Elevated CO2 concentration induces photosynthetic down-regulation with changes in leaf structure, non-structural carbohydrates and nitrogen content of soybean

Understanding the mechanisms of crops in response to elevated CO.sub.2 concentrations is pivotal to estimating the impacts of climate change on the global agricultural production. Based on earlier results of the "doubling-CO.sub.2 concentration" experiments, many current climate models may...

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Bibliographic Details
Published in:BMC plant biology 2019-06, Vol.19 (1), p.1-18, Article 255
Main Authors: Zheng, Yunpu, Li, Fei, Hao, Lihua, Yu, Jingjin, Guo, Lili, Zhou, Haoran, Ma, Chao, Zhang, Xixi, Xu, Ming
Format: Article
Language:English
Subjects:
Agricultural ecosystems
Agricultural production
Agriculture
Atmospheric models
Biochemistry
Carbohydrate metabolism
Carbohydrates
Carbon dioxide
Carboxylation
Cell division
Chemical properties
Climate change
Climate models
CO2 enhancement
Conductance
Crop growth
Crops
Down regulation
Ecosystems
Efficiency
Electron transport
Environmental changes
Fertilization
Global temperature changes
Glycine max
Growth chambers
Influence
Leaves
Mesophyll
N availability
Nitrogen
Nitrogen metabolism
Non-structural carbohydrates
Photochemicals
Photosynthesis
Physiological aspects
Physiology
Plant biochemistry
Resistance
Respiration
Soybean crops
Soybeans
Spatial distribution
Stomata
Stomatal conductance
Stomatal traits
Wheat
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Summary:Understanding the mechanisms of crops in response to elevated CO.sub.2 concentrations is pivotal to estimating the impacts of climate change on the global agricultural production. Based on earlier results of the "doubling-CO.sub.2 concentration" experiments, many current climate models may overestimate the CO.sub.2 fertilization effect on crops, and meanwhile, underestimate the potential impacts of future climate change on global agriculture ecosystem when the atmospheric CO.sub.2 concentration goes beyond the optimal levels for crop growth. This study examined the photosynthetic response of soybean (Glycine max (L.) Merr.) to elevated CO.sub.2 concentration associated with changes in leaf structure, non-structural carbohydrates and nitrogen content with environmental growth chambers where the CO.sub.2 concentration was controlled at 400, 600, 800, 1000, 1200, 1400, 1600 ppm. We found CO.sub.2-induced down-regulation of leaf photosynthesis as evidenced by the consistently declined leaf net photosynthetic rate (A.sub.n) with elevated CO.sub.2 concentrations. This down-regulation of leaf photosynthesis was evident in biochemical and photochemical processes since the maximum carboxylation rate (V.sub.cmax) and the maximum electron transport rate (J.sub.max) were dramatically decreased at higher CO.sub.2 concentrations exceeding their optimal values of about 600 ppm and 400 ppm, respectively. Moreover, the down-regulation of leaf photosynthesis at high CO.sub.2 concentration was partially attributed to the reduced stomatal conductance (G.sub.s) as demonstrated by the declines in stomatal density and stomatal area as well as the changes in the spatial distribution pattern of stomata. In addition, the smaller total mesophyll size (palisade and spongy tissues) and the lower nitrogen availability may also contribute to the down-regulation of leaf photosynthesis when soybean subjected to high CO.sub.2 concentration environment. Down-regulation of leaf photosynthesis associated with the changes in stomatal traits, mesophyll tissue size, non-structural carbohydrates, and nitrogen availability of soybean in response to future high atmospheric CO.sub.2 concentration and climate change.
ISSN:1471-2229
1471-2229
DOI:10.1186/s12870-019-1788-9