亚高山粗枝云杉人工林土壤原核微生物群落结构与功能变化

doi:10.13287/j.1001-9332.202312.031

应用生态学报 ›› 2023, Vol. 34 ›› Issue (12): 3279-3290.doi: 10.13287/j.1001-9332.202312.031

亚高山粗枝云杉人工林土壤原核微生物群落结构与功能变化

刘艳娇^1,2, 刘庆¹, 贺合亮³, 赵文强¹, 寇涌苹^1*

¹中国科学院成都生物研究所/中国科学院山地生态恢复与生物资源利用重点实验室/生态恢复与生物多样性保育四川省重点实验室, 成都 610041;
²福建农林大学资源与环境学院, 福州 350002;
³宜宾学院, 四川宜宾 644007

收稿日期:2023-05-30 修回日期:2023-10-02 出版日期:2023-12-15 发布日期:2024-06-15
通讯作者: *E-mail: kouyp@cib.ac.cn
作者简介:刘艳娇, 女, 1994年生, 博士研究生。主要从事土壤微生物生态研究。E-mail:15933237160@163.com
基金资助:
国家自然科学基金面上项目(32171550)和中国科学院青年创新促进会项目(2021371)

Changes in the structure and function of soil prokaryotic communities in subalpine Picea asperata plantations

LIU Yanjiao^1,2, LIU Qing¹, HE Heliang³, ZHAO Wenqiang¹, KOU Yongping^1*

¹Chengdu Institute of Biology, Chinese Academy of Sciences/CAS Key Laboratory of Mountain Ecological Restoration and Bioresource Utilization/Ecological Restoration and Biodiversity Conservation Key Laboratory of Sichuan Province, Chengdu 610041, China;
²College of Resources and Environment, Fujian Agriculture and Forestry University, Fuzhou 350002, China;
³Yibin University, Yibin 644007, Sichuan, China

Received:2023-05-30 Revised:2023-10-02 Online:2023-12-15 Published:2024-06-15

摘要/Abstract

摘要： 土壤原核微生物群落结构和功能特性对维持生态系统功能至关重要。本研究以不同林龄粗枝云杉为研究对象,结合高通量测序技术和生物信息学方法,研究粗枝云杉根际和非根际土壤原核微生物群落多样性和群落组成变化特征及其关键影响因素,并分析原核微生物群落功能特征的变化。结果表明: 土壤原核微生物群落的β多样性在根际与非根际均表现为不同林龄之间差异显著,而同一林龄的根际与非根际间无显著差异。从群落组成来看,门水平上,变形菌门和己科河菌门的相对丰度随人工林林龄增加而升高,而放线菌门随林龄增加而降低,且75年人工林(PF75)与天然林(NF)之间无显著差异。厚壁菌门和奇古菌门的相对丰度在25年云杉林(PF25)土壤中显著高于其他人工林和NF。属水平上,RB41、Terrimonas和酸杆菌属的相对丰度随人工林林龄增加而升高,且根际土壤中的RB41和Terrimonas在PF75显著高于NF。土壤理化性质和植被特性共同影响了原核微生物的群落结构,其中,草本覆盖度、土壤pH、总磷和总氮是主要影响因素。原核微生物群落的功能特性在不同林龄之间具有显著差异。与碳氮循环相关的部分功能(如纤维素降解和硝化作用)的相对丰度随人工林林龄增加而降低,而与硫循环相关的硫酸盐呼吸功能的相对丰度则升高。建议将土壤原核微生物群落的结构和功能特征作为云杉林发育阶段的重要指示。在人工林发育后期可通过调控解磷增氮的微生物以提高土壤养分有效性来维持人工林生态系统稳定。

关键词: 亚高山森林, 人工林, 粗枝云杉, 土壤原核微生物, 高通量测序, 功能预测

Abstract: The structural and functional characteristics of soil prokaryotic community are important for maintaining ecosystem functions. In this study, we examined the diversity and compositions, the key drivers, as well as functional characteristics of prokaryotic communities in the rhizosphere and non-rhizosphere soils of Picea asperata with different stand ages using high-throughput sequencing technique and bioinformatics methods. The results showed that β-diversity of soil prokaryotic communities in both rhizosphere and non-rhizosphere showed significant differences among different stand ages, but no significant difference between rhizosphere and non-rhizosphere in the same stand age. In terms of community composition at the phylum level, the relative abundances of Proteobacteria and Rokubacteria showed an increasing trend with the increases of stand age, while the relative abundance of Actinobacteria showed a decreasing trend, but no significant difference was observed between 75 year-old planted forests (PF75) and natural forests (NF). The relative abundances of Firmicutes and Thaumarchaeota in the soil of the 25 year-old planted forests (PF25) were significantly higher than in other planted forests and NF. At the genus level, the relative abundances of RB41, Terrimonas and Acidibacter showed an increasing trend with the increases of stand age, and RB41 and Terrimonas in rhizosphere soil of PF75 were significantly higher than those in NF. Soil properties and vegetation characteristics jointly influenced the structure of soil prokaryotic communities, with herb layer coverage, soil pH, total phosphorus, and total nitrogen as major drivers. The functional characteristics of soil prokaryotic communities were significantly different among different stand ages. The relative abundances of functions involved in carbon and nitrogen cycle, e.g., cellulolysis and nitrification, decreased with the increases of stand age, whereas that of sulfate respiration involved in the sulfur cycle increased. We proposed that the structure and functional characteristics of soil prokaryotic communities could serve as important indicators of the development stages of P. asperata forests. In the later stages of plantation forest development, soil nutrient availability could be improved by mediating phosphorus-dissolving and nitrogen-enhancing microorganisms to maintain the stability of the plantation ecosystem.

Key words: subalpine forest, planted forest, Picea asperata, soil prokaryotic microbiome, high-throughput sequencing, function prediction

刘艳娇, 刘庆, 贺合亮, 赵文强, 寇涌苹. 亚高山粗枝云杉人工林土壤原核微生物群落结构与功能变化[J]. 应用生态学报, 2023, 34(12): 3279-3290.

LIU Yanjiao, LIU Qing, HE Heliang, ZHAO Wenqiang, KOU Yongping. Changes in the structure and function of soil prokaryotic communities in subalpine Picea asperata plantations[J]. Chinese Journal of Applied Ecology, 2023, 34(12): 3279-3290.

参考文献

[1] 尹华军, 刘庆. 川西米亚罗亚高山云杉林种子雨和土壤种子库研究. 植物生态学报, 2005, 29(1): 108-115
[2] 张远东, 刘彦春, 顾峰雪, 等. 川西亚高山五种主要森林类型凋落物组成及动态. 生态学报, 2019, 39(2): 502-508
[3] 庞学勇, 刘世全, 刘庆, 等. 川西亚高山人工云杉林地有机物和养分库的退化与调控. 土壤学报, 2004, 41(1): 126-133
[4] Zhang YD, Gu FX, Liu SR, et al. Variations of carbon stock with forest types in subalpine region of southwestern China. Forest Ecology and Management, 2013, 300: 88-95
[5] 祁凯斌, 黄俊胜, 杨婷惠, 等. 亚高山森林自然与人工恢复对土壤涵水能力的影响. 生态学报, 2018, 38(22): 8118-8128
[6] Liu T, Wu XH, Li HW, et al. Soil organic matter, nitrogen and pH driven change in bacterial community following forest conversion. Forest Ecology and Management, 2020, 477: 118473
[7] Banning NC, Gleeson DB, Grigg AH, et al. Soil microbial community successional patterns during forest ecosystem restoration. Applied and Environmental Microbio-logy, 2011, 77: 6158-6164
[8] Dossa GGO, Yang YQ, Hu W, et al. Fungal succession in decomposing woody debris across a tropical forest disturbance gradient. Soil Biology and Biochemistry, 2021, 155: 108142
[9] Falkowski PG, Fenchel T, Delong EF. The microbial engines that drive earth’s biogeochemical cycles. Science, 2008, 320: 1034-1039
[10] 许从峰, 艾士奇, 申贵男, 等. 木质纤维素的微生物降解. 生物工程学报, 2019, 35(11): 2081-2091
[11] de Vries FT, Griffiths RI, Bailey M, et al. Soil bacterial networks are less stable under drought than fungal networks. Nature Communications, 2018, 9: 3033
[12] 曹升, 潘菲, 林根根, 等. 不同林龄杉木林土壤细菌群落结构与土壤酶活性变化研究. 生态学报, 2021, 41(5): 1846-1856
[13] Wan P, Peng H, Ji XL, et al. Effect of stand age on soil microbial communities of a plantation Ormosia hosiei forest in southern China. Ecological Informatics, 2021, 62: 101282
[14] Qu ZL, Liu B, Ma Y, et al. Differences in bacterial community structure and potential functions among Eucalyptus plantations with different ages and species of trees. Applied Soil Ecology, 2020, 149: 103515
[15] Wang CQ, Xue L, Dong YH, et al. Contrasting effects of Chinese fir plantations of different stand ages on soil enzyme activities and microbial communities. Forests, 2018, 10: 10.3390/f10010011
[16] Jiang S, Xing Y, Liu GC, et al. Changes in soil bacterial and fungal community composition and functional groups during the succession of boreal forests. Soil Biology and Biochemistry, 2021, 161: 108393
[17] Qiang W, He LL, Zhang Y, et al. Aboveground vegetation and soil physicochemical properties jointly drive the shift of soil microbial community during subalpine secondary succession in southwest China. Catena, 2021, 202: 105251
[18] Zhang XY, Zhao WQ, Kou YP, et al. Secondary forest succession drives differential responses of bacterial communities and interactions rather than bacterial functional groups in the rhizosphere and bulk soils in a subalpine region. Plant and Soil, 2022, 484: 293-312
[19] Fang K, Liu YJ, Zhao WQ, et al. Stand age alters fungal community composition and functional guilds in subalpine Picea asperata plantations. Applied Soil Ecology, 2023, 188: 104860
[20] 郭辉, 唐卫平. 不同林龄华北落叶松根际与非根际土壤酶和土壤微生物研究. 生态环境学报, 2020, 29(11): 2163-2170
[21] Tkacz A, Cheema J, Chandra G, et al. Stability and succession of the rhizosphere microbiota depends upon plant type and soil composition. The ISME Journal, 2015, 9: 2349-2359
[22] Zheng YY, Feng ZH, Wang JL, et al. Wheat-root associated prokaryotic community: Interplay between plant selection and location. Plant and Soil, 2021, 464: 183-197
[23] 陈悦, 吕光辉, 李岩. 独山子区优势草本植物根际与非根际土壤微生物功能多样性. 生态学报, 2018, 38(9): 3110-3117
[24] 汪其同, 朱婉芮, 刘梦玲, 等. 基于高通量测序的杨树人工林根际和非根际细菌群落结构比较. 应用与环境生物学报, 2015, 21(5): 967-973
[25] 汪其同, 高明宇, 刘梦玲, 等. 基于高通量测序的杨树人工林根际土壤真菌群落结构. 应用生态学报, 2017, 28(4): 1177-1183
[26] 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
[27] 刘艳娇, 樊丹丹, 李香真, 等. 人工与天然云杉林土壤真菌群落多样性及菌群网络关系特征. 应用生态学报, 2021, 32(4): 1441-1451
[28] Tamaki H, Wright CL, Li XZ, et al. Analysis of 16S rRNA amplicon sequencing options on the roche/454 next-generation titanium sequencing platform. PLoS One, 2011, 6: e25263
[29] Jiao S, Chen WM, Wang JL, et al. Soil microbiomes with distinct assemblies through vertical soil profiles drive the cycling of multiple nutrients in reforested ecosystems. Microbiome, 2018, 6: 146
[30] Zhang BG, Zhang J, Liu Y, et al. Biogeography and ecological processes affecting root-associated bacterial communities in soybean fields across China. Science of the Total Environment, 2018, 627: 20-27
[31] Louca S, Parfrey LW, Doebeli M. Decoupling function and taxonomy in the global ocean microbiome. Science, 2016, 353: 1272-1277
[32] 张晓, 刘世荣, 黄永涛, 等. 辽东栎林演替过程中的土壤细菌群落结构和多样性变化. 林业科学, 2019, 55(10): 193-202
[33] Rousk J, Bååth E, Brookes PC, et al. Soil bacterial and fungal communities across a pH gradient in an arable soil. The ISME Journal, 2010, 4: 1340-1351
[34] Nacke H, Thurmer A, Wollherr A, et al. Pyrosequencing-based assessment of bacterial community structure along different management types in german forest and grassland soils. PLoS One, 2011, 6: e17000
[35] Sun S, Li S, Avera BN, et al. Soil bacterial and fungal communities show distinct recovery patterns during forest ecosystem restoration. Applied and Environmental Microbiology, 2017, 83: e00966-17
[36] Shivlata L, Satyanarayana T. Actinobacteria in agricultural and environmental sustainability// Singh JS, Seneviratne G, eds. Agro-Environmental Sustainability. Cham, Germany: Springer International Publishing, 2017: 173-218
[37] Butterfield CN, Li Z, Andeer PF, et al. Proteogenomic analyses indicate bacterial methylotrophy and archaeal heterotrophy are prevalent below the grass root zone. PeerJ, 2016, 4: e2687
[38] Ou YN, Penton CR, Geisen S, et al. Deciphering underlying drivers of disease suppressiveness against pathogenic fusarium oxysporum. Frontiers in Microbiology, 2019, 10: 2535
[39] Fierer N, Bradford MA, Jackson RB. Toward an ecolo-gical classification of soil bacteria. Ecology, 2007, 88: 1354-1364
[40] Kalam S, Basu A, Ahmad I, et al. Recent understanding of soil Acidobacteria and their ecological significance: A critical review. Frontiers in Microbiology, 2020, 11: 580024
[41] Stone BW, Li JH, Koch BJ, et al. Nutrients cause consolidation of soil carbon flux to small proportion of bacterial community. Nature Communications, 2021, 12: 3381
[42] Tan XL, Kan L, Su ZY, et al. The composition and diversity of soil bacterial and fungal communities along an urban-to-rural gradient in south China. Forests, 2019, 10: 797
[43] 林波, 刘庆, 吴彦, 等. 川西亚高山针叶林凋落物对土壤理化性质的影响. 应用与环境生物学报, 2003, 9(4): 346-351
[44] Mooshammer M, Wanek W, Hämmerle I, et al. Adjustment of microbial nitrogen use efficiency to carbon:nitrogen imbalances regulates soil nitrogen cycling. Nature Communications, 2014, 5: 3694
[45] Qu ZL, Liu B, Ma Y, et al. The response of the soil bacterial community and function to forest succession caused by forest disease. Functional Ecology, 2020, 34: 2548-2559
[46] 陈立新, 段文标, 乔璐. 落叶松人工林根际与非根际土壤养分特征及酸度研究. 水土保持学报, 2011, 25(3): 131-135
[47] Shen CC, Xiong JB, Zhang HY, et al. Soil pH drives the spatial distribution of bacterial communities along elevation on Changbai Mountain. Soil Biology and Biochemistry, 2013, 57: 204-211
[48] Fierer N, Jackson RB. The diversity and biogeography of soil bacterial communities. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103: 626-631
[49] 白爱芹, 傅伯杰, 曲来叶, 等. 重度火烧迹地微地形对土壤微生物特性的影响——以坡度和坡向为例. 生态学报, 2013, 33(17): 5201-5209
[50] 张丽梅, 沈菊培, 贺纪正. 奇妙的古菌——奇古菌(Thaumarchaeota)的代谢和功能多样性. 科学观察, 2015, 10(6): 63-66
[51] 张丽梅, 贺纪正. 一个新的古菌类群——奇古菌门(Thaumarchaeota). 微生物学报, 2012, 52(4): 411-421
[52] 杨赛, 朱琳, 魏巍. 土壤生态系统硝化微生物研究进展. 中国土壤与肥料, 2018, 6(6): 1-10
[53] Tucker MP, Mohagheghi A, Grohmann K, et al. Ultra-thermostable cellulases from acidothermus cellulolyticus: Comparison of temperature optima with previously reported cellulases. Nature Biotechnology, 1989, 7: 817-820
[54] Lewin GR, Carlos C, Chevrette MG, et al. Evolution and ecology of Actinobacteria and their bioenergy applications. Annual Review of Microbiology, 2016, 70: 235-254
[55] Rabus R, Hansen TA, Widdel F. Dissimilatory sulfate- and sulfur-reducing Prokaryotes// Rosenberg E, DeLong EF, Lory S, eds. The Prokaryotes: Prokaryotic Physiology and Biochemistry. Berlin: Springer, 2013: 309-404
[56] 庞学勇, 刘庆, 刘世全, 等. 人为干扰对川西亚高山针叶林土壤物理性质的影响. 应用与环境生物学报, 2002, 8(6): 583-587
[57] 包维楷, 张镱锂, 王乾, 等. 青藏高原东部采伐迹地早期人工重建序列梯度上植物多样性的变化. 植物生态学报, 2002, 26(3): 330-338

亚高山粗枝云杉人工林土壤原核微生物群落结构与功能变化

Changes in the structure and function of soil prokaryotic communities in subalpine Picea asperata plantations

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