Why are Nitrogen Concentrations in Plant Tissues Lower under Elevated CO₂? A Critical Examination of the Hypotheses

Why are Nitrogen Concentrations in Plant Tissues Lower under Elevated CO₂? A Critical Examination of the Hypotheses

Plants grown under elevated atmospheric [CO₂] typically have decreased tissue concentrations of N compared with plants grown under current ambient [CO₂]. The physiological mechanisms responsible for this phenomenon have not been definitely established, although a considerable number of hypotheses ha...

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Veröffentlicht in:Journal of integrative plant biology 2008-11, Vol.50 (11), p.1365-1374
Hauptverfasser: Taub, Daniel R, Wang, Xianzhong
Format: Artikel
Sprache:eng
Schlagworte:
Biological Transport - drug effects
carbon dioxide
Carbon Dioxide - toxicity
dilution
elevated CO
elevated CO2
graphical vector analysis
nitrogen
Nitrogen - metabolism
Plant Transpiration - drug effects
plants
Plants - drug effects
Plants - metabolism
root uptake
tissue concentrations
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Wang, Xianzhong
description Plants grown under elevated atmospheric [CO₂] typically have decreased tissue concentrations of N compared with plants grown under current ambient [CO₂]. The physiological mechanisms responsible for this phenomenon have not been definitely established, although a considerable number of hypotheses have been advanced to account for it. In this review we discuss and critically evaluate these hypotheses. One contributing factor to the decreases in tissue N concentrations clearly is dilution of N by increased photosynthetic assimilation of C. In addition, studies on intact plants show strong evidence for a general decrease in the specific uptake rates (uptake per unit mass or length of root) of N by roots under elevated CO₂. This decreased root uptake appears likely to be the result both of decreased N demand by shoots and of decreased ability of the soil-root system to supply N. The best-supported mechanism for decreased N supply is a decrease in transpiration-driven mass flow of N in soils due to decreased stomatal conductance at elevated CO₂, although some evidence suggests that altered root system architecture may also play a role. There is also limited evidence suggesting that under elevated CO₂, plants may exhibit increased rates of N loss through volatilization and/or root exudation, further contributing to lowering tissue N concentrations.
doi_str_mv 10.1111/j.1744-7909.2008.00754.x
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In addition, studies on intact plants show strong evidence for a general decrease in the specific uptake rates (uptake per unit mass or length of root) of N by roots under elevated CO₂. This decreased root uptake appears likely to be the result both of decreased N demand by shoots and of decreased ability of the soil-root system to supply N. The best-supported mechanism for decreased N supply is a decrease in transpiration-driven mass flow of N in soils due to decreased stomatal conductance at elevated CO₂, although some evidence suggests that altered root system architecture may also play a role. 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source MEDLINE; Wiley Online Library Journals Frontfile Complete; Alma/SFX Local Collection
subjects Biological Transport - drug effects
carbon dioxide
Carbon Dioxide - toxicity
dilution
elevated CO
elevated CO2
graphical vector analysis
nitrogen
Nitrogen - metabolism
Plant Transpiration - drug effects
plants
Plants - drug effects
Plants - metabolism
root uptake
tissue concentrations
title Why are Nitrogen Concentrations in Plant Tissues Lower under Elevated CO₂? A Critical Examination of the Hypotheses
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