UV-aging of microplastics increases proximal ARG donor-recipient adsorption and leaching of chemicals that synergistically enhance antibiotic resistance propagation

Despite growing attention to environmental pollution by microplastics (MP), the effects of MP aging on bacterial horizontal gene transfer (HGT) have not been systematically investigated. Here, we used UV-aged polystyrene microplastics (PS-MPs) to investigate how aging affects antibiotic resistance genes (ARGs) transfer efficiency from various ARG vectors to recipient bacteria. The adsorption capacity of MP20 (20-day UV-aged PS-MPs) towards E. coli (harboring plasmid-borne bla(TEM-1)), plasmid pET29 (harboring bla(NDM-1)) and phage lambda (cartying the aphA1 ARG) increased by 6.6-, 5.2- and 8.3-fold, respectively, relative to pristine PS-MPs (MP0), due to increased specific surface area and affinity for these ARG vectors. Moreover, MP20 released more organic compounds (TOC 1.6 mg/g-MP20, versus 0.2 mg/g-MP0 in 4 h) -possibly depolymerization byproducts (verified by GC-MS), which induced intracellular ROS generation, increased cell permeability and upregulated HGT associated genes. Accordingly, MP20 enhanced ARG transfer frequency from E. coli, plasmid pET29 and phage lambda (relative to MP0) by 1.3-, 4.7- and 3.5-fold, respectively. The Bliss independence model infers that higher bacterial adsorption and exposure to chemicals released during MP aging synergistically enhanced ARG transfer. This underscores the need to assess the significance of this overlooked phenomenon to the environmental dissemination of antibiotic resistance and other HGT processes.

Automated summary

This study systematically investigated the effects of microplastic aging on bacterial horizontal gene transfer. The results showed that aging increased the efficiency of antibiotic resistance gene transfer from microplastics to recipient bacteria, possibly due to increased specific surface area and affinity for the gene vectors. Additionally, aged microplastics released more organic compounds, induced ROS generation, increased cell permeability, and upregulated genes associated with gene transfer. The findings highlight the significance of microplastic aging in the environmental dissemination of antibiotic resistance and other gene transfer processes.