Responses of non-structural carbohydrates and C∶N∶P stoichiometry of Agropyron mongolicum to nitrogen addition

doi:10.11686/cyxb2022045

Abstract

Abstract:

This research investigated the physiological and ecological adaptive mechanisms of Agropyron mongolicum to nitrogen （N） addition. Soluble sugar， starch， carbon （C）， N and phosphorus （P） contents in roots and leaves of A. mongolicum were determined at different levels of nitrogen addition （0， 0.8， 1.6， 2.4 and 4.0 g N·m^-2·yr^-1）. The effects of N addition on the non-structural carbohydrate （NSCs） content and the C∶N∶P stoichiometry in leaves and roots of A. mongolicum were analyzed. The results showed that adding the appropriate amount of N （2.4 g N·m^-2·yr^-1） favoured the accumulation of NSCs and C， N and P contents in the leaves and roots of A. mongolicum， and the responses of different organs were significantly different （P<0.05）. Leaf NSCs content was significantly positively correlated with leaf N， soluble sugar， starch content， C∶P and N∶P； And significantly negatively correlated with leaf P content and C∶N （P<0.05）. Root NSCs content was significantly positively correlated with root C， N content， C∶P， N∶P， soluble sugar and starch content （P<0.05）. Leaf and root N∶P were the main factors affecting the accumulation of soluble sugar； The N content of roots and P content of leaves collectively affected starch synthesis； Leaf P content， root N content and root N∶P were collectively the major factors affecting the accumulation of NSCs in A. mongolicum. In summary， appropriate N addition relieved N limitation， while the addition of large amounts of N produced an imbalance between N and P and exacerbated P limitation. Therefore， optimization of nitrogen fertilizer application and appropriate phosphorus addition should be considered in the establishment and management of artificial A. mongolicum grasslands and in the restoration of degraded grasslandsunder future climate change scenarios.

Key words: leaf, root, non-structural carbohydrates, stoichiometry, nutrient strategy

Ai-yun XU, Li-hua ZHANG, Xiao-jia WANG, Chong MA, Yuan-jing LI, Bing CAO. Responses of non-structural carbohydrates and C∶N∶P stoichiometry of Agropyron mongolicum to nitrogen addition[J]. Acta Prataculturae Sinica, 2023, 32(2): 35-43.

Figures/Tables 5

Fig.1 Accumulation of non-structural carbohydrates in leaf and root of A. mongolicum under different N addition treatments

Fig.2 C，N and P contents and stoichiometric ratio in leaf and root of A. mongolicum under different N addition gradients

Fig.3 Correlations coefficients of NSCs variables and C， N， P content and stoichiometry in leaf and root

Table 1 Stepwise regression analysis of NSCs variables and C， N， P content and stoichiometry in leaf and root

指标 Index	回归方程 Model	R²	F	P
SS	$Y S S = 518.73 + 40.86 X L N / P * * * + 22.26 X R N / P * * - 1.30 X L C *$	0.817	29.260	<0.001
ST	$Y S T = 52.68 + 11.66 X R N * * - 29.36 X L P *$	0.578	14.010	<0.001
NSCs	$Y N S C s = 249.98 + 43.20 X R N * * * - 141.14 X L P * *$	0.765	31.848	<0.001

Table 1 Stepwise regression analysis of NSCs variables and C， N， P content and stoichiometry in leaf and root

指标 Index	回归方程 Model	R²	F	P
SS	$Y S S = 518.73 + 40.86 X L N / P * * * + 22.26 X R N / P * * - 1.30 X L C *$	0.817	29.260	<0.001
ST	$Y S T = 52.68 + 11.66 X R N * * - 29.36 X L P *$	0.578	14.010	<0.001
NSCs	$Y N S C s = 249.98 + 43.20 X R N * * * - 141.14 X L P * *$	0.765	31.848	<0.001

Fig.4 Structural equation modeling showing the impact path of nitrogen addition on NSCs of A. mongolicum

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