Characterization of the stability and dynamics of Tn6330 in an Escherichia coli strain by nanopore long reads.

BACKGROUND: The mcr-1 gene has been widely reported in both bacterial chromosomes and plasmids, while its stability in these genetic materials is not well understood.

OBJECTIVES: Our aim was to characterize the stability and dynamics of Tn6330 elements in both a plasmid and the chromosome in a single bacterial population.

METHODS: Plasmid-borne and chromosomal Tn6330 were characterized by PCR, conjugation, S1-PFGE, stability assay, single-molecule long-read sequencing and bioinformatics analysis.

RESULTS: Tn6330 was simultaneously detected in both a plasmid and the chromosome of a clinical Escherichia coli strain. The plasmid was found to comprise the IncFIB replicon and a phage-like replicon, as well as two integrons that harboured various mobile elements and resistance genes including mcr-1, floR, blaTEM-1b and strAB. Both plasmid-borne and chromosomal Tn6330 transposons could be re-organized into a circular intermediate that played a role in transmission of the mcr-1 gene. Tn6330 was found to be very stable in both the plasmid and chromosome after 30 passages of 12 h with or without colistin selective pressure. The decayed structure of Tn6330 in the genuine single DNA molecules of bacterial populations, although occurring at a very low frequency, could be detected for the first time, in which Tn6330 was degraded into a single ISApl1 element.

CONCLUSIONS: Long-read sequencing technology is a good tool to study the evolution and stability of genetic elements in bacteria. The ultrastability of an mcr-1-encoding element in a bacterial plasmid and chromosome renders it unlikely to be eradicated quickly by the reduced use of colistin, and factors leading to the frequent demise of Tn6330 warrant further studies.