Increased high-level gentamicin resistance in invasive Enterococcus faecium is associated with aac(6')Ie-aph(2″)Ia-encoding transferable megaplasmids hosted by major hospital-adapted lineages.

Gentamicin is important in synergistic bactericidal therapy with cell wall agents for severe enterococcal infections. During 2003-2008, a 10-fold increase in the prevalence of high-level gentamicin resistance (HLGR), to above 50%, in blood culture isolates of Enterococcus faecium, was reported by the Norwegian Surveillance System for Antimicrobial Resistance. A representative national collection of invasive E. faecium isolates (n = 99) from 2008 was examined by a multilevel approach. Genotyping revealed a polyclonal population dominated by major hospital-associated lineages (mainly ST203, ST17, ST18, ST202 and ST192). The presence of aac(6')-Ie-aph(2″)-Ia, encoding the bi-functional aminoglycoside-modifying enzyme, was found in 98% of HLGR isolates (56/57). Furthermore, a significantly higher prevalence of potential virulence genes, toxin-antitoxin loci as well as pRE25 and pRUM type replicons was demonstrated in isolates belonging to major hospital-associated lineages compared to other sequence types. Megaplasmids of pLG1 replicon type (200-330 kb) were present in 90% of the isolates. Co-hybridization analyses revealed genetic linkage of aac(6')-Ie-aph(2″)-Ia to this replicon type. Transfer of HLGR-encoding plasmids was restricted to E. faecium. In conclusion, the increased prevalence of HLGR in invasive E. faecium in Norway is associated with hospital-adapted genetic lineages carrying aac(6')-Ie-aph(2″)-Ia-encoding transferable megaplasmids of the pLG1 replicon type.

PCR-based plasmid typing in Enterococcus faecium strains reveals widely distributed pRE25-, pRUM-, pIP501- and pHTbeta-related replicons associated with glycopeptide resistance and stabilizing toxin-antitoxin systems.

A PCR-based typing scheme was applied to identify plasmids in an epidemiologically and geographically diverse strain collection of Enterococcus faecium (n=93). Replicon types of pRE25 (n=56), pRUM (n=41), pIP501 (n=17) and pHTbeta (n=14) were observed in 83% of the strains, while pS86, pCF10, pAM373, pMBB1 or pEF418 were not detected. Furthermore, 61% of the strains contained the axe-txe (n=42) or/and the omega-epsilon-zeta (n=18) plasmid stabilization loci. Sequence analyses divided the omega-epsilon-zeta operon into two distinct phylogenetic groups. The present typing scheme accounted for about 60% of the total number of plasmids detected by S1 nuclease analyses, which revealed zero to seven plasmids (10 kb to >200 kb) per isolate. Interestingly, strains belonging to the clinically important clonal complex 17 (CC17) yielded a significantly higher number of plasmids (3.1) and pRUM replicons (74%) than non-CC17 strains (2.2% and 35%, respectively). A prevalent genetic linkage between the pRUM-replicon type and axe-txe was demonstrated by cohybridization analyses. The vanA resistance determinant was associated with all four replicon types, but we also confirmed the genetic linkage of vanA to unknown transferable replicons. PCR-based replicon typing, linked to the detection of other important plasmid-encoded traits, seems to be a feasible tool for tracing disseminating resistance plasmids stably maintained in various environments.