Cadmium contamination decreased bacterial network complexity and stability in coastal reclamation areas
Cadmium(Cd) contamination can exert significantly adverse effects on soil microbiota in reclaimed areas, however, its effects on bacterial network structure are still limitedly understood. Here we collected soil samples from typical reclaimed wetlands (RW) and ditch wetlands (DW) in coastal reclamat...
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Veröffentlicht in: | Journal of hazardous materials 2024-09, Vol.476, p.134896, Article 134896 |
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Sprache: | eng |
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Zusammenfassung: | Cadmium(Cd) contamination can exert significantly adverse effects on soil microbiota in reclaimed areas, however, its effects on bacterial network structure are still limitedly understood. Here we collected soil samples from typical reclaimed wetlands (RW) and ditch wetlands (DW) in coastal reclamation areas and examined the effects of Cd contamination on the bacterial network complexity and stability. The results showed that the bacterial networks were destabilized by the Cd contamination, while bacteria in DW soils showed robust invulnerability characterized by higher node constancy and compositional stability compared with RW soils. Soil bacteria resisted Cd stress by forming a network with intensive connections in the module but sparser connections among the modules. Especially, network modularity was higher in DW soils than in RW soils, but made it more vulnerable to nodes removal. In addition, Cd contamination promoted bacterial positive cohesion but decreased negative cohesion in RW soils. Flavobacteriaceae, Xanthomonadaceae, and Alcaligenaceae were identified as core phylotypes, which played pivotal roles in regulating interspecies interactions due to higher contributions to cohesion and significant correlations with soil nutrients. The findings of this work indicate the changes of bacterial network structure and the indispensable role of core phylotypes in regulating interactions and maintaining network sustainability under Cd contamination.
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•Cd contamination reduced complexity and stability of bacterial networks.•Cd stress enhanced bacterial connections within module while a decline among modules.•Core phylotypes maintained species interaction within bacterial network.•Soil nutrients had significant correlations with core phylotypes. |
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ISSN: | 0304-3894 1873-3336 1873-3336 |
DOI: | 10.1016/j.jhazmat.2024.134896 |