Mannose-containing oligosaccharides of non-specific human secretory immunoglobulin A mediate inhibition of Vibrio cholerae biofilm formation

The role of antigen-specific secretory IgA (SIgA) has been studied extensively, whereas there is a limited body of evidence regarding the contribution of non-specific SIgA to innate immune defenses against invading pathogens. In this study, we evaluated the effects of non-specific SIgA against infection with Vibrio cholerae O139 strain MO10 and biofilm formation. Seven day old infant mice deficient in IgA (IgA^-/- mice) displayed significantly greater intestinal MO10 burden at 24 hr post-challenge when compared to IgA^+/+ pups. Importantly, cross-fostering of IgA^-/- pups with IgA^+/+ nursing dams reversed the greater susceptibility to MO10 infection, suggesting a role for non-specific SIgA in protection against the infection. Since biofilm formation is associated with virulence of MO10, we further examined the role of human non-specific SIgA on this virulence phenotype of the pathogen. Human non-specific SIgA, in a dose-dependent fashion, significantly reduced the biofilm formation by MO10 without affecting the viability of the bacterium. Such an inhibitory effect was not induced by human serum IgA, IgG, or IgM, suggesting a role for the oligosaccharide-rich secretory component (SC) of SIgA. This was supported by the demonstration that SIgA treated with endoglycosidase H, to cleave the high-mannose containing terminal chitobiose residues, did not induce a reduction in biofilm formation by MO10. Furthermore, the addition of free mannose per se, across a wide dose range, induced significant reduction in MO10 biofilm formation. Collectively, these results suggest that mannose containing oligosacchardies within human non-specific secretory IgA can alter important virulence phenotypes of Vibrio cholerae such as biofilm formation, without affecting viability of the microorganism. Such effects may contribute significantly to innate immune defenses against invading pathogens in vivo in the gastrointestinal tract.

Proteome cataloging and relative quantification of Francisella tularensis tularensis strain Schu4 in 2D PAGE using preparative isoelectric focusing

The protein complement of whole cell extract of the bacterium Francisella tularensis tularensis was analyzed using two-dimensional electrophoresis with preparative isoelectric focusing in the first dimension. The format allows the quantification of relative protein abundance by linear densitometry and extends the potential dynamic range of protein detection by as much as an order of magnitude. The relative abundance and rank order of 136 unique proteins identified in F. tularensis tularensis were established. It is estimated that 16% of the moderately to highly expressed proteins and 8% of all predicted non-pseudogenes were identified by comparing this proteome information with the relative abundance of mRNA as measured by microarray. This rank-ordered proteome list provides an important resource for understanding the pathogenesis of F. tularensis and is a tool for the selection and design of synthetic vaccines. This method represents a useful additional technique to improve whole proteome analyses of simple organisms.

Intranasal vaccination with a defined attenuated Francisella novicida strain induces gamma interferon-dependent antibody-mediated protection against tularemia

Francisella tularensis is an intracellular gram-negative bacterium that is the causative agent of tularemia and a potential bioweapon. We have characterized the efficacy of a defined F. novicida mutant (DeltaiglC) as a live attenuated vaccine against subsequent intranasal challenge with the wild-type organism. Animals primed with the F. novicida DeltaiglC (KKF24) mutant induced robust splenic gamma interferon (IFN-gamma) and interleukin-12 (IL-12) recall responses with negligible IL-4 production as well as the production of antigen-specific serum immunoglobulin G1 (IgG1) and IgG2a antibodies. BALB/c mice vaccinated intranasally (i.n.) with KKF24 and subsequently challenged with wild-type F. novicida (100 and 1,000 50% lethal doses) were highly protected (83% and 50% survival, respectively) from the lethal challenges. The protection conferred by KKF24 vaccination was shown to be highly dependent on endogenous IFN-gamma production and also was mediated by antibodies that could be adoptively transferred to naive B-cell-deficient mice by inoculation of immune sera. Collectively, the results demonstrate that i.n. vaccination with KKF24 induces a vigorous Th1-type cytokine and antibody response that is protective against subsequent i.n. challenge with the wild-type strain. This is the first report of a defined live attenuated strain providing protection against the inhalation of F. novicida.

Characterizing lipopolysaccharide and core lipid A mutant O1 and O139 Vibrio cholerae strains for adherence properties on mucus-producing cell line HT29-Rev MTX and virulence in mice

Components of lipopolysaccharide (LPS), i.e. capsule, O antigen, core oligosaccharide, as well as the toxin-coregulated pili are among the factors which significantly contribute to intestinal colonization by Vibrio cholerae O1 and O139. To further address the contribution of LPS to V. cholerae virulence, we performed in vivo colonization experiments and mucus layer attachment studies with defined LPS and capsule mutants of O1 and O139. We investigated the interaction of V. cholerae strains with the differentiated human intestinal cell line HT29-Rev MTX, and found 3-5-fold reduced efficiencies for attachment by defined LPS and capsule mutants of O1 and O139 in comparison with the wild-type strains. In addition, two O1/O139-specific core oligosaccharide biosynthetic gene products, WavJ and WavD, were characterized and tested for colonization. We demonstrate that single and double knockout mutants in wavJ and wavD have an effect on core oligosaccharide biosynthesis, and that these mutants show an attenuated growth in the presence of novobiocin. Curiously, in the mouse intestinal colonization model, only the O139 wavJ,D mutants demonstrated reduced colonization.

The sodium-driven flagellar motor controls exopolysaccharide expression in Vibrio cholerae

Vibrio cholerae causes the life-threatening diarrheal disease cholera. This organism persists in aquatic environments in areas of endemicity, and it is believed that the ability of the bacteria to form biofilms in the environment contributes to their persistence. Expression of an exopolysaccharide (EPS), encoded by two vps gene clusters, is essential for biofilm formation and causes a rugose colonial phenotype. We previously reported that the lack of a flagellum induces V. cholerae EPS expression. To uncover the signaling pathway that links the lack of a flagellum to EPS expression, we introduced into a rugose flaA strain second-site mutations that would cause reversion back to the smooth phenotype. Interestingly, mutation of the genes encoding the sodium-driven motor (mot) in a nonflagellated strain reduces EPS expression, biofilm formation, and vps gene transcription, as does the addition of phenamil, which specifically inhibits the sodium-driven motor. Mutation of vpsR, which encodes a response regulator, also reduces EPS expression, biofilm formation, and vps gene transcription in nonflagellated cells. Complementation of a vpsR strain with a constitutive vpsR allele likely to mimic the phosphorylated state (D59E) restores EPS expression and biofilm formation, while complementation with an allele predicted to remain unphosphorylated (D59A) does not. Our results demonstrate the involvement of the sodium-driven motor and suggest the involvement of phospho-VpsR in the signaling cascade that induces EPS expression. A nonflagellated strain expressing EPS is defective for intestinal colonization in the suckling mouse model of cholera and expresses reduced amounts of cholera toxin and toxin-coregulated pili in vitro. Wild-type levels of virulence factor expression and colonization could be restored by a second mutation within the vps gene cluster that eliminated EPS biosynthesis. These results demonstrate a complex relationship between the flagellum-dependent EPS signaling cascade and virulence.

MglA regulates transcription of virulence factors necessary for Francisella tularensis intraamoebae and intramacrophage survival

Francisella tularensis is able to survive and grow within macrophages, a trait that contributes to pathogenesis. Several genes have been identified that are important for intramacrophage survival, including mglA and iglC. F. tularensis is also able to survive within amoebae. It is shown here that F. tularensis mglA and iglC mutant strains are not only defective for survival and replication within the macrophage-like cell line J774, but also within Acanthamoebae castellanii. Moreover, these strains are highly attenuated for virulence in mice, suggesting that a common mechanism underlies intramacrophage and intraamoebae survival and virulence. A 2D gel analysis of cell extracts of wild-type and mglA mutant strains revealed that at least seven prominent proteins were at low levels in the mglA mutant, and one MglA-regulated protein was identified as the IglC protein. RT-PCR analysis demonstrated reduced transcription of iglC and several other known and suspected virulence genes in the mglA mutant. Thus, MglA regulates the transcription of virulence factors of F. tularensis that contribute to intramacrophage and intraamoebae survival.

Allelic exchange inFrancisella tularensisusing PCR products

We describe here a technique for allelic exchange in Francisella tularensis subsp. novicida utilizing polymerase chain reaction (PCR) products. Linear PCR fragments containing gene deletions with an erythromycin resistance cassette insertion were transformed into F. tularensis. The subsequent ErmR progeny were found to have undergone allelic exchange at the correct location in the genome; the minimum flanking homology necessary was 500 bp. This technique was used to create mglA, iglC, bla, and tul4 mutants in F. tularensis subsp. novicida strains. The mglA and iglC mutants were defective for intramacrophage growth, and the tul4 mutant lacked detectable Tul4 by Western immunoblot, as expected. Interestingly, the bla mutant maintained resistance to ampicillin, indicating the presence of multiple ampicillin resistance genes in F. tularensis.

Role of Vibrio cholerae O139 surface polysaccharides in intestinal colonization

Since the first occurrence of O139 Vibrio cholerae as a cause of cholera epidemics, this serogroup has been investigated intensively, and it has been found that its pathogenicity is comparable to that of O1 El Tor strains. O139 isolates express a thin capsule, composed of a polymer of repeating units structurally identical to the lipopolysaccharide (LPS) O side chain. In this study, we investigated the role of LPS O side chain and capsular polysaccharide (CPS) in intestinal colonization by with genetically engineered mutants. We constructed CPS-negative, CPS/LPS O side chain-negative, and CPS-positive/LPS O side chain-negative mutants. Furthermore, we constructed two mutants with defects in LPS core oligosaccharide (OS) assembly. Loss of LPS O side chain or CPS resulted in a approximately 30-fold reduction in colonization of the infant mouse small intestine, indicating that the presence of both LPS O side chain and CPS is important during the colonization process. The strain lacking both CPS and LPS O side chain and a CPS-positive, LPS O side chain-negative core OS mutant were both essentially unable to colonize. To characterize the role of surface polysaccharides in survival in the host intestine, resistance to several antimicrobial substances was investigated in vitro. These investigations revealed that the presence of CPS protects the cell against attack of the complement system and that an intact core OS is necessary for survival in the presence of bile.

Characterization of the role of the ToxR-modulated outer membrane porins OmpU and OmpT in Vibrio cholerae virulence

ToxR, the transmembrane regulatory protein required for expression of virulence factors in the human diarrheal pathogen Vibrio cholerae, directly activates and represses the transcription of two outer membrane porins, OmpU and OmpT, respectively. In an attempt to dissect the role of the OmpU and OmpT porins in viability and virulence factor expression, in-frame chromosomal deletions were constructed in the coding sequences of ompU and ompT of V. cholerae. Two separate deletions were introduced into ompU; the first (small) deletion, Delta ompU1, removed the coding sequence for 84 internal amino acids (aa), while the second (large) deletion, Delta ompU2, removed the coding sequence for the entire amino-terminal 274 aa. The Delta ompU1 strain had a growth defect that could not be complemented by episomal expression of full-length ompU. In contrast, a strain with Delta ompU2 displayed wild-type growth kinetics in rich media, suggesting that this is the true phenotype of a strain lacking OmpU and that the truncated OmpU protein, rather than the absence of OmpU, may be the cause for the Delta ompU1 phenotype. A large deletion removing the coding sequence for the entire N-terminal 273 aa of OmpT (Delta ompT) was also constructed in wild-type as well as Delta toxR and Delta ompU2 strains, and these strains displayed wild-type growth kinetics in rich media. However, the Delta ompU2 strain was deficient for growth in deoxycholate compared to wild-type, Delta ompT, and Delta ompU2 Delta ompT strains, reinforcing a positive role for the OmpU porin and a negative role for the OmpT porin in V. cholerae resistance to anionic detergents. The Delta ompU2, Delta ompT, and Delta ompU2 Delta ompT strains exhibited wild-type levels of in vitro virulence factor expression and resistance to polymyxin B and serum and in vivo colonization levels similar to a wild-type strain in the infant mouse intestine. Our results demonstrate that (i) OmpU and OmpT are not essential proteins, as was previously thought; (ii) these porins contribute to V. cholerae resistance to anionic detergents; and (iii) OmpU and OmpT are not essential for virulence factor expression in vitro or intestinal colonization in vivo.

Characterization of Vibrio cholerae O1 El tor galU and galE mutants: influence on lipopolysaccharide structure, colonization, and biofilm formation

Recently we described the isolation of spontaneous bacteriophage K139-resistant Vibrio cholerae O1 El Tor mutants. In this study, we identified phage-resistant isolates with intact O antigen but altered core oligosaccharide which were also affected in galactose catabolism; this strains have mutations in the galU gene. We inactivated another gal gene, galE, and the mutant was also found to be defective in the catabolism of exogenous galactose but synthesized an apparently normal lipopolysaccharide (LPS). Both gal mutants as well as a rough LPS (R-LPS) mutant were investigated for the ability to colonize the mouse small intestine. The galU and R-LPS mutants, but not the galE mutant, were defective in colonization, a phenotype also associated with O-antigen-negative mutants. By investigating several parameters in vitro, we could show that galU and R-LPS mutants were more sensitive to short-chain organic acids, cationic antimicrobial peptides, the complement system, and bile salts as well as other hydrophobic agents, indicating that their outer membrane no longer provides an effective barrier function. O-antigen-negative strains were found to be sensitive to complement and cationic peptides, but they displayed significant resistance to bile salts and short-chain organic acids. Furthermore, we found that galU and galE are essential for the formation of a biofilm in a spontaneous phage-resistant rugose variant, suggesting that the synthesis of UDP-galactose via UDP-glucose is necessary for biosynthesis of the exopolysaccharide. In addition, we provide evidence that the production of exopolysaccharide limits the access of phage K139 to its receptor, the O antigen. In conclusion, our results indicate involvement of galU in V. cholerae virulence, correlated with the observed change in LPS structure, and a role for galU and galE in environmental survival of V. cholerae.

The absence of a flagellum leads to altered colony morphology, biofilm development and virulence in Vibrio cholerae O139

Throughout most of history, epidemic and pandemic cholera was caused by Vibrio cholerae of the serogroup O1. In 1992, however, a V. cholerae strain of the serogroup O139 emerged as a new agent of epidemic cholera. Interestingly, V. cholerae O139 forms biofilms on abiotic surfaces more rapidly than V. cholerae O1 biotype El Tor, perhaps because regulation of exopolysaccharide synthesis in V. cholerae O139 differs from that in O1 El Tor. Here, we show that all flagellar mutants of V. cholerae O139 have a rugose colony morphology that is dependent on the vps genes. This suggests that the absence of the flagellar structure constitutes a signal to increase exopolysaccharide synthesis. Furthermore, although exopolysaccharide production is required for the development of a three-dimensional biofilm, inappropriate exopolysaccharide production leads to inefficient colonization of the infant mouse intestinal epithelium by flagellar mutants. Thus, precise regulation of exopolysaccharide synthesis is an important factor in the survival of V. cholerae O139 in both aquatic environments and the mammalian intestine.

Phosphorylation of the flagellar regulatory protein FlrC is necessary for Vibrio cholerae motility and enhanced colonization

The human pathogen Vibrio cholerae specifically expresses virulence factors within the host, including cholera toxin (CT) and the toxin co-regulated pilus (TCP), which allow it to colonize the intestine and cause disease. V. cholerae is a highly motile organism by virtue of a polar flagellum, and motility has been inferred to be an important aspect of virulence, yet the exact role of motility in pathogenesis has remained undefined. The two-component regulatory system FlrB/FlrC is required for polar flagellar synthesis; FlrC is a sigma54-dependent transcriptional activator. We demonstrate that the transcriptional activity of FlrC affects both motility and colonization of V. cholerae. In a purified in vitro reaction, FlrB transfers phosphate to the wild-type FlrC protein, but not to a mutant form in which the aspartate residue at amino acid position 54 has been changed to alanine (D54A), consistent with this being the site of phosphorylation of FlrC. The wild-type FlrC protein, but not the D54A protein, activates sigma54-dependent transcription in a heterologous system, demonstrating that phospho-FlrC is the transcriptionally active form. A V. cholerae strain containing a chromosomal flrCD54A allele did not synthesize a flagellum and had no detectable levels of transcription of the critical sigma54-dependent flagellin gene flaA. The V. cholerae flrCD54A mutant strain was also defective in its ability to colonize the infant mouse small intestine, approximately 50-fold worse than an isogenic wild-type strain. Another mutation of FlrC (methionine 114 to isoleucine; M114I) confers constitutive transcriptional activity in the absence of phosphorylation, but a V. cholerae flrCM114I mutant strain, although flagellated and motile, was also defective in its ability to colonize. The strains carrying D54A or M114I mutant FlrC proteins expressed normal levels of CT and TCP under in vitro inducing conditions. Our results show that FlrC 'locked' into either an inactive (D54A) or an active (M114I) state results in colonization defects, thereby demonstrating a requirement for modulation of FlrC activity during V. cholerae pathogenesis. Thus, the sigma54-dependent transcriptional activity of the flagellar regulatory protein FlrC contributes not only to motility, but also to colonization of V. cholerae.

Only two of the Trichomonas vaginalis triplet AP51 adhesins are regulated by iron

The sexually transmitted parasite Trichomonas vaginalis cytoadheres to the vaginal epithelium, and four candidate trichomonad adhesins have been identified. One such protein, termed AP51, was characterized further. To do this, we studied a 1 kb cDNA clone (AP51.2) isolated from a phagemid expression library, which encoded a fusion protein of approximately 38 kDa that was immuno-crossreactive with anti-AP51 serum and retained functional adhesive properties. We performed 5'-PCR amplification to recover the missing 5' end in order to provide the complete cDNA sequence for the gene encoded by AP51.2 (ap51-2). Other PCR products revealed almost complete sequences for two additional ap51 genes, making AP51 a member of a multigene family of at least three distinct proteins and genes. The ap51-1 and ap51-3 genes each encoded for 407 amino acids while ap51-2 encoded 408 amino acids, and not unexpectedly, these genes had a high percent identity at the DNA and amino acid levels. Mapping confirmed the sequence distinctions and uniqueness of the three ap51 genes. Southern analysis using gene-specific probes revealed the single copy nature of each of the ap51 genes, all of which were present among the numerous agar clones of single trichomonads of the isolates tested. Importantly, Northern analysis showed transcriptional regulation by iron of only the ap51-1 and ap51-3 genes but not ap51-2, perhaps indicating the presence of two bona fide isoforms of the ap51 genes. The 3'-untranslated region of ap51-3 had a short poly (A) tail as well as the sequence motif AUUUA, which may relate to differential degradation of ap51-3 transcripts, in comparison to ap51-1 and ap51-2. Finally, the ap51 genes had partial homology to the beta-subunit of succinyl-CoA synthetase, reinforcing the idea that molecular mimicry may play a role in host parasitism by T. vaginalis.

Molecular characterization of a third malic enzyme-like AP65 adhesin gene of Trichomonas vaginalis

Adherence to the vaginal epithelium by the sexually transmitted parasite Trichomonas vaginalis is mediated by four trichomonad surface proteins (AP65, AP51, AP33 and AP23). We recently showed that the 65-kDa adhesin is a member of a multigene family comprised of two similar but distinct proteins, AP65-1 and AP65-2, encoded by the genes ap65-1 and ap65-2, respectively. An additional immuno-crossreactive clone, the 1.2 kb F11.1 cDNA, was isolated from a phagemid expression library and encoded a fusion protein of approximately 46,000 daltons (46 kDa) that bound to HeLa cell surfaces. A significant portion of the 5' end was missing which, using the 5'-RACE method, was obtained and combined with the F11.1 clone to give a full-length cDNA. The ap65-3 gene encoded for a protein of 567 amino acids with a molecular mass of 63.1 kDa. The gene showed 88% and 96% identity at the DNA level with ap65-1 and ap65-2, respectively. Restriction mapping confirmed that the three AP65 genes are different. Southern analysis revealed that the ap65-3 gene is present in the T. vaginalis genome in multiple copies. Experiments with agar clones of trichomonads showed that each gene of the multigene family is present in all parasites, and Northern analysis showed that ap65-3 is expressed and transcriptionally regulated by iron. The ap65-3 gene had a leader sequence and, as with ap65-1 and ap65-2, showed significant homology to malic enzyme. Finally, analysis of the 3'-untranslated regions revealed that the transcript of ap65-3 had a long poly (A) tail in comparison to ap65-1 and ap65-2. Even more intriguing, sequences were found that may relate to differential degradation of select AP65 transcripts, such as the sequence motifs AUUUA for ap65-1 mRNA and UUAUUUAU for the ap65-2 mRNA, which were not found for ap65-3.