Global dissemination of npmA mediated pan-aminoglycoside resistance via a mobile genetic element in Gram-positive bacteria
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2025
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Nature Research
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Serna, C., Matamoros, B. R., Pulido-Vadillo, M., Delgado-Blas, J. F., Jansen, R. R., Willems, R. J. L., Almeida, A., Harrison, E. M., Dupuy, B., Coll, F., & Gonzalez-Zorn, B. (2025). Global dissemination of npmA mediated pan-aminoglycoside resistance via a mobile genetic element in Gram-positive bacteria. Nature communications, 16(1), 6360. https://doi.org/10.1038/s41467-025-61152-y
Abstract
The npmA gene, encoding a 16S rRNA methyltransferase, confers resistance to all clinically available aminoglycosides, posing a significant threat to effective antibiotic therapy. We analyze 1,932,812 bacterial genomes to investigate the distribution and mobilization of npmA variants. npmA is not found in Gram-negative bacteria, where it was originally described, but is identified among Gram-positive bacteria, predominantly as the npmA2 variant in the globally distributed Clostridioides difficile ST11 lineage. We also detect npmA2 in two vancomycin-resistant Enterococcus faecium isolates from a Dutch hospital. Upon sequencing and phenotypic analysis, we determine that E. faecium isolates are pan-resistant to aminoglycosides. Genomic characterization links npmA2 to a composite transposon, Tn7734, which is integrated within a previously uncharacterized Integrative and Conjugative Element (ICE) Tn7740, present in both npmA2-carrying C. difficile and E. faecium clinical isolates. Tn7740-like, but not npmA2, appears across diverse taxa, including human microbiome members. Here, we show that Tn7740 likely facilitates cross-species npmA2 mobilization between these Gram-positive bacteria and emphasize the risk of mobile genetic elements transferring pan-aminoglycoside resistance between clinically important bacterial pathogens
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Author contributions:
C.S. contributed to conceptualization, methodology, software, validation, formal analysis, investigation, data curation, writing the original draft and visualization. B.R.M. carried out the phenotypic experiments and was involved in the investigation and methodology. M.P.V. performed the stability and conjugation experiments. J.F.D.-B. aided in conceptualization, drafted and reviewed the manuscript, and engaged in scientific discussions. R.R.J. and R.J.L.W. supplied the E. faecium isolates, with R.J.L.W. also providing critical feedback on the manuscript draft. A.A. performed the metagenomic analyses and contributed to writing, review & editing. E.M.H. provided supervision, discussed results, and contributed to writing, review & editing. B.D. performed the stability and conjugation experiments and contributed to writing, review & editing. F.C. was involved in conceptualization, resources, data curation, supervision, methodology, and writing, review & editing. B.G.Z. provided supervision, contributed to writing, review & editing, project administration and funding acquisition. All authors read and commented on successive drafts and approved the final version of the manuscript.