Inhibition of hepatitis C virus gene expression by adenoviral vectors encoding antisense RNA in vitro and in vivo.

BACKGROUND & AIMS: In this study, adenoviral vectors encoding an antisense RNA complementary to the 5' non-coding region (5'NCR) of the HCV-genome were generated to inhibit HCV-RNA gene expression in cell culture and in vivo. METHODS: First and second-generation (with E4-deletion) adenoviruses encoding the HCV5'NCR in antisense direction (Ad-NCRas and Ad-E4del-NCRas) were generated. Inhibition of HCV gene expression was analyzed in hepatoma cells stably transfected with the HCV5'NCR cDNA fused to the firefly luciferase gene (NCRluc), as well as in the HCV subgenomic replicon (genotypes 1b and 2a) and the fully infectious HCV JFH-1 cell culture systems. For in vivo experiments, an adenovirus encoding the NCRluc-gene was injected intravenously to achieve a NCR-dependent luciferase-expression in the liver of C3H/HeNcrl-mice. RESULTS: Forty eight hours after transduction with GFP-encoding adenoviruses, >85% of HepG2-, CCL13-and Huh7-cells expressed GFP. Surprisingly, GFP-expression of E4-deleted adenoviruses was considerably reduced at the same MOI. Using antisense first-generation adenoviruses (Ad-NCRas), a significant inhibition of the 5'NCR-dependent HCV-gene expression (54±19% in HepG2-cells and 66.2±15% in Huh7-cells) was achieved 48h after transduction. In Huh7-cells containing the HCV subgenomic replicons and in infectious HCV JFH-1 cell cultures, adenovirus-mediated transcription of antisense 5'NCR significantly blocked HCV-replication (40% and 76%, respectively). Corresponding to low transgene expression, the maximal inhibition reached with Ad-delE4-NCRas was 30%. In vivo, antisense adenoviral vectors also showed a significant inhibition (40%) of NCR-dependent luciferase expression compared to control adenoviruses (p<0.05). CONCLUSIONS: The data indicate that HCV gene expression can be inhibited by antisense RNA encoding adenoviruses in the tested settings.

Hammerhead ribozymes with cleavage site specificity for NUH and NCH display significant anti-hepatitis C viral effect in vitro and in recombinant HepG2 and CCL13 cells.

BACKGROUND/AIMS: Four different ribozymes (Rz) targeting the hepatitis C virus (HCV) 5'-non-coding region (NCR) at nucleotide (nt) positions GUA 165 (Rz1), GUC 270 (Rz2), GUA 330 (Rz3) and GCA 348 (Rz1293) were compared for in vitro cleavage using a 455 nt HCV RNA substrate. The GUA 330 (Rz3) and GCA 348 (Rz1293) ribozymes, both targeting the HCV loop IV region, were found to be the most efficient, and were further analyzed in an in vitro translation system. METHODS: For this purpose RNA transcribed from a construct encoding a HCV-5'-NCR-luciferase fusion protein was used. Cleavage-inactive (Rz1426), mismatch (Rz1293m) or unrelated ribozymes (Rz1437) were synthesized as controls for Rz-1293. HCV specificity was analysed by competition experiments using sense and mismatch oligodeoxynucleotides HCVrzCI and HCVrzMM, respectively. RESULTS: A chemically modified nuclease-resistant variant of the GCA 348 cleaving ribozyme was selected for cell culture experiments using recombinant HepG2 or CCL13 cell lines stably transfected with a HCV-5'-NCR-luciferase target construct. CONCLUSIONS: This ribozyme (Rz1293) showed an inhibitory activity of translation of more than 70% thus verifying that the GCA 348 cleavage site in the HCV loop IV is an accessible target site in vivo and may be suitable for the development of novel optimized hammerhead structures.

DNA vaccination with AFP-encoding plasmid DNA prevents growth of subcutaneous AFP-expressing tumors and does not interfere with liver regeneration in mice.

The oncofetal alpha-fetoprotein (AFP) is reexpressed in the majority of hepatocellular carcinomas and may be used as a target molecule for an immunotherapy or prophylaxis against this tumor. We investigated the potential of DNA vaccination with AFP-expressing plasmid DNA to induce an immune response against AFP-expressing tumor cells in DBA/2 mice. 62.5% of mice vaccinated with AFP-expressing plasmid DNA, rejected subcutaneous syngeneic AFP-expressing P815 tumors, whereas only 16.7% of mice vaccinated with control plasmid rejected these tumor cells (P=.03). Mean survival of mice after challenge with subcutaneous AFP-expressing tumor cells was prolonged for 8 days in mice vaccinated with AFP-expressing DNA (35 days) compared to mice vaccinated with control plasmid (27 days). To rule out possible autoimmune reactions against regenerating liver, which also reexpresses AFP, we evaluated the influence of AFP-specific DNA vaccination on liver regeneration in DBA/2 mice. Histologic quantification of proliferating hepatocytes and of the amount of necrotic liver tissue in carbon tetrachloride-damaged liver did not reveal statistically significant differences in mice vaccinated with AFP-expressing plasmid compared to control mice. These data suggest that AFP-specific DNA vaccination represents a useful tool to inhibit growth of AFP-expressing tumors in mice that does not affect liver regeneration.