Genomic characterisation and context of the blaNDM-1 carbapenemase in Escherichia coli ST101

Abstract

AbstractCarbapenems are last-resort antibiotics; however, the spread of plasmid-encoded carbapenemases such as the New Delhi metallo-β-lactamase 1 (NDM-1) challenges their effectiveness. The rise of NDM-1 has coincided with the emergence of extensively multidrug resistant (MDR) lineages such as Escherichia coli ST101. Here we present a comprehensive genomic analysis of seven E. coli ST101 isolates that carry the blaNDM-1 gene. We determined the complete genomes of two isolates and the draft genomes of five isolates, enabling complete resolution of the plasmid context of blaNDM-1. Comparisons with thirteen previously published ST101 genomes revealed a monophyletic lineage within the B1 phylogroup forming two clades (designated Clade 1 and Clade 2). Most Clade 1 strains are MDR, encoding resistance to at least 9 different antimicrobial classes, including extended spectrum cephalosporins. Additionally, we characterised different pathways for blaNDM-1 carriage and persistence in the ST101 lineage. For IncC plasmids, carriage was associated with recombination and local transposition events within the antibiotic resistance island. In contrast, we revealed recent transfer of a large blaNDM-1 resistance island between F-type plasmids. The complex acquisition pathways characterised here highlight the benefits of long-read Single Molecule Real Time sequencing in revealing evolutionary events that would not be apparent by short-read sequencing alone. These high-quality E. coli ST101 genomes will provide an important reference for further analysis of the role of mobile genetic elements in this emerging multidrug resistant lineage.ImportanceCarbapenem resistant Escherichia coli are urgent priority organisms as they are resistant to our drugs of last resort. E. coli ST101 have been reported as carriers of the New Delhi Metallo-beta-Lactamase 1 gene (blaNDM-1), conferring resistance to carbapenems, however there is limited genomic information available for this lineage. In this study we used long-read genome sequencing to characterise the complete genomes of two E. coli ST101 strains and determine the carriage of blaNDM-1 in a collection of E. coli ST101 strains. We showed that carriage of blaNDM-1 and resistance determinants to eight other antimicrobial classes was confined to a single clade. We also showed two different pathways for the carriage of blaNDM-1, which was dependent on the type of plasmid. Long-read sequencing allowed us to show the full complexities of these resistance regions and highlighted how strains from an emerging E. coli lineage have become resistant to nearly all available antimicrobials.