Holger Zimmermann

In Vitro and In Vivo Activities of the Novel Anticytomegalovirus Compound AIC246

ABSTRACT Human cytomegalovirus (HCMV) remains a serious threat for immunocompromised individuals, including transplant recipients and newborns. To date, all drugs licensed for the treatment of HCMV infection and disease target the viral DNA polymerase. Although these drugs are effective, several drawbacks are associated with their use, including toxicity and emergence of drug resistance. Hence, new and improved antivirals with novel molecular targets are urgently needed. Here we report on the antiviral properties of AIC246, a representative of a novel class of low-molecular-weight compounds that is currently undergoing clinical phase II studies. The anti-HCMV activity of AIC246 was evaluated in vitro and in vivo using various cell culture assays and an engineered mouse xenograft model. In addition, antiviral properties of the drug were characterized in comparison to the current gold standard ganciclovir. We demonstrate that AIC246 exhibits excellent in vitro inhibitory activity against HCMV laboratory strains and clinical isolates, retains activity against ganciclovir-resistant viruses, is well tolerated in different cell types (median selectivity index, 18,000), and exerts a potent in vivo efficacy in a mouse xenograft model. Moreover, we show that the antiviral block induced by AIC246 is reversible and the efficacy of the drug is not significantly affected by cell culture variations such as cell type or multiplicity of infection. Finally, initial mode-of-action analyses reveal that AIC246 targets a process in the viral replication cycle that occurs later than DNA synthesis. Thus, AIC246 acts via a mode of action that differs from that of polymerase inhibitors like ganciclovir.

RNA-dependent RNA polymerases from different hepatitis C virus genotypes reveal distinct biochemical properties and drug susceptibilities

The RNA-dependent RNA polymerase of the hepatitis C virus (HCV) is the key enzyme for viral replication, recognized as one of the promising targets for antiviral intervention. Several of the known non-nucleoside HCV polymerase inhibitors (NNIs) identified by screening approaches show limitations in the coverage of all six major HCV genotypes (GTs). Genotypic profiling therefore has to be implemented early in the screening cascade to discover new broadly active NNIs. This implies knowledge of the specific individual biochemical properties of polymerases from all GTs which is to date limited to GT 1 only. This work gives a comprehensive overview of the biochemical properties of HCV polymerases derived from all major GTs 1-6. Biochemical analysis of polymerases from 38 individual sequences revealed that the optima for monovalent cations, pH and temperature were similar between the GTs, whereas significant differences concerning concentration of the preferred cofactor Mg(2+) were identified. Implementing the optimal requirements for the polymerases from each individual GT led to significant improvements in their enzymatic activities. However, the specific activity was distributed unequally across the GTs and could be ranked in the following descending order: 1b, 6a>2a, 3a, 4a, 5a>1a. Furthermore, the optimized assay conditions for genotypic profiling were confirmed by testing the inhibitory activity of 4 known prototype NNIs addressing the NNI binding sites 1 to 4.