Progress in the Use of Antisense Oligonucleotides for Vaccine Improvement.

: Antisense oligonucleotides (ASOs) are synthetically prepared short single-stranded deoxynucleotide sequences that have been validated as therapeutic agents and as a valuable tool in molecular driving biology. ASOs can block the expression of specific target genes via complementary hybridization to mRNA. Due to their high specificity and well-known mechanism of action, there has been a growing interest in using them for improving vaccine efficacy. Several studies have shown that ASOs can improve the efficacy of vaccines either by inducing antigen modification such as enhanced expression of immunogenic molecules or by targeting certain components of the host immune system to achieve the desired immune response. However, despite their extended use, some problems such as insufficient stability and low cellular delivery have not been sufficiently resolved to achieve effective and safe ASO-based vaccines. In this review, we analyze the molecular bases and the research that has been conducted to demonstrate the potential use of ASOs in vaccines.

Improvement of in vivo stability of phosphodiester oligonucleotide using anionic liposomes in mice.

Antisense phosphodiester oligonucleotides (ODN) are unstable in biological fluids due to nuclease-mediated degradation and therefore cannot be used in most antisense therapeutic applications. We describe here an in vitro and in vivo stabilization of a 15 mer phosphodiester sequence using anionic liposomes. Two formulations have been studied: DOPC/OA/CHOL and DOPE/OA/CHOL (pH-sensitive liposomes). Our in vitro findings reveal the same stabilization effect in mouse plasma for both anionic liposomes. In vivo investigation showed a great protective effect for both formulations after intravenous administration to mice. By contrast with in vitro results, a higher protection of ODN was observed with DOPC/OA/CHOL liposomes compared to the DOPE/OA/CHOL formulation. The latter was degraded in blood (75% of the injected dose at 5 min) probably due to interactions with blood components, and the remaining (25% at 5 min) was distributed mostly to the liver and spleen. DOPC liposomes were remarkably stable in blood and were distributed more slowly to all studied organs (liver, spleen, kidneys and lungs). Intact ODN was still observed in some organs (liver, spleen, lungs), but not in blood, 24 hours after DOPC liposome administration. These results suggest that this antisense strategy using carrier systems may be applicable to the treatment of diseases involving the reticuloendothelial system.