植物氮同位素组成与其影响因子的关系研究进展

doi:10.11733/j.issn.1007-0435.2012.06.001

›› 2012, Vol. 20 ›› Issue (6): 981-989.DOI: 10.11733/j.issn.1007-0435.2012.06.001

• 前沿进展 • 下一篇

植物氮同位素组成与其影响因子的关系研究进展

周咏春¹, 程希雷², 樊江文¹

1. 中国科学院地理科学与资源研究所, 北京 100101;
2. 辽宁省环境科学研究院, 辽宁沈阳 110031

收稿日期:2012-05-15 修回日期:2012-07-28 出版日期:2012-12-15 发布日期:2012-12-28
通讯作者: 樊江文
作者简介:周咏春(1982-),女,辽宁盖州人,博士,主要从事环境生态研究,E-mail: yongchuN₂005@126.com
基金资助:
国家自然科学基金项目(31070427);国家重点基础研究发展计划项目(2010CB950902);国家科技支撑计划(2009BAC61B01)资助

Research Progress of Relationships between Plant δ¹⁵N and Influence Factors (Review)

ZHOU Yong-chun¹, CHENG Xi-lei², FAN Jiang-wen¹

1. Institute of Geographic Sciences and Natural Resources Research, CAS, Beijing 100101, China;
2. Liaoning Academy of Environmental Sciences, Shenyang, Liaoning Province 110031, China

Received:2012-05-15 Revised:2012-07-28 Online:2012-12-15 Published:2012-12-28

摘要/Abstract

摘要： 植物氮同位素组成(δ¹⁵N)能够综合反映氮循环特征,研究植物δ¹⁵N与其影响因子的关系,有助于理解气候变化对生态系统氮循环的影响。通过概述菌根类型、叶片N含量、氮源、温度、降水、大气CO₂浓度、土壤N有效性等生物和非生物因素对植物氮同位素组成(δ¹⁵N)的影响以及植物δ¹⁵N随海拔的变化趋势,指出目前研究中存在的不足,提出在群落水平上,采用野外调查和控制试验相结合的方法,研究环境因素(尤其是大气CO₂浓度)对植物δ¹⁵N的影响规律及机理将是今后该领域的研究重点。

关键词: 植物氮同位素组成, 生物因素, 环境因素, 氮循环

Abstract: Plant δ¹⁵N can reflect comprehensively the characteristics of nitrogen cycling. The relationships between plant δ¹⁵N and influence factors are investigated to understand the effect of climate change on nitrogen cycling. In this study, the effects of biotic and abiotic factors (such as mycorrhiza types, foliar N, nitrogen sources, temperature, precipitation, atmospheric CO₂ concentration, and soil nitrogen availability,) on both plant δ¹⁵N and the altitude pattern of plant δ¹⁵N were reviewed. The influence of environmental factors, especially atmospheric CO₂ concentration, on community level plant δ¹⁵N was suggested to further emphasize investigations in the field using combined method of both field survey and controlled experiments.

Key words: Plant δ¹⁵N, Biotic factors, Environmental factors, Nitrogen cycling

中图分类号:

周咏春, 程希雷, 樊江文. 植物氮同位素组成与其影响因子的关系研究进展[J]. , 2012, 20(6): 981-989.

ZHOU Yong-chun, CHENG Xi-lei, FAN Jiang-wen. Research Progress of Relationships between Plant δ¹⁵N and Influence Factors (Review)[J]. , 2012, 20(6): 981-989.

0
/ / 推荐

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://manu40.magtech.com.cn/Jweb_cdxb/CN/10.11733/j.issn.1007-0435.2012.06.001

https://manu40.magtech.com.cn/Jweb_cdxb/CN/Y2012/V20/I6/981

参考文献

[1] Koba K, Hirobe M, Koyama L, et al. Natural ¹⁵N abundance of plants and soil N in a temperate coniferous forest[J]. Ecosystems,2003,6(5):457-469
[2] Robinson D. δ¹⁵N as an integrator of the nitrogen cycle[J]. Trends in Ecology & Evolution,2001,16(3):153-162
[3] Martinelli L, Piccolo M, Townsend A, et al. Nitrogen stable isotopic composition of leaves and soil: tropical versus temperate forests[J]. Biogeochemistry,1999,46(1):45-65
[4] Craine J M, Elmore A J, Aidar M P M, et al. Global patterns of foliar nitrogen isotopes and their relationships with climate, mycorrhizal fungi, foliar nutrient concentrations, and nitrogen availability[J]. New Phytologist,2009,183(4):980-992
[5] Couto-Vázquez A, González-Prieto S J. Effects of climate, tree age, dominance and growth on δ¹⁵N in young pinewoods[J]. Trees,2010,24(3):507-514
[6] Högberg P. ¹⁵N natural abundance in soil-plant systems[J]. New Phytologist,1997,137(2):179-203
[7] Michelsen A, Quarmby C, Sleep D, et al. Vascular plant ¹⁵N natural abundance in heath and forest tundra ecosystems is closely correlated with presence and type of mycorrhizal fungi in roots[J]. Oecologia,1998,115(3):406-418
[8] Craine J, Lee W, Bond W, et al. Environmental constraints on a global relationship among leaf and root traits of grasses[J]. Ecology,2005,86(1):12-19
[9] Pardo L H, Templer P H, Goodale C L, et al. Regional assessment of N saturation using foliar and root δ¹⁵N[J]. Biogeochemistry,2006,80(2):143-171
[10] Amundson R, Austin A, Schuur E, et al. Global patterns of the isotopic composition of soil and plant nitrogen[J]. Global Biogeochemical Cycles,2003,17(1):1031,10p
[11] 刘贤赵,王国安,李嘉竹,等.北京东灵山地区现代植物氮同位素组成及其对海拔梯度的响应[J].中国科学D辑:地球科学,2009,39(10):1347-1359
[12] 石伟琦,王国安,李晓林.丛枝菌根真菌对羊草气体交换和δ13C、δ¹⁵N的组成影响[J].核农学报,2008,22(3):353-358
[13] 刘晓宏,赵良菊,Gasaw M,等.东非大裂谷埃塞俄比亚段内C₃植物叶片δ¹³C和δ¹⁵N及其环境指示意义[J].科学通报,2007,52(2):199-206
[14] Mariotti A. Atmospheric nitrogen is a reliable standard for natural ¹⁵N abundance measurements[J]. Nature,1983,303(5919):685-687
[15] 苏波,韩兴国,黄建辉.¹⁵N自然丰度法在生态系统氮素循环研究中的应用[J].生态学报,1999,19(3):120-128
[16] 李玉中,Redmann R E,祝廷成,等.羊草草原豆科牧草生物固定量研究[J].草地学报,2002,10(3):164-166
[17] Shearer G, Kohl D. Estimates of N₂ fixation in ecosystems: the need for and basis of the ¹⁵N natural abundance method[M]//Rundel P W, Ehleringer J R, Nagy K A, eds. Stable isotopes in ecological research. Berlin: Springer-Verlag,1988:342-374
[18] Handley L, Raven J. The use of natural abundance of nitrogen isotopes in plant physiology and ecology[J]. Plant, Cell & Environment,1992,15(9):965-985
[19] Aranibar J N, Anderson I C, Epstein H E, et al. Nitrogen isotope composition of soils, C₃ and C₄ plants along land use gradients in southern Africa[J]. Journal of Arid Environments,2008,72(4):326-337
[20] Evans R. Physiological mechanisms influencing plant nitrogen isotope composition[J]. Trends in Plant Science,2001,6(3):121-126
[21] Dawson T E, Mambelli S, Plamboeck A H, et al. Stable isotopes in plant ecology[J]. Annual Review of Ecology and Systematics,2002,33:507-559
[22] Michelsen A, Schmidt I K, Jonasson S, et al. Leaf ¹⁵N abundance of subarctic plants provides field evidence that ericoid, ectomycorrhizal and non- and arbuscular mycorrhizal species access different sources of soil nitrogen[J]. Oecologia,1996,105(1):53-63
[23] Pate J S, Stewart G R, Unkovich M. ¹⁵N natural abundance of plant and soil components of a Banksia woodland ecosystem in relation to nitrate utilization, life form, mycorrhizal status and N₂-fixing abilities of component species[J]. Plant Cell and Environment,1993,16(4):365-373
[24] Schmidt S, Stewart G R. Waterlogging and fire impacts on nitrogen availability and utilization in a subtropical wet heathland (wallum)[J]. Plant Cell and Environment,1997,20(10):1231-1241
[25] Handley L L, Azcon R, Lozano J M R, et al. Plant δ¹⁵N associated with arbuscular mycorrhization, drought and nitrogen deficiency[J]. Rapid Communications in Mass Spectrometry,1999,13(13):1320-1324
[26] Hobbie E, Colpaert J. Nitrogen availability and colonization by mycorrhizal fungi correlate with nitrogen isotope patterns in plants[J]. New Phytologist,2003,157(1):115-126
[27] Smith S, Read D. Mycorrhizal symbiosis[M]. New York: Academic Press, 2008
[28] Hobbie E, Jumpponen A, Trappe J. Foliar and fungal ¹⁵N:¹⁴N ratios reflect development of mycorrhizae and nitrogen supply during primary succession: testing analytical models[J]. Oecologia,2005,146(2):258-268
[29] Hobbie E A, Macko S A, Williams M. Correlations between foliar δ¹⁵N and nitrogen concentrations may indicate plant-mycorrhizal interactions[J]. Oecologia,2000,122(2):273-283
[30] Yoneyama T, Fujihara S, Yagi K. Natural abundance of ¹⁵N in amino acids and polyamines from leguminous nodules: unique ¹⁵N enrichment in homospermidine[J]. Journal of Experimental Botany,1998,49(320):521
[31] Bergersen F, Peoples M, Turner G. Isotopic discriminations during the accumulation of nitrogen by soybeans[J]. Functional Plant Biology,1988,15(3):407-420
[32] Evans R, Bloom A, Sukrapanna S, et al. Nitrogen isotope composition of tomato (Lycopersicon esculentum Mill. cv. T-5) grown under ammonium or nitrate nutrition[J]. Plant, Cell & Environment,1996,19(11):1317-1323
[33] Nadelhoffer K J, Downs M R, Fry B. Sinks for ¹⁵N-enriched additions to an oak forest and a red pine plantation[J]. Ecological Applications,1999,9(1):72-86
[34] Högberg P, Högbom L, Schinkel H, et al. ¹⁵N abundance of surface soils, roots and mycorrhizas in profiles of European forest soils[J]. Oecologia,1996,108(2):207-214
[35] Codron J, Codron D, Lee-Thorp J, et al. Taxonomic, anatomical, and spatio-temporal variations in the stable carbon and nitrogen isotopic compositions of plants from an African savanna[J]. Journal of Archaeological Science,2005,32(12):1757-1772
[36] Sah S, Brumme R. Altitudinal gradients of natural abundance of stable isotopes of nitrogen and carbon in the needles and soil of a pine forest in Nepal[J]. Journal of Forest Science,2003,49(1):19-26
[37] 吴田乡,黄建辉.放牧对内蒙古典型草原生态系统植物及土壤δ¹⁵N的影响[J].植物生态学报,2010,34(2):160-169
[38] Bai E, Boutton T W, Liu F, et al. Spatial variation of the stable nitrogen isotope ratio of woody plants along a topoedaphic gradient in a subtropical savanna[J]. Oecologia,2009,159(3):493-503
[39] Alvarez-Clare S, Mack M C. Influence of precipitation on soil and foliar nutrients across nine Costa Rican forests[J]. Biotropica,2011,43(4):433-441
[40] Körner C. The nutritional status of plants from high altitudes[J]. Oecologia,1989,81(3):379-391
[41] 胡启武,宋明华,欧阳华,等.祁连山青海云杉叶片氮、磷含量随海拔变化特征[J].西北植物学报,2007,27(10):2072-2079
[42] Schmidt S, Stewart G. δ¹⁵N values of tropical savanna and monsoon forest species reflect root specialisations and soil nitrogen status[J]. Oecologia,2003,134(4):569-577
[43] Shearer G, Chien D. The nitrogen-15 abundance in a wide variety of soils[J]. Soil Science Society of America Journal,1978,42(6):899
[44] Shearer G, Kohl D H, Virginia R A, et al. Estimates of N₂ fixation from variation in the natural abundance of ¹⁵N in Sonoran desert ecosystems[J]. Oecologia,1983,56(2/3):365-373
[45] Jacot K, Lüscher A, N sberger J, et al. Symbiotic N₂ fixation of various legume species along an altitudinal gradient in the Swiss Alps[J]. Soil Biology and Biochemistry,2000,32(8/9):1043-1052
[46] Kohls S, van Kessel C, Baker D, et al. Assessment of N₂ fixation and N cycling by Dryas along a chronosequence within the forelands of the Athabasca Glacier, Canada[J]. Soil Biology and Biochemistry,1994,26(5):623-632
[47] Liu W G, Wang Z. Nitrogen isotopic composition of plant-soil in the Loess Plateau and its responding to environmental change[J]. Chinese Science Bulletin,2008,54(2):272-279
[48] Swap R, Aranibar J, Dowty P, et al. Natural abundance of ¹³C and ¹⁵N in C₃ and C₄ vegetation of southern Africa: patterns and implications[J]. Global Change Biology,2004,10(3):350-358
[49] Wang L, D’Odorico P, Ries L, et al. Patterns and implications of plant-soil δ¹³C and δ¹⁵N values in African savanna ecosystems[J]. Quaternary Research,2010,73(1):77-83
[50] Austin A T, Sala O E. Foliar δ¹⁵N is negatively correlated with rainfall along the IGBP transect in Australia[J]. Australian Journal of Plant Physiology,1999,26(3):293-295
[51] Aranibar J, Otter L, Macko S, et al. Nitrogen cycling in the soil-plant system along a precipitation gradient in the Kalahari sands[J]. Global Change Biology,2004,10(3):359-373
[52] Groffman P, Rice C, Tiedje J. Denitrification in a tallgrass prairie landscape[J]. Ecology,1993,74(3):855-862
[53] Peterjohn W, Schlesinger W. Factors controlling denitrification in a Chihuahuan desert ecosystem[J]. Soil Science Society of America Journal,1991,55(6):1694-1701
[54] Lloyd D. Aerobic denitrification in soils and sediments: From fallacies to factx[J]. Trends in Ecology & Evolution,1993,8(10):352-356
[55] Houlton B, Sigman D, Hedin L. Isotopic evidence for large gaseous nitrogen losses from tropical rainforests[J]. Proceedings of the National Academy of Sciences,2006,103(23):8745
[56] Houlton B Z, Sigman D M, Schuur E A G, et al. A climate-driven switch in plant nitrogen acquisition within tropical forest communities[J]. Proceedings of the National Academy of Sciences,2007,104(21):8902
[57] Billings S A, Schaeffer S M, Zitzer S, et al. Alterations of nitrogen dynamics under elevated carbon dioxide in an intact Mojave desert ecosystem: evidence from nitrogen-15 natural abundance[J]. Oecologia,2002,131(3):463-467
[58] Horz H P, Barbrook A, Field C B, et al. Ammonia-oxidizing bacteria respond to multifactorial global change[J]. Proceedings of the National Academy of Sciences,2004,101(42):15136-15141
[59] 林先贵,胡君利,褚海燕,等.土壤氨氧化细菌对大气CO₂浓度增高的响应[J].农村生态环境,2005,21(1):44-46
[60] Smith S D, Huxman T E, Zitzer S F, et al. Elevated CO₂ increases productivity and invasive species success in an arid ecosystem[J]. Nature,2000,408(6808):79-81
[61] Ainsworth E A, Long S P. What have we learned from 15 years of free-air CO₂ enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO₂[J]. New Phytologist,2005,165(2):351-372
[62] Zak D R, Pregitzer K S, Curtis P S, et al. Atmospheric CO₂ and the composition and function of soil microbial communities[J]. Ecological Applications,2000,10(1):47-59
[63] Mikan C J, Zak D R, Kubiske M E, et al. Combined effects of atmospheric CO₂ and N availability on the belowground carbon and nitrogen dynamics of aspen mesocosms[J]. Oecologia,2000,124(3):432-445
[64] Taylor J, Ball A. The effect of plant material grown under elevated CO₂ on soil respiratory activity[J]. Plant and Soil,1994,162(2):315-318
[65] Zak D R, Pregitzer K S, Curtis P S, et al. Elevated atmospheric CO₂ and feedback between carbon and nitrogen cycles[J]. Plant and Soil,1993,151(1):105-117
[66] 庞静,朱建国,谢祖彬.大气CO₂体积分数升高对植物N素吸收的影响[J].生态环境,2005,14(3):429-433
[67] BassiriRad H, Griffin K L, Reynolds J F, et al. Changes in root NH⁺₄ and NO₃^- absorption rates of loblolly and ponderosa pine in response to CO₂ enrichment[J]. Plant and Soil,1997,190(1):1-9
[68] Garten C, Van Miegroet H. Relationships between soil nitrogen dynamics and natural ¹⁵N abundance in plant foliage from Great Smoky Mountains National Park[J]. Canadian Journal of Forest Research,1994,24(8):1636-1645
[69] Vitousek P, Shearer G, Kohl D. Foliar ¹⁵N natural abundance in Hawaiian rainforest: patterns and possible mechanisms[J]. Oecologia,1989,78(3):383-388
[70] Yi X, Yang Y. Enrichment of stable carbon and nitrogen isotopes of plant populations and plateau pikas along altitudes[J]. Journal of Animal and Feed Sciences,2006,15(4):661-667
[71] Binkley D, Hart S. The components of nitrogen availability assessments in forest soils[M]//Stewart B A, ed. Advances in soil science.New York: Springer Verlag,1989,10:57-112
[72] Garten C. Variation in foliar ¹⁵N abundance and the availability of soil nitrogen on Walker Branch watershed[J]. Ecology,1993,74(7):2098-2113
[73] Miller A, Bowman W. Variation in nitrogen-15 natural abundance and nitrogen uptake traits among co-occurring alpine species: do species partition by nitrogen form? [J]. Oecologia,2002,130(4):609-616
[74] Fan J W, Shao Q Q, Liu J Y, et al. Assessment of effects of climate change and grazing activity on grassland yield in the Three Rivers Headwaters Region of Qinghai-Tibet Plateau, China[J]. Environmental Monitoring and Assessment,2010,170(1/4):571-584
[75] IPCC. Climate chage 2001: Synthesis report. Inter-governmental panel on climate change. Cambridge: Cambridge University Press, 2001

植物氮同位素组成与其影响因子的关系研究进展

Research Progress of Relationships between Plant δ¹⁵N and Influence Factors (Review)

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 9

编辑推荐

Metrics

本文评价

[1]	姚世庭, 芦光新, 周华坤, 张海娟, 颜珲璘, 王军邦. 模拟增温对高寒草甸土壤性质的影响[J]. 草地学报, 2021, 29(S1): 218-224.
[2]	贾向阳, 田艳丽, 陆文涛, 种培芳, 刘晟彤. CO₂浓度升高及降水变化对红砂植物碳氮特征的影响[J]. 草地学报, 2020, 28(2): 429-436.
[3]	刘建国, 刘卫国. 微生物介导的氮循环过程研究进展[J]. 草地学报, 2018, 26(2): 277-283.
[4]	何树斌, 王燚, 程宇阳, 黄文静, 唐驯林, 庞仁江, 李菁, 呼天明, 龙明秀. 从枝菌根真菌与柳枝稷协同固碳机制及对土壤碳氮循环的调控[J]. 草地学报, 2016, 24(4): 802-806.
[5]	刘碧荣, 王常慧, 黄建辉, 何念鹏, 王其兵, 董宽虎. ¹⁵N库稀释法和¹⁵N示踪法在草地生态系统氮转化过程研究中的应用——方法与进展[J]. 草地学报, 2014, 22(6): 1153-1162.
[6]	王倩, 程积民, 万惠娥. 环境因素影响草地柠条生长的主成分及典型相关分析[J]. , 2009, 17(3): 321-326.
[7]	黄文娟, 于海多, 赵兰坡. 松嫩羊草草原植被与土壤的耦合关系[J]. , 2006, 14(1): 62-66.
[8]	呼天明, 王培, 姚爱兴. 多年生黑麦草/白三叶人工草地饲用价值及其与环境的关系[J]. , 2001, 9(2): 87-91,105.
[9]	关秀清, 杜千有, 于井朝. 内蒙古草原羊草根际联合固氮菌的分离鉴定及其生理生化特性研究[J]. , 1997, 5(2): 101-107.

植物氮同位素组成与其影响因子的关系研究进展

Research Progress of Relationships between Plant δ15N and Influence Factors (Review)

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 9

编辑推荐

Metrics

本文评价

Research Progress of Relationships between Plant δ¹⁵N and Influence Factors (Review)