Some properties of nicked Vibrio vulnificus hemolysin

Cardiolipin synthetase is involved in antagonistic interaction (reverse CAMP phenomenon) of Mycoplasma species with Staphylococcus aureus beta-hemolysis

Mycoplasma hyorhinis has been implicated in a variety of swine diseases. However, little is known about the hemolytic capabilities of Mycoplasma species in general or M. hyorhinis in particular. In this study, we show that M. hyorhinis possesses beta-hemolytic activity which may be involved in the invasion process. M. hyorhinis also possesses antagonistic cooperativity (reverse CAMP phenomenon) with Staphylococcus aureus beta-hemolysis, resulting in the protection of erythrocytes from the beta-hemolytic activity of S. aureus (reverse CAMP). The reversed CAMP phenomenon has been attributed to phospholipase D (PLD) activity. In silico analysis of the M. hyorhinis genome revealed the absence of the pld gene but the presence of the cls gene encoding cardiolipin synthetase, which contains two PLD active domains. The transformation of Mycoplasma gallisepticum that has neither the cls gene nor the reverse CAMP phenomenon with the cls gene from M. hyorhinis resulted in the reverse CAMP phenomenon, suggesting for the first time that reverse CAMP can be induced by cardiolipin synthetase.

The extracellular metalloprotease of Vibrio tubiashii directly inhibits its extracellular haemolysin

Vibrio tubiashii is a re-emerging pathogen of molluscs that secretes a variety of extracellular products (ECPs), including a metalloprotease and a cytolysin/haemolysin. Previously, we reported that the V. tubiashii haemolysin locus consists of two ORFs (vthB and vthA), similar to that of the homologous haemolysin genes (vvhB and vvhA) found in Vibrio vulnificus. Here, we demonstrate that the concomitant expression of both V. tubiashii genes resulted in significantly higher haemolytic activity than the vthA gene alone. In addition, we created a VthAB- mutant strain of V. tubiashii that was virtually devoid of haemolytic activity in liquid media. Interestingly, significant production of an additional haemolysin(s) was observed on blood plates. Moreover, we have previously reported that in V. tubiashii, proteolytic and haemolytic activities are inversely produced during bacterial growth. Here, we study this correlation in more detail and present evidence that the VtpA metalloprotease inhibits haemolytic activity in culture supernatants, based on the following evidence: (i) loss of metalloprotease activity by either mutation or EDTA inhibition resulted in increased haemolytic activity; (ii) overexpression of the vtpA gene resulted in decreased haemolytic activity; (iii) purified VtpA metalloprotease directly diminished haemolytic activity by purified VthA haemolysin. Importantly, we found not only that vthAB gene expression remained high throughout growth but also that there were no dramatic differences in vthAB gene expression between the parent and VtpA- mutant strains. Thus, our results strongly suggest that the V. tubiashii metalloprotease directly targets its haemolysin.

Role of the metalloprotease Vvp and the virulence plasmid pR99 of Vibrio vulnificus serovar E in surface colonization and fish virulence

The virulence for eels of Vibrio vulnificus biotype 2 serovar E (VSE) is conferred by a plasmid that codifies ability to survive in eel serum and cause septicaemia. To find out whether the plasmid and the selected chromosomal gene vvp plays a role in the initial steps of infection, the VSE strain CECT4999, the cured strain CT218 and the Vvp-deficient mutant CT201 (obtained in this work by allelic exchange) were used in colonization and virulence experiments. The eel avirulent biotype 1 (BT1) strain YJ016, whose genome has been sequenced, was used for comparative purposes. The global results demonstrate that the plasmid does not play a significant role in surface colonization because (i) CECT4999 and CT218 were equally chemoattracted towards and adherent to eel mucus and gills, and (ii) CT218 persisted in gills from bath-infected eels 2 weeks post infection. In contrast, mutation in vvp gene reduced significantly chemoattraction and attachment to eel mucus and gills, as well as virulence degree by immersion challenge. Co-infection experiments by bath with CECT4999 and CT201 confirmed that Vvp was involved in eel colonization and persistence in gills, because CECT4999 was recovered at higher numbers compared with CT201 from both internal organs of moribund fish (ratio 4:1) and gills from survivors (ratio 50:1). Interestingly, YJ016 also showed chemoattraction and attachment to mucus, and complementation of CT201 with BT1-vvp gene restored both activities together with virulence degree by immersion challenge. Additional experiments with algae mucus and purified mucin gave similar results. In conclusion, the protease Vvp of V. vulnificus seems to play an essential role in colonization of mucosal surfaces present in aquatic environments. Among the V. vulnificus strains colonizing fish mucus, only those harbouring the plasmid could survive in blood and cause septicaemia.

The crucial amino acid residue related to inactivation of Vibrio vulnificus hemolysin

Vibrio vulnificus, an opportunistic human pathogen causing fetal septicemia, produces a 50-kDa pore-forming toxin as a virulence factor. This toxin consists of 451 amino acid residues; however, there are two types of this toxin on the basis of the difference of some amino acid residues, type 1 (Leu(281), Ser(415), Asn(435)/Asp(435), Asn(438)) and type 2 (Ile(281), Asn(415), Asn(435), Thr(438)). In the present study, two characteristic properties of type 2 toxin that was elaborated by V. vulnificus cells or synthesized by the in vitro system were compared to those of type 1 toxin. Type 2 toxin was found to be more resistant to spontaneous inactivation at 37 degrees C and to specific inactivation by cholesterol. On the other hand, a variant of type 2 toxin (Asp(435), Asn(438)) showed the same properties as type 1 toxin. The replacement of the 438th Asn to Thr (N438T), but not the 435th Asp to Asn (D435N), resulted in reversion of the variant type 2 toxin to typical type 2 toxin. These findings indicate that a single amino acid residue, Thr(438), may be critical for higher stability of type 2 toxin.

The cytotoxin-hemolysin genes of human and eel pathogenic Vibrio vulnificus strains: comparison of nucleotide sequences and application to the genetic grouping

Vibrio vulnificus can be divided into two groups on the basis of pathogenesis. Group 1 is pathogenic only to humans, whereas group 2 is pathogenic to eels and occasionally to humans. Although both groups produce a 50-kDa cytotoxin-hemolysin (V. vulnificus hemolysin; VVH), the toxins are different. In the present study, the nucleotide sequence of the toxin gene (vvhA ) of strain CDC B3547 (a group 2 strain) was determined, and the deduced amino acid sequence was compared to that of strain L-180 (a group 1 strain). The nucleotide sequence of vvhA of strain CDC B3547 was about 96% identical with that of strain L-180, which results in a difference of 3 amino acid residues in the C-terminal lectin domain of VVH. Nevertheless, two primer sets for polymerase chain reaction could be designed to differentiate the toxin gene of each strain. When 27 V. vulnificus clinical isolates were tested, group 1 strains (9 strains) were shown to react only to the primers designed for vvhA of strain L-180; whereas, the gene of group 2 strains (18 strains) could be amplified with the primers for vvhA of strain CDC B3547. These findings may lead to development of a novel genetic grouping system related to the virulence potential or to the host range.

Pathogenic Factors of Vibrios with Special Emphasis on Vibrio vulnificus

Bacteria of the genus Vibrio are normal habitants of the aquatic environment and play roles for biocontrole of aquatic ecosystem, but some species are believed to be human pathogens. These species can be classified into two groups according to the types of diseases they cause: the gastrointestinal infections and the extraintestinal infections. The pathogenic species produce various pathogenic factors including enterotoxin, hemolysin, cytotoxin, protease, siderophore, adhesive factor, and hemagglutinin. We studied various pathogenic factors of vibrios with special emphasis on protease and hemolysin of V. vulnificus. V. vulnificus is now recognized as being among the most rapidly fatal of human pathogens, although the infection is appeared in patients having underlying disease(s) such as liver dysfunction, alcoholic cirrhosis or haemochromatosis. V. vulnificus protease (VVP) is thought to be a major toxic factor causing skin damage in the patients having septicemia. VVP is a metalloprotease and degrades a number of biologically important proteins including elastin, fibrinogen, and plasma proteinase inhibitors of complement components. VVP causes skin damages through activation of the Factor XII-plasma kallikrein-kinin cascade and/or exocytotic histamine release from mast cells, and a haemorrhagic lesion through digestion of the vascular basement membrane. Thus, the protease is the most probable candidate for tissue damage and bacterial invasion during an infection. Pathogenic roles and functional mechanism of other factors including hemolysins of V. vulnificus and V. mimicus are also shown in this review article.

Immunogenic antigens of the eel pathogen Vibrio vulnificus serovar E

The immunogenic antigens of Vibrio vulnificus serovar E were investigated in the eel. Fish were vaccinated by immersion with Vulnivaccine (V), revaccinated 2 years later by intraperitoneal injection (RV) and bath infected 15 days post-revaccination (RVI). The specific immune response in serum was followed in all groups, and selected sera were used for immunostaining of surface (SA) and extracellular antigens (ECA). Bacteria were grown in iron-rich (TSB and MSWYE) and iron-poor media (TSB and MSWYE plus human transferrin (TSB-T and MSWYE-T)) as well as eel serum (ES), and their SA and ECA were extracted and electrophoretically analysed. Cells grown in MSWYE-T and ES presented the same antigenic profiles, which suggests that iron-restriction is the main growth-limiting factor in vivo. The electrophoretic pattern of SA, but not that of ECA, varied with iron-availability in the growth medium. Further, SA extracted from bacteria grown in iron restriction were strongly immunogenic for eels, especially after vaccination and infection. Among the immunogenic antigens over expressed in iron-restriction, three outer membrane proteins of around 70-80 kDa, including the putative receptor for vulnibactin, together with the rapid and slow migrating forms of the lipopolysaccharide (LPS), were identified. The response was not so evident in the case of capsule, which was not clearly stained with any of the eel sera. With respect to ECA, two proteins, identified as the V. vulnificus protease (Vvp) and the major outer membrane protein (OMP), probably liberated to the medium after cell death, were recognised by RV and, more strongly, by RVI sera. The specific antibodies against the mentioned OMPs, LPS bands and the Vvp may contribute to the protection of vaccinated eels against infection, giving a reasonable explanation for the high effectiveness of Vulnivaccine.

Induction of oxidative stress in leukocytes by an Enterobacter cloacae toxin able to form oligomers and binding to proteins

A leukotoxic and hemolytic toxin was purified from cultures of Enterobacter cloacae. Stimulation of oxidative stress was observed and the production of reactive oxidant species was measured in leukocytes treated with toxin by means of nitroblue tetrazolium and chemiluminescence assays. Molecular weight of toxin was estimated by chromatography and SDS-PAGE. Two protean peaks with toxic activity were found in Sephadex G-100 (P1, 42.0 kDa; and P2, 13.3 kDa). The relative amounts between the peaks (P1/P2 = 0.36) changed when 2-mercaptoethanol was employed (P1/P2 = 0.59). When Sephadex G-200 chromatography was performed, a protean peak of Ve = 113 mL (100 kDa) was found; its was dissociated with 3 M urea in toxic proteins of lower mass: 42, 27, and 13.3 kDa. SDS-PAGE (15%) showed a single toxin band of purified monomer (13.3 kDa), but electrophoresis of a 42-kDa toxin with urea presented three bands of trimer, dimer, and monomer. An increase of casein hydrolysate and albumin molecular weight was observed by chromatography after incubation with toxin due to the binding of both proteins with toxin.

Oligomerization of Vibrio cholerae cytolysin yields a pentameric pore and has a dual specificity for cholesterol and sphingolipids in the target membrane

Vibrio cholerae cytolysin permeabilizes animal cell membranes. Upon binding to the target lipid bilayer, the protein assembles into homo-oligomeric pores of an as yet unknown stoichiometry. Pore formation has been observed with model liposomes consisting of phosphatidylcholine and cholesterol, but the latter were much less susceptible to the cytolysin than were erythrocytes or intestinal epithelial cells. We here show that liposome permeabilization is strongly promoted if cholesterol is combined with sphingolipids, whereby the most pronounced effects are observed with monohexosylceramides and free ceramide. These two lipid species are prevalent in mammalian intestinal brush border membranes. We therefore propose that, on its natural target membranes, the cytolysin has a dual specificity for both cholesterol and ceramides. To assess the stoichiometry of the pore, we generated hybrid oligomers of two naturally occurring variants of the toxin that differ in molecular weight. On SDS-polyacrylamide gel electrophoresis, the mixed oligomers formed a pattern of six distinct bands. Ordered by decreasing electrophoretic mobility, the six oligomer species must comprise 0 to 5 subunits of the larger form; the pore thus is a pentamer. Due to both lipid specificity and pore stoichiometry, V. cholerae cytolysin represents a novel prototype in the class of bacterial pore-forming toxins.