Polyethylene microplastics alter soil microbial community assembly and ecosystem multifunctionality

• Published in: Environment international Vol. 183; p. 108360
• Main Authors: Liu, Ziqiang, Wen, Jiahao, Liu, Zhenxiu, Wei, Hui, Zhang, Jiaen
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier Ltd 01.01.2024; Elsevier
• Subjects: alkaline phosphatase; ammonium nitrogen; carbon; Carbon cycling; community structure; Ecosystem; ecosystems; environment; Glucosidases; microbial communities; Microbial community assembly; Microbiota; Microplastics; nitrogen; nitrogen cycle; Nitrogen cycling; Peptide Hydrolases; phosphorus; Phosphorus cycling; phytomass; Plastics; pollution; Polyethylene; proteinases; Soil - chemistry; Soil Microbiology; soil microorganisms; Soil multifunctionality; soil pH; soil quality; soil water; species; sustainable agriculture; Urease; Microplastics; Microbial community assembly; Nitrogen cycling; Soil multifunctionality; Carbon cycling; Phosphorus cycling
• ISSN: 0160-4120; 1873-6750; 1873-6750
• DOI: 10.1016/j.envint.2023.108360

[Display omitted] •Ecosystem multifunctionality was improved by 1% PE MPs while reduced by 5% PE MPs.•The 5% PE MPs decreased the availability of soil water, carbon and phosphorus.•The activity of carbon-cycling enzymes was promoted by 1% PE MPs.•The activity of nitrogen-cycling enzymes was inhibited by 5% PE MPs.•Dispersal limitation contribution in microbial assembly was reduced by 5% PE MPs. Although pervasive microplastics (MPs) pollution in terrestrial ecosystems invites increasing global concern, impact of MPs on soil microbial community assembly and ecosystem multifunctionality received relatively little attention. Here, we manipulated a mesocosm experiment to investigate how polyethylene MPs (PE MPs; 0, 1%, and 5%, w/w) influence ecosystem functions including plant production, soil quality, microbial community diversity and assembly, enzyme activities in carbon (C), nitrogen (N) and phosphorus (P) cycling, and multifunctionality in the maize–soil continuum. Results showed that PE MPs exerted negligible effect on plant biomass (dry weight). The treatment of 5% PE MPs caused declines in the availability of soil water, C and P, whereas enhanced soil pH and C storage. The activity of C-cycling enzymes (α/β-1, 4-glucosidase and β-D-cellobiohydrolase) was promoted by 1% PE MPs, while that of β-1, 4-glucosidase was inhibited by 5% PE MPs. The 5% PE MPs reduced the activity of N-cycling enzymes (protease and urease), whereas increased that of the P-cycling enzyme (alkaline phosphatase). The 5% PE MPs shifted soil microbial community composition, and increased the number of specialist species, microbial community stability and networks resistance. Moreover, PE MPs altered microbial community assembly, with 5% treatment decreasing dispersal limitation proportion (from 13.66% to 9.96%). Overall, ecosystem multifunctionality was improved by 1% concentration, while reduced by 5% concentration of PE MPs. The activity of α/β-1, 4-glucosidase, urease and protease, and ammonium-N content were the most important predictors of ecosystem multifunctionality. These results underscore that PE MPs can alter soil microbial community assembly and ecosystem multifunctionality, and thus development and implementation of practicable solutions to control soil MPs pollution become increasingly imperative in sustainable agricultural production.