峡山水库水体和沉积物中微生物群落结构组成研究

COMPOSITION OF MICROBIAL COMMUNITY STRUCTURE IN WATER AND SEDIMENTS OF XIASHAN RESERVOIR IN SHANDONG PROVINCE

  • 摘要: 为探讨峡山水库水体与沉积物中微生物组成, 以深入理解其生态系统功能, 并为制定有效管理策略提供科学依据, 于2023年5月通过细菌16S rRNA编码基因的高通量测序, 获得了该水库水体和沉积物中的微生物组成特征。结果显示, 沉积物中的微生物Sobs、Chao1、Ace和Shannon指数都显著高于水体中的相应α多样性指数, 说明沉积物中微生物的丰富度和多样性比水体中的更高。β多样性分析也显示水体和沉积物中的微生物组成存在显著差异。峡山水库水体中丰度最高的3个菌门依次为放线菌门(57.65%)、变形菌门(34.9%)和拟杆菌门(6.22%); 属水平丰度最高的4个类群依次是hgcI_clade (29.98%)、Limnohabitans (17.06%)、CL500-29_marine_group (11.97%)和unclassified_f__Sporichthyaceae (7.12%)。沉积物中丰度最高的优势菌门分别是变形菌门(39.63%)、拟杆菌门(12.70%)、Desulfobacterota (9.88%)、绿弯菌门(6.79%)、硝化螺旋菌门(5.56%)和酸杆菌门(Acidobacteriota, 3.52%)等; 属水平上丰度最高的是Steroidobacteraceae (6.98%)、Thermodesulfovibrionia (4.97%)、Thiobacillus (4.33%)、Sutterellaceae (4.07%)和SC-I-84 (3.48%)等中的某些属。峡山水库优势细菌类群的种类与国内有些水库类似, 同时也具有盐碱地区域水库的特征。此外, 黄杆菌属和气单胞菌属等潜在鱼类致病菌在峡山水库中也存在一定的丰度, 这与水库中经常发生相关疾病的事实相吻合。微生物功能预测显示, 峡山水体和沉积物中微生物的功能类似, 在level 3预测的功能无论是水体还是沉积物中最主要的代谢通路为Metabolic pathways、biosynthesis of secondary metabolites、microbial metabolism in diverse environments、biosynthesis of amino acids及carbon metabolism等, 唯有immune diseases这个功能在水体中的丰度明显高于沉积物中。研究结果有利于认识该水库的生态学功能, 也为后续水库生态治理的效果评估提供必要的背景资料。

     

    Abstract: Xiashan Reservoir, the premier reservoir in Shandong Province, serves as a crucial source of drinking water. However, escalating human activities and environmental pressures have posed formidable challenges to its ecological equilibrium. A notable gap in research regarding the microbial composition of its water body and sediments, which hold significant ecological and economic importance, has hindered our comprehension of its ecosystem functions and the development of effective conservation measures. To address this, we conducted a comprehensive analysis of microbial composition in June 2023 using high-throughput sequencing of bacterial 16S rRNA genes. Our findings revealed that the microbial diversity indices, including Sobs, Chao1, Ace, and diversity, were significantly higher in the sediments compared to the water body, underscoring the richer and more diverse microbial communities in the sediments. β-diversity analysis further emphasized distinct microbial compositions between these two environments. In the water body, Actinobacteria (57.65%), Proteobacteria (34.9%), and Bacteroidetes (6.22%) were the dominant bacterial phyla, with the most abundant genera being hgcI_clade (29.98%), Limnohabitans (17.06%), CL500-29_marine_group (11.97%), and Sporichthyaceae (7.12%). Conversely, the sediments were predominantly inhabited by Proteobacteria (39.63%), Bacteroidota (12.70%), Desulfobacterota (9.88%), Chloroflexi (6.79%), Nitrospirota (5.56%), and Acidobacteriota (3.52%), with Steroidobacteraceae (6.98%), Thermodesulfovibrionia (4.97%), Thiobacillus (4.33%), Sutterellaceae (4.07%), and SC-I-84 (3.48%) as the leading genera. Although the dominant bacterial groups in Xiashan Reservoir exhibit similarities to those found in other domestic reservoirs, the presence of potential fish pathogens such as Flavobacterium and Aeromonas underscores the risk of fish diseases. Functional prediction analysis indicated that microbial functions in both water and sediments were largely congruent, with metabolic pathways, biosynthesis of secondary metabolites, microbial metabolism in diverse environments, biosynthesis of amino acids, and carbon metabolism being the most prominent metabolic pathways at level 3 prediction. Notably, immune diseases-related functions were significantly more abundant in the water body compared to the sediments. This study provides valuable insights into the ecological functions of the reservoir and offers essential background information for evaluating the effectiveness of future ecological management efforts.

     

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