Background The global dissemination of colistin resistance encoded by mcr-1 has been attributed to extensive use of colistin in livestock, threatening colistin efficacy in medicine. The emergence of mcr-1 in common pathogens, such as Escherichia coli, is of particular concern. China banned the use of colistin in animal feed from May 1, 2017. We investigated subsequent changes in mcr-1 prevalence in animals, humans, food, and the environment, and the genomic epidemiology of mcr-1-positive E coli (MCRPEC).Methods Sampling was done before (October to December, 2016) and after (October to December, 2017, and 2018, respectively) the colistin ban. 3675 non-duplicate pig faecal samples were collected from 14 provinces (66 farms) in China to measure intervention-related changes in mcr-1 prevalence. 15 193 samples were collected from pigs, healthy human volunteers, patients colonised or infected with Enterobacteriaceae who were admitted to hospital, food and the environment in Guangzhou, to characterise source-specific mcr-1 prevalence and the wider ecological effect of the ban. From these samples, 688 MCRPEC were analysed with whole genome sequencing, plasmid conjugation, and S1 pulsed-field gel electrophoresis with Southern blots to characterise associated genomic changes. FindingsAfter the ban, mcr-1 prevalence decreased significantly in national pig farms, from 308 (45%) of 684 samples in 2016 to 274 (19%) of 1416 samples in 2018 (p<0•0001). A similar decrease occurred in samples from most sources in Guangzhou (959 [19%] of 5003 samples in 2016; 238 [5%] of 4489 samples in 2018; p<0•0001). The population structure of MCRPEC was diverse (23 sequence clusters); sequence type 10 clonal complex isolates were predominant (247 [36%] of 688). MCRPEC causing infection in patients admitted to hospital were genetically more distinct and appeared less affected by the ban. mcr-1 was predominantly found on plasmids (632 [92%] of 688). Common mcr-1 plasmid types included IncX4, IncI2, and IncHI2 (502 [76%] of 656); significant increases in IncI2-associated mcr-1 and a distinct lineage of mcr-1-associated IncHI2 were observed post ban. Changes in the frequency of mcr-1-associated flanking sequences (ISApl1-negative MCRPEC), 63 core genome single nucleotide polymorphisms, and 30 accessory genes were also significantly different after the ban (Benjamini-Hochberg-adjusted p<0•05), consistent with rapid genetic adaptation in response to changing selection pressures. Interpretation A rapid, ecosystem-wide, decline in mcr-1 was observed after the use of colistin in animal feed was banned, with associated genetic changes in MCRPEC. Withdrawal of antimicrobials from animal feed should be an important One Health measure contributing to the wider control of antimicrobial resistance globally.
The global dissemination of the mobilized colistin resistance gene, mcr-1 , threatens human health. Recent studies by our group and others have shown that the withdrawal of colistin as a feed additive dramatically reduced the prevalence of mcr-1 . Although it is accepted that the rapid reduction in mcr-1 prevalence may have resulted, to some extent, from the toxic effects of MCR-1, the detailed mechanism remains unclear. Here, we found that MCR-1 damaged the outer membrane (OM) permeability in Escherichia coli and Klebsiella pneumonia and that this event was associated with MCR-1-mediated cell shrinkage and death during the stationary phase. Notably, the capacity of MCR-1-expressing cells for recovery from the stationary phase under improved conditions was reduced in a time-dependent manner. We also showed that mutations in the potential lipid-A-binding pocket of MCR-1, but not in the catalytic domain, restored OM permeability and cell viability. During the stationary phase, PbgA, a sensor of periplasmic lipid-A and LpxC production that performed the first step in lipid-A synthesis, was reduced after MCR-1 expression, suggesting that MCR-1 disrupted lipid homeostasis. Consistent with this, the overexpression of LpxC completely reversed the MCR-1-induced OM permeability defect. We propose that MCR-1 causes lipid remodelling that results in an OM permeability defect, thus compromising the viability of Gram-negative bacteria. These findings extended our understanding of the effect of MCR-1 on bacterial physiology and provided a potential strategy for eliminating drug-resistant bacteria.
The antibiotic resistance crisis continues to threaten human health. Better predictions of the evolution of antibiotic resistance genes could contribute to the design of more sustainable treatment strategies. However, comprehensive prediction of antibiotic resistance gene evolution via laboratory approaches remains challenging. By combining site-specific integration and high-throughput sequencing, we quantified relative growth under the respective selection of cefotaxime or ceftazidime selection in ∼23,000 E. coli MG1655 strains that each carried a unique, single-copy variant of the extended-spectrum β-lactamase gene blaCTX-M-14 at the chromosomal att HK022 site. Significant synergistic pleiotropy was observed within four subgenic regions, suggesting key regions for the evolution of resistance to both antibiotics. Moreover, we propose PEARP and PEARR, two deep learning models with strong clinical correlations, for the prospective and retrospective prediction of blaCTX-M-14 evolution, respectively. Single to quintuple mutations of blaCTX-M-14 predicted to confer resistance by PEARP were significantly enriched among the clinical isolates harboring blaCTX-M-14 variants, and the PEARR scores matched the minimal inhibitory concentrations (MICs) obtained for the 31 intermediates in all hypothetical trajectories. Altogether, we conclude that the measurement of local fitness landscape enables prediction of the evolutionary trajectories of antibiotic resistance genes, which could be useful for a broad range of clinical applications, from resistance prediction to designing novel treatment strategies.
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