Microbiology Department, Hôpital Ambroise Paré, AP-HP and Faculté de Médecine Paris-Ouest, Université Paris V, 9 avenue Charles de Gaulle, 92100 Boulogne-Billancourt, France
Received 2 January 2002; returned 25 March 2002; revised 9 May 2002; accepted 31 May 2002
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Abstract |
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Introduction |
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In recent times, these already multidrug-resistant organisms have been shown to be able to develop resistance to the last antibiotic family to which they were still susceptible, the glycopeptides. The history of S. aureus with reduced susceptibility to glycopeptides (GISA) began with the discovery of clinical isolates with intermediate susceptibility to teicoplanin. The first case, described in 1990, concerned an isolate susceptible to methicillin (MSSA), whereas the second case, in 1995, concerned clonally related strains of MRSA isolated in inpatients of a French hospital.2,3 The publication of sporadic MRSA isolates less susceptible to both vancomycin and teicoplanin, first in Japan,4 then in the USA5,6 and finally in France,7 triggered deep concern in the international medical community, because glycopeptides have been the drug of choice and commonly the sole antimicrobial agent available for the treatment of multiple-resistant S. aureus isolates for the past 15 years.8,9
The concern in the medical community was enhanced by the microbiologists uncertainty about the tests routinely used to detect GISA isolates, which did not seem to be reliable.10 The microbiological analysis performed by Sieradzki et al.6 on three MRSA isolates, obtained consecutively over a period of 3 months from a haemo-dialysed patient repeatedly treated with vancomycin, showed that a subpopulation which required a higher inhibitory concentration of vancomycin (MIC 16 mg/L) could be selected in vitro from the last isolated MRSA strain, which was less susceptible to vancomycin (MIC 8 mg/L). Moreover, they demonstrated that MRSA isolates collected in their hospital and clonally related to the MRSA isolates of the haemo-dialysed patient also contained subpopulations of bacteria for which the MIC of vancomycin was greater than that required by the majority of bacterial cells.6 A systematic search for such hetero-VISA subpopulations in MRSA isolates was recently performed by the Central Public Health Laboratory for epidemiological typing in the UK, and among S. aureus in general by the French National Reference Centre in France.11,12 Approximately three-quarters of the MRSA strains studied in the UK from May 1998 to April 1999 belonged to one or other of the two principal UK epidemic strains (EMRSA-15 and EMRSA-16), whereas those studied in France were representative of strains prevalent in France between 1987 and 1997. In the UK, no hetero-VISA were found in the above-mentioned study, whereas in France hetero-VISA were found in six of 11 gentamicin-resistant MRSA strains, but not in gentamicin-susceptible MRSA strains.11,12
In our hospital, we were faced with an outbreak of MRSA with reduced susceptibility to teicoplanin (GISA) between January and March 2000, involving six patients who were hospitalized in three different wards and who were free of MRSA infection and colonization when the GISA isolate emerged. These GISA isolates belonged to the gentamicin-resistant MRSA group, which are still isolated nowadays in our hospital, although their frequency has decreased continuously for the past 5 years.13
We decided to investigate this outbreak, which was suspected, on the basis of the clinical data, to be due to the spread of the same strain, by using two typing methods: pulsed-field gel electrophoresis (PFGE) and multilocus sequence typing (MLST). The PFGE typing method, which is the technique usually applied to type multiple-resistant MRSA isolates, generally classifies such isolates into one or few clones.1416 Consequently, by this technique it is difficult to prove that an outbreak results from the transmission of the same strain. For this reason, we also used the MLST method, which has been shown to be able to characterize a clone in an MRSA population.17,18 Indeed, by sequencing an internal fragment of seven unlinked housekeeping genes, allelic profiles can be determined, and a clone is defined as a group of isolates having a strictly identical sequence of all seven genes.18 This method has the advantage of not succumbing to interpretative ambiguities, as is the case for the PFGE technique.1921
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Materials and methods |
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Six patients were involved in an outbreak of GISA infec- tion or colonization (Table 1). The epidemiological graph (Figure 1) shows overlapping stays of patients 1 and 2, then patients 2 and 4 in the digestive surgery ward, and patients 1, 4 and 5, then patients 1, 5 and 6 in the surgery intensive care unit (ICU) of the Ambroise Paré hospital. Patient 3, who was being hospitalized in the orthopaedic ward when the GISA isolate was obtained from hip prosthesis haematoma, had spent 2 days in the digestive surgery ward before being transferred to the orthopaedic ward. This stay was concomitant to that of patient 2, who was hospitalized in the same unit of the digestive surgery ward as patient 3, and who was found, 5 days after the transfer of patient 3 to the orthopaedic ward, to have a GISA urinary tract infection.
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The isolation barriers that have been set up for the last 5 years in all wards of the hospital for MRSA colonized or infected patients were reinforced at the end of February in the surgery ICU when the second case appeared in this unit. The last GISA isolation took place in this unit at the beginning of March.
Bacterial strains
The first one of several GISA clinical isolates of each of the six patients was studied (Figure 1; Table 1). Six multiple-resistant MRSA isolates that were apparently susceptible to glycopeptides, and that were isolated up to 5 years before this outbreak (historical isolates) in our hospital (isolate LEV, 1996; isolates PEY and SOP, 1997; isolate BEC, 1998; and isolates VIL and PAG, 1999), and the methicillin-resistant S. aureus reference strain COL22 were also studied by the same means with regard to their antibiotic susceptibility and their molecular typing profile (Table 1).
Antibiotic susceptibility
Antimicrobial susceptibility was determined by the agar disc diffusion method on MuellerHinton agar (bioMérieux, Marcy lÉtoile, France) according to the recommendations of the French Antibiogram Committee.23 The antibiotics (Bio-Rad, Marne la Coquette, France) tested were: penicillin G, oxacillin, erythromycin, lincomycin, tetracycline, chloramphenicol, gentamicin, trobramycin, amikacin, rifampicin, pefloxacin, fusidic acid, sulfamethoxazole, trimethoprim, co-trimoxazole, fosfomycin, vancomycin and teicoplanin. The breakpoint for glycopeptide susceptibility was an inhibition zone diameter 17 mm. For diameters <17 mm, the French Antibiogram Committee recommends that the MIC is determined.23
The MICs of vancomycin and teicoplanin were determined by the Etest system (AB Biodisk, Solna, Sweden), and by agar (French Antibiogram Committee) and broth (NCCLS) dilution methods.23,24 Etest was carried out in three independent assays on MuellerHinton agar with an inoculum of 105 cfu/mL (0.5 McFarland). The MICs of vancomycin and teicoplanin were read after 24 and 48 h of incubation at 37°C according to the recommendations of the manufacturer. A triplicate determination of teicoplanin (Hoechst Marion Roussel, Romainville, France) and vancomycin (Lilly, Saint Cloud, France) MICs was performed on MuellerHinton agar using a Steers replicator with an inoculum of 104 cfu/spot. The determination of the MICs according to NCCLS standards was carried out in liquid medium (MuellerHinton broth; bioMérieux). All MIC methods were interpreted according to the recommendations of the French Antibiogram Committee.23
Molecular typing systems
PFGE was carried out using the GenePath system with a CHEF DRII apparatus (Bio-Rad Laboratories), as described previously.19 Briefly, SmaI-digested DNA was separated for 20 h with a current range of 100135 mA and an angle of 120°. The profile interpretation was performed according to Tenover et al.19
MLST analysis was carried out as described previously, including internal fragments of the following seven housekeeping genes: arcC (carbamate kinase), aroE (shikimate dehydrogenase), glpF (glycerol kinase), gmk (guanylate kinase), pta (phosphate acetyltransferase), tpi (triosephosphate isomerase) and yqiL (acetyl coenzyme A acetyltransferase).17 For specific DNA amplification of an 450 bp fragment of each of these genes, the primer sequences given at the MLST website were used (http://www.mlst.net/dbqry/saureus.htm). Sequencing was performed by the big dye technique with an ABI Prism sequencer (Applied Biosystems, Courtaboeuf, France). The profile analysis was carried out with the S. aureus MLST website scheme (multiple locus query and allelic profile query) (http://www.mlst.net/dbqry/saureus.htm).
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Results |
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Salient clinical data concerning the six patients involved in the GISA outbreak are presented in Table 2. Three patients had been hospitalized for surgery of colon adenocarcinoma, and two patients for acute pancreatitis. Patient 3 had been admitted following an accidental hip fracture. All patients except patient 3 had received non-glycopeptide antibiotics prior to the isolation of the GISA. Patients 15 were infected by the GISA isolate, whereas patient 6 became a chronic nasal carrier of the GISA isolate. This patient did not receive anti-staphylococcal treatment and recovered without further septic complications.
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The infection of patients 1 and 2 was cured and both patients recovered and left the hospital, one of them having become a chronic carrier of the GISA isolate. In patient 3 the infection was cured, but the patient died of heart failure. Patient 4 was cured of his infection and recovered, whereas patient 5 died of septic shock (Table 2).
Antibiotic susceptibility
The six isolates obtained from the six patients involved in the outbreak, and the six historical MRSA isolates, which all belonged to the gentamicin-resistant MRSA group, were susceptible only to chloramphenicol, fusidic acid, trimethoprim and sulfamethoxazole, with one exception among the historical isolates (isolate PEY 1997), which was additionally susceptible to erythromycin, lincomycin and fosfomycin.
The size of the inhibition zone diameter for teicoplanin was <17 mm for all outbreak isolates, but 17 mm for the historical MRSA isolates, whereas that for vancomycin was
17 mm in all cases (Table 3). The MRSA reference strain COL was susceptible to teicoplanin and vancomycin according to the critical inhibition zone diameters (Table 3).
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One of the historical MRSA isolates (SOP 1997) was found to be completely susceptible to teicoplanin and vancomycin by Etest and agar dilution (MICs 2 and 4 mg/L, respectively), but intermediately susceptible to teicoplanin by the broth dilution method (MIC 6 mg/L). The MIC of teicoplanin for isolates PAG (1999), BEC (1998), PEY (1997) and LEV (1996) was found to be in the intermediately susceptible range by the Etest and agar dilution methods (MICs 816 mg/L), but two of them [PAG (1999) and LEV (1996)] were found to be susceptible (MIC 4 mg/L) by the broth dilution method. For the last historical isolate [VIL (1999)], the MIC of teicoplanin was 32 mg/L by Etest, 8 mg/L by agar dilution and 14 mg/L by broth dilution (Table 3).
Molecular typing
PFGE. As shown in Figure 2, five of the six outbreak isolates (lanes 14 and 6) displayed an identical SmaI-restricted PFGE profile (profile A). The profile of the isolate of patient 4 (lane 5) differed from profile A by two bands (profile A1) (Figure 2; Table 4).
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MLST. All six outbreak isolates displayed an identical MLST profile for the seven housekeeping genes, namely 3-3-1-12-4-4-16 for the genes arcC (allele 3), aroE (allele 3), glpF (allele 1), gmk (allele 12), pta (allele 4), tpi (allele 4) and yqiL (allele 16), respectively. This MLST allelic profile was also found for all six historical MRSA isolates.
Concerning MRSA strain COL, the nucleotide sequences of the seven housekeeping genes were obtained by BLAST of the MLST reference sequence from the Institute for genomic research (TIGR) website (http://www.tigr.org/tdb/mdb/mdbinprogress.html), where the sequencing project of strain COL is currently underway. The sequence obtained for its seven genes arcC, aroE, glpF, gmk, pta, tpi and yqiL was identified with 100% identity to the sequence of alleles 3-3-1-1-4-4-16, respectively. Neither allelic profile is included in the MLST website database.
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Discussion |
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The clinical and epidemiological data strongly suggested that the isolation of the GISA isolates from the six patients resulted from the transmission of the same strain. Classically, molecular typing systems are used to confirm the clonal relatedness of outbreak isolates. For S. aureus the reference typing system is PFGE. However, for MRSA, it has been shown that PFGE profiles of epidemiologically unlinked isolates yielded remarkable uniformity due to the geographic dissemination of MRSA.14,15,2527 Our study confirmed this finding, as the six historical isolates, which were unlinked to each other and to the six outbreak isolates, displayed identical or similar PFGE profiles. Overall, according to the PFGE clone definition established by Tenover et al.,19 the six outbreak isolates, the six historical isolates and MRSA reference strain COL are the same clone. By using the MLST technique, we definitively confirmed that the outbreak and historical isolates belonged to the same clone, whose allelic profile corresponds to that of the Iberian MRSA clone HPV107 (MLST 3-3-1-12-4-4-16), which was recently identified in several MRSA isolates belonging to this clone.26,28 This clone, which has previously been found among several historical strains isolated in Denmark between 1964 and 1969, has spread from Portugal and Spain to Belgium and France since the beginning of the 1990s.27,29
Regarding the MLST profile of the MRSA reference strain COL (3-3-1-1-4-4-16), it represents a single locus variant of the MLST profile of the Iberian clone, which was also identified in several Iberian MRSA isolates such as the Spanish isolate PER34 and several MRSA strains isolated in the UK during the years 19601963.26,28,30 However, the allelic profile of strain COL has also been identified in several S. aureus strains susceptible to methicillin (MSSA), whereas the allelic profile of our clinical isolates has only been found in MRSA.26
The MLST method allowed us to confirm unambiguously what has been suspected on the basis of PFGE results before,29 namely the spread of the Iberian clone HPV107 in France, and our study demonstrates that strains belonging to this clone became less susceptible to teicoplanin.
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Footnotes |
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References |
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