Immunogenicity of a silica nanoparticle-based SARS-CoV-2 vaccine in mice

Safe and effective vaccines have been regarded early on as critical in combating the COVID-19 pandemic. Among the deployed vaccine platforms, subunit vaccines have a particularly good safety profile but may suffer from a lower immunogenicity compared to mRNA based or viral vector vaccines. In fact, this phenomenon has also been observed for SARS-CoV-2 subunit vaccines comprising the receptor-binding domain (RBD) of the spike (S) protein. Therefore, RBD-based vaccines have to rely on additional measures to enhance the immune response. It is well accepted that displaying antigens on nanoparticles can improve the quantity and quality of vaccine-mediated both humoral and cell-mediated immune responses. Based on this, we hypothesized that SARS-CoV-2 RBD as immunogen would benefit from being presented to the immune system via silica nanoparticles (SiNP). Herein we describe the preparation, in vitro characterization, antigenicity and in vivo immunogenicity of SiNPs decorated with properly oriented RBD in mice. We found our RBD-SiNP conjugates show narrow, homogeneous particle distribution with optimal size of about 100 nm for efficient transport to and into the lymph node. The colloidal stability and binding of the antigen was stable for at least 4 months at storage- and in vivo-temperatures. The antigenicity of the RBD was maintained upon binding to the SiNP surface, and the receptor-binding motif was readily accessible due to the spatial orientation of the RBD. The particles were efficiently taken up in vitro by antigen-presenting cells. In a mouse immunization study using an mRNA vaccine and spike protein as benchmarks, we found that the SiNP formulation was able to elicit a stronger RBD-specific humoral response compared to the soluble protein. For the adjuvanted RBD-SiNP we found strong S-specific multifunctional CD4+ T cell responses, a balanced T helper response, improved auto- and heterologous virus neutralization capacity, and increased serum avidity, suggesting increased affinity maturation. In summary, our results provide further evidence for the possibility of optimizing the cellular and humoral immune response through antigen presentation on SiNP

Multivalent display of engineered HIV-1 envelope trimers on silica nanoparticles for targeting and in vitro activation of germline VRC01 B cells

Selective targeting of germline B cells with specifically designed germline-targeting HIV-1 envelope immunogens (GT-Env) is considered a feasible vaccination strategy to elicit broadly neutralizing antibodies (bnAbs). BnAbs are extremely valuable because they neutralize genetically distant viral strains at the same time. To overcome its inherently low affinity to germline B cells, the aim of the study was to present GT-Env via different immobilization strategies densely arrayed on the surface of nanoparticles. We engineered a prefusion-stabilized GT-Env trimer with affinity to VRC01 germline B cells using a bioinformatics-supported design approach. Distinct glycan modifications and amino acid substitutions yielded a GT-Env trimer which bound to the receptor with a KD of 11.5 µM. Silica nanoparticles with 200 nm diameter (SiNPs) were used for the multivalent display of the novel GT-Env with a 15 nm mean centre-to-centre spacing either by site-specific, covalent conjugation or at random, non-specific adsorption. Oriented, covalent GT-Env conjugation revealed better binding of structure dependent bnAbs as compared to non-specifically adsorbed GT-Env. In addition, GT-Env covalently attached activated a B cell line expressing the germline VRC01 receptor at an EC50 value in the nanomolar range (4 nM), while soluble GT-Env required 1,000-fold higher concentrations to induce signalling. The significantly lower GT-Env concentration was likely required due to avidity effects, which were in the picomolar range. Thus, low affinity antigens may particularly benefit from a particulate and multivalent delivery. In future, SiNPs are ideal to be modified in a modular design with various GT-Env variants that target different stages of germline and bnAb precursor B cells

Lack of antibody affinity maturation due to poor Toll-like receptor stimulation leads to enhanced respiratory syncytial virus disease

Respiratory syncytial virus (RSV) is a leading cause of hospitalization in infants. A formalin-inactivated RSV vaccine was used to immunize children and elicited nonprotective, pathogenic antibody. Immunized infants experienced increased morbidity after subsequent RSV exposure. No vaccine has been licensed since that time. A widely accepted hypothesis attributed the vaccine failure to formalin disruption of protective antigens. Here we show that the lack of protection was not due to alterations caused by formalin but instead to low antibody avidity for protective epitopes. Lack of antibody affinity maturation followed poor Toll-like receptor (TLR) stimulation. This study explains why the inactivated RSV vaccine did not protect the children and consequently led to severe disease, hampering vaccine development for 42 years. It also suggests that inactivated RSV vaccines may be rendered safe and effective by inclusion of TLR agonists in their formulation, and it identifies affinity maturation as a key factor for the safe immunization of infants.Fil: Delgado, Maria Florencia. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación para la Investigación en Infectología Infantil; ArgentinaFil: Coviello, Silvina Andrea. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación para la Investigación en Infectología Infantil; ArgentinaFil: Monsalvo, Ana Clara. Fundación para la Investigación en Infectología Infantil; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Melendi, Guillermina Amanda. Fundación para la Investigación en Infectología Infantil; Argentina. University Johns Hopkins; Estados UnidosFil: Hernandez, Johanna Zea. Fundación para la Investigación en Infectología Infantil; Argentina. University Johns Hopkins; Estados UnidosFil: Batalle, Juan Pio. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación para la Investigación en Infectología Infantil; ArgentinaFil: Diaz, Leandro. Fundación para la Investigación en Infectología Infantil; ArgentinaFil: Trento, Alfonsina. Universidad Carlos III de Madrid. Instituto de Salud; EspañaFil: Chang, Herng-Yu. University Johns Hopkins; Estados UnidosFil: Mitzner, Wayne. University Johns Hopkins; Estados UnidosFil: Ravetch, Jeffrey. The Rockefeller University; Estados UnidosFil: Melero, José A.. Universidad Carlos III de Madrid. Instituto de Salud; EspañaFil: Irusta, Pablo M.. University Of Georgetown; Estados Unidos. Fundación para la Investigación en Infectología Infantil; ArgentinaFil: Polack, Fernando Pedro. Fundación para la Investigación en Infectología Infantil; Argentina. University Johns Hopkins; Estados Unido