Brenda L. Brandt

Efficacy, safety, and immunogenicity of a meningococcal group B (15:P1.3) outer membrane protein vaccine in Iquique, Chile

A meningococcal group B (15:P1.3) outer membrane protein vaccine was tested for efficacy in a randomized, double-blind controlled study in Iquique, Chile. A total of 40 811 volunteers, ages 1-21 years, enrolled in the study. Volunteers received two doses of vaccine six weeks apart by jet injector. Both the experimental vaccine and the control vaccine (Menomune, A, C, Y and W135 meningococcal polysaccharide vaccine) were well tolerated with minor side-effects. Active surveillance for suspected cases of meningococcal disease was conducted for 20 months in Iquique. Eighteen cases of group B meningococcal disease were confirmed during the 20 months. Efficacy was estimated to be 51% (p = 0.11) for all ages combined. In children aged 1-4 no protection was evident, but in volunteers aged 5-21 vaccine efficacy was 70% (p = 0.045). The IgG antibody response by ELISA was characterized by a large booster effect after the second dose, followed by a substantial drop in antibody levels by 6 months. The youngest children had the highest responses. The bactericidal antibody response, on the other hand, was characterized by the lack of a significant booster response, higher responses in the older children, and an increase in the geometric mean titer in the later months of the study in the older children.

Safety and immunogenicity testing of an intranasal group B meningococcal native outer membrane vesicle vaccine in healthy volunteers

An intranasal vaccine composed of native outer membrane vesicles (NOMV) not exposed to detergent or denaturing agents was prepared from the group B meningococcal strain 9162 SynX(-)(-:15:P1.3:P5.10,11:L3,7,9) and tested in 32 healthy adult volunteers. Four groups of 8 volunteers were vaccinated intranasally with three doses of vaccine. The vaccine was very well tolerated in all dosing groups, despite the presence of lipo-oligosaccharide in the vaccine at a level of 25% relative to protein. The antibody response as measured by ELISA in serum, saliva and nasal wash fluids was relatively low in all 4 groups, but the induced serum antibodies had strong bactericidal activity. Persistent bactericidal antibodies (> or =4-fold increase) were produced in 75% of the recipients. Some of the bactericidal antibodies were cross reactive against divergent group B strains. Most of the bactericidal antibodies appeared to be specific for PorA and L3,7,9 LOS. The vaccine also produced a local antibody response which was detected in the nasal wash fluids of volunteers. These data suggest that nasal immunization with NOMV is a safe and effective approach to induce systemic and local immunity against the group B meningococcus and deserves further study.

Characterization of Native Outer Membrane Vesicles from lpxL Mutant Strains of Neisseria meningitidis for Use in Parenteral Vaccination

ABSTRACT Native outer membrane vesicles (NOMV) of Neisseria meningitidis consist of intact outer membrane and contain outer membrane proteins (OMP) and lipooligosaccharides (LOS) in their natural conformation and membrane environment. NOMV have been safely used intranasally in P1 studies with encouraging results, but they are too toxic for parenteral vaccination. We now report the preparation and characterization of lpxL mutants that express LOS with reduced toxicity, and the evaluation of the potential of NOMV from these strains for use as a parenteral vaccine. A series of deletion mutants were prepared with knockouts of one or more of the lpxL1, lpxL2, or synX genes. The ΔlpxL2 mutants had a reduced growth rate, reduced level of LOS expression, and increased sensitivity to surfactants. In addition, ΔsynX ΔlpxL2 double mutants had reduced viability in stationary phase. The ΔlpxL1 ΔlpxL2 double mutant behaved essentially the same as the ΔlpxL2 single mutant. LOS from both lpxL mutant strains exhibited altered migration on polyacrylamide gels. The LOS of ΔlpxL2 mutants of L3,7 strains were fully sialylated. NOMV prepared from lpxL2 mutants was about 200-fold less active than wild-type NOMV in rabbit pyrogen tests and in tumor necrosis factor alpha release assays. Bactericidal titers induced in animals by ΔlpxL2 mutant NOMV were lower than those induced by ΔlpxL1 or wild-type NOMV. However, immunogenicity could be largely restored by use of an adjuvant. These results provide evidence that NOMV from ΔlpxL2 mutant strains will be safe and immunogenic in humans when given parenterally.

Immunogenicity and Safety Testing of a Group B Intranasal Meningococcal Native Outer Membrane Vesicle Vaccine

ABSTRACT The presently licensed meningococcal vaccine is a tetravalent capsular polysaccharide vaccine that induces immunity to serogroups A, C, Y, and W-135 but not to group B, which causes nearly half of the meningitis cases in the United States. The purpose of this study was to evaluate the safety and immunogenicity of an intranasal native outer membrane vesicle (NOMV) vaccine prepared from a capsule negative strain of group B of Neisseria meningitidis. In this study all volunteers received the same dose of vaccine, but we evaluated two different immunization schedules and the oropharyngeal and intranasal routes of vaccine delivery, assessed nasal cytology for cellular infiltration, and measured antibody-secreting cells (enzyme-linked immunospot assay [ELISPOT]) as an early marker for systemic immune response. Additionally, both intranasal and serum vaccine-specific antibodies were measured as well as serum bactericidal activity. Four groups with a total of 42 subjects were immunized on days 0, 28, and 56. Group 3 received an additional dose on day 7. Group 2 subjects were immunized both intranasally and oropharyngeally. Group 4 received a different lot of vaccine. All groups received approximately 1,200 μg of vaccine per subject. Patients were evaluated for side effects. The vaccine was well tolerated without evidence of inflammation on nasal cytology. The group receiving the extra vaccine dose showed the maximum increase in bactericidal activity. Thirty of 42 subjects demonstrated an increase in meningococcus-specific intranasal immunoglobulin A (IgA) titers, while 23 of 42 demonstrated an increase in specific IgG titers. The group receiving vaccine intranasally and oropharyngeally showed the highest rise in intranasal titers for both IgA and IgG. Groups 1, 3, and 4 showed a significant increase in antibody-secreting cells on ELISPOT. Eighteen of 42 volunteers demonstrated a fourfold or greater rise in bactericidal titers, with 81% showing an increase over baseline. We have demonstrated the immunogenicity and safety of a group B lipopolysaccharide-containing, intranasal, NOMV vaccine.

Antibody responses in serum and nasal secretions of children immunized with inactivated and attenuated measles-virus vaccines.

Abstract In 24 children immunized with inactivated or attenuated measles-virus vaccines, responses of serum antibody (characterized by density-gradient ultracentrifugation and radioimmunodiffusion studies) were comparable both in peak titers and in immunoglobulin contribution. In eight of nine children immunized with attenuated measles-virus vaccine nasal antibody associated primarily with the γA and less often with γG immunoglobulins developed; nasal antibody was detected in only three of seven immunized with inactivated measles-virus vaccine, and in these both γA and γG activities were observed. Of eight children with pre-existing serum antibody, six had nasal antibody in the preimmunization specimens. The differences in ability of these vaccines to stimulate local respiratory-tract antibody may in part explain the greater clinical effectiveness of the attenuated vaccine as well as the occurrence of altered reactivity of the host who received inactivated vaccine.

Antibody-dependent Mononuclear Cell-mediated Antimeningococcal Activity: COMPARISON OF THE EFFECTS OF CONVALESCENT AND POSTIMMUNIZATION IMMUNOGLOBULINS G, M, AND A

We have compared the abilities of immunoglobulin (Ig)G, IgM, and IgA to induce either mononuclear cell-mediated (complement-independent) or complement-mediated (cell-free) antibacterial activity against group C meningococci. In each of these assays, immunoglobulins purified from the sera of individuals immunized with meningococcal group C polysaccharide were compared with those purified from sera of patients convalescing from disseminated meningococcal disease. Our data support three conclusions. First, although nonbactericidal in cooperation with complement, IgA can induce cell-mediated antibacterial activity as well as IgG. Second, the amount of IgG required to induce cell-mediated antibacterial activity is similar to the amount required for complement-mediated killing. Third, although the amount of either postimmunization or convalescent IgM required to induce complement-mediated killing is 16- to 20-fold less than the amount of respective IgG required, IgM is inferior to IgG in its ability to induce cell-mediated antibacterial activity because in the cell-mediated system (a) postimmunization IgM is ineffective; (b) the amount of convalescent IgM required for minimal activity is eightfold more than the amount of convalescent IgG required; and (c) the maximal antibacterial index induced by convalescent IgM is 50% less than that which can be induced by IgG. These data suggest that IgG and IgA may play a greater role than IgM in mononuclear cell-mediated antibacterial host immune defense.

Diagnosis of Human Immunodeficiency Virus Infection by Immunoassay Using a Molecularly Cloned and Expressed Virus Envelope Polypeptide: Comparison to Western Blot on 2707 Consecutive Serum Samples

To detect human immunodeficiency virus (HIV) antibodies in a simple enzyme-linked immunoassay (CBre3-EIA), we used an Escherichia coli-expressed polypeptide antigen, representing the carboxy-terminal third of the external membrane glycoprotein gene fused with the amino-terminal half of the transmembrane glycoprotein gene. Over a 3-month period, 2707 consecutive serum samples referred for confirmatory testing for human T-lymphotrophic virus type III (HTLV-III) antibodies were evaluated by both Western blot and CBre3-EIA. On a single determination for each sample, the CBre3-EIA was found to have an estimated sensitivity (99.9%) and specificity (99.1%) similar or superior to the more cumbersome Western blot method. This study shows that all HIV-seropositive subjects have antibodies to the virus envelope protein; no other virus antigens are required for construction of highly sensitive immunoassays.

Human bactericidal antibody response to meningococcal outer membrane protein vaccines

Several different meningococcal outer membrane protein vaccines have been prepared and used in human safety and immunogenicity studies. The results of these studies have led to some general conclusions regarding the human antibody response to these vaccines. A review of these conclusions, however, indicates that a number of important questions and problems still need to be addressed. Two of these are the determination of the protective level of bactericidal antibody in human serum and the impact of phase variation of surface antigens on vaccine strategy. Bactericidal assays using intrinsic complement and high concentrations of serum suggest that the level of natural immunity to group B meningococci is quite high, but is increased by vaccination with outer membrane protein vaccine. Phase variation in meningococcal surface antigens including capsule, class 1 protein, class 5 protein, and lipopolysaccharide was demonstrated using colony blotting with monoclonal antibodies. Phase variation resulted in differences in susceptibility to the bactericidal activity of human sera.

Phase I study of a Neisseria meningitidis liposomal vaccine containing purified outer membrane proteins and detoxified lipooligosaccharide.

Purified outer membrane proteins and purified deacylated lipooligosaccharide (dLOS) were formulated for use as a vaccine in three formulations for clinical use. The three vaccine formulations included (1) purified outer membrane proteins (OMPs) and L8-5 dLOS adsorbed to aluminum hydroxide; (2) purified OMPs and L8-5 dLOS incorporated into liposomes; and (3) purified OMPs and L7 dLOS incorporated into proteoliposomes. The vaccines were compared for immunogenicity and safety in a phase 1clinical study. Ten adult volunteers were vaccinated with each of the three vaccine formulations. Two 50 μg doses were given six weeks apart, and serum samples were obtained at 0, 2, 6, 8 and 14 weeks. Volunteers were evaluated for reactogenicity 30 min after vaccination and at days 1, 2, and 14 after each vaccination, and laboratory safety tests were done at 0, 2 and 6 weeks. Overall, the vaccines were well tolerated. Bactericidal assays against a homologous strain showed a four-fold or greater increase in titer in 6 of 7 volunteers in group one, 9 of 10 volunteers in group two, and 5 of 10 volunteers in group three. A quantitative enzyme linked immunosorbant assay showed increases in antibody against both OMPs and LOS antigens. The liposome formulation appeared to be particularly effective in presenting the dLOS as an antigen.

Importance of Antibodies to Lipopolysaccharide in Natural and Vaccine-Induced Serum Bactericidal Activity against Neisseria meningitidis Group B

ABSTRACT Analysis of the specificity of bactericidal antibodies in normal, convalescent, and postvaccination human sera is important in understanding human immunity to meningococcal infections and can aid in the design of an effective group B vaccine. A collection of human sera, including group C and group B convalescent-phase sera, normal sera with naturally occurring cross-reactive bactericidal activity, and some postvaccination sera, was analyzed to determine the specificity of cross-reactive bactericidal antibodies. Analysis of human sera using a bactericidal antibody depletion assay demonstrated that a significant portion of the bactericidal activity could be removed by purified lipopolysaccharide (LPS). LPS homologous to that expressed on the bactericidal test strain was most effective, but partial depletion by heterologous LPS suggested the presence of antibodies with various degrees of cross-reactivity. Binding of anti-L3,7 LPS bactericidal antibodies was affected by modification of the core structure, suggesting that these functional antibodies recognized epitopes consisting of both core structures and lacto-N-neotetraose (LNnT). When the target strain was grown with 5′-cytidinemonophospho-N-acetylneuraminic acid (CMP-NANA) to increase LPS sialylation, convalescent-phase serum bactericidal titers were decreased by only 2- to 4-fold, and most remaining bactericidal activity was still depleted by LPS. Highly sialylated LPS was ineffective in depleting bactericidal antibodies. We conclude that natural infections caused by strains expressing L3,7 LPS induce persistent, protective bactericidal antibodies and appear to be directed against nonsialylated bacterial epitopes. Additionally, subsets of these bactericidal antibodies are cross-reactive, binding to several different LPS immunotypes, which is a useful characteristic for an effective group B meningococcal vaccine antigen.