Comparison of distinctive diversities, co-occurrence patterns and potential ecological functions of microbial communities in heterogeneous soil areas in typical subtropical forests, southeast China

•Prokaryotic communities were more intensely affected by soil heterogeneity than eukaryotes.•The complexity and stability of microbial networks are regulated by heterogeneous soils.•Soil heterogeneity had the same effect on the symbiosis pattern of microbial functions and taxa.•There are obvious dif...

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Bibliographic Details
Published in:Catena (Giessen) 2024-04, Vol.238, p.107838, Article 107838
Main Authors: Huang, Weihong, Wang, Junqi, Zhou, Yan, Xue, Ximei, Huang, Zhaobin, Wang, Mingkuang, Laanbroek, Hendrikus J., Zhang, Qiufang
Format: Article
Language:English
Subjects:
Co-occurrence network
Eukaryotes
Functional characteristics
Prokaryotes
Soil heterogeneity
Soil properties
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Summary:•Prokaryotic communities were more intensely affected by soil heterogeneity than eukaryotes.•The complexity and stability of microbial networks are regulated by heterogeneous soils.•Soil heterogeneity had the same effect on the symbiosis pattern of microbial functions and taxa.•There are obvious differences in multiple prokaryotic functions but not eukaryotes. Although microbes are crucial in ecological cycling in forest soil, the response of the network structure and ecological functions of these microorganisms to soil heterogeneity remains elusive. Here, we analyzed the composition and co-occurrence network patterns of microorganisms in heterogeneous soil areas and evaluated their potential ecological functions, taking the scenic area (SA) and nature reserve (NR) of Wuyishan National Park as examples. Our results showed that the soil properties of SA and NR could almost be clustered separately, and soil heterogeneity between them has been found. Prokaryotic communities in both areas were also divided and showed higher similarities individually than those of eukaryotes. The prokaryotic community composition in both areas was mainly affected by pH and ammonia, while the eukaryotic community composition was mainly affected by total carbon and the carbon to nitrogen ratio. Both the microbial network and ecological function network in SA were more complex than those of NR, while those of NR were more stable than those of SA. The keystone taxa of pro- and eukaryotes with important ecological functions were enriched in SA and NR, respectively. Moreover, significant discrepancies between SA and NR were found in the prokaryotic functions related to nitrogen cycling, sulfur cycling, and compound degradation. Our study illuminated that the soil heterogeneity in subtropical areas changed microbial community diversity, interaction patterns, and keystone taxa composition, and might further affect their ecological functions.
ISSN:0341-8162
DOI:10.1016/j.catena.2024.107838