应用生态学报 ›› 2018, Vol. 29 ›› Issue (7): 2445-2454.doi: 10.13287/j.1001-9332.201807.041
• 综合评述 • 上一篇
许淼平, 任成杰, 张伟, 陈正兴, 付淑月, 刘伟超, 杨改河, 韩新辉*
收稿日期:
2018-04-16
出版日期:
2018-07-18
发布日期:
2018-07-18
通讯作者:
*E-mail: hanxinhui@nwsuaf.edu.cn
作者简介:
许淼平, 男, 1992年生, 硕士研究生. 主要从事土壤微生物生态研究. E-mail: 854937714@qq.com
基金资助:
本文由国家重点研发计划项目(2017YFC0504601)资助.
XU Miao-ping, REN Cheng-jie, ZHANG Wei, CHEN Zheng-xing, FU Shu-yue, LIU Wei-chao, YANG Gai-he, HAN Xin-hui*
Received:
2018-04-16
Online:
2018-07-18
Published:
2018-07-18
Contact:
*E-mail: hanxinhui@nwsuaf.edu.cn
Supported by:
This work was supported by the National Key Research & Development Program of China (2017YFC0504601).
摘要: 微生物和土壤酶是陆地生态系统中生物地球化学循环的重要驱动力,深入理解微生物在生态系统中的调节作用以及气候变化过程中微生物量和土壤酶的响应机制是生态学领域关注的重要科学问题.本研究从气候因素角度出发,基于生态化学计量学理论,综述了微生物和土壤酶在陆地生态系统碳氮磷循环中的作用,以及土壤微生物生物量碳氮磷和土壤酶化学计量对气候变化的响应机制,即: 改变微生物代谢速率和酶活性;调整微生物群落结构;调整微生物生物量碳氮磷与土壤酶化学计量特征;改变碳氮磷养分元素利用效率.最后分析当前研究的不足,并提出了该领域亟待解决的科学问题: 综合阐明土壤微生物和土壤酶对气候变化的响应机制;探究土壤微生物和胞外酶养分耦合机理;深入探究土壤微生物量和土壤酶化学计量特征对气候变化的适应对策.
许淼平, 任成杰, 张伟, 陈正兴, 付淑月, 刘伟超, 杨改河, 韩新辉. 土壤微生物生物量碳氮磷与土壤酶化学计量对气候变化的响应机制[J]. 应用生态学报, 2018, 29(7): 2445-2454.
XU Miao-ping, REN Cheng-jie, ZHANG Wei, CHEN Zheng-xing, FU Shu-yue, LIU Wei-chao, YANG Gai-he, HAN Xin-hui. Responses mechanism of C:N:P stoichiometry of soil microbial biomass and soil enzymes to climate change.[J]. Chinese Journal of Applied Ecology, 2018, 29(7): 2445-2454.
[1] | Xia J, Niu S, Wan S. Response of ecosystem carbon exchange to warming and nitrogen addition during two hydrologically contrasting growing seasons in a temperate steppe. Global Change Biology, 2010, 15: 1544-1556 |
[2] | Burns RG. International Conference: Enzymes in the Environment: Activity, Ecology and Applications. Flo-rida: CRC Press, 2002 |
[3] | Badiane NNY, Chotte JL, Pate E, et al. Use of soil enzyme activities to monitor soil quality in natural and improved fallows in semi-arid tropical regions. Applied Soil Ecology, 2001, 18: 229-238 |
[4] | Elser JJ, Kyle M, Makino W, et al. Ecological stoichio-metry in the microbial food web: A test of the light: nutrient hypothesis. Aquatic Microbial Ecology, 2003, 31: 49-65 |
[5] | Fan Z-Z (范珍珍), Wang X (王 鑫), Wang C (王超), et al. Effect of nitrogen and phosphorus addition on soil enzyme activities: A meta-analysis. Chinese Journal of Applied Ecology (应用生态学报), 2018, 29(4): 1266-1272 (in Chinese) |
[6] | Zogg GP, Zak DR, Ringelberg DB, et al. Compositional and functional shifts in microbial communities due to soil warming. Soil Science Society of America Journal, 1997, 61: 475-481 |
[7] | Treseder K. Nitrogen additions and microbial biomass: A meta-analysis of ecosystem studies. Ecology Letters, 2008, 11: 1111-1120 |
[8] | Bardgett RD, Vries FTD. Hierarchical responses of plant-soil interactions to climate change: Consequences for the global carbon cycle. Journal of Ecology, 2013, 101: 334-343 |
[9] | Moore JAM, Jiang J, Patterson CM, et al. Interactions among roots, mycorrhizas and free-living microbial communities differentially impact soil carbon processes. Journal of Ecology, 2015, 103: 1442-1453 |
[10] | Buchkowski RW, Schmitz OJ, Bradford MA. Microbial stoichiometry overrides biomass as a regulator of soil carbon and nitrogen cycling. Ecology, 2016, 96: 1139-1149 |
[11] | Zechmeister-Boltenstern S, Keiblinger KM, Mooshammer M, et al. The application of ecological stoichiometry to plant-microbial-soil organic matter transformations. Ecological Monographs, 2016, 85: 133-155 |
[12] | Jansson JK, Prosser JI. Microbiology: The life beneath our feet. Nature, 2013, 494: 40-41 |
[13] | Ren C, Zhao F, Shi Z, et al. Differential responses of soil microbial biomass and carbon-degrading enzyme activities to altered precipitation. Soil Biology & Bioche-mistry, 2017, 115: 1-10 |
[14] | Sterner RW, Elser JJ. Ecological Stoichiometry: The Biology of Elements from Molecules to the Biosphere. New Jersey: Princeton University Press, 2002 |
[15] | Zelezniak A, Andrejev S, Ponomarova O, et al. Metabolic dependencies drive species co-occurrence in diverse microbial communities. Proceedings of the Natio-nal Academy of Sciences of the United States of America, 2015, 112: 6449-6454 |
[16] | Hessen DO, Elser JJ. Elements of ecology and evolution. Oikos, 2010, 109: 3-5 |
[17] | Elser JJ, Andrew H. Stoichiometry and the new biology: The future is now. PLoS Biology, 2007, 5(7): e181 |
[18] | Elser JJ, Sterner RW, Gorokhova E, et al. Biological stoichiometry from genes to ecosystems. Ecology Letters, 2000, 3: 540-550 |
[19] | Elser O’Brien, Dobberfuhl, et al. The evolution of ecosystem processes: Growth rate and elemental stoichio-metry of a key herbivore in temperate and arctic habitats. Journal of Evolutionary Biology, 2000, 13: 845-853 |
[20] | Elser JJ, Acharya K, Kyle M, et al. Growth rate-stoichiometry couplings in diverse biota. Ecology Letters, 2003, 6: 936-943 |
[21] | Wang S-Q (王绍强), Yu G-R (于贵瑞). Ecological stoichiometry characteristics of ecosystem carbon, nitrogen and phosphorus elements. Acta Ecologica Sinica (生态学报), 2008, 28(8): 3937-3947 (in Chinese) |
[22] | Anderson JPE, Domsch KH. A physiological method for the quantitative measurement of microbial biomass in soils. Soil Biology and Biochemistry, 1978, 10: 215-221 |
[23] | Mooney H, Larigauderie A, Cesario M, et al. Biodiversity, climate change, and ecosystem services. Current Opinion in Environmental Sustainability, 2009, 1: 46-54 |
[24] | Lavergne S, Mouquet N, Thuiller W, et al. Biodiversity and climate change: Integrating evolutionary and ecolo-gical responses of species and communities. Annual Review of Ecology, Evolution & Systematics, 2010, 41: 321-350 |
[25] | Bengtsson J, Janion C, Chown SL, et al. Variation in decomposition rates in the fynbos biome, South Africa: The role of plant species and plant stoichiometry. Oecologia, 2011, 165: 225-235 |
[26] | Griffiths BS, Spilles A, Bonkowski M. C:N:P stoichiometry and nutrient limitation of the soil microbial biomass in a grazed grassland site under experimental P limitation or excess. Ecological Processes, 2012, 1: 6 |
[27] | Giai C, Boerner REJ. Effects of ecological restoration on microbial activity, microbial functional diversity, and soil organic matter in mixed-oak forests of southern Ohio, USA. Applied Soil Ecology, 2007, 35: 281-290 |
[28] | Carrasco M, Rozas JM, Barahona S, et al. Diversity and extracellular enzymatic activities of yeasts isolated from King George Island, the sub-Antarctic region. BMC Microbiology, 2012, 12: 251 |
[29] | Zeng D-H (曾德慧), Chen G-S ( 陈广生). Ecological stoichiometry: A science to explore the complexity of living systems. Acta Phytoecologica Sinica (植物生态学报), 2005, 29(6): 1007-1019 (in Chinese) |
[30] | Bardgett R, Usher M, Hopkins D. Biological Diversity and Function in Soils. Cambridge: Cambridge University Press, 2005 |
[31] | Zhang N-L (张乃莉), Guo J-X (郭继勋), Wang X-Y (王晓宇), et al. Soil microbial feedbacks to climate warming and atmospheric N deposition. Chinese Journal of Plant Ecology (植物生态学报), 2007, 31(2): 252-261 (in Chinese) |
[32] | Dick WA, Tabatabai MA, Metting FBJ. Significance and Potential Uses of Soil Enzymes. New York: Agricultural and Environmental Management, 1992 |
[33] | Ward BB, Jensen MM. The microbial nitrogen cycle. Front Microbiology, 2014, 5: 553 |
[34] | Schimel JP, Weintraub MN. The implications of exoenzyme activity on microbial carbon and nitrogen limitation in soil: A theoretical model. Soil Biology & Biochemistry, 2003, 35: 549-563 |
[35] | Hill BH, Elonen CM, Jicha TM, et al. Sediment microbial enzyme activity as an indicator of nutrient limitation in Great Lakes coastal wetlands. Freshwater Biology, 2006, 51: 1670-1683 |
[36] | Moorhead DL, Sinsabaugh RL. A theoretical model of litter decay and microbial interaction. Ecological Monographs, 2006, 76: 151-174 |
[37] | Allison VJ, Condron LM, Peltzer DA, et al. Changes in enzyme activities and soil microbial community composition along carbon and nutrient gradients at the Franz Josef chronosequence, New Zealand. Soil Biology & Biochemistry, 2007, 39: 1770-1781 |
[38] | Allison SD, Weintraub MN, Gartner TB, et al. Evolutionary-Economic Principles as Regulators of Soil Enzyme Production and Ecosystem Function. Berlin, Germany: Springer, 2011: 229-243 |
[39] | Bardgett RD, Freeman C, Ostle NJ. Microbial contributions to climate change through carbon cycle feedbacks. ISME Journal, 2008, 2: 805-814 |
[40] | Suseela V, Tharayil N, Xing B, et al. Labile compounds in plant litter reduce the sensitivity of decomposition to warming and altered precipitation. New Phytologist, 2013, 200: 122-133 |
[41] | Seeling B, Zasoski RJ. Microbial effects in maintaining organic and inorganic solution phosphorus concentrations in a grassland topsoil. Plant and Soil, 1993, 148: 277-284 |
[42] | Manzoni S, Schaeffer SM, Katul G, et al. A theoretical analysis of microbial eco-physiological and diffusion limi-tations to carbon cycling in drying soils. Soil Biology & Biochemistry, 2014, 73: 69-83 |
[43] | Li P, Yang Y, Han W, et al. Global patterns of soil microbial nitrogen and phosphorus stoichiometry in forest ecosystems. Global Ecology and Biogeography, 2015, 23: 979-987 |
[44] | Walker TW, Syers JK. The fate of phosphorus during pedogenesis. Geoderma, 1976, 15: 1-19 |
[45] | Crews TE, Kitayama K, Fownes JH, et al. Changes in soil phosphorus fractions and ecosystem dynamics across a long chronosequence in Hawaii. Ecology, 1995, 76: 1407-1424 |
[46] | Vitousek PM, Farrington H. Nutrient limitation and soil development: Experimental test of a biogeochemical theory. Biogeochemistry, 1997, 37: 63-75 |
[47] | Chadwick OA, Derry LA, Vitousek PM, et al. Changing sources of nutrients during four million years of ecosystem development. Nature, 1999, 397: 491-497 |
[48] | Levinton JS. The latitudinal compensation hypothesis: Growth data and a model of latitudinal growth differentiation based upon energy budgets. Ⅰ. Interspecific comparison of Ophryotrocha (Polychaeta: Dorvilleidae). Biological Bulletin, 1983, 165: 686-698 |
[49] | Reich PB, Oleksyn J. Global patterns of plant leaf N and P in relation to temperature and latitude. Procee-dings of the National Academy of Sciences of the United States of America, 2004, 101: 11001-11006 |
[50] | Sinsabaugh R, Lauber C, Weintraub M, et al. Stoichio-metry of soil enzyme activity at global scale. Ecology Letters, 2008, 11: 1252-1264 |
[51] | Parry ML, Canziani OF, Palutikof JP, eds. Contribution of Working Group Ⅱ to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. New York: Cambridge University Press, 2007 |
[52] | Wang B-B (王冰冰), Qu L-Y (曲来叶), Ma K-M (马克明), et al. Patterns of ecoenzymatic stoichiometry in the dominant shrubs in the semi-arid upper Minjiang River valley. Acta Ecologica Sinica (生态学报), 2015, 35(18): 6078-6088 (in Chinese) |
[53] | Dijkstra FA, Pendall E, Morgan JA, et al. Climate change alters stoichiometry of phosphorus and nitrogen in a semiarid grassland. New Phytologist, 2012, 196: 807-815 |
[54] | Djukic I, Zehetner F, Watzinger A, et al. In situ carbon turnover dynamics and the role of soil microorganisms therein: A climate warming study in an Alpine ecosystem. FEMS Microbiology Ecology, 2013, 83: 112-124 |
[55] | Li H-J (李洪杰), Liu J-W (刘军伟), Yang L (杨林), et al. Effects of simulated climate warming on soil microbial biomass carbon, nitrogen and phosphorus of alpine forest. Chinese Journal of Applied and Environmental Biology (应用与环境生物学报), 2016(4): 599-605 (in Chinese) |
[56] | Xu Z-F (徐振锋), Hu T-X (胡庭兴), Zhang Y-B (张远彬), et al. Responses of phenology and growth of Betula utilis and Abies faxoniana in subalpine timberline ecotone to stimulated global warming western Sichuan, China. Journal of Plant Ecology (植物生态学报), 2008, 32(5): 1061-1071 (in Chinese) |
[57] | Xu ZF, Hu R, Xiong P, et al. Initial soil responses to experimental warming in two contrasting forest ecosystems, Eastern Tibetan Plateau, China: Nutrient availabilities, microbial properties and enzyme activities. Applied Soil Ecology, 2010, 46: 291-299 |
[58] | Rinnan R, Michelsen A, Bth E, et al. Fifteen years of climate change manipulations alter soil microbial communities in a subarctic heath ecosystem. Global Change Biology, 2007, 13: 28-39 |
[59] | Gao Y-N (高艳娜), Qi Z-W (戚志伟), Zhong Q-C (仲启铖), et al. Responses of soil microbial biomass to long-term simulated warming in Eastern Chongming Island wetlands, China. Acta Ecologica Sinica (生态学报), 2018, 38(2): 711-720 (in Chinese) |
[60] | Fanin N, Fromin N, Buatois B, et al. An experimental test of the hypothesis of non-homeostatic consumer stoichiometry in a plant litter-microbe system. Ecology Letters, 2013, 16: 764-772 |
[61] | Mouginot C, Kawamura R, Matulich KL, et al. Elemental stoichiometry of fungi and bacteria strains from grassland leaf litter. Soil Biology & Biochemistry, 2014, 76: 278-285 |
[62] | Stark JM, Firestone MK. Kinetic characteristics of Ammonium-Oxidizer communities in California oak woodland-annual grassland. Soil Biology & Biochemistry, 1996, 28: 1307-1317 |
[63] | Hart SC, Perry DA. Transferring soils from high- to low-elevation forests increases nitrogen cycling rate: Climate change implications. Global Change Biology, 1999, 5: 23-32 |
[64] | Kapkiyai JJ, Karanja NK, Qureshi JN, et al. Soil organic matter and nutrient dynamics in a Kenyan nitisol under long-term fertilizer and organic input management. Soil Biology & Biochemistry, 1999, 31: 1773-1782 |
[65] | Callaghan TV, Christensen TR, Jantze EJ. Plant and vegetation dynamics on Disko Island, West Greenland: Snapshots separated by over 40 years. Ambio, 2011, 40: 624-637 |
[66] | Planchet E, Rannou O, Ricoult C, et al. Nitrogen metabolism responses to water deficit act through both abscisic acid (ABA)-dependent and independent pathways in Medicago truncatula during post-germination. Journal of Experimental Botany, 2011, 62: 605-615 |
[67] | Neff JC, Townsend AR, Gleixner G, et al. Variable effects of nitrogen additions on the stability and turnover of soil carbon. Nature, 2002, 419: 915-917 |
[68] | Galloway JN, Townsend AR, Erisman JW, et al. Transformation of the nitrogen cycle: Recent trends, questions, and potential solutions. Science, 2008, 320: 889-892 |
[69] | Allen AS, Schlesinger WH. Nutrient limitations to soil microbial biomass and activity in loblolly pine forests. Soil Biology & Biochemistry, 2004, 36: 581-589 |
[70] | Johnson D, Leake JR, Lee JA, et al. Changes in soil microbial biomass and microbial activities in response to 7 years simulated pollutant nitrogen deposition on a heathland and two grasslands. Environmental Pollution, 1998, 103: 239-250 |
[71] | Crowther TW, Thomas SM, Maynard DS, et al. Biotic interactions mediate soil microbial feedbacks to climate change. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112: 7033-7038 |
[72] | Heuck C, Weig A, Spohn M. Soil microbial biomass C:N:P stoichiometry and microbial use oforganic phosphorus. Soil Biology & Biochemistry, 2015, 85: 119-129 |
[73] | Sinsabaugh RL, Hill BH, Shah JJF. Ecoenzymatic stoichiometry of microbial organic nutrient acquisition in soil and sediment. Nature, 2010, 462: 795-798 |
[74] | Waring BG, Weintraub SR, Sinsabaugh RL. Ecoenzymatic stoichiometry of microbial nutrient acquisition in tropical soils. Biogeochemistry, 2014, 117: 101-113 |
[75] | Olander LP, Vitousek PM. Regulation of soil phosphatase and chitinase activityby N and P availability. Biogeochemistry, 2000, 49: 175-191 |
[76] | Drake JE, Darby BA, Giasson MA, et al. Stoichiometry constrains microbial response to root exudation: Insights from a model and a field experiment in a temperate forest. Biogeosciences, 2013, 10: 821-838 |
[77] | Papanikolaou N, Britton AJ, Helliwell RC, et al. Nitrogen deposition, vegetation burning and climate warming act independently on microbial community structure and enzyme activity associated with decomposing litter in low-alpine heath. Global Change Biology, 2010, 16: 3120-3132 |
[78] | Pachauri RK, Meyer LA. Climate Change 2014: Synthesis Report. Contribution of Working Groups Ⅰ, Ⅱand Ⅲ to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Genera: IPCC, 2014 |
[79] | Karl TR, Melillo JM, Peterson TC, et al. Global climate change impacts in the United States: Highlights. Environmental Policy Collection, 2009, 11: 139-144 |
[80] | Tischer A, Potthast K, Hamer U. Land-use and soil depth affect resource and microbial stoichiometry in a tropical mountain rainforest region of southern Ecuador. Oecologia, 2014, 175: 375-393 |
[81] | Wilkinson JF. Carbon and energy storage in storage in bacteria. Journal of General and Applied Microbiology, 1963, 32: 171-176 |
[82] | Winkler HH. Distribution of an inducible hexose-phosphate transport system among various bacteria. Journal of Bacteriology, 1973, 116: 1079-1081 |
[83] | Wilson WA, Roach PJ, Montero M, et al. Regulation of glycogen metabolism in yeast and bacteria. FEMS Microbiology Reviews, 2010, 34: 952-985 |
[84] | Heimann M, Reichstein M. Terrestrial ecosystem carbon dynamics and climate feedbacks. Nature, 2008, 451: 289-292 |
[85] | Hu S, Firestone MK, Field CB, et al. Nitrogen limitation of microbial decomposition in a grassland under elevated CO2. Nature, 2001, 409: 188-191 |
[86] | Carreira JA, Lajtha K. Factors affecting phosphate sorption along a Mediterranean, dolomitic soil and vegetation chronosequence. European Journal of Soil Science, 1997, 48: 139-149 |
[87] | Eljaschewitsch E, Witting A, Mawrin C, et al. Phosphate adsorption and precipitation in calcareous soils: The role of calcium ions in solution and carbonate minerals. Nutrient Cycling in Agroecosystems, 1999, 53: 219-227 |
[88] | Lambers H, Shane MW, Cramer MD, et al. Root structure and functioning for efficient acquisition of phospho-rus: Matching morphological and physiological traits. Annals of Botany, 2006, 98: 693-713 |
[89] | Austin AT, Yahdjian L, Stark JM, et al. Water pulses and biogeochemical cycles in arid and semiarid ecosystems. Oecologia, 2004, 141: 221-235 |
[90] | Liu ZF, Fu BJ, Zheng XX, et al. Plant biomass, soil water content and soil N:P ratio regulating soil microbial functional diversity in a temperate steppe: A regional scale study. Soil Biology & Biochemistry, 2010, 42: 445-450 |
[91] | Güsewell S, Gessner MO. N:P ratios influence litter decomposition and colonization by fungi and bacteria in microcosms. Functional Ecology, 2009, 23: 211-219 |
[92] | Ruizlozano JM, Azcon R, Gomez M. Effects of arbuscular-mycorrhizal glomus species on drought tolerance: Physiological and nutritional plant responses. Applied and Environmental Microbiology, 1995, 61: 456-460 |
[93] | Zhang L-X (张立欣), Duan Y-X (段玉玺), Wang B (王 博), et al. Characteristics of soil microorganisms and soil nutrients in different sand-fixation shrub plantations in Kubuqi Desert, China. Chinese Journal of Applied Ecology (应用生态学报), 2017, 28(12): 3871-3880 (in Chinese) |
[94] | Li Y-L (李跃林), Peng S-L (彭少麟), Li Z-H (李志辉), et al. Relationship between soil enzyme activities and trace element contents in Eucalyptus plantation soil. Chinese Journal of Applied Ecology (应用生态学报), 2003, 14(3): 345-348 (in Chinese) |
[95] | Chen YL, Chen LY, Peng YF, et al. Linking microbial C:N:P stoichiometry to microbial community and abiotic factors along a 3500 km grassland transect on the Tibetan Plateau. Global Ecology and Biogeography, 2016, 25: 1416-1427 |
[96] | Ren C, Zhao F, Shi Z, et al. Differential responses of soil microbial biomass and carbon-degrading enzyme activities to altered precipitation. Soil Biology & Biochemistry, 2017, 115: 1-10 |
[97] | Ren C, Kang D, Wu JP, et al. Temporal variation in soil enzyme activities after afforestation in the Loess Plateau, China. Geoderma, 2016, 282: 103-111 |
[98] | De VFT, Ashley S. Controls on soil microbial community stability under climate change. Frontiers in Microbiology, 2013, 4: 265 |
[99] | Ren C, Zhao F, Kang D, et al. Linkages of C:N:P stoichiometry and bacterial community in soil following afforestation of former farmland. Forest Ecology and Management, 2016, 376: 59-66 |
[100] | Castro HF, Classen AT, Austin EE, et al. Soil microbial community responses to multiple experimental climate change drivers. Applied and Environmental Microbiology, 2010, 76: 999-1007 |
No related articles found! |
阅读次数 | ||||||
全文 |
|
|||||
摘要 |
|
|||||