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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.

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Project description:Genome wide transcriptional changes induced by various types of oxidative stresses as well as salt stress were studied in a DatfA mutant and the appropriate control A. nidulans strains. Although a significant number of stereotypically regulated genes was identified (Core Oxidative Stress Response or COSR genes) when the global transcriptional effects of five different oxidative stress conditions were compared the number of co-regulated genes decreased to 13 when NaCl stress was included into the analyses. The appearance of only a few co-regulated genes and the great number of genes regulated merely by one certain type of stress do not support the existence of a S. cerevisiae-type Environmental Stress Response in A. nidulans. Deletion of atfA, a true functional ortholog of fission yeast’s “all-purpose” stress response transcription factor, increased the oxidative stress sensitivity of A. nidulans and affected the transcription of several genes under both unstressed and stressed conditions. The number of genes under AtfA control was quite stress-type dependent; e.g. deletion of atfA altered the transcription of a wide spectrum of genes under menadione sodium bisulfite stress but had only a minor effect on the transcriptome profiles when A. nidulans cultures were exposed to H2O2, tBOOH, NaCl and, especially, to diamide stress. These observations suggest that the function of AtfA in the regulation of various stress responses is much smaller than we thought before or other transcription factors can take over a number of AtfA’s functions when the atfA gene is deleted. It is noteworthy that both oxidative and salt stress induced the transcription of some secondary metabolite gene clusters and the deletion of atfA enhanced the stress responsiveness of further clusters. Surprisingly, certain clusters were down-regulated by the stress conditions tested and the majority of them were not stress-responsive at all. Therefore, stress dependent regulation seems to be a frequent but far not a general feature of the regulation of secondary metabolism in A. nidulans. 14 samples, 7 with the control strain and 7 with an DatfA strain (each series contains samples from untreated as well as menadione, low concentration hidrogen-peroxide, high concentration hidrogen-peroxide, tert-butylhydroperoxide, diamide and NaCl treated cultures)

Project description: Not available