Shiga Toxin 2-Converting Bacteriophages Associated with Clonal Variability in Escherichia coli O157:H7 Strains of Human Origin Isolated from a Single Outbreak

Shiga toxin 2 (Stx2)-converting bacteriophages induced from49 strains of Escherichia coli O157:H7 isolated during a recentoutbreak of enterocolitis in Spain were examined in an attemptto identify the variability due to the stx₂-converting phages.The bacterial isolates were divided into low-, medium-, andhigh-phage-production groups on the basis of the number of phagesreleased after mitomycin C induction. Low- and medium-phage-productionisolates harbored two kinds of phages but released only oneof them, whereas high-phage-production isolates harbored onlyone of the two phages. One of the phages, ${phi}$ SC370, which was detectedonly in the isolates with two phages, showed similarities withphage 933W. The second phage, ${phi}$ LC159, differed from ${phi}$ SC370 inmorphology and DNA structure. When both phages were presentin the same bacterial chromosome, as occurred in most of theisolates, only ${phi}$ SC370 was detected in the supernatants of theinduced cultures. If ${phi}$ LC159 was released, its presence was maskedby ${phi}$ SC370. When ${phi}$ SC370 was absent, large amounts of ${phi}$ LC159 werereleased, suggesting that there was some regulation of phageexpression between the two phages. To our knowledge, this isthe first description of clonal variability due to phage loss.The higher level of phage production was reflected in the largeramounts of Stx2 toxin produced by the cultures. Some relationshipbetween phage production and the severity of symptoms was observed,and consequently these observations suggest that the virulenceof the isolates studied could be related to the variabilityof the induced stx₂-converting phages.

INTRODUCTION

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Introduction

Escherichia coli Shiga toxin-producing (STEC) strains are responsiblefor hemorrhagic diarrhea and hemolytic-uremic syndrome, whichleads to acute renal failure in children (19, 22). E. coli O157:H7is the most common virulent serogroup, but other serogroupshave been described, such as O18, O26, O111, O128, and O138(1). STEC is mainly transmitted by consumption of contaminatedfood and water and by personal contact (6, 17, 19). The numberof outbreaks caused by STEC has increased drastically in alldeveloped countries (19, 22).

Among other virulence factors, the pathogenicity of STEC isrelated to the production of Shiga toxin 1 (Stx1), Stx2, orvariants of Stx2 (7, 22). The genes encoding Shiga toxins (stx)are located in the genomes of temperate lambdoid bacteriophages(21). Stx2-converting phages are heterogeneous because theyhave wide ranges of DNA structures, restriction patterns, hostspectra, and morphologies (10, 26, 30, 31). Phages carry stx₁(20), stx₂ (21), and stx₂ variants (18, 29). They carry notonly the Shiga toxin genes but also some regulatory genes; hence,they are responsible for the production of toxin and its regulation(31, 32). Intraintestinal phage transmission between differentbacteria has been described for stx₁ (2) and in vitro for stx₂(26). Additionally, treatment with inhibitors of DNA synthesis,such as trimethoprim-sulfamethoxazole and mitomycin C, resultsin phage induction and an increase in toxin production in variousSTEC strains (12).

The mobility of the stx₂ characteristic mediated by phages suggeststhat a wide variety of E. coli strains (and other enterobacteria)are susceptible to infection by stx phages. Recent studies haveindicated that strains of the most virulent enterohemorrhagicE. coli serotypes (O157:H7, O103:H2, O111:H-) belong to a fewclone complexes (3, 11). However, the presence of variable DNA,which can be readily transferred by horizontal genetic exchange,has hampered our understanding of the phylogeny and pathogenesisof STEC. Moreover, genetic exchange has been demonstrated inlambdoid phages, and it has been proposed that these phageshave a common gene pool from which DNA can be exchanged (9,18). This exchange could influence the host strain, as has beendescribed for E. coli O157:H7 (34), Shigella dysenteriae (15),and Shigella sonnei, (28), producing variations in toxin productionand thus in the virulence of the host bacteria.

This study of stx₂-converting phages was carried out with 49strains of E. coli isolated from a recent outbreak of STEC infectionreported in Spain, which occurred in the Barcelona area between19 September and 5 November 2000 and affected three schools.Infections in two of the schools were caused by contaminatedfood supplied by the same caterers. In the third school thetransmission was attributed to personal contact. The whole outbreakinvolved more than 200 patients, most of whom were childrenunder the age of 10 years. Six children developed hemolytic-uremicsyndrome. The outbreak was associated with ingestion of E. coliO157:H7 via contaminated sausages (4), although bacteria werenot isolated from the suspected food.

Although all bacterial of the isolates were E. coli O157:H7stx₁^- stx₂⁺ and thus were assumed to be clonal, we were interestedin examining the presence of stx₂-converting phages in thesebacteria. The presence and expression of stx₂ varied from oneisolate to another due to certain variability observed in thestx₂-converting bacteriophages.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, bacteriophages, and media. Forty-nine strains were isolated from children under the ageof 10 years and from one adult from three schools in the Barcelonaarea in Spain in 2000. Fifty percent of the strains were isolatedfrom patients showing symptoms of infection; most of the patientshad primary infections, but nine patients had secondary infections(Table 1). The individuals with primary infections had directcontact with the contaminated food and exhibited symptoms before2 October, whereas the individuals with secondary infectionshad no contact with the contaminated food but were in contactwith individuals with primary infections and exhibited symptomsafter 3 October. Analyses were also performed with asymptomaticsubjects related to the outbreak, who could not be classifiedas individuals with primary or secondary infections. A totalof 24 of the asymptomatic subjects were positive for E. coliO157:H7, and the strains were included in this study (Table1). All of the isolates were E. coli O157:H7 stx₁^- stx₂⁺.

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TABLE 1. Isolates used in this study

E. coli laboratory strain DH5 ${alpha}$ was used as the host for propagationof bacteriophages induced from the isolates studied. E. coliO157:H7 strain ATCC 43889, which produces Stx2, and bacteriophage933W (21) were used as positive controls for bacteria and phages,respectively, and for the bacteriophage immunity tests. E. coliO157:H7 strain ATCC 43888, which does not contain either stx₁or stx₂, was used as a negative control in some experiments.

Luria-Bertani (LB) broth or LB agar was used for culture ofbacteria.

PCR studies. PCRs were performed with a GeneAmp 2400 PCR system (Perkin-Elmer,PE Applied Biosystems, Barcelona, Spain). A DNA template wasprepared by suspending two colonies of each isolate in 50 µlof double-distilled water and heating the preparation at 96°Cfor 10 min prior to addition of the reaction mixture or by dilutingisolated bacterial or phage DNA 1:20 in double-distilled water.A 5-µl portion of each PCR product was analyzed by agarose(1%) gel electrophoresis, and bands were visualized by ethidiumbromide staining. Oligonucleotides used for PCR amplificationand customized primers used for sequencing are shown in Table2.

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TABLE 2. Oligonucleotides used for PCR analysis and stx₂-flanking regions

Preparation of DIG-labeled stxA₂-specific gene probes. A 378-bp DNA fragment of the stxA₂ gene resulting from amplificationwith primers UP 378 and LP 378 (Table 2) was labeled with digoxigenin(DIG) and used as a probe. The probe was labeled by incorporatingdigoxigenin-11-deoxyuridine triphosphate (Roche Diagnostics,Barcelona, Spain) during PCR as described previously (18).

Standard DNA techniques. DNA was digested with restriction endonucleases (Promega Co.,Inc., Madison, Wis.), and restriction fragments were analyzedby separation on 0.7% agarose gels in 0.5x Tris-borate-EDTAbuffer and stained with ethidium bromide. PCR products werepurified with a PCR purification kit (Qiagen Inc., Valencia,Calif.). DNA fragments were purified from agarose gels by usinga gel excision kit (Qiagen Inc.).

Isolation of temperate bacteriophages and preparation of phage lysates. Bacteria were grown from single colonies in Luria broth to theexponential growth phase. Mitomycin C was added to the culturesto a final concentration of 0.5 µg/ml. The cultures werethen incubated overnight. Supernatants of the induced cultureswere centrifuged at 10,000 x g for 10 min, filtered throughlow-protein-binding 0.22-µm-pore-size membrane filters(Millex-GP; Millipore, Bedford, Mass.), and treated with DNase(10 U/ml; Sigma-Aldrich, Madrid, Spain).

To measure the rate of phage production after induction of eachisolate, the cultures were analyzed with a spectrophotometerat 600 nm every 30 min after addition of mitomycin C. The opticaldensity was compared with the optical density of a control ofthe same culture without mitomycin C. Induction and opticaldensity measurements were performed at least in triplicate foreach isolate.

Screening for the presence of stx₂-containing temperate bacteriophages. A plate containing E. coli DH5 ${alpha}$ as the host strain was used toscreen for the presence of temperate bacteriophages in the isolates.It was prepared with 500 µl of a log-phase culture ofstrain E. coli DH5 ${alpha}$ , 100 µl of 0.1 M CaCl₂, and 3 ml ofmolten LB top agar; the mixture was then poured onto LB agarplates and allowed to solidify. Fifteen-microliter portionsof a suspension of each phage lysate and phage 933W, used asa positive control, were dropped onto the plates. The plateswere examined for the presence of lysis zones after incubationfor 18 h at 37°C.

Additionally, phage lysates were diluted 10-fold. One hundredmicroliters of each dilution was then mixed with 100 µlof 0.1 M CaCl₂ and 500 µl of a log-phase culture of E.coli DH5 ${alpha}$ and examined by the plaque assay by using a double-layeragar method (26). The plates were examined for the presenceof plaques after incubation for 18 h at 37°C.

Plaque hybridization. To determine the presence of the stx₂ gene in the bacteriophagespresent in a lysis zone in which a drop of phage suspensionwas placed, the plaques were transferred to a nylon membrane(Hybond-N+; Amersham Pharmacia Biotech, Barcelona, Spain) byusing a standard procedure (25) and hybridized at 65°C witha DIG-labeled stxA₂ probe prepared as described above. Stringenthybridization was performed with a DIG DNA labeling and detectionkit (Roche Diagnostics) used according to the manufacturer'sinstructions.

Isolation of phage DNA and detection of the stx₂ gene. Phage DNA was isolated from 200-ml cultures after inductionwith mitomycin C by the polyethylene glycol method and phenol-chloroformextraction as described previously (25). Purified DNA was digestedwith EcoRI, the fragments were separated by agarose (0.7%) gelelectrophoresis, and bands were visualized by ethidium bromidestaining. After electrophoresis, the DNA was transferred tonylon membranes (Hybond N+; Amersham Pharmacia Biotech) by capillaryblotting (25). The membranes were hybridized with the DIG-labeledstxA₂ fragment probe as described above. DNA was quantifiedwith a spectrophotometer at 260 nm.

Isolation and detection of stx₂ in bacterial DNA. Chromosomal DNA was isolated from 40-ml cultures of each strainby lysozyme treatment and phenol-chloroform extraction as describedpreviously (27). Purified DNA was diluted 1:3 in double-distilledwater and digested with EcoRI. Electrophoresis, transfer tonylon membranes, and hybridization were carried out under thesame conditions that were used for phage DNA.

Electron microscopy. The stx₂-converting bacteriophages obtained after inductionof each isolate were purified by cesium chloride centrifugation(25). One drop of a phage suspension was deposited on a coppergrid with carbon-coated Formvar film and stained with 2% KOH-phosphotungsticacid (pH 7.2) for 2.5 min. Samples were examined with a HitachiE.M. 600 electron microscope operating at 80 kV.

Toxin production. To compare the relative levels of production of Stx2 in theinduced cultures, an enzyme immunoassay (Premier EHEC; MeridianDiagnostics Inc., Cincinnati, Ohio) was performed by using themanufacturer's instructions. Levels of expression by low-, medium-,and high-phage-production isolates with and without inductionwith mitomycin C were compared. E. coli DH5 ${alpha}$ was used as a negativecontrol. Results were analyzed spectrophotometrically at twowavelengths (450 and 630 nm).

Characterization of the two types of phages observed. Two phages were chosen as representatives for analysis of thetwo types of phage detected, those induced from isolate 159and those induced from isolate 370. These phages are referredto below as ${phi}$ LC159 and ${phi}$ SC370. The characteristics of each phageare described in the Results.

Bacteriophage immunity test. Phage immunity was tested on LB agar plates by spotting 10-µlportions of a suspension of phages ${phi}$ LC159, ${phi}$ SC370, and 933W ontofour plates containing a top agar overlay; each overlay containedE. coli DH5 ${alpha}$ , E. coli C600 (933W), isolate 370, or isolate 159.

Cross-hybridization studies. For cross-hybridization of digested DNAs of phages ${phi}$ SC370, ${phi}$ LC159,and 933W, SmaI-digested DNA of each phage was labeled with DIGby using a DIG labeling detection kit (Roche Diagnostics) andthe manufacturer's instructions. For phage ${lambda}$ , the ${lambda}$ molecularweight marker restricted with EcoRI and HindIII and labeledwith DIG was used. The labeled digested DNA of each phage wasused as a probe in a Southern blot to detect homologies withthe SmaI-digested DNAs of the other two phages and with phage ${lambda}$ DNA.

Sequencing of the stx₂ gene and stx₂-flanking regions encoded by temperate phages. Since not all of the isolates produced the same number of phageafter induction, two approaches were used to sequence the twotypes of phages observed, ${phi}$ LC159 and ${phi}$ SC370. When the rates ofphage production after induction were high, resulting in highlyconcentrated phage DNA, as observed for the long-capsid phage ${phi}$ LC159, 3 µg of purified phage DNA was used for directsequencing by standard genomic DNA methods (Perkin-Elmer, PEApplied Biosystems). The fragment was sequenced by chromosomalwalking. The oligonucleotides used for sequencing are describedin Table 2.

When the production of phage did not result in a high concentrationof DNA, as observed for phage ${phi}$ SC370, phage DNA was purifiedfrom 500 ml of induced bacterial cultures and digested withvarious restriction enzymes, including BamHI, ClaI, EcoRI, EcoRV,KpnI, PstI, SalI, and SmaI (Promega Co.). The digested DNA wastransferred to a nylon membrane, and the presence of the stx₂gene was determined by Southern blot hybridization as describedabove. A 4.8-kb EcoRI restriction fragment containing the stx₂gene was excised from the agarose gel and purified as describedabove. Five microliters of the purified fragment was used asa template for PCRs performed with stx₂ reverse primers andforward primers for Q and stxB₂-flanking regions as describedin Table 2. PCR products were used directly for sequencing,and 4,189 bp between primers Q-up and Rev FB (Table 2) of the4.8-kb fragment was sequenced.

Sequencing was performed with an ABI PRISM Big Dye II terminatorcycle sequencing Ready Reaction kit (Perkin-Elmer, PE AppliedBiosystems) by using an ABI PRISM 3700 DNA analyzer (Perkin-Elmer,PE Applied Biosystems) according to the manufacturer's instructions.All sequences were determined in duplicate.

Nucleotide sequence analysis, searches for open reading frames(ORFs), and searches for homologous DNA sequences in the EMBLand GenBank database libraries were performed with the WisconsinPackage, version 10.2 (Genetics Computer Group, Madison, Wis.).BLAST analyses were done with tools available on the web (http://www.ncbi.nlm.nih.gov).

Nucleotide sequence accession numbers. The nucleotide sequence of the 5,812-bp fragment of phage ${phi}$ LC159DNA and the nucleotide sequence of the 4,189-bp fragment ofphage ${phi}$ SC370 containing the stx₂ gene and stx₂-flanking regionshave been deposited in the EMBL database library under accessionnumbers AF548456 and AF548457, respectively.

RESULTS

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Results

Presence of stx₂-converting bacteriophages. stx₂-converting bacteriophages were detected in all 49 isolateson the basis of the formation of a lysis zone, which gave apositive signal when the phages were hybridized with the stxA₂-DIGprobe. However, the rate of phage production after inductiondiffered from one isolate to another (Table 3). Phage inducedfrom high- and medium-phage-production isolates produced a confluentlysis zone in the spot area, whereas low-phage-production isolatesproduced only isolated plaques, which sometimes were not veryvisible. The negative control E. coli O157:H7 strain ATCC 43888showed no lysis. Enumeration of plaques was difficult becausethey were barely discernible on the agar plates. Plaques wereobserved only after plaque blot hybridization. However, althoughpositive signals were obtained after hybridization, the plaqueswere still too small to count accurately (data not shown).

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TABLE 3. Induction of stx₂-converting phages and detection of the stx₂ gene in phage and chromosomal DNAs

On the basis of the optical densities of the cultures afterlysogenic induction, isolates were classified into three groups:isolates producing large, medium, and small amounts of stx₂-convertingphages, corresponding to optical densities of <0.3, between0.3 and 0.6, and > 0.6, respectively (Fig. 1). Results describedbelow (phage DNA size and restriction analysis and electronmicroscopy results) indicated that no phages other than stx₂-convertingphages were detected in the isolates studied.

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FIG. 1. Comparison of bacteriophage production after induction with mitomycin C of high-phage-production isolates (A), medium-phage-production isolates (B) and low-phage-production isolates (C). Symbols: ${blacksquare}$ , without mitomycin C; ${circ}$ , with mitomycin C. O.D., optical density.

Isolation of phage DNA and detection of the stx₂ gene. Isolation of phage DNA after induction from all the isolatesstudied indicated that some isolates had a higher rate of phageproduction than other isolates. After three independent inductionsof each culture, the isolates exhibiting optical densities higherthan 0.6 produced lower concentrations of phage DNA than theisolates exhibiting lower optical densities, although the concentrationof DNA obtained varied slightly from one experiment to another.From a 200-ml culture no more than 0.5 µg of phage DNAwas obtained from the low-phage-production isolates, whereas3 µg of phage DNA was obtained from the high-phage-productionisolates. The medium-phage-production isolates yielded between0.5 and 3 µg of DNA.

The stx₂ gene was located in a fragment of the DNA that wasthe same size (4.8 kb) in phages induced from most of the isolates(Fig. 2); however, in phages induced from two of the isolates,isolates 159 and 360 (Table 3), the stx₂ gene was located ina 5.8-kb DNA fragment. DNAs of phages isolated from all medium-and low-phage-production isolates showed the same restrictionpatterns when the phage DNAs were analyzed with a range of enzymes(data not shown), and the patterns were always different fromthose produced by the phages induced from isolates 159 and 360.The genome sizes of the phages released from all the isolateswere calculated to be 60 ± 0.2 kb based on the sum ofthe sizes of the EcoRI or SmaI restriction fragments of thephage DNA.

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FIG. 2. Detection of the stx₂ gene by Southern blot analysis of the EcoRI restriction patterns of phage and chromosomal DNAs of the low-phage-production isolates (lanes L), medium-phage-production isolates (lanes M), and high-phage-production isolates (lanes H). (A) EcoRI restrictions patterns of phage DNAs. (B) Southern blot hybridization with stxA₂-DIG probe of the phage DNAs shown in panel A. (C) Southern blot hybridization with stxA₂-DIG probe of the chromosomal DNAs extracted from the same isolates.

The phage DNAs obtained with isolates 159 and 360 had the samerestriction patterns, and no differences were observed betweenthem when they were tested with several enzymes. The genomesizes of these phages, calculated from the sum of the sizesof the EcoRI or SmaI restriction fragments of phage DNA, were48 ± 0.3 kb.

Isolation and detection of stx₂ in bacterial DNA. Restriction analysis and Southern blot analysis revealed twobands of different sizes (4.8 and 5.8 kb) for low- and medium-phage-productionisolates but only one band at 5.8 kb for the two high-phage-productionisolates (isolates 159 and 360) (Fig. 2 and Table 3), indicatingthat there were two copies of the stx₂ gene in all of the isolatesexcept isolates 159 and 360.

Electron microscopy. Two different kinds of phages were also observed with the electronmicroscope. The medium- and low-phage-production isolates releaseda phage with an isometric capsid that was approximately 60 nmdiameter and a short tail (Fig. 3A). Isolates 159 and 360 produceda phage with a capsid that was 45 by 90 nm and a long tail.(Fig. 3B).

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FIG. 3. Electron micrographs of the two main types of bacteriophages. (A) Phage ${phi}$ SC370; (B) phage ${phi}$ LC159. Bars = 100 nm.

Toxin production. Results of the toxin production analysis are shown in Fig. 4,in which the amounts of toxin produced are expressed in absorbanceunits. Isolate 975, which was used as a representative of thelow-phage-production group, produced less toxin than isolate370, which was used as a representative of the medium-phage-productiongroup. Isolate 159, a representative of the high-phage-productiongroup, produced the most toxin. Toxin production increased afteraddition of mitomycin C, and the number of absorbance unitswas proportionally higher in each group. As expected, DH5 ${alpha}$ didnot produce toxin (Fig. 4.)

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FIG. 4. Toxin production evaluated with low-, medium-, and high-phage-production isolates with and without induction with mitomycin C. Values on the y axis correspond to absorbance units (AU) at two wavelengths (450 and 630 nm). The negative control was strain DH5 ${alpha}$ . Open bars, without mitomycin C; shaded bars, with mitomycin C.

Characterization of phages. Two phages were chosen as representatives for analysis of thetwo types of phages detected in the set of isolates studied.Phage ${phi}$ SC370, obtained after induction of isolate 370, was chosenas a representative of the low- and medium-phage-productionisolates, since these isolates released different amounts ofthe same kind of phage. Phage ${phi}$ LC159, induced from isolate 159,was selected as a representative of the two high-phage-productionisolates.

(i) Cross-hybridization studies. Cross-hybridization of EcoRI-digested DNAs of phages ${phi}$ SC370, ${phi}$ LC159, and 933W revealed some DNA homology between ${phi}$ SC370 and933W (Fig. 5). However, phage ${phi}$ LC159 was different. All phagesexhibited low levels of similarity with bacteriophage ${lambda}$ .

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FIG. 5. Agarose gel electrophoresis and Southern blot hybridization of phage DNAs. (A) Agarose gel electrophoresis of SmaI-digested DNAs of phages ${phi}$ SC370, ${phi}$ LC159, and 933W. The molecular weight marker was bacteriophage lambda DNA digested with EcoRI and HindIII. (B) Hybridization with lambda marker as the gene probe. (C) Hybridization with SmaI-digested DNA of phage ${phi}$ LC159 as the gene probe. (D) Hybridization with SmaI-digested DNA of phage ${phi}$ SC370 as the gene probe.

(ii) Bacteriophage immunity test. E. coli DH5 ${alpha}$ was sensitive to phages ${phi}$ SC370 and ${phi}$ LC159. Strain370 was resistant to ${phi}$ SC370 and ${phi}$ LC159, whereas strain 159 wasresistant to ${phi}$ LC159 but sensitive to ${phi}$ SC370. These results indicatedthat phage ${phi}$ LC159 was present in isolate 370 and that phage ${phi}$ SC370was not present in wild-type strain 159. These differences inimmunity also indicated that phages ${phi}$ SC370 and ${phi}$ LC159 are in differentbacteriophage immunity groups.

(iii) Sequencing of the stx₂ gene and stx₂-flanking regions encoded by temperate phages ${phi}$ LC159 and ${phi}$ SC370. A 5,812-bp fragment of ${phi}$ LC159 DNA and a 4,189-bp fragment of ${phi}$ SC370 DNA containing the stx₂ gene and stx₂-flanking regionswere sequenced to find out whether they had the structure describedpreviously for other stx-converting phages (23, 30).

The total nucleotide sequence of the stx₂ gene present in bothphages exhibited 100% homology with the stx₂ sequences carriedby phages described previously (13, 23).

The 4,189-bp fragment of ${phi}$ SC370 DNA including the stx₂ gene andflanking regions exhibited 100% homology with the correspondingfragment of phage 933W (23). Although the restriction patternsof this phage indicated that the total DNA of ${phi}$ SC370 is not identicalto the total DNA of 933W, the fragment studied, which includedthe stx₂ gene A and B subunits, the Q gene, and a fragment ofthe L0105 region (Fig. 6), showed that the stx₂-flanking regionsof ${phi}$ SC370 did not differ from those studied by other workers(13, 23).

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FIG. 6. Comparison of ${phi}$ SC370 and ${phi}$ LC159 or 933W stx₂-flanking regions. The arrows indicate the relative lengths and directions of ORFs. The solid arrows indicate the stx₂ genes. The percentages of sequence identity for the two phages and for phages ${phi}$ LC159 and 933W are indicated by shaded boxes. Bar = 1 kb. Gene designations are described in the text.

The first attempt to sequence phage ${phi}$ LC159 with the same setof primers used to sequence phage ${phi}$ SC370 was unsuccessful sincethe primers did not amplify the target DNA. The sequence ofphage ${phi}$ LC159 was different from the sequence of phage ${phi}$ SC370 (Table4 and Fig. 6). The stx₂ gene sequence was again identical tothe sequences of phage ${phi}$ SC370 and phages described previously.However, the sequence of the stx₂-flanking regions was significantlydifferent from the sequences in other phages. The sequence mostclosely related to the fragment studied was a 5,606-bp sequencedescribing the stx₂ vhdA and stx₂ vhdB genes for the type 2variant subunit (accession number AB071845; submitted to theEMBL gene bank by T. Hamabata [unpublished data]), which exhibited99% homology with the fragment of phage ${phi}$ LC159 sequenced in thisstudy. However, we did not identify the ORFs present in thisfragment except for the stx₂ gene.

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TABLE 4. Description of ORFs in the sequence of the 5,812-bp fragment of phage ${phi}$ LC159

Eight ORFs were identified (Table 4). The stx₂ gene in phage ${phi}$ LC159 (ORFs 5 and 6) was found downstream of the homologuesof the ileZ and argN genes. A sequence homologue of the Q antiterminatorgene was found upstream of the ileZ gene, which exhibited 97%homology with the Q gene of bacteriophage 21 (accession numberM58702); the protein exhibited 95% identity with the encodedQ protein of bacteriophage 21.

Upstream of the Q gene, ORFs 1, 2, and 3 were detected (Table4 and Fig. 6). ORF 1 exhibited 100% homology with the roi geneof phage 933W (accession number AF125520). ORF 2 exhibited highlevels of homology with sequences of phages 1639, H-19, and933W coding for a protein similar to the NinG protein (ORF 204)of bacteriophages lambda and P22, and the protein exhibited80% amino acid identity with the NinG protein of phage 933W.ORF 3 exhibited similarity to the gene encoding a serine/threonineprotein phosphatase of E. coli O157:H7 strain EDL 933 and tothe nin 221 gene of phage ${lambda}$ . The protein homology data confirmedthe similarity of the protein to a serine/threonine proteinphosphatase.

Downstream of the stx₂ gene two ORFs were detected, includingORF 7, which appeared to be identical to ORF 107 previouslydescribed downstream of the stx₂ region in stx_2c phage and otherstx₂⁺ strains (30) (accession numbers AJ251452, AJ250954, AJ251483,and AJ251520). Finally, the fragment of ORF 8 sequenced exhibiteda high level of homology with the corresponding fragment ORF645 described for stx_2c and other stx₂⁺ strains (accession numbersAJ251452 and AJ251520).

DISCUSSION

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Discussion

In this study the variability of the E. coli O157:H7 strainsisolated from a single outbreak due to stx₂-converting bacteriophageswas analyzed. The field epidemiology and molecular epidemiologyof the isolates (data not shown) indicate that they had a commonorigin. After the studies described here, we concluded thatstx₂-converting phages conferred certain variability to theisolates. Not all the isolates produced the same amount of phageafter lysogenic induction, and the variability allowed us toclassify them in three main groups. Although the criteria usedfor this classification are subjective, we intended only toclarify the expression results. The coherence of the resultswas demonstrated after several replications of induction foreach isolate, which showed that the differences were reproducible.The three categories selected could also be demonstrated bythe absorbance data for the cultures after phage induction andby the amounts of phage DNA obtained. For a given culture, ahigh level of phage production corresponded to low absorbancedue to the bacterial cell lysis after phage release, and consequentlymore phage DNA was obtained from the culture.

Variability was also observed because low- and medium-phage-productionisolates harbored two phages, although they released only onephage, phage ${phi}$ SC370. If ${phi}$ LC159 was released, its presence in thesupernatants of the induced cultures was masked by phage ${phi}$ SC370.We do not know whether the second phage, ${phi}$ LC159, was also releasedfrom the low- and medium-phage-production isolates at low concentrationsthat could not be detected. In contrast, high-phage-productionisolates harbored only one phage, ${phi}$ LC159, and had only one copyof the toxin gene, and phage ${phi}$ SC370 was not present in theirchromosomes.

There are differences in the morphological and genetic structuresof the two phages. Phage ${phi}$ SC370 has many similarities with phage933W (23), although it is not identical. The sequence of the4,189-bp fragment, the length of the DNA, the morphology, andthe bacteriophage immunity test results indicated that phage ${phi}$ SC370 is related to bacteriophage 933W. The second phage, ${phi}$ LC159,has different characteristics. Its morphology is similar tothat of phage H-19 (20), but it harbors the stx₂ gene insteadof stx₁. It has shorter DNA than phage ${phi}$ SC370 and differs inits genetic patterns.

The sequence of the phage ${phi}$ LC159 DNA fragment indicated thatthe sequence of the stx₂ gene is highly conserved, and the analysisof the flanking regions indicated that the structure is similarto that of other stx₂-converting phages (30). A homologue ofthe antiterminator gene Q is located upstream the stx₂genesand probably has an equivalent function in the regulation ofstx gene expression. With the Q gene homologue, stx genes couldbe transcribed from the pR' promoter as a part of late geneexpression under the influence of the Q-like gene product synthesizedafter inactivation of the phage repressor (20, 32). Althougha homologue of the pR' promoter has not been identified in thesequence studied, some other sequence may have its function,since phage production and toxin production are directly relatedto Q-activated pR'-promoted transcription (32). Upstream ofthe Q region the presence of the roi gene (ORF 1) suggests similaritieswith phage 933W, but ORFs 2 and 3 appeared to be different.Genes located downstream of the stx₂ genes seemed to be quitesimilar to phages described previously (30), although the regionswere only partially sequenced. Phage ${phi}$ LC159 flanking regionsappeared to be like those in a typical stx₂ phage but had amosaic structure that makes the phage slightly different fromother phages, in accordance with the findings of other workers,who suggested that there is a common mosaic structure in stx₂and in general lambdoid, double-stranded DNA phages (8, 30).

The variability of the phage-converted strains was reflectedin toxin production, in accordance with the findings of otherworkers (12, 14, 16). Greater phage release was associated withhigher levels of toxin production, and it could produce a moresevere infection. In our study to some extent this effect couldbe observed by looking at the symptoms. Although not all thelow-phage-production isolates were from asymptomatic patients,all the asymptomatic patients were infected by one isolate belongingto the low-phage-production group. In contrast, all the medium-and high-production isolates caused symptoms.

Both high-phage-production isolates (isolates 159 and 360) wereisolated from patients with secondary infections, who were siblings.These isolates lacked one of the phages, although we do notknow whether the phage was lost before or after infection ofthe two secondary carriers. Nevertheless, assuming that thewild-type strain had lost one of the two phages, this shouldhave had a clear effect on phage release and hence toxin production.The presence of the two temperate phages in the same bacterialgenome seemed to affect the induction of both phages. It hada stronger effect on the long-capsid phage, which was not detectedafter induction when the isometric-capsid phage was present.Once the isometric-capsid phage disappeared, the long-capsidphage could be induced, and very large amounts were induced.This appears to be a mechanism of phage repression that actswhen both phages are present. Watarai et al. (33) suggestedsome mechanisms of regulation in temperate phages in studiesof the two converting phages isolated from the outbreak in Japanin 1996. In that case, the workers showed that when one of thephages was transduced to a C600 strain, the amounts of the phageproduced were less than the amounts produced in the wild-typestrain harboring two phages, which is the opposite of the effectobserved here.

Clonal variability produced by changes either in the phage orin the flanking regions has been described by other workers(5, 11). However, to our knowledge, this is the first descriptionof clonal variability due to loss of a phage.

The biological significance of clonal variability in eitherphage or toxin production remains unknown, but it surely resultsin variability, producing a mixed population that allows thebacteria to adapt to the most favorable conditions. In thiscase isolates showing higher phage induction produced more toxinand hence were more virulent. However, these strains had highermortality rates due to the higher phage induction and consequentlysis. In contrast, this effect was reduced with the fractionof low-phage-production strains, which showed lower virulencebut had higher survival rates.

Also, for phages implication in clonal variability is advantageoussince being integrated as a prophage that is more or less inducibleincreases the chances of persistence. Clonal variability isadvantageous either as a prophage, in which case the conditionsfor bacterial survival are good, or as a virion when conditionsfor bacterial survival are bad.

Clonal variability may also influence epidemiological studiesby making it difficult to show linkage among epidemiologicallyrelated O157 isolates or by undervaluing Shiga toxin-producingE. coli as the causal agent of infectious enteritis.

Our results suggest that the variability induced by stx₂-convertingphages in strains is related to virulence. This variabilitycould be observed even in closely related strains, like thestrains studied here, which were isolated from the same outbreak.Since phages are an important element of gene exchange, morestudies on stx₂-converting phages are needed to increase ourknowledge of the epidemiology and pathogenicity of STEC strains.

ACKNOWLEDGMENTS

We thank Cristina Valdivieso for excellent technical assistance.

This work was supported by the project BMC2000-0549 of the Ministeriode Ciencia y Tecnologia, by the Generalitat de Catalunya (2001SGR00099),and by the Centre de Referència en Biotecnologia (CeRBa).

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, University of Barcelona, Diagonal 645, E-08028 Barcelona, Spain. Phone: 34934021487. Fax: 34934110592. E-mail: joan{at}porthos.bio.ub.es.

Editor: A. D. O'Brien

REFERENCES

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