Airborne antibiotic and metal resistance genes - A neglected potential risk at e-waste recycling facilities

Heavy metal-rich environments can promote the selection of metal-resistance genes (MRGs) in bacteria, often leading to the simultaneous selection of antibiotic-resistance genes (ARGs) through a process known as co-selection. To comprehensively evaluate the biological pollutants at electronic-waste (...

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Bibliographic Details
Published in:The Science of the total environment 2024-04, Vol.920, p.170991-170991, Article 170991
Main Authors: Agarwal, V., Meier, B., Schreiner, C., Figi, R., Tao, Y., Wang, J.
Format: Article
Language:English
Subjects:
Aerosols
air
antibiotic resistance
antibiotics
Antimicrobial resistance
electronic wastes
Endotoxins
environment
Heavy metals
metal tolerance
Mobile genetic elements
resistance genes
risk
rivers
soil
species
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Summary:Heavy metal-rich environments can promote the selection of metal-resistance genes (MRGs) in bacteria, often leading to the simultaneous selection of antibiotic-resistance genes (ARGs) through a process known as co-selection. To comprehensively evaluate the biological pollutants at electronic-waste (e-waste) recycling facilities, air, soil, and river samples were collected at four distinct Swiss e-waste recycling facilities and analyzed for ARGs, MRGs, mobile genetic elements (MGEs), endotoxins, and bacterial species, with correlations drawn to heavy metal occurrence. To our knowledge, the present work marks the first attempt to quantify these bio-pollutants in the air of e-waste recycling facilities, that might pose a significant health risk to workers. Although ARG and MRG's profiles varied among the different sample types, intl1 consistently exhibited high relative abundance rates, identifying it as the predominant MGE across all sample types and facilities. These findings underscore its pivol role in driving diverse bacterial adaptations to extreme heavy metal exposure by selection and dissemination of ARGs and MRGs. All air samples exhibited consistent profiles of ARGs and MRGs, with blaTEM emerging as the predominant ARG, alongside pbrT and nccA as the most prevalent MRGs. However, one facility, engaged in batteries recycling and characterized by exceptionally high concentrations of heavy metals, showcased a more diverse resistance gene profile, suggesting that bacteria in this environment required more complex resistance mechanisms to cope with extreme metal exposure. Furthermore, this study unveiled a strong association between gram-negative bacteria and ARGs and less with MRGs. Overall, this research emphasizes the critical importance of studying biological pollutants in the air of e-waste recycling facilities to inform robust safety measures and mitigate the risk of resistance gene dissemination among workers. These findings establish a solid foundation for further investigations into the complex interplay among heavy metal exposure, bacterial adaptation, and resistance patterns in such distinctive ecosystems. [Display omitted] •Intl1 plays a major role in resistance genes acquisition at e-waste facilities.•Co-selection is the driving mechanism of gene acquisition at e-waste facilities.•Different ARGs were found in air, soil and, river samples at e-waste facilities.•Gram-negative bacteria carry more ARGs while gram-positive bacteria carry more MRG
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.170991