Improving Vaccine Design For Viral Diseases Using Modified Antigens And Vectors

Two of the principal challenges facing vaccine design today are how to generate protective antibody responses against viruses that have evolved sophisticated strategies to evade the humoral immune system and how to more rapidly and effectively produce vaccines to address emerging epidemics. In this regard, we explored multiple strategies to improve vaccine design for HIV-1 and Zika virus. In one approach, we derived CD4-independent variants of HIV-1 envelope (Env) with the hypothesis that such Envs would expose conserved epitopes that may be targets of protective, non-neutralizing antibodies. We characterized the biological and structural properties of two CD4-independent Env clones and found that they exhibited significantly greater exposure of a relatively conserved, linear epitope in the second variable loop (V2) that had previously been associated with decreased risk of infection in a clinical HIV-1 vaccine trial. This epitope was significantly more immunogenic in mice and nonhuman primates and, intriguingly, was associated with more rapid development of antibody-dependent cell-mediated cytotoxicity. In another approach, we designed mutations in the cytoplasmic tail of HIV-1 Env that were predicted to increase its cell surface expression and thus its immunogenicity in a vaccinia prime-protein boost vaccine protocol. We found that the highest level of surface expression was mediated by Envs with truncated cytoplasmic tails, and this was associated with higher levels of binding and neutralizing antibodies after vaccinia primes and protein boosts, respectively. These two studies revealed that modifications to HIV-1 Env immunogens are able to influence both the quality and magnitude of desirable antibody responses. Finally, we used a newly developed vaccine platform based on nucleoside-modified mRNA to design a vaccine against Zika virus. This vaccine, encoding the surface prM and E proteins, was potently immunogenic and elicited high and sustained titers of neutralizing antibodies in mice and nonhuman primates following a single intradermal immunization. We observed rapid and durable protection from Zika virus infection in mice and a high level of protection in monkeys challenged five weeks after vaccination. This vaccine thus represents a promising candidate for clinical use in controlling the spread of Zika virus

Structure-Based Stabilization of HIV-1 gp120 Enhances Humoral Immune Responses to the Induced Co-Receptor Binding Site

The human immunodeficiency virus type 1 (HIV-1) exterior envelope glycoprotein, gp120, possesses conserved binding sites for interaction with the primary virus receptor, CD4, and also for the co-receptor, generally CCR5. Although gp120 is a major target for virus-specific neutralizing antibodies, the gp120 variable elements and its malleable nature contribute to evasion of effective host-neutralizing antibodies. To understand the conformational character and immunogenicity of the gp120 receptor binding sites as potential vaccine targets, we introduced structure-based modifications to stabilize gp120 core proteins (deleted of the gp120 major variable regions) into the conformation recognized by both receptors. Thermodynamic analysis of the re-engineered core with selected ligands revealed significant stabilization of the receptor-binding regions. Stabilization of the co-receptor-binding region was associated with a marked increase in on-rate of ligand binding to this site as determined by surface plasmon resonance. Rabbit immunization studies showed that the conformational stabilization of core proteins, along with increased ligand affinity, was associated with strikingly enhanced humoral immune responses against the co-receptor-binding site. These results demonstrate that structure-based approaches can be exploited to stabilize a conformational site in a large functional protein to enhance immunogenic responses specific for that region

Elicitation of broadly neutralizing HIV-1 antibodies by guiding the immune responses using primary and secondary immunogens

Abstract also published in AIDS Research and Human Retroviruses. November 2013, 29(11): A-44. doi:10.1089/aid.2013.1500Poster presentationpublished_or_final_versio