Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.

Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.

A study was conducted over two years to determine whether growth under elevated CO2 (700 μmol mol-1) and temperature (ambient + 4ºC) conditions modifies photochemical efficiency or only the use of electron transport products in spring wheat grown in field chambers. Elevated atmospheric CO2 concentrations increased crop dry matter at maturity by 12%-17%, while above-ambient temperatures did not significantly affect dry matter yield. In measurements with ambient CO2 at ear emergence and after anthesis, growth at elevated CO2 concentrations decreased flag leaf light-saturated carbon assimilation. The quantum yield of electron transport (ΦPSII) measured at ambient CO2 and higher irradiances increased at ear emergence and decreased after anthesis in plants grown at elevated CO2. At higher light intensities, but not in low light, photochemical quenching (qP) decreased after growth in elevated CO2 conditions. Growth under CO2 enrichment increased dark- (Fv:Fm) and light-adapted (Fv’:Fm’) photochemical efficiencies, and decreased the chlorophyll a:b ratio, suggesting an increase in light-harvesting complexes relative to PSII reaction centres. A relatively higher decrease in carbon assimilation than the decrease in ΦPSII pointed to a sink other than CO2 assimilation for electron-transport products at defined growth stages. With higher light intensities, warmer temperatures increased ΦPSII and Fv’:Fm’ at ear emergence and decreased ΦPSII after anthesis; in ambient -but not elevated- CO2, warmer temperatures also decreased qP after anthesis. CO2 fixation increased or did not change with temperature, depending on the growth stage and year. We conclude that elevated CO2 decreases the carbon assimilation capacity, but increases photochemistry and resource allocation to light harvesting, and that elevated levels of CO2 can mitigate photochemistry inhibition due to warm temperatures.

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Main Authors: Gutiérrez del Pozo, Diego, Gutiérrez Rodríguez, Elena, Pérez Pérez, Pilar, Morcuende, Rosa, Verdejo, Ángel L., Martínez-Carrasco, Rafael
Format: artículo biblioteca
Language:English
Published: Wiley-Blackwell
Subjects:Acclimation, chlorophyll a:b ratio;, Chlorophyll fluorescence, Carbon assimilation, elevated CO2, elevated temperature, Crop yield, wheat,
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spelling dig-irnasa-es-10261-189492022-06-01T13:10:08Z Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers. Gutiérrez del Pozo, Diego Gutiérrez Rodríguez, Elena Pérez Pérez, Pilar Morcuende, Rosa Verdejo, Ángel L. Martínez-Carrasco, Rafael Acclimation chlorophyll a:b ratio; Chlorophyll fluorescence Carbon assimilation elevated CO2 elevated temperature Crop yield wheat A study was conducted over two years to determine whether growth under elevated CO2 (700 μmol mol-1) and temperature (ambient + 4ºC) conditions modifies photochemical efficiency or only the use of electron transport products in spring wheat grown in field chambers. Elevated atmospheric CO2 concentrations increased crop dry matter at maturity by 12%-17%, while above-ambient temperatures did not significantly affect dry matter yield. In measurements with ambient CO2 at ear emergence and after anthesis, growth at elevated CO2 concentrations decreased flag leaf light-saturated carbon assimilation. The quantum yield of electron transport (ΦPSII) measured at ambient CO2 and higher irradiances increased at ear emergence and decreased after anthesis in plants grown at elevated CO2. At higher light intensities, but not in low light, photochemical quenching (qP) decreased after growth in elevated CO2 conditions. Growth under CO2 enrichment increased dark- (Fv:Fm) and light-adapted (Fv’:Fm’) photochemical efficiencies, and decreased the chlorophyll a:b ratio, suggesting an increase in light-harvesting complexes relative to PSII reaction centres. A relatively higher decrease in carbon assimilation than the decrease in ΦPSII pointed to a sink other than CO2 assimilation for electron-transport products at defined growth stages. With higher light intensities, warmer temperatures increased ΦPSII and Fv’:Fm’ at ear emergence and decreased ΦPSII after anthesis; in ambient -but not elevated- CO2, warmer temperatures also decreased qP after anthesis. CO2 fixation increased or did not change with temperature, depending on the growth stage and year. We conclude that elevated CO2 decreases the carbon assimilation capacity, but increases photochemistry and resource allocation to light harvesting, and that elevated levels of CO2 can mitigate photochemistry inhibition due to warm temperatures. D.G. and E.G. were the recipients of Junta de Castilla y León and I3P-European Social Fund fellowships, respectively. We thank the staff of this Institute’s experimental farm for technical assistance in crop husbandry. This work has been funded by the Spanish National Research and Development Programme– European Regional Development Fund ERDF (Project BFI2003-01277 and AGL2006-13541-C02- 02/AGR). Peer reviewed 2009 artículo http://purl.org/coar/resource_type/c_6501 Physiologia Plantarum 137,.86-100. (2009) 10261/18949 10.1111/j.1399-3054.2009.01256.x en http://www.wiley.com/bw/journal.asp?ref=0031-9317&site=1 open Wiley-Blackwell
institution IRNASA ES
collection DSpace
country España
countrycode ES
component Bibliográfico
access En linea
databasecode dig-irnasa-es
tag biblioteca
region Europa del Sur
libraryname Biblioteca del IRNASA España
language English
topic Acclimation
chlorophyll a:b ratio;
Chlorophyll fluorescence
Carbon assimilation
elevated CO2
elevated temperature
Crop yield
wheat
Acclimation
chlorophyll a:b ratio;
Chlorophyll fluorescence
Carbon assimilation
elevated CO2
elevated temperature
Crop yield
wheat
spellingShingle Acclimation
chlorophyll a:b ratio;
Chlorophyll fluorescence
Carbon assimilation
elevated CO2
elevated temperature
Crop yield
wheat
Acclimation
chlorophyll a:b ratio;
Chlorophyll fluorescence
Carbon assimilation
elevated CO2
elevated temperature
Crop yield
wheat
Gutiérrez del Pozo, Diego
Gutiérrez Rodríguez, Elena
Pérez Pérez, Pilar
Morcuende, Rosa
Verdejo, Ángel L.
Martínez-Carrasco, Rafael
Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
description A study was conducted over two years to determine whether growth under elevated CO2 (700 μmol mol-1) and temperature (ambient + 4ºC) conditions modifies photochemical efficiency or only the use of electron transport products in spring wheat grown in field chambers. Elevated atmospheric CO2 concentrations increased crop dry matter at maturity by 12%-17%, while above-ambient temperatures did not significantly affect dry matter yield. In measurements with ambient CO2 at ear emergence and after anthesis, growth at elevated CO2 concentrations decreased flag leaf light-saturated carbon assimilation. The quantum yield of electron transport (ΦPSII) measured at ambient CO2 and higher irradiances increased at ear emergence and decreased after anthesis in plants grown at elevated CO2. At higher light intensities, but not in low light, photochemical quenching (qP) decreased after growth in elevated CO2 conditions. Growth under CO2 enrichment increased dark- (Fv:Fm) and light-adapted (Fv’:Fm’) photochemical efficiencies, and decreased the chlorophyll a:b ratio, suggesting an increase in light-harvesting complexes relative to PSII reaction centres. A relatively higher decrease in carbon assimilation than the decrease in ΦPSII pointed to a sink other than CO2 assimilation for electron-transport products at defined growth stages. With higher light intensities, warmer temperatures increased ΦPSII and Fv’:Fm’ at ear emergence and decreased ΦPSII after anthesis; in ambient -but not elevated- CO2, warmer temperatures also decreased qP after anthesis. CO2 fixation increased or did not change with temperature, depending on the growth stage and year. We conclude that elevated CO2 decreases the carbon assimilation capacity, but increases photochemistry and resource allocation to light harvesting, and that elevated levels of CO2 can mitigate photochemistry inhibition due to warm temperatures.
format artículo
topic_facet Acclimation
chlorophyll a:b ratio;
Chlorophyll fluorescence
Carbon assimilation
elevated CO2
elevated temperature
Crop yield
wheat
author Gutiérrez del Pozo, Diego
Gutiérrez Rodríguez, Elena
Pérez Pérez, Pilar
Morcuende, Rosa
Verdejo, Ángel L.
Martínez-Carrasco, Rafael
author_facet Gutiérrez del Pozo, Diego
Gutiérrez Rodríguez, Elena
Pérez Pérez, Pilar
Morcuende, Rosa
Verdejo, Ángel L.
Martínez-Carrasco, Rafael
author_sort Gutiérrez del Pozo, Diego
title Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
title_short Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
title_full Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
title_fullStr Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
title_full_unstemmed Acclimation to future atmospheric CO2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
title_sort acclimation to future atmospheric co2 levels increases photochemical efficiency and mitigates photochemistry inhibition by warm temperatures in wheat under field chambers.
publisher Wiley-Blackwell
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