Genetic Analysis and Prevalence Studies of the brp Exopolysaccharide Locus of Vibrio vulnificus

Phase variation in the Gram-negative human pathogen Vibrio vulnificus involves three colonial morphotypes- smooth opaque colonies due to production of capsular polysaccharide (CPS), smooth translucent colonies as the result of little or no CPS expression, and rugose colonies due to production of a separate extracellular polysaccharide (EPS), which greatly enhances biofilm formation. Previously, it was shown that the brp locus, which consists of nine genes arranged as an operon, is up-regulated in rugose strains in a c-di-GMP-dependent manner, and that plasmid insertions into the locus resulted in loss of rugosity and efficient biofilm production. Here, we have used non-polar mutagenesis to assess the involvement of individual brp genes in production of EPS and related phenotypes. Inactivation of genes predicted to be involved in various stages of EPS biosynthesis eliminated both the rugose colonial appearance and production of EPS, while knockout of a predicted flippase function involved in EPS transport resulted in a dry, lightly striated phenotype, which was associated with a reduction of brp-encoded EPS on the cell surface. All brp mutants retained the reduced motility characteristic of rugose strains. Lastly, we provide evidence that the brp locus is highly prevalent among strains of V. vulnificus.


Introduction
Vibrio vulnificus is a Gram-negative bacterium found in estuarine and marine waters, and is commonly associated with human disease caused by ingestion of raw oysters or contact of the organism with an open wound. The mortality rate of V. vulnificus is the highest among food-borne pathogens, ranging from 50-75% [1], and pathogenesis is directly related to the presence of capsular polysaccharide (CPS), which protects the bacteria from the host immune system [2][3][4][5]. Encapsulated strains exhibit a smooth opaque colony phenotype on agar plates and kill an ironoverloaded mouse at lower doses than attenuated unencapsulated strains, which exhibit a smooth translucent phenotype [3]. A third colony type called rugose has been isolated from both opaque and translucent parental strains, and it is characterized by dry, wrinkled colonies, decreased motility, and robust biofilm formation caused by production of extracellular polysaccharide (EPS) [6,7].
V. vulnificus can spontaneously switch among opaque, translucent and rugose phases in response to certain environmental conditions [8,9]. Genetic loci relevant to these switching events include the group I CPS operon, involved in CPS biosynthesis and transport [10,11], and the brp locus, which was shown to be involved in EPS production [7,12]. The brp cluster (renamed from wcr) was originally identified by RT-PCR analysis as being more highly expressed in rugose variants when compared to opaque or translucent ones [7]. The translucent phenotype of a transposon mutant (TDB3[T]), which contains an insertion in the brp gene cluster, raised the possibility that one or more brp genes may also be required for CPS production [7,13].
The brp locus is regulated by bacterial second messenger c-di-GMP, though the mechanism remains undetermined [12]. The importance of c-di-GMP as a regulator of EPS production, and biofilm formation has been established previously in several bacterial species [14,15]. Recently, an additional exopolysaccharide locus, rbd, was characterized in V. vulnificus, and it was found to enhance biofilm and cell aggregation phenotypes, though its polysaccharide did not appear to be required for either development or maintenance of the rugose phenotype [16].
In this study, we used a non-polar mutagenesis approach to assess the involvement of individual brp genes in exopolysaccharide production and related phenotypes. Four brp genes were disrupted, and two phenotypes with respect to colony morphology and EPS production were observed. All non-polar brp mutants showed greatly reduced biofilm capability and also remained less motile than opaque or translucent variants. Through a combined PCR and Southern blotting approach, we also found the brp locus to be widespread within this species.

Bacterial strains & growth conditions
All V. vulnificus strains were grown in heart infusion broth (Difco) supplemented to 2% NaCl (HI) and on HI agar plates containing 18 g/l of agar (Difco). Broth cultures were incubated at 30uC and 200 rpm; plates were incubated overnight (ON) for 16-24 h at 30uC. Phase switching assays in HI and growth curves were all performed as previously described [8]. Escherichia coli strains were grown in LB broth (Difco), broth cultures were incubated at 37uC and 250 rpm, and plates were incubated ON for 16-24 h at 37uC. Antibiotics (Sigma) were used at the following concentrations: 150 mg/ml kanamycin, 50 mg/ml ampicillin, and 2 mg/ml chloramphenicol for V. vulnificus and 50 mg/ml kanamycin, 50 mg/ml ampicillin, and 10 mg/ml chloramphenicol for E. coli. Arabinose (Sigma) was typically added to a final concentration of 0.2% when needed. E. coli and V. vulnificus strains used or created in this study are listed in Table 1.

Molecular genetic and recombinant DNA techniques
DNA manipulations were carried out using standard molecular techniques [17]. Restriction enzymes, calf intestinal alkaline phosphatase (CIP), T4 polynucleotide kinase, and Klenow polymerase were obtained from New England Biolabs, Pfu polymerase from Stratagene, AmpliTaq polymerase from Applied Biosystems, and primers from Sigma Genosys. Plasmids used or created in this study are listed in Table 2, while primers are listed  in Tables 3 and 4. Genomic DNA was isolated and PCRs for brp gene linkage analysis were completed as described [7,8]. For Southern blotting, fragments specific for the brpC or brpI genes were generated via PCR with primer pairs RUG17/RUG18, and CAP27/CAP28, respectively. Production of radiolabeled probes and hybridizations were performed as described [7] using ca. 10 8 cpm/ml of probe per hybridization.

Generation of in-frame brpD and brpI insertion mutants
Mutants of brpD and brpI were generated from the rugose parental strain KG3(R) as follows. Using PCR, ,1-kb fragments of brpD and brpI were amplified using primer pairs Npm1/Npm2 and Npm3/Npm4, respectively. Each 50-ml PCR reaction mixture contained 5 ml of 106 buffer, 4 ml of a 10 mM dNTP mixture (each dNTP at 2.5 mM), 1 ml of each primer (20 mM), 1 ml of Pfu polymerase (2.5 U/ml), 100 ng of YJ016 genomic DNA, and nuclease-free H 2 O. The PCRs were performed using an initial temperature of 95uC for 2 min, followed by 30 cycles of 95uC for 45 sec, 55uC for 45 sec, and 72uC for 1.5 min; these cycles were then followed by a final extension at 72uC for 10 min and holding at 4uC. PCR mixtures were examined by gel electrophoresis, and, upon relevant restriction enzyme digestion, the 1-kb products were cloned into the EcoRI and EcoRV sites and the EcoRI and XhoI sites of vector pSP72 (Promega) to create pVV1 (brpD) and pVV4 (brpI), respectively. An 840-bp nonpolar kanamycin-resistance cassette [18], which was generated by digestion of plasmid pKan2 with SmaI, was cloned in the correct orientation into the ClaI site (which had been blunt ended using Klenow) of pVV1 or the MscI site of pVV4 to create pVV2 and pVV8, respectively. To confirm the cassette was inserted in frame with the downstream portion of brpD and brpI, sequencing reactions were performed using BigDye v3.1 (Applied Biosystems) [8]. The 1.88-kb HpaI-SmaI fragment of pVV2 and the 1.75-kb EcoRI-XhoI fragment (whose ends were filled in using Klenow) of pVV8 were then cloned into the bluntended XbaI site of suicide vector pGP704sacB28 [19] to create pVV21 (brpD) and pVV18 (brpI). Matings between V. vulnificus KG3(R) and S17.1lpir harboring the respective insertion plasmids were carried out on filter membranes; kanamycin-resistant, ampicillin-sensitive transconjugants that had undergone double homologous recombination were selected, and PCRs using AmpliTaq polymerase and primer pairs Npm1/Npm2 (brpD) and Npm3/Npm4 (brpI) were performed as described [7] to check for proper integration of the cassette. Southern blot hybridizations were used to confirm the mutant strains KG3-02 (brpD::aphA-3) and KG3-17 (brpI::aphA-3).
Generation of in-frame brpA and brpJ deletion mutants Deletions of brpA and brpJ were generated from the rugose strain KG3(R) as follows. Using Pfu polymerase and PCR conditions as described above, primers A and B amplified a 1-kb fragment at the 39 end of the target gene (AB), while primers C and D amplified a 1-kb fragment at the 59 end (CD). The resulting 1-kb AB & CD fragments for a given gene were joined using splice overlap extension with primers A and D as previously described [20] to create a 2-kb deletion fragment. The fragment specific for brpA was digested with EcoRI and BamHI and cloned into these sites on pSP72, creating pVV27, while the brpJ-specific fragment was digested with EcoRI and XbaI and cloned into these sites on pSP72 to create pVV42. The 840-bp nonpolar kanamycin cassette was then cloned as a SmaI fragment in the correct orientation into the SmaI site of each deletion clone to create pVV28 (brpA) and pVV44 (brpJ). Following sequencing as described earlier, the brpA deletion construct containing the non-polar cassette was cloned as a 3-kb EcoRI-HindIII fragment (made blunt ended with Klenow) into the blunt-ended XbaI site of pGP704sacB28 to create pVV29, while the same construct for brpJ was cloned as a 3-kb ClaI-XhoI fragment (with ends filled) into the blunt-ended XbaI site of pGP704sacB28 to create pVV46. Intergeneric matings, selection of transconjugants and subsequent PCR analysis of potential mutants were performed as described in the previous section, except that primer pairs Del_wcrA_A/Del_wcrA_D (brpA) and Del_wcrJ_A/ Del_wcrJ_D (brpJ) were used for the latter step. Southern blot hybridizations were used to confirm the mutant strains KG3-01 (DbrpA::aphA-3) and KG3-03 (DbrpJ::aphA-3).

Microscopy
Whole colony images were taken using a Leica MZ7.5 stereomicroscope and a SPOT Insight camera (Diagnostic Instruments, Inc.). Scanning electron microscopy (SEM) analysis of colony surfaces was performed as previously described [7].

EPS isolation and visualization
EPS was isolated as previously described [22] with modifications. Two related protocols were performed with similar results. In the first protocol, a single colony was used to inoculate an entire plate of HI (with necessary antibiotics), which was incubated at room temperature (RT) for 2 days (2 plates were used for strain KG3-03 due to its relatively slow growth). Each lawn was collected by scraping with a glass pipette in the presence of PBS, and the resulting suspension was stirred briskly for 1-2 h at RT and then vigorously vortexed for 30 sec. Cells were harvested by centrifugation at 8,000 rpm for 1 h at 4uC, and a 5-ml aliquot of the supernatant was treated with 50 mg/ml RNase A (Qiagen) and 50 mg/ml DNase (Promega) in the presence of 10 mM MgCl 2 at 37uC for 8 h, followed by treatment with 200 mg/ml protease (Sigma) at 37uC for 17.5 h. The supernatant was then extracted twice with an equal volume of phenol:chloroform (50:50), and EPS was precipitated by the addition of 2 volumes of 100% ethanol. EPS was pelleted in a microfuge at 10,000 rpm for 30 min at 4uC, and the pellet was washed with 70% ethanol, dried and finally resuspended in 100 ml dH 2 O. An equal volume of each sample was then analyzed by SDS-polyacrylamide gel electrophoresis (PAGE) (100 V, 2-3 h) using 4% stacking/10% resolving gels. Finished gels were stained with Stains-All as previously described [23]. In the second protocol, a single colony was used to inoculate plates as before, except that 3 plates were used per strain. Following incubation, the lawns for a given strain were collected by scraping, the resulting suspension was vortexed vigorously for 1 min, and a 20-ml aliquot was used to create serial dilutions, which were plated on HI (with necessary antibiotics) to calculate CFU/ml of the cell suspension. The suspension was then shaken at 30uC for 90 min, and the vortexing and shaking was repeated a second time. Cells were harvested by centrifugation at 5,000 rpm for 15 min at 25uC, and the supernatant was re-centrifuged using the same parameters. The resulting supernatant was treated with RNaseA, DNase and protease, extracted twice with phenol:chloroform (50:50) and polysaccharide was precipitated with 100% ethanol, all as in the first protocol. SDS-PAGE and staining were performed also as before, except that sample volumes were adjusted for differences in CFU/ml of the original cell suspensions.

Pellicle and biofilm assays
Pellicle formation was observed after ON growth at 30uC in 3 ml HI (with necessary antibiotics and/or arabinose) with shaking at 200 rpm. Pellicle thickness was scored qualitatively as -(no pellicle), + (thin pellicle), ++ (pellicle), or +++ (thick pellicle). Three pellicles for each strain were scored. Biofilm assays were conducted as previously described [8], except static cultures were incubated for 18 h. At least two independent assays with six replicates of each strain were completed.

Motility assays
Motility assays were conducted as previously described [6]. At least two independent assays with four replicates of each strain were completed.

Statistical Analysis
All data were analyzed using a non-paired Student's t-test.

Phenotypic characterization of individual brp mutants
Given the possibility of co-transcription of the brp gene cluster ( Figure 1A), a mutagenesis approach involving insertion of a nonpolar kanamycin resistance cassette [18] was used in a rugose background to assess the contribution of select brp genes to rugosity, biofilm formation, exopolysaccharide production and motility. As shown previously, the presence of conserved domains revealed putative function for some of the brp genes while, for others, no conserved domains were apparent [7]; here, we chose to mutate four genes for which putative functions had been identified ( Figure 1A). For the first two mutants, the kanamycin-resistant cassette was inserted between encoded functional domains of the brpD and brpI genes. Though, as detailed below, this approach yielded clear mutant phenotypes consistent with previous plasmid insertions into the locus [12], we were concerned that continued use of such a strategy would leave open the possibility of creating a truncated product which retained activity; thus, for the brpA and brpJ mutants, a different approach was employed which resulted in nearly the entire gene being replaced by the cassette (Figure 1A).
The brpA [KG3-01], brpD [KG3-02], and brpI [KG3-17] mutants lost the dry, wrinkled colony morphology of the KG3(R) parent, but appeared opaque, indicating they retained the ability to make CPS ( Figure 1B-C). Meanwhile, the brpJ mutant (KG3-03) also lost its wrinkled look, though it remained dry in appearance with faint striations that became more pronounced upon extended incubation; thus, it possessed an intermediate phenotype which did not match any of the typical opaque, translucent or rugose colony types ( Figure 1B-C). KG3-03 also grew detectably slower (by ,50%) relative to the parent and other mutants (data not shown). It is unknown to what extent, if any, this defect contributed to the unique colonial phenotype of this mutant. Each mutant was then complemented using a cloned arabinose-inducible promoter construct which could induce expression of a wild type copy of each gene. The rugose colony phenotype was restored for each complemented mutant, although the degree of rugosity was clearly greater for KG3-02 containing the brpD complementation vector pVV41 ( Figure 1B).
The complementation shown in Figure 1B was performed on plates containing 0.2% arabinose. When the concentration of arabinose was titrated (i.e., 0.02% and 0.002%), the strongest complementation was still always seen for KG3-02 (pVV41) (data not shown). Despite this effect, when pVV41 was introduced into strain KG3(R), rugosity of the parental strain did not appear to be increased relative to KG3(R) itself or KG3(R) containing the brpI complementation vector pVV40 (data not shown).
The opaque phenotype of the brpI mutant KG3-17 was consistent with a previous plasmid insertion into that gene [12] but not with the translucent phenotype of mutant TDB3(T) [13]. This mutant was derived from an opaque strain and contains a mini-Tn10 insertion in the brpI gene. Upon further analysis of TDB3(T), we found here that it could not be complemented back to opacity with either the brpI gene alone (plasmid pVV40), or with brpI and the downstream brpJ and brpK genes (plasmid pVV53) all together (data not shown). Thus, it was unlikely that brp gene disruption was the cause of the translucent phenotype of TDB3(T). To further explore the genetic basis of this mutant, PCR was used to assess its wzb gene. It has been shown that deletions in the wzabc region of the group I CPS operon can cause an irreversible switch from the opaque to the translucent phenotype [10]. The wzb gene was still present with no mutations (data not shown), suggesting the translucent phenotype of TDB3(T) is the result of a separate genetic or epigenetic change somewhere in the genome.
Since rugose isolates form robust biofilms [6], we expected that the brp mutants isolated here would produce less biofilm. Biofilm formation was assessed both qualitatively (pellicle formation) and quantitatively (biofilm assays). All four brp mutants lost the ability to form a pellicle, and pellicle formation was partially or fully restored upon complementation (Figure 2A). In quantitative biofilm assays, all four mutants formed significantly less biofilm than their rugose parent KG3(R) (max p,0.001), and biofilm formation was again partially or fully restored upon complementation ( Figure 2B).
We hypothesized that the intermediate phenotype of the brpJ mutant KG3-03 may be associated with a partial reduction, rather than complete loss, of brp-encoded EPS on the cell surface. Consistent with this view, a non-polar brpJ mutant of the opaque strain YJ016 (YJ-10) remained opaque ( Figure 1D), indicating that deletion of brpJ per se does not appear to affect CPS production. To assess relative EPS production of KG3-03 directly, we compared the amount of EPS isolated from rugose strain KG3(R) and its four brp mutant derivatives. The data in Figure 3 show that much less EPS was recovered from KG3-03 cells than KG3(R), but reproducibly more than the other brp mutants, which did not yield detectable amounts of EPS in this analysis.
To obtain further evidence consistent with EPS production by KG3-03, colonies of this strain, as well as several others, were subjected to SEM analysis. Previous SEM studies indicated that opaque and translucent variants of V. vulnificus have smooth colony surfaces with flat architecture, while EPS-producing rugose variants have wrinkled surfaces and dramatic three-dimensional architectures consisting of pillars and channels [7]. Here, we found that while the smooth flat colony surfaces of the brpI mutant KG3-17 ( Figure 4, panel D) appeared indistinguishable from those of KG4(T) and YJ016 (panels B and C, respectively), the surface of KG3-03 colonies showed evidence of striations even at relatively low magnification (panel E); upon higher magnification, the striated areas corresponded to partial three-dimensional structuring, which is consistent with production of EPS (panel F). While the EPS isolation results and SEM data support the notion that the brpJ gene product was not absolutely required for brp-encoded EPS production to occur in strain KG3-03, it was nevertheless found to be necessary for production of a pellicle and robust biofilm formation under the conditions tested (Figure 2A-B).
As rugose isolates of V. vulnificus are less motile than their opaque or translucent counterparts [6], we measured the motility of each brp mutant described here and found that their motilities remained at low levels similar to the rugose parental strain ( Figure 5A-B). The motility of KG3-03 was significantly less than KG3(R) (and the other mutants), but we attribute this to its slower growth rate (data not shown). The observation that KG3 mutants retained the reduced motility of KG3(R) suggests that elimination or reduction of EPS production does not appear to affect (i.e., increase) motility in this species.

Evidence of the brp locus being widespread among strains of V. vulnificus
Since the brp locus is required for rugosity and efficient biofilm formation, it may provide a survival advantage in the environment, and, as such, it would be predicted to be well-conserved among strains of this species. This possibility was tested by screening for the presence of the brp cluster in a number of clinical and environmental strains. Linkage PCR was used as previously described [7] to determine that 41 of the 42 V. vulnificus strains in our collection contained the brp locus ( Table 5). The lone exception was the environmental isolate MLT198, which was locked in the translucent phase based on switching assay results (data not shown). To further characterize the brp genes in the 41 brp+ strains, Southern blot hybridization was performed, and it showed that 20 of the strains were of a single 10.5 kb PstI Open rectangles indicate the nonpolar Kan R cassette, while the filled rectangle indicates the mini-Tn10 insertion in strain TDB3(T) (41). Shading of arrows for the brp cluster indicates putative function encoded: black, flippase involved in EPS transport (for brpJ) or EPS export-related protein (for brpC); light grey, tyrosine autokinase involved in EPS biosynthesis; dark grey, glycosyltransferase involved in EPS biosynthesis; white, unknown function. B. Colony morphology of opaque, rugose, and translucent control variants, the 4 brp mutant strains derived from strain KG3(R), and the complemented mutants. Strains were streaked for isolation on HI agar (containing kanamycin, chloramphenicol and arabinose, as appropriate) and incubated at 30uC ON. C. Streak plate of opaque, rugose, and translucent control variants and the 4 brp mutant strains. Strains were inoculated into HI broth (with kanamycin, where appropriate), shaken ON at 30uC, streaked onto HI (with no antibiotics), and incubated ON at 30uC. D. Colony morphology of the YJ016-derived brpJ mutant YJ-10. The strain was streaked for isolation on HI agar containing kanamycin and incubated at 30uC ON. doi:10.1371/journal.pone.0100890.g001 restriction fragment length polymorphism (RFLP) profile while 6 others were of a single 2.7-kb PstI profile ( Table 5). The exact profile of the other 15 could not be determined from the available data. All representatives of each RFLP profile group tested showed the ability to switch to the rugose colony type and produce pellicles in culture (data not shown).

Discussion
Here we assessed individual genes within the brp cluster for their contribution to rugose colony morphology, biofilm formation, EPS production, and motility. The apparent lack of brp-encoded EPS production for the brpA, brpD, and brpI mutants suggests these genes designate required functions. Consistent with this interpretation, the brpA and brpI genes are predicted to encode glycosyltransferases, which are enzymes that catalyze the sequential transfer of specific individual sugars to an undecaprenyl phosphate carrier lipid during the early steps of polysaccharide synthesis [24]. The brpD gene product also appears to be involved in polysaccharide biosynthesis and may play a role in EPS production similar to Wzc, a tyrosine autokinase which is required for assembly of high-molecular-weight CPS and EPS polymers on the bacterial cell surface [7,24]. The finding here that brpD is required for EPS production is consistent with the results for capsule but not K LPS synthesis in E. coli K30 wzc mutants [24].
On the other hand, the brpJ gene appears to be involved in polysaccharide transport as its product has homology to Wzx flippases [7], which are transmembrane proteins that have been proposed to translocate undecaprenyl-phosphate-linked sugar precursors across the cytoplasmic membrane during synthesis of various polysaccharides including certain forms of CPS, EPS and O-antigens of LPS [24,25]. The reduction, but not elimination, of EPS production in the KG3(R)-derived brpJ mutant is reminiscent  of the results seen previously for knockout of the wzxE flippase gene, which is involved in synthesis of phosphoglyceride-linked and cyclic forms of enterobacterial common antigen in E. coli [26], and the production of EPS here suggests a couple of possible explanations. As complementation among Wzx proteins has been demonstrated [27], albeit often at much reduced efficiency [28], it is possible that loss of brpJ function can be partially compensated for (either naturally or via suppressor mutation) by a separate Wzx protein encoded by V. vulnificus. In this case, a potential candidate may be the wzx gene found in the Group I CPS operon [7].
Alternatively, it is known that transport of polysaccharides across the inner membrane of Gram-negatives actually involves two different pathways: one requiring Wzx, which may use an antiport mechanism to flip substrates [29], and the other requiring an ABC transporter [24,30]. Such movement of individual polysaccharides has long been considered to occur exclusively by one or the other of these pathways; however, using an artificially constructed genetic system, there is now evidence that translocation of at least some lipid-linked oligosaccharides across the inner membrane can be accomplished using either Wzx or ABC transporter function Figure 4. Evidence of three-dimensional structuring of KG3-03 colonies. Whole colonies taken from HI agar plates were vapor fixed with osmium tetroxide and viewed by SEM as described previously [7]. Panels: (A), KG3(R); (B) YJ016; (C), KG4(T); (D) KG3-17; (E, F) KG3-03. All scale bars equal 100 mm. Images in panels E and F are taken from the same colony. All images presented are representative of many images taken for several colonies of each strain. To achieve uniformity, brightness was increased somewhat for images in panels A, B, D and F, while it was decreased for the image in panel C. Contrast was not adjusted for any of the images. doi:10.1371/journal.pone.0100890.g004 [31]. Therefore another possibility is that an undetermined ABC transporter may also be capable of translocating brp-encoded EPS polymers across the inner membrane in V. vulnificus.
Based on the results of the EPS isolation for mutants KG3-01, KG3-02 and KG3-17 (Figure 3), we found no evidence of rbdencoded EPS production under the experimental conditions used here. Our results were not surprising given the previous data showing that the rbd locus is poorly transcribed under standard lab conditions and is under the control of a two-component sensor kinase/response regulator whose environmental induction signal(s) remains unknown [16]. In any event, the finding that rbd polysaccharide does not contribute to rugosity [16] supports the conclusion that the EPS found here on the surface of the brpJ mutant KG3-03 is brp-encoded.
We also found no evidence that CPS expression is controlled by the brp locus, which is in agreement with the previous results of Guo and Rowe-Magnus [12]. Additionally, our results point to another potential mechanism for the creation of phase-locked translucent variants. The transposon mutant TDB3(T), which is derived from the clinical isolate 1003(O), could not be complemented with the brpIJK genes and its wzb gene remained intact, indicating its translucent phenotype is due to an uncharacterized genetic or epigenetic change. Previous transposon mutagenesis of 1003(O) revealed additional genes that appear to be involved in CPS production in that strain [13,32]. A mutation in any of these  + or -indicates the presence or absence, respectively, of all genes in the brp cluster. 2 Indicates the size of the band hybridized to a radiolabeled probe specific for brpC or brpI. A -indicates that either no bands were present or that band size could not be determined. doi:10.1371/journal.pone.0100890.t005 genes or in an additional unidentified gene that affects CPS expression could explain the translucent phenotype of TDB3(T).
Biofilm development occurs in an ordered series of events which begins with initial attachment of planktonic cells to a surface, colonization of that surface, and then development of a threedimensional architecture [33]. Biofilm formation provides a distinct survival advantage for microbes, because it not only allows them to bind to surfaces that may provide nutrients, but also makes them more resistant to environmental stresses [34,35]. Consistent with such an advantage we found the brp locus to be highly prevalent among V. vulnificus strains tested. Further elucidation of the loci that play roles in EPS production in V. vulnificus will continue to provide important insights regarding the genetic and physiological bases for biofilm formation by this marine inhabitant and occasional human pathogen.