Nanoparticle vaccine based on the envelope protein domain III of Japanese encephalitis virus elicits robust protective immune responses in mice

Self-Assembling protein nanoparticle platform for multivalent antigen delivery in vaccine development

Nanoparticle vaccines can efficiently and repeatedly display multivalent antigens, thereby improving the targeted delivery of antigens and inducing more durable immune responses, making them an important representative of novel vaccines. The global COVID-19 pandemic has accelerated the development of nanoparticle vaccines, offering a promising solution for the prevention and control of infectious diseases. Currently, the development of nanoparticle vaccines involves the use of various types of nanoparticles, including liposomes, polymers, inorganic materials, and emulsions. Protein nanoparticles candidate vaccines are attracting increasing attention because of their unique antigen presentation methods and self-assembly characteristics during their development, leading to a broad consensus on their promising future. Naturally self-assembling protein nanoparticles, such as ferritin, enhance antigen presentation, which aids in the activation of both humoral and cellular immune responses. This has led to significant advancements in the study of hepatitis B virus. Meanwhile, some synthetically engineered protein nanoparticles, such as mi3, and I53-50, can induce higher antibody titers through chemical conjugation with the SpyTag-SpyCatcher system, thereby providing better immunoprotection and showing promising prospects in the prevention of H1N1 and H3N2 influenza virus infections. This article reviews the unique advantages of protein nanoparticles as antigen delivery platforms, progress made in immunological design mechanisms, advances in the application of related adjuvants in preclinical and clinical trials, and the performance of commonly used computationally designed protein nanoparticles in preclinical trials, with a particular emphasis on the progress in the application of cationic nanoparticle vaccines. The aim is to provide future researchers with effective adjuvant strategies and high-quality selections for computationally designed protein nanoparticles, thereby promoting the clinical trial process of protein nanoparticles vaccines.

Molecular mechanisms of Japanese encephalitis virus infection and advances in vaccine research

Japanese encephalitis (JE) is a central nervous system disease caused by the Japanese encephalitis virus (JEV), resulting in high morbidity and mortality, especially in Asia. This review summarizes the current understanding of the JEV infection cycle, including virus attachment and entry, genome replication, viral protein translation, and virus particle assembly and release. The roles of host factors and viral proteins in these processes are discussed. Furthermore, the latest advancements in JE vaccine research are emphasized, including the development of attenuated vaccine SA14-14-2, inactivated mouse brain-derived vaccine, inactivated cell culture vaccine, and chimeric attenuated vaccine. The efficacy and safety of these candidate vaccines and ongoing efforts to enhance their immunogenicity are also reviewed. A comprehensive understanding of the molecular mechanisms of JEV infection and advancements in vaccine research is crucial for the development of effective strategies for JE control and prevention.

Advancements in nanoparticle-based vaccine development against Japanese encephalitis virus: a systematic review

Vaccination remains the sole effective strategy for combating Japanese encephalitis (JE). Both inactivated and live attenuated vaccines exhibit robust immunogenicity. However, the production of these conventional vaccine modalities necessitates extensive cultivation of the pathogen, incurring substantial costs and presenting significant biosafety risks. Moreover, the administration of live pathogens poses potential hazards for individuals or animals with compromised immune systems or other health vulnerabilities. Subsequently, ongoing research endeavors are focused on the development of next-generation JE vaccines utilizing nanoparticle (NP) platforms. This systematic review seeks to aggregate the research findings pertaining to NP-based vaccine development against JE. A thorough literature search was conducted across established English-language databases for research articles on JE NP vaccine development published between 2000 and 2023. A total of twenty-eight published studies were selected for detailed analysis in this review. Of these, 16 studies (57.14%) concentrated on virus-like particles (VLPs) employing various structural proteins. Other approaches, including sub-viral particles (SVPs), biopolymers, and both synthetic and inorganic NP platforms, were utilized to a lesser extent. The results of these investigations indicated that, despite variations in the usage of adjuvants, dosages, NP types, antigenic proteins, and animal models employed across different studies, the candidate NP vaccines developed were capable of eliciting enhanced humoral and cellular adaptive immune responses, providing effective protection (70-100%) for immunized mice against lethal challenges posed by virulent Japanese encephalitis virus (JEV). In conclusion, prospective next-generation JE vaccines for humans and animals may emerge from these candidate formulations following further evaluation in subsequent vaccine development phases.

Efficacy of genotype-matched vaccine against re-emerging genotype V Japanese encephalitis virus

Japanese encephalitis (JE), caused by the Japanese encephalitis virus (JEV), is a highly threatening disease with no specific treatment. Fortunately, the development of vaccines has enabled effective defense against JE. However, re-emerging genotype V (GV) JEV poses a challenge as current vaccines are genotype III (GIII)-based and provide suboptimal protection. Given the isolation of GV JEVs from Malaysia, China, and the Republic of Korea, there is a concern about the potential for a broader outbreak. Under the hypothesis that a GV-based vaccine is necessary for effective defense against GV JEV, we developed a pentameric recombinant antigen using cholera toxin B as a scaffold and mucosal adjuvant, which was conjugated with the E protein domain III of GV by genetic fusion. This GV-based vaccine antigen induced a more effective immune response in mice against GV JEV isolates compared to GIII-based antigen and efficiently protected animals from lethal challenges. Furthermore, a bivalent vaccine approach, inoculating simultaneously with GIII- and GV-based antigens, showed protective efficacy against both GIII and GV JEVs. This strategy presents a promising avenue for comprehensive protection in regions facing the threat of diverse JEV genotypes, including both prevalent GIII and GI as well as emerging GV strains.

Protection against the H1N1 influenza virus using self-assembled nanoparticles formed by lumazine synthase and bearing the M2e peptide

There is an urgent need for influenza vaccines that offer broad cross-protection. The highly conserved ectodomain of the influenza matrix protein 2 (M2e) is a promising candidate; however, its low immunogenicity can be addressed. In this study, we developed influenza vaccines using the Lumazine synthase (LS) platform. The primary objective of this study was to determine the protective potential of M2e proteins expressed on Lumazine synthase (LS) nanoparticles. M2e-LS proteins, produced through the E. coli system, spontaneously assemble into nanoparticles. The study investigated the efficacy of the M2e-LS nanoparticle vaccine in mice. Mice immunized with M2e-LS nanoparticles exhibited significantly higher levels of intracellular cytokines than those receiving soluble M2e proteins. The M2e-LS protein exhibited robust immunogenicity and provided 100% protection against cross-clade influenza.

Japanese encephalitis virus E protein domain III immunization mediates cross-protection against Zika virus in mice via antibodies and CD8+T cells

Zika virus (ZIKV) and Japanese encephalitis virus (JEV) are antigenically related flaviviruses that co-circulate in many countries/territories. The interaction between the two viruses needs to be determined. Recent findings by ourselves and other labs showed that JEV-elicited antibodies (Abs) and CD8+T cells exacerbate and protect against subsequent ZIKV infection, respectively. However, the impact of JEV envelope (E) protein domain III (EDIII)-induced immune responses on ZIKV infection is unclear. We show here that sera from JEV-EDIII-vaccinated mice cross-react with ZIKV-EDIII in vitro, and transfer of the same sera to mice significantly decreases death upon lethal ZIKV infection at a dose-dependent manner. Maternally acquired anti-JEV-EDIII Abs also significantly reduce the mortality of neonatal mice born to JEV-EDIII-immune mothers post ZIKV challenge. Similarly, transfer of ZIKV-EDIII-reactive IgG purified from JEV-vaccinated humans increases the survival of ZIKV-infected mice. Notably, transfer of an extremely low volume of JEV-EDIII-immune sera or ZIKV-EDIII-reactive IgG does not mediate the Ab-mediated enhancement (ADE) of ZIKV infection. Similarly, transfer of JEV-EDIII-elicited CD8+T cells protects recipient mice against ZIKV challenge. These results demonstrate that JEV-EDIII-induced immune components including Abs and T cells have protective roles in ZIKV infection, suggesting EDIII is a promising immunogen for developing effective and safety JEV vaccine.