Type-I interferons (IFNs) are major innate immune messengers that are produced by cells upon viral infection. They trigger transcriptional upregulation of a subset of host genes called interferon stimulated genes (ISGs). The concert of hundreds of expressed ISGs builds a robust line of defense. IFNs are used therapeutically but cause severe side effects. A better understanding of the multi-layered ISG barrier is crucial to allow manipulation of ISG effector function in a more targeted manner. Currently, several hundred ISGs remain largely uncharacterized. Previous studies that aimed to identify antiviral ISG effectors have focused predominantly on early stages of viral infection. As a result, a potential pool of antiviral ISGs that inhibit late stages of virus infection (assembly, egress or particle infectivity) has yet to be identified. I propose a project to investigate ISG effector functions. First, I will characterize the antiviral function of the ISG DDX60, recently shown to inhibit hepatitis C virus (HCV). Based on sequence homology to proteins with known function, I hypothesize that DDX60 might inhibit viral protein translation or undermine viral RNA stability. I propose to perform a number of functional assays, including mapping of functional motifs and viral life cycle studies in order to define the mechanism by which DDX60 inhibits HCV. Second, I plan to identify ISGs that specifically inhibit late stages in virus lifecycles. I will modify a current ISG gain-of-function assay and utilize the 300+ ISGs from a previously published ISG screen to identify inhibitors of influenza A virus, HCV, West Nile virus, Dengue virus, and yellow fever virus. I expect that the results from this screen will enable side-by-side comparison of ISGs that inhibit late lifecycle stages of each of these viruses, providing insight into similarities and differences in viral egress mechanisms.

DFG Programme Research Fellowships

International Connection USA

Host Professor Dr. Charles M. Rice, Ph.D.