Comparative inhibitory potential of differently modified antisense oligodeoxynucleotides on hepatitis C virus translation.

BACKGROUND: A completely modified phosphorothioate antisense oligodeoxynucleotide (cS-ODN 4) directed against nucleotides 326-348 of the hepatitis C virus (HCV) 5' non-coding region (NCR) efficiently inhibits viral gene expression. As cS-ODN exerts undesired side-effects in vivo, we synthesized partially modified ODN 4 that contained only six modified nucleotides which are located at the ODN termini or are scattered along the molecule. The tested modifications were polar phosphorothioates (S) and non-polar methyl- (M) or benzylphosphonates (B). RESULTS: In an in vitro translation system, specific inhibition of HCV gene expression by M-ODN 4 or B-ODN 4 was observed if terminally modified ODN were used; the maximal inhibition was 92.3% +/- 1.9% and 87.1% +/- 3.7%, respectively, at 10 microgram mol L-1 concentration. S-ODN 4 specifically suppressed viral translation irrespective of the location of the modifications, resulting in a maximal inhibition of 86.3% +/- 3.3%. For all terminally modified ODNs the therapeutic index was high, with tB-ODN 4 the second best at 3.8. Inhibition correlated with efficient RNase H-associated cleavage of target RNA. In transient co-transfection experiments of HepG2 cells with a reporter gene construct and the ODN, terminally modified B-ODN 4 was the most effective and specific inhibitor. At a concentration of 5 microgram mol L-1 the suppression of HCV translation was 96.3% +/- 0.7%. CONCLUSION: These data demonstrate that terminally modified B-ODN 4 is a potent inhibitor of HCV gene expression in vitro and in HepG2 cell culture and may be valuable for future antiviral treatment.

Characterization of a human cell clone expressing cytochrome P450 for safe use in human somatic cell therapy.

We have previously demonstrated the therapeutic effect and efficacy of implantation of cells genetically modified to express cytochrome P450 2B1 in a nude mouse tumor model. The cells are encapsulated in polymerized cellulose sulphate and injected into preformed tumors. Upon administration of ifosfamide, the P450 enzyme converts the ifosfamide into antitumorigenic toxic metabolites at the site required, thereby significantly reducing tumor burden. Feline kidney epithelial cells were chosen for these studies, because they are easy to culture and can readily be transfected. However, these cells are not suitable for eventual use in human patients, since they are known to express endogenous retroviruses that are able to infect mammalian cells. They thus represent a safety risk. Here we describe the establishment of a human cell line that has been genetically modified to express the same cytochrome P450 construct and their characterization. The usefulness of mitomycin C treatment, both to protect the cells from the toxic metabolites that they produce and to incapacitate these cells from replicating, should they escape from the capsules, has also been investigated.

Injection of encapsulated cells producing an ifosfamide-activating cytochrome P450 for targeted chemotherapy to pancreatic tumors.

The prognosis of pancreatic cancer is poor, and current medical treatment is mostly ineffective. The aim of this study was to design a new treatment modality in an animal model system. We describe here a novel treatment strategy employing a mouse model system for pancreatic carcinoma. Embryonal kidney epithelial cells were genetically modified to express the cytochrome P450 subenzyme 2B1 under the control of a cytomegalovirus (CMV) immediate early promoter. This CYP2B1 gene converts ifosfamide to its active cytotoxic compounds, phosphoramide mustard, which alkylates DNA, and acrolein, which alkylates proteins. The cells were then encapsulated in a cellulose sulphate formulation and implanted into preestablished tumors derived from a human pancreatic tumor cell line. Intraperitoneal administration of low-dose ifosfamide to tumor bearing mice that received the encapsulated cells results in partial or even complete tumor ablation. Such an in situ chemotherapy strategy utilizing genetically modified cells in an immunoprotected environment may prove useful for solid tumor therapy in man.

Intratumoral injection of encapsulated cells producing an oxazaphosphorine activating cytochrome P450 for targeted chemotherapy.

The prognosis of pancreatic adenocarcinoma is poor and current treatment is for the most part ineffective. We describe here a novel treatment strategy using a mouse model system for pancreatic cancer. Human embryonic epithelial cells have been genetically modified to express the cytochrome P450 2B1 enzyme under the control of a CMV immediate-early promoter. This CYP2B1 gene converts oxazaphosphorines (ifosfamide or cyclophosphamide) to their active cytotoxic compounds, phosphoramide mustard, which alkylates DNA, and acrolein, which alkylates proteins. A number of assays were performed to demonstrate the CYP2B1 gene function as well as toxic effects on neighbouring cells (bystander effect). The cells were then encapsulated in a cellulose sulphate formulation shown to be well tolerated in the pancreas of immunocompetent mice, and injected 1 cm away from pre-established tumours derived from a human pancreatic tumour cell line (PaCa-44). Intraperitoneal administration of low-dose ifosfamide to tumour bearing mice that received the encapsulated cells results in partial or even complete tumour ablation. Such an in situ chemotherapy strategy utilizing genetically modified cells in an immunoprotected environment may prove useful for solid tumour therapy in man.

Core specific antisense phosphorothioate oligodeoxynucleotides as potent and specific inhibitors of hepatitis C viral translation.

Antisense phosphorothioate oligodeoxynucleotides (S-ODN) complementary to sequence stretches in the 5' non coding region (NCR) of the hepatitis C virus (HCV) have recently been shown to effectively inhibit viral gene expression. In order to further delineate the optimum target region in the highly conserved 5' end of the viral RNA, S-ODN complementary to HCV core coding sequences were analysed in the present study. In a rabbit reticulocyte lysate (RRL) in vitro translation assay S-ODN 5, complementary to the HCV-RNA nucleotides 340-353, and S-ODN-6, complementary to nucleotides 348-365, resulted in an inhibition of viral translation of 90.4 +/- 1.3% and 93.7 +/- 5.1%, respectively at a concentration of 4.14 microM. S-ODN 7, complementary to nucleotides 371-388, was relatively inefficient and showed a maximal inhibition of 42.4 +/- 12.2%. It has been suggested that in living cells an inhibition by S-ODN is mainly mediated by the action of RNAse H. In RRL the RNAseH content is very low; therefore, to simulate the situation in living cells inhibition experiments in RRL enriched with RNAse H were performed. Under these conditions S-ODN 5, 6 and 7 inhibited viral translation by 45.6 +/- 6.3%, 80.3 +/- 2.8% and 70.9 +/- 5.7% at concentrations as low as 0.2 microM. At this concentration no inhibition was observed in the standard RRL assay. In cell culture S-ODN 7 was by far the most efficient inhibitor of viral translation, resulting in a specific inhibition of 89.4 +/- 3.6% at a concentration of 0.3 microM. Taken together with the results of our previous study, nucleotides 326-348 comprising the 3' end of the NCR and nucleotides 371-388, located entirely in the core coding region of the HCV RNA, are effective targets for S-ODN mediated inhibition of viral translation.

Specific inhibition of hepatitis C viral gene expression by antisense phosphorothioate oligodeoxynucleotides.

The inhibitory effect of antisense phosphorothioate oligodeoxynucleotides (S-ODN) on hepatitis C viral gene expression and analyzed in an in vitro test system and in cell culture. S-ODN were directed against different stem loop structures in the 5'noncoding region (NCR) of the hepatitis C virus, (HCV) RNA and against a nucleotide stretch, including the start codon of the polyprotein precursor. The inhibitory effect of these S-ODN was quantified employing a viral RNA consisting of the first 407 nucleotides of a HCV type 1b genome fused to the coding sequence of the firefly luciferase gene. For in vitro assays this RNA was generated by in vitro transcription and used as a template in a rabbit reticulocyte lysate in vitro translation system. The production of active luciferase in the absence or presence of S-ODN was monitored using an enzymatic assay. The best results were obtained with S-ODN 4 directed against nucleotides 326 to 348, comprising the start AUG of the polyprotein coding sequence. With this oligonucleotide, a specific and dose-dependent effect was observed with a maximal inhibition of 96 +/- 1% at a S-ODN concentration of 4.14 mumol/L. For cell culture experiments, the hepatoblastoma cell line HepG2 was transfected with a plasmid expressing the HCV-luciferase fusion RNA. In this assay system S-ODN 2, complementary to nucleotides 264 to 282 of the HCV RNA, and S-ODN 4 were most efficient and reduced the viral translation by 96 +/- 0.4% and 94 +/- 0.7%, respectively, at a concentration of 0.3 mumol/L. The inhibition was specific (1) because the expression of the HCV-luciferase fusion RNA was not significantly impaired by the control S-ODN and (2) because the expression of an unrelated messenger RNA was not or only slightly downregulated. These data suggest that HCV gene expression can be inhibited effectively by antisense S-ODN. Therefore, this approach represents a promising perspective for the treatment of hepatitis C.