Long-term nucleoside analog therapy for hepatitis B virus (HBV)-related disease frequently results in the selection of mutant HBV strains that are resistant to therapy. Molecular studies of such drug-resistant variants are clearly warranted but have been difficult to do because of the lack of convenient and reliable in vitro culture systems for HBV. We previously developed a novel in vitro system for studying HBV replication that relies on the use of recombinant baculoviruses to deliver greater than unit length copies of the HBV genome to HepG2 cells. High levels of HBV replication can be achieved in this system, which has recently been used to assess the effects of lamivudine on HBV replication and covalently closed circular DNA accumulation. The further development of this novel system and its application to determine the cross-resistance profiles of drug-resistant HBV strains are described here. For these studies, novel recombinant HBV baculoviruses which encoded the L526M, M550I, and L526M M550V drug resistance mutations were generated and used to examine the effects of these substitutions on viral sensitivity to lamivudine, penciclovir (the active form of famciclovir), and adefovir, three compounds of clinical importance. The following observations were made:(i) the L526M mutation confers resistance to penciclovir and partial resistance to lamivudine,(ii) the YMDD mutations M550I and L526M M550V confer high levels of resistance to lamivudine and penciclovir, and (iii) adefovir is active against each of these mutants. These findings are supported by the limited amount of clinical data currently available and confirm the utility of the HBV-baculovirus system as an in vitro tool for the molecular characterization of clinically significant HBV strains.

Long-term nucleoside analog therapy for hepatitis B virus (HBV)-related disease frequently results in the selection of mutant HBV strains that are resistant to therapy. Molecular studies of such drug-resistant variants are clearly warranted but have been difficult to do because of the lack of convenient and reliable in vitro culture systems for HBV. We previously developed a novel in vitro system for studying HBV replication that relies on the use of recombinant baculoviruses to deliver greater than unit length copies of the HBV genome to HepG2 cells. High levels of HBV replication can be achieved in this system, which has recently been used to assess the effects of lamivudine on HBV replication and covalently closed circular DNA accumulation. The further development of this novel system and its application to determine the cross-resistance profiles of drug-resistant HBV strains are described here. For these studies, novel recombinant HBV baculoviruses which encoded the L526M, M550I, and L526M M550V drug resistance mutations were generated and used to examine the effects of these substitutions on viral sensitivity to lamivudine, penciclovir (the active form of famciclovir), and adefovir, three compounds of clinical importance. The following observations were made:(i) the L526M mutation confers resistance to penciclovir and partial resistance to lamivudine,(ii) the YMDD mutations M550I and L526M M550V confer high levels of resistance to lamivudine and penciclovir, and (iii) adefovir is active against each of these mutants. These findings are supported by the limited amount of clinical data currently available and confirm the utility of the HBV-baculovirus system as an in vitro tool for the molecular characterization of clinically significant HBV strains.

The treatment of woodchuck hepatitis virus infections with 1-(2'-deoxy-2'-fluoro-beta-D-arabinofuranosyl)-5-iodocytosine (FIAC) and 1-(2'-deoxy-2'-fluoro-beta-D-arabinofuranosyl)-5-methyluracil (FMAU), given intraperitoneally, caused complete and permanent decrease of serum virus endogenous DNA polymerase and viral DNA in all treated woodchucks but was associated with severe toxicity. By contrast 1-(2'-deoxy-2'-fluoro-beta-D-arabinofuranosyl)-5-ethyluracil (FEAU) induced a sustained, although less dramatic, decrease of viral replication without apparent toxic effect. FEAU was also effective when given orally. However, in both cases this inhibitory effect was transient.

Attempts at antiviral therapy of patients with active liver disease as a consequence of chronic hepatitis B virus infection have been moderately successful. The molecular and cellular basis for a successful outcome in these patients is not understood and the same therapies do not appear to benefit carriers that still have fairly normal livers and only a moderate hepatitis as a result of the immune response to the infection. Most carriers fall into this latter classification, at least during the early years of infection, and a therapy that could be successfully applied before extensive liver damage had occurred would presumably reduce the risk of subsequent liver damage and the progression to primary hepatocellular carcinoma. Traditionally, it has been assumed that the primary reason that individuals become chronically infected is that the cytotoxic T-cell response and/or antibody-dependent killing of infected hepatocytes is insufficient to clear the infection. Less attention has been focused on the role of the antibody response in the generation of virus-neutralizing antibodies as the possible major deficiency predisposing some individuals to become carriers. However, carriers normally are antigenemic for HBsAg and virus, and carriers with only antibodies to these structures in their circulation are virtually unknown. In addition, it is usually assumed that the hepatocyte, the major target of infection, does not spontaneously turn over and that, in the absence of an immune response to the infected cell, hepatocellular viability is unaffected.(ABSTRACT TRUNCATED AT 250 WORDS)

The view that chemical or physical oncogenesis and tumor therapy resistance represent different parts of common cellular alterations gained considerable attractiveness, because it explains the inherent unreponsiveness of many tumors. Viruses are potent oncogenes and are causally linked to approximately one-fifth of all human malignancies. Whether viral oncogenesis exerts comparable effects was less clear. Recent progress in experimental research provided ample evidence that viruses affect response of tumor cells toward anti-cancer drugs and irradiation. Resistance to cytostatic drugs and radiation develops by alterations at the drug-target sites (i.e., DNA or specific target proteins), upstream (i.e., detoxification mechanisms), or downstream of them (i.e., programmed cell death). Viruses interfere with specific cellular genes at these three levels. Viral proteins induce the expression and expression of drug resistance genes, that is, MDR1, DHFR, or CAD. Viral interactions with the tumor suppressor genes (p53, pRB) abrogate cell cycle arrests and disturb DNA repair of drug- and radiation-induced DNA lesions. The readiness to commit cellular suicide (apoptosis) is also affected by viral genes. The connection between viral oncogenesis and the response of tumor cells to treatment adds a new dimension to tumor biology and may have important consequences for oncological treatment modalities in the future.

The woodchuck was selected to study the efficacy of liver-targeted antiviral drugs on hepadnavirus replication. Nineteen woodchucks chronically infected with woodchuck hepatitis virus were treated with adenine arabinoside monophosphate or acyclovir monophosphate, either free or conjugated with the liver-targeting molecule lactosaminated human serum albumin. Circulating woodchuck hepatitis virus DNA levels remained unchanged in untreated animals and in those receiving the carrier lactosaminated human serum albumin alone; in contrast, they were consistently lower after 5 days of treatment with the antiviral drugs. Free and conjugated adenine arabinoside monophosphate were active at doses of 10 and 0.75 mg/kg, respectively, and free and coupled ACVMP were active at doses of 20 and 2.6 mg/kg, respectively. These results indicate that the dosages of adenine arabinoside monophosphate and acyclovir monophosphate required to inhibit hepadnavirus growth can be sharply reduced by coupling the drugs to lactosaminated human serum albumin.