# Soil core microbial taxa maintain community resistance to drive soil ecosystem multifunctionality under Alternanthera philoxeroides invasion

**Authors:** Xiao Lin, Xinyu Zhang, Shujing Li, Yongming Wang, Haiyang Yu, Wenxiu Qin, Jiaoyang Zhang

PMC · DOI: 10.3389/fmicb.2025.1707273 · Frontiers in Microbiology · 2025-11-06

## TL;DR

This study shows that core soil bacteria help maintain ecosystem functions when an invasive plant spreads, by stabilizing nutrient cycles and resisting changes.

## Contribution

The study reveals that bacterial community resistance, driven by core taxa, is key to maintaining soil ecosystem multifunctionality during plant invasion.

## Key findings

- Invasion increased soil ecosystem multifunctionality by up to 34.2% in some regions, mainly due to enhanced nitrogen and phosphorus functions.
- Bacterial communities showed higher resistance than fungal communities due to more complex interaction networks.
- Core bacterial taxa were positively linked to microbial resistance and supported nutrient cycling to maintain ecosystem functions.

## Abstract

Alien plant invasion exerts profound impacts on local ecosystems, like biodiversity, stability, and overall functionality. Understanding the ecological stability of soil microbial communities is essential for elucidating how plant invasions drive changes in soil ecosystem functions. In this study, soil ecosystem multifunctionality (EMF) was examined in relation to the resistance of microbial communities across five Alternanthera philoxeroides–invaded sites (Xiaoxian, Hefei, Tongling, Anqing, and Huangshan) within different ecological functional zones in Anhui Province, China, with contrasting soil properties and environmental conditions. Soil samples were collected from invaded and uninvaded plots, microbial core taxa were identified, and structural equation modeling was applied to examine the relationships among invasion, microbial traits, and ecosystem functions. The results showed that invasion significantly increased soil EMF at Xiaoxian by 34.2% and at Hefei by 24.1%, which was primarily by increasing in nitrogen- and phosphorus-related functions. Bacterial communities exhibited consistently higher resistance than fungal communities, owing to their more complex interaction networks. Core bacterial taxa were positively associated with microbial resistance, supporting nutrient cycling and maintaining ultimately EMF. Structural equation modeling revealed that invasion-driven changes in soil properties influenced EMF indirectly through bacterial community resistance mediated by core microbial taxa. These findings demonstrated that bacterial resistance, underpinned by the stabilizing role of core microbial taxa, played a central role in maintaining EMF during plant invasion. The results highlight the importance of core microbial taxa as ecological stabilizers and provide new insights into the belowground mechanisms linking biological invasions to ecosystem resilience.

## Linked entities

- **Species:** Alternanthera philoxeroides (taxon 381410), Mus musculus (taxon 10090)

## Full-text entities

- **Chemicals:** nitrogen (MESH:D009584), phosphorus (MESH:D010758)
- **Species:** Alternanthera philoxeroides (species) [taxon 381410]

## Full text

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## Figures

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## References

63 references — full list in the complete paper: https://tomesphere.com/paper/PMC12633765/full.md

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Source: https://tomesphere.com/paper/PMC12633765