Hepatitis C virus (HCV) chronically infects 170 million individuals, causing severe liver disease. Although antiviral chemotherapy exists, the current regimen is ineffective in 50% of cases due to high levels of innate virus resistance. New, virus-specific therapies are forthcoming although their development has been slow and they are few in number, driving the search for new drug targets. The HCV p7 protein forms an ion channel in vitro and is critical for the secretion of infectious virus. p7 displays sensitivity to several classes of compounds, making it an attractive drug target. We recently demonstrated that p7 compound sensitivity varies according to viral genotype, yet little is known of the residues within p7 responsible for channel activity or drug interactions. Here, we have employed a liposome-based assay for p7 channel function to investigate the genetic basis for compound sensitivity. We demonstrate using chimeric p7 proteins that neither the two transmembrane helices nor the p7 basic loop individually determines compound sensitivity. Using point mutation analysis, we identify amino acids important for channel function and demonstrate that null mutants exert a dominant negative effect over wild-type protein. We show that, of the three hydrophilic regions within the amino-terminal trans-membrane helix, only the conserved histidine at position 17 is important for genotype 1b p7 channel activity. Mutations predicted to play a structural role affect both channel function and oligomerization kinetics. Lastly, we identify a region at the p7 carboxy terminus which may act as a specific sensitivity determinant for the drug amantadine.Hepatitis C virus (HCV) chronically infects 170 million individuals and is a major cause of severe liver disease such as cirrhosis and hepatocellular carcinoma. Acute HCV infection is asymptomatic which, combined with the lack of an available vaccine, means that the majority of carriers are unaware of their positive status. Thus, clinical intervention takes place upon the presentation of symptoms when liver damage is already extensive and when the virus is well established. Current therapy comprises a combination of pegylated alpha interferon (IFN-␣) with ribavirin (Rib), which is effective in only 50% of cases and is both expensive and poorly tolerated by patients. This relatively low success rate is due to the highly prevalent, IFN-resistant genotype 1 viruses; other genotypes generally respond well to treatment (27). As IFN-Rib acts primarily via stimulation of the immune system, improving current therapy relies on the development of new, virus-specific drugs. A small number of polymerase and protease inhibitors are at late stages of development, but progress has been hampered by the inability until recently to culture HCV in vitro (21, 40, 45). The highly variable nature of HCV, however, means that new drugs will most likely have to be used in combination, making expansion of available drug targets and the development of new inhibitors a major research focus.HCV is the prot...
The hepatitis C virus (HCV) p7 ion channel plays a critical role during infectious virus production and represents an important new therapeutic target. Its activity is blocked by structurally distinct classes of small molecules, with sensitivity varying between isolate p7 sequences. Although this is indicative of specific protein-drug interactions, a lack of highresolution structural information has precluded the identification of inhibitor binding sites, and their modes of action remain undefined. Furthermore, a lack of clinical efficacy for existing p7 inhibitors has cast doubt over their specific antiviral effects. We identified specific resistance mutations that define the mode of action for two classes of p7 inhibitor: adamantanes and alkylated imino sugars (IS). Adamantane resistance was mediated by an L20F mutation, which has been documented in clinical trials. Molecular modeling revealed that L20 resided within a membrane-exposed binding pocket, where drug binding prevented low pH-mediated channel opening. The peripheral binding pocket was further validated by a panel of adamantane derivatives as well as a bespoke molecule designed to bind the region with high affinity. By contrast, an F25A polymorphism found in genotype 3a HCV conferred IS resistance and confirmed that these compounds intercalate between p7 protomers, preventing channel oligomerization. Neither resistance mutation significantly reduced viral fitness in culture, consistent with a low genetic barrier to resistance occurring in vivo. Furthermore, no cross-resistance was observed for the mutant phenotypes, and the two inhibitor classes showed additive effects against wild-type HCV. Conclusion: These observations support the notion that p7 inhibitor combinations could be a useful addition to future HCV-specific therapies. (HEPATOLOGY 2011;54:79-90) H epatitis C virus (HCV) infects over 3% of the population, causing severe liver disease. Current therapy comprising pegylated interferon (IFN) and ribavirin (Rib) is inadequate, which, combined with high cost and poor patient compliance, has driven the demand for new virus-specific drugs.1 Future standard of care will replace IFN/Rib with combinations of specific inhibitors, such as seen for human immunodeficiency virus (HIV) therapy. However, extensive HCV variability raises concerns over the ability of relatively few compounds to suppress resistance. Thus, great effort focuses on expanding the repertoire of HCV drug targets, expedited by the availability of the Japanese fulminant hepatitis clone 1 (JFH-1) infectious isolate.
Human respiratory syncytial virus (HRSV) is the leading cause of lower respiratory tract disease in infants. The HRSV small hydrophobic (SH) protein plays an important role in HRSV pathogenesis, although its mode of action is unclear. Analysis of the ability of SH protein to induce membrane permeability and form homo-oligomers suggests it acts as a viroporin. For the first time, we directly observed functional SH protein using electron microscopy, which revealed SH forms multimeric ring-like objects with a prominent central stained region. Based on current and existing functional data, we propose this region represents the channel that mediates membrane permeability.Structured summaryMINT-7890792, MINT-7890805: SH (uniprotkb:P04852) and SH (uniprotkb:P04852) bind (MI:0407) by chromatography technology (MI:0091)MINT-7890784, MINT-7890776: SH (uniprotkb:P04852) and SH (uniprotkb:P04852) bind (MI:0407) by electron microscopy (MI:0040)
The product of the human cytomegalovirus (HCMV) gene UL144, expressed at early times postinfection, is located in the UL/b region of the viral genome and is related to members of the tumor necrosis factor receptor superfamily, but it does not bind tumor necrosis factor superfamily ligands. However, UL144 does activate NF-B, resulting in NF-B-mediated activation of the cellular chemokine CCL22. Consistent with this finding, isolates of HCMV lacking the UL/b region show no such activation of CCL22. Recently, it has been suggested that activation of NF-B is repressed by the product of the viral gene IE86: IE86 appears to block NF-B binding to DNA but not nuclear translocation of NF-B. Intriguingly, IE86 is detectable throughout an infection with the virus, so how UL144 is able to activate NF-B in the presence of continued IE86 expression is unclear. Here we show that although IE86 does repress the UL144-mediated activation of a synthetic NF-B promoter, it is unable to block UL144-mediated activation of the CCL22 promoter, and this lack of responsiveness to IE86 appears to be regulated by binding of the CREB transcription factor.
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