Habitats modulate influencing factors shaping the spatial distribution of bacterial communities along a Tibetan Plateau riverine wetland

The Tibetan Plateau riverine wetland is very sensitive to global climate change. Understanding the mechanisms that maintain the spatial patterns of bacterial communities provides insight into the dominant biogeochemical processes within the plateau riverine wetlands. Nonetheless, the spatial distrib...

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Bibliographic Details
Published in:The Science of the total environment 2023-02, Vol.860, p.160418, Article 160418
Main Authors: Zhang, Hongjie, Xu, Huimin, Wang, Shuren, Qin, Mengyu, Zhao, Dayong, Wu, Qinglong L., Zeng, Jin
Format: Article
Language:English
Subjects:
Bacteria
Bacterial community diversity
Co-occurrence network
Distance-decay relationship
Ecosystem
Habitat
Plateau riverine wetland
Soil - chemistry
Soil Microbiology
Tibet
Tibetan Plateau
Wetlands
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Summary:The Tibetan Plateau riverine wetland is very sensitive to global climate change. Understanding the mechanisms that maintain the spatial patterns of bacterial communities provides insight into the dominant biogeochemical processes within the plateau riverine wetlands. Nonetheless, the spatial distribution of bacterial communities along these wetlands has rarely been explored. We investigated the spatial patterns of bacterial community within rhizosphere soil, bulk soil, and sediment samples collected along the Yarlung Tsangpo riverine wetland (YTRW), the longest plateau riverine wetland in China. Our results indicated that the diversity of bacterial communities in all three habitats increased significantly along the YTRW. The slope of the linear relationship between distance and bacterial community diversity in sediment was steeper than those for bulk and rhizosphere soils. Furthermore, bacterial communities in all three habitats showed significant distance–decay relationships. A combination of historical factors (geographical distance and climatic factors) and contemporary environmental heterogeneity (edaphic properties) controlled spatial distributions of bacterial communities in all three habitats, although climatic factors were predominant. Climatic factors affected rhizosphere bacterial communities more than those in bulk soil and sediment. Co-occurrence network analysis revealed that the potential interactions between bacterial taxa may decrease along the YTRW. This field investigation highlighted that the climatic factors strongly influenced the spatial distribution of bacterial communities along the YTRW; however, habitat differences among rhizosphere soil, bulk soil, and sediment samples affected the relative importance of climatic factors on spatial distributions of the associated bacterial communities. These findings would improve the understanding of biogeochemical processes in these typical habitats and potential alterations provoked by climate change. [Display omitted] •Climatic factors were dominant factors in spatial patterns of bacterial community.•Climatic factors had greater effects on the rhizosphere bacterial community.•The complexity of bacterial community co-occurrence networks reduced along the YTRW.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2022.160418