Primary hepatocytes as targets for hepatitis C virus replication

Much of our current understanding of hepatitis C virus (HCV) replication has hailed from the use of a small number of cloned viral genomes and transformed hepatoma cell lines. Recent evidence suggests that lipoproteins play a key role in the HCV life cycle and virus particles derived from the sera of infected patients exist in association with host lipoproteins. This report will review the literature on HCV replication in primary hepatocytes and transformed cell lines, focusing largely on host factors defining particle entry

Saponin Inhibits Hepatitis C Virus Propagation by Up-regulating Suppressor of Cytokine Signaling 2

Saponins are a group of naturally occurring plant glycosides which possess a wide range of pharmacological properties, including anti-tumorigenic and antiviral activities. To investigate whether saponin has anti-hepatitis C virus (HCV) activity, we examined the effect of saponin on HCV replication. HCV replication was efficiently inhibited at a concentration of 10 µg/ml of saponin in cell culture grown HCV (HCVcc)-infected cells. Inhibitory effect of saponin on HCV replication was verified by quantitative real-time PCR, reporter assay, and immunoblot analysis. In addition, saponin potentiated IFN-α-induced anti-HCV activity. Moreover, saponin exerted antiviral activity even in IFN-α resistant mutant HCVcc-infected cells. To investigate how cellular genes were regulated by saponin, we performed microarray analysis using HCVcc-infected cells. We demonstrated that suppressor of cytokine signaling 2 (SOCS2) protein level was distinctively increased by saponin, which in turn resulted in inhibition of HCV replication. We further showed that silencing of SOCS2 resurrected HCV replication and overexpression of SOCS2 suppressed HCV replication. These data imply that saponin inhibits HCV replication via SOCS2 signaling pathway. These findings suggest that saponin may be a potent therapeutic agent for HCV patients

The Tat protein of human immunodeficiency virus-1 enhances hepatitis C virus replication through interferon gamma-inducible protein-10

<p>Abstract</p> <p>Background</p> <p>Co-infection with human immunodeficiency virus-1 (HIV-1) and hepatitis C virus (HCV) is associated with faster progression of liver disease and an increase in HCV persistence. However, the mechanism by which HIV-1 accelerates the progression of HCV liver disease remains unknown.</p> <p>Results</p> <p>HIV-1/HCV co-infection is associated with increased expression of interferon gamma-induced protein-10 (IP-10) mRNA in peripheral blood mononuclear cells (PBMCs). HCV RNA levels were higher in PBMCs of patients with HIV-1/HCV co-infection than in patients with HCV mono-infection. HIV-1 Tat and IP-10 activated HCV replication in a time-dependent manner, and HIV-1 Tat induced IP-10 production. In addition, the effect of HIV-1 Tat on HCV replication was blocked by anti-IP-10 monoclonal antibody, demonstrating that the effect of HIV-1 Tat on HCV replication depends on IP-10. Taken together, these results suggest that HIV-1 Tat protein activates HCV replication by upregulating IP-10 production.</p> <p>Conclusions</p> <p>HIV-1/HCV co-infection is associated with increased expression of IP-10 mRNA and replication of HCV RNA. Furthermore, both HIV-1 Tat and IP-10 activate HCV replication. HIV-1 Tat activates HCV replication by upregulating IP-10 production. These results expand our understanding of HIV-1 in HCV replication and the mechanism involved in the regulation of HCV replication mediated by HIV-1 during co-infection.</p

ARF1 and GBF1 Generate a PI4P-Enriched Environment Supportive of Hepatitis C Virus Replication

Cellular levels of phosphatidylinositol 4-phosphate (PI4P) have been shown to be upregulated during RNA replication of several viruses, including the HCV replicon model. However, whether PI4P is required in an infectious HCV model remains unknown. Moreover, it is not established whether the host transport machinery is sequestered by the generation of PI4P during HCV infection. Here we found that PI4P was enriched in HCV replication complexes when Huh7.5.1 cells were infected with JFH1. HCV replication was inhibited upon overexpression of the PI4P phosphatase Sac1. The PI4P kinase PI4KIII$\beta$ was also found to be required for HCV replication. Moreover, the vesicular transport proteins ARF1 and GBF1 colocalized with PI4KIIIβ and were both required for HCV replication. During authentic HCV infection, PI4P plays an integral role in virus replication

A Bayesian measurement error model for two-channel cell-based RNAi data with replicates

RNA interference (RNAi) is an endogenous cellular process in which small double-stranded RNAs lead to the destruction of mRNAs with complementary nucleoside sequence. With the production of RNAi libraries, large-scale RNAi screening in human cells can be conducted to identify unknown genes involved in a biological pathway. One challenge researchers face is how to deal with the multiple testing issue and the related false positive rate (FDR) and false negative rate (FNR). This paper proposes a Bayesian hierarchical measurement error model for the analysis of data from a two-channel RNAi high-throughput experiment with replicates, in which both the activity of a particular biological pathway and cell viability are monitored and the goal is to identify short hair-pin RNAs (shRNAs) that affect the pathway activity without affecting cell activity. Simulation studies demonstrate the flexibility and robustness of the Bayesian method and the benefits of having replicates in the experiment. This method is illustrated through analyzing the data from a RNAi high-throughput screening that searches for cellular factors affecting HCV replication without affecting cell viability; comparisons of the results from this HCV study and some of those reported in the literature are included.Comment: Published in at http://dx.doi.org/10.1214/11-AOAS496 the Annals of Applied Statistics (http://www.imstat.org/aoas/) by the Institute of Mathematical Statistics (http://www.imstat.org

Eukaryotic translation initiation factor 4All contributes to microRNA-122 regulation of hepatitis C virus replication

Hepatitis C virus (HCV) is a positive sense RNA virus that persistently infects human liver, leading to cirrhosis and hepatocellular carcinoma. HCV replication requires the liver-specific microRNA-122 (miR-122). In contrast to canonical miRNA-mediated repression via 3’UTR sites, miR-122 positively regulates HCV replication by a direct interaction with the 5’ untranslated region (UTR) of the viral RNA. The protein factor requirements for this unusual miRNA regulation remain poorly understood. Here, we identify eIF4AII, previously implicated in miRNA-mediated repression via 3’UTR sites, as a host factor that is important for HCV replication. We demonstrate that eIF4AII interacts with HCV RNA and that this interaction is miR-122-dependent. We show that effective miR-122 binding to, and regulation of, HCV RNA are reduced following eIF4AII depletion. We find that the previously identified HCV co-factor CNOT1, which has also been implicated in miRNA-mediated repression via 3’UTR sites, contributes to regulation of HCV by eIF4AII. Finally, we show that eIF4AI knockdown alleviates the inhibition of HCV replication mediated by depletion of either eIF4AII or CNOT1. Our results suggest a competition effect between the eIF4A proteins to influence HCV replication by modulation of miR-122 function

MATHEMATICAL MODELING OF HOST CELL DETERMINANTS AND PHARMACOLOGICAL INTERVENTION IN HEPATITIS C VIRUS REPLICATION

Hepatitis C virus (HCV) is a blood-borne, enveloped, single-stranded, (+)-oriented RNA virus that mainly infects hepatocytes. Most infections progress into chronicity and eventually lead to severe liver disease. Although effective treatments have been developed, access to diagnosis and treatment is low, particularly in non-developed countries. Thus, eradication of the disease is unlikely without a prophylactic vaccine. Research, therefore, has to continue despite the high cure rates of today’s HCV regimens. We use mathematical modeling to study HCV replication and its intricate connection with the infected host cell. A model that is able to simulate intracellular HCV RNA replication suggested a host factor species (HF), representing a protein (complex) or a host process, to be critically involved in HCV replication. Gene expression profiling revealed several candidates potentially representing this HF. We validated those candidates in two variants of the human hepatoma cell line Huh7 and could confirm that five of them indeed played a role for HCV replication, namely CRAMP1, LBHD1, CRYM, THAP7, and NR0B2. The latter three are nuclear receptors or transcriptional (co )repressors, suggesting they could influence HCV replication indirectly, e.g. through glucose, lipid, or cholesterol metabolism. Follow-up studies will help to understand the implication of those factors in HCV replication and reveal important insights into the metabolic pathways regulating HCV replication. Model analyses also revealed the most sensitive steps in HCV RNA replication that could potentially be targeted by specific intervention. The standard of care for chronic HCV infection has been interferon alpha (IFN α) therapy that elicited a very broad but rather unspecific antiviral response of the host cell and came along with severe side effects. IFN-α activates signaling cascades that lead to the expression of hundreds of interferon stimulated genes that exert antiviral action. Despite its decades-long use, the exact mechanism of the suppression of HCV replication by IFN α treatment remains elusive. We thus combined experimental data with an intracellular model for HCV replication and revealed the steps in the viral replication cycle that are most probably affected by IFN α treatment. The obtained findings were well in line with in vitro data and confirmed the validity of our intracellular model to make such analyses. Recently, direct-acting antivirals (DAAs) have replaced IFN-α-containing regimens as the standard of care for chronic HCV infection. Those DAAs possess much less side effects, can be taken orally, and give extraordinarily high cure rates. Mainly three classes exist: inhibitors of the viral protease, the viral polymerase, and a viral multifunctional phosphoprotein. The latter class constitutes highly potent inhibitors of the HCV NS5A protein, exerting effects in the low picomolar range. However, due to the many roles of NS5A in the HCV life cycle, the exact mechanism of action of those DAAs remains unclear. For the other two classes, the mode of action is distinct and well defined. We, thus, used one representative member of each of these classes to validate the capacity of our model to implement drug effects and predict HCV replication correctly. Model predictions upon a priori fixing of the affected parameters in the model qualitatively resembled HCV replication dynamics under the respective drug treatment. This allowed us to apply our model to HCV replication data under treatment with an NS5A inhibitor in order to gain insights into its mode of action. The model revealed that the translation rate of HCV RNA as well as RNA synthesis steps in the HCV replication compartment are most probably affected by the drug. These findings were reasonable and supported by known roles of NS5A in the HCV life cycle. However, our model was limited to intracellular HCV replication and did not account for steps like particle assembly or infection of target cells. Therefore, we extended our intracellular model to cover the full viral life cycle. Our new full life cycle model could simulate viral (+)- and (-)-strand RNA, viral titers as well as spread of the infection, and was able to correctly predict HCV replication under drug treatment. Our new model will be helpful in further elucidating the mode of action of NS5A inhibitors and IFN α and in deciphering the role of host factors that determine permissiveness for HCV. Hence, this study provides a novel, extended mathematical model of the full HCV life cycle with the proven capacity of simulating and analyzing HCV replication even under pharmacological intervention. It can serve as an invaluable tool to study further molecular details of HCV replication and to devise and test novel therapeutic approaches

Comparative analysis of the lambda-interferons IL-28A and IL-29 regarding their transcriptome and their antiviral properties against hepatitis C virus.

Specific differences in signaling and antiviral properties between the different Lambda-interferons, a novel group of interferons composed of IL-28A, IL-28B and IL-29, are currently unknown. This is the first study comparatively investigating the transcriptome and the antiviral properties of the Lambda-interferons IL-28A and IL-29. Expression studies were performed by microarray analysis, quantitative PCR (qPCR), reporter gene assays and immunoluminometric assays. Signaling was analyzed by Western blot. HCV replication was measured in Huh-7 cells expressing subgenomic HCV replicon. All hepatic cell lines investigated as well as primary hepatocytes expressed both IFN-λ receptor subunits IL-10R2 and IFN-λR1. Both, IL-28A and IL-29 activated STAT1 signaling. As revealed by microarray analysis, similar genes were induced by both cytokines in Huh-7 cells (IL-28A: 117 genes; IL-29: 111 genes), many of them playing a role in antiviral immunity. However, only IL-28A was able to significantly down-regulate gene expression (n = 272 down-regulated genes). Both cytokines significantly decreased HCV replication in Huh-7 cells. In comparison to liver biopsies of patients with non-viral liver disease, liver biopsies of patients with HCV showed significantly increased mRNA expression of IL-28A and IL-29. Moreover, IL-28A serum protein levels were elevated in HCV patients. In a murine model of viral hepatitis, IL-28 expression was significantly increased. IL-28A and IL-29 are up-regulated in HCV patients and are similarly effective in inducing antiviral genes and inhibiting HCV replication. In contrast to IL-29, IL-28A is a potent gene repressor. Both IFN-λs may have therapeutic potential in the treatment of chronic HCV

Hepatitis C virus relies on lipoproteins for its life cycle

Hepatitis C virus (HCV) infects over 150 million people worldwide. In most cases, HCV infection becomes chronic causing liver disease ranging from fibrosis to cirrhosis and hepatocellular carcinoma. Viral persistence and pathogenesis are due to the ability of HCV to deregulate specific host processes, mainly lipid metabolism and innate immunity. In particular, HCV exploits the lipoprotein machineries for almost all steps of its life cycle. The aim of this review is to summarize current knowledge concerning the interplay between HCV and lipoprotein metabolism. We discuss the role played by members of lipoproteins in HCV entry, replication and virion production

Interferon-inducible protein SCOTIN interferes with HCV replication through the autolysosomal degradation of NS5A

Hepatitis C virus (HCV) utilizes autophagy to promote its propagation. Here we show the autophagy-mediated suppression of HCV replication via the endoplasmic reticulum (ER) protein SCOTIN. SCOTIN overexpression inhibits HCV replication and infectious virion production in cells infected with cell culture-derived HCV. HCV nonstructural 5A (NS5A) protein, which is a critical factor for HCV RNA replication, interacts with the IFN-beta-inducible protein SCOTIN, which transports NS5A to autophagosomes for degradation. Furthermore, the suppressive effect of SCOTIN on HCV replication is impaired in both ATG7-silenced cells and cells treated with autophagy or lysosomal inhibitors. SCOTIN does not affect the overall flow of autophagy; however, it is a substrate for autophagic degradation. The physical association between the transmembrane/proline-rich domain (TMPRD) of SCOTIN and Domain-II of NS5A is essential for autophagosomal trafficking and NS5A degradation. Altogether, our findings suggest that IFN-beta-induced SCOTIN recruits the HCV NS5A protein to autophagosomes for degradation, thereby restricting HCV replication.1110Ysciescopu