Determining Antimicrobial Resistance in the Plastisphere: Lower Risks of Nonbiodegradable vs Higher Risks of Biodegradable Microplastics

The plastisphere is a potential contributor to global antimicrobial resistance (AMR), posing potential threats to public and environmental health. However, comprehensively quantifying the contribution of microplastics with different biodegradability to AMR is lacking. In this study, we systematically quantified AMR risk mediated by biodegradable and nonbiodegradable microplastics using abundance-based methods and a custom AMR risk ranking framework that includes antimicrobial resistance genes (ARGs) abundance, mobility, and host pathogenicity. Our results demonstrated that biodegradable microplastics exhibited higher AMR risk compared to that of nonbiodegradable plastics. Key resistance genes, including those for multidrug, bacitracin, and aminoglycoside resistance, were predominant. Machine learning analysis identified cell motility as the most significant signature associated with AMR risk, highlighting its potential role in promoting ARGs dissemination. In addition, biodegradable microplastics promoted oxidative stress and SOS responses, which likely enhanced horizontal gene transfer (HGT) and AMR. Metagenome-assembled genomes (MAGs) analysis uncovered the colocalization of microplastic degradation genes, ARGs, and virulence factors (VFs), further supporting the elevated risk in biodegradable plastisphere. The proximity of ARGs to mobile genetic elements (MGEs) suggests that microplastic degradation processes might favor ARGs mobility. These findings would contribute critical insights into AMR dissemination in the plastisphere, emphasizing the need for integrated environmental and public health strategies under the context of One Health.