Daniel Samain

A new family of carriers (biovectors) enhances the immunogenicity of rabies antigens

Biovectors (BV) are a new family of protein carriers. They are nanoparticles of polymerized polysaccharides substituted with phosphate residues and surrounded by covalently bound lipid molecules (palmitic acid). The effect of BV was tested on the immunogenicity of rabies antigens. Biovectors enhanced the production of antibody induced by both rabies glycoprotein and ribonucleoprotein. Moreover, they enhanced the protective activity of an experimental rabies vaccine composed of inactivated and purified virus. The isotype profile of antibody produced in vivo was not modified when BV were mixed with rabies antigens. To clarify the mechanism of the adjuvant/ immunostimulation effect of BV, two types of approach were used: (1) analysis of the antibody response when antigen and BV were injected separately; (2) determination of the nature of cells involved in the proliferation in vitro of murine splenocytes in the presence of BV. The enhancing effect of BV on antibody production was highest when mixed with antigens. In vitro BV induced the proliferation of B cells. These findings suggest that BV have immunostimulating properties in addition to their probable depot and/or antigen-presentation effect which explain in part their adjuvant activity.

SYNTHESIS AND CHARACTERIZATION OF SUPRAMOLECULAR BIOVECTOR (SMBV) SPECIFICALLY DESIGNED FOR THE ENTRAPMENT OF IONIC MOLECULES

Supramolecular biovectors (SMBV) are nanoparticular drug carriers composed of an internal crosslinked solid core externally grafted with fatty acids and surrounded with a phospholipid layer. We show in this paper that the internal core can be derivatized with anionic ligands such as phosphate in order to allow the efficient entrapment of cationic molecules through a process akin to ion exchange. Synthesis of SMBV involved first a cross linking and derivatization step of polysaccharides followed by a homogenization, a drying and a regioselective acylation step. Acylated polysaccharide cores are thus obtained which can be loaded with drugs and wrapped with a phospholipid layer. The SMBVs obtained are characterized through their size, 20 nm, and their ability to filter through 0.22 microns pore size membrane. Gel permeation chromatography experiments performed with various phospholipid/acylated cores ratios indicate that SMBVs form entities distinct from liposomes and that the optimum phospholipid/acylated cores ratio for this specific type of SMBVs is close to 100%. The supramolecular structure of SMBVs and in particular the spatial proximity between acylated cores and phospholipids is demonstrated through resonance energy transfer experiments. The drug loading capability of SMBVs is illustrated by the preparation of gentamicin and doxorubicin loaded SMBV. The therapeutic potential of SMBVs is then discussed notably in the light of a possible biomimetism with low density lipoproteins (LDL).

Stabilization and enhancement of interleukin-2 in vitro bioactivity by new carriers: supramolecular biovectors

Human recombinant interleukin-2 can be associated and released from supramolecular biovectors (SMBVs), consisting of particles made of polymerized polysaccharides. The particles are substituted with phosphate residues and contain bound lipid molecules (palmitic acid) buried near their surfaces. The association of IL-2 with SMBVs modifies its in vitro bioactivity. SMBVs prolong the growth of IL-2-dependent cells, enhance IL-2 proliferative activity and restore the activity of impaired IL-2. These properties mainly depend on the presence of lipids linked to the SMBV and on both the degree of acylation and the SMBV: IL-2 ratio. SMBVs are therefore good candidates for the stabilization and enhancement of the biological activity of IL-2.