Progress of Research on Relationships between Terrestrial Plant Nitrogen Isotope Composition and Climate Environment Change
Received date: 2013-10-08
Revised date: 2014-01-21
Online published: 2014-02-10
Copyright
Recently, since stable nitrogen composition (15N) in plants records abundant climate and environment information (such as information on temperature, humidity, precipitation and environment isotopes composition), it has been widely used in paleoclimate studies and becomes a powerful tool for understanding paleoenvironment reconstruction and modern climate change. However, some potential uncertainties have always involved in the reconstruction of paleoclimate and paleoenvironment. Among them, the most dominant uncertainty is due to our poor understanding of the relationship between nitrogen isotope ratios of plants and climatic factors, particularly the relationships among nitrogen isotope ratios, temperature and precipitation. Based on summarizing plant 15N fractionation and nitrogen isotope distribution of different N sources, the effects of environmental factors, e.g., temperature, precipitation, atmospheric CO2 concentration, and altitude on terrestrial plant 15N and their mechanism were analyzed in this paper. Furthermore, the existing and disputed problems in nitrogen isotope study were discussed, and the future trends of nitrogen isotope technique in global change research were prospected. It is pointed out that the technology of nitrogen isotope in plants could not only be used to rebuild paleoclimate (such as reconstructing the sequences of atmospheric CO2 concentration changes), revealing the trends of climate changes, but also in a certain time and space to reflect comprehensively the characteristics of nitrogen cycling in ecosystem. This will make more readers have a more profound understanding of the field and eventually broaden the development of the field.
Xianzhao Liu , Yong Zhang , Qing Su , Yanlin Tian , Qing Wang , Bin Quan . Progress of Research on Relationships between Terrestrial Plant Nitrogen Isotope Composition and Climate Environment Change[J]. Advances in Earth Science, 2014 , 29(2) : 216 -226 . DOI: 1001-8166(2014)02-0216-11
| [1] | Zhu H F, Shao X M, Yin Z Y, et al. August temperature variability in the southeastern Tibetan Plateau since AD 1385 inferred from tree rings[J].Palaeogeography, Palaeoclimatology, Palaeoecology, 2011, 305: 84-92. |
| [2] | Yuan Zineng, Xing Lei, Zhang Hailong, et al. Progress of biomarker stable hydrogen isotope and its application to marine paleoenvironmental reconstruction[J]. Advances in Earth Science, 2012, 27(3): 276-283. |
| [2] | [袁子能, 邢磊, 张海龙, 等. 生物标志物稳定氢同位素研究进展及在海洋古环境重建中的应用[J]. 地球科学进展, 2012, 27(3): 276-283.] |
| [3] | Hafida E B, Patterson R T. Influence of cellulose oxygen isotope variability in sub-fossil Sphagnum and plant macrofossil components on the reliability of paleoclimate records at the Mer Bleue Bog, Ottawa, Ontario, Canada[J]. Organic Geochemistry, 2012, 43: 39-49. |
| [4] | Meytal B H, Rebecca S R, Susan J C, et al. Evidence from chlorin nitrogen isotopes for alternating nutrient regimes in the Eastern Mediterranean Sea[J]. Earth and Planetary Science Letters, 2010, 290(1/2): 102-107. |
| [5] | Verleyen E, Hodgson D A, Sabbe K, et al. Post-glacial regional climate variability along the East Antarctic coastal margin#cod#x02014;Evidence from shallow marine and coastal terrestrial records[J]. Earth-Science Reviews, 2011, 104(4): 199-212. |
| [6] | Valery J T,Zewdu E, Albert C,et al. Reconstructing palaeoenvironment from #cod#x003b4;13C and #cod#x003b4;15N ransects values of soil organic matter: A calibration from arid and wetter elevation transects in Ethiopia[J]. Geoderma, 2008, 147:197-210. |
| [7] | Li Chaozhu, Zhang Xiao, Xu Yuanbin, et al. Reviews on the reconstructed C3/C4 variations since the Late Miocene in the Chinese Loess Plateau[J]. Advances in Earth Science, 2012, 27(3): 284-291. |
| [7] | [李朝柱, 张晓, 许元斌, 等. 黄土高原地区晚中新世以来陆地植被C3/C4植物相对丰度演化研究进展[J]. 地球科学进展, 2012, 27(3): 284-291.] |
| [8] | Reynard L M, Hedges R E. Stable hydrogen isotopes of bone collagen in palaeodietary and palaeoenvironmental reconstruction[J]. Journal of Archaeological Science, 2008, 35: 1 934-1 942. |
| [9] | Wang G A, Li J Z, Liu X Z, et al. 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[J]. Quaternary Science Reviews, 2013, 63: 83-90. |
| [10] | Ann-Kathrin S, Michael Z, Bj#cod#x000f6;rn B, et al. The late Quaternary loess record of Tokaj, Hungary: Reconstructing palaeoenvironment, vegetation and climate using stable C and N isotopes and biomarkers[J]. Quaternary International, 2011, 240: 52-61. |
| [11] | Doroth#cod#x000e9;e D, Herv#cod#x000e9; B, Anne B, et al. Carbon and nitrogen isotopic composition of red deer (Cervus elaphus) collagen as a tool for tracking palaeoenvironmental change during the Late-Glacial and Early Holocene in the northern Jura (France)[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2003, 195: 375-388. |
| [12] | Liu Xiaohong, Zhao Liangju, Gasaw M, et al. Foliar #cod#x003b4;13C and #cod#x003b4;15N values of C3 plants in the Ethiopia Rift Valley and their environmental controls[J]. Chinese Science Bulletin, 2007, 52(2): 199-206. |
| [12] | [刘晓宏, 赵良菊, Gasaw M, 等. 东非大裂谷埃塞俄比亚段内C-3植物叶片#cod#x003b4;13C和#cod#x003b4;15N及其环境指示意义[J]. 科学通报, 2007, 52(2): 199-206.] |
| [13] | 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. |
| [14] | Robinson D. #cod#x003b4;15N as an integrator of the nitrogen cycle[J]. Trends in Ecology & Evolution, 2001, 16(3): 153-162. |
| [15] | Liu Xianzhao, Wang Guoan, Li Jiazhu, et al. Nitrogen isotope composition characteristics of modern plants and their variations along an altitudinal gradient in Dongling Mountain in Beijing[J]. Science in China (Series D), 2009, 39(10):128-140. |
| [15] | [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, 2009, 39(10): 128-140.] |
| [16] | Amundson R, Austin A T, Schur E A, et al. Global patterns of the isotopic composition of soil and plant nitrogen[J]. Global Biogeochemical Cycles,2003,17(1): 1 031-1 038. |
| [17] | Tcherkez G, Hodges M. How stable isotopes may help to elucidate primary nitrogen metabolism and its interaction with (photo) respiration in C3 leaves[J]. Journal of Experimental Botany, 2008, 59: 941-953. |
| [18] | Ledgard S F, Wook C, Bergersen F J. Isotopic fractionation during reduction of nitrate and nitrite by extracts of spinach leaves[J]. Australian Journal of Plant Physiology, 1985, 12: 631-640. |
| [19] | Evans R D. Physiological mechanisms influencing plant nitrogen isotope composition[J]. Trends in Plant Science, 2001, 6: 121-126. |
| [20] | Mariotti A, Mariotti F, Champigny M L, et al. Nitrogen isotope fractionation associated with nitrate reductase activity and uptake of NO-3 by pearl millet[J]. Plant Physiology, 1982, 69:880-884. |
| [21] | Hgberg P, Hgberg M N, Quist M E, et al. Nitrogen isotope fractionation during nitrogen uptake by ectomycorrhizal and non-mycorrhizal Pinus sylvestris[J]. New Phytologist, 1999, 142: 569-576. |
| [22] | Peterson B J, Fry B. Stable isotopes in ecosystem studies[J]. Annual Review of Ecology and Systematics, 1987, 18: 293-320. |
| [23] | Ambrose S H, Katzenberg M A. Biogeochemical Approaches to Paleodietary Analysis[M]. New York: Kluwer Academic/Plenum Publisher, 2000. |
| [24] | Heaton T H. Isotopic studies of nitrogen pollution in the hydrosphere and atmosphere: A review[J]. Chemical Geology, 1986, 59: 87-102. |
| [25] | Hirata K M. Pollution of Soil and Groundwater and Its Management[M]. Tokyo: Law and Regulations Center Publishing House, 1996. |
| [26] | Kreitler C W. Nitrogen isotope ratio studies of soil and groundwater nitrate from alluvial fan aquifers in Texas[J]. Journal of Hydrology, 1979, 42: 147-170. |
| [27] | Michener R,Lajtha K. Stable Isotopes in Ecology and Environmental Science[M]. Boston: Blackwell Publishing, 2007. |
| [28] | Kendall C, Mcdonnell J J. Isotope Tracers in Catchment Hydrology[M]. Amsterdam: Elsevier, 1998. |
| [29] | Shearer G, Duffy J, Kohl D H, et al. The nitrogen-15 abundance in a wide variety of soils[J]. Soil Science Society of America Journal, 1978, 42: 899-902. |
| [30] | Muzuka A N. Isotopic compositions of tropical east African flora and their potential as source indicators of organic matter in coastal marine sediments[J]. Journal of African Earth Sciences, 1999, 3: 757-766. |
| [31] | Liu W G, Wang Z F, Wang Z, et al. Variations in nitrogen isotopic values among various particle-sized fractions in modern soil in northwestern China[J]. Chinese Journal of Geochemistry, 2011, 30(3): 295-303. |
| [32] | Liu X Z, Wang G A. Measurements of nitrogen isotope composition of plants and surface soils along the altitudinal transect of the eastern slope of Mount Gongga in southwest China[J]. Rapid Communications in Mass Spectrumetry, 2010, 24: 3 063-3 071. |
| [33] | Garten C T, Schwab A B, Shirshac T L. Foliar retention of 15N tracers: Implications for net canopy exchange in low-and high-elevation forest ecosystems[J]. Forest Ecology and Management, 1998, 103:211-216. |
| [34] | Martinelli L A, Piccolo M C, Townsend A R,et al. Nitrogen stable isotopic composition of leaves and soil: Tropical versus temperate forests[J]. Biogeochemistry, 1999, 46: 45-65. |
| [35] | Craine J M, Elmore A J, Aidar M P, 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. |
| [36] | Liu Weiguo, Wang Zheng. Nitrogen isotopic composition of plant-soil in the Loess Plateau and its responding to environmental change[J]. Chinese Science Bulletin, 2009, 54(2):272-279. |
| [36] | [刘卫国, 王政. 黄土高原现代植物#cod#x02014;土壤氮同位素组成及对环境变化的响应[J]. 科学通报, 2008, 53(23): 2 917-2 924.] |
| [37] | Miller A E, Bowman W D. Variation in 15N natural abundance and nitrogen uptake traits among co-occurring alpine species: Do species partition by nitrogen form[J]. Oecologia, 2002, 130: 609-616. |
| [38] | Austin A T, Sala O E. Foliar #cod#x003b4;15N is negatively correlated with rainfall along the IGBP transect in Australia[J]. Australian Journal of Plant Physiology, 1999, 26: 293-295. |
| [39] | Eshetu Z, Hgberg P. Effects of land use on 15N natural abundance of soils in Ethiopian highlands[J]. Plant Soil, 2000, 22: 109-117. |
| [40] | 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: 326-337. |
| [41] | Wang L, D#cod#x02019;Odorico P, Ries L, et al. Patterns and implications of plant-soil #cod#x003b4;13C and #cod#x003b4;15N values in African savanna ecosystems[J]. Quaternary Research, 2010,73(1): 77-83. |
| [42] | 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. |
| [43] | Yi X F, Yang Y Q. Enrichment of stable carbon and nitrogen isotopes of plant populations and plateau pikas along altitudes[J]. Journal of Animal and Feed Sciences, 2006, 15: 661-667. |
| [44] | Schulze E D, Farquhar G D, Miller J M, et al. Interpretation of increased foliar #cod#x003b4;15N in woody species along a rainfall gradient in north Australia[J]. Australian Journal of Plant Physiology, 1999, 26: 296-298. |
| [45] | Swap R J, Aranibar J N, Dowty P R, 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: 350-358. |
| [46] | 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. |
| [47] | Heaton T H. The 15N/14N ratios of plants in South Africa and Namibia: Relationship to climate and coastal/saline environments[J]. Oecologia, 1987, 74: 236-246. |
| [48] | Austin A T, Vitousek P M. Nutrient dynamics on a precipitation gradient in Hawaii[J]. Oecologia, 1998, 113: 519-529. |
| [49] | Handley L, Austin A, Robinson D, et al. The 15-N natural abundance of ecosystem samples reflects measures of water availability[J]. Australian Journal of Plant Physiology, 1999, 26: 185-199. |
| [50] | Julieta N A, Luanne O,Stephen A M, et al. Nitrogen cycling in the soil-plant system along a precipitation gradient in the Kalahari sands[J]. Global Change Biology, 2004, 10: 359-373. |
| [51] | Vitousek P M, Shearer G, Daniel H K. Foliar 15N natural abundance in Hawaiian rainforest: Patterns and possible mechanisms[J]. Oecologia, 1989, 78: 383-388. |
| [52] | 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): 1 757-1 772. |
| [53] | Sutton M A, Schjorring J K, Wyers G P. Plant-atmosphere exchange of ammonia[J]. Philosophical Transactions: Physical Sciences and Engineering, 1995, 351: 261-278. |
| [54] | H#cod#x000f6;gberg P. 15N natural abundance in soil-plant systems[J]. New Phytologist, 1997, 137: 179-203. |
| [55] | Sah S P, 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. |
| [56] | Benjamin Z H, Daniel M S, Edward A G, et al. A climate-driven switch in plant nitrogen acquisition within tropical forest communities[J]. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104(21): 8 902-8 906. |
| [57] | Hormoz B, John V H, John L, et al. Widespread foliage #cod#x003b4;15N depletion under elevated CO2: Inferences for the nitrogen cycle[J]. Global Change Biology, 2003, 9(11): 1 582-1 590. |
| [58] | Dijkstra F A, Cheng W X. Increased soil moisture content increases plant N uptake and the abundance of 15N in plant biomass[J]. Plant Soil, 2008, 302: 263-271. |
| [59] | Charles T G, Colleen M I, Richard J N. Litter fall 15N abundance indicates declining soil nitrogen availability in a free-air CO2 enrichment experiment[J]. Ecology, 2011, 92(1): 133-139. |
| [60] | 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 fromnitrogen-15 natural abundance[J]. Oecologia, 2002, 131(3): 463-467. |
| [61] | 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): 15 136-15 141. |
| [62] | Ross E M, Roderick C D, Belinda E M, et al. Effects of elevated CO2 on forest growth and carbon storage:A modeling analysis of the consequences of changes in litter quality/quantity and root exudation[J]. Plant and Soil, 2000, 224(18): 135-152. |
| [63] | 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. |
| [64] | Mikan C J, Zak D R, Kubiske M E, et al. Combined effects of atmospheric CO2 and N availability on the blowground carbon and nitrogen dynamics of aspen mesocosms[J]. Oecologia, 2000, 124(3): 432-445. |
| [65] | Bassirirad H, Thomas R B. Differential responses of root uptake kinetics of NH4 and NO3 to enriched atmospheric CO2 concentration in field-grown loblolly pine[J]. Plant Cell and Environment, 1996, 19(3): 367-371. |
| [66] | Merwe C A, Cramer M D. Effect of enriched rhizosphere carbon dioxide on nitrate and ammonium uptake in hydroponically grown tomato plants[J]. Plant and Soil, 2000, 221: 5-11. |
| [67] | 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. |
/
| 〈 |
|
〉 |
甘公网安备62010202000687
