生态化学计量不平衡驱动高寒草甸土壤细菌群落对氮添加的响应

doi:10.13287/j.1001-9332.202504.018

应用生态学报 ›› 2025, Vol. 36 ›› Issue (4): 1081-1090.doi: 10.13287/j.1001-9332.202504.018

生态化学计量不平衡驱动高寒草甸土壤细菌群落对氮添加的响应

连晨星¹, 张秋芳^1*, 任飞^2,3, 李兰平^2,3, 陈静琪¹, 曾泉鑫¹, 陈岳民¹, 朱彪⁴

¹福建师范大学地理科学学院, 福州 350117;
²青海大学省部共建三江源生态与高原农牧业国家重点实验室, 西宁 810016;
³青海三江源草地生态系统国家野外科学观测研究站, 西宁 810016;
⁴北京大学城市与环境学院, 北京 100871

收稿日期:2024-10-14 接受日期:2025-02-22 出版日期:2025-04-18 发布日期:2025-10-18
通讯作者: *E-mail: qiufangzh@fjnu.edu.cn
作者简介:连晨星, 女, 2004年生, 本科生。主要从事全球变化生态学研究。E-mail: lianchenxing727@163.com
基金资助:
国家自然科学基金项目(U21A201936,31901171,31960339)、福建省自然科学基金项目(2024J01466,2023R1002002)、青海大学省部共建三江源生态和高原农牧业国家重点实验室自主研究项目(2019-KF-001)和青海省科技厅项目(2018-ZJ-967Q)

Ecological stoichiometric imbalance drives the responses of soil bacterial communities to nitrogen addition in an alpine meadow

LIAN Chenxing¹, ZHANG Qiufang^1*, REN Fei^2,3, LI Lanping^2,3, CHEN Jingqi¹, ZENG Quanxin¹, CHEN Yuemin¹, ZHU Biao⁴

¹School of Geographical Science, Fujian Normal University, Fuzhou 350117, China;
²State Key Laboratory of Plateau Ecology and Agriculture, Qinghai University, Xining 810016, China;
³Sanjiangyuan Grassland Ecosystem National Observation and Research Station, Xining 810016, China;
⁴College of Urban and Environmental Sciences, Peking University, Beijing 100871, China

Received:2024-10-14 Accepted:2025-02-22 Online:2025-04-18 Published:2025-10-18

摘要/Abstract

摘要： 氮是草地生态系统生产力的主要限制性养分,可通过改变土壤性质间接作用于微生物群落结构,特别是细菌群落。本研究在青藏高原东北部的海北高寒草甸开展野外氮添加试验,以尿素为氮源,设置了5个氮添加水平:N₀(对照,无氮添加)、N₅₀(50 kg N·hm^-2·a^-1)、N₁₀₀(100 kg N·hm^-2·a^-1)、N₁₅₀(150 kg N·hm^-2·a^-1)和N₂₀₀(200 kg N·hm^-2·a^-1)。在试验的第3年采集表层土壤样品,测定其理化性质、稳定同位素δ¹⁵N和微生物生物量,计算微生物化学计量不平衡性,并通过16S rRNA高通量测序分析细菌群落特征(组成、多样性和群落构建)沿氮添加水平的变化。通过相关性分析、非度量多维尺度分析以及基于系统发育的二元零模型分析,探究土壤细菌群落变化的驱动机制和群落构建过程。结果表明: 1)氮添加显著影响草甸土壤细菌的群落组成,但是土壤细菌α多样性没有显著变化;2)与对照相比,氮添加使土壤无机氮含量显著增加了85.7%,碳∶氮化学计量不平衡性降低了40.6%,且其与细菌群落组成和优势菌门(拟杆菌门)的相对丰度显著相关,表明细菌类群受土壤有效氮及其引起的化学计量不平衡的显著影响;3)所有处理中细菌群落构建的随机性过程(54.7%～56.8%)均占据优势地位,但是氮添加对细菌群落构建过程无明显影响。综上,土壤有效氮及其引起的化学计量不平衡是调控氮添加下细菌类群相对丰度的主要因素,本研究为预测未来环境变化背景下高寒草地土壤微生物群落的变化提供了科学依据。

关键词: 有效氮, 生态化学计量, 高通量测序, 群落构建, 草甸

Abstract: Nitrogen is the main limiting nutrient for the productivity of grassland ecosystems, and can indirectly affect the structure of microbial communities, especially bacterial communities, by altering soil properties. In this study, we conducted a field nitrogen addition experiment in the alpine meadow of Haibei in the northeastern Tibetan Plateau. Urea was used as the nitrogen source. Five nitrogen addition levels were set up: N₀ (control, no nitrogen addition), N₅₀ (50 kg N·hm^-2·a^-1), N₁₀₀ (100 kg N·hm^-2·a^-1), N₁₅₀ (150 kg N·hm^-2·a^-1), and N₂₀₀ (200 kg N·hm^-2·a^-1). In the third year of the experiment, we collected soil samples of the surface layer to measure soil physical and chemical properties, stable isotope δ¹⁵N, and microbial biomass. The microbial stoichiometric imbalance was calculated, and bacterial community characteristics (composition, diversity, and community assembly) along the nitrogen addition levels were analyzed by 16S rRNA high-throughput sequencing. Through correlation analysis, non-metric multidimensional scaling analyses, and phylogenetic-bin-based null model analyses, we investigated the driving mechanisms of the changes in soil bacterial community composition and community assembly. The results showed that: 1) Nitrogen addition significantly altered soil bacterial community composition, but did not change the α diversity of soil bacteria. 2) Nitrogen addition significantly increased soil inorganic nitrogen content by 85.7% and reduced the stoichiometric imbalance of carbon:nitrogen by 40.6%. Soil inorganic nitrogen content and carbon:nitrogen stoichiometric imbalance were significantly correlated with bacterial community composition and the relative abundance of the dominant phylum (i.e., Bacteroidetes), indicating that bacterial taxa were significantly influenced by soil available nitrogen and stoichiometric imbalance. 3) The stochastic process (54.7%-56.8%) dominated the community assembly of soil bacteria across all treatments. Nitrogen addition had no significant effect on the community assembly of soil bacteria. In conclusion, soil available nitrogen and the resulting stoichiometric imbalance were the primary factors regulating the relative abundance of bacterial taxa under nitrogen addition. Our findings provide a scientific basis for predicting the changes of soil microbial communities in alpine meadows in the context of future environmental changes.

Key words: available nitrogen, ecological stoichiometry, high-throughput sequencing, community assembly, meadow

连晨星, 张秋芳, 任飞, 李兰平, 陈静琪, 曾泉鑫, 陈岳民, 朱彪. 生态化学计量不平衡驱动高寒草甸土壤细菌群落对氮添加的响应[J]. 应用生态学报, 2025, 36(4): 1081-1090.

LIAN Chenxing, ZHANG Qiufang, REN Fei, LI Lanping, CHEN Jingqi, ZENG Quanxin, CHEN Yuemin, ZHU Biao. Ecological stoichiometric imbalance drives the responses of soil bacterial communities to nitrogen addition in an alpine meadow[J]. Chinese Journal of Applied Ecology, 2025, 36(4): 1081-1090.

参考文献

[1] 龙世友, 鲍雅静, 李政海, 等. 内蒙古草原67种植物碳含量分析及与热值的关系研究. 草业学报, 2013, 22(1): 112-119
[2] Xu XT, Liu HY, Song ZL, et al. Response of aboveground biomass and diversity to nitrogen addition along a degradation gradient in the Inner Mongolian steppe, China. Scientific Reports, 2015, 5: 10284
[3] 刘卓艺, 王晓光, 魏海伟, 等. 氮素补给对呼伦贝尔草甸草原退化草地牧草产量和品质的影响. 应用生态学报, 2019, 30(9): 2992-2998
[4] Galloway JN, Dentener FJ, Capone DG, et al. Nitrogen cycles: Past, present, and future. Biogeochemistry, 2004, 70: 153-226
[5] Lu XK, Vitousek PM, Mao QG, et al. Nitrogen deposition accelerates soil carbon sequestration in tropical forests. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118: e2020790118
[6] 张薇, 魏海雷, 高洪文, 等. 土壤微生物多样性及其环境影响因子研究进展. 生态学杂志, 2005, 24(1): 48-52
[7] Ren JS, Huang KX, Xu FF, et al. The changes in soil microbial communities and assembly processes along vegetation succession in a subtropical forest. Forests, 2024, 15: 242
[8] Wang XD, Feng JG, Ao GKL, et al. Globally nitrogen addition alters soil microbial community structure, but has minor effects on soil microbial diversity and richness. Soil Biology and Biochemistry, 2023, 179: 108982
[9] 杨山, 李小彬, 王汝振, 等. 氮水添加对中国北方草原土壤细菌多样性和群落结构的影响. 应用生态学报, 2015, 26(3): 739-746
[10] Yang A, Liu NN, Tian QY, et al. Rhizosphere bacterial communities of dominant steppe plants shift in response to a gradient of simulated nitrogen deposition. Frontiers in Microbiology, 2015, 6: 789
[11] Zhou JZ, Ning DL. Stochastic community assembly: Does it matter in microbial ecology? Microbiology and Molecular Biology Reviews, 2017, 81: e00002-17
[12] Fierer N, Bradford MA, Jackson RB. Toward an ecolo-gical classification of soil bacteria. Ecology, 2007, 88: 1354-1364
[13] Cui H, He C, Zheng WW, et al. Effects of nitrogen addition on rhizosphere priming: The role of stoichiometric imbalance. Science of the Total Environment, 2024, 914: 169731
[14] Ning DL, Deng Y, Tiedje JM, et al. A general framework for quantitatively assessing ecological stochasticity. Proceedings of the National Academy of Sciences of the United States of America, 2019, 116: 16892-16898
[15] 马转转, 乔沙沙, 曹苗文, 等. 环境选择和扩散限制驱动温带森林土壤细菌群落的构建. 应用生态学报, 2018, 29(4): 1179-1189
[16] Gossner MM, Lewinsohn TM, Kahl T, et al. Land-use intensification causes multitrophic homogenization of grassland communities. Nature, 2016, 540: 266-269
[17] Martiny JBH, Eisen JA, Penn K, et al. Drivers of bacterial β-diversity depend on spatial scale. Proceedings of the National Academy of Sciences of the United States of America, 2011, 108: 7850-7854
[18] He JH, Jiao S, Tan XP, et al. Adaptation of soil fungal community structure and assembly to long- versus short-term nitrogen addition in a tropical forest. Frontiers in Microbiology, 2021, 12: 689674
[19] Zheng W, Zhao ZY, Lv FL, et al. Fungal alpha diversity influences stochasticity of bacterial and fungal community assemblies in soil aggregates in an apple orchard. Applied Soil Ecology, 2021, 162: 103878
[20] Dini-Andreote F, Stegen JC, van Elsas JD, et al. Disentangling mechanisms that mediate the balance between stochastic and deterministic processes in microbial succession. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112: 1326-1332
[21] Zhang XM, Johnston ER, Liu W, et al. Environmental changes affect the assembly of soil bacterial community primarily by mediating stochastic processes. Global Change Biology, 2016, 22: 198-207
[22] Zhou ZH, Zheng MH, Xia JY, et al. Nitrogen addition promotes soil microbial beta diversity and the stochastic assembly. Science of the Total Environment, 2022, 806: 150569
[23] Louca S, Polz MF, Mazel F, et al. Function and functional redundancy in microbial systems. Nature Ecology and Evolution, 2018, 2: 936-943
[24] 刘艳, 陈梦娇, 郭童童, 等. 多梯度氮磷添加对高寒草甸植物群落生物量与氮磷含量的影响. 草地学报, 2023, 31(3): 751-759
[25] Lu XY, Yan Y, Sun J, et al. Carbon, nitrogen, and phosphorus storage in alpine grassland ecosystems of Tibet: Effects of grazing exclusion. Ecology and Evolution, 2015, 5: 4492-4504
[26] 叶琼丹, 任飞, 李永慧, 等. 不同养分添加对高寒植物功能性状的影响. 草地学报, 2022, 30(10): 2737-2744
[27] Carter MR, Gregorich EG. Soil Sampling and Methods of Analysis. Boca Raton, FL, USA: CRC Press, 1993: 20-23
[28] Bu XL, Wang LM, Ma WB, et al. Spectroscopic cha-racterization of hot-water extractable organic matter from soils under four different vegetation types along an elevation gradient in the Wuyi Mountains. Geoderma, 2010, 159: 139-146
[29] Vance ED, Brookes PC, Jenkinson DS. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry, 1987, 19: 703-707
[30] Claesson MJ, O'Sullivan O, Wang Q, et al. Comparative analysis of pyrosequencing and a phylogenetic microarray for exploring microbial community structures in the human distal intestine. PLoS One, 2009, 4: e6669
[31] Chao A, Lee SM, Jeng SL. Estimating population size for capture-recapture data when capture probabilities vary by time and individual animal. Biometrics, 1992, 48: 201-216
[32] Shannon CE. The mathematical theory of communication. The Bell System Technical Journal, 1948, 27: 379-423
[33] Li J, Sang CP, Yang JY, et al. Stoichiometric imba-lance and microbial community regulate microbial elements use efficiencies under nitrogen addition. Soil Bio-logy and Biochemistry, 2021, 156: 108207
[34] 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. 应用生态学报, 2024, 35(8): 2108-2118
[35] Ning DL, Yuan MT, Wu LW, et al. A quantitative framework reveals ecological drivers of grassland microbial community assembly in response to warming. Nature Communications, 2020, 11: 4717
[36] Li M, Zhang XZ, He YT, et al. Assessment of the vulnerability of alpine grasslands on the Qinghai-Tibetan Plateau. PeerJ, 2020, 8: e8513
[37] Jia MQ, Gao ZW, Gu HJ, et al. Effects of precipitation change and nitrogen addition on the composition, diversity, and molecular ecological network of soil bacterial communities in a desert steppe. PLoS One, 2021, 16: e0248194
[38] Wu BB, Wang P, Devlin AT, et al. Influence of soil and water conservation measures on soil microbial communities in a citrus orchard of southeast China. Microorganisms, 2021, 9: 319
[39] Fierer N, Lauber CL, Ramirez KS, et al. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients. The ISME Journal, 2012, 6: 1007-1017
[40] van der Heijden MGA, Bardgett RD, van Straalen NM. The unseen majority: Soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems. Eco-logy Letters, 2008, 11: 296-310
[41] 曾红丽, 白炜, 房佳辰, 等. 模拟增温对高寒沼泽草甸土壤细菌群落的影响. 环境科学与技术, 2022, 45(4): 164-172
[42] Cui YX, Bing HJ, Fang LC, et al. Diversity patterns of the rhizosphere and bulk soil microbial communities along an altitudinal gradient in an alpine ecosystem of the eastern Tibetan Plateau. Geoderma, 2019, 338: 118-127
[43] Delgado-Baquerizo M, Reich PB, Khachane AN, et al. It is elemental: Soil nutrient stoichiometry drives bacterial diversity. Environmental Microbiology, 2017, 19: 1176-1188
[44] Cleveland CC, Liptzin D. C:N:P stoichiometry in soil: Is there a “Redfield ratio” for the microbial biomass? Biogeochemistry, 2007, 85: 235-252
[45] He XJ, Abs E, Allison SD, et al. Emerging multiscale insights on microbial carbon use efficiency in the land carbon cycle. Nature Communications, 2024, 15: 8010
[46] Domeignoz-Horta LA, Pold G, Liu XJA, et al. Micro-bial diversity drives carbon use efficiency in a model soil. Nature Communications, 2020, 11: 3684
[47] 王常慧, 邢雪荣, 韩兴国. 草地生态系统中土壤氮素矿化影响因素的研究进展. 应用生态学报, 2004, 15(11): 2184-2188
[48] Gao WJ, Ma T, Shi BW, et al. Effects of nitrogen and phosphorus addition on the mineralization potential of soil organic carbon and the corresponding regulations in the Tibetan alpine grassland. Applied Soil Ecology, 2024, 196: 105314
[49] Luan L, Liang C, Chen LJ, et al. Coupling bacterial community assembly to microbial metabolism across soil profiles. mSystems, 2020, 5: e00298-20
[50] Xu XF, Wang NN, Lipson D, et al. Microbial macroecology: In search of mechanisms governing microbial biogeographic patterns. Global Ecology and Biogeography, 2020, 29: 1870-1886
[51] Wang HC, Qi JF, Xiao DR, et al. Bacterial community diversity and underlying assembly patterns along vertical soil profiles in wetland and meadow habitats on the Zoige Plateau, China. Soil Biology and Biochemistry, 2023, 184: 109076

生态化学计量不平衡驱动高寒草甸土壤细菌群落对氮添加的响应

Ecological stoichiometric imbalance drives the responses of soil bacterial communities to nitrogen addition in an alpine meadow

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	杜安娜, 张玉革, 李慧, 姜勇, 冯雪. 土壤酸化对草甸草原植物形态性状和光合色素含量的影响 [J]. 应用生态学报, 2025, 36(2): 473-480.
[2]	张仲富, 王禹童, 艾静, 刀静梅, 李傲梅, 邓军, 吴建明, 赵勇. 钾肥对甘蔗根际微生物多样性和群落构建过程的影响 [J]. 应用生态学报, 2025, 36(2): 526-536.
[3]	李昱达, 王国华, 赵丽娜, 缑倩倩. 荒漠绿洲边缘不同种植年限人工梭梭林土壤和根系微生物群落特征 [J]. 应用生态学报, 2025, 36(1): 39-49.
[4]	宋珊珊, 朱江玲, 唐志尧. 短期围封对河北塞罕坝草甸草原植物功能多样性的影响 [J]. 应用生态学报, 2025, 36(1): 104-112.
[5]	吴傲淼, 洪宗文, 游成铭, 徐琳, 徐红伟, 徐振锋, 骆紫藤, 谭波. 华西雨屏区不同林龄柳杉人工林土壤团聚体碳氮磷化学计量特征 [J]. 应用生态学报, 2024, 35(9): 2518-2526.
[6]	冯莉绚, 黄志群, 王振宇, 王涛, 卢安琪, 邹秉章, 王思荣, 陈志杰. 恢复年限对亚热带次生林土壤化学计量比的影响 [J]. 应用生态学报, 2024, 35(8): 2091-2098.
[7]	王倩, 王克勤, 宋娅丽, 陈雨芊, 彭秀媛, 邓秋江. 滇中云南松林土壤-微生物-胞外酶化学计量特征对氮沉降的响应 [J]. 应用生态学报, 2024, 35(7): 1789-1798.
[8]	蔡斌, 董瑞, 花蕊, 刘济泽, 王磊, 郝媛媛, 杨思维, 花立民. 基于无人机影像的鼠害地秃斑识别算法筛选 [J]. 应用生态学报, 2024, 35(7): 1951-1958.
[9]	尧波, 邹素珍, 梁金凤, 叶家飞, 徐晨瀛, 汪晓倩, 任琼, 胡启武. 候鸟活动对鄱阳湖苔草湿地土壤碳氮磷化学计量特征的影响 [J]. 应用生态学报, 2024, 35(7): 1988-1996.
[10]	王宇昕, 赵文智, 刘鹄. 生态系统突变及其在寒旱区生态系统管理中的应用展望 [J]. 应用生态学报, 2024, 35(7): 1997-2005.
[11]	李非凡, 陈淼, 刘顺, 许格希, 陈健, 邢红爽, 史作民. 青藏高原东缘亚高山森林群落的多维度生物多样性 [J]. 应用生态学报, 2024, 35(6): 1447-1454.
[12]	孙新, 谢致敬, 乔志宏, 高梅香, 殷睿, 常亮, 吴东辉, 刘满强, 朱永官. 基于功能性状的土壤动物群落生态学研究进展 [J]. 应用生态学报, 2024, 35(4): 1150-1158.
[13]	刘一麟, 任悦, 高广磊, 丁国栋, 张英, 柳叶. 樟子松林根际与非根际土壤碳氮磷化学计量特征 [J]. 应用生态学报, 2024, 35(3): 615-621.
[14]	艾灵, 吴福忠, 樊雪波, 杨静, 吴秋霞, 朱晶晶, 倪祥银. 米槠和杉木人工林土壤酶活性和酶化学计量特征对凋落物输入的短期响应 [J]. 应用生态学报, 2024, 35(3): 631-638.
[15]	孙官发, 陆梅, 闪昇阳, 赵定蓉, 孙煜佳, 刘国庆, 赵旭燕, 冯峻. 短期氮沉降对纳帕海高寒退化疏花早熟禾草甸土壤呼吸干湿季变化的影响 [J]. 应用生态学报, 2024, 35(2): 390-398.