Multilocus Sequence Typing Scheme for Enterococcus faecium

A multilocus sequence typing (MLST) scheme has been developedfor Enterococcus faecium. Internal fragments from seven housekeepinggenes of 123 epidemiologically unlinked isolates from humansand livestock and 16 human-derived isolates from several outbreaksin the United States, the United Kingdom, Australia, and TheNetherlands were analyzed. A total of 62 sequence types weredetected in vancomycin-sensitive E. faecium (VSEF) and vancomycin-resistantE. faecium (VREF) isolates. VSEF isolates were genetically morediverse than VREF isolates. Both VSEF and VREF isolates clusteredin host-specific lineages that were similar to the host-specificclustering obtained by amplified fragment length polymorphismanalysis. Outbreak isolates from hospitalized humans clusteredin a subgroup that was defined by the presence of a unique allelefrom the housekeeping gene purK and the surface protein geneesp. The MLST results suggest that epidemic lineages of E. faeciumemerged recently worldwide, while genetic variation in bothVREF and VSEF was created by longer-term recombination. Theresults show that MLST of E. faecium provides an excellent toolfor isolate characterization and long-term epidemiologic analysis.

INTRODUCTION

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Introduction

Vancomycin-resistant Enterococcus faecium (VREF) has recentlyemerged as an important threat in U.S. hospitals (5, 24). InEurope, VREF isolates are found relatively frequently in thecommunity and farm animals, while prevalence in hospitals isgenerally low (14). The latter observation was explained bythe use of the glycopeptide avoparcin as an antimicrobial growthpromoter in animal feeding operations.

Several molecular typing schemes have been developed to studythe epidemiology of VREF. Of these, pulsed-field gel electrophoresisanalysis of genomic restriction fragments has been consideredthe "gold standard" for the study of hospital outbreaks becauseof its high degree of isolate differentiation (15, 17, 20, 23).However, due to this high degree of isolate differentiation,pulsed-field gel electrophoresis typing is less suitable fordetermining the degree of relatedness among epidemiologicallyunrelated isolates. Recently, amplified fragment length polymorphism(AFLP) analysis was applied as a new method for the typing ofVREF (1, 33). AFLP analysis is a robust and fast typing techniquewith high intra- and interexperimental reproducibilities andappears to be discriminatory enough for the recognition of hospitaloutbreaks (1, 32, 33). In addition, AFLP analysis has allowedthe detection of associations among different E. faecium geneticlineages and different human and animal hosts (33), suggestingthe existence of host-specific VREF lineages. Whether this isalso true for vancomycin-sensitive E. faecium (VSEF) is notknown, since VSEF isolates were not included in that study.AFLP typing also disclosed two different human-associated lineages.One lineage comprised epidemic-related isolates recovered fromhospitalized patients, while isolates of the other lineage weremainly from nonhospitalized persons. Interestingly, the epidemiclineage was characterized by the presence of the esp virulencegene (32). Recently, the existence of host-specific lineagesand an epidemic esp-bearing lineage was confirmed by ribotypinganalysis of VREF isolates (4).

Although AFLP data generated within a given laboratory appearreproducible and were successfully used in identifying clustersof closely related E. faecium isolates, the method may be lesssuitable for global epidemiologic analysis. Variations in bandintensities can easily occur and can be a source of ambiguitieswhen curve-based similarity coefficients, such as the Pearsoncorrelation, are used to compare banding patterns (27).

An unambiguous international database of E. faecium geneticlineages could be a powerful resource for global epidemiologicstudy, recognition, and tracking the worldwide interhospitalspread of virulent, epidemic, and multiresistant clones. Themost appropriate technique for such studies is multilocus sequencetyping (MLST), as MLST is based on identifying alleles fromDNA sequences of internal fragments of housekeeping genes. Thistechnique is preeminently useful for electronic data exchange.MLST has been used successfully for the study of the molecularepidemiology and the exploration of the population structureand evolution of virulence of various bacterial species (6,8, 10, 11, 18, 22).

In this study, we describe an MLST scheme for E. faecium basedon the nucleotide sequences of seven housekeeping genes. Previousstudies focused only on vancomycin-resistant isolates; therefore,we included vancomycin-sensitive isolates as well. We show thatMLST discerns the same main genetic lineages as were previouslydisclosed by ALFP typing and that VSEF isolates are groupedwithin these lineages. Furthermore, we show that epidemic VREFisolates have been disseminated worldwide in the recent pastand that recombination plays an important role in the generationof diversity in E. faecium.

MATERIALS AND METHODS

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Materials and Methods

Bacterial isolates and bacteriological determinations. A total of 123 E. faecium isolates were used for establishingthe MLST scheme; the main properties of these isolates are describedin Table 1. These isolates were not known to have an epidemiologicallink (32). Isolates from nonhospitalized humans and animalswere derived from the feces of healthy hosts. Isolates fromhospitalized humans consisted of representative clinical isolatesfrom hospital outbreaks in the United States, the United Kingdom,The Netherlands, and Australia; isolates from clinical sitesnot related to outbreaks; and fecal isolates from screeningsin hospitals. The samples included previously described vancomycin-resistantisolates (33). Another 16 isolates were derived from hospitalizedindividuals involved in the outbreaks. Species identificationof E. faecium was performed by D-alanine:D-alanine ligase (ddl)gene-specific PCR (7). Susceptibility testing for vancomycinand determination of vanA and vanB genes were performed as describedearlier (33).

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TABLE 1. Origins and characteristics of E. faecium isolates

MLST. Seven housekeeping loci were selected for the characterizationof E. faecium isolates by MLST (Table 2). The choice of thesehousekeeping genes was based on their putative function, ontheir use in MLST schemes for other bacterial species (9, 12,31) and, in most cases, on the availability of sequence datafrom E. faecalis. These loci are separated by at least 160 kbin E. faecalis (preliminary sequence data from The Institutefor Genomic Research; www.tigr.org). Although the complete sequenceof the E. faecium genome has not yet been determined, all sevenhousekeeping genes are located on different E. faecium contigs;therefore, these loci are likely to be genetically unlinked.With the exception of the sequences of the primers for D-alanine:D-alanineligase (ddl), the primer sequences for the housekeeping geneswere taken from homologues in the E. faecalis genome database(The Institute for Genomic Research).

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TABLE 2. Allelic variation in seven housekeeping genes from VSEF and VREF isolates

Internal 400- to 600-bp fragments of the following genes wereamplified by PCR: adk (adenylate kinase), atpA (ATP synthase,alpha subunit), ddl (D-alanine:D-alanine ligase), gyd (glyceraldehyde-3-phosphatedehydrogenase), gdh (glucose-6-phosphate dehydrogenase), purK(phosphoribosylaminoimidazol carboxylase ATPase subunit), andpstS (phosphate ATP-binding cassette transporter). Fragmentswere amplified from bacterial lysates by PCR with the followingsets of primers: adk, 5'-TAT GAA CCT CAT TTT AAT GGG-3', andadk2, 5'-GTT GAC TGC CAA ACG ATT TT-3'; atpA1, 5'-CGG TTC ATACGG AAT GGC ACA-3', and atpA2, 5'-AAG TTC ACG ATA AGC CAC GG-5';ddl1, 5'-GAG ACA TTG AAT ATG CCT TAT G-3', and ddl2, 5'-AAAAAG AAA TCG CAC CG-3'; gdh1, 5'-GGC GCA CTA AAA GAT ATG GT-3',and gdh2, 5'-CCA AGA TTG GGC AAC TTC GTC CCA-3'; gyd1, 5'-CAAACT GCT TAG CTC CAA GG C-3', and gyd2, 5'-CAT TTC GTT GTC ATACCA AGC-3'; purK1, 5'-GCA GAT TGG CAC ATT GAA AGT-3', and purK2,5'-TAC ATA AAT CCC CCT GTT TY-3'; and pstS1, 5'-TTG AGC CAAGTC GAA GCT GGA G-3', and pstS2, 5'-CGT GAT CAC GTT CTA CTTCC-3'.

PCR conditions for all amplification reactions were as follows:initial denaturation at 94°C for 3 min; 35 cycles at 94°Cfor 30 s, 50°C for 30 s, and 72°C for 30 s; and extensionat 72°C for 5 min. Reactions were performed in 50-µlvolumes with buffers and Taq polymerase from SphaeroQ (Leiden,The Netherlands). PCR products were purified with a PCR purificationkit from Qiagen Inc. (Hilden Germany) and sequenced with PCRforward or reverse primers, an ABI PRISM Big Dye Cycle SequencingReady Reaction kit (Perkin-Elmer, Applied Biosystems, FosterCity, Calif.), and an ABI 3700 DNA sequencer (Perkin-Elmer).Different sequences of a given locus were given allele numbers,and each unique combination of alleles (the allelic profile)was assigned a sequence type (ST).

AFLP analysis and sequence analysis of 16S ribosomal DNA wereperformed by previously described methods (3, 33). 16S ribosomalDNA sequences were analyzed by a BLAST search of the GenBankdatabase.

Computer analysis of MLST data. Clustering of 123 isolates from the matrix of pairwise similaritiesbetween the allelic profiles was performed with BioNumericssoftware (Applied Maths) by the unweighted pair-group methodwith arithmetic averages (UPGMA) and the categorical coefficientof similarity.

The MEGA suit of programs (version 2.1; http://www.megasoftware.net)(21) was used to calculate average numbers of nucleotide differencesbetween alleles and to construct gene trees by the neighbor-joining(NJ) method. The significance of branching of the NJ trees wasevaluated by bootstrap analysis of 500 computer-generated trees.

Ratios of nonsynonymous to synonymous substitutions were calculatedto test the degree of selection operating on a locus by usingSTART (http://www.mlst.net). Allelic diversity was calculatedwith the equation [n/(n - 1)](1 - ${Sigma}$ x_i²), where x_i is the frequencyof the ith allele and n is the number of isolates (25).

The measure of linkage equilibrium between alleles at the sevenhousekeeping genes was assessed by calculating the index ofassociation (I_a) with the program at the MLST website (http://www.mlst.net).The I_a is defined as the observed variance in the distributionof allelic mismatches in all pairwise comparisons of the allelicprofiles divided by the expected variance in a freely recombiningpopulation, minus 1 (30). When the alleles are in linkage equilibrium,the I_a is expected not to deviate significantly from zero. Thesignificance of I_a was estimated by comparing the observed varianceobtained from the actual data with the maximum variance calculatedfrom 1,000 data sets under the assumption of the random associationof loci. Significant linkage disequilibrium was establishedwhen the observed variance obtained from the actual data wasgreater than the calculated maximum variance after 1,000 randomizations(P < 0.001).

Nucleotide sequence accession numbers. The sequences of the alleles from the E. faecium housekeepinggenes have been given the following GenBank accession numbers:AF443299 to AF443305 (adk); AF443306 to AF443322 (atpA); AF443323to AF443331 (ddl); AF443332 to AF443343 (gdh); AF443344 to AF443354(gyd); AF443355 to AF443367 (purK); and AF443368 to AF443384(pstS).

RESULTS

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Results

Allelic variation in E. faecium. The set of E. faecium isolates subjected to MLST analysis comprised123 epidemiologically unlinked isolates (41 vancomycin sensitiveand 72 vanA and 10 vanB containing) originating from hospitalizedand nonhospitalized humans, veal calves, pigs, poultry, dogs,and cats. The number of unique alleles found for each of theseven housekeeping genes ranged from 7 for adk to 17 for pstSand atpA (Table 2). The average number of nucleotide differencesbetween alleles of a given locus varied from 2.8 (for adk) to17.6 (for pstS) among the 123 E. faecium isolates analyzed.The variations in the sequences extended over the whole stretchof the sequenced portion of each of the seven genes investigated,as shown in Tables 3 and 4 for the gdh and atpA allelic variants.Most polymorphisms resulted in synonymous substitutions. Theratios of nonsynonymous to synonymous substitutions varied from0 for atpA and ddl to 0.07 for pstS. The average ratio for allloci was 0.02 (results not shown). These low ratios indicatea very limited contribution of environmental selection to thesequence variations in the seven housekeeping genes used inthis study; therefore, these housekeeping genes are assumedto be suitable for a population-genetic study.

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TABLE 3. Polymorphic nucleotide sites in the gdh locus^a

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TABLE 4. Polymorphic nucleotide sites in the atpA locus^a

Dendrograms of the alleles of the separate housekeeping genetargets are shown in Fig. 1. Interestingly, a clear bifurcationinto majority and minority allelic populations was observedfor all the genes, except for atpA. The alleles of atpA alsoclustered into two populations, but the populations had approximatelyequal numbers of isolates and both comprised VREF and VSEF isolates.The significance of the observed bifuractions is strongly supportedby bootstrap analysis. The average numbers of nucleotide differencesbetween the majority and the minority group populations were30, 29, 33, 10, 4.3, and 4.1 for purK, pstS, gdh, ddl, adk,and gyd, respectively. Only five isolates were shared amongthe minority allelic populations of these six housekeeping genes.Based on MLST data, these five isolates, four VSEF isolatesand one vanB-harboring E. faecium isolate, are most distantlyrelated to the other isolates, clustering at the bottom of thedendrogram constructed from the allelic profiles (Fig. 2, isolatesrepresented by STs 39, 60, 40, 61, and 62). They differed insix of the seven alleles from all of the remaining isolatesinvestigated in this study. Furthermore, these isolates alsoclustered separately from the four major lineages determinedby AFLP analysis (data not shown). Therefore, these isolatesare genetically the most divergent of the isolates analyzedin this study, and much of the allelic variation shown in Table2 is due to variations in these five genetically divergent isolates.

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FIG. 1. Dendrograms showing the genetic relationships among the allele sequences of individual loci used for MLST. The trees were established by analysis of the allele sequences from the seven housekeeping loci by the NJ method. Numbers of VSEF and VREF strains in the different clusters are given to the right of the dendrograms. The scale bar indicates five nucleotide differences. Dots indicate the alleles associated with allele purK6. Bootstrap values of greater than 90% are indicated.

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FIG.2. Dendrogram (categorical, UPGMA) showing the genetic relatedness among the STs of E. faecium. The following data are included: ST; number of strains with the same ST; AFLP group (genogroup determined by AFLP analysis; R, non-A, -B, -C, or -D); host origin (C, calf; H, human; HF, fecal sample from a hospitalized human; HC, clinical sample from a hospitalized human, not outbreak related; HO, clinical sample from a hospitalized human, outbreak related; S, pig; P, poultry); presence of vanA or vanB (A, vanA resistant strain; B, vanB resistant strain; S, sensitive strain); presence of the esp gene; and country (NL, The Netherlands; UK, United Kingdom; USA, United States; Aus or Austr., Australia). The dendrogram is divided by dotted lines into a number of lineages, labeled A to D, similar to the genogroups detected by AFLP analysis (33). Genetically divergent isolates are indicated in bold. n.d., not determined.

To test whether these five isolates might have been misdiagnosedas E. faecium by the standard bacteriological determination,sequencing of their 16S rRNA genes was undertaken. This analysisrevealed that the three isolates with STs 40, 60, and 61 differedin only one residue from both E. faecium and E. durans, whereasthe sequences of isolates with ST 39 and ST 62 were identicalto the sequence of E. durans. However, species determinationby ddl gene analysis, a method generally used for enterococci(7, 26), grouped the sequences of the five divergent isolatesin a cluster having 98% similarity with all E. faecium ddl sequences,well separated (83% similarity) from the E. durans sequence(GenBank accession number AF170804) and the E. hirae sequence(GenBank accession number U39788) (results not shown). Furthermore,all polymorphisms in the ddl alleles were silent, coding forpeptide fragments with identical amino acid compositions whichdiffered by 3% from the compositions of the fragments in E.durans and E. hirae. These data suggest that three of the divergentisolates can be considered E. faecium and that classificationof two of the isolates is ambiguous.

Genetic diversity of VSEF and VREF isolates. Among the 123 epidemiologically unlinked isolates investigated,62 STs were found; the majority of these, 44 STs, were representedby single isolates (Fig. 2). The types most frequently encounteredwere ST 17 (17 isolates), ST 6 (14 isolates), ST 4 (9 isolates),and ST 16 (6 isolates). Isolates with ST 16 and ST 17, whichshared six of the seven housekeeping alleles, were from hospitalizedindividuals. All ST 16 isolates and two of the ST 17 isolateswere representatives from outbreaks; the remaining ST 17 isolateswere taken from clinical sites and were not known to have anepidemiological link. Three of the 14 ST 6 isolates were fromfeces derived from hospitalized humans and were not outbreakrelated. The remaining ST 6 isolates originated from healthyhumans (six isolates) and pigs (five isolates). All ST 4 isolatesoriginated from calves (Fig. 2).

Thirty-six different STs were found among 41 VSEF isolates,and 31 were found among 82 VREF isolates. VSEF and VREF isolatessharing the same ST were present only among the five allelictypes ST 4, ST 5, ST 6, ST 17, and ST 44; however, the majorityof the isolates belonging to these STs (40 of 47 isolates) werevancomycin resistant. The most prevalent allelic type, ST 17,was the only one comprising both vanA- and vanB-carrying isolates(Fig. 2). Although the number of VSEF isolates (n = 41) examinedwas considerably smaller than the number of vanA-carrying E.faecium isolates (n = 72), the VSEF isolates contributed disproportionatelymore to the allelic diversity of the whole sample of isolatesanalyzed: 70 different alleles were present among the vancomycin-sensitiveisolates, and only 39 were identified among the vanA-carryingisolates. Consistent with this difference is the higher meanallelic diversity value of the vancomycin-sensitive isolates(0.71) than of the vanA-carrying isolates (0.53) (Table 2).Even after exclusion of the five divergent isolates, the vancomycin-sensitiveisolates were genetically more diverse than the vancomycin-resistantisolates, although the difference in mean allelic diversitydecreased after exclusion of the divergent isolates (valuesof 0.64 and 0.53 for the vancomycin-sensitive and vancomycin-resistantisolates, respectively) (Table 2).

There were only 10 vanB-carrying isolates in the collection;9 originated from Australia and 1 was from the United States.Nine of the isolates had the most prevalent allelic type, ST17 (Fig. 2). The remaining isolate was one of the five geneticallydivergent isolates described above.

Epidemiology of genetic lineages. The results of the clustering by UPGMA of the allelic profilesare shown in Fig. 2. Four major groups, containing isolateswith >40% similarity in allelic profiles, were discernible;a residual group included the five genetically most divergentisolates. Groups were designated MLST lineages A through D (Fig.2). These lineages corresponded well with the previously establishedgenogroups A through D obtained by clustering based on AFLPtyping of E. faecium (33). Interestingly, the relationship betweenlineages and host specificity was found not only among the vancomycin-resistantisolates, as described previously, but also among the vancomycin-sensitiveisolates (Fig. 2). Lineage D isolates were mainly from calves(16 of 18 isolates), lineage A isolates were mainly from nonhospitalizedhumans and pigs (17 of 25 isolates), lineage B isolates weremainly from poultry (15 of 20 isolates), and lineage C isolateswere from hospitalized humans (37 of 47 isolates) and a varietyof sources, such as dogs, cats, and poultry (10 of 47 isolates).

All four major lineages contained both vancomycin-sensitiveand vancomycin-resistant isolates. Isolates from humans weredistributed among all lineages; however, isolates related tohospital outbreaks in The Netherlands, Australia, the UnitedKingdom, and the United States all clustered in a geneticallyclosely related subgroup of lineage C with ST 16, 17, 18, or20 (Fig. 2, lineage C1). The esp gene, which has been associatedwith virulence and epidemicity in hospitals (29, 32), was uniquelypresent in isolates with these STs (Fig. 2). The remaining isolatesin subgroup C1 (STs 19 and 31) were sporadic isolates from patientsin different hospitals and were not known to be related to anoutbreak. Both isolates lacked the esp gene, a finding consistentwith the idea that esp is a requisite for epidemicity. All isolatesbelonging to subgroup C1 shared allele purK1, which was notfound among any of the other isolates. This result confirmsthe previous observation that this purK allele invariably wascorrelated with the presence of esp in vancomycin-resistantisolates (32).

To investigate how MLST performs with epidemiologically relatedisolates, we analyzed 16 additional isolates (not belongingto the sample of 123 isolates) involved in different outbreaksin the United States, The Netherlands, Australia, and the UnitedKingdom and belonging to STs 16, 17, 18, and 20. The analysisrevealed that all isolates involved in a particular outbreakexhibited the same allelic profile as the representative isolate(data not shown).

Evidence for recombination in E. faecium. As described above, the gene tree of the atpA alleles is notcongruent with the trees of the other loci. The noncongruencebetween the gene trees suggests a weak linkage between the atpAalleles and the other loci, and this characteristic is indicativeof a role for recombination in the generation of divergencein E. faecium. The poor linkage between alleles from differentloci is directly obvious from Fig. 2 and is further illustratedfor purK6 in Fig. 1. The latter figure shows that allele purK6is associated with several alleles from the other loci. A morequantitative analysis of the association between alleles fromdifferent loci was performed by calculating the I_a (30). Significantlinkage disequilibrium was detected when all 123 isolates orSTs were included in the analysis (I_as, 1.07 and 0.79, respectively)(Table 5). Also, after exclusion of the five genetically mostdivergent isolates, the alleles of the 118 remaining isolateswere found to be in linkage disequilibrium (I_a, 0.83; P <0.001). However, no evidence for linkage was detected when theanalysis was performed at the level of STs (I_a, 0.44; P >0.05) (Table 5). Analysis of VSEF isolates and vanA-containingisolates separately showed that, at the level of STs, therewas no evidence for linkage between loci of the vanA-containingisolates (I_a, 0.41; P > 0.05). Loci of the VSEF isolateswere in linkage disequilibrium at the levels of both isolatesand STs. However, no significant linkage between loci was detectedat both isolate and ST levels when the most divergent isolateswere excluded from the VSEF group (Table 5). These observationsimply that horizontal transfer of DNA plays an important rolein the generation of genetic variations in both VSEF and vanA-containingisolates.

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TABLE 5. I_as for vanA-carrying and VSEF isolates

An approximate estimation of the relative contributions of recombinationand mutation to clonal divergence was made by using the methodand criteria described by Feil et al. (13). Clonal complexesconsisting of STs that differed in one or two alleles and thatwere part of the UPGMA lineages were made, and the contributionof recombination or mutation was calculated. It was estimatedthat recombinational exchange generated new alleles at a frequencyfivefold higher than point mutation, while single nucleotidesites were 24 times more likely to change through recombinationthan through mutation (results not shown). The per-site recombination-to-mutationratio was about one-half the ratio for Streptococcus pneumoniaeand one-fourth the ratio for Neisseria meningitidis (13).

DISCUSSION

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Discussion

One of the main objectives of this study was to provide a referencescheme for the typing of E. faecium to allow unambiguous comparisonof data between different laboratories. We determined the degreeof allelic variations in seven housekeeping genes of E. faeciumby using a sample of 123 isolates originating from human andanimal sources in various countries. The degree of isolate differentiationby MLST appears adequate for use in epidemiological investigations,as the number of different types obtained by MLST was comparableto that obtained by AFLP analysis, a technique with proven discriminatorypower for VREF isolates (1, 32, 33). Further confirmation ofthe classification of VREF isolates by AFLP analysis and MLSTwas recently provided by ribotyping analysis (4). Genogroupingof E. faecium isolates by MLST was highly congruent with groupingby AFLP analysis. In previous studies with AFLP analysis, themajority of VREF isolates were grouped into four different lineages,designated genogroups A through D (33). The majority of theisolates investigated by MLST also were grouped into four correspondinglineages. In contrast to previous studies, this study includedVSEF isolates, and the majority of these isolates belonged toone of the four lineages established by typing of VREF isolates.The VSEF isolates were overall genetically more diverse thanthe vanA-carrying isolates. However, this difference was largelydue to a few genetically highly divergent isolates not belongingto lineages A through D.

Assuming that the dissemination of the vanA gene among E. faeciumstarted with the introduction of vancomycin and related antibioticsabout only 40 years ago implies that vanA was rapidly disseminatedamong the four main lineages of E. faecium. Dissemination ofvancomycin resistance in E. faecium has been extensively describedand is mediated by the intercellular spread of self-transferableplasmids and conjugative transposons harboring vancomycin resistancegenes (2).

In this study, we included only representative isolates fromhospital outbreaks and excluded other isolates that were epidemiologicallyrelated to any of these outbreaks. Nevertheless, 78% (64 of82) of the VREF isolates shared allelic profiles, whereas only22% (9 of 41) of the VSEF isolates did so. Although the numberof isolates included in this study was small, these data suggeststrongly that vancomycin-resistant isolates recently spreadepidemically. Because isolates with shared allelic profilesoriginated from different countries and continents, this disseminationis worldwide.

It was previously shown that epidemic strains are exclusivelyfound within AFLP genogroup C, share allele purK1, and carrythe esp gene, irrespective of the country of origin (32). Inthe current study, all epidemic VREF strains were found in MLSTlineage C1, which is characterized by allele purK1, and allshare the esp gene, confirming the classification based on AFLPanalysis. The remaining hospitalized human-derived strains presentin lineages A, B, and C were taken from clinical sites or obtainedfrom fecal screenings and did not have a known relationshipto outbreaks. Most likely, a subpopulation of lineage C gaverise to an epidemic VREF subpopulation, equipped with virulencefactors such as esp, enabling E. faecium to preferentially colonizeand spread in hospitalized human patients worldwide (28, 29,32).

The previously observed relationship between VREF genogroupand host was confirmed in this study. In addition, this studyindicates that this relationship holds true for VSEF as well.This result is not unexpected, because the introduction of themobile vancomycin resistance genes into the E. faecium populationwould not be expected to affect a preexisting specific host-bacteriumrelationship, which presumably is the result of long-term coevolutionof the bacterium and host.

Single-locus phylogenetic trees were noncongruent, suggestingthat recombination plays an important role in the generationof diversity of the E. faecium population. Consistently, basedon I_as between alleles, random association between gene lociwas detected at the level of STs but not at the level of isolates,suggesting that E. faecium has an epidemic population structure(30). Because the VSEF population was in linkage equilibriumat the level of all isolates (when divergent isolates were excluded),the epidemic population structure seems to be mainly due tolineages in the resistant population. These results suggestthat horizontal transfer of genetic information in E. faeciumplayed a role in long-term evolution, while clonal lineagesemerged and disseminated recently as a consequence of antibioticpressure. Confirmation of the importance of recombination forthe generation of alleles in housekeeping genes from E. faeciumwas derived from a sequence-based approach described by Feilet al. (13). Enterococci contain several efficient systems forexchanging genetic information, including pheromone-responsiveplasmids, broad-host-range plasmids, and conjugative transposons.Horizontal transfer of resistance genes in enterococci withthese systems is well documented (16). In addition, horizontaltransfer of tuf housekeeping genes encoding elongation factorTu, involved in protein synthesis, among enterococci was recentlyreported (19).

The E. faecium MLST scheme developed in this study providesa universal and portable method for isolate typing and addressinglong-term epidemiological questions. Laboratories worldwidecan build a virtual isolate collection that will enable disclosureof the emergence of epidemic clones that may be disseminatedamong different hospitals in different countries and continents.By comparison of patient-related information with moleculargenetic data, novel genetic lineages with specific propertiesrelating to pathogenicity and epidemiology may be revealed.

ACKNOWLEDGMENTS

J. Davis, M. Veitch, J. Straughan, N. Cooper, M. Whipp, andA. Zaia from the MDU are sincerely thanked for their valuableinput, as are Z. Manztioros and P. L. Soong from the Departmentof Microbiology and Immunology, University of Melbourne, andMarga van Santen-Verheuvel and Janetta Top from the NationalInstitute of Public Health and the Environment. The Australiananalysis would not have been possible without support from theVictorian Department of Human Services and the generous cooperationof a network of clinical microbiology laboratories. We thankLeo Schouls (National Institute of Public Health and the Environment)for critical review of the manuscript and Brian Spratt for welcomeassistance.

FOOTNOTES

* Corresponding author. Mailing address: Research Laboratory for Infectious Diseases (LIO), National Institute of Public Health and the Environment (RIVM), P.O. Box 1, 3720 BA Bilthoven, The Netherlands. Phone: 31.30.2742909. Fax: 31.30.2744449. E-mail: wieger.homan{at}rivm.nl.

REFERENCES

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