Development of a low molecular weight synthetic Vi conjugate vaccine for salmonella typhi

Project summary Salmonella typhi (S. typhi) is the major cause of typhoid fever which causes 9.2 million cases of the disease and 110 thousand deaths as reported in 2019. Vaccines against S. typhi have been developed, including Vi polysaccharide vaccine and more recently, Vi conjugate vaccines. They are based on the Vi

polysaccharide of S. typhi which is a linear alpha 1–4 linked polygalacturonic acid (PGA) that is N-acetylated at C2 and O-acetylated at C3 of the galacturonic acid (Gal UA) residue. The O-acetyl group at C3 is the dominant determinant of immunogenicity and potency. The Vi conjugate vaccines, overcoming the T-independence of Vi

polysaccharide vaccine, are T-dependent and effective in protection against typhoid fever in people > 6 months. However, because of the high molecular weight of Vi polysaccharide, these conjugate vaccines could potentially still induce a partial T-independent response and hyporesponsiveness after booster immunization in

people under 2-years. Thus, conjugate vaccines with fragmented or low molecular weight Vi (~50 kDa) are being developed as the potential fully T-dependent and more effective vaccines. Production of Vi vaccines are complex and challenging due to reliance on bacterial fermentation and processing difficulties and low yield of the Vi polysaccharide. Thus, synthetic Vi polysaccharides have been

generated and evaluated through an extensive series of studies initiated by scientists of NICHD (National Institute of Child Health and Human Development). It is produced by O-acetylation of plant polygalacturonic acid (PGA) which shares the same backbone as the Vi polysaccharide and are readily and abundantly

available. The resulting O-acetylated PGA (AcPGA) thus carries the dominant O-acetyl group epitope of Vi polysaccharide. A phase I clinical trial with a synthetic Vi conjugate vaccine has been successfully conducted by the NICHD team which showed that it is safe and immunogenic, thus providing a critical clinical proof-of-

concept for the synthetic Vi conjugate vaccine. Such a synthetic vaccine could provide significant advantages over current Vi conjugate vaccine by eliminating the complex and challenging bacteria-based production system. However, development of the synthetic Vi vaccines does face a significant challenge of potential

variation of plant PGA raw materials, especially in molecular weight, which in turn could lead to variation in AcPGA or the synthetic Vi antigen. To overcome this challenge and also produce a more effective T- dependent synthetic Vi polysaccharide, we have developed a simple and efficient process to generate low

molecular weight (LMW) AcPGA through controlled hydrolysis of AcPGA. The resulting LMW AcPGA has a low molecular weight of 30-60 kDa and a high degree of O-acetylation (DOAc) which exceeds its specification for Vi polysaccharide. We have further generated a LMW AcPGA conjugate with a novel nanoparticle carrier

protein (Dps, DNA-binding protein from starved cells) of Salmonella bacteria and showed that it is capable of generating high titers of anti-Vi polysaccharide antibodies in rabbits, thus demonstrating the feasibility of this LMW synthetic Vi conjugate vaccine. Based on these promising results, we propose to continue development

of this LMW synthetic Vi conjugate vaccine through two specific aims. Specific aim 1 will focus on generation and characterization of LMW AcPGA while Specific aim 2 will focus on generation, characterization, and immunogenicity evaluation of LMW AcPGA-Dps conjugates. The primary goals are to establish the optimal

processes and assays for production and characterization of LWM AcPGA and demonstrate the fully T- dependent induction of anti-Vi polysaccharide antibodies by the LWM AcPGA-Dps conjugates. Successful completion of the proposed studies will demonstrate production of the synthetic Vi antigen (LMW AcPGA) from plant PGA raw materials and establish the LMW synthetic Vi conjugate vaccine candidate

(LMW AcPGA-Dps). They will form the basis for further development toward cGMP manufacturing development and clinical studies. Successful development of this LMW synthetic Vi conjugate vaccine could potentially provide a drastically improved Vi conjugate vaccine which will not only be produced more efficiently

with a higher capacity but could also be more effective by being fully T-dependent with its LMW synthetic Vi polysaccharide.