Jacquelyn Wright-Minogue

SCH 43478 and analogs: in vitro activity and in vivo efficacy of novel agents for herpesvirus type 2

SCH 43478 and analogs are a class of non-nucleoside antiviral agents that have potent and selective activity against herpes simplex virus type 2 (HSV-2). The IC50 for these compounds in plaque reduction analysis using Vero cells ranges from 0.8 to 2.0 microg/ml. All compounds have a LC50 > 100 microg/ml in cytotoxicity analysis. Mechanism of action studies suggest that these molecules have an effect on the transactivation of viral immediate early (alpha) gene expression. Time of addition studies indicate that antiviral activity of these analogs is limited to the initial 2-3 h after infection and is not due to inhibition of viral adsorption or penetration. Analysis of HSV protein expression demonstrates that SCH 49286 inhibits the accumulation of viral immediate early (alpha) gene products. SCH 43478 demonstrates statistically significant efficacy (P < 0.05) in the guinea pig genital model of HSV infection. Following subcutaneous administration in a therapeutic treatment regimen, SCH 43478 (90 mg/kg/day) is efficacious in reducing the number and severity of lesions and the neurological complications of acute HSV infection. Thus, SCH 43478 and analogs are anti-herpesvirus agents with a unique mechanism of action.

Antipicornavirus activity of SCH 47802 and analogs: in vitro and in vivo studies.

SCH 47802 and its derivatives are potent inhibitors of enteroviruses in vitro. The IC50 for SCH 47802 ranges from 0.03 to 10 micrograms/ml when tested against a spectrum of enteroviruses in plaque reduction assays. The compounds have in vitro therapeutic indices of at least 81 based on viral cytopathic effect (CPE) assays. The in vitro activity of SCH 47802 translates into in vivo activity in the murine model of poliovirus encephalitis. In an oral dosing regimen, SCH 47802 protects mice from mortality at 60 mg/kg per day. Consistent with the in vivo efficacy, pharmacokinetic analyses after oral dosing with SCH 47802 demonstrate serum levels of the compound above the in vitro IC50 for poliovirus for at least 4 h. SCH 47802 and its active analogs stabilize poliovirus to thermal inactivation indicating that the compounds bind to the virus capsid. Mechanistic studies with poliovirus indicate that SCH 47802 acts early in viral infection. This series of molecules represents potential candidates for the treatment of human enterovirus infections.

Conserved C-Terminal Threonine of Hepatitis C Virus NS3 Regulates Autoproteolysis and Prevents Product Inhibition

ABSTRACT Inspection of over 250 hepatitis C virus (HCV) genome sequences shows that a threonine is strictly conserved at the P1 position in the NS3-NS4A (NS3-4A) autoproteolysis junction, while a cysteine is maintained as the P1 residue in all of the putative trans cleavage sites (NS4A-4B, NS4B-5A, and NS5A-5B). To understand why T631 is conserved at the NS3-4A junction of HCV, a series of in vitro transcription-translation studies were carried out using wild-type and mutant (T631C) NS3-4A constructs bearing native, truncated, and mutant NS4A segments. The autocleavage of the wild-type junction was found to be dependent on the presence of the central cofactor domain of NS4A (residues 21 to 34). In contrast, all NS3-4A T631C mutant proteins underwent self-cleavage even in the absence of the cofactor. Subgenomic replicons derived from the Con1 strain of HCV and bearing the T631C mutation showed reduced levels of colony formation in transfection studies. Similarly, replicons derived from a second genotype 1b virus, HCV-N, demonstrated a comparable reduction in replication efficiency in transient-transfection assays. These data suggest that the threonine is conserved at position 631 because it serves two functions: (i) to slow processing at the NS3-4A cleavage site, ensuring proper intercalation of the NS4A cofactor with NS3 prior to polyprotein scission, and (ii) to prevent subsequent product inhibition by the NS3 C terminus.

Cross-genotypic interaction between hepatitis C virus NS3 protease domains and NS4A cofactors

BACKGROUND/AIMS Hepatitis C virus (HCV) nonstructural protein 3 (NS3) protease requires NS4A as a cofactor. This cofactor activity has been mapped to the central region of NS4A which interacts with the N-terminus of NS3 protease. To investigate whether this interaction is conserved among different genotypes of HCV cross-genotypic characterization were performed to delineate the importance of NS4A cofactor function in relation to the molecular evolution of HCV METHODS: Active NS3 protease domains of genotype 1-3 (representing five subtypes: la, 1b, 2a, 2b and 3a) were produced and purified from bacterial cells. NS4A cofactor-dependent in vitro trans cleavage assays were established using the in vitro translated recombinant protein substrates. These substrates contained the junction site of NS4A/NS4B, NS4B/NS5A or NS5A/NS5B. RESULTS Our data revealed that NS3 proteases cross-interacted with NS4A cofactors derived from different genotypes, although the genotype 2 cofactor was less efficient, which could be due to greater genetic variations in this region. Furthermore, the corresponding region in hepatitis G virus (HGV) NS4A was found to provide weak cofactor activity for HCV NS3 protease. Surprisingly, a synthetic substrate peptide from the NS4B/NS5A junction was also found to enhance HCV NS3 protease activity in a dose-dependent manner. CONCLUSION Our study suggests that the NS4A cofactor function is well conserved among HCV It is likely that other HCV-related viruses may have developed similar strategies to regulate their protease activity.

Effects of genotypic variations on hepatitis C virus nonstructural protein 5B structure and activity

Publisher Summary Hepatitis C virus (HCV) is the causative agent for most cases of non-A and non-B hepatitis. HCV, a member of the Flaviviridae family, is a positive-stranded RNA virus. Its life cycle consists of several interrelated processes that occur primarily in the cytoplasm of the host cells. Nonstructural protein 5B (NS5B) of HCV possesses an RNA-dependent RNA polymerase (RdRp) activity responsible for viral genome replication. It presents an excellent target for antiviral development. Recent studies revealed that removal of the C-terminal hydrophobic domain improved the solubility of NS5B to a level suitable for enzymatic characterization and structural determination. This hydrophobic C-terminal tail is highly conserved among all six genotypes of HCV, indicating an important functional and structural role, presumably as a membrane anchor for the assembly of a replication complex. Hydrophobic domains were also identified in related viruses, such as pestiviruses and GB viruses. Structure-based surface variability analysis identified highly conserved regions in the active site and predicted asymmetric distribution of important functionality and critical structural elements essential for replication.