Depth-dependent effects of tree species identity on soil microbial community characteristics and multifunctionality

Soil microbes play key roles that support forest ecosystem functioning, while their community characteristics are strongly determined by tree species identity. However, the majority studies primarily focus on soil microorganisms in the topsoil, resulting in limited understanding of the linkages betw...

Full description

Saved in:
Bibliographic Details
Published in:The Science of the total environment 2023-06, Vol.878, p.162972-162972, Article 162972
Main Authors: Xu, Zhiyuan, Hu, Zhenhong, Jiao, Shuo, Bell, Stephen M., Xu, Qian, Ma, Longlong, Chen, Ji
Format: Article
Language:English
Subjects:
Bacteria
Biomarker
Co-occurrence network
Deep soil layers
Ecosystem
Forests
Keystone taxa
Microbial stability
Microbiota
Plantation forest
Sciences of the Universe
Soil - chemistry
Soil Microbiology
Trees
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Soil microbes play key roles that support forest ecosystem functioning, while their community characteristics are strongly determined by tree species identity. However, the majority studies primarily focus on soil microorganisms in the topsoil, resulting in limited understanding of the linkages between tree species identity and the microbial communities that inhabit deep soils. Here we investigated the diversity, structure, function, and co-occurrence networks of soil bacterial and fungal communities, as well as related soil physicochemical properties, to a depth of two meters in dryland forests dominated by either Pinus tabuliformis, a native coniferous species, Robinia pseudoacacia, an exotic broadleaf and nitrogen-fixing species, or both. Tree species identity had stronger effects on soil multifunctionality and microbial community structure in the deep layers (80–200 cm) than in the top layers (0–60 cm). In addition, fungal communities were more responsive to tree species identity, whereas bacteria were more sensitive to soil depth. Tree species identity strongly influenced microbial network stability and complexity, with higher quantities in R. pseudoacacia than the other plantations, by affecting microbial composition and their associations. The increased in microbial network complexity and the relative abundance of keystone taxa enhance the soil multifunctionality of microbial productivity, sugar and chitin degradation, and nutrient availability and cycling. Meanwhile, the relative abundance of keystone taxa was more representative of soil multifunctionality than microbial diversity. Our study highlights that tree species identity significantly influences soil microbial community characteristics and multifunctionality, especially in deep soils, which will help us understand soil nutrients processed in plantation forest ecosystem and provide a reference for tree species selection in ecological restoration. [Display omitted] •Tree identity influences soil microbes and soil nutrient cycles.•Exploring soil microbes to a depth of 2 m in diverse plantations by sequencing.•Tree identity impacts soil microbes and multifunctionality, notably in deep soil.•Tree identity impacts soil multifunctionality through network complexity.•Tree identity’s impact on deep soil should be considered in ecological restoration.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2023.162972