The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)

Elevated CO(2) concentration [e(CO(2))] often promotes plant growth with a decrease in tissue N concentration. In this study, three experiments, two under hydroponic and one in well-watered soil, including various levels or patterns of CO(2), humidity, and N supply were conducted on wheat (Triticum...

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Autores principales: Fan, Jinjie, Halpern, Moshe, Yu, Yangliu, Zuo, Qiang, Shi, Jianchu, Fan, Yuchuan, Wu, Xun, Yermiyahu, Uri, Sheng, Jiandong, Jiang, Pingan, Ben-Gal, Alon
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2022
Materias:
Plant Science
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8888439/
https://www.ncbi.nlm.nih.gov/pubmed/35251079
http://dx.doi.org/10.3389/fpls.2022.801443
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author Fan, Jinjie
Halpern, Moshe
Yu, Yangliu
Zuo, Qiang
Shi, Jianchu
Fan, Yuchuan
Wu, Xun
Yermiyahu, Uri
Sheng, Jiandong
Jiang, Pingan
Ben-Gal, Alon
author_facet Fan, Jinjie
Halpern, Moshe
Yu, Yangliu
Zuo, Qiang
Shi, Jianchu
Fan, Yuchuan
Wu, Xun
Yermiyahu, Uri
Sheng, Jiandong
Jiang, Pingan
Ben-Gal, Alon
author_sort Fan, Jinjie
collection PubMed
description Elevated CO(2) concentration [e(CO(2))] often promotes plant growth with a decrease in tissue N concentration. In this study, three experiments, two under hydroponic and one in well-watered soil, including various levels or patterns of CO(2), humidity, and N supply were conducted on wheat (Triticum aestivum L.) to explore the mechanisms of e[CO(2)]-induced N deficiency (ECIND). Under hydroponic conditions, N uptake remained constant even as transpiration was limited 40% by raising air relative humidity and only was reduced about 20% by supplying N during nighttime rather than daytime with a reduction of 85% in transpiration. Compared to ambient CO(2) concentration, whether under hydroponic or well-watered soil conditions, and whether transpiration was kept stable or decreased to 12%, e[CO(2)] consistently led to more N uptake and higher biomass, while lower N concentration was observed in aboveground organs, especially leaves, as long as N supply was insufficient. These results show that, due to compensation caused by active uptake, N uptake can be uncoupled from water uptake under well-watered conditions, and changes in transpiration therefore do not account for ECIND. Similar or lower tissue [Formula: see text]-N concentration under e[CO(2)] indicated that [Formula: see text] assimilation was not limited and could therefore also be eliminated as a major cause of ECIND under our conditions. Active uptake has the potential to bridge the gap between N taken up passively and plant demand, but is limited by the energy required to drive it. Compared to ambient CO(2) concentration, the increase in N uptake under e[CO(2)] failed to match the increase of carbohydrates, leading to N dilution in plant tissues, the apparent dominant mechanism explaining ECIND. Lower N concentration in leaves rather than roots under e[CO(2)] validated that ECIND was at least partially also related to changes in resource allocation, apparently to maintain root uptake activity and prevent more serious N deficiency.
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spelling pubmed-88884392022-03-03 The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2) Fan, Jinjie Halpern, Moshe Yu, Yangliu Zuo, Qiang Shi, Jianchu Fan, Yuchuan Wu, Xun Yermiyahu, Uri Sheng, Jiandong Jiang, Pingan Ben-Gal, Alon Front Plant Sci Plant Science Elevated CO(2) concentration [e(CO(2))] often promotes plant growth with a decrease in tissue N concentration. In this study, three experiments, two under hydroponic and one in well-watered soil, including various levels or patterns of CO(2), humidity, and N supply were conducted on wheat (Triticum aestivum L.) to explore the mechanisms of e[CO(2)]-induced N deficiency (ECIND). Under hydroponic conditions, N uptake remained constant even as transpiration was limited 40% by raising air relative humidity and only was reduced about 20% by supplying N during nighttime rather than daytime with a reduction of 85% in transpiration. Compared to ambient CO(2) concentration, whether under hydroponic or well-watered soil conditions, and whether transpiration was kept stable or decreased to 12%, e[CO(2)] consistently led to more N uptake and higher biomass, while lower N concentration was observed in aboveground organs, especially leaves, as long as N supply was insufficient. These results show that, due to compensation caused by active uptake, N uptake can be uncoupled from water uptake under well-watered conditions, and changes in transpiration therefore do not account for ECIND. Similar or lower tissue [Formula: see text]-N concentration under e[CO(2)] indicated that [Formula: see text] assimilation was not limited and could therefore also be eliminated as a major cause of ECIND under our conditions. Active uptake has the potential to bridge the gap between N taken up passively and plant demand, but is limited by the energy required to drive it. Compared to ambient CO(2) concentration, the increase in N uptake under e[CO(2)] failed to match the increase of carbohydrates, leading to N dilution in plant tissues, the apparent dominant mechanism explaining ECIND. Lower N concentration in leaves rather than roots under e[CO(2)] validated that ECIND was at least partially also related to changes in resource allocation, apparently to maintain root uptake activity and prevent more serious N deficiency. Frontiers Media S.A. 2022-02-16 /pmc/articles/PMC8888439/ /pubmed/35251079 http://dx.doi.org/10.3389/fpls.2022.801443 Text en Copyright © 2022 Fan, Halpern, Yu, Zuo, Shi, Fan, Wu, Yermiyahu, Sheng, Jiang and Ben-Gal. https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Plant Science
Fan, Jinjie
Halpern, Moshe
Yu, Yangliu
Zuo, Qiang
Shi, Jianchu
Fan, Yuchuan
Wu, Xun
Yermiyahu, Uri
Sheng, Jiandong
Jiang, Pingan
Ben-Gal, Alon
The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title_full The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title_fullStr The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title_full_unstemmed The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title_short The Mechanisms Responsible for N Deficiency in Well-Watered Wheat Under Elevated CO(2)
title_sort mechanisms responsible for n deficiency in well-watered wheat under elevated co(2)
topic Plant Science
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8888439/
https://www.ncbi.nlm.nih.gov/pubmed/35251079
http://dx.doi.org/10.3389/fpls.2022.801443
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