Allocation patterns of nonstructural carbohydrates in response to CO2 elevation and nitrogen deposition in Cunninghamia lanceolata saplings

Stored nonstructural carbohydrates (NSC) indicate a balance between photosynthetic carbon (C) assimilation and growth investment or loss through respiration and root exudation. They play an important role in plant function and whole-plant level C cycling. CO 2 elevation and nitrogen (N) deposition,...

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Bibliographic Details
Published in:Journal of forestry research 2023-02, Vol.34 (1), p.87-98
Main Authors: Zheng, Wenhui, Li, Renshan, Yang, Qingpeng, Zhang, Weidong, Huang, Ke, Guan, Xin, Chen, Longchi, Yu, Xin, Wang, Qingkui, Wang, Silong
Format: Article
Language:English
Subjects:
Assimilation
Biomass
Biomedical and Life Sciences
Carbohydrates
Carbon dioxide
Cunninghamia lanceolata
Deposition
Environmental changes
Environmental effects
Exudation
Forest ecosystems
Forestry
Life Sciences
Nitrogen
Organs
Original Paper
Photosynthesis
Pine needles
Reserves
Roots
Terrestrial ecosystems
Tradeoffs
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Summary:Stored nonstructural carbohydrates (NSC) indicate a balance between photosynthetic carbon (C) assimilation and growth investment or loss through respiration and root exudation. They play an important role in plant function and whole-plant level C cycling. CO 2 elevation and nitrogen (N) deposition, which are two major environmental issues worldwide, affect plant photosynthetic C assimilation and C release in forest ecosystems. However, information regarding the effect of CO 2 elevation and N deposition on NSC storage in different organs remains limited, especially regarding the trade-off between growth and NSC reserves. Therefore, here we analyzed the variations in the NSC storage in different organs of Chinese fir ( Cunninghamia lanceolata ) under CO 2 elevation and N addition and found that NSC concentrations and contents in all organs of Chinese fir saplings increased remarkably under CO 2 elevation. However, N addition induced differential accumulation of NSC among various organs. Specifically, N addition decreased the NSC concentrations of needles, branches, stems, and fine roots, but increased the NSC contents of branches and coarse roots. The increase in the NSC contents of roots was more pronounced than that in the NSC content of aboveground organs under CO 2 elevation. The role of N addition in the increase in the structural biomass of aboveground organs was greater than that in the increase in the structural biomass of roots. This result indicated that a different trade-off between growth and NSC storage occurred to alleviate resource limitations under CO 2 elevation and N addition and highlights the importance of separating biomass into structural biomass and NSC reserves when investigating the effects of environmental change on biomass allocation.
ISSN:1007-662X
1993-0607
DOI:10.1007/s11676-022-01533-x