IS26 cannot move alone

Background IS26 plays a major role in the dissemination of antibiotic resistance determinants in Gram-negative bacteria. Objectives To determine whether insertion sequence IS26 is able to move alone (simple transposition) or if it exclusively forms cointegrates. Methods A two-step PCR using outward-facing primers was used to search for circular IS26 molecules. Gibson assembly was used to clone a synthetic IS26 containing a catA1 chloramphenicol resistance gene downstream of the tnp26 transposase gene into pUC19. IS activity in a recA− Escherichia coli containing the non-conjugative pUC19-derived IS26::catA1 construct and the conjugative plasmid R388 was detected using a standard mating-out assay. Transconjugants were screened for resistance. Results Circular IS26 molecules that would form with a copy-out route were not detected by PCR. The synthetic IS26::catA1 construct formed CmRTpR transconjugants (where CmR and TpR stand for chloramphenicol resistant and trimethoprim resistant, respectively), representing an R388 derivative carrying the catA1 gene at a frequency of 5.6 × 10−7 CmRTpR transconjugants per TpR transconjugant, which is comparable to the copy-in activity of the unaltered IS26. To test for simple transposition of IS26::catA1 (without the plasmid backbone), 1200 CmRTpR colonies were screened and all were resistant to ampicillin, indicating that the pUC19 backbone was present. Hence, IS26::catA1 had only formed cointegrates. Conclusions IS26 is unable to move alone and cointegrates are the exclusive end products of the reactions mediated by the IS26 transposase Tnp26. Consequently, when describing the formation of complex resistance regions, simple ‘transposition’ of a single IS26 should not be invoked.

Plasmid-Mediated Colistin Resistance (mcr-1) in Escherichia coli from Non-Imported Fresh Vegetables for Human Consumption in Portugal

In this study, we report the presence of the plasmid-mediated colistin resistance (PMCR)-encoding gene mcr-1 in an Escherichia coli isolate, INSali25, recovered from lettuce produced and marketed in Portugal. Colistin MIC from the vegetable E. coli isolate—determined by microdilution broth method according to EUCAST guidelines—revealed a non-wild-type phenotype of colistin (MIC 16 mg/L). To understand the genetic background of E. coli INSali25, we performed whole genome sequencing. Plasmid sequencing was also performed after plasmid DNA extraction from the transconjugant TcINSali25 (mcr-1). Directed bioinformatics analysis identified the mcr-1 gene in a 39,998 bp length contig, with an upstream region including the antibiotic resistance gene blaTEM-1 in a partial transposon Tn2, truncated by the insertion sequence IS26 and showing >99% identity with previously described mcr-1-harboring IncHI2 plasmids. Further in silico analysis showed the presence of additional genes conferring resistance to β-lactams (blaTEM-1), aminoglycosides (aadA1, aph(4)-Ia, aph(6)-Id, aac(3)-Iv), macrolides (mdf(A)-type), phenicol (floR-type), tetracycline (tetA), and sulphonamides (sul2). INSali25 isolate belonged to the ST1716 lineage and showed the fimH54 and fumC27 alleles. Lettuce is a vegetable that is commonly consumed fresh and not subjected to any cooking process, which may amplify human food safety risks. Moreover, the occurrence of plasmid-mediated colistin resistance in a sample that was not imported and was acquired in a large retail store reinforces the widespread distribution of mcr-1.