Project description:The main goal of this study is to characterize the transcriptional modulations induced by antiviral compounds derived from chloroquine on Huh7 cells infected with HCV. And thus to identify among the genes modulated by infection, those who are regulated by chloroquine and potentially involved in the antiviral activity of the compound.Two HCV cell models were used: a non-infectious HCV replicon and the infectious HCV cell culture (HCVcc). In addition, this study aimed to highlight the characteristics of derivatives of antiviral chloroquine, compared with chloroquine itself. Abstract from the associated publication: Autophagy is a process of self-degradation of cellular components in which double-membrane autophagosomes sequester organelles or portion of cytosol and fuse with lysosomes or vacuoles for breakdown by resident hydrolases. Autophagy is upregulated in response to extra- or intracellular stress and signals such as starvation, growth factor deprivation, ER stress, and pathogen infection. Indeed, infection with hepatitis C virus (HCV) was shown to induce autophagy through ER stress signaling and subsequent Unfolded Protein Response (UPR) activation. Moreover, a role of autophagy in promoting HCV infection has been suggested and chloroquine (CQ), a lysosomal protease inhibitor, has been seen blocking autophagy as well as inhibiting HCV replication. In the present report, mechanisms accounting for these inhibitory effects were investigated. Gene expression profiling was performed on CQ treated JFH-1-infected Huh7 cells to identify the host cellular genes that are transcriptionally regulated by infection, and silenced by CQ-based treatment. Herein, we demonstrate that CQ reduces the expression of genes induced by the viral infection such as those encoding autophagic key factors triggering the turn-off of mTOR activity as well as factors involved in p53 and NF-KappaB activities. However, we present several lines of evidence demonstrating that the CQ repressive effect observed on the HCV-induced pathways results from a decrease of ER stress due to the upstream pH-dependent inhibitory effect of CQ on viral replication. Gene expression modulations were measured in Huh7 harboring replicon cells stimulated with a 10M-BM-5M of a Chloroquine derivative compound called CQd, during 6h, 12h and 24h. Two independent experiments were performed at each time. An untreated control condition was performed in each experiment, expression was measured at the 24h time point. For the HCVcc model, gene expression analysis was analyzed in two conditions: infection and treatment of infected cells. To characterize modulations in time course of infection, Huh7 naM-CM-/ve cells were infected with JFH1/CS-N6-A4 viral stock and gene expression was measured at 6h, 24h and 48h postinfection. For each kinetic time point, an uninfected condition was performed and gene expression was measured. An additional control testing the interferon (IFN) induced modulations on infected cells was included and gene expression was measured after a 48h stimulation with 100 IU of IFN (alpha 2 b). To characterize the antiviral modulations resulting from treatment with Chloroquine (CQ) or a derivative compound (CQd), gene expression was measured in JFH1/CS-N6-A4 infected Huh7 cells treated with 40M-BM-5M of CQ or CQd during 12h or 48h post-treatment and infection. For each kinetic time point 12h and 48h, an untreated infected control was also performed and gene expression measured.

Project description:Hepatitis C virus (HCV) infection is a major cause of chronic hepatitis, liver cirrhosis and hepatocellular carcinoma. HCV can be sensed by host innate immunity to induce expression of interferons (IFNs) and a number of antiviral effectors. HCV-encoded NS3/4 serine protease can subvert host innate immune responses by cleaving MAVS, a critical adaptor protein in the RLR-mediated IFN signaling. To study innate immunity in the context of HCV infection, we constructed Huh7-MAVSR cells which express a mutant MAVS resistant to NS3/4A cleavage. HCV infection induces robust IFN response in Huh7-MAVSR cells, providing a cellular system to study antiviral innate immune response against HCV infection. To analyze host innate antiviral effectors against HCV infection, we performed an mRNA microarray analysis in the HCV-infected Huh7-MAVSR cells.

Project description:MX1 is a well-characterized interferon-induced antiviral gene. MX1 is activated by viral infection due to interferon production in cells. We treated non-permissive Huh7 cells and permissive HRP4 cells with interferon. We compared the expression of genes induced by interferon to determine host factors affecting HCV replication. Huh7 cells and HRP4 cells were treated with 40U/ml interferon-α for 6h. RNA was extracted and hybridized on Affymetrix microarrays

Project description:A powerful approach to study innate antiviral response is to compare the difference between wild type Huh7 cells, which do not support robust replication of hepatitis C virus (HCV)2, versus certain subclones of Huh7 cells that are permissive for HCV replication. We generated two permissive cell lines and two independent non-permissive subclone from Huh7 cells. We compared the global methylation pattern of these different cells and find that Huh7 cells exist as a heterogeneous population of cells with distinct patterns of gene methylation. Comparison of Huh7, HRP1, HRP4, Huh7-pNeo1 and Huh7-pNeo2 cells.

Project description:OSM increases the antiviral effect of IFNα in Huh7 cells infected with hepatitis A virus (HAV) or HCV replicon and synergizes with IFNα in the induction of antiviral genes

Project description:MX1 is a well-characterized interferon-induced antiviral gene. MX1 is activated by viral infection due to interferon production in cells. We treated non-permissive Huh7 cells and permissive HRP4 cells with interferon. We compared the expression of genes induced by interferon to determine host factors affecting HCV replication.

Project description:Pyronaridine (PN) and chloroquine (CQ) are structurally related anti-malarial drugs with primarily the same mode of action. However, PN is effective against several multidrug-resistant lines of Plasmodium falciparum, including CQ-resistant lines, suggestive of important operational differences between the two drugs. Synchronized trophozoite-stage cultures of P. falciparum strain K1 (CQ resistant) were exposed to 50% inhibitory concentrations (IC50) of PN and CQ, and parasites were harvested from culture after 4 and 24 hours exposure. Global transcriptional changes effected by drug treatment were investigated using DNA microarrays. Plasmodium falciparum in vitro cultures were synchronized to trophozoite stage (22-24h post infection) and exposed to either CQ or PN at IC50 concentrations. 18 sample pairs (drug treated/untreated) were analyzed; 9 for CQ and 9 for PN. All drug-treated samples were labelled with Cy5 and untreated controls were labelled with Cy3.

Project description:A powerful approach to study innate antiviral response is to compare the difference between wild type Huh7 cells, which do not support robust replication of hepatitis C virus (HCV)2, versus certain subclones of Huh7 cells that are permissive for HCV replication. We generated two permissive cell lines and two independent non-permissive subclone from Huh7 cells. We compared the global methylation pattern of these different cells and find that Huh7 cells exist as a heterogeneous population of cells with distinct patterns of gene methylation.

Project description:OSM increases the antiviral effect of IFNα in Huh7 cells infected with hepatitis A virus (HAV) or HCV replicon and synergizes with IFNα in the induction of antiviral genes 16 samples. Four replicates for each experimental condition. 72 hours of treatment in DMEM supplemented with 2% FBS.

Project description:Nilotinib is a second-generation BCR-ABL1 tyrosine kinase inhibitor for the first-line treatment of Philadelphia chromosome-positive chronic myeloid leukemia. However, its nephrotoxicity has become prominent with the increase of clinical use, which greatly limits its long-term application. So far, the mechanism of nilotinib’s nephrotoxicity is still unknown leading to a lack of clinical intervention strategies. Here, we found that nilotinib could promote intrinsic apoptosis of both vascular endothelial cells and renal tubular epithelial cells, which was mediated by the excessive ubiquitin-proteasome degradation of anti-apoptotic protein BCL-XL. Moreover, we confirmed that Chloroquine (CQ) could intervene nilotinib-induced apoptosis by reversing the decreased BCL-XL whose mechanism was not relied on autophagy inhibition. Furthermore, RNA-seq analysis was applied to identify the potential target of CQ and the result suggested that CQ could alleviate nilotinib-induced ANKRD1 reduction. Further, we found ANKRD1 abrogated cell apoptosis by preventing ubiquitination of BCL-XL and hence inhibiting BCL-XL degradation. In conclusion, our research reveals the molecular mechanism of nilotinib’s nephrotoxicity, wherein the excessive degradation of BCL-XL via ubiquitin-proteasome pathway promotes kidney cells apoptosis, and provides CQ analogs as the clinical intervention strategy of nilotinib’s nephrotoxicity whose pharmacological effect is dependent on ANKRD1 instead of autophagy inhibition.