A novel lamprey antibody sequence to multimerize and increase the immunogenicity of recombinant viral and bacterial vaccine antigens.

Hemagglutinin, the major surface protein of influenza viruses, was recombinantly expressed in eukaryotic cells as a monomer instead of its native trimer, and was only immunogenic when administered with an adjuvant [Pion et al. 2014]. In order to multimerize this antigen to increase its immunogenicity, a cysteine-rich peptide sequence found at the extreme C-terminus of lamprey variable lymphocyte receptor (VLR)-B antibodies was fused to various recombinant hemagglutinin (rHA) proteins from A and B influenza virus strains. The rHA-Lamp fusion (rHA fused to the lamprey sequence) protein was expressed in Leishmania tarentolae and Chinese hamster ovary (CHO) cells and shown to produce several multimeric forms. The multimers produced were very stable and more immunogenic in mice than monomeric rHA. The lamprey VLR-B sequence was also used to multimerize the neuraminidase (NA) of influenza viruses expressed in CHO cells. For some viral strains, the NA was expressed as a tetramer like the native viral NA form. In addition, the lamprey VLR-B sequence was fused with two surface antigens of Shigella flexneri 2a, the invasion plasmid antigen D and a double mutated soluble form of the membrane expression of the invasion plasmid antigen H namely MxiH. The fusion proteins were expressed in Escherichia coli to produce the respective multimer protein forms. The resulting proteins had similar multimeric forms as rHA-Lamp protein and were more immunogenic in mice than the monomer forms. In conclusion, the VLR-B sequence can be used to increase the immunogenicity of recombinant viral and bacterial antigens, thus negating the need for adjuvants.

Influenza A and B virus-like particles produced in mammalian cells are highly immunogenic and induce functional antibodies.

Influenza virus-like particles (VLPs) represent an attractive alternative to traditional influenza vaccine formulations. Influenza VLPs mimic the natural virus while lacking the genetic material, are easily recognized by the immune system, and are considered safe. The use of a mammalian cell platform offers many advantages for VLP production, such as flexibility and the same glycosylation patterns as a human virus. In this study, the influenza VLPs containing hemagglutinin (HA), neuraminidase (NA) and matrix M1 proteins were expressed in CHO-K1, Vero or 293 T cell lines using transient transfection. After production in 3L bioreactor and purification, extensive characterization was performed on two batches of VLPs produced in 293 T, the best cell line for VLP expression; one batch expressed the HA and NA genes from A/Hong Kong/4801/2014 (H3N2) strain and the other, HA and NA genes from B/Phuket/3073/2013. Characterizations provided evidence that mammalian VLPs closely emulate the exterior of authentic virus particles in terms of both antigen presentation and biological properties. The two VLPs produced contained more NA proteins on their surface with a HA:NA ratio around 1:1 than influenza viruses which present a HA:NA ratio of around 4:1. Immunogenicity studies in BALB/c mice demonstrated that the VLPs, administered intra-muscularly, were highly immunogenic at low doses, with the induction of functional antibodies against HA and NA. Immunogenicity was also shown in a human in vitro model (MIMIC® system). In conclusion, we believe that influenza vaccines made of VLPs produced in mammalian cell lines, constitute a potential alternative to the classical influenza vaccines.

Non-conventional expression systems for the production of vaccine proteins and immunotherapeutic molecules.

The increasing demand for recombinant vaccine antigens or immunotherapeutic molecules calls into question the universality of current protein expression systems. Vaccine production can require relatively low amounts of expressed materials, but represents an extremely diverse category consisting of different target antigens with marked structural differences. In contrast, monoclonal antibodies, by definition share key molecular characteristics and require a production system capable of very large outputs, which drives the quest for highly efficient and cost-effective systems. In discussing expression systems, the primary assumption is that a universal production platform for vaccines and immunotherapeutics will unlikely exist. This review provides an overview of the evolution of traditional expression systems, including mammalian cells, yeast and E.coli, but also alternative systems such as other bacteria than E. coli, transgenic animals, insect cells, plants and microalgae, Tetrahymena thermophila, Leishmania tarentolae, filamentous fungi, cell free systems, and the incorporation of non-natural amino acids.

Antibiotic-free selection in E. coli: new considerations for optimal design and improved production.

BACKGROUND: The increasing regulatory requirements to which biological agents are subjected will have a great impact in the field of industrial protein expression and production. There is an expectation that in a near future, there may be "zero tolerance" towards antibiotic-based selection and production systems. Besides the antibiotic itself, the antibiotic resistance gene is an important consideration. The complete absence of antibiotic-resistance gene being the only way to ensure that there is no propagation in the environment or transfer of resistance to pathogenic strains. RESULTS: In a first step, we have designed a series of vectors, containing a stabilization element allowing a complete elimination of antibiotics during fermentation. Vectors were further improved in order to include alternative selection means such as the well known poison/antidote stabilization system. Eventually we propose an elegant positive pressure of selection ensuring the elimination of the antibiotic-resistance gene through homologous recombination. In addition, we have shown that the presence of an antibiotic resistance gene can indirectly reduce the amount of expressed protein, since even in absence of selection pressure the gene would be transcribed and account for an additional stress for the host during the fermentation process. CONCLUSIONS: We propose a general strategy combining plasmid stabilization and antibiotic-free selection. The proposed host/vector system, completely devoid of antibiotic resistance gene at the end of construction, has the additional advantage of improving recombinant protein expression and/or plasmid recovery.