Xiding Wang, Huimin Li, Ruikai Zhang, Xudong Liu, Fangru Nan, Qi Liu, Junping Lv, Jia Feng, Shulian Xie, Yang Liu
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Environmental parameters, particularly total phosphorus (TP) and dissolved oxygen (DO), were found to significantly influence the distribution and composition of bacterial phyla through redundancy analysis. The pattern of bacterial community assembly has shifted from predominantly deterministic to predominantly stochastic as a result of human activities. The analysis of DOM through EEM-PARAFAC identified three main fluorescent components, reflecting varied sources and interactions with bacterial communities. Upstream, microbial activities predominantly contributed to autochthonous DOM, while downstream, increased inputs of allochthonous DOM from human activities were evident. Furthermore, the study revealed that through the introduction of various organic pollutants and nutrient loads that shift microbial metabolic functions towards increased degradation and transformation of complex organic compounds downstream. 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引用次数: 0
摘要
本研究利用 16S rRNA 基因高通量测序和激发-发射矩阵并行因子分析(EEM-PARAFAC)评估了河流上游(受影响较小)和下游(受影响严重)两段的细菌群落组成和溶解有机物结构,重点研究了细菌多样性与溶解有机物(DOM)特征之间的相互作用。结果表明,细菌群落具有明显的空间多样性,与污染较严重的下游河段相比,上游河段的α-多样性更高。通过冗余分析发现,环境参数,尤其是总磷(TP)和溶解氧(DO),对细菌群落的分布和组成有显著影响。由于人类活动的影响,细菌群落的组合模式已从确定性为主转变为随机性为主。通过 EEM-PARAFAC 分析 DOM,确定了三种主要的荧光成分,反映了不同的来源以及与细菌群落的相互作用。在上游,微生物活动主要产生自生 DOM,而在下游,人类活动明显增加了异源 DOM 的输入。此外,研究还发现,通过引入各种有机污染物和营养负荷,微生物的新陈代谢功能发生了转变,增加了对下游复杂有机化合物的降解和转化。结构方程模型(SEM)显示,上游人类活动主要通过改变 DOM 的特性间接影响细菌群落。相比之下,下游活动由于污染物负荷更高、环境条件更复杂,因此既有直接影响,也有间接影响。这些相互作用凸显了人为因素对河流生态系统的深远影响,并强调了管理人类影响以保护微生物生物多样性和水质的重要性。
Bacterial community and dissolved organic matter networks in urban river: The role of human influence
Human activities have significantly altered the biogeochemical cycles of carbon, nitrogen, and sulfur in aquatic ecosystems, leading to ecological problems.This study utilized 16S rRNA gene high-throughput sequencing and excitation-emission matrix parallel factor analysis (EEM-PARAFAC) to evaluate the bacterial community composition and dissolved organic matter structure in the upstream (less impacted) and downstream (severely impacted) sections of the river, with a focus on the interactions between bacterial diversity and dissolved organic matter (DOM) characteristics.Results indicated significant spatial diversity in bacterial communities, with a higher α-diversity upstream compared to the more polluted downstream sections. Environmental parameters, particularly total phosphorus (TP) and dissolved oxygen (DO), were found to significantly influence the distribution and composition of bacterial phyla through redundancy analysis. The pattern of bacterial community assembly has shifted from predominantly deterministic to predominantly stochastic as a result of human activities. The analysis of DOM through EEM-PARAFAC identified three main fluorescent components, reflecting varied sources and interactions with bacterial communities. Upstream, microbial activities predominantly contributed to autochthonous DOM, while downstream, increased inputs of allochthonous DOM from human activities were evident. Furthermore, the study revealed that through the introduction of various organic pollutants and nutrient loads that shift microbial metabolic functions towards increased degradation and transformation of complex organic compounds downstream. Structural equation modeling (SEM) revealed that upstream human activities primarily affected bacterial communities indirectly by altering DOM properties. In contrast, downstream activities had both direct and indirect effects due to higher pollutant loads and more complex environmental conditions. These interactions underline the profound effect of anthropogenic factors on riverine ecosystems and emphasize the importance of managing human impacts to preserve microbial biodiversity and water quality.
期刊介绍:
The Environmental Research journal presents a broad range of interdisciplinary research, focused on addressing worldwide environmental concerns and featuring innovative findings. Our publication strives to explore relevant anthropogenic issues across various environmental sectors, showcasing practical applications in real-life settings.