HCV-796 selectively inhibits hepatitis C virus (HCV) NS5B RNA-dependent RNA polymerase. In hepatoma cells containing a genotype 1b HCV replicon, HCV-796 reduced HCV RNA levels by 3 to 4 log 10 HCV copies/g total RNA (the concentration of the compound that inhibited 50% of the HCV RNA level was 9 nM). Cells bearing replicon variants with reduced susceptibility to HCV-796 were generated in the presence of HCV-796, followed by G418 selection. Sequence analysis of the NS5B gene derived from the replicon variants revealed several amino acid changes within 5 Å of the drug-binding pocket. Specifically, mutations were observed at Leu314, Cys316, Ile363, Ser365, and Met414 of NS5B, which directly interact with HCV-796. The impacts of the amino acid substitutions on viral fitness and drug susceptibility were examined in recombinant replicons and NS5B enzymes with the single-amino-acid mutations. The replicon variants were 10-to 1,000-fold less efficient in forming colonies in cells than the wild-type replicon; the S365L variant failed to establish a stable cell line. Other variants (L314F, I363V, and M414V) had four-to ninefold-lower steady-state HCV RNA levels. Reduced binding affinity with HCV-796 was demonstrated in an enzyme harboring the C316Y mutation. The effects of these resistance mutations were structurally rationalized using X-ray crystallography data. While different levels of resistance to HCV-796 were observed in the replicon and enzyme variants, these variants retained their susceptibilities to pegylated interferon, ribavirin, and other HCV-specific inhibitors. The combined virological, biochemical, biophysical, and structural approaches revealed the mechanism of resistance in the variants selected by the potent polymerase inhibitor HCV-796.Hepatitis C virus (HCV) is an enveloped, positive-sense, single-stranded RNA virus of approximately 9.6 kb that possesses an RNA-dependent RNA polymerase (RdRp), NS5B. Like that in many RNA viruses, this RNA replicase lacks a proofreading mechanism. The mutation rate of the HCV RdRp is estimated to be 10
In our search for novel inhibitors of herpes simplex virus type 1 (HSV-1), a new class of thiourea inhibitors was discovered. N-{4-[3-(5-Chloro-2,4-dimethoxyphenyl)-thioureido]-phenyl}-acetamide and its 2-fluoro-benzamide derivative inhibited HSV-1 replication. HSV-2, human cytomegalovirus, and varicella-zoster virus were inhibited to a lesser extent. The compounds acted late in the replication cycle by impairing both the cleavage of concatameric viral DNA into progeny genome length and the packaging of the DNA into capsids, indicative of a defect in the encapsidation process. To uncover the molecular target of the inhibition, resistant HSV-1 isolates were generated, and the mutation responsible for the resistance was mapped using marker transfer techniques. Each of three independent isolates had point mutations in the UL6 gene which resulted in independent single-amino-acid changes. One mutation was located in the N terminus of the protein (E121D), while two were located close together in the C terminus (A618V and Q621R). Each of these point mutations was sufficient to confer drug resistance when introduced into wild-type virus. The UL6 gene is one of the seven HSV-1 genes known to play a role in DNA packaging. This novel class of inhibitors has provided a new tool for dissection of HSV-1 encapsidation mechanisms and has uncovered a new viable target for the treatment of herpesviral diseases.The herpesvirus family has many members that are human pathogens and make a significant contribution to morbidity and mortality associated with viral diseases. Based on criteria such as host cell specificity, oncogenicity, length of replication cycle, and genome arrangement, the herpesviruses have been divided into alpha-, beta-, and gammaherpesviruses (31). The alphaherpesviruses herpes simplex virus (HSV) types 1 and 2 latently infect nerve cells. HSV-1 is primarily associated with herpes labialis, and HSV-2 is associated with herpes genitalis, but both types have been associated with both diseases (28,39,47). In immunocompetent adults, these diseases often recur due to reactivation of the virus from the latent state. HSV infections of immunocompromised patients such as transplant and AIDS patients are often chronic and fatal. Current therapy for HSV disease consists of nucleoside analogs such as acyclovir (ACV) and valacyclovir, a prodrug of ACV, and pencyclovir (PCV) and its prodrug, famcyclovir. ACV and PCV are selectively phosphorylated by the viral thymidine kinase in HSVinfected cells, followed by further phosphorylation to the triphosphate by cellular kinases. Triphosphorylated ACV and PCV are both inhibitors of the viral DNA polymerase, and ACV also acts as a chain terminator when incorporated into the nascent viral DNA chain (4, 13). Drug resistance can occur in chronic infections, where replication is ineffectively curtailed by the immune system. Recently increasing numbers of drugresistant HSV strains have been isolated from immunocompromised people. The mechanism of resistance of most ACV-resistant isolates is...
The human gene GLVR1 has been shown to render mouse cells sensitive to infection by gibbon ape leukemia virus. This indication that the GLVR1 protein acts as a virus receptor does not reveal the protein's normal physiological role. We now report that GLVR1 is homologous to pho-4', a phosphate permease of Neurospora crassa, at a level sufficiently high to predict that GLVR1 is also a transport protein, although the substrate transported remains unknown. To characterize the gene further, we have cloned cDNA for the mouse homolog of the gene, Glvr-1. The sequence of the murine protein differs from that of the human protein in 10% of residues, and it may be presumed that some of these differences are responsible for the inability of gibbon ape leukemia virus to infect mouse fibroblasts. Glvr-l RNA is most abundant in mouse brain and thymus, although it is present in all tissues examined. The pattern of RNA expression found in mouse tissues was also found in rat tissues, in which the RNA was expressed at high levels in all compartments of the brain except the caudate nucleus and was expressed most abundantly early in embryogenesis. Thus, high-level expression of Glvr-l appears to be restricted to specific tissues and may have developmental consequences.
Glvr1 encodes the human receptor for gibbon ape leukemia virus (GALV) and feline leukemia virus subgroup B (FeLV-B), while the related gene Glvr2 encodes the human receptor for amphotropic murine leukemia viruses (A-MLVs). The two proteins are 62% identical in their amino acid sequences and are predicted to have 10 transmembrane domains and five extracellular loops. A stretch of nine amino acids (region A) in the predicted fourth extracellular loop was previously shown to be critical for the function of Glvr1 as receptor for GALV and FeLV-B. Glvr1 and -2 show clusters of amino acid differences in several of their predicted extracellular loops, with the highest degree of divergence in region A. Chimeras were made between the two genes to further investigate the role of Glvr1 region A in defining receptor specificity for GALV and FeLV-B and to map which regions of Glvr2 control receptor specificity for A-MLVs. Region A fromGlvr1 was sufficient to confer receptor specificity for GALV upon Glvr2, with the same chimera failing to act as a receptor for FeLV-B.
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