Approaches to quality control, preclinical and clinical studies of live recombinant viral vector vaccines

At present, there are not much data on the clinical use of live recombinant viral vector vaccines. Characteristics of new vaccines should be factored into requirements/recommendations for quality control, preclinical and clinical studies of vaccines in order to enable further risk/benefit assessment. The aim of this study was to analyse current approaches to quality control, preclinical and clinical studies of live recombinant viral vector vaccines. The paper provides an overview of the licensed live viral vector vaccines and those at various stages of clinical trials. The authors analysed Russian, European, American, and Japanese guidelines related to quality issues, preclinical and clinical studies of live viral vector vaccines. The analysis demonstrated that the regulatory requirements for live recombinant viral vector vaccines include assessment of a detailed rationale for vaccine development, including information on the choice of the vector, the origin of the heterologous antigen gene(s), elements related to the transgene(s) expression, as well as assessment of the genetic and phenotypic stability of the recombinant virus, the risk of reversion to virulence or recombination with wild type strains, the potential for virus genome integration into the host cell chromosome, the pre-existing immunity to the vector, the intensity of the immune response elicited by the vector, and the reusability of the vector. The choice and number of applicable toxicological and pharmacological models will depend on these aspects. The results of the analysis of approaches to quality control, preclinical and clinical studies of live recombinant viral vector vaccines may be used in the development of Russian regulatory guidelines harmonised with the international norms and regulations.

Novel Simple Conjugation Chemistries for Decoration of GMMA with Heterologous Antigens

Outer Membrane Vesicles (OMV) constitute a promising platform for the development of efficient vaccines. OMV can be decorated with heterologous antigens (proteins or polysaccharides), becoming attractive novel carriers for the development of multicomponent vaccines. Chemical conjugation represents a tool for linking antigens, also from phylogenetically distant pathogens, to OMV. Here we develop two simple and widely applicable conjugation chemistries targeting proteins or lipopolysaccharides on the surface of Generalized Modules for Membrane Antigens (GMMA), OMV spontaneously released from Gram-negative bacteria mutated to increase vesicle yield and reduce potential reactogenicity. A Design of Experiment approach was used to identify optimal conditions for GMMA activation before conjugation, resulting in consistent processes and ensuring conjugation efficiency. Conjugates produced by both chemistries induced strong humoral response against the heterologous antigen and GMMA. Additionally, the use of the two orthogonal chemistries allowed to control the linkage of two different antigens on the same GMMA particle. This work supports the further advancement of this novel platform with great potential for the design of effective vaccines.

A recombinant commensal bacteria elicits heterologous antigen-specific immune responses during pharyngeal carriage

The human nasopharynx contains a stable microbial ecosystem of commensal and potentially pathogenic bacteria, which can elicit protective primary and secondary immune responses. Experimental intranasal infection of human adults with the commensal Neisseria lactamica produced safe, sustained pharyngeal colonization. This has potential utility as a vehicle for sustained release of antigen to the human mucosa, but commensals in general are thought to be immunologically tolerated. Here, we show that engineered N. lactamica, chromosomally transformed to express a heterologous vaccine antigen, safely induces systemic, antigen-specific immune responses during carriage in humans. When the N. lactamica expressing the meningococcal antigen Neisseria Adhesin A (NadA) was inoculated intranasally into human volunteers, all colonized participants carried the bacteria asymptomatically for at least 28 days, with most (86%) still carrying the bacteria at 90 days. Compared to an otherwise isogenic but phenotypically wild-type strain, colonization with NadA-expressing N. lactamica generated NadA-specific immunoglobulin G (IgG)– and IgA-secreting plasma cells within 14 days of colonization and NadA-specific IgG memory B cells within 28 days of colonization. NadA-specific IgG memory B cells were detected in peripheral blood of colonized participants for at least 90 days. Over the same period, there was seroconversion against NadA and generation of serum bactericidal antibody activity against a NadA-expressing meningococcus. The controlled infection was safe, and there was no transmission to adult bedroom sharers during the 90-day period. Genetically modified N. lactamica could therefore be used to generate beneficial immune responses to heterologous antigens during sustained pharyngeal carriage.

The C-Terminal Domain of Nefmut Is Dispensable for the CD8+ T Cell Immunogenicity of In Vivo Engineered Extracellular Vesicles

Intramuscular injection of DNA vectors expressing the extracellular vesicle (EV)-anchoring protein Nefmut fused at its C-terminus to viral and tumor antigens elicit a potent, effective, and anti-tolerogenic CD8+ T cell immunity against the heterologous antigen. The immune response is induced through the production of EVs incorporating Nefmut-derivatives released by muscle cells. In the perspective of a possible translation into the clinic of the Nefmut-based vaccine platform, we aimed at increasing its safety profile by identifying the minimal part of Nefmut retaining the EV-anchoring protein property. We found that a C-terminal deletion of 29-amino acids did not affect the ability of Nefmut to associate with EVs. The EV-anchoring function was also preserved when antigens from both HPV16 (i.e., E6 and E7) and SARS-CoV-2 (i.e., S1 and S2) were fused to its C-terminus. Most important, the Nefmut C-terminal deletion did not affect levels, quality, and diffusion at distal sites of the antigen-specific CD8+ T immunity. We concluded that the C-terminal Nefmut truncation does not influence stability, EV-anchoring, and CD8+ T cell immunogenicity of the fused antigen. Hence, the C-terminal deleted Nefmut may represent a safer alternative to the full-length isoform for vaccines in humans.

CD8+ T cell immunogenicity induced by endogenous EVs engineered by antigens fused to a truncated Nefmut EV-anchoring protein

Intramuscular injection of DNA vectors expressing the extracellular vesicle (EV)-anchoring protein Nefmut fused at its C-terminus to viral and tumor antigens elicits a potent, effective, and anti-tolerogenic CD8+ T cell immunity against the heterologous antigen. The immune response is induced through the production of EVs incorporating Nefmut-derivatives released by muscle cells. In the perspective to a possible translation into the clinic of the Nefmut-based vaccine platform, we aimed at increasing its safety profile by identifying the minimal part of Nefmut retaining the EV-anchoring protein property. We found that a C-terminal deletion of 29-amino acids did not affect the ability of Nefmut to associate with EVs. Furthermore, the EV-anchoring function was preserved when antigens from both HPV16 (i.e., E6 and E7) and SARS-CoV-2 (i.e., S1 and S2) were fused to its C-terminus. By analyzing the immune responses induced after intramuscular injection of DNA vectors expressing fusion products based on the four viral antigens, we found that the Nefmut C-terminal deletion did not impact on the levels of antigen –specific CD8+ T lymphocytes as evaluated by IFN-γ EliSpot analysis and intracellular cytokine staining. In addition, immune responses at distal sites remained unaffected, as indicated by the similar percentages of SARS-CoV-2 S1- and S2-specific CD8+ T cells detected in spleens and lung airways of mice injected with DNA vectors expressing the viral antigens fused with either Nefmut or NefmutPL.We concluded that the C-terminal Nefmut truncation does not affect stability, EV-anchoring, and CD8+ T cell immunogenicity of the fused antigen. Hence, NefmutPL represents a safer alternative to full-length Nefmut for the design of CD8+ T cell vaccines for humans.

A self-assembled protein nanoparticle serving as a one-shot vaccine carrier

In this paper, we are exploring the role of an amphipathic helical peptide in mediating the self-assembly of a fusion protein into a protein nanoparticle and the application of the nanoparticle as a one-shot vaccine carrier. Out of several candidates, an amphipathic helical peptide derived from M2 protein of type A influenza virus is found to stimulate high antigenicity when fused to a fluorescent protein genetically. This fusion protein was found to form protein nanoparticle spontaneously when expressed and purified protein stimulates long-lasting antibody responses in single immunization. Through modeling peptide structure and nanoparticle assembly, we have improved this vaccine carrier in complex stability. The revised vaccine carrier is able to stimulate constant antibody titer to a heterologous antigen for at least six months in single immunization. The immune response against a heterologous antigen can be boosted further by additional immunization in spite of high immune responses to carrier protein.

Pharyngeal carriage of inoculated recombinant commensal bacteria generates antigen-specific immunological memory

ABSTRACTThe human nasopharynx is colonized by commensal bacteria and pathobionts, which comprise a complex microbial ecosystem capable of generating primary and secondary immune responses. Experimental intranasal infection of human adults with the commensal Neisseria lactamica results in safe, sustained colonization. Herein is described a novel technology to chromosomally transform N. lactamica with heterologous antigen, for the purpose of safe delivery to the mucosal surface and the generation of an antigen-specific immune response. N. lactamica was transformed to express the meningococcal vaccine antigen Neisseria Adhesin A (NadA) and was inoculated intranasally into humans at a dose of 105 colony-forming units. NadA-expressing N. lactamica colonized these individuals and was carried asymptomatically for 3 months. Colonization with NadA-expressing N. lactamica generated NadA-specific IgG-secreting plasma cells within 14 days of colonization and both NadA-specific IgG and NadA-specific IgG memory B cells within 28 days of colonization. NadA-specific IgG memory B cells circulate in the bloodstream of colonized participants for at least 90 days. Genetically transformed N. lactamica has the potential to be a safe bacterial vehicle to generate beneficial immune responses to a wide range of heterologous antigens during sustained pharyngeal carriage.