不同放牧强度下荒漠草原土壤化学计量失衡与微生物碳利用效率的联系

doi:10.13287/j.1001-9332.202408.003

摘要/Abstract

摘要： 长期放牧改变了草地生态系统的土壤资源可利用性和微生物生物量化学计量。研究放牧荒漠草原土壤化学计量不平衡与微生物碳利用效率(CUE)的关系,有助于从微生物视角理解土壤碳动态。本研究依托2004年建立的内蒙古短花针茅荒漠草原长期放牧实验平台,以围封禁牧为对照,设置重度、中度和轻度放牧处理,测定了土壤有效养分、微生物生物量及其获取的相关酶活性,并利用生态化学计量法对土壤微生物CUE进行计算。结果表明: 与对照相比,放牧抑制了土壤微生物CUE,降幅为1.0%～10.3%;土壤C∶N不平衡在中度放牧处理下显著增加20.6%,C∶P不平衡和N∶P不平衡在重度放牧处理分别显著增加20.7%和25.2%,这表明土壤微生物群落更容易受N、P限制。土壤微生物群落通过调节元素阈值计量比和胞外酶的产生来维持自身化学计量平衡。结构方程模型结果表明,化学计量不平衡通过改变元素阈值计量比、微生物生物量化学计量和酶化学计量间接影响微生物CUE。

关键词: 放牧强度, 微生物碳利用效率, 化学计量不平衡, 胞外酶活性

Abstract: Long-term grazing alters soil resource availability and microbial biomass stoichiometry in grassland ecosystems. Exploring the relationship between soil stoichiometric imbalance and microbial carbon use efficiency (CUE) in grazed desert steppe can help understand soil carbon dynamics from a microbial perspective. Based on a long-term grazing platform in Stipa breviflora desert steppe of Inner Mongolia established in 2004, taking heavy, moderate and light grazing intensities, using no grazing as a control, we measured soil available nutrients, microbial biomass and associated enzyme activities for their acquisition, and calculated soil microbial CUE using ecological stoichiometry. The results showed that grazing inhibited soil microbial CUE by 1.0%-10.3%. Soil C:N imbalance was significantly increased by 20.6% in the moderate grazing treatment, while both C:P imbalance and N:P imba-lance were significantly increased by 20.7% and 25.2% in the heavy grazing treatment, indicating that soil microbial communities were more susceptible to N and P limitation. Soil microbial communities maintained their stoichiometric balance by regulating the threshold of elemental stoichiometry ratios and the production of extracellular enzymes. Structural equation modelling (SEM) results indicated that stoichiometric imbalance indirectly affected microbial CUE by altering the threshold of elemental stoichiometry ratios, microbial biomass stoichiometry, and enzyme stoichiometry.

Key words: grazing intensity, microbial carbon use efficiency, stoichiometric imbalance, extracellular enzymatic activity

吴佳芯, 李邵宇, 韩国栋. 不同放牧强度下荒漠草原土壤化学计量失衡与微生物碳利用效率的联系[J]. 应用生态学报, 2024, 35(8): 2108-2118.

WU Jiaxin, LI Shaoyu, HAN Guodong. Linkage between soil stoichiometric imbalance and microbial carbon use efficiency in desert steppe under different grazing intensities[J]. Chinese Journal of Applied Ecology, 2024, 35(8): 2108-2118.

参考文献

[1] Bai YF, Cotrufo MF. Grassland soil carbon sequestration: Current understanding, challenges, and solutions. Science, 2022, 377: 603-608
[2] Chen LL, Wang KX, Baoyin TGT. Effects of grazing and mowing on vertical distribution of soil nutrients and their stoichiometry (C:N:P) in a semi-arid grassland of North China. Catena, 2021, 206: 105507
[3] 张子萱, 郭建英, 杨振奇. 放牧与刈割对典型草原碳储量的影响研究进展. 绿色科技, 2023(24): 99-104
[4] Shao PS, Liang C, Lynch L, et al. Reforestation acce-lerates soil organic carbon accumulation: Evidence from microbial biomarkers. Soil Biology and Biochemistry, 2019, 131: 182-190
[5] Wang C, Qu LR, Yang LM, et al. Large-scale importance of microbial carbon use efficiency and necromass to soil organic carbon. Global Change Biology, 2021, 27: 2039-2048
[6] Geyer MK, Kyker-Snowman E, Grandy SA, et al. Micro-bial carbon use efficiency: Accounting for population, community, and ecosystem-scale controls over the fate of metabolized organic matter. Biogeochemistry, 2016, 127: 173-188
[7] Kallenbach CM, Frey AD, Grand SA. Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls. Nature Communications, 2016, 7: 13630
[8] Geyer MK, Dijkstra P, Sinsabaugh R, et al. Clarifying the interpretation of carbon use efficiency in soil through methods comparison. Soil Biology and Biochemistry, 2019, 128: 79-88
[9] Spohn M, Pötsch EM, Eichorst SA, et al. Soil microbial carbon use efficiency and biomass turnover in a long-term fertilization experiment in a temperate grassland. Soil Biology and Biochemistry, 2016, 97: 168-175
[10] Maria M, Wolfgang W, Ieda H, et al. Adjustment of microbial nitrogen use efficiency to carbon:nitrogen imbalances regulates soil nitrogen cycling. Nature Communications, 2014, 5: 3694
[11] Li JW, Liu YL, Hai XY, et al. Dynamics of soil microbial C:N:P stoichiometry and its driving mechanisms following natural vegetation restoration after farmland abandonment. Science of the Total Environment, 2019, 693: 133613
[12] Yuan XB, Niu DC, Gherardi LA, et al. Linkages of stoi-chiometric imbalances to soil microbial respiration with increasing nitrogen addition: Evidence from a long-term grassland experiment. Soil Biology and Biochemistry, 2019, 138: 107580
[13] Saiya-Cork K, Sinsabaugh R, Zak D. The effects of long term nitrogen deposition on extracellular enzyme activity in an Acer saccharum forest soil. Soil Biology and Biochemistry, 2002, 34: 1309-1315
[14] Manzoni S, Chakrawal A, Spohn M, et al. Modeling microbial adaptations to nutrient limitation during litter decomposition. Frontiers in Forests and Global Change, 2021, 4: 686945
[15] Xiao L, Liu GB, Li P, et al. Ecoenzymatic stoichiome-try and microbial nutrient limitation during secondary succession of natural grassland on the Loess Plateau, China. Soil Tillage Research, 2020, 200: 104605
[16] Nicolas F, Nathalie F, Bruno 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
[17] Zhong ZK, Li WJ, Lu XQ, et al. Adaptive pathways of soil microorganisms to stoichiometric imbalances regulate microbial respiration following afforestation in the Loess Plateau, China. Soil Biology and Biochemistry, 2020, 151: 108048
[18] Rattan L. Digging deeper: A holistic perspective of factors affecting soil organic carbon sequestration in agroe-cosystems. Global Change Biology, 2018, 24: 3285-3301
[19] Wang YH, Wang ZW, Li HG, et al. Grazing decreased soil organic carbon by decreasing aboveground biomass in a desert steppe in Inner Mongolia. Journal of Environmental Management, 2023, 347: 119112
[20] 张峰, 高峰, 孙嘉伟, 等. 不同放牧强度对荒漠草原建群种短花针茅种群时空变异性的影响. 草地学报, 2021, 29(6): 1369-1374
[21] 鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2006: 25-103
[22] Vance ED, Brookes PC, Jenkinson DS. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry, 1987, 19: 703-707
[23] Sinsabaugh RL, Lauber CL, Weintraub MN, et al. Stoichiometry of soil enzyme activity at global scale. Ecology Letters, 2008, 11: 1252-1264
[24] Wang Y, Niu DC, Yuan XB, et al. Dominant plant species alter stoichiometric imbalances between soil microbes and their resources in an alpine grassland: Implications for soil microbial respiration. Geoderma, 2023, 431: 116336
[25] Sterner RW, Elser JJ. Ecological Stoichiometry: The Biology of Elements from Molecules to the Biosphere. Princeton, NJ, USA: Princeton University Press, 2002: 1183
[26] Allen AP, Gillooly JF. Towards an integration of ecological stoichiometry and the metabolic theory of ecology to better understand nutrient cycling. Ecology Letters, 2009, 12: 369-384
[27] Sinsabaugh RL, Turner BL, Talbot JM, et al. Stoichio-metry of microbial carbon use efficiency in soils. Ecologi-cal Monographs, 2016, 86: 172-189
[28] Sinsabaugh RL, Manzoni S, Moorhead DL, et al. Carbon use efficiency of microbial communities: Stoichio-metry, methodology and modelling. Ecology Letters, 2013, 16: 930-939
[29] Huang YP, Wang QQ, Zhang WJ, et al. Stoichiometric imbalance of soil carbon and nutrients drives microbial community structure under long-term fertilization. App-lied Soil Ecology, 2021, 168: 104119
[30] Zechmeister-Boltenstern S, Keiblinger KM, Mooshammer M, et al. The application of ecological stoichiometry to plant-microbial-soil organic matter transformations. Ecological Monographs, 2015, 85: 133-155
[31] Xie YY, Zhang W, Guo ZW, et al. Effects of vegetation succession on soil microbial stoichiometry in Phyllsta-chys edulis stands following abandonment. Science of the Total Environment, 2023, 895: 164971
[32] 刘玉祯, 刘文亭, 杨晓霞, 等. 放牧对全球草地生态系统碳氮磷化学计量特征影响的Meta分析. 应用生态学报, 2022, 33(5): 1251-1259
[33] 陈智, 于贵瑞. 土壤微生物碳素利用效率研究进展. 生态学报, 2020, 40(3): 756-767
[34] Ye JS, Bradford MB, Dacal M, et al. Increasing microbial carbon use efficiency with warming predicts soil hete-rotrophic respiration globally. Global Change Biology, 2019, 25: 3354-3364
[35] Thorhallsdottir AG, Gudmundsson J. Carbon dioxide fluxes and soil carbon storage in relation to long-term gra-zing and no grazing in Icelandic semi-natural grasslands. Applied Vegetation Science, 2023, 26: 1402-2001
[36] Zhang ZH, Gong JR, Song LY, et al. Adaptations of soil microbes to stoichiometric imbalances in regulating their carbon use efficiency under a range of different grazing intensities. Applied Soil Ecology, 2024, 193: 105141
[37] Jones LD, Olivera-Ardid S, Klumpp E, et al. Moisture activation and carbon use efficiency of soil microbial communities along an aridity gradient in the Atacama Desert. Soil Biology and Biochemistry, 2018, 117: 68-71
[38] Wang QK, Liu SG, Tian P. Carbon quality and soil microbial property control the latitudinal pattern in temperature sensitivity of soil microbial respiration across Chinese forest ecosystems. Global Change Biology, 2018, 24: 2841-2849
[39] Kyaschenko J, Clemmensen KE, Hagenbo A, et al. Shift in fungal communities and associated enzyme acti-vities along an age gradient of managed Pinus sylvestris stands. The ISME Journal, 2017, 11: 863-874
[40] Rousk J, Brookes PC, Bååth E. Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Applied Environmental Microbiology, 2009, 75: 1589-1596
[41] Katharina MK, Edward KH, Wolfgang W, et al. The effect of resource quantity and resource stoichiometry on microbial carbon-use-efficiency. FEMS Microbiology Ecology, 2010, 73: 430-440
[42] Juliana T, Lara S, Soizig SL, et al. Fire promotes functional plant diversity and modifies soil carbon dynamics in tropical savanna. Science of the Total Environment, 2021, 812: 152317
[43] 刘明辉, 谢婷婷, 李瑞, 等. 三峡库区消落带池杉-土壤碳氮磷生态化学计量特征. 生态学报, 2020, 40(9): 3072-3084
[44] Tapia-Torres Y, Elser JJ, Souza V, et al. Ecoenzymatic stoichiometry at the extremes: How microbes cope in an ultra-oligotrophic desert soil. Soil Biology and Bioche-mistry, 2015, 87: 34-42
[45] Allison SD, Vitousek PM. Responses of extracellular enzymes to simple and complex nutrient inputs. Soil Bio-logy and Biochemistry, 2005, 37: 937-944
[46] Stefano M, Philip T, Andreas R, et al. Environmental and stoichiometric controls on microbial carbon-use efficiency in soils. New Phytologist, 2012, 196: 79-91
[47] Jiang YL, Lei YB, Qin W, et al. Revealing microbial processes and nutrient limitation in soil through ecoenzymatic stoichiometry and glomalin-related soil proteins in a retreating glacier forefield. Geoderma, 2019, 338: 313-324
[48] Takriti M, Wild B, Schnecker J, et al. Soil organic matter quality exerts a stronger control than stoichiometry on microbial substrate use efficiency along a latitudinal transect. Soil Biology and Biochemistry, 2018, 121: 212-220
[49] Maire V, Gross N, Börger L, et al. Habitat filtering and niche differentiation jointly explain species relative abundance within grassland communities along fertility and disturbance gradients. New Phytologist, 2012, 196: 497-509
[50] Wieder WR, Bonan GB, Allison SD. Global soil carbon projections are improved by modelling microbial processes. Nature Climate Change, 2013, 3: 909-912
[51] Mooshammer M, Wanek W, Zechmeister-Boltenstern S, et al. Stoichiometric imbalances between terrestrial decomposer communities and their resources: Mechanisms and implications of microbial adaptations to their resources. Frontiers in Microbiology, 2014, 5: 22
[52] Sinsabaugh RL, Hill BH, Follstad JJ. Ecoenzymatic stoichiometry of microbial organic nutrient acquisition in soil and sediment. Nature, 2009, 462: 795-798
[53] 栾历历, 刘恩媛, 顾新, 等. 凋落物处理和氮添加对松栎混交林土壤生态酶化学计量的影响. 生态学报, 2020, 40(24): 9220-9233
[54] Deng L, Peng CH, Huang CB, et al. Drivers of soil microbial metabolic limitation changes along a vegetation restoration gradient on the Loess Plateau, China. Geoderma, 2019, 353: 188-200