Discovery of novel antimicrobial resistance genes in food and fertiliser using a high-throughput gene capture and functional screening platform

Integrons are genetic elements that drive bacterial adaptation by capturing and expressing mobile gene cassettes. They play a key role in dissemination of antimicrobial resistance (AMR) genes, particularly in Gram-negative bacteria. In addition to known AMR determinants, integron gene cassettes carry a vast reservoir of novel genes whose functions are largely uncharacterised, making it diNicult to assess their full contribution to the resistome. Contributing to this are limitations in current sequence-based prediction methods which often lack the ability to identify unknown AMR or other adaptive genes with novel mechanisms. To address this, we developed an integron gene cassette capture system, a functional screening platform that captures environmental gene cassettes for direct phenotypic testing. Using this system, we recovered previously unknown AMR determinants while also providing insights into the prevalence of known clinical AMR genes in a range of environmental samples, including food items. Here we provide experimental data on multiple novel bleomycin resistance genes and a stress response gene conferring gentamicin and tobramycin resistance. Our sequence analysis of the captured library also highlighted the diversity of the environmental cassette pool, with 656 unique cassettes recovered, the majority of which encoded proteins with unknown functions. The cassette capture system is a powerful tool for accessing hidden elements of the resistome and discovering novel adaptive genes that may go undetected using current sequence-based approaches. Environmental implicationAntimicrobial resistance (AMR) genes are hazardous biological contaminants, yet the vast majority of environmental integron gene cassettes remain functionally uncharacterised. This study addresses this sequence-to-function gap by deploying a novel functional capture platform directly on realistic environmental matrices, including agricultural fertilisers, coastal seawater, and commercial food products. By characterising these cassettes, we uncovered hidden reservoirs of both novel and clinically established AMR genes circulating in critical exposure pathways. This work reveals the true hazardous potential of the mobile environmental resistome, validating a proactive One Health surveillance tool for monitoring emerging biological threats.