Comparative Genomic Analyses of the Vibrio Pathogenicity Island and Cholera Toxin Prophage Regions in Nonepidemic Serogroup Strains of Vibrio cholerae

Two major virulence factors are associated with epidemic strains(O1 and O139 serogroups) of Vibrio cholerae: cholera toxin encodedby the ctxAB genes and toxin-coregulated pilus encoded by thetcpA gene. The ctx genes reside in the genome of a filamentousphage (CTX ${phi}$ ), and the tcpA gene resides in a vibrio pathogenicityisland (VPI) which has also been proposed to be a filamentousphage designated VPI ${phi}$ . In order to determine the prevalence ofhorizontal transfer of VPI and CTX ${phi}$ among nonepidemic (non-O1and non-O139 serogroups) V. cholerae, 300 strains of both clinicaland environmental origin were screened for the presence of tcpAand ctxAB. In this paper, we present the comparative geneticanalyses of 11 nonepidemic serogroup strains which carry theVPI cluster. Seven of the 11 VPI⁺ strains have also acquiredthe CTX ${phi}$ . Multilocus sequence typing and restriction fragmentlength polymorphism analyses of the VPI and CTX ${phi}$ prophage regionsrevealed that the non-O1 and non-O139 strains were geneticallydiverse and clustered in lineages distinct from that of theepidemic strains. The left end of the VPI in the non-O1 andnon-O139 strains exhibited extensive DNA rearrangements. Inaddition, several CTX ${phi}$ prophage types characterized by novelrepressor (rstR) and ctxAB genes and VPIs with novel tcpA geneswere found in these strains. These data suggest that the potentiallypathogenic, nonepidemic, non-O1 and non-O139 strains identifiedin our study most likely evolved by sequential horizontal acquisitionof the VPI and CTX ${phi}$ independently rather than by exchange ofO-antigen biosynthesis regions in an existing epidemic strain.

INTRODUCTION

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Introduction

Vibrio cholerae is a serologically diverse, environmental, gram-negativebacterial species. Although V. cholerae comprises more than200 O-antigen-based serogroups (35), only the O1 and O139 serogroupstrains are known to cause epidemics of cholera, a severe diarrhealdisease. Ever since cholera epidemics caused by V. choleraeO139 Bengal surfaced in 1992 in the Bay of Bengal region (1,31), there has been renewed interest in the pathogenesis andevolutionary mechanisms of non-O1 vibrios. Several studies havereported (8, 9, 11, 15, 28-30, 33, 36) the presence of the twovirulence genes found in epidemic strains, tcpA and ctxAB, inenvironmental and clinical strains of serogroups other thanO1 and O139. However, the mechanisms of origin of these strainsare not completely understood at the present time.

Cholera toxin encoded by ctxAB is responsible for the severediarrheal symptoms elicited by the bacterium (20), and toxin-coregulatedpilus (TCP) encoded by tcpA is responsible for efficient colonizationof the human intestinal tract by the bacterium (42, 43). Inaddition, the O antigen is the bacterium's major protectiveantigen, and therefore, changes in the O antigen of a preexistingepidemic strain may result in a new pathogen capable of causingdisease in populations immune to the original epidemic strain(1, 31). For example, the V. cholerae O139 Bengal strain emergedfrom an O1 epidemic strain by genetic exchange of O-antigenbiosynthesis regions (3, 26, 40), and O139 strains cause diseasein persons immune to O1 strains (4, 27).

The ctxAB genes are carried in the genome of a filamentous,single-stranded DNA phage designated CTX ${phi}$ (44), and their disseminationto nonpathogenic strains may, therefore, occur via phage-mediatedhorizontal gene transfer. Since the discovery of CTX ${phi}$ , intra-and interspecies transfers of ctxAB genes in V. cholerae andVibrio mimicus, via CTX ${phi}$ -mediated transduction, have been demonstratedunder both laboratory and natural conditions (6, 7, 13, 14).

The TCP structural gene, tcpA, has been mapped (21) to a genecluster designated the vibrio pathogenicity island (VPI), andthe VPI has recently been proposed (22) to also be a filamentousphage, VPI ${phi}$ . Unlike for the CTX ${phi}$ , convincing data are lackingfor the existence or the horizontal transfer of VPI ${phi}$ . At thepresent time, none of the 29 genes in the VPI (other than tcpA)has been assigned, based on experimental data, any functionin the proposed phage's life cycle or phage transduction. However,TCP has clearly been demonstrated (32, 43, 44) to be the receptorfor CTX ${phi}$ and to be the bacterium's colonization factor.

V. cholerae non-O1 and non-O139 strains have been occasionallyisolated from humans with gastroenteritis, extraintestinal infections,and cholera-like illness (20, 34). Strains of serogroup O37have been implicated in localized outbreaks of cholera in thepast (2, 19). In addition, Mukhopadhyay et al. (28) reportedthe identification and genetic characterization of potentiallypathogenic non-O1 and non-O139 V. cholerae strains from environmentalsamples in the Calcutta region. However, how frequently potentiallyepidemic non-O1 and non-O139 strains arise, and how widely theyare distributed in nature, are not known at the present time.

Thus, the aims of our studies were to identify potentially pathogenicnon-O1 and non-O139 strains in a large collection of V. choleraeisolates not examined previously and to determine the identifiedstrains' evolutionary history. Here we report the identificationand comparative genetic analyses of diverse non-O1 and non-O139strains which possess VPI only or VPI and pre-CTX ${phi}$ (a precursorof CTX ${phi}$ which lacks ctxAB genes) (7) or CTX ${phi}$ prophage and havedistinct lineages compared to the epidemic strains, thus indicatingindependent horizontal transfer and acquisition of the virulenceregions. While this manuscript was under preparation, Boyd andWaldor (8) also reported the evolutionary and functional analysesof several novel TcpA alleles carried by non-O1 and non-O139strains.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and growth conditions.
The V. cholerae strains used in the preliminary screening forthe presence of tcpA and ctxAB included 194 serogroup strainsfrom the Shimada type culture collection (35), 36 clinical strains,and 70 clinical and environmental strains from the Smith collection(37). N16961 and 395 represented the O1 El Tor and O1 classicalstrains, respectively. Other strains characterized in detailare described in Table 1. Bacterial strains were grown in Luria-Bertanimedium, and other methods pertaining to bacterial growth andstorage conditions have been described previously (38).

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TABLE 1. Characterization of non-O1 and non-O139 V. cholerae strains with pathogenic potential^g

PCR.
PCR amplification of various segments of the VPI and CTX regionsto be used as probes in dot blot and restriction fragment lengthpolymorphism (RFLP) analyses and PCR amplification of the tcpA,rstR, pgm, recA, and gyrB genes for sequencing were performedby using Taq DNA polymerase (Promega Corp. Madison, Wis). Primersused in PCRs were reported previously (25) and were designedbased on the V. cholerae genome sequence (16). Five additionalpairs of primers used to prepare PCR probes to characterizethe left end of the VPI and the primers used to amplify fragmentsof pgm (phosphoglucomutase), gyrB, and recA for multilocus sequencetyping (MLST) are listed in Table 2. For most PCRs, the amplificationconditions were as follows: 92°C for 5 min, followed by35 amplification cycles, each consisting of sequential incubationat 92°C (30 s), 55°C (1 min), and 72°C (1 to 2 min),and a final extension at 72°C (5 min). In some PCRs, optimalannealing temperatures were determined by gradient PCR analysiswith a Robocycler Gradient 96 (Stratagene, Inc.) thermocycler.

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TABLE 2. List of primers

MLST.
A 900-bp fragment of pgm, a 650-bp fragment of gyrB, a 785-bpfragment of recA, a 1.8-kb fragment encompassing the tcpA gene,and a 1.5-kb fragment of the ctxAB genes were PCR amplified,and the amplified fragments were sequenced (in both directions)by using the BigDye terminator cycle sequencing kit (AppliedBiosystems, Inc., Foster City, Calif.) and either an ABI 377Prism automated sequencer or an ABI 3700 DNA analyzer (AppliedBiosystems, Inc.). Sequence alignments and dendrograms weregenerated as described previously (24) by using the Clustal-X(18) and PAUP (D. Swofford, Sinauer Associates, Sunderland,Mass.) programs, respectively. The rstR gene (750 bp) was PCRamplified with primers M407 (rstR1) and M408 (rstR2) (25), subclonedin the pCR2.1 vector (Invitrogen Life Technologies, Carlsbad,Calif.), and sequenced. When two different-sized fragments wereobtained in a PCR of a single strain, the fragments were gelpurified, cloned separately, and sequenced.

DNA dot blot and Southern analyses.
Screening for the presence of tcpA and ctxAB was performed byDNA dot blot analysis as described previously (38). The presenceof the aldA, toxT, int, rstR, and rstA genes was determinedby Southern hybridization of the genomic DNAs with PCR fragmentsof these genes amplified from an El Tor strain, N16961. TherstA gene was PCR amplified with primers M573 (rstA1) and M574(rstA2) (Table 2), and all of the other primers were reportedearlier (25).

RFLP analysis.
Two $~$ 50-kb genomic segments encompassing the VPI and CTX ${phi}$ prophageregions were analyzed by RFLP. Genomic DNAs were restrictiondigested with XmnI (for analysis of the VPI region) and withEcoRI or SphI (for analysis of the ctx region), electrophoresedin an agarose gel, transferred onto a Zetaprobe membrane (Bio-RadLaboratories, Hercules, Calif), and simultaneously hybridizedwith multiple nonradioactive probes prepared with an enhancedchemiluminescence kit (Amersham Biosciences, Piscataway, N.J.).Hybridization conditions, the various probes, the lengths andorder of the restriction fragments probed, and the exact endpointsof the two regions analyzed by RFLP were reported previously(25). The identity of the individual bands was confirmed byhybridizing the same blot with individual probes.

Nucleotide sequence accession number.
The nucleotide sequences of the rstR (accession numbers AF452585to AF452586),tcpA (accession numbers AF452570 to AF452580),ctxA (accession numbers AF452584, AF46340, and AF463401), ctxB(accession numbers AF463402 and AF452581 to AF452583), and gyrBalleles (accession numbers AF501888 to AF501913) of the non-O1and non-O139 serogroup strains have been deposited in the GenBankdatabase.

RESULTS

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Results

Identification of non-O1 and non-O139 strains containing VPI and CTX ${phi}$ .
To determine the prevalence of tcpA and ctxAB in non-O1 andnon-O139 V. cholerae, 300 strains were screened by DNA dot blotanalysis for the presence of the genes. Fifteen non-O1 and non-O139strains carried the tcpA gene, 9 of the 15 strains carried thectxAB genes, and none of the 300 strains carried ctxAB alone.The 15 tcpA⁺ strains were further analyzed, by Southern hybridization,for the presence of other genes in the VPI and CTX regions,and the results are summarized in Table 3. All of the tcpA⁺strains also carried three other genes, aldA, toxT, and int,from the left, middle, and right ends of the VPI cluster, respectively,which indicated that the entire VPI region might be presentin these strains. Thirteen of the 15 tcpA⁺ strains carried rstRand rstA of the CTX ${phi}$ genome, and two other strains (serogroupsO77 and O80) did not carry any of the CTX ${phi}$ genes. Nine of the13 rstA⁺rstR⁺ strains also carried ctxAB, one strain (serogroupO115) carried only rstA and rstR, and three strains (serogroupsO48, O53, and O65) carried rstR, rstA, and the genes of thecore region, except ctxAB. Li et al. (25) previously reportedthe genetic characterization of four of the 15 strains (serogroupsO27, O37, O53, and O65) carrying the entire VPI and a CTX ${phi}$ ora pre-CTX ${phi}$ (7), i.e., CTX ${phi}$ lacking the ctxAB genes and an epidemicgenetic backbone. In the present study, we examined the 11 remainingstrains which have genetic backbones different from those ofthe epidemic strains, and we found that seven of the strainscarried the CTX ${phi}$ , one carried the pre-CTX ${phi}$ , and one only had therepeat sequence element.

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TABLE 3. Classification of screened V. cholerae strains^a

Genetic relatedness of the non-O1 and non-O139 strains to the epidemic strains.
To determine the genetic relatedness of the 11 tcpA⁺ nonepidemicstrains to the tcpA⁺ epidemic strains, MLST was performed. A900-bp fragment of pgm (phosphoglucomutase), a 650-bp fragmentof gyrB, and a 785-bp fragment of recA were sequenced. The nucleotidesequences were analyzed by using the maximum-parsimony and maximum-likelihoodmethods reported previously (17) to be well suited for determiningphylogenetic relationships among various bacterial strains andspecies, and both methods gave consistent results for each ofthe three genes. The epidemic and nonepidemic strains were topologicallyseparated into two major branches of the phylogenetic tree.The phylogram (Fig. 1) generated for one of the genes (gyrB)revealed a tight clustering of the strains of epidemic serogroups(O1 and O139) and strains of four other serogroups (O27, O37,O53, and O65), thus indicating the clonal nature of these strains.The branch node of the epidemic cluster was supported by a valueof 99% in a 1,000-replicate bootstrap analysis. Similar clusteringof epidemic strains was seen with the pgm and recA gene trees(data not shown), where the number of nucleotide changes persite among the strains was greater than with gyrB. The branchcarrying 10 tcpA⁺ non-O1 and non-O139 strains and several othernon-O1 and non-O139 strains had a low bootstrap value (47%)(Fig. 1), which suggests that the strains in this group arenonclonal in nature and, accordingly, mostly formed independentsecondary branches. Although a few strains within this groupformed clusters with high bootstrap values (serogroups O77 toO80, O8 to O44, and O89 to O144) (Fig. 1), this clustering wasnot consistent with the pgm- and recA-based trees. The remainingone tcpA⁺ non-O1 and non-O139 strain (serogroup O115) was aV. mimicus strain and was an outlier in the tree. Apparently,this strain has acquired the VPI region via interspecies horizontaltransfer. Based on these data, we conclude that the 11 tcpA⁺non-O1 and non-O139 strains have distinct lineages and did notoriginate directly from epidemic strains by O-antigen switching.

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FIG. 1. Neighbor-joining tree constructed by the maximum-parsimony method with the nucleotide sequences of gyrB gene fragments of V. cholerae strains. Labels at the branch tips represent strain designation, serogroup, and the virulence gene (T for tcpA and C for ctxAB), if present. The horizontal length represents the genetic distance, and the vertical lengths are not meaningful. The numbers above the branch lines represent the number of changes, and the numbers in parentheses below the branch lines at the branch node are the bootstrap values. Strains for which O-antigen switching is the proposed mechanism are underlined, and strains in which O-antigen switching is supported by sequence evidence are indicated by asterisks. Strains which appear to have acquired VPI and CTX ${phi}$ or pre-CTX ${phi}$ by independent horizontal gene transfer are highlighted.

Genetic organization of VPIs.
The genetic organization of the VPI region in epidemic and nonepidemicstrains was compared by RFLP analysis of genomic DNAs digestedwith XmnI and hybridized with various probes derived from theVPI region (Fig. 2). The VPIs of the O1 classical and O1 ElTor strains had distinct RFLP patterns (Fig. 2, lanes O1 claand O1 ET). Ten of the 11 non-O1 and non-O139 strains had distinctRFLP patterns that were different from those of the epidemicstrains, with additional XmnI sites and/or genetic rearrangements(insertions and deletions) at the left end of the VPI (Fig.2, lanes O77 through O8), and O77 and O80 serogroups had identicalclusters. The deduced restriction maps of the VPI regions inthe 10 strains are shown in Fig. 3. The insertions and deletionsat the VPI's left end in the non-O1 and non-O139 strains wereconfirmed by hybridization of SalI-digested genomic DNAs (Fig.4). A SalI-generated fragment of the expected size of 4,299bp in length was seen in the wild-type VPI (Fig. 4b, lanes O1cla and O1 ET). However, in the non-O1 and non-O139 strains,a fragment of >10 to 12 kb was observed (Fig. 4b, lanes O8to O80, O191, O105, and O141), thus indicating a DNA insertion( $~$ 5 to 7 kb) in the VPI region. Also, the O49 and O115 strainsdid not hybridize with this probe, which indicates a deletionin this region. Thus, these non-O1 and non-O139 strains couldbe divided into three groups with respect to their VPIs' leftends. First, strains of serogroups O26, O44, O48, O77, and O80contained an insertion of an approximately 6-kb fragment betweenthe VPI left att site and the SalI site within open readingframe (VC0817) at the left end of the VPI. Second, strains ofserogroups O8, O105, and O141 carried a deletion and an insertionof an approximately 7-kb fragment (O8) or an approximately 5-kbfragment (O105 and O141) at the left end of the VPI. Third,strains of serogroups O49, O115, and O191 carried deletionsof various lengths at the left end of the VPI.

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FIG. 2. RFLP analysis of the VPI region in various V. cholerae strains. Southern analysis of the XmnI-digested genomic DNAs of the indicated strains was done by simultaneous hybridization with multiple probes. The probes used were b, d, e, g, h, and i, as shown in Fig. 3. The corresponding restriction fragments (shown in Fig. 3) of the El Tor (ET) VPI detected by these probes are indicated by the numbers on the left side of the figure. The size markers (in kilobases) are indicated on the right side of the figure. cla, classical.

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FIG. 3. Genetic organization of the VPI cluster. A schematic diagram of the VPI region in an O1 El Tor strain, based on the V. cholerae (16) genome sequence, is shown. The top bar represents the various subclusters within the VPI region, the filled bar indicates the junction segments of the VPI region, and the vertical lines mark the ends of the VPI cluster. The various probes are indicated in the second row (a through j). The predicted XmnI fragments of the VPI region of the El Tor chromosome (numbered 1 to 13) are indicated in the third row. The observed XmnI fragments of the VPI region deduced from hybridization analyses and the resulting genetic maps of the El Tor (ET), classical (Cla), and various non-O1 and non-O139 strains of V. cholerae are shown below. DNA insertions and their sizes in kilobases are indicated by triangles and the numbers above the triangles, broken lines represent deletions, and thin lines indicate the adjoining sequences on the chromosome. The El Tor type included the O53, O65, and O139 serogroups, the classical type included the O37 serogroup, and the O77 type included the O80 serogroup.

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FIG. 4. RFLP analysis of the left end of the VPI region in V. cholerae strains. The schematic diagram of the left end of the VPI region and the expected SalI- and XmnI-generated fragments 1 to 3 as shown in Fig. 3 are indicated at the top (A). SalI-digested genomic DNAs were hybridized with the b* probe (B). Strains of serogroups O49 and O115 have a deletion in the region of the probe. ET, El Tor; cla, classical.

To elucidate further the origin of the VPIs found in the above-describednon-O1 and non-O139 strains, the tcpA genes located within theVPIs were sequenced. As observed earlier in other studies (8,9, 15, 28-30), extensive divergence in the tcpA gene sequencesof these strains was observed. The results are summarized inTable 1, and a phylogenetic tree based on the amino acid sequences(12 tcpA sequences from this study and 12 previously publishedtcpA sequences) is shown in Fig. 5. Four strains (serogroupsO44, O53, O65, and O139) carried an El Tor allele, and strain203-93 (serogroup O141) carried an allele very similar to theone found previously in strain 10259 (serogroup O53), exceptat three positions (^O53A190G^O141, ^O53P191T^O141, and ^O53G193S^O141)(15). The tcpA alleles in serogroups O27 and O105 were verysimilar to the recently described tcpA-env allele (28), exceptat one position (^O27,O105D9V^tcpA-env), and the O49 allele differedfrom the O27 and O105 alleles at one position (^O27,O105N56H^O49).Seven new alleles in serogroups O8, O26, O48, O49, O77, O141,and O191 were identified in this study. Taken together, thesedata suggest that the VPIs of a majority of the non-O1 and non-O139strains differ from those of the epidemic strains (classicaland El Tor) as do their tcpA genes.

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FIG. 5. Neighbor-joining tree constructed by the maximum-parsimony method with the amino acid sequences of the tcpA gene fragments of V. cholerae strains. The labels at the branch tips represent the strain designation and serogroup, if known. A total of 28 tcpA sequences, which included alleles described in this study (highlighted) and in previously published studies, were used for the analysis. The strain designations of published sequences are as follows (serogroups, if known, and GenBank accession numbers are in parentheses): N16961-ET (O1, AF325734), 395 classical (O1, AF325733), 151 (O37, AF030546), 208 (O11, AF030309), VCE22 (AF414371), SCE5 (O11, AB012946), 10259 (O53, AF139626), SCE188, SCE354 (O27, O44, AF208385), GX95065 (AY056618), HB84419 (AY052830), XJ90006 (AY056619), SD95001, (AY052831), and 365-96 (O27, AF390571). The strain designations of novel alleles reported in this paper are as follows (serogroups, if known, and GenBank accession numbers are in parentheses): 366-96 (O191, AF452580), AQ1875 (O48, AF452573), 1322-69 (O37), No. 63 (O26, AF452571), 8-76 (O77, AF452575), 203-93 (O141, AF452579), 523-80 (O115, AF452578), 507-94 (O49, AF452574), 153-94 (O8, AF452570), 571-88 (AF452577), 1421-77 (O80, AF452576), and 506-94 (O44, AF452572). ET, El Tor; cla, classical.

Genetic organization of the ctx region.
The organization of the ctx region in the seven non-O1 and non-O139strains that were ctxAB⁺ (serogroups O8, O26, O44, O49, O105,O141, and O191) was determined by RFLP analysis. EcoRI doesnot cut within the CTX ${phi}$ genome; thus, digestion of the genomicDNAs with EcoRI and hybridization with ctxAB probes revealeda single copy of the CTX ${phi}$ genome in strains of serogroups O8,O26, O44, O49, O105, and O191 and two copies in O141 (Fig. 6).Five other previously described (25) probes, ctxrgn 1 to 5,were used to scan the ctx region, and the genetic organizationof that region in the non-O1 and non-O139 strains was foundto be quite heterogeneous and distinct from that of the epidemicstrains. Also, the non-O1 and non-O139 strains lacked pTLC,an element carried by all of the epidemic strains, and theypossessed an El Tor-like RTX cassette (data not shown).

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FIG. 6. Analysis of the CTX ${phi}$ prophage in V. cholerae strains. Southern blot analysis of EcoRI-digested genomic DNAs probed with the ctxAB gene probes is shown; each band represents one copy of the CTX ${phi}$ prophage genome. ET, El Tor; Cla, classical.

To understand further the origin of the CTX ${phi}$ s present in thenon-O1 and non-O139 strains, the nucleotide sequences of therstR and ctxAB genes were determined (the allelic types basedon their sequences are listed in Table 1). The rstR sequenceswere diverse among the strains examined in this study. Fourstrains (serogroups O8, O44, O48, and O49) had two alleles (doublelysogens), one of which was an El Tor type in the O8, O44, andO49 serogroups, three strains carried the rstR^cla allele (serogroupsO26, O141, and O191), two strains carried only an rstR^ET allele(serogroups O105 and O115) and two new alleles were found, rstR^O8and rstR^O44 (serogroups O8, O44, and O49). rstR^O8 is a variantof the rstR4** type (28), and rstR^O44 is a novel type, whichwe provisionally designate rstR6, and is similar to a sequencealready available in the GenBank database (accession numberAF302794). A Clustal-X alignment of the nucleotide sequencesof the rstR type alleles and two variants is shown in Fig. 7.Twenty-four rstR sequences available in the GenBank databasewere aligned. They fall into 5 rstR types: El Tor type (5 sequences),classical type (4 sequences), Calcutta type (4 sequences), rstR4**type (9 sequences), and rstR6 (2 sequences). The sequences upstreamand downstream of rstR (ig-1 and rstA) are highly conservedin all of the alleles while the rstR region showed extensivevariations, as do their respective RstR proteins.

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FIG.7. Clustal-X alignment of rstR sequences. A total of 24 rstR sequences available in the GenBank database, which included alleles described in this study, were used for the analysis. Only the rstR type sequences that encode different RstR proteins (5 type sequences, i.e., El Tor [ET], classical [Cla], Calcutta [Cal], rstR4**, and rstR6) and two variants are shown in the figure. One sequence (accession number AF133308, designated rstR5 from strain SCE264) of the Calcutta type shows extensive variations, its RstR protein exhibited the least similarity to all of the other alleles (28), and hence, it was not included in the alignment. The strain designations of the published sequences are as follows (the serogroup [if known] and the GenBank accession numbers are in parentheses: El Tor (ET) type, E7946 (O1 ET, U83795), E7946 (O1 ET, U83796), SC8511 (O1 ET, AF511000), N16961 (O1 ET, AE004224), and JS9803 (O139, AY101180); classical (Cla) type, O39 (O1 Cla, AF262318), SC9773 (O1 ET, AF510999), 569B (O1 Cla, AF05890), and 86015 (O1 ET, AF220606); Calcutta (Cal) type, AS207 (O139, AF110029), SCE188 (O44, AF133310), FJ98352 (O139, AF511001), and SCE264 (O42, AF133308); rstR4** type, SCE223 (O27, AF133307), 365-96 (O27, AF390570), JX94484 (O139, AF511001), VCE22 (O36, AY145124), VCE228 (O27, AY145125), VCE232 (O4, AY145126), VCE233 (O27, AY145127), 153-94 (O8, AF452585), and SCE263 (O10, AF133309); Novel type, 506-94 (O44, AF452586) and 9803 (O139, AF302794). Nucleotides CT and AG are in green and red, respectively. ig-1, intergenic region 1; rstA, the 5' end of the rstA gene. Nucleotides that are identical in all sequences are indicated by asterisks.

The CtxA protein was conserved in all seven strains, exceptat one position in two strains (^wtS46N^O105,O141). The CtxB proteinwas of the El Tor type in serogroups O8 and O49 and was of theclassical type in serogroups O141 and O191. The classical andEl Tor CtxB alleles differed from each other at two positions(^ETY39H^cla and ^ETI68T^cla). In the O26, O44, and O105 serogroups,novel alleles with four amino acid substitutions (^wtT36A, ^wtF46L,^wtK55N, and ^ETI68T^{cla,O26,O44,O105}) were found.

DISCUSSION

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Discussion

In this study we utilized a panel of 300 clinical and environmentalstrains of V. cholerae to identify and characterize 15 novelpathogens which belong to serogroups traditionally considerednonpathogenic and nonepidemic and which carry the VPI or theVPI and CTX prophage (regions originally thought to be exclusiveto O1 and O139 serogroups). Mukhopadhyay et al. (28) reportedthe identification and characterization of similarly unusualV. cholerae pathogens (serogroups O8, O10, O11, O27, O35, O42,and O69) isolated from environmental samples from the Calcuttaregion, and very recently, Boyd and Waldor (8) reported severaladditional isolates (serogroups O8, O37 and O141). Thus, ourstudy further expands the repertoire of novel V. cholerae serogroups(O26, O37, O44, O48, O49, O53, O65, O77, O80, O105, O115, O141,and O191) found to carry virulence genes.

The 15 non-O1 and non-O139 strains carrying the VPI clustercould be divided into two groups, based on comparative genomicanalyses (MLST and RFLP) (Fig. 1 and 2 to 4, respectively).First, strains of serogroups O27, O37, O53, and O65 have verysimilar genetic backgrounds and cluster with the epidemic strains,and they most likely emerged by horizontal transfer and exchangeof O-antigen biosynthesis regions. In that regard, previousstudies (5, 26) and the results we obtained during our sequencingof the O-antigen biosynthesis region in an O37 serogroup strain(25) support that emergence mechanism. Second, strains of serogroupsO8, O26, O44, O48, O49, O77, O80, O105, O115, O141, and O191have distinct genetic backgrounds and virulence regions comparedto the epidemic strains, and they most likely arose by independentacquisition of the VPI. Also, several strains in the secondgroup subsequently acquired a CTX ${phi}$ or a pre-CTX ${phi}$ . None of the300 strains screened in our study had the CTX ${phi}$ alone, which supportsthe two-step sequential model for the acquisition of VPI andCTX ${phi}$ (7). Also, as previously reported (7), intermediates inthe evolution of the CTX ${phi}$ have also been found, i.e., a pre-CTX ${phi}$ lacking ctxAB has been found in three different non-O1 serogroups(O48, O53, and O65).

The tcpA, rstR, and ctxAB diversity observed in this study issimilar to that reported in previous publications. For example,the two new rstR alleles identified in the present work (rstR^O8and rstR^O44) are very similar to the rstR4 allele (28) and toanother sequence deposited in the GenBank database (accessionnumber AF302794). In addition, an insertion and deletion observedat the left end of the VPIs in some non-O1 and non-O139 strainshas been reported by Mukhopadhyay et al. (28). However, thesizes of the inserted fragments observed by us are much largerthan the 1.6-kb segment of chromosome II reported, in the above-referencedstudy (28), to have been translocated to the left end of theVPI on chromosome I in place of a 300-bp segment. The geneticcontents of the inserts and the deletion end-points need tobe determined in order to understand whether translocation ofthe same region has occurred in the non-O1 and non-O139 strainsdescribed in this paper.

Extensive site-directed mutagenesis analysis of the tcpA gene(10, 23, 41) has yielded useful insights into the structure-functionrelationship of the TCP. Based on functional analysis of mutantTcpA pilins, the TcpA protein has been proposed to have threedistinct domains, N-terminal, C-terminal structural, and C-terminalinteraction domains (10, 23, 41). As observed earlier (8), thevarious tcpA alleles identified in our study have variationsin the amino acid residues previously demonstrated (23, 41)to have functional significance, i.e., the majority of the changesare found in the C-terminal structural and interaction domains(Fig. 8). The novel finding, however, is further delineationof the region between amino acid residues 50 and 120, whichcarries two mutational hotspots, residues 53 to 75 and 90 to105, where multiple variations are seen (Fig. 8). The role ofthis region in the structure-function relationship of TcpA pilinremains to be determined. Since there are multiple variationswithin any given tcpA allele, assessing the effect of thesechanges may be difficult, especially if the changes in one domainare the result of intragenic suppression of mutations elsewherein the gene. Site-directed mutagenesis studies of this region(residues 50 to 120) in a wild-type tcpA may reveal the functionalsignificance of this domain.

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FIG. 8. Domain structure of TcpA. The primary amino acid sequence of the El Tor TcpA is shown. The residues shown to have functional significance, based on site-directed mutagenesis (10, 23, 41), are indicated in boldface type, the two cysteine residues predicted to be essential for the structure and function of TcpA pilin are indicated by boxes, and the proposed domains are indicated by bars (10, 23, 41). The variations in the amino acid residues found in various tcpA alleles described in other studies (9, 15, 28-30) and in this work (highlighted) are indicated above the primary sequences. The variations seen in the classical allele are underlined. The changes unique to a single strain are indicated in italics. The O37 serogroup has a classical TcpA with a single change (K184 to E) indicated by a shaded box.

Horizontal gene transfer plays an important role in the evolutionof pathogenic bacteria, including V. cholerae, which has becomea paradigmatic organism for studying horizontal gene transfermechanisms. All three of the major known V. cholerae virulencemarkers (CTX ${phi}$ , VPI, and O-antigen biosynthesis regions) are believedto have been acquired by horizontal gene transfer. Two of thesemarkers (CTX ${phi}$ and VPI) have been introduced into the V. choleraechromosome via phage-mediated transduction (22, 44); the mechanismsresponsible for acquiring the O-antigen biosynthesis regionsare unknown at the present time. However, acquisition of VPIand CTX ${phi}$ appears to be more frequent than exchange of O antigensin epidemic serogroups, which may reflect mechanistic differencesin their horizontal transfer. Acquisition of VPI and CTX ${phi}$ involvessingle-stranded phages and a site-specific recombination process,whereas acquisition of the O-antigen region probably involvesgeneralized transducing phages and a homologous recombinationmechanism. Hence, it is tempting to speculate that horizontaltransfer of O-antigen regions might be subjected to DNA restrictionand recombination barriers.

The present study provides further support to the growing bodyof evidence that the classical V. cholerae virulence markers,ctxAB and tcpA, are not unique to epidemic strains and thatthey are found in at least some nonepidemic, non-O1 and non-O139V. cholerae serogroups. However, the epidemic potential of thesestrains is not clear at the present time, especially since—andin clear contrast to O1 and O139 isolates—none of thenon-O1 and non-O139 strains has been associated with past epidemicsand/or pandemics of cholera. However, these observations raisethe intriguing possibility that the presence of ctxAB and tcpAin V. cholerae, while critical, is not sufficient for the full-blownepidemics of cholera. In this context, Dziejman et al. (12)recently reported comparative genome analyses of 11 V. choleraestrains of epidemic serogroups, and they identified two clustersof genes differentiating pandemic strains from other strains.Similar comparative genomic analysis of epidemic strains withthe nonepidemic, non-O1 and non-O139 strains identified in thisstudy is likely to provide invaluable information regardingthe mechanisms responsible for the emergence of the epidemicV. cholerae serogroups and strains.

ACKNOWLEDGMENTS

We thank Arnold Kreger, Alexander Sulakvelidze, and Colin Stinefor helpful comments and editorial assistance, Judy Johnsonfor providing access to the Smith strain collection, and GlennMorris for support and encouragement during the course of thisstudy.

M.K. was supported by an International Training and Researchin Emerging Infectious Diseases grant from the Fogarty InternationalCenter, National Institutes of Health. Funding for our studieswas provided by a University of Maryland intramural grant (toS.S.) and BREF intramural support from the Department of VeteransAffairs (to S.S.).

FOOTNOTES

* Corresponding author. Present address: Intralytix, Inc., The Columbus Center, 701 E. Pratt St., Room 4016, Baltimore, MD 21202. Phone: (410) 625-2422. Fax: (410) 625-2506. E-mail: ssozhamannan{at}intralytix.com.

Present address: Intralytix, Inc., Baltimore, MD 21202.

REFERENCES

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