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.
The evolutionary processes responsible for the long-term persistence of glycopeptide-resistant Enterococcus faecium (GREF) in nonselective environments were addressed by genetic analyses of E. faecium populations in animals and humans on two Norwegian poultry farms that were previously exposed to avoparcin. A total of 222 fecal GREF (n ؍ 136) and glycopeptide-susceptible (n ؍ 86) E. faecium (GSEF) isolates were obtained from farmers and poultry on three separate occasions in 1998 and 1999. Pulsed-field gel electrophoresis (PFGE) and plasmid DNA analyses discerned 22 GREF and 32 GSEF PFGE types within shifting polyclonal animal and human E. faecium populations and indicated the presence of transferable plasmid-mediated vanA resistance, respectively. Examples of dominant, persistent GREF PFGE types supported the notion that environmentally well-adapted GREF types may counteract the reversal of resistance. PFGE analyses, sequencing of the purK housekeeping gene, and partial typing of vanA-containing Tn1546 suggested a common animal and human reservoir of glycopeptide resistance. Inverse PCR amplification and sequence analyses targeting the right end of the Tn1546-plasmid junction fragment strongly indicated the presence of a common single Tn1546-plasmidmediated element in 20 of 22 GREF PFGE types. This observation was further strengthened by vanY-vanZ hybridization analyses of plasmid DNAs as well as the finding of a physical linkage between Tn1546 and a putative postsegregation killing system for seven GREF PFGE types. In conclusion, our observations suggest that the molecular unit of persistence of glycopeptide resistance is a common mobile plasmid-mediated vanA-containing element within a polyclonal GREF population that changes over time. In addition, we propose that "plasmid addiction systems" may contribute to the persistence of GREF in nonselective environments.
ObjectivesTo determine the genetic composition of the first VanA-type plasmid (pIP816) reported, which was isolated from a clinical Enterococcus faecium (BM4147) strain in France in 1986, and to reveal the genetic units responsible for the dissemination of the vanA gene cluster by comparisons with current, published and additionally generated vanA-spanning plasmid sequences obtained from a heterogeneous E. faecium strain collection (n = 28).MethodsPlasmid sequences were produced by shotgun sequencing using ABI dye chemistry and primer walking, and were subsequently annotated. Comparative sequence analysis of the vanA region was done with published plasmids, with a partial vanA plasmid (pVEF4) reported here and to >140 kb of sequence obtained from a collection of vanA-harbouring plasmid fragments.ResultsBioinformatic analyses revealed that pIP816 from 1986 and contemporary vanA plasmids shared a conserved genetic fragment of 25 kb, spanning the 10.85 kb vanA cluster encoded by Tn1546, and that the larger unit is present in both clinical and animal complexes of E. faecium. A new group II intron in pVEF4 was characterized.ConclusionsComparative DNA analyses suggest that Tn1546 disseminates in and between clonal complexes of E. faecium as part of a larger genetic unit, possibly as a composite transposon flanked by IS1216 elements.
The DNA sequences of two plasmids carrying vanA, pVEF1 (39,626 bp) and pVEF2 (39,714 bp), were determined. Forty-three shared coding sequences were identified, and the only nucleotide difference was an 88-bp indel. A postsegregational killing system was identified. This system possibly explains the persistence of the vanA gene cluster in Norwegian poultry farms.
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