VanB表型-vanA基因型VRE分子特征及遗传背景研究

目的 探讨VanB表型-vanA基因型VRE耐药转座子结构、分子特征及遗传背景,并与VanA表型-vanA基因型VRE进行比较分析,以确定基因型与表型不一致的形成机制.方法 收集2008年3月至2009年1月卫生部北京医院临床标本中21株VRE菌株,用Etest法对10种抗生紊进行MIC测定,并通过PCR、序列测定、接合试验、耐药转座子结构、PFGE及MLST进行分子特征和遗传背景研究.结果 21株VRE均为vanA基因型,其中3株菌呈现VanB表型(万古霉素耐药,替考拉宁敏感);21株菌属于9个不同PFGE型,6个不同MIST型;多对引物对转座子的不同区域PCR扩增并进行序列拼接、比对,发现Tn1546结构中vanX、vanY的缺失及ISEfa4的插入与VanB表型-vanA基因型VRE菌株形成相关.结论 VanB表型-vanA基因型VRE菌株在国内较为罕见,Tn1546结构的改变与菌株的基因型与表型不一致相关.     

A new Tn1546 type of VanB phenotype–vanA genotype vancomycin-resistant Enterococcus faecium isolates in mainland China

VanB phenotype–vanA genotype vancomycin-resistant Enterococcus faecium (VREF) has never been reported in mainland China. We investigated the frequency and molecular characteristics of this strain in a Beijing tertiary hospital. Of 23 vanA genotype VREF clinical isolates, 12 (54.3%) were VanB phenotype–vanA genotype. Mutilocus sequence typing (MLST) analysis revealed that all isolates belong to a single clonal complex (CC78), which has been disseminated worldwide. Based on MLST and pulsed-field gel electrophoresis, 23 isolates were polyclonal dissemination in our hospital. Tn1546-like element structure analysis showed that of 12 VanB phenotype–vanA genotype isolates, 5 had complete deletion of vanY and vanZ accompanying insertion of IS1216V in vanX–vanY intergenic region, 5 had ISEfa4 insertion in orf2–vanR intergenic region, a new Tn1546 structure type, and 2 were identical to VanA phenotype–vanA genotype VREF. Data showed that the deletion of vanY and vanZ genes or ISEfa4 insertion in orf2–vanR intergenic region can partly explain the causes of difference between phenotype and genotype.     

Intra-hospital dissemination of quinupristin/dalfopristin- and vancomycin-resistant Enterococcus faecium in a paediatric ward of a German hospital

OBJECTIVES: To demonstrate nosocomial transmission of Enterococcus faecium resistant to quinupristin/dalfopristin and vancomycin/teicoplanin among paediatric patients in a German hospital ward. MATERIALS AND METHODS: Multiply-resistant E. faecium were isolated from three female patients aged 9 months, 2 and 15 years during a 10 day time span. Antibiotic susceptibilities were determined by microbroth dilution. Clonal relatedness among the isolates was investigated via SmaI-macrorestriction analysis by PFGE, multilocus sequence typing (MLST), and plasmid profiling. Presence of virulence and resistance determinants was tested by polymerase chain reaction (PCR). Selected resistance genes were localized by Southern hybridizations. RESULTS: A single E. faecium isolate per patient was investigated. All exhibited resistances to quinupristin/dalfopristin, vancomycin/teicoplanin, streptomycin (high-level), penicillin/ampicillin, erythromycin, oxytetracycline, chloramphenicol, rifampicin and fusidic acid. The isolates were susceptible to linezolid only and intermediately resistant to fluoroquinolones including moxifloxacin. PFGE revealed identical patterns for all three isolates. PCRs for virulence determinants hyaluronidase and enterococcal surface protein, esp, were negative, whereas PCR for the enterocin A gene was positive. MLST identified clonal type [8-5-1-1-1-1-1] belonging to a clonal subgroup C1 of hospital- and outbreak-related E. faecium. Southern hybridizations located several resistance genes (erm(B), vat(D), vanA) on a large plasmid, which was transferable in mating experiments with an E. faecium recipient. CONCLUSIONS: These data show routes of dissemination of resistance to multiple antibiotics including streptogramins and glycopeptides in E. faecium via vertical and/or horizontal gene transfer. The isolates spread in the absence of a direct selective pressure, as none of the patients had received earlier streptogramin or glycopeptide therapy.     

Comparison of Glycopeptide-Resistant Enterococcus faecium Isolates and Glycopeptide Resistance Genes of Human and Animal Origins

One hundred thirty-two glycopeptide-resistant Enterococcus faecium (GREF) isolates from different hospitals and pig and poultry farms in Belgium were compared on the basis of (i) their antibiotic susceptibilities, (ii) their SmaI pulsed-field gel electrophoresis (PFGE) patterns, and (iii) the organization of their Tn1546 or related elements in order to detect possible phenotypic and genotypic relationships among both groups of isolates. Human and animal vanA-positive GREF isolates were found to have similar susceptibility patterns; they remained susceptible to gentamicin and were, in general, susceptible to ampicillin. PFGE demonstrated a very high degree of genomic heterogeneity in both groups of isolates. However, indistinguishable isolates were found within different farms or hospitals, and in two instances, epidemiologically unrelated pig and human isolates showed indistinguishable PFGE patterns. In total, eight different transposon types were identified, and all were related to the prototype transposon Tn1546. The two predominant types, Tn1546 and type 2 transposons, which differed at three band positions, were present in both human and animal isolates. Type 2 transposons were significantly associated with pig isolates. The other types were seldom detected. These data suggest a possible exchange of glycopeptide resistance markers between animals and humans.     

Glycopeptide susceptibility among Danish Enterococcus faecium and Enterococcus faecalis isolates of animal and human origin and PCR identification of genes within the VanA cluster.

The MICs of vancomycin and avoparcin were determined for isolates of Enterococcus faecium and isolates of Enterococcus faecalis recovered from the feces of humans and animals in Denmark. Two hundred twenty-one of 376 (59%) isolates of E. faecium and 2 of 133 (1.5%) isolates of E. faecalis were resistant to vancomycin (MICs, 128 to > or = 256 micrograms/ml), and all vancomycin-resistant isolates were resistant to avoparcin (MICs, 64 to > or = 256 micrograms/ml). All vancomycin-resistant isolates examined carried the vanA, vanX, and vanR genes, suggesting that a gene cluster similar to that of the transposon Tn1546 was responsible for the resistance.     

Vancomycin-resistant enterococci (VRE) colonization of high-risk patients in tertiary care Canadian hospitals. Canadian VRE Surveillance Group.

We isolated 1487 Enterococcus species from 1200 stool specimens collected from high-risk patients in 12 Canadian tertiary care hospitals between October 1995 and November 1996. The composition of the 1487 isolates was 601 vancomycin-sensitive Enterococcus faecalis (40.4%), 667 vancomycin-sensitive Enterococcus faecium (44.9%), 18 vancomycin-resistant (nine isolates MIC 8-16 micrograms/mL; nine isolates MIC > or = 32 micrograms/mL) E. faecium (VREF) (1.2%), 95 vancomycin-sensitive Enterococcus gallinarum (6.4%), 29 vancomycin-resistant (all MICs 8-16 micrograms/mL) E. gallinarum (2.0%), and 77 vancomycin-sensitive Enterococcus casseliflavus (5.2%). Nine of the 18 VREF isolates collected possessed the vanA genotype and were from three patients at one hospital. Two other VREF isolates, of the vanB genotype, were from a single patient at a second hospital, and the remaining seven isolates, also all of the vanB genotype, were from five patients at a third hospital. All VREF were ampicillin resistant (MIC > or = 16 micrograms/mL), streptomycin resistant (MIC > 1000 micrograms/mL), and ciprofloxacin resistant (MIC > or = 4 micrograms/mL). Ten of the 18 VREF were also resistant to gentamicin (MIC > 500 micrograms/mL), while all 18 isolates had quinupristin/dalfopristin MICs < or = 0.5 microgram/mL. In conclusion, high-risk patients in tertiary care Canadian hospitals are rarely colonized (9/1200 patients, 0.75%) with VREF in their lower gastrointestinal tract. These findings correlate well with the lack of reported VREF infection in high-risk patients in Canadian hospitals. Quinupristin/dalfopristin demonstrated excellent in vitro activity against VREF and other non-faecalis species of Enterococcus, many of which also possessed high-level ampicillin, and/or high-level aminoglycoside, and/or ciprofloxacin resistance.     

Loss of vancomycin resistance not completely dependent on the Tn1546 element in Enterococcus faecium isolates

We investigated characteristics of 3 Enterococcus faecium strains (SHY-1, SHY-2, and SHY-3) isolated successively from 1 patient. In vitro susceptibility testing was performed using broth microdilution method. Change of vancomycin MIC was monitored during incubation with vancomycin for SHY-3 strain. Genetic backgrounds were determined both by multilocus sequence typing (MLST) and pulsed-field gel electrophoresis (PFGE). In addition, the genetic variations among Tn1546 element were investigated by polymerase chain reaction (PCR) assay and sequencing. vanA and vanX expression of 3 strains was evaluated using quantitative real-time (qRT)-PCR method. Although all the strains possessed the vanA gene, SHY-3 was susceptible to glycopeptides, while SHY-1 and SHY-2 were resistant to glycopeptides. Judged by MLST and PFGE, 3 strains have the same genetic background. The vancomycin resistance of SHY-3 was not recovered after exposure to vancomycin. The vanA and vanX genes were expressed in strains SHY-1 and SHY-2 but not in strain SHY-3, although the SHY-2 and SHY-3 strains shared the same arrangement of the van gene cluster, a common 88-bp deletion in vanS gene. Our results indicate that vancomycin resistance might not be completely dependent on the Tn1546 element.     

Enterococci of animal origin and their significance for public health

Enterococci are commensal bacteria in the intestines of humans and animals, but also cause infections in humans. Most often, Enterococcus faecium isolates from clinical outbreaks belong to different types than E. faecium from animals, food, and humans in the community. The same variants of the vanA gene cluster (Tn1546) encoding vancomycin resistance can be detected in enterococci of both human and animal origin. This could indicate horizontal transfer of Tn1546 between enterococci of different origin. E. faecium isolates of animal origin might not constitute a human hazard in themselves, but they could act as donors of antimicrobial resistance genes for other pathogenic enterococci. Enterococcus faecalis of animal origin seems to be a human hazard, as the same types can be detected in E. faecalis from animals, meat, faecal samples from humans in the community, and patients with bloodstream infections.     

Relationship between copper, glycopeptide, and macrolide resistance among Enterococcus faecium strains isolated from pigs in Denmark between 1997 and 2003

A significant relationship between copper resistance (tcrB), glycopeptide resistance (Tn1546), and macrolide resistance [erm(B)] in Enterococcus faecium isolated from pigs was found. The tcrB gene was located closely upstream of the Tn1546 element. However, the continued use of copper sulfate has not been able to maintain high levels of macrolide and glycopeptide resistance.     

Identification of chromosomal mobile element conferring high-level vancomycin resistance in Enterococcus faecium.

A clinical isolate of Enterococcus faecium that contains a chromosomally encoded vanA gene cluster, Tn1546::IS1251, transferred vancomycin resistance to the plasmid-free strain Enterococcus faecalis JH2-2 during filter matings. Hybridization of a vanHAXY probe to SmaI restriction-digested genomic DNA separated by pulsed-field gel electrophoresis showed that the vanA gene cluster was located on a 40-kb fragment in the original donor strain and on fragments of different sizes (150 to 450 kb) in the transconjugants. No hybridization to vanA gene cluster probes was obtained with plasmid DNA preparations from the donor or transconjugants. These results suggested that in each case, the van genes had integrated into the recipient chromosome. The transconjugants in turn could act as donors of vancomycin resistance, and resistance was transferable to a Rec- recipient. The results of restriction analyses and DNA hybridizations of genomic DNA from the donor and transconjugants were consistent with the transfer of a mobile element that includes the 12.3-kb Tn1546::IS1251 gene cluster and at least 13 kb of additional DNA. This element has been tentatively designated Tn5482. DNA sequence analysis of a fragment predicted to contain the left end of Tn5482 revealed two insertion sequence-like elements: IS1216V and an apparently truncated IS3-like element. Restriction mapping and DNA hybridization patterns of the van gene clusters of three additional clinical isolates from New York City showed an element similar to Tn5482. Transfer of Tn5482 and related elements may be involved in dissemination of vancomycin resistance.     

Comparison of Tn1546-like elements in vancomycin-resistant Staphylococcus aureus isolates from Michigan and Pennsylvania

In 2002, the first two clinical isolates of vancomycin-resistant Staphylococcus aureus (VRSA) containing vanA were recovered in Michigan and Pennsylvania. Tn1546, a mobile genetic element that encodes high-level vancomycin resistance in enterococci, was present in both isolates. With PCR and DNA sequence analysis, we compared the Tn1546 elements from each isolate to the prototype Tn1546 element. The Michigan VRSA element was identical to the prototype Tn1546 element. The Pennsylvania VRSA element showed three distinct modifications: a deletion of nucleotides 1 to 3098 at the 5' end, which eliminated the orf1 region; an 809-bp IS1216V-like element inserted before nucleotide 3099 of Tn1546; and an inverted 1,499-bp IS1251-like element inserted into the vanSH intergenic region. These differences in the Tn1546-like elements indicate that the first two VRSA isolates were the result of independent genetic events.     

Outbreak of hospital-adapted clonal complex-17 vancomycin-resistant Enterococcus faecium strain in a haematology unit: role of rapid typing for early control

OBJECTIVES: To describe the investigation and molecular characterization of a vancomycin-resistant Enterococcus faecium (VREF) strain responsible for a nosocomial outbreak in the haematology unit of a tertiary-care university hospital. PATIENTS AND METHODS: Two patients admitted to the haematology unit developed infection/colonization with VREF over a 3 month period when compared with none in the 2 previous years. On the basis of the identification of a clonal link between these two strains, weekly rectal screening was implemented for all patients in the haematology unit and contact precautions were extended to VREF carriers. In the following 6 month period, 11 patients colonized with VREF were detected. No further case was detected in the following 1 year period. RESULTS: VREF isolates from the haematology unit carried the vanA gene and were multiresistant to antimicrobial agents, including high-level resistance to vancomycin, teicoplanin and ampicillin. This resistance profile restricted the choice of antimicrobial therapy to linezolid or investigational drugs such as tigecycline. Molecular analysis showed that 11 of 13 (85%) VREF isolates belonged to pandemic clonal complex-17 carrying the esp and hyl virulence genes. CONCLUSIONS: Rapid typing and infection control measures, including early reinforcement of barrier precautions combined with weekly rectal surveillance cultures, were followed by control of nosocomial spread of this VREF clone.     

Molecular characterization of glycopeptide-resistant Enterococcus faecium isolates from Portuguese hospitals

Fifty-one pulsed-field gel electrophoresis types and 17 Tn1546 variants were identified among 101 Enterococcus faecium isolates recovered in three distant Portuguese hospitals. Intra- and interhospital dissemination of specific strains and Tn1546 types was detected, which might largely contribute to the endemicity of vancomycin-resistant E. faecium in Portuguese hospitals, as happened previously in other geographical locations.     

Antibiotic activity against urinary tract infection (UTI) isolates of vancomycin-resistant enterococci (VRE): results from the 2002 North American Vancomycin Resistant Enterococci Susceptibility Study (NAVRESS)

BACKGROUND: The purpose of this study was to assess the prevalence of vancomycin-resistant enterococci (VRE) in urinary isolates in North America, and the activity of various antibiotics against VRE. MATERIALS AND METHODS: Twenty-eight medical centres in the United States and 10 centres in Canada assessed the prevalence of VRE in urinary isolates in 2002. Each study site was asked to collect up to a maximum of 50 consecutive VRE (Enterococcus faecium, Enterococcus faecalis only) urinary isolates. Susceptibility was determined by NCCLS broth microdilution. The prevalence of vanA and vanB resistance genotypes was determined by multiplex PCR. RESULTS: From the 28 US medical centres, a total of 697 VRE (616 [88.4%] E. faecium and 81 [11.6%] E. faecalis) were received. Approximately 75% of all VRE (E. faecium and E. faecalis) isolates demonstrated a VanA phenotype (resistance to both vancomycin and teicoplanin). PCR detection of vanA and vanB resistance determinants showed that the vanA genotype was present in 584 of 697 (83.8%) VRE isolates, whereas 113 (16.2%) isolates possessed the vanB gene. The most active agents were linezolid, nitrofurantoin and chloramphenicol, with 0.3%, 0.6% and 2.4% resistance, respectively. The majority (77.8%) of vancomycin-resistant E. faecium isolates displayed the VanA phenotype, and 538 of these 616 (87.3%) isolates were PCR-positive for vanA; the vanB genotype was detected in 78 (12.7%) isolates. Resistance was lowest with linezolid, chloramphenicol and nitrofurantoin at 0.3%, 0.3% and 0.5%, respectively. Only three genetically indistinguishable vanA-positive E. faecium were isolated from the 10 Canadian medical centres. CONCLUSION: VRE urinary isolates are common in the United States, are primarily of the vanA genotype and are very susceptible to linezolid, nitrofurantoin and chloramphenicol. In Canada, VRE urinary isolates remain uncommon.     

Transposon characterization of vancomycin-resistant Enterococcus faecium (VREF) and dissemination of resistance associated with transferable plasmids

OBJECTIVES: VanA glycopeptide resistance has persisted on broiler farms in the UK despite the absence of the antimicrobial selective pressure, avoparcin. This study aimed to investigate the contribution of horizontal gene transfer of Tn1546 versus clonal spread in the dissemination of the resistance. METHODS AND RESULTS: One hundred and one vancomycin-resistant Enterococcus faecium isolated from 19 unrelated farms have been investigated. Tn1546 characterization by long PCR and ClaI-digestions of amplicons showed a very low diversity of Tn types (n=4) in comparison to the high genotypic diversity demonstrated by PFGE (n=62). Conjugation experiments were carried out to assess the transfer of vancomycin resistance. Co-transfer of vanA together with erm(B) positioned on the same conjugative plasmid containing a replicon similar to pRE25 was demonstrated and also the presence of different plasmid replicons, associated with antimicrobial resistance on several unrelated farms. CONCLUSIONS: Horizontal transfer of vancomycin resistance may play a more important role in the persistence of antimicrobial resistance than clonal spread. The presence of different plasmid replicons, associated with antimicrobial resistance on several unrelated farms, illustrates the ability of these enterococci to acquire and disseminate mobile genetic elements within integrated livestock systems.     

Molecular diversity and evolutionary relationships of Tn1546-like elements in enterococci from humans and animals

We report on a detailed study on the molecular diversity and evolutionary relationships of Tn1546-like elements in vancomycin-resistant enterococci (VRE) from humans and animals. Restriction fragment length polymorphism (RFLP) analysis of the VanA transposon of 97 VRE revealed seven different Tn1546 types. Subsequent sequencing of the complete VanA transposons of 13 VRE isolates representing the seven RFLP types followed by sequencing of the identified polymorphic regions in 84 other VanA transposons resulted in the identification of 22 different Tn1546 derivatives. Differences between the Tn1546 types included point mutations in orf1, vanS, vanA, vanX, and vanY. Moreover, insertions of an IS1216V-IS3-like element in orf1, of IS1251 in the vanS-vanH intergenic region, and of IS1216V in the vanX-vanY intergenic region were found. The presence of insertion sequence elements was often associated with deletions in Tn1546. Identical Tn1546 types were found among isolates from humans and farm animals in The Netherlands, suggesting the sharing of a common vancomycin resistance gene pool. Application of the genetic analysis of Tn1546 to VRE isolates causing infections in Hospitals in Oxford, United Kingdom, and Chicago, Ill., suggested the possibility of the horizontal transmission of the vancomycin resistance transposon. The genetic diversity in Tn1546 combined with epidemiological data suggest that the DNA polymorphism among Tn1546 variants can successfully be exploited for the tracing of the routes of transmission of vancomycin resistance genes.     

Transfer of plasmid and chromosomal glycopeptide resistance determinants occurs more readily in the digestive tract of mice than in vitro and exconjugants can persist stably in vivo in the absence of glycopeptide selection

OBJECTIVES AND METHODS: The transferability of vanA and vanB glycopeptide resistance determinants with a defined plasmid (n = 9) or chromosomal (n = 4) location between Enterococcus faecium strains of human and animal origins was compared using filter mating (in vitro) and germ-free mice (in vivo) as experimental models. Moreover, the stability of exconjugants in vivo in the absence of antibiotic selection was examined. RESULTS: Higher transfer rates were observed in vivo for four of six vanA and five of six vanB donor strains. For plasmid-encoded resistance, several log higher transfer frequencies were observed in vivo for some strains. Moreover, the in vivo model supported transfer of plasmid-encoded vanB (1 x 10(-7) exconjugants/donor) when repeated in vitro experiments were negative (estimated < 1 x 10(-9) exconjugants/donor). Readily detectable transfer of plasmid-located vanA and vanB as well as large chromosomal (>200 kb) vanB elements was observed after 24 h. The number of plasmid-mediated vanA exconjugants generally decreased markedly after 3 days. However, exconjugants containing a plasmid harbouring the vanA transposon Tn1546 linked to the post-segregational killing system omega-epsilon-zeta persisted stably in vivo in the absence of glycopeptides for more than 20 days. CONCLUSIONS: The overall results support the notion that the in vitro model underestimates the transfer potential. Rapid transfer of vanA plasmids from poultry- and pig-derived strains to human faecal E. faecium shows that even transiently colonizing strains may provide a significant reservoir for transfer of resistance genes to the permanent commensal flora. Newly acquired resistance genes may be stabilized and persist in new populations in the absence of antibiotic selection.     

氨基糖苷类高水平耐药肠球菌的耐药及分子机制的研究

目的分析氨基糖苷类高水平耐药（HighLevelAminoglyeosideResistant,HLAR）肠球菌的耐药性与耐药基因,并研究其耐药分子机制。方法采用VITEK-2全自动鉴定仪法测定53株氨基糖苷类高水平耐药肠球菌对11种抗菌药物的最小抑菌浓度,用聚合酶链反应（PCR）检测肠球菌转座子Tn917和Tnl546／Tn916、红霉素耐药基因er—mB、毒力岛基因mefA、I类整合酶Intll、氯霉素耐药基cat、表面蛋白基因esp,并对万古霉素耐药肠球菌（Vancomy—cin—resistantEnterococc,VRE）进行基因分型（vanA、vanB、vanC）。结果53株肠球菌检出含ermB26株,占49．0％;含mefA9株,占17．0％;含Tnl546／Tn91619株,占35．8％;含Tn91711株,占20．8％;含Intll26株,占49．1％;含esp15株,占28．3％;未检出cat。53株肠球菌对复方新诺明全部耐药,对红霉素耐药高达94．3％,对高水平庆大霉素、高水平链霉素、环丙沙星、四环素和氨苄西林的耐药率分别为75．5％、73．6％、75．5％、66．0％、62．3％;对利奈唑胺和替考拉宁的敏感率高达98．1％;1株耐万古霉素,其基因和表型均为VanA。结论HLAR肠球菌可携带多种耐药基因,耐药基因与肠球菌耐药性密切相关,可能在多重耐药机制中起重要作用。     

Molecular analysis of Tn1546-like elements mediating high-level vancomycin resistance in Enterococcus gallinarum

OBJECTIVES: Four Enterococcus gallinarum isolates, all highly resistant to vancomycin, were studied in order to investigate their relationship and to gain insight into the molecular events responsible for their acquired resistance. METHODS: Extensive molecular analysis was performed to compare the four E. gallinarum isolates and their Tn1546-like elements. RESULTS: The four strains had very similar random amplified polymorphic DNA (RAPD) patterns and different but related PFGE profiles. Genotypic analysis demonstrated that all carried both vanC-1 and vanA genes. Using a vanA probe, no hybridization was detected to plasmid DNA, whereas hybridization to different SmaI fragments of the four strains was obtained with total DNA. Amplification and sequencing experiments showed that all four strains carried a Tn1546-like element that contained the orf2, vanR, vanS, vanH, vanA and vanX genes and was flanked at both ends by oppositely oriented IS1216V sequences. On the left side of the vanA cluster, all lacked IRL, and all had, upstream from orf2, 1029 bp of the 3' end of orf1. On the right side, one of the strains lacked vanY, vanZ and IRR, whereas in one of the other three there was an IS1542 element inserted within the vanZ gene. In one strain, an additional IS1216V element was inserted in the intergenic region vanX-vanY. CONCLUSIONS: This is the first study providing a molecular analysis of chromosomal Tn1546-like elements (possibly composite transposons) associated with high-level vancomycin resistance in human and animal strains of E. gallinarum. These molecular findings, together with those from PFGE and RAPD, suggest that the four E. gallinarum isolates are related and might have a common ancestor.     

Heterogeneity of the vanA gene cluster in clinical isolates of enterococci from the northeastern United States.

In several strains of Enterococcus faecium isolated in Europe, the cluster of genes encoding high-level resistance to vancomycin (VanA phenotype) resides on a 10.85-kb transposon, Tn1546, or closely related elements. To determine whether Tn1546 was conserved in recent enterococcal isolates from the northeastern United States, seven strains were compared by restriction mapping and DNA hybridization with probes from within the van cluster. Two of the seven strains contained intact Tn1546-like sequences; however, in five of the strains, the organization of the van cluster differed from that of Tn1546. Three of the five strains with variations harbored a novel DNA segment within the van gene cluster. This 1,496-bp segment was similar to IS1165 of Leuconostoc mesenteroides and IS1181 of Staphylococcus aureus and was flanked by 24- and 23-bp imperfect inverted repeats and 8-bp direct repeats. On the basis of these findings, we propose that this element comprises a novel insertion-like sequence, IS1251. Multiple copies of IS1251 were also present at other sites in both resistant and susceptible clinical isolates. Our findings suggest that the van cluster in recent isolates from the northeastern United States differs from that present in the early European VanA phenotype strains.