Multiplex PCR Strategy for Rapid Identification of Structural Types and Variants of the mec Element in Methicillin-Resistant Staphylococcus aureus

Full characterization of methicillin-resistant Staphylococcusaureus (MRSA) requires definition of not only the bacterialgenetic background but also the structure of the complex andheterologous mec element these bacteria carry, which is associatedwith drug resistance determinant mecA. We report the development,validation, and application of a multiplex PCR strategy thatallows quick presumptive characterization of the mec elementtypes based on the structural features that were shown to betypical of mec elements carried by several MRSA clones. Thestrategy was validated by using a representative collectionof pandemic MRSA clones in which the full structure of the associatedmec elements was previously determined by hybridization andPCR screenings and also by DNA sequencing. The method was testedtogether with multilocus sequence typing and other typing methodsfor the characterization of 18 isolates representative of theMRSA clones recovered during a hospital outbreak in Barcelona,Spain. The multiplex PCR was shown to be rapid, robust, andcapable in a single assay of identifying five structural typesof the mec element among these strains, three major and twominor variants, each one of which has been already been seenamong MRSA characterized earlier. This technique should be auseful addition to the armamentarium of molecular typing toolsfor the characterization of MRSA clonal types and for the rapidtentative identification of structural variants of the mec element.

INTRODUCTION

Top

Introduction

Molecular typing techniques have been used with increasing frequencyin studies of the epidemiology of methicillin-resistant Staphylococcusaureus (MRSA) and also for a better understanding of the evolutionaryrelationships among MRSA clones (3, 7, 9, 26). One of the conclusionsemerging from these studies was that a complete characterizationof MRSA lineages requires not only identification of the geneticbackground of the bacteria but also identification of the structuraltypes of the large and heterologous mec element, which carriesmethicillin resistance determinant mecA (11, 26, 27).

Studies by Ito et al. have elucidated the complete structureof three major mec elements, also referred to as the staphylococcalchromosomal cassette (SCCmec). Type I (34 kb) was identifiedin the first MRSA strain isolated in 1961 in the United Kingdom(strain NCTC10442), type II (52 kb) was identified in an MRSAstrain isolated in 1982 in Japan (strain N315), and type III(66 kb) was identified in an MRSA strain isolated in 1985 inNew Zealand (strain 82/2082) (12, 13). More recently, a smallerfourth mec element, SCCmec type IV (20 to 24 kb), was independentlyidentified among representatives of the Pediatric clone (26)and in two community-acquired MRSA strains (18).

In a recent report we described the characterization of thestructural types of the mec elements carried by 28 MRSA isolatesbelonging to five widespread epidemic clones, which were allcharacterized by multilocus sequence typing (MLST) as single-locusor double-locus variants of two completely different geneticbackgrounds (26). The full structure of each mec element carriedby these MRSA isolates was determined by Southern blot analysisusing three restriction enzymes and several key probes specificfor each SCCmec type, by PCR detection of several loci coveringthe entire mec element structures, and by DNA sequencing, basedon the information described in references 12 and 13.

However, these methods are laborious and time-consuming. Inthis paper we describe a multiplex PCR strategy which was designedto detect the structural variations observed in the mec elementin our previous study. Such a method should provide a usefultool for the rapid tentative identification of the structuraltype of the mec elements in MRSA isolates.

MATERIALS AND METHODS

Top

Materials and Methods

Strain selection. The 26 strains used for the validation of the multiplex PCRwere selected from among MRSA isolates previously characterizedfor MLST profile and for the structural type of the mec element(26) (Table 1). Strains COL, N315, and ANS46 were included ascontrols for the three major structural types of mec elements,as previously described (26). Genome data from strain COL (www.tigr.org)indicate that this strain has a mec element identical to thatof strain NCTC10442, used by Ito et al. for the definition ofSCCmec I (13). Strain N315 was used in the definition of SCCmecII (13). The physical mapping of the mecA region of strain ANS46showed that it carried a mec element identical to that of SCCmecIII (5, 12). After validation, the multiplex PCR was appliedto the characterization of 18 representative isolates of MRSArecovered during an outbreak investigation in a hospital inBarcelona, Spain. These strains had been characterized earlierby pulsed-field gel electrophoresis (PFGE) (4).

View this table:
[in this window]
[in a new window]
TABLE 1. MRSA strains used for the validation of the multiplex PCR

DNA isolation. Chromosomal DNAs from three to five isolated colonies were preparedby using the Wizard genomic DNA preparation kit (Promega, Madison,Wis.), with lysostaphin at 0.5 mg/ml and RNase at 0.3 mg/mlfor the lysis step.

MLST and spaA typing. Molecular typing based on the sequences of seven housekeepinggenes (MLST) and the typing of the polymorphic region of proteinA (spaA typing) were performed according to previously describedprocedures (7, 25, 33).

Multiplex PCR for mec element type assignment. The multiplex PCR includes eight loci (A through H) selectedon the basis of previously described mec element sequences (12,13, 26) (Table 2). Also included in the protocol as an internalpositive control was the mecA gene. Locus A is located downstreamof the pls gene and is specific for SCCmec type I; locus B isinternal to the kdp operon, which is specific for SCCmec typeII; locus C is internal to the mecI gene present in SCCmec typesII and III; locus D is internal to the dcs region, present inSCCmec types I, II, and IV; locus E is located in the regionbetween integrated plasmid pI258 and transposon Tn554, specificfor SCCmec type III; locus F, which is also specific for SCCmectype III, is located in the region between Tn554 and the chromosomalright junction (orfX). Loci G and H were included to distinguishstructural variants IA and IIIA, respectively. Locus G is theleft junction between IS431 and pUB110, and locus H is the leftjunction between IS431 and pT181. Primers were designed manuallyand were commercially obtained (Gibco, Invitrogen Corporation,Carlsbad, Calif.). Primer length and GC contents were kept asuniform as possible in order to minimize differences in theannealing temperature and kinetics, and primer sequences werechecked for specificity against available S. aureus genomesand SSCmec sequences with the BLAST utility available throughthe National Center for Biotechnology Information website (www.ncbi.nlm.nih.gov).Amplicon sizes ranged from 162 to 495 bp, differing by at least40 bp in size from one another (Table 2).

View this table:
[in this window]
[in a new window]
TABLE 2. Primers used in the multiplex PCR

The optimization of the multiplex PCR followed the general principlesdescribed by Henegariu et al. (10). Each pair of primers wasfirst tested for amplification specificity and robustness atannealing temperatures of 55 and 60°C. For the multiplexPCR, we found it necessary to decrease the annealing temperature,increase the extension time, and adjust primer amounts for someloci. These alterations were tested empirically in small steps.The multiplex PCR was performed in a 50-µl volume withthe GeneAmp PCR kit (Applied Biosystems, Foster City, Calif.)containing the following: 1x PCR buffer II; 200 µM (each)deoxynucleoside triphosphate; 400 nM concentrations of primersCIF2 F2, CIF2 R2, MECI P2, MECI P3, RIF5 F10, RIF5 R13, pUB110R1, and pT181 R1; 800 nM concentrations of primers DCS F2, DCSR2, MECA P4, MECA P7, and IS431 P4; 200 nM concentrations ofprimers KDP F1, KDP R1, RIF4 F3, and RIF4 R9; 1.25 U of AmpliTaq;and approximately 5 ng of template DNA. PCR amplifications wereperformed in a DNA Thermal Cycler 480 (Applied Biosystems) withthe following parameters: predenaturation for 4 min at 94°C;30 cycles of 94°C for 30 s, 53°C for 30 s, and 72°Cfor 1 min; postextension for 4 min at 72°C; and soakingat 4°C. PCR products (10 µl) were resolved in a 2%SeaKem LE (BioWhittaker Molecular Applications, Rockland, Maine)agarose gel in 0.5x Tris-borate-EDTA buffer (Bio-Rad, Hercules,Calif.) at 100 V and visualized with ethidium bromide.

RESULTS AND DISCUSSION

Top

Results and Discussion

Multiplex PCR was first developed in 1988 by Chamberlain etal. (2). For staphylococci, this technique has been used tospecifically detect MRSA (1, 8, 16, 19, 21, 30, 36), to discriminatebetween S. aureus and coagulase-negative staphylococci togetherwith detection of oxacillin resistance (19, 21, 30), and todetect several resistance determinants (19, 20, 24) and staphylococcaltoxin genes simultaneously (22, 23, 31, 32).

Strategy for selecting loci included in the multiplex PCR. In choosing the main loci (A through F) for the multiplex PCRwe followed three criteria. The first two were to include foreach SCCmec type one locus located upstream of the mecA geneand a second locus located downstream of the mecA gene. Thethird was to select one of the loci to be unique for a singleSCCmec type.

In addition to those criteria, the genetic organizations ofthe SCCmec types and the similarities among them conditionedthe choice of loci (12, 26). SCCmec types I and II have verysimilar downstream region organizations, explaining the commondownstream locus D and specific upstream loci A and B. Mostof the SCCmec type III upstream sequence is similar to thatof part of the type II upstream region, whereas the downstreamregion of type III differs from and is much longer than thoseof types I and II, explaining the nondifferentiating upstreamlocus C and the two specific downstream loci, E and F. SCCmectype IV is closely related to type I, having the same downstreamregion and part of the upstream region. Moreover, the specificupstream region (i.e., the one not present in type I) is variablefrom strain to strain, so that this SCCmec type is more accuratelydefined by the absence of the pls region (18 kb) in the mecAupstream region (26). Therefore, strains harboring SCCmec typeIV are positive for downstream locus D and negative for upstreamlocus A, located in the pls region.

To distinguish SCCmec type variants IA (from I) and IIIA (fromIII), primers to amplify the left junctions between IS431 andintegrated plasmids pUB110 (present in variant IA) and pT181(absent in variant IIIA) were included. The distinction betweenSCCmec types I and IA is important, since type IA is associatedwith a widely spread MRSA clone, the Iberian clone. In the sameway, type IIIA is associated with another widely spread MRSAclone, the Brazilian clone.

Validation of the multiplex PCR strategy. The amplification profiles obtained for the strains includedin the validation collection (Table 1) are shown in Fig. 1.All strains were positive for the 162-bp internal fragment ofthe mecA gene, included in the multiplex PCR as an internalpositive control. The four major SCCmec types are easily distinguishable:type I strains display two bands of 495 and 342 bp; type IIstrains display four bands of 381, 342, 284, and 209 bp; typeIII strains display four bands of 414, 303, 243, and 209 bp;and type IV strains display a single band of 342 bp. SCCmecvariant IA is distinguished from type I by an extra band of381 bp corresponding to the pUB110 insertion (Fig. 1A, lanes5 to 7 and 9); SCCmec variant IIIA is distinguished from typeIII by the absence of the 303-bp band corresponding to the pT181insertion (Fig. 1B, lanes 3 and 4); and SCCmec variant IIIBis discriminated from type III by the absence of all downstreambands (Fig. 1B, lane 5). Strain PER184 (Fig. 1A, lane 8) shows,by multiplex PCR, a pattern characteristic of type I. In a detailedprevious study, this strain was assigned to variant IA because,in spite of not having the integrated pUB110 copy in the mecAdownstream vicinity, it has a truncated HVR region (1-kb deletion),which is the specific characteristic of type IA (26), sincelinearized plasmid pUB110 is also present in SCCmec type II(13). The distinction between SCCmec types I and IA by the multiplexstrategy is based on the detection of a pUB110-specific fragment,so the multiplex PCR fails to discriminate these types. However,the absence of pUB110 in SCCmec type IA strains is rare andcan be detected on the basis of ClaI::mecA vicinity polymorphisms(28).

View larger version (66K):
[in this window]
[in a new window]
FIG. 1. Validation of the SCCmec multiplex PCR strategy. Major SCCmec types are given at the bottom. (A) SCCmec type I (lanes 1 to 4 and 8), variant IA (lanes 5 to 7 and 9), and SCCmec type II (lanes 10 to 12). (B) SCCmec type III (lanes 1, 2, 6, and 7), variant IIIA (lanes 3 and 4), and variant IIIB (lane 5). (C) SCCmec type IV. Lane numbers are correlated with the order of strains (from top to bottom) in Table 1 (e.g., panel A, lane 1 represents strain UK13136 and panel B, lane 1 represents strain ANS46). M, DNA molecular size marker (1-kb DNA Ladder Plus; Gibco BRL, Invitrogen Corporation).

The primary criteria originally used for the classificationof the mec element into three structural types were the structureof the mecA complex (mecA gene with the upstream regulatoryregion) and the nature of the ccrAB allele (12), the functionof which is associated with the precise insertion and excisionmechanisms of the mec element at the specific chromosomal siteof orfX (15). The multiplex PCR method described here was designedto provide maximum resolution for the various structural variantsof the mec element that we have identified in association withvarious clones of MRSA (26). This strategy did not include identificationof the ccrAB alleles. However, PCR primers to confirm the presenceof the specific ccrAB alleles associated with SCCmec types I,II, and III, identified by the multiplex PCR strategy, are available(12). Identification of the recently described type IV mec elementis more problematic. This new mec element has a structure identicalto that of mec element I in its mecA complex and in the downstreamregion but showed variability, from one strain to another, furtherupstream of the mecA complex (18, 26). The ccrAB allele of typeIV strains differed from the alleles associated with mec elementtypes I through III. Moreover, different strains carrying thetype IV mec element showed variations in ccrAB. In the multiplexPCR described here the type IV mec element is defined throughthe absence of the pls region (characteristic of SCCmec typeI) and a positive reaction for the downstream dcs region.

Overall, the multiplex PCR strategy was able to discriminatethe four major mec element types and some of its previouslydetected variants, such as SCCmec IA and IIIA, associated withwidespread MRSA clones (Iberian and Brazilian MRSA clones, respectively).There was a correct assignment of SCCmec types to the strainsfor which the mec element had been previously extensively characterizedexcept for strain PER184 (see above) (Table 1).

Application of the multiplex PCR strategy. We tested the multiplex PCR method as part of a protocol forthe complete genetic characterization of a group of MRSA isolatesrecovered in a hospital outbreak in Barcelona, Spain (4). Apreliminary, relatively rapid characterization of the geneticbackground of strains was done by spaA typing, which was shownto be predictive of MLST results in many of the cases (26).Confirmation of the genetic background was done by MLST, andtentative identification of the mec elements was done by multiplexPCR. The strains had already been characterized by PFGE (5).The results of this study are summarized in Table 3.

View this table:
[in this window]
[in a new window]
TABLE 3. Application of the multiplex PCR to an outbreak collection

The application of the multiplex PCR to this collection of strainsallowed rapid presumptive assignment of the SCCmec types (Fig.2). The outbreak clone (Iberian clone), classified as havingPFGE patterns A and B, carried SCCmec type IA (Fig. 2, lanes1 to 9). Representative isolates of what appeared to be sporadiclineages, found by MLST and spaA typing to be related to theIberian clone, also carried SCCmec type IA (Fig. 2, lanes 11and 14). The single isolate belonging to the epidemic Brazilianclone was shown to have the characteristic SCCmec type IIIA(Fig. 2, lane 12). The isolates representing clone ST30/UK,a single-locus variant of clone E-MRSA 16 (epidemic MRSA clone16) (7), were assigned to SCCmec type IV or IVA, which differsfrom type IV by the presence of a 381-bp band due to the integrationof pUB110 (Fig. 2, lanes 13, 15, and 16). The new clone, classifiedas having PFGE pattern C, also carried SCCmec type IVA (Fig.2, lane 10).

View larger version (41K):
[in this window]
[in a new window]
FIG. 2. Application of the SCCmec multiplex PCR strategy to an outbreak collection including the sporadic clones. Lanes 1 to 9, PFGE patterns A1, A2, B1 to B6, and B8, respectively; lane 10, pattern C; lanes 11 to 16, patterns E through J, respectively. M, DNA molecular size marker (1-kb DNA Ladder Plus).

We applied the SCCmec multiplex PCR to MRSA isolates collectedin the Barcelona outbreak as a kind of field test of the multiplexPCR method. Beyond proving its rapidity and fidelity, the studyalso yielded some interesting new information. First, some ofthe "sporadic isolates" were related to the major clone responsiblefor the outbreak, and others were related to highly epidemicMRSA clones, such as the Brazilian and E-MRSA 16 clones (14,35). Second, the previously detected presence of SCCmec typeIV in different genetic backgrounds was observed, which is compatiblewith the suggested enhanced mobility of this mec element (18,27), perhaps because it is smaller than the other SCCmec types.In previous studies, this SCCmec type was found to be associatedwith MRSA of several different genetic backgrounds, each oneof which was also found in association with other SCCmec types(26). Recent data indicate the presence of SCCmec type IV alsoin community-acquired MRSA (18) and in coagulase-negative staphylococci(11). In this study, SCCmec type IV was found in two distinctMRSA clones: the new clone classified as having PFGE patternC and clone ST30, which is related to clone E-MRSA 16. A representativestrain of clone E-MRSA 16 is being sequenced, and analysis ofits preliminary genome sequence indicates that it harbors SCCmectype II, which was confirmed by the multiplex PCR strategy describedin this study (data not shown). Another important MRSA clonecirculating in British hospitals and also present in Germany,E-MRSA clone 15, was also found to carry SCCmec type IV by SCCmecmultiplex PCR (data not shown). It seems that SCCmec type IVis or was a mobile version of the mec element, and SCCmec multiplexPCR has provided more evidence for this mobility (Table 4).

View this table:
[in this window]
[in a new window]
TABLE 4. Presence of SCCmec type IV in different genetic backgrounds^b

The protocol for the multiplex PCR developed in this study waskept as simple as possible in order to allow rapid presumptiveassignment of SCCmec types to MRSA strains. This strategy allowsthe presumptive classification of the SCCmec type resident ineach MRSA isolate in a single PCR, a technique nowadays commonlyavailable in clinical microbiology laboratories. The routineassignment MRSA isolates to SCCmec types, now feasible withthe SCCmec multiplex PCR typing tool, may provide researcherswith important information concerning the origin of MRSA clonesand the evolutionary relationships among them, since it probesthe genetic organization of the mec element, which harbors thecentral genetic component of methicillin resistance.

ACKNOWLEDGMENTS

We thank Alexander Tomasz for suggestions, support, and criticalreading and revision of the manuscript. Some observations weremade possible by the information available at the MLST database(www.mlst.net) and the COL and E-MSRA 16 genome-sequencing projectsavailable at www.tigr.org and www.sanger.ac.uk, respectively.

Partial support for this study was provided by project POCTI/1999/ESP/34872from Fundação para a Ciência e Tecnologia,Lisbon, Portugal, awarded to H. de Lencastre, by a grant fromFundação Calouste Gulbenkian, Lisbon, Portugal,awarded to H. de Lencastre, and by a grant from the U.S. PublicHealth Service awarded to A. Tomasz, project RO1 AI37275. D.C.Oliveira was supported by a doctoral grant from FundaçãoCalouste Gulbenkian.

FOOTNOTES

* Corresponding author. Mailing address: The Rockefeller University, 1230 York Ave., New York, NY 10021. Phone: (212) 327-8278. Fax: (212) 327-8688. E-mail: lencash{at}mail.rockefeller.edu.

REFERENCES

Top