Elevated CO2 Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis

Department of Plant and Environmental Sciences

Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis

Research output: Contribution to journal › Journal article › Research › peer-review

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Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis. / Abdelhakim, Lamis Osama Anwar; Mendanha, Thayna; Palma, Carolina Falcato Fialho; Vrobel, Ondrej; Stefelova, Nikola; Cavar Zeljkovic, Sanja; Tarkowski, Petr; De Diego, Nuria; Wollenweber, Bernd; Rosenqvist, Eva; Ottosen, Carl-Otto.

In: Frontiers in Plant Science, Vol. 13, 824476, 2022.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Abdelhakim, LOA, Mendanha, T, Palma, CFF, Vrobel, O, Stefelova, N, Cavar Zeljkovic, S, Tarkowski, P, De Diego, N, Wollenweber, B, Rosenqvist, E & Ottosen, C-O 2022, 'Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis', Frontiers in Plant Science, vol. 13, 824476. https://doi.org/10.3389/fpls.2022.824476

APA

Abdelhakim, L. O. A., Mendanha, T., Palma, C. F. F., Vrobel, O., Stefelova, N., Cavar Zeljkovic, S., Tarkowski, P., De Diego, N., Wollenweber, B., Rosenqvist, E., & Ottosen, C-O. (2022). Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis. Frontiers in Plant Science, 13, [824476]. https://doi.org/10.3389/fpls.2022.824476

Vancouver

Abdelhakim LOA, Mendanha T, Palma CFF, Vrobel O, Stefelova N, Cavar Zeljkovic S et al. Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis. Frontiers in Plant Science. 2022;13. 824476. https://doi.org/10.3389/fpls.2022.824476

Author

Abdelhakim, Lamis Osama Anwar ; Mendanha, Thayna ; Palma, Carolina Falcato Fialho ; Vrobel, Ondrej ; Stefelova, Nikola ; Cavar Zeljkovic, Sanja ; Tarkowski, Petr ; De Diego, Nuria ; Wollenweber, Bernd ; Rosenqvist, Eva ; Ottosen, Carl-Otto. / Elevated CO₂ Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis. In: Frontiers in Plant Science. 2022 ; Vol. 13.

Bibtex

@article{48bb7745b7f947f0ba80339cd1840f00,

title = "Elevated CO2 Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis",

abstract = "Heat and drought events often occur concurrently as a consequence of climate change and have a severe impact on crop growth and yield. Besides, the accumulative increase in the atmospheric CO2 level is expected to be doubled by the end of this century. It is essential to understand the consequences of climate change combined with the CO2 levels on relevant crops such as wheat. This study evaluated the physiology and metabolite changes and grain yield in heat-sensitive (SF29) and heat-tolerant (LM20) wheat genotypes under individual heat stress or combined with drought applied during anthesis at ambient (aCO(2)) and elevated CO2 (eCO(2)) levels. Both genotypes enhanced similarly the WUE under combined stresses at eCO(2). However, this increase was due to different stress responses, whereas eCO(2) improved the tolerance in heat-sensitive SF29 by enhancing the gas exchange parameters, and the accumulation of compatible solutes included glucose, fructose, beta-alanine, and GABA to keep water balance; the heat-tolerant LM20 improved the accumulation of phosphate and sulfate and reduced the lysine metabolism and other metabolites including N-acetylornithine. These changes did not help the plants to improve the final yield under combined stresses at eCO(2). Under non-stress conditions, eCO(2) improved the yield of both genotypes. However, the response differed among genotypes, most probably as a consequence of the eCO(2)-induced changes in glucose and fructose at anthesis. Whereas the less-productive genotype LM20 reduced the glucose and fructose and increased the grain dimension as the effect of the eCO(2) application, the most productive genotype SF29 increased the two carbohydrate contents and ended with higher weight in the spikes. Altogether, these findings showed that the eCO(2) improves the tolerance to combined heat and drought stress but not the yield in spring wheat under stress conditions through different mechanisms. However, under non-stress conditions, it could improve mainly the yield to the less-productive genotypes. Altogether, the results demonstrated that more studies focused on the combination of abiotic stress are needed to understand better the spring wheat responses that help the identification of genotypes more resilient and productive under these conditions for future climate conditions.",

keywords = "wheat, elevated CO2, heat stress, gas exchange, chlorophyll fluorescence, targeted metabolomic analysis, grain yield, CHLOROPHYLL FLUORESCENCE, PHOTOSYNTHETIC CAPACITY, RESPONSE CURVES, TOLERANCE, TEMPERATURE, ACCUMULATION, EFFICIENCY, CULTIVARS, DEFICIT, GROWTH",

author = "Abdelhakim, {Lamis Osama Anwar} and Thayna Mendanha and Palma, {Carolina Falcato Fialho} and Ondrej Vrobel and Nikola Stefelova and {Cavar Zeljkovic}, Sanja and Petr Tarkowski and {De Diego}, Nuria and Bernd Wollenweber and Eva Rosenqvist and Carl-Otto Ottosen",

year = "2022",

doi = "10.3389/fpls.2022.824476",

language = "English",

volume = "13",

journal = "Frontiers in Plant Science",

issn = "1664-462X",

publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Elevated CO2 Improves the Physiology but Not the Final Yield in Spring Wheat Genotypes Subjected to Heat and Drought Stress During Anthesis

AU - Abdelhakim, Lamis Osama Anwar

AU - Mendanha, Thayna

AU - Palma, Carolina Falcato Fialho

AU - Vrobel, Ondrej

AU - Stefelova, Nikola

AU - Cavar Zeljkovic, Sanja

AU - Tarkowski, Petr

AU - De Diego, Nuria

AU - Wollenweber, Bernd

AU - Rosenqvist, Eva

AU - Ottosen, Carl-Otto

PY - 2022

Y1 - 2022

N2 - Heat and drought events often occur concurrently as a consequence of climate change and have a severe impact on crop growth and yield. Besides, the accumulative increase in the atmospheric CO2 level is expected to be doubled by the end of this century. It is essential to understand the consequences of climate change combined with the CO2 levels on relevant crops such as wheat. This study evaluated the physiology and metabolite changes and grain yield in heat-sensitive (SF29) and heat-tolerant (LM20) wheat genotypes under individual heat stress or combined with drought applied during anthesis at ambient (aCO(2)) and elevated CO2 (eCO(2)) levels. Both genotypes enhanced similarly the WUE under combined stresses at eCO(2). However, this increase was due to different stress responses, whereas eCO(2) improved the tolerance in heat-sensitive SF29 by enhancing the gas exchange parameters, and the accumulation of compatible solutes included glucose, fructose, beta-alanine, and GABA to keep water balance; the heat-tolerant LM20 improved the accumulation of phosphate and sulfate and reduced the lysine metabolism and other metabolites including N-acetylornithine. These changes did not help the plants to improve the final yield under combined stresses at eCO(2). Under non-stress conditions, eCO(2) improved the yield of both genotypes. However, the response differed among genotypes, most probably as a consequence of the eCO(2)-induced changes in glucose and fructose at anthesis. Whereas the less-productive genotype LM20 reduced the glucose and fructose and increased the grain dimension as the effect of the eCO(2) application, the most productive genotype SF29 increased the two carbohydrate contents and ended with higher weight in the spikes. Altogether, these findings showed that the eCO(2) improves the tolerance to combined heat and drought stress but not the yield in spring wheat under stress conditions through different mechanisms. However, under non-stress conditions, it could improve mainly the yield to the less-productive genotypes. Altogether, the results demonstrated that more studies focused on the combination of abiotic stress are needed to understand better the spring wheat responses that help the identification of genotypes more resilient and productive under these conditions for future climate conditions.

AB - Heat and drought events often occur concurrently as a consequence of climate change and have a severe impact on crop growth and yield. Besides, the accumulative increase in the atmospheric CO2 level is expected to be doubled by the end of this century. It is essential to understand the consequences of climate change combined with the CO2 levels on relevant crops such as wheat. This study evaluated the physiology and metabolite changes and grain yield in heat-sensitive (SF29) and heat-tolerant (LM20) wheat genotypes under individual heat stress or combined with drought applied during anthesis at ambient (aCO(2)) and elevated CO2 (eCO(2)) levels. Both genotypes enhanced similarly the WUE under combined stresses at eCO(2). However, this increase was due to different stress responses, whereas eCO(2) improved the tolerance in heat-sensitive SF29 by enhancing the gas exchange parameters, and the accumulation of compatible solutes included glucose, fructose, beta-alanine, and GABA to keep water balance; the heat-tolerant LM20 improved the accumulation of phosphate and sulfate and reduced the lysine metabolism and other metabolites including N-acetylornithine. These changes did not help the plants to improve the final yield under combined stresses at eCO(2). Under non-stress conditions, eCO(2) improved the yield of both genotypes. However, the response differed among genotypes, most probably as a consequence of the eCO(2)-induced changes in glucose and fructose at anthesis. Whereas the less-productive genotype LM20 reduced the glucose and fructose and increased the grain dimension as the effect of the eCO(2) application, the most productive genotype SF29 increased the two carbohydrate contents and ended with higher weight in the spikes. Altogether, these findings showed that the eCO(2) improves the tolerance to combined heat and drought stress but not the yield in spring wheat under stress conditions through different mechanisms. However, under non-stress conditions, it could improve mainly the yield to the less-productive genotypes. Altogether, the results demonstrated that more studies focused on the combination of abiotic stress are needed to understand better the spring wheat responses that help the identification of genotypes more resilient and productive under these conditions for future climate conditions.

KW - wheat

KW - elevated CO2

KW - heat stress

KW - gas exchange

KW - chlorophyll fluorescence

KW - targeted metabolomic analysis

KW - grain yield

KW - CHLOROPHYLL FLUORESCENCE

KW - PHOTOSYNTHETIC CAPACITY

KW - RESPONSE CURVES

KW - TOLERANCE

KW - TEMPERATURE

KW - ACCUMULATION

KW - EFFICIENCY

KW - CULTIVARS

KW - DEFICIT

KW - GROWTH

U2 - 10.3389/fpls.2022.824476

DO - 10.3389/fpls.2022.824476

M3 - Journal article

C2 - 35330869

VL - 13

JO - Frontiers in Plant Science

JF - Frontiers in Plant Science

SN - 1664-462X

M1 - 824476

ER -

ID: 304158406