Design and properties of hepatitis C virus antisense oligonucleotides for liver specific drug targeting

Inhibition of hepatitis C virus RNA translation by antisense bile acid conjugated phosphorothioate modified oligodeoxynucleotides (ODN)

BACKGROUND

The 5'-noncoding region (5'NCR) of the HCV-genome comprises an internal ribosome entry site essential for HCV-translation/replication. Phosphorothioate oligodeoxynucleotides (tS-ODN) complementary to this region can inhibit HCV-translation in vitro. In this study, bile acid conjugated tS-ODN were generated to increase cell-selective inhibition of 5'NCR-dependent HCV-translation.

METHODS

Different bile acid conjugated tS-ODN complementary to the HCV5'NCR were selected for their inhibitory potential in an in vitro transcription/translation assay. To analyze OATP (organic anion transporting polypeptides)-selective uptake of bile acid conjugated ODN, different hepatoma cells were stably transfected with the OATP1B1-transporter and primary human hepatocytes were used. An adenovirus encoding the HCV5'NCR fused to the luciferase gene (Ad-GFP-NCRluc) was generated to quantify 5'NCR-dependent HCV gene expression in OATP-overexpressing hepatoma cells and in vivo.

RESULTS

A 17mer phosphorothioate modified ODN (tS-ODN4_13) complementary to HCV5'NCR was able to inhibit 5'NCR-dependent HCV-translation in an in vitro transcription/translation test system by more than 90% and it was also effective in Huh7-cells containing the HCV subgenomic replicon. Conjugation to taurocholate (tS-ODN4_13T) significantly increased selective ODN uptake by primary human hepatocytes and by OATP1B1-expressing HepG2-cells compared to parental HepG2-cells. Correspondingly, tS-ODN4_13T significantly inhibited HCV gene expression in liver-derived OATP1B1-expressing HepG2- or CCL13-cells up to 70% compared to unconjugated tS-ODN and compared to mismatch taurocholate coupled tS-ODN. In vivo, tS-ODN4_13T showed also a trend to block 5'NCR-dependent HCV gene expression.

CONCLUSIONS

The tested taurocholate conjugated 17mer antisense ODN complementary to HCV5'NCV showed an increased and selective uptake by hepatocytes and liver-derived cells through OATP-mediated transport resulting in enhanced specific inhibition of HCV gene expression in vitro and in vivo. Thus, this novel approach may represent a promising strategy to improve antisense approaches with ODN in the control of hepatitis C infection.

Postsynthetic on column RNA labeling via Stille coupling

Stille Coupling is a versatile C-C bond forming reaction with high functional group tolerance under mild conditions. Our on column synthesis concept for RNA modification is based on the incorporation of iodo substituted nucleotide precursors to RNA during automated standard solid phase synthesis via TBDMS-, TC-, and ACE- protecting group strategies. Subsequently, the RNA, still bound on solid support, is ready for orthogonal postsynthetic functionalization via Stille cross-couplings utilizing the advantages of solid phase synthesis. Several monomer test reactions were employed with 2-iodo adenosine and 5-iodo uridine and organostannanes as coupling partners under different conditions, changing the catalyst/ligand system, temperature, and reaction time as well as conventional heating and microwave irradiation. Finally, Stille cross-couplings under optimized conditions were transferred to fully protected 5-mer and 12-mer RNA oligonucleotides on-column. Deprotection and cleavage from solid support resulted in site-specifically labeled oligonucleotides. Derivatizations via Stille cross-couplings were performed initially with vinyltributylstannane as well as later with 2-furanyl-, 2-thiophene-, and benzothiophene-2-tributylstannanes yielding fluorescently functionalized RNA.

Synthesis and properties of oligonucleotides containing a cholesterol thymidine monomer

Highly selective base-pair recognition makes DNA a suitable building block for orderly self-assembled structures. For some applications in nanotechnology DNA complexes need to be fixed onto surfaces. To fulfil this requirement on lipid membranes we have synthesised a thymidine monomer modified with a cholesterol moiety. Solution studies show that the melting temperature (Tm) of the duplex, with adjacent cholesterols on each strand, is much higher than that of the unmodified duplex.

Exploitation of bile acid transport systems in prodrug design

The enterohepatic circulation of bile acids is one of the most efficient recycling routes in the human body. It is a complex process involving numerous transport proteins, which serve to transport bile acids from the small intestine into portal circulation, from the portal circulation into the hepatocyte, from the hepatocyte into the bile, and from the gall bladder to the small intestine. The tremendous transport capacity and organ specificity of enterohepatic circulation combined with versatile derivatization possibilities, rigid steroidal backbone, enantiomeric purity, availability, and low cost have made bile acids attractive tools in designing pharmacological hybrid molecules and prodrugs with the view of improving intestinal absorption, increasing the metabolic stability of pharmaceuticals, specifically targeting drugs to organs involved in enterohepatic circulation, as well as sustaining therapeutically reasonable systemic concentrations of active agents. This article briefly describes bile acid transport proteins involved in enterohepatic circulation, summarizes the key factors affecting on the transport by these proteins, and reviews the use of bile acids and their derivatives in designing prodrugs capable of exploiting the bile acid transport system.

A novel class of DNA analogs bearing 5'-C-phosphonothymidine units: synthesis and physicochemical and biochemical properties

S(C) and R(C) diastereomers of 5'-C-(O,O-diethyl)-phosphonylthymidine ((R)T and (S)T) were used for the synthesis of the dimers T(R)T and T(S)T, respectively. These dimers were incorporated at selected sites in oligonucleotide constructs. Melting temperature (Tm) experiments demonstrated that relative to the unmodified oligodeoxyribonucleotide, the presence of the (R)T moiety reduced the thermal stability of the duplexes by approximately 5.0 degrees C per modification, whereas their (S)T counterparts only slightly destabilized the duplex structure (deltaTm < or = 1 degree C/modification). The stability of the triple-helical complexes containing one, two, or three modified thymidines is slightly higher than that of the parent complex. Nuclease resistance studies performed with snake venom phosphodiesterase, calf spleen phosphodiesterase, and 3'-exonuclease from human plasma showed that cleavage of the oligonucleotides at the site of the modification was completely suppressed regardless of the stereochemistry of the 5'-C-chiral center. The influence of the (R)T and (S)T modification in the recognition sequence of HindIII, EcoRI, and HpaI restriction endonucleases was also investigated. Although the catalytic activity of HindIII was not affected by the presence of the 5'-C-ethoxyphosphonyl modification, the activities of the two remaining restriction enzymes were partially suppressed depending on the site of modification or the stereochemistry of the modification or both ((R)T vs. (S)T).

Developments in hepatitis C therapy during 2000 – 2002

Hepatitis C virus (HCV) is a human hepatotropic virus with an estimated worldwide prevalence of 170 million cases, including approximately 4 million cases in the US. It is a major cause of liver disease and is the most common indication for liver transplantation in the US. The majority of infected individuals are eligible for therapy. Since it is difficult to predict who will have progressive disease, those with significant inflammation or fibrosis on histologic examination of liver biopsy are generally offered treatment. The following chapter is an overview of the patent literature during 2000-mid-2002, and discusses the potential of various treatment modalities for HCV.