Aged microplastics enhance their interaction with ciprofloxacin and joint toxicity on Escherichia coli

Microplastics (MPs) in natural environments undergo complex aging processes, changing their interactions with coexisting antibiotics, and posing unpredictable ecological risks. However, the joint toxicity of aged MPs (aMPs) and antibiotics to bacteria, especially at the molecular level, is unclear....

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Bibliographic Details
Published in:Ecotoxicology and environmental safety 2022-12, Vol.247, p.114218-114218, Article 114218
Main Authors: Feng, Li-Juan, Zhang, Kai-Xin, Shi, Zong-Lin, Zhu, Fan-Ping, Yuan, Xian-Zheng, Zong, Wan-Song, Song, Chao
Format: Article
Language:English
Subjects:
Aged microplastic
Ciprofloxacin
Joint toxicity, flagellar assembly
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Summary:Microplastics (MPs) in natural environments undergo complex aging processes, changing their interactions with coexisting antibiotics, and posing unpredictable ecological risks. However, the joint toxicity of aged MPs (aMPs) and antibiotics to bacteria, especially at the molecular level, is unclear. In this study, non-thermal plasma technology was used to simultaneously simulate various radical oxidation and physical reactions that occur naturally in the environment, breaking the limitation of simple aging process in laboratory aging technologies. After aging, we investigated the altered properties of aMPs, their interactions with ciprofloxacin (CIP), and the molecular responses of E. coli exposed to pristine MPs (13.5 mg/L), aMPs (13.5 mg/L), and CIP (2 μg/L) individually or simultaneously. aMPs bound far more CIP to their surfaces than pristine MPs, especially in freshwater ecosystems. Notably, the growth of E. coli exposed to aMPs alone was inhibited, whereas pristine MPs exposure didn’t affect the growth of E. coli. Moreover, the most differentially expressed genes in E. coli were induced by the coexposure of aMPs and CIP. Although E. coli depended on chemotaxis to improve its flagellar rotation and escaped the stress of pollutants, the coexposure of aMPs and CIP still caused cell membrane damage, oxidative stress, obstruction of DNA replication, and osmotic imbalance in E. coli. This study filled the knowledge gap between the toxicity of aMPs and pristine MPs coexisting with antibiotics at the transcription level, helping in the accurate assessment of the potential risks of MPs to the environment. [Display omitted] ●Aging of MPs was simulated by nonthermal plasma, including various aging processes.●Aging process significantly improved adsorption rate and capacity of MPs for CIP.●Enhanced adsorption of aMPs induced more differentially expressed genes in E. coli.●E. coli depended on chemotaxis to improve flagellar assembly and escaped stress.●ABC transporters, amino acid and TCA cycle pathways was downregulated.
ISSN:0147-6513
1090-2414
DOI:10.1016/j.ecoenv.2022.114218