Inhibition of shoot‐expressed NRT1.1 improves reutilization of apoplastic iron under iron‐deficient conditions

SUMMARY Iron deficiency is a major constraint for plant growth in calcareous soils. The interplay between NO3− and Fe nutrition affects plant performance under Fe‐deficient conditions. However, how NO3− negatively regulates Fe nutrition at the molecular level in plants remains elusive. Here, we show...

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Published in:The Plant journal : for cell and molecular biology 2022-10, Vol.112 (2), p.549-564
Main Authors: Ye, Jia Yuan, Zhou, Miao, Zhu, Qing Yang, Zhu, Ya Xin, Du, Wen Xin, Liu, Xing Xing, Jin, Chong Wei
Format: Article
Language:English
Subjects:
Alkalizing
Apoplast
apoplastic pH
Buffers
Calcareous soils
Cell walls
Depletion
Disruption
Fe deficiency
Fe reutilization
Iron
Iron deficiency
nitrate
NRT1.1
Nutrient deficiency
Nutrition
Plant growth
Plant nutrition
Roots
shoot
Shoots
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container_issue 2
container_start_page 549
container_title The Plant journal : for cell and molecular biology
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creator Ye, Jia Yuan
Zhou, Miao
Zhu, Qing Yang
Zhu, Ya Xin
Du, Wen Xin
Liu, Xing Xing
Jin, Chong Wei
description SUMMARY Iron deficiency is a major constraint for plant growth in calcareous soils. The interplay between NO3− and Fe nutrition affects plant performance under Fe‐deficient conditions. However, how NO3− negatively regulates Fe nutrition at the molecular level in plants remains elusive. Here, we showed that the key nitrate transporter NRT1.1 in Arabidopsis plants, especially in the shoots, was markedly downregulated at post‐translational levels by Fe deficiency. However, loss of NRT1.1 function alleviated Fe deficiency chlorosis, suggesting that downregulation of NRT1.1 by Fe deficiency favors plant tolerance to Fe deficiency. Further analysis showed that although disruption of NRT1.1 did not alter Fe levels in both the shoots and roots, it improved the reutilization of apoplastic Fe in shoots but not in roots. In addition, disruption of NRT1.1 prevented Fe deficiency‐induced apoplastic alkalization in shoots by inhibiting apoplastic H+ depletion via NO3− uptake. In vitro analysis showed that reduced pH facilitates release of cell wall‐bound Fe. Thus, foliar spray with an acidic buffer promoted the reutilization of Fe in the leaf apoplast to enhance plant tolerance to Fe deficiency, while the opposite was true for the foliar spray with a neutral buffer. Thus, downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. Our findings may provide a basis for elucidating the link between N and Fe nutrition in plants and insight to scrutinize the relevance of shoot‐expressed NRT1.1 to the plant response to stress. Significance Statement Our study shows that downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. Our findings may provide a basis for elucidating the link between N and Fe nutrition in plants and insight to scrutinize the relevance of shoot‐expressed NRT1.1 to the plant response to stress.
doi_str_mv 10.1111/tpj.15967
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The interplay between NO3− and Fe nutrition affects plant performance under Fe‐deficient conditions. However, how NO3− negatively regulates Fe nutrition at the molecular level in plants remains elusive. Here, we showed that the key nitrate transporter NRT1.1 in Arabidopsis plants, especially in the shoots, was markedly downregulated at post‐translational levels by Fe deficiency. However, loss of NRT1.1 function alleviated Fe deficiency chlorosis, suggesting that downregulation of NRT1.1 by Fe deficiency favors plant tolerance to Fe deficiency. Further analysis showed that although disruption of NRT1.1 did not alter Fe levels in both the shoots and roots, it improved the reutilization of apoplastic Fe in shoots but not in roots. In addition, disruption of NRT1.1 prevented Fe deficiency‐induced apoplastic alkalization in shoots by inhibiting apoplastic H+ depletion via NO3− uptake. In vitro analysis showed that reduced pH facilitates release of cell wall‐bound Fe. Thus, foliar spray with an acidic buffer promoted the reutilization of Fe in the leaf apoplast to enhance plant tolerance to Fe deficiency, while the opposite was true for the foliar spray with a neutral buffer. Thus, downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. Our findings may provide a basis for elucidating the link between N and Fe nutrition in plants and insight to scrutinize the relevance of shoot‐expressed NRT1.1 to the plant response to stress. Significance Statement Our study shows that downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. 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Thus, foliar spray with an acidic buffer promoted the reutilization of Fe in the leaf apoplast to enhance plant tolerance to Fe deficiency, while the opposite was true for the foliar spray with a neutral buffer. Thus, downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. Our findings may provide a basis for elucidating the link between N and Fe nutrition in plants and insight to scrutinize the relevance of shoot‐expressed NRT1.1 to the plant response to stress. Significance Statement Our study shows that downregulation of the shoot‐part function of NRT1.1 prevents apoplastic alkalization to ensure the reutilization of apoplastic Fe under Fe‐deficient conditions. 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subjects Alkalizing
Apoplast
apoplastic pH
Buffers
Calcareous soils
Cell walls
Depletion
Disruption
Fe deficiency
Fe reutilization
Iron
Iron deficiency
nitrate
NRT1.1
Nutrient deficiency
Nutrition
Plant growth
Plant nutrition
Roots
shoot
Shoots
title Inhibition of shoot‐expressed NRT1.1 improves reutilization of apoplastic iron under iron‐deficient conditions
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