Mary Matheson

Recombinant Neisseria meningitidis Transferrin Binding Protein A Protects against Experimental Meningococcal Infection

ABSTRACT To better characterize the vaccine potential of Neisseria meningitidis transferrin binding proteins (Tbps), we have overexpressed TbpA and TbpB from Neisseria meningitidisisolate K454 in Escherichia coli. The ability to bind human transferrin was retained by both recombinant proteins, enabling purification by affinity chromotography. The recombinant Tbps were evaluated individually and in combination in a mouse intraperitoneal-infection model to determine their ability to protect against meningococcal infection and to induce cross-reactive and bactericidal antibodies. For the first time, TbpA was found to afford protection against meningococcal challenge when administered as the sole immunogen. In contrast to the protection conferred by TbpB, this protection extended to a serogroup C isolate and strain B16B6, a serogroup B isolate with a lower-molecular-weight TbpB than that from strain K454. However, serum from a TbpB-immunized rabbit was found to be significantly more bactericidal than that from a TbpA-immunized animal. Our evidence demonstrates that TbpA used as a vaccine antigen may provide protection against a wider range of meningococcal strains than does TbpB alone. This protection appears not to be due to complement-mediated lysis and indicates that serum bactericidal activity may not always be the most appropriate predictor of efficacy for protein-based meningococcal vaccines.

Phase I safety and immunogenicity study of a candidate meningococcal disease vaccine based on Neisseria lactamica outer membrane vesicles.

ABSTRACT Natural immunity to meningococcal disease in young children is associated epidemiologically with carriage of commensal Neisseria species, including Neisseria lactamica. We have previously demonstrated that outer membrane vesicles (OMVs) from N. lactamica provide protection against lethal challenge in a mouse model of meningococcal septicemia. We evaluated the safety and immunogenicity of an N. lactamica OMV vaccine in a phase I placebo-controlled, double-blinded clinical trial. Ninety-seven healthy young adult male volunteers were randomized to receive three doses of either an OMV vaccine or an Alhydrogel control. Subsequently, some subjects who had received the OMV vaccine also received a fourth dose of OMV vaccine, 6 months after the third dose. Injection site reactions were more frequent in the OMV-receiving group, but all reactions were mild or moderate in intensity. The OMV vaccine was immunogenic, eliciting rises in titers of immunoglobulin G (IgG) against the vaccine OMVs, together with a significant booster response, as determined by an enzyme-linked immunosorbent assay. Additionally, the vaccine induced modest cross-reactive immunity to six diverse strains of serogroup B Neisseria meningitidis, including IgG against meningococcal OMVs, serum bactericidal antibodies, and opsonophagocytic activity. The percentages of subjects showing ≥4-fold rises in bactericidal antibody titer obtained were similar to those previously reported for the Norwegian meningococcal OMV vaccine against the same heterologous meningococcal strain panel. In conclusion, this N. lactamica OMV vaccine is safe and induces a weak but broad humoral immune response to N. meningitidis.

Nasopharyngeal Colonization by Neisseria lactamica and Induction of Protective Immunity against Neisseria meningitidis

BACKGROUND Natural immunity to Neisseria meningitidis may result from nasopharyngeal carriage of closely related commensals, such as Neisseria lactamica. METHODS We enrolled 61 students with no current carriage of Neisseria species and inoculated them intranasally with 10,000 colony-forming units of Neisseria lactamica or sham control. Colonization was monitored in oropharyngeal samples over 6 months. We measured specific mucosal and systemic antibody responses to N. lactamica and serum bactericidal antibody (SBA) and opsonophagocytic antibodies to a panel of N. meningitidis serogroup B strains. We also inoculated an additional cohort following vaccination with N. lactamica outer-membrane vesicles (OMV) produced from the same strain. RESULTS Twenty-six (63.4%) of 41 inoculated individuals became colonized with N. lactamica; 85% remained colonized at 12 weeks. Noncarriers were resistant to rechallenge, and carriers who terminated carriage were relatively resistant to rechallenge. No carriers acquired N. meningitidis carriage over 24 weeks, compared with 3 control subjects (15%). Carriers developed serum IgG and salivary IgA antibodies to the inoculated N. lactamica strain by 4 weeks; noncarriers and control subjects did not. Cross-reactive serum bactericidal antibody responses to N.meningitidis were negligible in carriers, but they developed broad opsonophagocytic antimeningococcal antibodies. OMV vaccinees developed systemic and mucosal anti-N. lactamica antibodies and were relatively resistant to N. lactamica carriage but not to natural acquisition of N. meningitidis. CONCLUSIONS Carriers of N. lactamica develop mucosal and systemic humoral immunity to N. lactamica together with cross-reacting systemic opsonophagocytic but not bactericidal antibodies to N. meningitidis. Possession of humoral immunity to N. lactamica inhibits acquisition of N. lactamica but not of N. meningitidis. Some individuals are intrinsically resistant to N. lactamica carriage, independent of humoral immunity.

Immunogenicity of a single dose of meningococcal group C conjugate vaccine given at 3 months of age to healthy infants in the United kingdom.

Background: From 1999, in the United Kingdom, meningococcal C conjugate (MCC) vaccines from 3 manufacturers were introduced to the infant immunization schedule at 2, 3 and 4 months of age. In 2006, the schedule was refined to a 2-dose primary schedule at 3 and 4 months of age, with a combined MCC/Haemophilus influenzae type b (MCC/Hib-TT) booster at 12 months of age. Recent data have demonstrated that 2 of the 3 MCC vaccines showed potential for use as a single priming dose in infancy. Methods: A randomized trial was undertaken with 2 MCC vaccines; one using tetanus toxoid carrier protein (MCC-TT) and one using CRM197 carrier protein (MCC-CRM197). Infants were immunized with MCC at 3 months of age followed by an MCC/Hib-TT booster at 12 months of age. Results: The serum bactericidal antibody geometric mean titers 1 month after a single dose of MCC-TT or MCC-CRM 197 were 223.3 (95% confidence interval [CI]: 162.9–306.1) and 95.8 (95% CI: 66.4–138.2) with 100% and 95.5% of infants having serum bactericidal antibody titers ≥ 8, respectively. Before boosting, antibody titers had declined, and 1 month after the MCC/Hib-TT booster, serum bactericidal antibody geometric mean titers rose to 2251.0 (95% CI: 1535.3–3300.3) and 355.9 (95% CI: 235.4–538.1) for children primed with MCC-TT and MCC-CRM 197, respectively. Conclusions: In conclusion, a single priming dose of either MCC-TT or MCC-CRM197 administered at 3 months of age can be used together with the Hib/MCC-TT booster in the second year of life.

Safety and Immunogenicity of Coadministering a Combined Meningococcal Serogroup C and Haemophilus influenzae Type b Conjugate Vaccine with 7-Valent Pneumococcal Conjugate Vaccine and Measles, Mumps, and Rubella Vaccine at 12 Months of Age

ABSTRACT The coadministration of the combined meningococcal serogroup C conjugate (MCC)/Haemophilus influenzae type b (Hib) vaccine with pneumococcal conjugate vaccine (PCV7) and measles, mumps, and rubella (MMR) vaccine at 12 months of age was investigated to assess the safety and immunogenicity of this regimen compared with separate administration of the conjugate vaccines. Children were randomized to receive MCC/Hib vaccine alone followed 1 month later by PCV7 with MMR vaccine or to receive all three vaccines concomitantly. Immunogenicity endpoints were MCC serum bactericidal antibody (SBA) titers of ≥8, Hib-polyribosylribitol phosphate (PRP) IgG antibody concentrations of ≥0.15 μg/ml, PCV serotype-specific IgG concentrations of ≥0.35 μg/ml, measles and mumps IgG concentrations of >120 arbitrary units (AU)/ml, and rubella IgG concentrations of ≥11 AU/ml. For safety assessment, the proportions of children with erythema, swelling, or tenderness at site of injection or fever or other systemic symptoms for 7 days after immunization were compared between regimens. No adverse consequences for either safety or immunogenicity were demonstrated when MCC/Hib vaccine was given concomitantly with PCV and MMR vaccine at 12 months of age or separately at 12 and 13 months of age. Any small differences in immunogenicity were largely in the direction of a higher response when all three vaccines were given concomitantly. For systemic symptoms, there was no evidence of an additive effect; rather, any differences between schedules showed benefit from the concomitant administration of all three vaccines, such as lower overall proportions with postvaccination fevers. The United Kingdom infant immunization schedule now recommends that these three vaccines may be offered at one visit at between 12 and 13 months of age.

Randomized Trial to Compare the Immunogenicity and Safety of a CRM or TT Conjugated Quadrivalent Meningococcal Vaccine in Teenagers who Received a CRM or TT Conjugated Serogroup C Vaccine at Preschool Age.

Background: Protection after meningococcal C (MenC) conjugate (MCC) vaccination in early childhood is short-lived. Boosting with a quadrivalent vaccine in teenage years, a high-risk period for MenC disease, should protect against additional serogroups but might compromise MenC response. The carrier protein in the primary MCC vaccine determines the response to MCC booster in toddlers, but the relationship between primary vaccine and booster given later is unclear. This study compared responses to a CRM-conjugated or tetanus toxoid (TT)-conjugated MenACWY vaccine in teenagers primed with different MCC vaccines at preschool age. Methods: Ninety-three teenagers (16–19 years), who were previously randomized at age 3–6 years to receive single-dose MCC–CRM or MCC–TT, were randomized to receive either MenACWY–CRM or MenACWY–TT booster. Serum bactericidal antibodies (SBA, protective titer ≥8) were measured before, 1 month and 6 or 9 months after boosting. Results: Preboosting, MCC–TT-primed teenagers had significantly higher MenC SBA titers than those MCC–CRM-primed (P = 0.02). Postboosting, both MenACWY vaccines induced protective SBA titers to all 4 serogroups in most participants (≥98% at 1 month and ≥90% by 9 months postboost). The highest MenC SBA titers were seen in those MCC–TT-primed and MenACWY–TT-boosted [geometric mean titer (GMT) ~ 22,000] followed by those boosted with MenACWY–CRM irrespective of priming (GMT ~ 12,000) and then those MCC–CRM-primed and MenACWY–TT-boosted (GMT ~ 5500). The estimated postbooster MenC SBA decline beyond 1 month was ~40% as time since booster doubles. Both vaccines were well tolerated with no attributable serious adverse events. Conclusion: Both MenACWY vaccines safely induced protective sustained antibody responses against all targeted serogroups in MCC-primed teenagers.