Autophagy constitutes a major catabolic process for the quality control of internal proteins and organelles of eukaryotic cells, and is emerging as an essential part of the host antiviral defense. Many studies have shed light on the importance of autophagy in homeostasis, but it is not well understood how viruses co-opt the cellular autophagic pathway to establish virulence in vivo. Our recent study presents direct in vivo evidence for the key role of the anti-autophagic aspect of the virally encoded Bcl-2 proteins in the chronic infection of oncogenic γ-herpesviruses and proposes that cellular autophagy may have a substantial effect on viral persistence and may influence the in vivo fitness of viruses. This discovery expands upon known antiviral activities of the autophagy machinery and also suggests new approaches for treating some virally induced diseases.

Autophagy is a lysosome-directed membrane trafficking event for the degradation of cytoplasmic components, including organelles. The past few years have seen a great advance in our understanding of the cellular machinery of autophagosome biogenesis, the hallmark of autophagy. However, our global understanding of autophagosome maturity remains relatively poor and fragmented. The topological similarity of autophagosome and endosome delivery to lysosomes suggests that autophagic and endosomal maturation may have evolved to share associated machinery to promote the lysosomal delivery of their cargoes. We have recently discovered that UVRAG, originally identified as a Beclin 1-binding autophagy protein, appears to be an important factor in autophagic and endosomal trafficking through its interaction with the class C Vps tethering complex. Given the ability of UVRAG to bind Beclin 1 and the class C Vps complex in a genetically and functionally separable manner, it may serve as an important regulator for the spatial and/or temporal control of diverse cellular trafficking events. As more non-autophagic functions of UVRAG are unveiled, our understanding of seemingly different cellular processes may move a step further.

Autophagy removes long-lived proteins and damaged organelles and is important for maintaining cellular homeostasis. It can also serve in innate immunity to remove intracellular pathogens. As such, viruses have evolved different mechanisms to subvert this innate immune response. We have recently demonstrated that hepatitis C virus (HCV) can also suppress autophagic protein degradation by suppressing the fusion between autophagosomes and lysosomes. This suppression causes the accumulation of autophagosomes and enhances HCV RNA replication.1 Our further analysis indicated that the induction of autophagosomes by HCV is dependent on the unfolded protein response (UPR). Our studies thus delineate a molecular pathway by which HCV induces autophagosomes. The prolonged perturbation of the autophagic pathway by HCV likely plays an important role in HCV pathogenesis.