Japanese encephalitis virus (JEV) is a mosquito-borne pathogenic flavivirus responsible for acute viral encephalitis in humans. The cellular entry of JEV is poorly characterized in terms of molecular requirements and pathways. Here we present a systematic study of the internalization mechanism of JEV in fibroblasts and neuroblastoma cells. To verify the roles of distinct pathways of cell entry, we used fluorescently labeled virus particles, a combination of pharmacological inhibitors, RNA interference (RNAi), and dominant-negative (DN) mutants of regulatory proteins involved in endocytosis. Our study demonstrates that JEV infects fibroblasts in a clathrin-dependent manner, but it deploys a clathrin-independent mechanism to infect neuronal cells. The clathrin-independent pathway requires dynamin and plasma membrane cholesterol. Virus binding to neuronal cells leads to rapid actin rearrangements and an intact and dynamic actin cytoskeleton, and the small GTPase RhoA plays an important role in viral entry. Immunofluorescence analysis of viral colocalization with endocytic markers showed that JEV traffics through Rab5-positive early endosomes and that release of the viral nucleocapsid occurs at the level of the early and not the late endosomes.
Host factors provide critical support for every aspect of the virus life cycle. We recently identified the valosin-containing protein (VCP)/p97, an abundant cellular ATPase with diverse cellular functions, as a host factor important for Japanese encephalitis virus (JEV) replication. In cultured cells, using siRNA-mediated protein depletion and pharmacological inhibitors, we show that VCP is crucial for replication of three flaviviruses: JEV, Dengue, and West Nile viruses. An FDA-approved VCP inhibitor, CB-5083, extended survival of mice in the animal model of JEV infection. While VCP depletion did not inhibit JEV attachment on cells, it delayed capsid degradation, potentially through the entrapment of the endocytosed virus in clathrin-coated vesicles (CCVs). Early during infection, VCP-depleted cells showed an increased colocalization of JEV capsid with clathrin, and also higher viral RNA levels in purified CCVs. We show that VCP interacts with the JEV nonstructural protein NS5 and is an essential component of the virus replication complex. The depletion of the major VCP cofactor UFD-1 also significantly inhibited JEV replication. Mechanistically, thus, VCP affected two crucial steps of the JEV life cycle – nucleocapsid release and RNA replication. Our study establishes VCP as a common host factor with a broad antiviral potential against flaviviruses.
Importance
JEV is the leading cause of viral encephalitis epidemics in South-east Asia, affecting majorly children with high morbidity and mortality. Identification of host factors is thus essential for the rational design of anti-virals that are urgently need as therapeutics. Here we have identified the VCP protein as one such host-factor. This protein is highly abundant in cells and engages in diverse functions and cellular pathways by its ability to interact with different co-factors. Using siRNA mediated protein knockdown, we show that this protein is essential for release of the viral RNA into the cell so that it can initiate replication. The protein plays a second crucial role for the formation of the JEV replication complex. FDA-approved drugs targeting VCP show enhanced mouse survival in JE model of disease, suggesting that this could be a druggable target for flavivirus infections.
Hepatitis C virus (HCV) is a global pathogen and infects more than 185 million individuals worldwide. Although recent development of direct acting antivirals (DAA) has shown promise in HCV therapy, there is an urgent need for the development of more affordable treatment options. We initiated this study to identify novel inhibitors of HCV through screening of compounds from the National Cancer Institute (NCI) diversity dataset. Using cell-based assays, we identified NSC-320218 as a potent inhibitor against HCV with an EC50 of 2.5 μM and CC50 of 75 μM. The compound inhibited RNA dependent RNA polymerase (RdRp) activity of all six major HCV genotypes indicating a pan-genotypic effect. Limited structure-function analysis suggested that the entire molecule is necessary for the observed antiviral activity. However, the compound failed to inhibit HCV NS5B activity in vitro, suggesting that it may not be directly acting on the NS5B protein but could be interacting with a host protein. Importantly, the antiviral compound also inhibited dengue virus and hepatitis E virus replication in hepatocytes. Thus, our study has identified a broad-spectrum antiviral therapeutic agent against multiple viral infections.
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