内蒙古草原的土壤细菌群落结构研究

doi:10.12160/j.issn.1672-5190.2025.02.001

摘要/Abstract

摘要： [目的]明确内蒙古草原土壤细菌群落结构特征及其关键环境驱动因子,为保护草原生态系统提供微生物学依据。[方法]沿内蒙古草原自西向东梯度（荒漠草原-草甸草原-天然草滩-人工草地）,选取巴彦淖尔市乌拉特草原（BM）、包头市乌拉特草原（BT）、乌兰察布市格根塔拉草原（WH）、乌兰察布市辉腾锡勒草原（HT）、乌兰察布市乌兰察布草原（WL）、呼伦贝尔市呼伦贝尔草原（HM）、通辽市科尔沁草原（TL）、赤峰市阿鲁科尔沁旗牧草种植核心区（CF）8个典型样点,采集0~20 cm土层土壤,测定土壤理化指标,通过高通量测序技术解析细菌群落组成,结合基于距离的冗余分析（dbRDA）和FAPROTAX功能预测,探究不同草原土壤细菌群落结构、功能特征及其与环境因子的关系。[结果]①内蒙古草原土壤均呈碱性（pH值为7.65~10.13）。②变形菌门（Proteobacteria）、拟杆菌门（Bacteroidota）和厚壁菌门（Firmicutes）为相对丰度排名前三的优势菌门,拟杆菌属（Bacteroides）、红杆菌属（Rubrobacter）和芽孢杆菌属（Bacillus）为相对丰度排名前三的优势菌属。③dbRDA结果表明,土壤有效磷、有机质、有效钾、pH值、容重、全氮和水溶性盐总量是引起细菌群落特征差异的驱动因子（累计解释率79.20%）。④乌兰察布草原（WL）的Shannon指数（10.41）和Chao1指数（6 184.13）高于其他样点,富集放线菌门和变形菌门,且捕食性或外寄生性功能活性较高;乌拉特草原（BM）与乌兰察布草原（WL）群落组成相似性高（ANOVA检验,P>0.05）。⑤FAPROTAX功能预测显示,呼伦贝尔草原（HM）化能异养功能显著,科尔沁草原（TL）好氧化能异养功能活性最强,阿鲁科尔沁旗牧草种植核心区（CF）氮循环相关功能活性强,格根塔拉草原（WH）好氧氨氧化与硝化作用活性最高。[结论]内蒙古草原土壤细菌群落结构及功能具有明显的空间异质性,乌兰察布草原（WL）的微生物多样性最高且功能具有复杂性。有效磷、有机质、有效钾、pH值、容重、全氮和水溶性盐总量等土壤理化因子是调控细菌群落构建的关键因素。研究结果为解析内蒙古草原的土壤细菌生态机制及可持续管理提供了数据支撑。

关键词: 内蒙古草原, 微生物多样性, 细菌群落结构, 环境驱动因子, 功能预测

Abstract: [Objective] To investigate the characteristics of soil bacterial community structures in Inner Mongolia grasslands and identify key environmental drivers, providing a microbiological basis for grassland ecosystem conservation. [Methods] Along a west-to-east gradient of Inner Mongolia grasslands （desert steppe, meadow steppe, natural meadow, and artificial grassland）, eight representative sampling sites were selected: Urad Grassland in Bayannur City （BM）, Urad Grassland in Baotou City （BT）, Gegentala Grassland in Ulanqab City （WH）, Huitengxile Grassland in Ulanqab City （HT）, Ulanqab Grassland in Ulanqab City （WL）, Hulun Buir Grassland in Hulun Buir City （HM）, Horqin Grassland in Tongliao City （TL）, and the core forage planting area in Ar Horqin Banner, Chifeng City （CF）. Soil samples from these eight sites were collected from the 0-20 cm soil layer. Soil physicochemical properties were measured and soil bacterial community compositions were characterized using high-throughput sequencing. Distance based redundancy analysis （dbRDA） and FAPROTAX functional prediction were employed to examine the structure, functional characteristics, and relationships with environmental factors of soil bacterial communities across different grasslands. [Results] ①Soils in Inner Mongolia grasslands were generally alkaline （pH 7.65-10.13）; ②Proteobacteria, Bacteroidota, and Firmicutes were the three most abundant bacterial phyla, while Bacteroides, Rubrobacter, and Bacillus were the top three most abundant genera; ③dbRDA revealed that available phosphorus, organic matter, available potassium, pH, bulk density, total nitrogen, and total water-soluble salts were drivers of differences in bacterial community characteristics （cumulative explanation power：79.20%）; ④Ulanqab Grassland （WL） exhibited highest Shannon （10.41） and Chao1 （6 184.13） indices compared to other sites, with enrichment of Actinobacteria and Proteobacteria and higher predatory or ectoparasitic functional activity. The bacterial community composition of Urad Grassland （BM） was highly similar to that of WL （ANOVA, P>0.05）; ⑤ FAPROTAX functional predictions indicated significant chemoheterotrophic activity in Hulun Buir Grassland （HM）, the strongest aerobic chemoheterotrophic activity in Horqin Grassland （TL）, robust nitrogen cycling activity in the core forage planting area in Ar Horqin Banner （CF）, and the highest aerobic ammonia oxidation and nitrification activity in Gegentala Grassland （WH）. [Conclusion] The soil bacterial community structure and functions in Inner Mongolia grasslands exhibit significant spatial heterogeneity, with Ulanqab Grassland （WL） displaying the highest microbial diversity and functional complexity. Soil physicochemical factors, including available phosphorus, organic matter, available potassium, pH, bulk density, total nitrogen, and total water-soluble salts, are crucial in shaping bacterial community structure. These findings provide valuable data for understanding the ecological mechanisms of soil bacteria and supporting sustainable management of Inner Mongolia grasslands.

Key words: Inner Mongolia grasslands, microbial diversity, bacterial community structure, environmental driving factors, functional prediction

中图分类号:

S812.2

董琦, 孙峰成, 栗艳芳, 李秀萍, 李宝贺, 任超, 尹鑫, 狄彩霞. 内蒙古草原的土壤细菌群落结构研究[J]. 畜牧与饲料科学, 2025, 46(2): 1-10.

DONG Qi, SUN Fengcheng, LI Yanfang, LI Xiuping, LI Baohe, REN Chao, YIN Xin, DI Caixia. Study on the Soil Bacterial Community Structure of Inner Mongolia Grasslands[J]. Animal Husbandry and Feed Science, 2025, 46(2): 1-10.

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