关帝山针叶林土壤细菌群落结构特征

doi:10.11707/j.1001-7488.20170211

摘要/Abstract

摘要： [目的] 分析环境与空间因素在寒温性针叶林土壤细菌群落构建中的作用，为区域森林生态系统管理措施的制定提供理论依据。[方法] 利用Illumina高通量测序技术分析关帝山庞泉沟自然保护区华北落叶松林（Lp）、青杄林（Pw）以及油松林（Pt）4个土壤细菌群落（LpMC1、LpMC2、PwMC和PtMC）的结构，同时测定土壤理化性质和土壤酶活性，探讨细菌群落结构与森林类型和土壤环境因子的相关性。[结果] 1）在该区域的森林土壤细菌群落中，变形菌门、拟杆菌门、放线菌门、疣微菌门、浮霉菌门、酸杆菌门、厚壁菌门、芽单胞菌门、绿弯菌门、衣原体门和硝化螺旋菌门为优势细菌群。2）优势细菌类群相对丰度和土壤环境因子的RDA分析表明，土壤含水率、碳氮比、pH以及土壤酶活性是影响土壤细菌群落结构的重要因子。其中，变形菌门中的大部分类群和拟杆菌门更适于生活在酸性、湿度大、营养状况良好的土壤中，主要碳源是易分解性碳；放线菌门、浮霉菌门和绿弯菌门则在碱性、干旱、营养贫瘠的土壤中更占优势，主要分解顽固性碳。3）Alpha多样性分析结果表明，土壤细菌群落多样性在4个样地间存在差异，在营养贫瘠的油松林样地土壤中细菌群落（PtMC）丰富度低，多样性高；而在营养丰富的高海拔华北落叶松样地中细菌群落（LpMC1）丰富度高，多样性低。4）细菌群落Beta多样性分析结果表明，青杄林和油松林的土壤细菌群落（PwMC与PtMC）、高海拔华北落叶松林和低海拔华北落叶松林的土壤细菌群落（LpMC1与LpMC2）结构分别具有相似性。[结论] 受环境选择和扩散限制的共同影响，不同针叶林土壤细菌群落结构和物种多样性具有显著差异。据此，可通过制定不同的育林措施，改变林下土壤环境，进而优化土壤细菌群落结构；提高土壤碳汇，促进土壤氮、硫、磷等营养物质的循环，提高土壤肥力。

关键词: 环境选择, 扩散限制, 关帝山, 针叶林, 高通量测序, 细菌群落结构

Abstract: [Objective] Soil microorganisms drive the biogeochemical processes of carbon, nitrogen, phosphorus and sulfur in soil, and play a key role in maintaining soil carbon sink and forest ecosystem function. In this study, we analysed effects of environmental and spatial factors on the soil bacterial community structure in cold-temperature coniferous forest,which would provide the oretical basis for making management measures for the local forest ecosystem.[Method] This research analyzed four soil bacteria communities (LpMC1, LpMC2, PwMC and PtMC) in three coniferous forest types, including Larix gmelinii var. principis-rupprechtii forest, Picea wilsonii forest and Pinus tabulaeformis forest in the Pangquangou Nature Reserve in Guandi Mountains with Illumina high-throughput sequencing technology. Meanwhile, soil enzyme activity and soil physicochemical properties were determined to analyze the relationship between bacteria community structure and forest types as well as soil environmental factors.[Result] 1) In the region, Proteobacteria, Bacteroidetes, Actinobacteria, Verrucomicrobia, Planctomycetes, Acidobacteria, Firmicutes, Gemmatimonadetes, Chloroflexi, Chlamydiae and Nitrospirae were dominant bacteria groups; 2) Redundancy analysis between the relative abundance of dominant bacterial groups and soil environmental parameters showed that soil moisture content, carbon and nitrogen ratio, pH and soil enzyme activity were the main factors that affected soil bacterial community structure; Proteobacteria and Bacteroidetes were relatively more suitable for living in the acid, humidity and nutrition rich status soil, and active carbon was the main carbon source, while Actinobacteria, Planctomycetes and Chloroflexi were more dominant in alkaline, drought and poor nutrient soil, and resistant carbon was the main carbon source.3) Alphadiversity analysis showed that there existed difference in diversity of soil bacteria community between the four coniferous forests.Low richness and high diversity were observed in P. tabulaeformis forest (PtMC) with poor nutrient while high richness and low diversity were observed in L. gmelinii var.principis-rupprechtii forest (LpMC1) on high altitude with rich nutrient.4) Beta diversity analysis showed that bacteria community structures of P. wilsonii forest and P. tabuliformis forest were the most similar while L. gmelinii var.principis-rupprechtii forests on different elevations had the same trend.[Conclusion] Environmental selection and dispersal limitation led to the significant differences of structure and biodiversity among soil bacterial communities from coniferous forests in the study area. Hereby, through the development of different forest management measures, we can change the soil environment,and then optimize the soil bacterial community structure, improve the soil carbon sequestration, and promote the recycling of nutrients such as nitrogen, sulfur and phosphorus in improving soil fertility.

Key words: environmentalselection, dispersal limitation, Guandi Mountains, coniferous forest, high-throughput sequencing, bacterial community structure

中图分类号:

S718.83

乔沙沙, 周永娜, 刘晋仙, 景炬辉, 贾彤, 李毳, 杨欣, 柴宝峰. 关帝山针叶林土壤细菌群落结构特征[J]. 林业科学, 2017, 53(2): 89-99.

Qiao Shasha, Zhou Yongna, Liu Jinxian, Jing Juhui, Jia Tong, Li Cui, Yang Xin, Chai Baofeng. Characteristics of Soil Bacterial Community Structure in Coniferous Forests of Guandi Mountains, Shanxi Province[J]. Scientia Silvae Sinicae, 2017, 53(2): 89-99.

参考文献

常雅军,曹靖,李建建,等. 2009.秦岭西部山地针叶林凋落物层的化学性质.生态学杂志,28(07):1308-1315.
(Chang Y J, Cao J, Li J J, et al.2009.Chemical properties of litter layers in coniferous forests of western Qinling Mountains. Chinese Journal of Ecology,28(07):1308-1315.[in Chinese])
关松荫. 1986.土壤酶及其研究法.北京:中国农业出版社.
(Guan S Y. 1986. Soil enzymes and research method. Beijing:China Agriculture Press.[in Chinese])
刘欣宇,霍姗姗,陈歆,等. 2015.植物根系分泌物的组成及分析方法研究进展.中国热带农业,(3):100-106.
(Liu X Y, Huo S S, Chen X, et al.2015. The research development of composition and analysis methods of plant root secretion. China Tropical Agriculture,(3):100-106.[in Chinese])
徐冰,张大勇.2014.微生物多样性及其分布的研究进展:模式与过程.生命科学,26(2):144-152.
(Xu B, Zhang D Y. 2014. Progress on the biodiversity of microorganisms:patterns and processes.Chinese Bulletin of Life Sciences, 26(2):144-152.)
周礼恺. 1987.土壤酶学.北京:科学出版社.
(Zhou L K. 1987. Soil Enzymology. Beijing:Science Press.[in Chinese])
朱丽霞,章家恩,刘文高. 2003.根系分泌物与根际微生物相互作用研究综述.生态环境,12(1):102-105.
(Zhu L X, Zhang J E, Liu W G.2003. Review of studies on interactions between root exudatesand rhizopheric microorganisms. Ecology and Environment, 12(1):102-105.[in Chinese])
Bahram M, Kõljalg U, Courty P, et al. 2013. The distance decay of similarity in communities of ectomycorrhizal fungi in different ecosystems and scales. Journal of Ecology,101(5):1335-1344.
Bahram M, Polme S, Koljalg U, et al. 2012. Regional and local patterns of ectomycorrhizal fungal diversity and community structure along an altitudinal gradient in the Hyrcanian forests of northern Iran. New Phytologist,193(2):465-473.
Bastian F, Bouziri L, Nicolardot B, et al. 2009. Impact of wheat straw decomposition on successional patterns of soil microbial community structure. Soil Biology and Biochemistry,41(2):262-275.
Chu H, Fierer N, Lauber C L, et al. 2010. Soil bacterial diversity in the Arctic is not fundamentally different from that found in other biomes. Environmental Microbiology,12(11):2998-3006.
Cottenie K. 2005. Integrating environmental and spatial processes in ecological community dynamics. Ecology Letters,8(11):1175-1182.
Cox F, Barsoum N, Lilleskov E A, et al. 2010. Nitrogen availability is a primary determinant of conifer mycorrhizas across complex environmental gradients. Ecology Letters,13(9):1103-1113.
Debruyn J M, Nixon L T, Fawaz M N, et al. 2011. Global biogeography and quantitative seasonal dynamics of gemmatimonadetes in soil. Applied and Environmental Microbiology,77(17):6295-6300.
Fierer N, Bradford M A, Jackson R B. 2007. Toward an ecological classification of soil bacteria. Ecology,88(6):1354-1364.
Guo G, Kong W, Liu J, et al. 2015. Diversity and distribution of autotrophic microbial community along environmental gradients in grassland soils on the Tibetan Plateau. Applied Microbiology and Biotechnology,99(20):8765-8776.
Han W, Kemmitt S J, Brookes P C. 2007. Soil microbial biomass and activity in Chinese tea gardens of varying stand age and productivity. Soil Biology and Biochemistry,39(7):1468-1478.
Högberg M N, Högberg P, Myrold D D. 2006. Is microbial community composition in boreal forest soils determined by pH, C-to-N ratio, the trees, or all three? Oecologia,150(4):590-601.
Hooper D U, Bignell D E, Brown V K, et al. 2000. Interactions between aboveground and belowground biodiversity in terrestrial ecosystems:Patterns, mechanisms, and feedbacks. BioScience,50(12):1049-1061.
Huang L N, Tang F Z, Song Y S, et al. 2011. Biodiversity, abundance, and activity of nitrogen-fixing bacteria during primary succession on a copper mine tailings. FEMS Microbiology Ecology,78(3):439-450.
Kranabetter J M, Durall D M, Mackenzie W H. 2009. Diversity and species distribution of ectomycorrhizal fungi along productivity gradients of a southern boreal forest. Mycorrhiza. 19(2):99-111.
Lauber C L, Hamady M, Knight R, et al. 2009. Pyrosequencing-Based assessment of soil pH as a predictor of soil bacterial community structure at the continental scale. Applied and Environmental Microbiology,75(15):5111-5120.
Lauber C L, Strickland M S, Bradford M A, et al. 2008. The influence of soil properties on the structure of bacterial and fungal communities across land-use types. Soil Biology and Biochemistry,40(9):2407-2415.
Li X, Sun M, Zhang H, et al. 2016. Use of mulberry-soybean intercropping in salt-alkali soil impacts the diversity of the soil bacterial community. Microbial Biotechnology,9(3):293-304.
Lindström E S, Langenheder S. 2012. Local and regional factors influencing bacterial community assembly. Environmental Microbiology Reports,4(1):1-9.
Logue J B, Lindström E S. 2011. Species sorting affects bacterioplankton community composition as determined by 16S rDNA and 16S rRNA fingerprints. ISME Journal,4:729-738.
Martinez-Toledo M V, De La Rubia T. 1988. Root exudates of Zea mays and production of auxins, gibberellins and cytokinins by Azotobacter chroococcum. Plant and Soil,110:149-152.
Martiny J B H, Eisen J A, Penn K, et al. 2011. Drivers of bacterial-diversity depend on spatial scale. Proceedings of the National Academy of Sciences,108(19):7850-7854.
Peay K G, Kennedy P G, Bruns T D. 2011. Rethinking ectomycorrhizal succession:are root density and hyphal exploration types drivers of spatial and temporal zonation? Fungal Ecology,4(3):233-240.
Polme S, Bahram M, Yamanaka T, et al. 2013. Biogeography of ectomycorrhizal fungi associated with alders(Alnus spp.) in relation to biotic and abiotic variables at the global scale. New Phytologist,198(4):1239-1249.
Roy M, Rochet J, Manzi S, et al. 2013. What determines Alnus-associated ectomycorrhizal community diversity and specificity? A comparison of host and habitat effects at a regional scale. New Phytologist,198(4):1228-1238.
Schimel J P, Gulledge J M, Clein-Curley J S, et al. 1999. Moisture effects on microbial activity and community structure in decomposing birch litter in the Alaskan taiga. Soil Biology& Biochemistry,31(6):831-838.
Shen C, Xiong J, Zhang H, et al. 2013. Soil pH drives the spatial distribution of bacterial communities along elevation on Changbai Mountain. Soil Biology and Biochemistry,57:204-211.
Stursova M, Zifcakova L, Leigh M B, et al. 2012. Cellulose utilization in forest litter and soil:identification of bacterial and fungal decomposers. FEMS Microbiology Ecology,80(3):735-746.
Taylor B R, Parkinson D, Parsons W F J. 1989. Nitrogen and lignin content as predictors of litter decay rates:A microcosm test. Ecology,70(1):97-104.
Tedersoo L, Bahram M, Jairus T, et al. 2011. Spatial structure and the effects of host and soil environments on communities of ectomycorrhizal fungi in wooded savannas and rain forests of Continental Africa and Madagascar. Molecular Ecology, 20(14):3071-3080.
Ward D M, Weller R, Bateson M M. 1990. 16S rRNA sequences reveal numerous uncultured microorganisms in a natural community. Nature,345(6270):63-65.
Yuan Y, Si G, Wang J, et al. 2014. Bacterial community in alpine grasslands along an altitudinal gradient on the Tibetan Plateau. FEMS Microbiology Ecology,87(2014):121-132.
Zeng Q, Dong Y, An S. 2016. Bacterial community responses to soils along a latitudinal and vegetation gradient on the Loess Plateau, China. PLoS ONE,11(4):e152894.
Zhang B, Kong W, Wu N, et al. 2016. Bacterial diversity and community along the succession of biological soil crusts in the Gurbantunggut Desert, Northern China. Journal of Basic Microbiology,56(6):670-679.

[1]	蒋铮, 于倩楠, 乔明锋, 肖娟, 张子良, 尹华军. 云杉幼树根系分泌物对2种草本植物种子萌发和幼苗生长的影响[J]. 林业科学, 2019, 55(6): 160-166.
[2]	韩小红, 卢赐鼎, 华银, 林浩宇, 是雨霏, 吴松青, 张飞萍, 梁光红. 星天牛转录组及三大解毒酶家族相关基因系统发育分析[J]. 林业科学, 2019, 55(5): 104-113.
[3]	于涛, 张宇阳, 高健, 柯蕾, 马文宝, 李俊清. 极小种群濒危植物盐桦叶绿体基因组特征分析[J]. 林业科学, 2019, 55(2): 41-49.
[4]	秦媛, 潘雪玉, 靳微, 陈连庆, 袁志林. 杨树人工林土壤微生物群落4种提取方法比较[J]. 林业科学, 2018, 54(9): 169-176.
[5]	尤号田, 邢艳秋, 彭涛, 丁建华. 机载LiDAR航带旁向重叠对针叶林结构参数估测的影响[J]. 林业科学, 2018, 54(6): 109-118.
[6]	陆梅, 田昆, 孙向阳, 任玉连, 王行, 彭淑娴. 纳帕海典型湿地土壤真菌群落特征的积水条件和干湿季节变化[J]. 林业科学, 2018, 54(2): 98-109.
[7]	丁新景, 敬如岩, 黄雅丽, 陈博杰, 马风云. 基于高通量测序的4种不同树种人工林根际土壤细菌结构及多样性[J]. 林业科学, 2018, 54(1): 81-89.
[8]	郭丽丽, 尹伟伦, 郭大龙, 侯小改. 油用凤丹牡丹不同种植时间根际细菌群落多样性变化[J]. 林业科学, 2017, 53(11): 131-141.
[9]	冯广, 艾训儒, 姚兰, 刘峻城, 黄永涛, 林勇. 鄂西南亚热带常绿落叶阔叶混交林的自然恢复动态及其影响因素[J]. 林业科学, 2016, 52(8): 1-9.
[10]	王振海, 殷秀琴, 张成蒙. 土壤动物在长白山臭冷杉凋落物分解中的作用[J]. 林业科学, 2016, 52(7): 59-67.
[11]	杨承栋. 我国人工林土壤有机质的量和质下降是制约林木生长的关键因子[J]. 林业科学, 2016, 52(12): 1-12.
[12]	李金航, 齐秀慧, 徐程扬, 王畅, 刘海轩, 孙鹏. 黄栌幼苗叶片气体交换对干旱胁迫的短期响应[J]. 林业科学, 2015, 51(1): 29-41.
[13]	胡玉玲, 姚小华, 任华东, 王开良, 林萍. 油茶花发育转录组测序及相关基因表达分析[J]. 林业科学, 2014, 50(9): 36-43.
[14]	张俊艳, 成克武, 臧润国, 丁易. 海南岛热带针-阔叶林交错区群落环境特征[J]. 林业科学, 2014, 50(8): 1-6.
[15]	温强, 徐林初, 江香梅, 李江, 顾胤聪, 徐立安, 黄敏仁. 基于454测序的油茶DNA序列微卫星观察与分析[J]. 林业科学, 2013, 49(8): 43-50.