Development and pre-clinical evaluation of a synthetic oligosaccharide-protein conjugate vaccine against Neisseria meningitidis serogroup C.

Significant improvement has been made in the development of vaccines against Neisseria meningitidis infections since the introduction of polysaccharide-protein conjugate vaccines. Conventional bacterial capsular polysaccharide (PS) based conjugate vaccines require unique and expensive manufacturing facilities, complex production processes and extensive quality testing. Synthetic oligosaccharide (OS) based approach is one of the novel technologies that is being developed to simplify production of conjugate vaccines. OSs can be chemically synthesized to a desired length long enough to represent the antigenic epitopes which often present as a homogenous mixture. We prepared OSs corresponding to tetramer and octamer of N. meningitidis serogroup C (MenC) PS by organic synthesis. The MenC tetramer and octamer were further conjugated with tetanus toxoid to produce respective monovalent conjugates having the desired physico-chemical characteristics. The conjugates were evaluated in a mouse model for immunogenicity and compared with a licensed PS conjugate vaccine. Synthetic conjugates could induce anti-MenC PS IgG as well as serum bactericidal titers at levels comparable to those elicited by the licensed vaccine. The increase in length of synthetic oligomers from tetramer to octamer did not appear to increase immunogenicity. The results establish the pre-clinical proof of concept for a synthetic MenC oligosaccharide conjugate vaccine candidate.

Inhibition ELISA as a putative tool for the identification and quantification of meningococcal A and X polysaccharides at various stages of vaccine development.

The multivalent glycoconjugate vaccines against Neisseria meningitidis are extremely high-priced for the developing world. The high cost is due to the manufacturing set-up required to produce an effective vaccine and other inflators like complex production steps including the production and purification of the polysaccharide and consequently its conjugation with a protein and finally formulating the finished multivalent product. There is an urgent need for assays which are simple, precise, can be applicable at multiple steps and contribute in reducing the overall manufacturing cost, thereby making the vaccines more equitable to the developing world. WHO recommends serological tests for polysaccharide identification and quantitation at different stages of conjugate vaccine production. We report development of inhibition ELISAs for the identification and quantification of N. meningitidis serogroup A (MenA) and N. meningitidis serogroup X (MenX) polysaccharides (PSs) in samples from stage of cell banking till production of finished product. The method was qualified on various parameters such as specificity, intermediate precision, sensitivity and accuracy. Our results provide a proof of concept for the use of an inhibition ELISA as a common tool for the identification and quantification of PS at various stages of vaccine development and manufacture.

Evaluation of impact of temperature and pH alterations on the size and antigenicity of meningococcal serogroup A and X polysaccharides and conjugates.

The changes in the recommended storage conditions of the glycoconjugate vaccines against Neisseria meningitidis (Men) serogroup A and serogroup X can affect its activity or potency. Elevated temperature and the change in pH may result in the physical instability leading to the size degradation of the polysaccharide (PS) and subsequent loss of PS epitopes. Moreover, high temperature may also result in protein aggregation and altered tertiary structure of the protein in the conjugate. Consequently, the construction of a potent glycoconjugate is dependent on optimal temperature and pH. The changes in both these conditions can also affect the production of a capsular polysaccharide (PS) and its conjugation to a protein carrier and may also affect the integrity of the vaccine molecule including the maintenance of the protective epitopes. In our study we have used inhibition ELISA as a tool to assess the impact of temperature and pH alterations on the antigenicity of N. meningitidis serogroup A and X, PS and conjugates and their correlation with the size distribution analysis using high pressure size exclusion chromatography. The studies on pH alterations from 5 to 9 led to minimal impact on size and antigenicity of all antigens, however, an elevated temperature adversely impacted the antigen size as well as antigenicity to varying extent. Results indicate the higher stability of MenX PS and conjugate as compared to that for MenA counterparts at elevated temperatures. Furthermore, both the MenA and MenX conjugates appears to be more stable as compared to the corresponding PSs.

Rapid processes for purification of capsular polysaccharides from Neisseria meningitidis serogroups A and C.

The glycoconjugate vaccines against Neisseria meningitidis are highly effective, however most of these vaccines are expensive and still out of reach in the developing world as well as the technical know-how and the set-up required for the consistent production of pure polysaccharide is limited. Our laboratory has developed rapid, efficient and scalable processes for the downstream purification of N. meningitidis serogroup A (MenA) and serogroup C (MenC) capsular polysaccharides (PS). The MenC-PS was purified with a novel 2-step procedure including de-O-acetylation and hydrophobic interaction chromatography whereas, MenA-PS was purified using a rapid method as compared to the prior art. The purified PSs were analyzed by various analytical tests including nuclear magnetic resonance, molecular weight, composition and purity analyses to meet desired specifications. Our results provide a proof of principle for the purification of MenA-PS and MenC-PS with reduced timelines.