Immune mechanisms and protective antigens of Vibrio cholerae serogroup O139 as a basis for vaccine development.

We have characterized 11 isolates of Vibrio cholerae O139 Bengal with regard to properties deemed to be relevant for development of a vaccine against O139 cholera. For most strains two colony variants, A and B, which are nonhemolytic and hemolytic, respectively, were detected on blood agar. The A and B variants were associated with high- and low-level production of soluble hemagglutinin-protease, respectively. However, on Luria-Bertani agar both types formed opaque colonies, which has been shown to be associated with capsule formation. Interestingly, under the stationary tube-shaken flask culture conditions in yeast extract-peptone water medium which were used to stimulate the production of cholera toxin (CT) and toxin-coregulated pili, B variants constitutively produced CT and TcpA, two ToxR-regulated proteins, at 28 and 37 degrees C, whereas the production of these proteins by A variants was downregulated at the higher temperature. One of the strains, 4260B, having a well-exposed O antigen and capsule and the capacity to produce large amounts of TcpA, CT, and mannose-sensitive hemagglutinin pili but minimal amounts of the proteolytic soluble hemagglutinin, was selected to produce antibacterial antisera and as a challenge strain in protection studies using the rabbit ileal loop model. Rabbit antisera to live, heat-killed, or formalin-killed O139 vibrios or to purified O139 lipopoly-saccharide (LPS) as well as monoclonal antibodies (MAbs) to O139 LPS agglutinated all O139 isolates. However, when A and B variants of strain 4260 were tested for sensitivity to vibriocidal activity of these antibody preparations, only the B variant was killed. All of the antisera against live or killed O139 vibrios conferred passive protection against fluid accumulation induced by the challenge strain. The protective effects of the antisera were correlated to anti-LPS antibody titers rather than to titers against whole bacteria that had been grown for toxin-coregulated pilus expression. This protection was considerably higher than that conferred by antisera to classical, EI Tor, or recombinantly produced (classical) CT or CTB. Furthermore, MAbs to O139 LPS and CTB-CT exhibited a strong synergistic protection against O139 challenge irrespective of the level of sensitivity of challenge strains to O139 LPS MAbs in vibriocidal assays in vitro.