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. 2002 May;70(5):2441–2453. doi: 10.1128/IAI.70.5.2441-2453.2002

Evidence for the Emergence of Non-O1 and Non-O139 Vibrio cholerae Strains with Pathogenic Potential by Exchange of O-Antigen Biosynthesis Regions

Manrong Li 1,2,, Toshio Shimada 3, J Glenn Morris Jr 1,2, Alexander Sulakvelidze 1, Shanmuga Sozhamannan 1,2,*
PMCID: PMC127942  PMID: 11953381

Abstract

The novel epidemic strain Vibrio cholerae O139 Bengal originated from a seventh-pandemic O1 El Tor strain by antigenic shift resulting from homologous recombination-mediated exchange of O-antigen biosynthesis (wb*) clusters. Conservation of the genetic organization of wb* regions seen in other serogroups raised the possibility of the existence of pathogenic non-O1 and non-O139 V. cholerae strains that emerged by similar events. To test this hypothesis, 300 V. cholerae isolates of non-O1 and non-O139 serogroups were screened for the presence of virulence genes and an epidemic genetic background by DNA dot blotting, IS1004 fingerprinting, and restriction fragment length polymorphism (RFLP) analysis. We found four non-O1 strains (serogroups O27, O37, O53, and O65) with an O1 genetic backbone suggesting exchange of wb* clusters. DNA sequence analysis of the O37 wb* region revealed that a novel ∼23.4-kb gene cluster had replaced all but the ∼4.2-kb right junction of the 22-kb O1 wbe region. In sharp contrast to the backbones, the virulence regions of the four strains were quite heterogeneous; the O53 and O65 strains had the El Tor vibrio pathogenicity island (VPI) cluster, the O37 strain had the classical VPI cluster, and the O27 strain had a novel VPI cluster. Two of the four strains carried CTXφ; the O27 strain possessed a CTXφ with a recently reported immune specificity (rstR-4** allele) and a novel ctxB allele, and the O37 strain had an El Tor CTXφ (rstRET allele) and novel ctxAB alleles. Although the O53 and O65 strains lacked the ctxAB genes, they carried a pre-CTXφ (i.e., rstRcla). Identification of non-O1 and non-O139 serogroups with pathogenic potential in epidemic genetic backgrounds means that attention should be paid to possible future epidemics caused by these serogroups and to the need for new, rapid vaccine development strategies.


Cholera is a diarrheal disease caused by the gram-negative bacterium Vibrio cholerae, and an estimated 120,000 deaths from cholera occur globally every year (58). Cholera is both an endemic and epidemic disease and is the only bacterial pandemic disease known in modern times. One of the etiological agent's major protective antigens appears to be the O antigen (27), and the enormous serological diversity of V. cholerae is shown by the fact that more than 200 O-antigen serogroups have been identified (43). Interestingly, only the O1 and O139 serogroups are known to cause epidemic and pandemic disease, although occasional outbreaks caused by non-O1 and non-O139 strains have been reported in the past. For example, strains of serogroup O37 were responsible for localized outbreaks in 1965 in Czechoslovakia (2) and in 1968 in the Sudan (26). Seven pandemics have been recorded in the history of cholera; the sixth pandemic was caused by O1 strains of the classical biotype, and the seventh pandemic, which started in 1961 and continues to the present time, is caused by O1 El Tor biotype strains (27). The only other serogroup known to cause epidemic cholera (O139) emerged in 1992 in the Bay of Bengal region and has remained endemic to this region (1, 41). The O139 Bengal strains cause disease with severity comparable to the severity of the disease caused by O1 strains, and prior exposure to O1 strains does not provide protection against O139 infections (7, 37). Molecular epidemiological studies (ribotyping, fingerprinting, multilocus enzyme electrophoresis, etc.) have indicated that the O139 strains have genetic backbones very similar to those of the O1 El Tor Asian seventh-pandemic strains (6, 25, 56).

The O1 O-antigen biosynthesis genes of V. cholerae are organized in a cluster (wbe cluster) on chromosome I, between open reading frames (ORFs) VC0240 (gmhD) and VC0264 (rjg) (22). DNA sequence analyses of the wb* clusters of two other serogroups (O22 and O139) revealed a similar organization of this region; i.e., serogroup-specific genes are flanked by gmhD (which encodes d-glycero-d-manno-heptose 1-phosphate guanosyltransferase, involved in lipopolysaccharide core biosynthesis) at the left junction and by rjg (which encodes a conserved hypothetical protein with similarities to mRNA 3′ end processing factor) at the right junction (9, 14, 18, 33, 48, 59). These data led to the idea that the V. cholerae O139 Bengal strain originated from an O1 strain by homologous recombination-mediated replacement of the wbe region of an O1 strain with the O139 wbf region (36, 47, 49). However, the donor or the vehicle for this horizontal transfer event is not yet known. An O22 serogroup strain has been proposed to be a possible donor since its wb* region shares extensive homology with the O139 wbf region (59), and a generalized transducing phage or a conjugative plasmid is the speculated vector (36, 47).

DNA fingerprinting and phylogenetic analyses of V. cholerae strains have established that there is a lack of correlation between serogroup and phylogeny (8, 46); i.e., strains belonging to various serogroups appear to fall in the same phylogenetic clade, and strains belonging to the same serogroup have been found in many different clades. These data support the hypothesis that there are frequent horizontal transfers of O-antigen clusters among non-O1 and non-O139 V. cholerae strains. However, such transfers into epidemic strains seem to have been limited, since O139 is the only known example of O-antigen transfer into an epidemic strain.

Two critical virulence factors have been associated with epidemic strains. Cholera toxin is the primary virulence factor responsible for the severe diarhheal symptoms (27), and the toxin coregulated pilus (TCP) is the primary factor responsible for efficient colonization of the human intestinal tract (52, 53). In a landmark study, Waldor and Mekalanos (57) showed that the cholera toxin genes (ctxAB) are carried on a filamentous, f1-like, single-stranded DNA phage, designated CTXφ. Also, it has been demonstrated (42, 57) that TCP serves not only as a colonization factor but also as the receptor for CTXφ. Recently, the tcpA gene has been shown (28) to be located on a pathogenicity island designated the vibrio pathogenicity island (VPI) and has been reported to be predominantly associated with epidemic and pandemic strains. Interestingly, the VPI has also been proposed (29) to be a filamentous phage, designated VPIφ. Despite the lack of further evidence of the existence of VPIφ, this idea raises the interesting possibility that there is phage-phage interaction in horizontal gene transfer (54).

Several Vibrio mimicus strains carrying VPI and CTXφ have been identified (12), and the remarkable identity at the sequence level of some of the V. mimicus and El Tor VPI genes (aldA and toxT) suggested that there was recent interspecies horizontal transfer of these factors between V. cholerae and V. mimicus. Identification of several non-O1 and non-O139 serogroup V. cholerae strains containing the tcpA gene (13, 39, 40) suggests that these strains represent the environmental reservoirs of this virulence factor. Recently, extensive analysis (38) of the VPI and CTX prophage regions of several environmental V. cholerae strains has been described, although the mechanism(s) of the origin of these strains has not been addressed.

Conservation of the genetic organization of the wb* region raises the possibility that non-O1 and non-O139 V. cholerae strains with an epidemic genetic background may have arisen by exchange of O-antigen biosynthesis regions. In order to evaluate this hypothesis, we analyzed 300 V. cholerae strains in all of the 194 known serogroups, and we found several non-O1 and non-O139 strains possessing ctxAB and tcpA genes. Four of these strains appeared to have a genetic background similar to that of the epidemic strains. DNA sequencing of the O-antigen cluster in one of the strains (O37 serogroup) revealed that most of the O1 wbe region had been replaced by a novel wb* cluster. Thus, homologous recombination-mediated O-antigen shift appears to be a general mechanism for the emergence of novel virulent strains of V. cholerae.

MATERIALS AND METHODS

Bacterial strains, growth conditions, and primers.

The bacterial strains used in this study included strains in the Shimada type culture collection (194 serotypes) (43), 36 clinical V. cholerae isolates, and 70 clinical and environmental strains from the Smith collection (44). The strains characterized in this study are listed in Table 1, and the primers used in various analyses are listed in Table 2. Media and culture conditions have been described previously (45).

TABLE 1.

Characterization of non-O1 and non-O139 V. cholerae strains with pathogenic potentiala

Strain Country Year Source Sakazaki serogroup CTXφ
VPI
ctxA ctxB rstR Clusterb tcpA
395 India 1966 Diarrhea O1 cla WT cla cla cla cla
NIH35A3 India 1941 Diarrhea O1 cla WT cla cla cla cla
5011 Unknown H. Smith collection O1 cla (O333)c WT cla cla cla cla
N16961 Bangladesh 1975 Diarrhea O1 ET WT ET ET ET ET
E7946 Bahrain 1978 Diarrhea O1 ET WT ET ET ET ET
365-96 Japan 1996 Prawn, import from Thailand O27 WT NT rstR-4∗∗d NT NTe
1322-69 India 1969 Diarrhea O37 NTf NT ET cla cla
8585 Iraq 1966 Diarrhea O53 (O340)c cla ET ET
981-75 India 1975 Diarrhea O65 cla ET ET
63-93 (MO45) India 1992 Diarrhea O139 WT ET ET ET ET
AM2 India 1995 Diarrhea O9
AM107 India 1996 Diarrhea O144
NRT36-S Japan 1990 Diarrhea O31
a

Abbreviations: wt, wild type; cla, classical; ET, El Tor; NT, novel type.

b

Presence of the entire VPI cluster based on restriction mapping and hybridization.

c

O333 and O340 are Smith serogroups.

d

rstR-4** = SCE223 (38).

e

Differs from the tcpA-env allele described by Mukhopadhyay et al. (38) at one position (O27V9D).

f

There is a single amino acid substitution (wtS46NO37).

TABLE 2.

List of primers

Primer Gene Sequence Reference(s)
J 101 gmhD1 5′-GCCATCCCACTCTGTGGTCGCAGAGCAAGCTCC-3′ 14
J 103 rjg2 5′-CCCGTGACACTCGCCTTCCCTCCGTGATGAACC-3′ 14
M 177 gmhD1 5′-TTACTTACGATTAATCAGCGCCAT-3′ 45
M 178 gmhD2 5′-GGCGGCGCTGGCATGATTGGCAGC-3′ 45
M 179 rjg1 5′-CATGGAAGTGGTTCATCACGGAGG-3′ 45
J 414 rjg2 5′-GTGGACGCGTTCAAAGCACCGAATATCCGAGTT-3′ 45
M 310 orf21 5′-GGTGACATCAAAGGGACCACTTTTTC 22; this study
M 311 orf22 5′-GGTGTATGCCACTAGTGTAGGTAAT 22; this study
M 459 IS10041 5′-CCCCAGCTTTTGACGCTTATTGTGAACGT-3′ 22; this study
M 460 IS10042 5′-GATCGATATCTTTCTAACTTCTGTATAAGG-3′ 22; this study
M 277 ctxA1 5′-ACAGAGTGAGTACTTTGACC-3′ 22; this study
M 278 ctxA2 5′-ATACCATCCATATATTTGGGAG-3′ 22; this study
S 86 ctxAB1 5′-GGCTGTGGGTAGAAGTGAAACGG-3′ 22; this study
S 87 ctxAB2 5′-CTAAGGATGTGGAATAAAAACATC-3′ 22; this study
M 279 tcpA1 5′-AAAACCGGTCAAGAGGG-3′ (same as KAR 24) 28
M 280 tcpA2 5′-CAAAAGCTACTGTGAATGG-3′ (same as KAR 25) 28
M 281 tcpA3 5′-CAAATGCAACGCCGAATGG-3′ (same as KAR 82) 28
M 590 tcpAL1 5′-GATCGCATGCCAGAGTTCTATCTTTCGTC-3′ 22; this study
M 591 tcpAL2 5′-GATCGTCGACATAGTGATAAGAGTCTTACCC-3′ 22; this study
M 668 smt1 (smt-VCA0198) 5′-CCGAAATACGGTCATTACTTGGGC-3′ 22; this study
M 669 smt2 5′-CACTTCATTATTCCCGTAAGCAGC-3′ 22; this study
M 680 smt1.1 (nupC-VCA0179) 5′-AATAGCCAATCACGCACCAAG-3′ 22; this study
M 681 smt1.2 5′-TAATCGCACTGCGGCTTTCAG-3′ 22; this study
M 682 smt2.1 (hmpA-VCA0183) 5′-TGACCCACCAGAAAACCGGAC-3′ 22; this study
M 683 smt2.2 5′-GCGCCTTATCCACACCAAGCG-3′ 22; this study
M 684 smt3.1 (rhlE-VCA0204) 5′-CGCTCAATCGCAAATAATTCC-3′ 22; this study
M 685 smt3.2 (dcuB-VCA0205) 5′-TGCTCTCTCTCCCCAAATGAC-3′ 22; this study
M 686 smt4.1 (VCA0206) 5′-GTATTGTCGGATTTCATTTGC-3′ 22; this study
M 687 smt4.2 (VCA0208) 5′-AGTGACGGCCTCTGGCGGAGC-3′ 22; this study
M 688 smt5.1 (hlyA-VCA0219) 5′-GGGTTCCGCGACACCGGATGC-3′ 22; this study
M 689 smt5.2 5′-TGTTTAATGGCTATGTTGACG-3′ 22; this study
M 698 ctxrgn1.1 (VC1444) 5′-TAATCTGCTATTTCACTGAAG-3′ 22; this study
M 699 ctxrgn1.2 5′-TTCCTGAGTGATCCCCAATCC-3′ 22; this study
M 700 ctxrgn2.1 (VC1451-rtxA) 5′-GCGGAAAAGCTGAAAGGCACC-3′ 22; this study
M 701 ctxrgn2.2 5′-ACCTTCATGGTGTGAAATCAC-3′ 22; this study
M 702 ctxrgn3.1 (VC1465) 5′-CCGCTGTCTCAATAGAACCTG-3′ 22; this study
M 703 ctxrgn3.2 5′-GGACATCATACAAGAGAAGAC-3′ 22; this study
M 704 ctxrgn4.1 (VC1470) 5′-GAACATGAACCTTAATGCGAG-3′ 22; this study
M 705 ctxrgn4.2 5′-CACGTCATTTATGAATTACGG-3′ 22; this study
M 706 ctxrgn5.1 (VC1476-VC1477) 5′-GGTATCAGCATGAGACTTTTTTG-3′ 22; this study
S 122 ctx core (orfU) 5′-CGTCACACCAGTTACTTTTCG-3′ 22; this study
S 123 ctx core (zot) 5′-AACCCCGTTTCACTTCTAC-3′ 22; this study
M 707 ctxrgn5.2 5′-CCAATAGTGATAACTACTTCG-3′ 22; this study
M 452 ald2 5′-TTTTCTTGATTGTTAGGATGC-3′ 12
M 453 ald1 5′-ATTCTTCTGAGGATTGCTGAT-3′ 12
M 644 tagD1 5′-GCGGTGACACTAAAGTAGTGTTTG-3′ 22; this study
M 645 tagD2 5′-GATGGTCAGATAAAAGAACGCAGG-3′ 22; this study
M 664 tcpAdn1 5′-TTCGCAATTACAGTCGGTGGCTTG-3′ 22; this study
M 665 tcpAdn2 5′-AGCCAACTCAGTTAAAACTTGTTC-3′ 22; this study
M 448 toxT2 5′-CTTGGTGCTACATTCATGG-3′ 12
M 449 toxT1 5′-AGGAGATGGAAGTGGTGTG-3′ 12
M 646 vpi08451 5′-ATCATTCCAGATAAAGTTACGCAGA-3′ 22; this study
M 647 vpi08452 5′-TCTACTTCCGGCTTCCCTGCCACG-3′ 22; this study
M 407 rstR1 5′-GACGTAGCGTGCGGAGTCGCGTTG-3′ 22; this study
M 408 rstR2 5′-TGAAGCATAAGGAACCGACCAAGC-3′ 22; this study
M 573 rstA1 5′-ACTCGATACAAACGCTTCTC-3′ 22; this study
M 574 rstA2 5′-AGAATCTGGAGGTTGAGTG-3′ 22; this study

DNA dot blotting and PFGE.

DNA dot blot analysis and pulsed-field gel electrophoresis (PFGE) were carried out as described previously (45).

Long-range PCR.

In order to determine the lengths of the wb* regions in various serogroup strains, long-range PCR was performed with an XL-PCR kit (Perkin-Elmer Cetus Corp., Foster City, Calif.). PCRs were performed by using 1 μg of genomic DNA as the template, primers J 101 and J 103, and the protocol and conditions recommended by the manufacturer. The PCR products were electrophoresed in 0.5% agarose gels and stained with ethidium bromide.

Sequencing of the O37 wb* region.

The entire DNA sequence of the region between the gmhD and rjg genes of an O37 serogroup strain was obtained from the XL-PCR product. The XL-PCR fragment amplified from an O37 serogroup strain, 1322-69, was digested with PstI, and the resulting fragments were gel purified, cloned in the pBluescript vector (Stratagene Corp., La Jolla, Calif.), and sequenced by primer walking. The fragments were aligned using restriction maps of the XL-PCR fragment. The order of the PstI sites was confirmed by targeted PCR and sequencing of the PCR fragments. The XL-PCR end fragments were PCR amplified, cloned in pCR2.1, and sequenced. The final aligned sequence of the O37 wb* region was analyzed by the DNASIS program (Hitachi Software Engineering Co., Ltd., South San Francisco, Calif.) in order to identify the ORFs, and the individual ORFs were searched by using the National Center for Biotechnology Information Blast program (3) for identifying protein similarities.

Isolation of wb* regions.

In order to isolate the entire wb* region on a single restriction fragment, a unique NotI site in the rjg gene at the right junction of the wb* region was utilized. A second NotI site was introduced at the left junction. In order to accomplish this, the genes orf-2 (VC0239) and gmhD (VC0240) were cloned on either side of the NotI site of the pBluescript vector, and a Kanr cassette was introduced between orf-2 and gmhD. A SacI-EcoRV fragment containing orf-2-NotI-Kanr-gmhD was blunt ended and cloned into SalI-digested and blunt-ended suicide vector pCVD442. The NotI site in the derivative of pVCD442 was introduced into the chromosomes of selected strains, as previously described (17), by the sucrose selection procedure. The resulting strains were subjected to PFGE after NotI digestion of their DNAs in agarose plugs as previously described (45). Southern analysis was performed by transfer of the restriction enzyme-digested chromosomal DNA fragments onto a nitrocellulose membrane, followed by hybridization with probes prepared by enhanced chemiluminescence (Amersham Biosciences, Piscataway, N.J.).

IS1004 fingerprinting.

Genomic DNAs were digested with HpaII, transferred onto a Zeta-probe membrane (Bio-Rad Laboratories, Hercules, Calif.), and hybridized with an IS1004 probe. Direct amplification of the IS1004 element from genomic DNA was unsuccessful, and hence, the following procedure was used to clone the IS1004 element. Primers M 459 and M 460 were used to PCR amplify a fragment (2.2 kb) encompassing an IS1004 copy and the neighboring sequences, and the fragment was cloned into the pCR2.1 vector (Invitrogen Life Technologies, Carlsbad, Calif.). The resulting plasmid was digested with EcoRI, and this was followed by purification of the EcoRI fragment containing the genomic sequences and not the plasmid sequences. This fragment was further digested with HaeIII and AvrII, and a 0.5-kb fragment containing the IS1004 sequences was cloned into an SmaI-XbaI-digested pBluescript vector. An AccI-SacII fragment of the resulting plasmid containing the insertion (IS) sequences was used as the probe.

RFLP analysis. (i) smt region.

The region analyzed by restriction fragment length polymorphism (RFLP) spanned 48,759 bp on chromosome I. The left end of the region was at coordinate 190747 within ORF VCA0174, and the right end was at coordinate 239506 within ORF VCA0219 (hlyA). This region contains nine SphI fragments. They are, in the order in which they are arranged on the chromosome, 5,201, 5,755, 705, 6,993, 11,899, 1,755, 972, 839, and 14,640 bp long. Five different probes (smtrgn 1 to 5, prepared by PCR using primers M 680 to M 689) were used to detect the various fragments. The probes were designed in such a way as to detect two fragments with a single probe. For example, the 5,201- and 5,755-bp SphI fragments are adjacent to each other, and a probe designed centrally at the SphI site could detect these two fragments.

(ii) ctx region.

The ctx region spanned a 54,715-bp region starting within ORF VC1443 (at the 5′ end of ccoN; coordinate 1539558) and ending with coordinate 1594273 within VC1488 (encoding a hypothetical protein). It included sequences upstream of RTX, the RTX cassette, RS1, and the CTX core and sequences downstream of the CTX prophage (cri, tlc, transposase, fabA, rmf, and several hypothetical proteins). The SphI fragments detected were 1,106, 13,818, 2,862, 13,387, 3,255, 1,365, 2,651, 2,180, 2,651, and 11,400 bp long, in the order in which they are arranged on the chromosome. Five probes (ctxrgn 1 to 5, prepared by PCR using primers M 698 to M 707) were used to detect these fragments.

(iii) VPI region.

The VPI region analyzed included ORFs VC0815 to VC0850 (coordinates 871612 to 915843; 44,231 bp). The VPI cluster spans coordinates 873020 (between VC0816 and VCO817) to 914296 (between VC0847 and VC0848). The XmnI fragments that were detected included 11,064-, 3,994-, 837-, 3,273-, 1,070-, 12,332-, 3,976-, and 7,685-bp fragments, and five different probes (ald, tagD, tcpAdn, toxT, vpi0845) were used.

Nucleotide sequence accession numbers.

The nucleotide sequences of the rstR, tcpA, and ctxAB genes of strain 365-96 (serogroup O27) and the wb* region of strain 1322-69 (serogroup O37) determined in this study have been deposited in the GenBank database under accession no. AF390570, AF390571, AF390572, and AF390573, respectively.

RESULTS

Conservation of the genetic organization of the wb* regions.

The gmhD and rjg genes have previously been reported (45) to be present in all of the V. cholerae serogroups examined, and the wb* regions of these genes are believed to be organized in a cluster. To further investigate the genetic organization of this region in non-O1 and non-O139 serogroups, long-range PCRs were performed using primers designed from the gmhD and rjg genes. In several serogroups (O37, O53, O65, O77, O80, and O89), the region between gmhD and rjg was amplified, and the resulting XL-PCR fragments varied in size from 18 to 28 kb (Fig. 1a). In serogroup O105, amplification of this region was not possible, perhaps because of limitations of the PCR. Perhaps the gmhD and rjg genes flank a wb* cluster that is too long to be PCR amplified, or perhaps they do not flank the wb* cluster and are present at different locations on the chromosome in this strain.

FIG. 1.

FIG. 1.

Genetic organization of the wb* regions. (a) Agarose gel electrophoresis of XL-PCR amplification products of the O-antigen biosynthesis regions (wb*) from different serogroup strains. The line at the top is a schematic diagram of the wb* region with gmhD and rjg at the ends; the primers used in XL-PCR (indicated by the small bars below the line) are situated at the 5′ ends of the gmhD and rjg genes. Lane S contained a 1-kb ladder, and lane L contained a HindIII digest of λ DNA. The positions (in kilobases) of the markers are indicated on the left. (b) PFGE and Southern analysis of the NotI fragments of O1, O139, and O105 serogroup strains. The blot was hybridized with a gmhD probe. The asterisk indicates the position of unexplained recombination intermediates or partial digestion products. Lanes 1, 3, and 5 contained parent strains without the NotI site at the left junction, and lanes 2, 4, and 6 contained the strains with the NotI sites flanking the wb* regions. Lanes 2, 4, and 6 also contained partially digested parent fragments of the wb* region in addition to the newly generated wb* fragments. (c) Southern blot analysis of the gmhD and rjg junction fragments in various strains. The genomic DNAs were digested with EcoRI and were simultaneously hybridized with the gmhD and rjg probes. The upper and lower bands in each lane are the rjg- and gmhD-specific fragments, respectively.

Thus, an alternative strategy was devised in order to investigate the organization of the wb* region in an O105 strain and to isolate the entire wb* region on a single restriction fragment. PCR and restriction analyses of the rjg gene in many serogroup strains indicated that a rare restriction enzyme site, NotI, was present in the gene. If rjg and gmhD are close to one another, introduction of a NotI site at the left junction would yield a unique NotI fragment containing the entire wb* cluster. Hence, a NotI site was introduced between orf-2 and gmhD at the left boundary of the wb* region in three strains (serogroups O1, O139, and O105), as described in Materials and Methods. Genomic DNAs of the resulting strains were digested with NotI in agarose plugs, and the fragments were separated by PFGE. A fragment that was not present in the parent strains was detected in the strains with an engineered NotI site at the left boundary (Fig. 1b, lanes 2, 4, and 6). As expected based on previously published DNA sequence data (9, 14, 18, 33, 48), the O1 and O139 NotI fragments were estimated to be 22 and 35 kb long, respectively. In the O105 strain, a 45-kb fragment was released (Fig. 1b, lane 6), indicating that the sizes of the serogroup-specific regions varied. Digestion of the chromosomal DNAs by various restriction enzymes and hybridization with gmhD and rjg probes revealed fragments of various sizes in different serogroups, indicating that the wb* regions contain unique sequences (Fig. 1c). Taken together, these data demonstrated that the wb* region is organized in a cluster.

Identification of the junctions of the O37 wb* region.

Based on the data described above, we hypothesized that the organization of the wb* regions of the non-O1 and non-O139 strains is similar to that of epidemic strains; i.e., the gmhD and rjg genes flank serogroup-specific O-antigen biosynthesis genes. In order to test this hypothesis, restriction enzyme PstI-digested O37 XL-PCR fragments (Fig. 1a) were subcloned and sequenced to see if these fragments encode polysaccharide biosynthesis genes. We chose to sequence the O37 region instead of the regions of other serogroups because this serogroup has clinical relevance and strains of this serogroup were implicated in localized cholera outbreaks in the past (2, 26). The entire O37 wb* region is 27,552 bp long, and the O37-specific sequence is 23,388 bp long. A comparison of this sequence with the sequences of the previously described wb* clusters (9, 14, 18, 33, 48, 59) revealed that there was an exchange of the wb* region, since the O37 region had some remnants of the O1 wbe region (Fig. 2). The homology breakpoints (i.e., the DNA sequences where the common backbone sequence ends and the serogroup-specific sequence starts) in O37 strains were different from those of the O1 and O139 junctions (Fig. 2 and 3). In the O37 serogroup, the left and right junctions are at gmhD and wbeV, respectively, instead of at gmhD and rjg as they are in O139 (Fig. 2). The left junction in O37 is at the gmhD locus, and the O37-specific sequence begins about 120 bp to the right of initiation codon ATG of the gmhD ORF. In contrast, the left junction in the O139 strain is at the start codon (ATG) of the gmhD locus (Fig. 3A). In the case of O37, the right junction is well within the O1 wbeV gene; i.e., part of the O1 wbe region is retained in the O37 wb* region (Fig. 3B). Previously, it was shown that the right junction in the O139 strain is at the rjg gene (right after the wbeW gene and the wbfX gene of the O1 and O139 strains, respectively) (Fig. 3C); i.e., the entire O1 wbe region has been replaced by the wbf cluster (14).

FIG. 2.

FIG. 2.

Comparison of the O37 wb* region with the O1 wbe and O139 wbf regions. The genetic organization of the wb* region of the O37 strain is compared to the genetic organizations reported previously (49) for the O1 and O139 strains. The O139, O1, and O37 regions are 35, 22, and 27 kb long, respectively. The ORFs and the directions of transcription are indicated by the arrows, and the common ORFs in the three serogroups are indicated by the same types of arrows. The common junction genes (gmhD and rjg) of the three serogroups are indicated by solid arrows. While the left junction is at gmhD in all three serogroups, the right junction in O37 is different from the right junction in O139. The O1 right junction genes, wbeV through rjg, are conserved in the O37 wb* region.

FIG. 3.

FIG. 3.

Analyses of the left junctions (LJ) and the right junctions (RJ) of O1, O139, and O37 wb* regions performed using the ClustalW program (http://www.ebi.ac.uk/index.html). The asterisks indicate identical bases in the sequences compared. (A) Left junctions of the O1, O37, and O139 wb* regions. The solid arrowhead and its orientation indicate the gmhD ORF start codon and the direction of transcription, respectively. The homology breakpoints between O1 and O37 are ca. 120 bp upstream of the start codon of gmhD since the sequences diverge near this position. The homology breakpoints of the O1 and O139 sequences are at the start codon of the gmhD ORF, since the sequences after gmhD completely diverge. (B) Right junctions of the O1 and O37 sequences. The homology breakpoint is in the wbeV ORF, which is preceded by wbeU in O1 and by orf-18 in O37. The stop codon of wbeV (indicated by the arrowhead pointing upward) overlaps with the start codon of orf-18 in O37. The stop codon of wbeV of O1 is indicated by the arrowhead pointing downward. (C) Right junctions of the O1 and O139 sequences published previously (14, 45). The homology breakpoint is at the start of the rjg ORF. The rjg genes of O1 and O139 strains have different N terminus and start codons. In all these cases, the actual recombination crossover sites could be anywhere within homologous segments far away from the homology breakpoints and not necessarily at the junctions.

O37 wb* region.

The O37 wb* cluster is unique, since we did not observe any significant DNA homology between the O37-specific sequences and the previously published V. cholerae wb* cluster sequences except at the right junction (see above). Twenty-three ORFs were identified in the O37 wb* region, and as expected, many of the orf genes (orf-1 to -13 and orf-18) (Fig. 2) encode enzymes involved in polysaccharide biosynthesis. orf-14 and orf-15 encode hypothetical proteins of unknown functions. orf-14 has very weak homology (26% identical and 46% positive in a 64-amino-acid region) to yhfO (which encodes a hypothetical protein) of Bacillus subtilis. A 1,549-bp promoter region separates gmhD and orf-1, and this region contains a putative promoter and ops elements found in known polysaccharide biosynthesis regions (4, 23). As seen in other wb* regions, there is an IS element in the interval between the region that is unique to O37 and the right junction, and this element, which appears to contain an insertion of another fragment encoding a transposase, spans 3,580 bp and has an 18-bp inverted repeat at its ends. The original IS element is 1,054 bp long and is virtually identical (95% identical at the DNA level; the transposase is 90% identical [278 of 306 amino acids]) to the IS elements found in Vibrio parahaemolyticus (ISV-3L, ISV-5R, ISV-5L, ISV-4R) (55). Interestingly, the tnp gene of the V. cholerae element is interrupted after the 76th amino acid residue by a 2,527-bp DNA fragment. This insert encodes an ORF (orf-17) that is transcribed in the opposite direction and has extensive homology to transposases of various IS elements found in other bacterial species. The region downstream of the IS element has three ORFs almost identical to the O1 wbe cluster: wbeV, galE, and wbeW followed by rjg. The wbeV gene in the O37 strain appears to consist of three small ORFs. Thus, these data clearly demonstrate that (i) the region between gmhD and rjg in the O37 serogroup encodes O-antigen biosynthesis genes and (ii) the O37 wb* region originated by homologous recombination-mediated exchange of wb* gene clusters.

Identification of non-O1 and non-O139 strains containing virulence genes.

Based on the data described above, we reasoned that a homologous recombination event flanking the gmhD and rjg genes may result in non-O1 and non-O139 pathogens similar to O139 strains. In order to identify O139 Bengal-like strains that originated by exchange of wb* clusters, 300 V. cholerae strains were screened for the presence of the ctxAB and tcpA genes, which are known to be present in epidemic and pandemic strains. DNA dot blot analysis was performed by using the ctxAB and tcpA genes as the probes. Fifteen non-O1 and non-O139 strains were found to be tcpA+. All of these strains also carried three other genes (aldA, toxT, and int) of the VPI cassette, which indicated that the entire VPI may be present in these strains. Thirteen strains carried the rstR and rstA genes; nine of these strains also carried the ctxAB genes; and two strains did not carry any of these three genes. Of the four ctxAB mutant strains, one carried just the rstR and rstA genes, while the three other strains carried the rstR and rstA genes and the genes of the core region except the ctxAB genes (data not shown). Further characterization of 4 of the 15 tcp+ strains (serogroups O27, O37, O53, and O65) indicated that they contained the entire VPI and a pre-CTXφ (CTXφ without the ctx genes) or a CTXφ. These four strains had genetic backgrounds very similar to those of the epidemic O1 strains (see below), thus indicating that there was an O-antigen shift in an O1 strain.

Genetic relatedness of the non-O1 and non-O139 strains to the epidemic strains as determined by IS1004 fingerprinting and RFLP analysis.

In order to determine the genetic relatedness among the various strains and to determine which of these strains resulted from an O-antigen shift in an epidemic strain, IS1004 fingerprinting and RFLP analyses were performed.

IS1004 is an IS element present in multiple copies in O1 classical and El Tor strains, and it has been used previously (8) for typing V. cholerae strains. In agreement with a previous report (8), O1 classical and El Tor strains exhibited unique fingerprints; i.e., the classical and El Tor strains had six and four IS1004 copies, respectively (Fig. 4a, lanes O1 cla and O1 El Tor). In the present analysis, the O27 and O139 strains were identical to the El Tor strains (Fig. 4a, lanes O139 and O27), and the O37 strain was similar to the classical strains (Fig. 4a, lane O37). The O53 and O65 strains exhibited some similarity to both O1 El Tor and O1 classical strains and thus appeared to have diverged early from the progenitor of the O1 strains (Fig. 4a, lanes O53 and O65).

FIG. 4.

FIG. 4.

IS1004 fingerprinting and RFLP analyses of the various serogroup strains. (a) IS1004 fingerprints of HpaII-digested chromosomal DNAs of various V. cholerae strains. Since HpaII does not cut within IS1004, each band represents one copy of the element. (b) RFLP analysis of the smt region of chromosome II of various V. cholerae strains. The genomic DNAs were digested with SphI and hybridized simultaneously with multiple probes (smtrgn 1 to 5). The identities of the bands were deduced from their predicted sizes, based on the published V. cholerae genome sequence (22), and they were confirmed by separately hybridizing the same blot with individual probes. The sizes of the molecular weight markers (in kilobases) are indicated on the left. (c) Blot used in panel b rehybridized with an smt probe (primers M 668 and M 669). Lanes O144, O9, and O27 were omitted since they did not show any hybridizing band with this probe.

Further evidence of genetic similarity among the strains was obtained by RFLP analyses of two regions of chromosomes I and II. For this analysis, the vps (vibrio polysaccharide synthesis) (22) operon from chromosome I and a region on chromosome II that contains a site-specific methyl transferase gene (smt-VCA 0198) were chosen. Restriction enzyme SphI-digested genomic DNAs were hybridized with various probes (described in Materials and Methods). The RFLP patterns of the vps regions of the O1 classical and El Tor strains and the four non-O1 and non-O139 strains (serogroups O27, O37, O53, and O65) were identical, whereas many other non-O1 and non-O139 strains had extensive variations (data not shown).

The smt region in the classical and El Tor strains exhibited unique RFLP patterns (Fig. 4b). The RFLP patterns of the smt region of the O139 and O27 strains were identical to those of the El Tor strains (Fig. 4b, compare lanes O1 El Tor to lanes O139 and O27), and the RFLP patterns of the O37, O53, and O65 strains were similar but not identical to the pattern of the smt region of either the classical or El Tor strains. Furthermore, the smt gene was found only in strains that have an O1 backbone (Fig. 4c). None of the non-O1 and non-O139 strains used in this analysis (O9, O31, and O144) have an O1-like backbone, as determined either by IS1004 fingerprinting (Fig. 4a, lanes O144, O9, and O31) or by RFLP analyses (Fig. 4b, lanes O144, O9, and O31), and they lacked the smt gene. Taken together, IS1004 fingerprinting and RFLP analysis results indicated that the four non-O1 and non-O139 strains were derived from an epidemic strain by wb* cluster exchange and subsequently diverged. A DNA sequence analysis of one of the wb* regions (serogroup O37) determined in this study (see above) supports this conclusion.

Genetic organization of the CTX prophage and VPI regions of the non-O1 and non-O139 strains.

We reasoned that exchange of the wb* region in an O1 strain would result in a non-O1 and non-O139 strain containing either the classical or El Tor ctx and VPI regions. In order to determine the structural organization of the ctx region in the non-O1 and non-O139 strains examined in this study, chromosomal DNAs were digested with EcoRI (an enzyme that does not cut within the CTXφ genome), and the fragments were hybridized with rstA, rstR, ctx core, and ctxAB gene probes. As expected, there was diversity in the arrangement and location of the CTX prophage genomes in various strains. The sizes of the fragments of the second CTX prophage copy (chromosome II) varied in the three classical strains analyzed [Fig. 5a, upper panel, lanes 395 (O1 Cla), NIH35-A3 (O1 Cla), and 5011 (O1 Cla)]. Like O1 El Tor and O139 strains, the O37 strain had a chromosome I copy(ies) of CTXφ [Fig. 5a, upper panel, lanes N16961 (O1 El Tor), E7946 (O1 El Tor), O37, and O139], and the O27 strain also contained a single copy (Fig. 5a, lane O27). The same fragment was detected when the blot was hybridized with rstA or rstR or ctx core probes in all of the strains except the O53 and O65 strains (Fig. 5a, lower panel). These two strains produced a single band when they were hybridized with rstA or rstR or ctx core probes (Fig. 5a, lower panel, lanes O53 and O65) but did not hybridize with any band when the ctxAB probe was used.

FIG. 5.

FIG. 5.

RFLP analysis of the virulence regions of the various strains. (a) EcoRI-digested genomic DNAs were probed with ctxAB gene probes (upper panel) and the ctx core probe (lower panel). EcoRI does not cut within the CTXφ genome, and each hybridizing band therefore represents one copy of CTX present in a strain. (b) SphI-digested genomic DNAs of the strains were probed with five probes spanning a 45-kb region surrounding the CTXφ genome integrated on chromosome I. The probes and the sizes of the fragments and the corresponding bands are as follows: ctxrgn 1, 1,106 and 13,818 bp (bands a and j); ctxrgn 2, 2,862 and 13,387 bp (bands e and b); ctxrgn 3, 3,255 and 1,365 bp (bands d and i); ctxrgn 4, 2,651 and 2,180 bp (bands f and h); and ctxrgn 5, 2,651 and 11,400 bp (bands g and c). (c) Genomic DNAs digested with XmnI and probed simultaneously with five different probes from the VPI region. The identities of the bands were confirmed by separate hybridization with individual probes. The probes and the sizes of the fragments and the corresponding bands are as follows: ald, 11,064 bp (band b); tagD, 3,994 bp (band e) and 837 bp (band h); tcpAdn, 3,273 bp (band f) and 1,070 bp (band g); toxT, 12,332 bp (band a); and vpi0845, 3,976 bp (band d) and 7,685 bp (band c).

To further elucidate the genetic organization, the ctx region on chromosome I was analyzed by RFLP. The region analyzed encompassed about 54,715 bp, which included the RTX cassette, CTXφ, and the sequences upstream and downstream of them. Figure 5b shows that the O37 and O139 strains have an El Tor-like organization (compare lane O1 El Tor to lanes O37 and O139). The O27, O53, and O65 strains resembled El Tor strains in the RTX cassette segment (bands a and b were produced only by El Tor strains and not by a classical strain [Fig. 5b]) but differed from epidemic strains by lacking the pTLC element (Fig. 5b, compare lanes O1 Cla, O1 El Tor, O37, and O139 to lanes O27, O53, and O65, bands f/g, h, and i).

We analyzed the VPI region in the non-O1 and non-O139 strains examined in this study. Digestion of the genomic DNAs with XmnI, followed by hybridization of the blot with five different probes spanning the entire VPI region, resulted in identification of seven and eight fragments in the O1 classical and El Tor strains, respectively (Fig. 5c, lanes O1 Cla and O1 El Tor). Among the other strains, the O37 strain had a classical VPI cluster (Fig. 5c, compare lanes O1 Cla and O37), the O53, O65, and O139 strains had an El Tor VPI cluster (compare lane O1 El Tor to lanes O139, O53, and O65), and the O27 strain appeared to contain a novel VPI cluster (Fig. 5c, lane O27). Further hybridization analyses with additional probes indicated that the O27 strain had the entire VPI cluster with two additional XmnI sites (data not shown).

DNA sequence of the rstR, ctxAB, tcpA, and aldA genes of the non-O1 and non-O139 strains.

In order to understand further the origin of the ctx and VPI regions, the rstR gene (which encodes the repressor of CTXφ and determines the phage immune specificity) and the ctxAB genes of CTXφ and the tcpA and aldA genes of the VPI were sequenced. These genes are known to be different in classical and El Tor biotypes (15, 30, 31, 32). The results are summarized in Table 1.

The rstR genes were PCR amplified, cloned into the pCR2.1 vector, and sequenced. Strains of serogroups O37 and O139 had an rstR allele with El Tor specificity, the O53 and O65 strains had classical immune specificity and the O27 strain had novel specificity. The rstRO27 allele, whose specificity differs from that of the classical, El Tor, and Calcutta CTXφs, is identical to the recently reported rstR-4** gene (38) encoding an RstR repressor protein that is 86 amino acids long.

We sequenced the ctxAB genes of the two non-O1 and non-O139 (O27 and O37) strains in order to identify the variations in the ctx genes in various serogroups. The O53 and O65 strains did not possess ctx genes. The O27 and O37 strains possessed highly conserved ctxAB genes; i.e., the 1,152 bp of their ctxAB genes differed by less than three or four nucleotides, and their proteins differed by two or three amino acids (CtxA, cla/ETS46NO37; CtxB, cla/ETQ24HO27, cla/ETD28AO27, cla/ETF46LO37, and cla/ETK55NO37, where cla indicates classical and ET indicates El Tor). In addition to these changes, the CtxBO27,O37 alleles were identical to the classical alleles at two other positions, ETY39Hcla/O27/O37 and ETI68Tcla/O27/O37.

A 1.4-kb fragment encompassing the tcpA gene was PCR amplified, and the tcpA gene was sequenced. The tcpAO37 allele was identical to the tcpAcla allele, the tcpAO53,O65 alleles were identical to the tcpAET allele, and the O27 strain had a novel allele. The tcpAO27 allele is identical to the recently reported tcpA-env allele (38) except for a single amino acid substitution (cla/ETV9DtcpA-env). In contrast to the tcpA alleles, the aldA genes of the strains exhibited very few variations (data not shown).

DISCUSSION

Antigenic shift and emergence of novel pathogens.

Exchange of polysaccharide biosynthesis clusters resulting in novel pathogens has been well documented in many bacterial pathogens, such as Streptococcus pneumoniae and Neisseria meningitidis (16, 24, 51). Previous phylogenetic studies of V. cholerae (8, 46) indicated that exchange of wb* regions may be common in this species. Moreover, the O-antigen diversity and conservation of the structural architecture of the wb* regions seen in V. cholerae provide ample opportunity for O-antigen shifts resulting from exchange of wb* regions. Serogroup changes in nonpathogenic V. cholerae may not have serious consequences and may go unnoticed, whereas in pathogenic backgrounds, such as O1, antigen shifting may result in novel pathogens (e.g., V. cholerae O139 Bengal, which causes cholera epidemics even in populations immune to V. cholerae O1).

The non-O1 and non-O139 strains identified in this study further expand the repertoire of V. cholerae strains with epidemic potential and underscore the idea that the emergence of the O139 serogroup was not a unique event. The genetic relatedness of the four non-O1 strains, based on IS1004 fingerprinting and RFLP analyses, was supported by an extensive multilocus sequence typing analysis in which these four strains always clustered with the epidemic strains (data not shown). Interestingly, the four strains diverged further by acquiring different virulence cassettes or parts of cassettes. For example, the O37 serogroup strain with a classical backbone and a classical VPI acquired an El Tor CTXφ, the O53 and O65 strains with an El Tor backbone acquired a preclassical CTXφ (without the ctx genes), and the O27 strain with an El Tor backbone acquired a novel CTXφ and a VPI cluster. Thus, it appears that the genetic backbone, wb* cluster, VPI, and CTX regions have evolved as independent units.

The O37 wb* region DNA sequence determined in our study revealed that the O37 strain resulted from an exchange of the O1 wbe cluster with a wb* O37 cluster, similar to the event that occurred in the O139 serogroup. However, the homology breakpoints in O37 are different from the breakpoints of the O139 junctions. Unlike O139, in which the entire wbe region has been replaced by the wbf region, in O37 some of the O1 wbe genes closer to the right junction have been retained, which provides further support for the idea that the O37 strain emerged from an O1 strain by O-antigen shifting. Although the precise crossover points in this recombination event cannot be predicted from the sequence, phage-mediated transfer of the donor wb* cluster would place the crossover sites closer to the wb* junctions, due to the large size of the wb* clusters (25 to 45 kb) and the general packaging limits of transducing phages. On the other hand, conjugational transfer does not impose such constraints, and the actual crossover could occur anywhere, even kilobases away from the junctions in the homologous segments flanking the divergent wb* clusters. It is also possible that the wb* junctions are hyperrecombinogenic. Such a proposal has been advanced before (50), and chi-like sequences have been found at the junctions of wb* clusters in Escherichia coli and Klebsiella spp.

The sequence of the O37 wb* region has also revealed the putative genes responsible for synthesis of the receptor of an O1-specific generalized transducing phage, CP-T1. The O1 O-antigen has been postulated to be the receptor for the phage (21), and CP-T1 has recently been reported (10) to be able to infect O37 serogroup strains as well. Our sequence analysis suggests that the three genes (wbeV,  galE, and wbeW) shared by the O1 and O37 wb* regions are directly involved in a step in the synthesis of the phage receptor component of the O-antigen.

Based on the XL-PCR and hybridization data (Fig. 1), we predict that the O27, O53, O65, O77, O80, and O139 strains probably have similar left junctions. The left and right junctions in the O53 and O65 strains may be similar since the sizes of the EcoRI junction fragments are the same (Fig. 1c) and the sizes of the wb* regions of these two strains are also similar, indicating that the strains may have minor variations in their wb* regions. These hybridization data further suggest that the three other strains (serogroups O27, O53, and O65) which have backbones very similar to those of O1 strains probably arose by exchange of wb* clusters.

Heterogeneity in the genetic organization of CTX prophage.

Heterogeneity in the genetic organization of the CTX prophage region in various strains of V. cholerae has been documented previously. For example, O1 classical strains have two copies of the CTXφ, one located on each of the two chromosomes. Also, some El Tor strains contain a single copy, while many others have two or more copies arranged in tandem on chromosome I (5, 12, 15, 31, 32, 34). V. cholerae O139 strains are similar to O1 El Tor strains in that they have two copies of the CTXφ arranged in tandem on chromosome I (5, 56). There was remarkable diversity in the CTXφs of the four strains identified in this study with respect to the arrangement of the copies and their gene sequences.

VPI is not unique to epidemic serogroups.

Unlike the ctx region, the VPI has not been analyzed in great detail in any strain other than O1 classical and El Tor strains (30) and, recently, several environmental strains (38). A few studies have examined the tcpA gene from non-O1 and non-O139 serogroup strains, and they have identified several tcpA variants (13, 20, 39, 40). These studies, together with our results, clearly demonstrate that the VPI is not unique to the epidemic and pandemic O1 and O139 Bengal strains, as was originally reported (28). While some of the non-O1 and non-O139 pathogens (O27, O37, and O139) have been derived from O1 strains, independent acquisition of these virulence factors via phage-mediated transfer in multiple O serogroup strains has also been observed, and many of these non-O1 and non-O139 strains have a full complement of the VPI cluster (unpublished data).

Model for the emergence of virulent V. cholerae strains.

Since TCP has been demonstrated to be the receptor for CTXφ, a two-step model for the origin of virulent V. cholerae strains has emerged (10, 19, 35). In the first step, VPI is horizontally acquired by a nontoxigenic strain, and the TCP produced by the VPI-containing strain serves as the receptor for CTXφ, which leads to the second step, in which the CTXφ carrying ctxAB genes is acquired. This model is supported by the findings that (i) CTXφ and VPI are associated with a majority of the O1 and O139 strains and (ii) CTXφ VPI+ non-O1 and non-O139 strains have been occasionally found, whereas CTXφ+ VPI non-O1 and non-O139 strains are rare (19). However, to account for these rare strains, a TCP-independent mechanism of acquisition of CTXφ has been proposed, which involves a generalized transducing phage, CP-T1 (10). Data obtained during our studies not only support the two-step model (none of the 300 non-O1 and non-O139 strains screened by us was CTXφ+ VPI) but also delineate some of the additional steps involving O-antigen exchange (Fig. 6). As proposed before (11), classical and El Tor biotype strains originated, diverged, and subsequently acquired the classical and El Tor VPI and CTXφs from a nonpathogenic V. cholerae progenitor (O1 serogroup) strain that did not possess either VPI or CTXφ. The pre-CTX phages evolved independently, as revealed by their distinct rstR alleles (11; unpublished data), and ctxAB genes were subsequently acquired by a horizontal transfer event, as revealed by the different ctx alleles in O27 and O37 strains.

FIG. 6.

FIG. 6.

Model for emergence of the non-O1 and non-O139 strains with epidemic potential by O-antigen switching. A dendrogram of the genetic relatedness of the various serogroups, based on IS1004 fingerprinting analysis, is shown on the left. The O37 strain appears to have been derived from an O1 preclassical strain (classical VPI cluster) by O-antigen shifting, divergence, and subsequent acquisition of an El Tor CTXφ. The El Tor strains diverged from classical strains, acquired a distinct CTXφ, and probably acquired a tcpA allele by recombination (30). The O139 strain appears to have been derived from an El Tor strain by O-antigen switching, and the O27 strain appears to have been derived from an El Tor progenitor and to have acquired a distinct CTXφ and a distinct VPI. It is also probable that O27 emerged from an El Tor strain by O-antigen switching and subsequently changed its rstR and tcpA genes by allelic exchange. The O53 and O65 strains have an El Tor VPI cluster and are identical to each other. They have genetic backbones resembling those of both classical and El Tor strains, and hence, they probably emerged from an O1 progenitor, diverged, and subsequently acquired a classical pre-CTXφ and and an El Tor VPI. These two strains probably underwent O-antigen switching events independently or sequentially, from O1 to O53 and O65. Cl, classical; ET, El Tor; NT, novel type (38).

Based on our data, the O37 strain seems to have arisen from the classical strain progenitor (classical backbone and VPI) by changing its O-antigen, diverging, and subsequently acquiring an El Tor CTXφ. The O53 and O65 strains seem to have originated from an O1 progenitor (backbone showing similarity to both O1 classical and El Tor) by changing O-antigens (sequentially or independently) and then diverging and acquiring an El Tor VPI and a classical pre-CTXφ. The O27 strain originated from an El Tor progenitor (El Tor backbone) and acquired a novel VPI (novel tcpA allele) and a novel CTXφ. The tcpA gene and presumably the rstR gene evolved by recombination from a common VPI and CTXφ rather than as different phages. The idea of a mosaic pattern of similar and divergent genes within VPI was proposed recently based on analyses of the VPI of several environmental V. cholerae strains (38). A comparison of the complete VPI sequences of a classical strain and an El Tor strain also supports the role of recombination in the evolution of VPI (30). Thus, a change in the O-antigen of the O27 strain may have occurred in the progenitor prior to acquisition of the VPI and CTX phages, or the O27 strain may have originated directly from an El Tor strain and its rstR and tcpA genes may have subsequently been altered by allelic exchange.

Our data demonstrate that genetic switching of O-antigen biosynthesis regions resulted in the emergence of at least some non-O1 and non-O139 V. cholerae strains having pathogenic potential (i.e., containing the known V. cholerae virulence regions VPI and CTX prophage). The nonrandom distribution of these virulence markers in various V. cholerae serogroups (not all 200 serogroups have these virulence factors) suggests that horizontal transmission of virulence genes may not be similarly effective or frequent in various V. cholerae strains. The underlying mechanisms for this phenomenon are not clear at this time. However, the data presented in this paper improve our understanding of the evolution of the species and provide insight into the possible mechanisms for emergence of epidemic V. cholerae strains and serogroups from nonepidemic V. cholerae strains and serogroups. From a public health standpoint, our data raise the possibility that existing V. cholerae vaccines may provide little or no protection against the newly identified pathogenic strains, and they suggest that there is a need for novel strategies for developing vaccines against V. cholerae.

Acknowledgments

We thank Nick Ambulos and Lisa Sadzewicz (UMAB Bioploymer Laboratory) for DNA sequencing and primer synthesis. Thanks are also due to Rick Blank, Arnold Kreger, and an anonymous reviewer for helpful comments on the manuscript and to Judy Johnson for providing access to the Smith strain collection.

Funding for this study was provided by a grant from the Department of Veterans Affairs (to J.G.M.), by grant RO1 GM60791 from the National Institutes of Health (to J.G.M.), by a University of Maryland intramural grant (to S.S.), and by BREF intramural support from the Department of Veterans Affairs (to S.S.).

Editor: D. L. Burns

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