Soil pH determines bacterial distribution and assembly processes in natural mountain forests of eastern China

Soil pH determines bacterial distribution and assembly processes in natural mountain forests of eastern China

Aim There have been numerous studies of forest‐soil microbial biogeography, but an integrated view of edaphic factors, plant, climatic factors, and geographic distance in determining the variation of bacterial community and assembly processes remains unclear at large spatial scales. Here, we analyse...

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Bibliographic Details
Published in:Global ecology and biogeography Vol. 30; no. 11; pp. 2164 - 2177
Main Authors: Ni, Yingying, Yang, Teng, Ma, Yuying, Zhang, Kaoping, Soltis, Pamela S., Soltis, Douglas E., Gilbert, Jack A., Zhao, Yunpeng, Fu, Chengxin, Chu, Haiyan, Waring, Bonnie G.
Format: Journal Article
Language:English
Published: Oxford Wiley Subscription Services, Inc 01-11-2021
Subjects:
Acidic soils
Acidification
Assembly
assembly processes
Bacteria
bacterial distribution
Biogeography
Climate change
Community composition
Composition
Dispersal
forest ecosystems
Forest soils
Forests
Microorganisms
Mountain forests
Mountains
pH effects
Phylogeny
plant phylogeny
Plant species
Soil acidification
soil bacteria
Soil chemistry
Soil microorganisms
Soil pH
Soils
Spatial analysis
Stochasticity
Taxa
Variation
China
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Summary:Aim There have been numerous studies of forest‐soil microbial biogeography, but an integrated view of edaphic factors, plant, climatic factors, and geographic distance in determining the variation of bacterial community and assembly processes remains unclear at large spatial scales. Here, we analysed the factors affecting the biogeographic pattern and assembly processes of soil bacterial communities under 58 tree species in five natural mountain forests. Location Eastern China. Major taxa studied Bacterial communities. Methods Hierarchical partitioning analysis and distance decay models were performed to evaluate the relative contributions of plant phylogeny, environmental, and spatial variables to the composition of bacterial communities. We applied the nearest taxon index (NTI), β‐nearest taxon index (βNTI), and the modified Raup–Crick metric to reveal the mechanisms of bacterial assembly processes. Results We found that plant phylogeny accounted for a significant, but minor, fraction (0.7%) of the variation in composition of bacterial communities. In contrast, soil pH was the primary determinant of bacterial diversity and community composition, independently explaining 68.6 and 69.9% of the variation, respectively. Based on the NTI analysis, bacterial community assembly was more phylogenetically clustered with increasing soil pH. Variable selection was the predominant process explaining bacterial community assembly when differences in soil pH were ≥ 0.83, whereas homogenizing dispersal dominated when differences in soil pH were <0.83. However, there was no significant relationship between plant phylogenetic distance and βNTI. Main conclusions Our findings provide strong evidence that soil pH predominantly determines bacterial distribution and mediates the relative impact of stochasticity and determinism in soil bacterial community assembly. This suggests that climate‐change associated forest soil acidification could have a dramatic impact on soil bacterial diversity, composition, and function.
ISSN:1466-822X
1466-8238
DOI:10.1111/geb.13373