Lipid A mimetics BECC438 and BECC470 potentiate durable and balanced immune responses using an ovalbumin murine vaccine model.

Abstract

Abstract The need for effective infectious disease vaccines has become an inescapable topic over the past year. Continued development of next-generation vaccines that provide robust protective immunity is imperative. Such vaccines will likely include an adjuvant that avoids excessive adverse reactions and allows for dose and antigen sparing. Bacterial lipid A mimetics BECC438 and BECC470 have recently emerged as lead adjuvant candidates across several experimental models of infectious disease including Yersinia pestis (plague), human papilloma virus (HPV), and influenza-A (flu). To further define BECC438 and BECC470 as immuno-adjuvants, even without antigen from an infectious pathogen, studies presented here use ovalbumin (Ova) as a model antigen in a murine prime-boost vaccine model. Higher magnitude and more balanced production of antibody isotypes IgG1 and IgG2 are observed when BECC adjuvants are compared to classic adjuvants alum and PHAD. This optimal antibody response is durable and maintained for at least 12 weeks post-vaccination. Initial experiments use C57BL6 mice and are expanded to include BALBc and CD-1 (outbred) mice. Observed immune metrics maintained similar trends across male and females, and genetic backgrounds tested. Biacore immunogenicity analysis of C57BL6 serum found an increased half-life of Ova-specific antibodies in BECC438-adjuvanted animals potentially indicative of a higher antigen binding affinity. Toxicity studies conducted in New Zealand White rabbits report that BECC438 was well tolerated with no significant reactogenicity after 50μg and 100μg intra-muscular adjuvant injection. These studies provide continued evidence supporting development of BECC adjuvants in vaccines for human use.