Global health is threatened by emerging viral infections, which largely lack effective vaccines or therapies. Targeting host pathways that are exploited by multiple viruses could offer broad-spectrum solutions. We previously reported that AAK1 and GAK, kinase regulators of the host adaptor proteins AP1 and AP2, are essential for hepatitis C virus (HCV) infection, but the underlying mechanism and relevance to other viruses or in vivo infections remained unknown. Here, we have discovered that AP1 and AP2 cotraffic with HCV particles in live cells. Moreover, we found that multiple viruses, including dengue and Ebola, exploit AAK1 and GAK during entry and infectious virus production. In cultured cells, treatment with sunitinib and erlotinib, approved anticancer drugs that inhibit AAK1 or GAK activity, or with more selective compounds inhibited intracellular trafficking of HCV and multiple unrelated RNA viruses with a high barrier to resistance. In murine models of dengue and Ebola infection, sunitinib/erlotinib combination protected against morbidity and mortality. We validated sunitinib- and erlotinib-mediated inhibition of AAK1 and GAK activity as an important mechanism of antiviral action. Additionally, we revealed potential roles for additional kinase targets. These findings advance our understanding of virus-host interactions and establish a proof of principle for a repurposed, host-targeted approach to combat emerging viruses.
Broad spectrum antiviral drugs targeting host processes could potentially treat a wide range of viruses while reducing the likelihood of emergent resistance. Despite great promise as therapeutics, such drugs remain largely elusive. Here we use parallel genome-wide high-coverage shRNA and CRISPR-Cas9 screens to identify the cellular target and mechanism of action of GSK983, a potent broad spectrum antiviral with unexplained cytotoxicity1–3. We show that GSK983 blocks cell proliferation and dengue virus replication by inhibiting the pyrimidine biosynthesis enzyme dihydroorotate dehydrogenase (DHODH). Guided by mechanistic insights from both genomic screens, we found that exogenous deoxycytidine markedly reduces GSK983 cytotoxicity but not antiviral activity, providing an attractive novel approach to improve the therapeutic window of DHODH inhibitors against RNA viruses. Together, our results highlight the distinct advantages and limitations of each screening method for identifying drug targets and demonstrate the utility of parallel knockdown and knockout screens for comprehensively probing drug activity.
Autophagy is an important component of the innate immune response, directly destroying many intracellular pathogens. However, some pathogens, including several RNA viruses, subvert the autophagy pathway, or components of the pathway, to facilitate their replication. In the present study, the effect of inhibiting autophagy on the growth of dengue virus was tested using a novel inhibitor, spautin-1 (specific and potent autophagy inhibitor 1). Inhibition of autophagy by spautin-1 generated heat-sensitive, noninfectious dengue virus particles, revealing a large effect of components of the autophagy pathway on viral maturation. A smaller effect on viral RNA accumulation was also observed. Conversely, stimulation of autophagy resulted in increased viral titers and pathogenicity in the mouse. We conclude that the presence of functional autophagy components facilitates viral RNA replication and, more importantly, is required for infectious dengue virus production. Pharmacological inhibition of host processes is an attractive antiviral strategy to avoid selection of treatmentresistant variants, and inhibitors of autophagy may prove to be valuable therapeutics against dengue virus infection and pathogenesis.A ll positive-strand RNA viruses, including picornaviruses, such as poliovirus, rhinovirus, and hepatitis A virus, and flaviviruses, such as dengue virus and hepatitis C virus (HCV), rely heavily on cellular membranes at numerous stages of their infectious cycles. For example, RNA replication complexes must assemble on the topologically cytoplasmic surfaces of intracellular membranes. In some cases, such as poliovirus and hepatitis A virus, these RNA replication complexes are on the convex outer surfaces of discrete vesicles (1). In others, such as dengue virus, RNA replication complexes are assembled on invaginated membrane surfaces that are connected to the cytosol only via narrow openings (2, 3). For dengue virus, newly synthesized viral RNA exits the invaginated cytoplasm and interacts with core protein, which encapsidates the viral RNA and decorates the surfaces of nearby lipid droplets via the high-affinity binding of its N-terminal domain (4, 5). For HCV, a similar interaction of the core protein with lipid droplets has been described and seems to play a critical role in the assembly of viral particles (6-9). During dengue virus infection, formation of the nucleocapsid, subsequent interaction with envelope proteins, and budding into the ER lumen are likely to occur in close proximity (2). In the cis-Golgi, the virion undergoes a conformational change, and the viral prM (prematrix) protein is cleaved by the cellular furin protease into the mature M (matrix) protein and a peptide (pr) (10, 11). Upon cleavage, the pr peptide dissociates from the virion, resulting in the formation of mature progeny viruses that are highly infectious. This finely tuned interplay between cellular membrane remodeling, cellular lipid storage, and viral assembly is not only a fascinating cell biological puzzle, but also provides exciting...
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