环境选择和扩散限制驱动温带森林土壤细菌群落的构建

doi:10.13287/j.1001-9332.201804.039

应用生态学报 ›› 2018, Vol. 29 ›› Issue (4): 1179-1189.doi: 10.13287/j.1001-9332.201804.039

环境选择和扩散限制驱动温带森林土壤细菌群落的构建

马转转¹, 乔沙沙², 曹苗文², 周永娜², 刘晋仙², 贾彤², 李毳³, 柴宝峰^2*

¹山西大学生物技术研究所, 太原 030006;
²山西大学黄土高原研究所, 太原 030006;
³山西财经大学环境经济学院, 太原 030006;

收稿日期:2017-08-02 出版日期:2018-04-18 发布日期:2018-04-18
通讯作者: * E-mail: bfchai@sxu.edu.cn
作者简介:马转转,女, 1992年生,硕士. 主要从事微生物生态学研究. E-mail: 1041568938@qq.com
基金资助:
本文由国家自然科学基金项目(31772450)、山西省科技攻关项目(20150313001-3)和山西省应用基础研究基金项目(201601D102054)资助

Environmental selection and dispersal limitation drive the assemblage of bacterial community in temperate forest soils

MA Zhuan-zhuan¹, QIAO Sha-sha², CAO Miao-wen², ZHOU Yong-na², LIU Jin-xian², JIA Tong², LI Cui³, CHAI Bao-feng²

¹Institute of Biotechnology, Shanxi University, Taiyuan 030006, China;
²Institute of Loess Plateau, Shanxi University, Taiyuan 030006, China;
³Department of Environment and Economics, Shanxi University of Finance and Economics, Taiyuan 030006, China;

Received:2017-08-02 Online:2018-04-18 Published:2018-04-18
Contact: * E-mail: bfchai@sxu.edu.cn
Supported by:
This work was supported by the National Natural Science Foundation of China (31772450), the Science and Technology Research Project of Shanxi Province (20150313001-3) and the Applied Basic Research Foundation of Shanxi Province (201601D102054).

摘要/Abstract

摘要： 环境选择和扩散限制是生态系统中生物群落构建的两个基本过程,而两者相对作用的大小因研究尺度、群落属性和类型等有所不同.目前对温带亚高山森林土壤微生物群落构建的驱动因子和机制尚缺乏了解.本文利用PCR-DGGE技术研究庞泉沟自然保护区内5种典型森林包括华北落叶松林、青杄林、白杄林、油松林以及桦树林的6个森林土壤细菌群落(LpMC1、LpMC2、PwMC、PmMC、PtMC、BMC)的结构特征及其影响因素,分析细菌群落结构与环境因子的相关性,以及土壤因子、植被和空间因素对细菌群落结构的影响.结果表明: 研究区各样地土壤细菌群落的结构和生物多样性具有显著差异,低海拔落叶松和油松土壤细菌群落多样性较高(20条带),白杄林土壤细菌群落(13条带)多样性最低,高海拔落叶松土壤细菌群落多样性最高;土壤环境因子,如pH、土壤含水量、总碳、总氮、土壤有机质、速效磷以及土壤酶活性与土壤细菌群落多样性和结构显著相关;样地土壤细菌群落的beta多样性与群落的空间距离呈显著相关,表明扩散限制对群落结构具有一定的影响;方差分解分析结果显示,6个样地细菌群落结构的驱动因素大小依次为土壤因子(0.27)、空间因素(0.19)和植被(0.15);将区域土壤微生物作为“源群落”,微宇宙试验结果显示,土壤因子是细菌群落结构形成的主要驱动力(0.35),同时源群落丰富的物种多样性对微宇宙土壤细菌群落结构具有显著影响.总之,在局域尺度下,环境选择对温带森林土壤细菌群落结构动态和多样性发挥主导作用,地理距离对群落结构具有显著影响,即确定性过程和随机过程共同决定局域森林土壤细菌群落结构,前者占主导地位.对于土壤细菌群落而言,扩散群落的组成和结构受到源群落的多样性特征和环境因子的双重影响.

Abstract: Environmental selection and dispersal limitation are two basic processes underlying community assembly. The relative importance of those two processes differs across scales, community identities, and community types. The processes responsible for structuring microbial communities in soil of temperate subalpine forest are poorly understood. Here, we investigated the relationship between soil bacterial community structure and environmental factors, and quantified the relative role of edaphic factors, vegetation, and spatial variables in shaping the structure of six soil bacterial communities (LpMC1, LpMC2, PwMC, PmMC, PtMC, and BMC) in five forest types including Larix principis-rupprechtii, Picea wilsonii, Picea meyeri, Pinus tabulaeformis, and Betula platyphylla in Pangquangou Nature Reserve by using PCR-DGGE technology. Our results showed that the structure and biodiversity of bacterial communities were significantly different among six communities. The biodiversity of bacterial community were higher in LpMC2 and PtMC, lowest in PmMC, and highest in LpMC1. Soil environmental factors, such as pH, soil water content, total carbon, total nitrogen, soil organic matter, available phosphorous, and soil enzymes, were significantly correlated with biodiversity and structure of soil bacterial community. The beta diversity of bacterial communities were significantly correlated with geographic distance, indicating the influence of dispersal limitation on the structure of bacterial community. The order of driving force on the structure of bacterial community was edaphic factors (0.27), spatial factor (0.19) and vegetation (0.15) in six samples. Using regional soil microbes from 10 samples around reserve as source community, results from the microcosm experiments showed that the edaphic factors were the predominant driving factors (0.35) on structure of artificial dispersal bacterial community, while the high diversity of source microbial community affected the structure of microcosm soil. In summary, at local scale, environmental selection predominantly determined the structural and biodiversity of soil bacterial communities in temperate subalpine forest, while dispersal limitation played a significant role. Such a result indicated that deterministic processes and stochastic processes played important roles in shaping the structure of soil bacterial community at local scale, with the former having the leading role. The composition of dispersal soil bacteria community was source-dependent but also modulated by local environmental selection.

马转转, 乔沙沙, 曹苗文, 周永娜, 刘晋仙, 贾彤, 李毳, 柴宝峰. 环境选择和扩散限制驱动温带森林土壤细菌群落的构建[J]. 应用生态学报, 2018, 29(4): 1179-1189.

MA Zhuan-zhuan, QIAO Sha-sha, CAO Miao-wen, ZHOU Yong-na, LIU Jin-xian, JIA Tong, LI Cui, CHAI Bao-feng. Environmental selection and dispersal limitation drive the assemblage of bacterial community in temperate forest soils[J]. Chinese Journal of Applied Ecology, 2018, 29(4): 1179-1189.

参考文献

[1] Hutchinson GE. Homage to santa rosalia or why are there so many kinds of animals? The American Naturalist, 1959, 93: 145-159
[2] Bell G. The distribution of abundance in neutral communities. The American Naturalist, 2000, 155: 606-617
[3] Hubbell SP. The Unified Neutral Theory of Biodiversity and Biogeography. Princeton, NJ: Princeton University Press, 2001
[4] Gravel D, Canham CD, Beaudet M, et al. Reconciling niche and neutrality: The continuum hypothesis. Ecology Letters, 2006, 9: 399-409
[5] Gewin V. Beyond neutrality-ecology finds its niche. PLoS Biology, 2006, 4(8): e278
[6] Niu K-C (牛克昌), Liu Y-N (刘怿宁), Shen Z-H (沈泽昊), et al. Community assembly: The relative importance of neutral theory and niche theory. Biodiversity Science (生物多样性), 2009, 17(6): 579-593 (in Chinese)
[7] Chase JM, Myers JA. Disentangling the importance of ecological niches from stochastic processes across scales. Philosophical transactions of the Royal Society of London Series B: Biological Sciences, 2011, 366: 2351-2363
[8] Logue JB, Findlay SE, Comte J. Editorial: microbial responses to environmental changes. Frontiers in Microbio-logy, 2015, 6: 1364
[9] Widder S, Allen RJ, Pfeiffer T, et al. Challenges in microbial ecology: Building predictive understanding of community function and dynamics. ISME Journal, 2016, 10: 2557-2568
[10] Evans S, Martiny JB, Allison SD. Effects of dispersal and selection on stochastic assembly in microbial communities. ISME Journal, 2017, 11: 176-185
[11] Cj VDG. Microbial biogeography: The end of the ubiquitous dispersal hypothesis? Environmental Microbiology, 2015, 17: 544-546
[12] Hazard C, Gosling P, Cj VDG, et al. The role of local environment and geographical distance in determining community composition of arbuscular mycorrhizal fungi at the landscape scale. ISME Journal, 2013, 7: 498-508
[13] Ranjard L, Dequiedt S, Chemidlin PN, et al. Turnover of soil bacterial diversity driven by wide-scale environmental heterogeneity. Nature Communications, 2013, 4: 66-78
[14] Papke RT, Ramsing NB, Bateson MM, et al. Geographi-cal isolation in hot spring cyanobacteria. Environmental Microbiology, 2003, 5: 650-659
[15] Whitaker RJ, Grogan DW, Taylor JW. Geographic barriers isolate endemic populations of hyperthermophilic archaea. Science, 2003, 301: 976-978
[16] Lindstrom ES, Eiler A, Langenheder S, et al. Does ecosystem size determine aquatic bacterial richness? Comment. Ecology, 2007, 88: 252-255
[17] Yannarell AC, Triplett EW. Geographic and environmental sources of variation in lake bacterial community composition. Applied and Environmental Microbiology, 2005, 71: 227-239
[18] Cox F, Barsoum N, Lilleskov EA, et al. Nitrogen avai-lability is a primary determinant of conifer mycorrhizas across complex environmental gradients. Ecology Letters, 2010, 13: 1103-1113
[19] Bahram M, P#xF1lme S, K#xF1ljalg U, et al. Regional and local patterns of ectomycorrhizal fungal diversity and community structure along an altitudinal gradient in the Hyrcanian forests of northern Iran. New Phytologist, 2015, 193: 465-473
[20] Zeng QC, Dong YH, An SS. Bacterial community responses to soils along a latitudinal and vegetation gradient on the Loess Plateau, China. PLoS One, 2016, 11(4): e0152894
[21] Shen CC, Xiong JB, Zhang HY, et al. Soil pH drives the spatial distribution of bacterial communities along elevation on Changbai Mountain. Soil Biology & Biochemistry, 2013, 57(00): 204-211
[22] Qiao S-S (乔沙沙), Zhou Y-N (周永娜), Liu J-X (刘晋仙), et al. Characteristics of soil bacterial community structure in coniferous forests of Guandi mountains, Shanxi Province. Scientia Silvae Sinicae (林业科学), 2017, 53(2): 89-99 (in Chinese)
[23] Bell T. Experimental tests of the bacterial distance-decay relationship. ISME Journal, 2010, 4: 1357-1365
[24] Lu R-K (鲁如坤). Soil and Agro-chemistry Analysis. Beijing: China Agriculture Science and Technology Press, 2000 (in Chinese)
[25] Guan S-Y (关松荫). Soil Enzymes and the Research Methodology. Beijing: China Agriculture Press, 1986 (in Chinese)
[26] Shanmugam SG, Magbanua ZV, Williams MA, et al. Bacterial diversity patterns differ in soils developing in sub-tropical and cool-temperate ecosystems. Microbial Ecology, 2017, 73: 556-569
[27] Ge Y, He JZ, Zhu YG, et al. Differences in soil bacterial diversity: Driven by contemporary disturbances or historical contingencies? ISME Journal, 2008, 2: 254-264
[28] Dumbrell AJ, Nelson M, Helgason T, et al. Relative roles of niche and neutral processes in structuring a soil microbial community. ISME Journal, 2010, 4: 337-345
[29] Faoro H, Alves AC, Souza EM, et al. Influence of soil characteristics on the diversity of bacteria in the Southern Brazilian Atlantic Forest. Applied and Environmental Microbiology, 2010, 76: 4744-4749
[30] Siles JA, Cajthaml T, Minerbi S, et al. Effect of altitude and season on microbial activity, abundance and community structure in Alpine forest soils. FEMS Microbiology Ecology, 2016, 92: doi: 10.1093/femsec/fiw008
[31] Tian J, Mccormack L, Wang JY, et al. Linkages between the soil organic matter fractions and the microbial metabolic functional diversity within a broad-leaved Korean pine forest. European Journal of Soil Biology, 2015, 66: 57-64
[32] Zheng H-F (郑海峰), Chen Y-M (陈亚梅), Yang L(杨林), et al. Responses of soil microbial community structure to simulated warming in alpine timberline in western Sichuan, China. Chinese Journal of Applied Ecology (应用生态学报), 2017, 28(9): 2840-2848(in Chinese)
[33] Cao R (曹瑞), Wu F-Z (吴福忠), Yang W-Q (杨万勤), et al. Effects of altitudes on soil microbial biomass and enzyme activity in alpine-gorge regions. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(4): 1257-1264(in Chinese)
[34] Burns JH, Anacker BL, Strauss SY, et al. Soil microbial community variation correlates most strongly with plant species identity, followed by soil chemistry, spatial location and plant genus. AoB Plants, 2015, 7: doi: 10.1093/aobpla/plv030
[35] Dini-Andreote F, de Cassia Pereira e Silva M, Triado-Margarit X, et al. Dynamics of bacterial community succession in a salt marsh chronosequence: Evidences for temporal niche partitioning. ISME Journal, 2014, 8: 1989-2001
[36] Barberan A, Bates ST, Casamayor EO, et al. Using network analysis to explore co-occurrence patterns in soil microbial communities. ISME Journal, 2012, 6: 343-351
[37] Rutger DW, Thierry B. ‘Everything is everywhere, but, the environment selects’; what did Baas Becking and Beijerinck really say? Environmental Microbiology, 2006, 8: 755-758
[38] Liao JQ, Cao XF, Zhao L, et al. The importance of neutral and niche processes for bacterial community assembly differs between habitat generalists and specia-lists. FEMS Microbiology Ecology, 2016, 92: 1-10
[39] Schadt CW, Rosling A. Fungal biogeography. Comment on “Global diversity and geography of soil fungi”. Science, 2015, 348: 1438
[40] Cermeno P, Vargas CD, Abrantes F, et al. Phytoplankton biogeography and community stability in the ocean. PLoS One, 2010, 5(4): e10037
[41] Szekely AJ, Berga M, Langenheder S. Mechanisms determining the fate of dispersed bacterial communities in new environments. ISME Journal, 2013, 7: 61-71
[42] Karayanni H, Meziti A, Spatharis S, et al. Changes in microbial (Bacteria and Archaea) plankton community structure after artificial dispersal in grazer-free microcosms. Microorganisms, 2017, 5: 1-14
[43] Krause E, Wichels A, Gimenez L, et al. Small changes in pH have direct effects on marine bacterial community composition: A microcosm approach. PLoS One, 2012, 7(10): e47035
[44] Langenheder S, Lindstrom ES, Tranvik LJ. Structure and function of bacterial communities emerging from different sources under identical conditions. Applied and Environmental Microbiology, 2006, 72: 212-220
[45] Lima-Mendez G, Faust K, Henry N, et al. Ocean plankton. Determinants of community structure in the global plankton interactome. Science, 2015, 348: 1262073
[46] Lupatini M, Suleiman AKA, Jacques RJS, et al. Network topology reveals high connectance levels and few key microbial genera within soils. Frontiers in Environmental Science, 2014, 2: 1-10

环境选择和扩散限制驱动温带森林土壤细菌群落的构建

Environmental selection and dispersal limitation drive the assemblage of bacterial community in temperate forest soils

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