Hepatitis C virus infection increases autophagosome stability by suppressing lysosomal fusion through an Arl8b-dependent mechanism.

Autophagy is a conserved cellular process involving intracellular membrane trafficking and degradation. Pathogens, including hepatitis C virus (HCV), often exploit this process to promote their own survival. The aim of this study was to determine the mechanism by which HCV increases steady-state autophagosome numbers while simultaneously inhibiting flux through the autophagic pathway. Using the lysosomal inhibitor bafilomycin A1, we showed that HCV-induced alterations in autophagy result from a blockage of autophagosome degradation rather than an increase in autophagosome generation. In HCV-infected cells, lysosome function was normal, but a tandem RFP-GFP-LC3 failed to reach the lysosome even under conditions that activate autophagy. Autophagosomes and lysosomes isolated from HCV-infected cells were able to fuse with each other normally in vitro, suggesting that the cellular fusion defect resulted from trafficking rather than an inability of vesicles to fuse. Arl8b is an Arf-like GTPase that specifically localizes to lysosomes and plays a role in autophagic flux through its effect on lysosomal positioning. At basal levels, Arl8b was primarily found in a perinuclear localization and co-localized with LC3-positive autophagosomes. HCV infection increased the level of Arl8b 3-fold and redistributed Arl8b to a more diffuse, peripheral pattern that failed to co-localize with LC3. Knockdown of Arl8b in HCV-infected cells restored autophagosome-lysosome fusion and autophagic flux to levels seen in control cells. Thus, HCV suppresses autophagic flux and increases the steady-state levels of autophagosomes by increasing the expression of Arl8b, which repositions lysosomes and prevents their fusion with autophagosomes.

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The current political climate in the United States has mobilized scientists to become more cognizant of the need to advocate for sustainable science funding from the federal government and for acceptance of evidence-based policy making that relies on the best available scientific data. Many scientists, however, do not learn about science policy or how to advocate in Washington, D.C., or at the local level as part of their scientific training. Here we explain why science advocacy is important and provide steps on how to get involved by communicating with elected officials and engaging in the local community.

Hepatitis C virus promotes virion secretion through cleavage of the Rab7 adaptor protein RILP.

Hepatitis C virus (HCV) is an enveloped RNA virus that modifies intracellular trafficking processes. The mechanisms that HCV and other viruses use to modify these events are poorly understood. In this study, we observed that two different RNA viruses, HCV and Sendai, cause inhibition of ras-related protein Rab-7 (Rab7)-dependent endosome-lysosome fusion. In both cases, viral infection causes cleavage of the Rab7 adaptor protein RILP (Rab interacting lysosomal protein), which is responsible for linking Rab7 vesicles to dynein motor complexes. RILP cleavage results in the generation of a cleaved RILP fragment (cRILP) missing the N terminus of the molecule. Although RILP localizes in a perinuclear fashion, cRILP moves to the cell periphery. Both knockdown of RILP and expression of cRILP reproduced the HCV-induced trafficking defect, and restoring full-length RILP reversed the trafficking effects of virus. For the first 3 d after electroporation of HCV RNA, intracellular virus predominates over secreted virus, but the quantity of intracellular virus then rapidly declines as secreted virus dominates. The transition from the intracellular-predominant to the secretion-predominant phenotype corresponds to the time course of cRILP generation. Expressing cRILP directly prevents intracellular virus accumulation at early times without affecting net virus production. The ability of cRILP to promote virus secretion could be prevented by a kinesin inhibitor. HCV thus modifies cellular trafficking by cleaving RILP, which serves to redirect Rab7-containing vesicles to a kinesin-dependent trafficking mode promoting virion secretion. Cleavage of a Rab adaptor protein is thus a mechanism by which viruses modify trafficking patterns of infected cells.