mRNA LNP Vaccine(University of Pennsylvania)

At the end of 2019, SARS-CoV-2 emerged and rapidly spread, having a profound negative impact on human health and socioeconomic conditions. In response to this unprecedented global health crisis, significant advancements were made in the mRNA vaccine technology. In this study, we have compared the difference between two SARS-CoV-2 receptor-binding domain (RBD) mRNA-Lipid nanoparticle (LNP) vaccines prepared from two different ionizable cationic lipids: ALC-0315 and MC3. Characterization of RBD mRNA-LNPs showed that both MC3-LNP and ALC-0315-LNP are highly uniform and stable. Furthermore, we assessed the humoral immune response in mice after immunization; our findings indicated that both vaccine formulations effectively enhanced the formation and differentiation of germinal center (GC). Notably, the mice immunized with the ALC-0315-LNP vaccine elicited higher levels of IgG and its subclasses and significantly enhanced the activation of dendritic cells and T cells in draining lymph nodes (dLNs) compared to those immunized with the MC3-LNP vaccine. Further analysis of the T cell phenotype after splenic restimulation showed that mice injected with both LNP mRNA vaccines had significantly increased activation of the splenic T cells and Th1-type cytokine production. In addition, our finding showed that both LNP mRNA vaccines significantly increased the proportions of follicular helper T cells (Tfh) and long-lasting plasma cells in the dLNs of mice on day 14 postimmunization compared to control. In conclusion, both ALC-0315 and MC3 exhibited good stability and immunogenicity as mRNA-LNP recipes, but the ALC-0315-based mRNA-LNP vaccine showed higher efficacy in humoral and cellular immune responses compared to MC3.

The lack of success in clinical trials for HIV vaccines highlights the need to explore novel strategies for vaccine development. Research on highly exposed seronegative (HESN) HIV-resistant Kenyan female sex workers revealed naturally protective immunity is correlated with a focused immune response mediated by virus-specific CD8 T cells. Further studies indicated that the immune response is unconventionally focused on highly conserved sequences around HIV viral protease cleavage sites (VPCS). Thus, taking an unconventional approach to HIV vaccine development, we designed lipid nanoparticles loaded with mRNA that encodes multi-epitopes of VPCS (MEVPCS-mRNA LNP), a strategic design to boost antigen presentation by dendritic cells, promoting effective cellular immunity. Furthermore, we developed a novel cold-chain compatible mRNA LNP formulation, ensuring long-term stability and compatibility with cold-chain storage/transport, widening accessibility of mRNA LNP vaccine in low-income countries. The in-vivo mouse study demonstrated that the vaccinated group generated VPCS-specific CD8 memory T cells, both systemically and at mucosal sites of viral entry. The MEVPCS-mRNA LNP vaccine-induced CD8 T cell immunity closely resembled that of the HESN group and displayed a polyfunctional profile. Notably, it induced minimal to no activation of CD4 T cells. This proof-of-concept study underscores the potential of the MEVPCS-mRNA LNP vaccine in eliciting CD8 T cell memory specific to the highly conserved multiple VPCS, consequently having a broad coverage in human populations and limiting viral escape mutation. The MEVPCS-mRNA LNP vaccine holds promise as a candidate for an effective prophylactic HIV vaccine.