nagy and Dr George Hendrey for assisting in its installation and consulting about its use. This work contributes to the Global Change Terrestrial Ecosystem (GCTE) Core Research Programme, which is part of the International Geosphere-Biosphere Programme (IGBP).",

year = "2000",

doi = "10.1023/A:1010646225929",

language = "English (US)",

volume = "66",

pages = "79--95",

journal = "Photosynthesis Research",

issn = "0166-8595",

publisher = "Springer",

number = "1-2",

}

TY - JOUR

T1 - Acclimation response of spring wheat in a free-air CO2 enrichment (FACE) atmosphere with variable soil nitrogen regimes. 2. Net assimilation and stomatal conductance of leaves

AU - Wall, Gerard W.

AU - Adam, Neal R.

AU - Brooks, Talbot J.

AU - Kimball, Bruce A.

AU - Pinter, Paul J.

AU - Lamorte, Robert L.

AU - Adamsen, Floyd J.

AU - Hunsaker, Douglas J.

AU - Wechsung, Gabrielle

AU - Wechsung, Frank

AU - Grossman-Clarke, Susanne

AU - Leavitt, Steven W.

AU - Matthias, Allan D.

AU - Webber, Andrew N.

N1 - Funding Information: This research was supported by Grant #DE-FG03-95ER-62072 from the Department of Energy Terrestrial Carbon Processes Research Program to the University of Arizona, Tucson and Maricopa, Arizona (S. Leavitt, T. Thompson, A. Matthias, R. Rauschkolb and H.Y. Cho are principal investigators) and by Interagency Agreement No. IBN-9652614 between the National Science Foundation and the USDA-ARS, US Water Conservation Laboratory as part of the NSF/DOE/NASA/USDA Joint Program on Terrestrial Ecology and Global Change (TECO II; G.W. Wall, F.J Adamsen, B.A. Kimball and A.N. Webber are principal investigators). Operational support was also provided by the USDA-ARS, US Water Conservation Laboratory, Phoenix, Arizona. We also acknowledge the helpful cooperation of Dr Roy Rauschkolb (deceased) and his staff at the Maricopa Agricultural Center. The FACE apparatus was furnished by Brookhaven National Laboratory, and we are grateful to Mr Keith Lewin, Dr John Nagy and Dr George Hendrey for assisting in its installation and consulting about its use. This work contributes to the Global Change Terrestrial Ecosystem (GCTE) Core Research Programme, which is part of the International Geosphere-Biosphere Programme (IGBP).

PY - 2000

Y1 - 2000

N2 - Atmospheric CO2 concentration continues to rise. It is important, therefore, to determine what acclimatory changes will occur within the photosynthetic apparatus of wheat (Triticum aestivum L. cv. Yecora Rojo) grown in a future high-CO2 world at ample and limited soil N contents. Wheat was grown in an open field exposed to the CO2 concentration of ambient air [370 μmol (CO2) mol-1; Control] and air enriched to ∼200 μmol (CO2) mol-1 above ambient using a Free-Air CO2 Enrichment (FACE) apparatus (main plot). A High (35 g m-2) or Low (7 and 1.5 g m-2 for 1996 and 1997, respectfully) level of N was applied to each half of the main CO2 treatment plots (split-plot). Under High-N, FACE reduced stomatal conductance (gs) by 30% at mid-morning (2 h prior to solar noon), 36% at midday (solar noon) and 27% at mid-afternoon (2.5 h after solar noon), whereas under Low-N, gs was reduced by as much as 31% at mid-morning, 44% at midday and 28% at mid-afternoon compared with Control. But, no significant CO2 × N interaction effects occurred. Across seasons and growth stages, daily accumulation of carbon (A′) was 27% greater in FACE than Control. High-N increased A′ by 18% compared with Low-N. In contrast to results for gs, however, significant CO2 × N interaction effects occurred because FACE increased A′ by 30% at High-N, but by only 23% at Low-N. FACE enhanced the seasonal accumulation of carbon (A″) by 29% during 1996 (moderate N-stress), but by only 21% during 1997 (severe N-stress). These results support the premise that in a future high-CO2 world an acclimatory (down-regulation) response in the photosynthetic apparatus of field-grown wheat is anticipated. They also demonstrate, however, that the stimulatory effect of a rise in atmospheric CO2 on carbon gain in wheat can be maintained if nutrients such as nitrogen are in ample supply.

AB - Atmospheric CO2 concentration continues to rise. It is important, therefore, to determine what acclimatory changes will occur within the photosynthetic apparatus of wheat (Triticum aestivum L. cv. Yecora Rojo) grown in a future high-CO2 world at ample and limited soil N contents. Wheat was grown in an open field exposed to the CO2 concentration of ambient air [370 μmol (CO2) mol-1; Control] and air enriched to ∼200 μmol (CO2) mol-1 above ambient using a Free-Air CO2 Enrichment (FACE) apparatus (main plot). A High (35 g m-2) or Low (7 and 1.5 g m-2 for 1996 and 1997, respectfully) level of N was applied to each half of the main CO2 treatment plots (split-plot). Under High-N, FACE reduced stomatal conductance (gs) by 30% at mid-morning (2 h prior to solar noon), 36% at midday (solar noon) and 27% at mid-afternoon (2.5 h after solar noon), whereas under Low-N, gs was reduced by as much as 31% at mid-morning, 44% at midday and 28% at mid-afternoon compared with Control. But, no significant CO2 × N interaction effects occurred. Across seasons and growth stages, daily accumulation of carbon (A′) was 27% greater in FACE than Control. High-N increased A′ by 18% compared with Low-N. In contrast to results for gs, however, significant CO2 × N interaction effects occurred because FACE increased A′ by 30% at High-N, but by only 23% at Low-N. FACE enhanced the seasonal accumulation of carbon (A″) by 29% during 1996 (moderate N-stress), but by only 21% during 1997 (severe N-stress). These results support the premise that in a future high-CO2 world an acclimatory (down-regulation) response in the photosynthetic apparatus of field-grown wheat is anticipated. They also demonstrate, however, that the stimulatory effect of a rise in atmospheric CO2 on carbon gain in wheat can be maintained if nutrients such as nitrogen are in ample supply.

KW - Acclimation

KW - CO

KW - Climate change

KW - Down-regulation

KW - Global change

KW - Photosynthesis

KW - Stomatal conductance

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