Neisseria meningitidis serogroup B is a major cause of bacterial meningitis in younger populations. The available vaccines are based on outer membrane vesicles obtained from wild-type strains. In children less than 2 years old they confer protection only against strains expressing homologous PorA, a major, variable outer membrane protein (OMP). We genetically modified a strain in order to eliminate PorA and to overproduce one or several minor and conserved OMPs. Using a mouse model mimicking children's PorA-specific bactericidal activity, it was demonstrated that overproduction of more than one minor OMP is required to elicit antibodies able to induce complement-mediated killing of strains expressing heterologous PorA. It is concluded that a critical density of bactericidal antibodies needs to be reached at the surface of meningococci to induce complement-mediated killing. With minor OMPs, this threshold is reached when more than one antigen is targeted, and this allows cross-protection.
Current pneumococcal vaccines are composed of capsular polysaccharides (PS) of various serotypes, either as free PS or as protein-PS conjugates. The use of pneumococcus protein antigens that are able to afford protection across the majority of serotypes is envisaged as a relevant alternative and/or complement to the polysaccharides. In this context, based on several studies, the Pht protein family emerged as relevant vaccine candidates. The purpose of the present study was to evaluate the Pht protein family in several preclinical mouse models. Immunization with these antigens was compared with immunization with other pneumococcal antigens, such as CbpA, PspA, and PsaA. In a nasopharyngeal colonization model and in a lung colonization model, the Phts were found to be superior to the other candidates in terms of efficacy of protection and serotype coverage. Likewise, vaccination with PhtD allowed higher animal survival rates after lethal intranasal challenge. Finally, a passive transfer model in which natural anti-PhtD human antibodies were transferred into mice demonstrated significant protection against lethal intranasal challenge. This indicates that natural anti-PhtD human antibodies are able to protect against pneumococcal infection. Our findings, together with the serotype-independent occurrence of the Phts, designate this protein family as valid candidate antigens to be incorporated in protein-based pneumococcal vaccines.
Infections caused by Streptococcus pneumoniae are a major cause of mortality throughout the world. Protein-based pneumococcal vaccines are envisaged to replace or complement the current polysaccharide-based vaccines. In this context, detoxified pneumolysin (dPly) and pneumococcal histidine triad protein D (PhtD) are two potential candidates for incorporation into pneumococcal vaccines. In this study, the protective efficacy of a PhtD-dPly vaccine was evaluated in a rhesus macaque (Macaca mulatta) model of pneumonia. The animals were immunized twice with 10 µg of PhD and 10 µg of dPly formulated in the Adjuvant System AS02 or with AS02 alone, before they were challenged with a 19F pneumococcal strain. The survival was significantly higher in the protein-vaccinated group and seemed to be linked to the capacity to greatly reduce bacterial load within the first week post-challenge. Vaccination elicited high concentrations of anti-PhtD and anti-Ply antibodies and a link was found between survival and antibody levels. In conclusion, AS02-adjuvanted PhtD-dPly vaccine protects against S. pneumoniae-induced pneumonia. It is probable that the protection is at least partially mediated by PhtD- and Ply-specific antibodies.
Recombinant Xgtll phages were selected by screening a genomic library of BruceUa abortus DNA with monoclonal antibodies specific for a 16.5-kDa BruceUla outer membrane protein (Ompl6). The corresponding gene, named pal, was subcloned on a 0.7-kb AluI fragment. Immunoblotting confirmed the expression of a recombinant Ompl6 in the transformants. DNA sequence analysis revealed an open reading frame of 168 codons. The deduced amino acid sequence agrees with an internal peptide sequence of native Ompl6 and contains a potential lipoprotein signal peptide cleavage site, giving rise to a predicted mature protein of 144 amino acids. The predicted sequence of Ompl6 also shows a remarkable degree of similarity to the sequences of three peptidoglycan-associated bacterial lipoproteins. In immunoblotting with a monoclonal antibody specific for Ompl6, we demonstrated that Ompl6 was expressed in the 34 BruceUla strains tested, representing all six species and known biovars.
Brucellosis research is currently focused on the identification of nonlipopolysaccharide (LPS) antigens which could potentially be useful for the specific serologic diagnosis of brucellosis as well as for vaccinal prophylaxis. On the basis of previous reports, we selected eight Brucella proteins (OMP36, OMP25, OMP19, OMP16, OMP10, p17, p15, and p39) as candidate antigens to be further evaluated. The genes encoding these proteins were cloned, sequenced, and overexpressed in Escherichia coli. The recombinant proteins were purified with a polyhistidine tag and metal chelate affinity chromatography and evaluated in an indirect enzyme-linked immunosorbent assay (iELISA). The specificity of the iELISA was determined with sera from healthy cattle, sheep, and goats and ranged from 95 to 99%, depending on the recombinant antigen and the species tested. Sera from experimentally infected, and from naturally infected, animals were used to evaluate the sensitivity of the iELISA. The antiprotein antibody response was often delayed when compared to the anti-smooth LPS (S-LPS) response and was limited to animals which developed an active brucellosis infection (experimentally infected pregnant animals and sheep and goats from areas where brucellosis is still endemic). Among the recombinant antigens, the three cytoplasmic proteins (p17, p15, and p39) gave the most useful results. More than 80% of the animals positive in S-LPS serology were also positive with one of these cytoplasmic proteins alone or a combination of two of them. None of the recombinant antigens detected experimentally infected nonpregnant cows and sheep or naturally infected cattle. This study is a first step towards the development of a multiprotein diagnostic reagent for brucellosis.
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