| Literature DB >> 34362925 |
An-Ni Zhang1,2, Jeffry M Gaston3, Chengzhen L Dai2, Shijie Zhao2, Mathilde Poyet2,4,5, Mathieu Groussin2,4,5, Xiaole Yin1, Li-Guan Li1, Mark C M van Loosdrecht6, Edward Topp7, Michael R Gillings8, William P Hanage9, James M Tiedje10, Katya Moniz2, Eric J Alm2,4,5, Tong Zhang11,12,13.
Abstract
Antibiotic resistance genes (ARGs) are widespread among bacteria. However, not all ARGs pose serious threats to public health, highlighting the importance of identifying those that are high-risk. Here, we developed an 'omics-based' framework to evaluate ARG risk considering human-associated-enrichment, gene mobility, and host pathogenicity. Our framework classifies human-associated, mobile ARGs (3.6% of all ARGs) as the highest risk, which we further differentiate as 'current threats' (Rank I; 3%) - already present among pathogens - and 'future threats' (Rank II; 0.6%) - novel resistance emerging from non-pathogens. Our framework identified 73 'current threat' ARG families. Of these, 35 were among the 37 high-risk ARGs proposed by the World Health Organization and other literature; the remaining 38 were significantly enriched in hospital plasmids. By evaluating all pathogen genomes released since framework construction, we confirmed that ARGs that recently transferred into pathogens were significantly enriched in Rank II ('future threats'). Lastly, we applied the framework to gut microbiome genomes from fecal microbiota transplantation donors. We found that although ARGs were widespread (73% of genomes), only 8.9% of genomes contained high-risk ARGs. Our framework provides an easy-to-implement approach to identify current and future antimicrobial resistance threats, with potential clinical applications including reducing risk of microbiome-based interventions.Entities:
Year: 2021 PMID: 34362925 DOI: 10.1038/s41467-021-25096-3
Source DB: PubMed Journal: Nat Commun ISSN: 2041-1723 Impact factor: 14.919