内蒙古草原常见植物叶片δ~(13)C和δ~(15)N对环境因子的响应
Response patterns of foliar δ~(13)C and δ~(15)N to environmental factors for the dominant plants in Inner Mongolia steppe, China
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文摘
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在中国东北样带沿线的内蒙古草原地区采集了一些常见植物的叶片样品,并测定其δ~(13)C和δ~(15)N值,分析了其统计学特征以及对环境因子(年平均降雨量和温度)的响应模式。发现东北样带草原区同时存在C_3和C_4两种不同光合途径的植物,但是C _3植物占主导地位,C_4植物数量有限。C_3植物叶片δ~(13)C随着年平均降雨量和年平均温度的升高而显著降低,反映了此区域C_3植物δ~(13)C受控于降水量和温度。C_4植物的叶片δ~(13)C值随着降雨量的增多而有轻微升高的趋势,但是C_4植物的叶片δ~(13)C值对年平均温度的响应不敏感。不论对C_3植物还是C_4植物而言,叶片δ~(15)N都随降雨量增加而显著降低,即干旱区的植物叶片δ~(15)N大于湿润地区,这说明降水是影响植物叶片δ~(15)N的一个重要因素。然而两者叶片δ~(15)N对温度的响应不敏感。 |
其他语种文摘
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The determination of plant carbon (C) isotopic concentration is related to the C assimilation and diffusion of CO_2 influenced by water stress. In addition, the determination of plant nitrogen (N) isotopic concentration is related to the availability of nutrients and water, and is indicative of N cycling on different spatial and temporal scales. The question arises as to whether a relationship exists in the processing of C and N by vegetation across various physical environments in temperate steppes as evidenced by the natural abundances of C and N in foliage (δ~(13)C and δ~(15)N). Given the strong precipitation and temperature variation, Inner Mongolia is an ideal region for this study. The regional patterns of foliar δ~(13)C and δ~(15)N along the Northeast China Transect (NECT) in Inner Mongolia steppe, and their relationship with environmental factors, which are mean annual precipitation (MAP) and mean annual temperature (MAT), have been studied. We collected 158 samples, which included 18 species of C_3 plants and 5 species of C_4 plants. The δ~(13)C values of C_3 plants in this region range from -28.87‰ to -22.53‰, while those in C_4 vary from - 14.06‰ to -11.64‰. The δ~(15)N values of plants in this region range from -2.63‰ to 8.57‰ with a mean value of 2.13%o, and most values (80% of all data) are higher than 0‰. Our results show that δ~(13)C values in C_3 plants decrease significantly with increasing MAP (R~2 = 0.549, P< 0.001), such that the coefficient of δ~(13)C-MAP is -1.16‰/100 mm. However, a positive linear relationship exists between the δ~(13)C values of C_4 plants and MAP (R~2 = 0.188,P<0.05). Foliar δ~(13)C values of C_3 plants also decrease significantly with increasing MAT (R~2 = 0.549, P<0.05), such that the coefficient of δ~(13)C-MAT is -0.14‰/1℃. However, MAT does not significantly affect the δ~(13)C values of C_4 plants (R~2 = 0.032, P = 0.432). The δ~(15)N values decrease significantly with increasing MAP, both for C_3 plants (R~2 = 0.373, P<0.001) and C_4 plants (R~2 = 0.319, P<0.01); i.e., plant species occupying a dry habitat has a higher δ~(15)N value as compared to species growing in wet environments, irrespective of whether they are C_3 or C_4 plants. However, MAT does not significantly affect the δ~(15)N values of C_3(R~2 = 0.373, P = 0.053) and C_4 plants (R~2 = 0.023, P= 0.514). Therefore, our conclusions are that the dominant species in this region are C_3 plants, and the foliar δ~(13)C of C_3 plants in this region is dominated by MAP and MAT, and that of C_4 plants is only affected by MAP. Furthermore, both for C_3 and C_4 plants, MAP is an important factor affecting the foliar δ~(15)N, while MAT does not significantly affect the foliar δ~(15)N values of plants in Inner Mongolia. |
来源
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生态学报
,2016,36(1):235-243 【核心库】
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DOI
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10.5846/stxb201405261081
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关键词
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稳定性碳同位素
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稳定性氮同位素
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温带草原
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样带
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N循环
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水分利用效率
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地址
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中国科学院大学,资源与环境学院, 北京, 100049
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语种
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中文 |
文献类型
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研究性论文 |
ISSN
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1000-0933 |
基金
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国家自然科学基金资助项目
;
中国科学院知识创新工程重要方向项目
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文献收藏号
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CSCD:5611108
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参考文献 共
49
共3页
|
1.
Farquhar G D. On the relationship between carbon isotope discrimination and the intercellular carbon dioxide concentration in leaves.
Australian Journal of Plant Physiology,1982,9(2):121-137
|
被引
297
次
|
|
|
|
2.
Stewart G R. ~(13)C natural abundance in plant communities along a rainfall gradient: a biological integrator of water availability.
Australian Journal of Plant Physiology,1995,22(1):51-55
|
被引
42
次
|
|
|
|
3.
Ehleringer J R. Variation in leaf carbon isotope discrimination in Encelia farinosa: implications for growth, competition,and drought survival.
Oecologia,1993,95(3):340-346
|
被引
7
次
|
|
|
|
4.
Chen S P. Variations in life-form composition and foliar carbon isotope discrimination among eight plant communities under different soil moisture conditions in the Xilin River Basin, Inner Mongolia, China.
Ecological Research,2005,20(2):167-176
|
被引
17
次
|
|
|
|
5.
Seibt U. Carbon isotopes and water use efficiency: sense and sensitivity.
Oecologia,2008,155(3):441-454
|
被引
15
次
|
|
|
|
6.
Corcuera L. Phenotypic plasticity in Pinus pinaster δ~(13)C: environment modulates genetic variation.
Annals of Forest Science,2010,67(8):812-812
|
被引
2
次
|
|
|
|
7.
Prentice I C. Evidence of a universal scaling relationship for leaf CO_2 drawdown along an aridity gradient.
New Phytologist,2011,190(1):169-180
|
被引
7
次
|
|
|
|
8.
Liu Y J. Foliar δ~(13)C response patterns along a moisture gradient arising from genetic variation and phenotypic plasticity in grassland species of Inner Mongolia.
Ecology and Evolution,2013,3(2):262-267
|
被引
2
次
|
|
|
|
9.
刘艳杰. 降雨量对大针茅水分利用效率的影响.
中国科学院研究生院学报,2013,30(3):334-338
|
被引
1
次
|
|
|
|
10.
Letts M G. Drought stress ecophysiology of shrub and grass functional groups on opposing slope aspects of a temperate grassland valley.
Botany,2010,88(9):850-866
|
被引
4
次
|
|
|
|
11.
Liu Y J. Habitat-specific differences in plasticity of foliar δ~(13)C in temperate steppe grasses.
Ecology and Evolution,2014,4(5):648-655
|
被引
2
次
|
|
|
|
12.
Swap R J. Natural abundance of ~(13)C and ~(15)N in C_3 and C_4 vegetation of southern Africa: patterns and implications.
Global Change Biology,2004,10(3):350-358
|
被引
27
次
|
|
|
|
13.
王国安. 中国北方黄土区C4植物稳定碳同位素组成的研究.
中国科学D辑,2005,35(12):1174-1179
|
被引
16
次
|
|
|
|
14.
Wang G A. Variations in carbon isotope ratios of plants across a temperature gradient along the 400 mm isoline of mean annual precipitation in north China and their relevance to paleovegetation reconstruction.
Quaternary Science Reviews,2013,63:83-90
|
被引
18
次
|
|
|
|
15.
Panek J A. Stable carbon isotopes as indicators of limitations to forest growth imposed by climate stress.
Ecological Applications,1997,7(3):854-863
|
被引
12
次
|
|
|
|
16.
Tilman D.
Plant Strategies and the Dynamics and Structure of Plant Communities,1988
|
被引
72
次
|
|
|
|
17.
Robinson D. δ~(15)N as an integrator of the nitrogen cycle.
Trends in Ecology & Evolution,2001,16(3):153-162
|
被引
76
次
|
|
|
|
18.
Aranibar J N. Nitrogen cycling in the soil-plant system along a precipitation gradient in the Kalahari sands.
Global Change Biology,2004,10(3):359-373
|
被引
24
次
|
|
|
|
19.
刘贤赵. 陆生植物氮同位素组成与气候环境变化研究进展.
地球科学进展,2014,29(2):216-226
|
被引
17
次
|
|
|
|
20.
Martinelli L A. Nitrogen stable isotopic composition of leaves and soil: Tropical versus temperate forests.
Biogeochemistry,1999,46(1/3):45-65
|
被引
25
次
|
|
|
|
|