The Atg17-Atg31-Atg29 complex and Atg11 regulate autophagosome-vacuole fusion

The macroautophagy (hereafter autophagy) process involves de novo formation of double-membrane autophagosomes; after sequestering cytoplasm these transient organelles fuse with the vacuole/lysosome. Genetic studies in yeasts have characterized more than 40 autophagy-related (Atg) proteins required for autophagy, and the majority of these proteins play roles in autophagosome formation. The fusion of autophagosomes with the vacuole is mediated by the Rab GTPase Ypt7, its guanine nucleotide exchange factor Mon1-Ccz1, and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins. However, these factors are not autophagosome-vacuole fusion specific. We recently showed that 2 autophagy scaffold proteins, the Atg17-Atg31-Atg29 complex and Atg11, regulate autophagosome-vacuole fusion by recruiting the vacuolar SNARE Vam7 to the phagophore assembly site (PAS), where an autophagosome forms in yeast.     

Evolutionarily conserved role and physiological relevance of a STX17/Syx17 (syntaxin 17)-containing SNARE complex in autophagosome fusion with endosomes and lysosomes

Phagophores engulf cytoplasmic material and give rise to autophagosomes, double-membrane vesicles mediating cargo transport to lysosomes for degradation. The regulation of autophagosome fusion with endosomes and lysosomes during autophagy has remained poorly characterized. Two recent papers conclude that STX17/syntaxin 17 (Syx17 in Drosophila) has an evolutionarily conserved role in autophagosome fusion with endosomes and lysosomes, acting in one SNARE complex with SNAP29 (ubisnap in Drosophila) and the endosomal/lysosomal VAMP8 (CG1599/Vamp7 in Drosophila). Surprisingly, a third report suggests that STX17 might also contribute to proper phagophore assembly. Although several experiments presented in the two human cell culture studies yielded controversial results, the essential role of STX17 in autophagic flux is now firmly established, both in cultured cells and in an animal model. Based on these data, we propose that genetic inhibition of STX17/Syx17 may be a more specific tool in autophagic flux experiments than currently used drug treatments, which impair all lysosomal degradation routes and also inactivate MTOR (mechanistic target of rapamycin), a major negative regulator of autophagy. Finally, the neuronal dysfunction and locomotion defects observed in Syx17 mutant animals point to the possible contribution of defective autophagosome clearance to various human diseases.     

Genome-wide siRNA screen reveals amino acid starvation-induced autophagy requires SCOC and WAC

Autophagy is a catabolic process by which cytoplasmic components are sequestered and transported by autophagosomes to lysosomes for degradation, enabling recycling of these components and providing cells with amino acids during starvation. It is a highly regulated process and its deregulation contributes to multiple diseases. Despite its importance in cell homeostasis, autophagy is not fully understood. To find new proteins that modulate starvation-induced autophagy, we performed a genome-wide siRNA screen in a stable human cell line expressing GFP-LC3, the marker-protein for autophagosomes. Using stringent validation criteria, our screen identified nine novel autophagy regulators. Among the hits required for autophagosome formation are SCOC (short coiled-coil protein), a Golgi protein, which interacts with fasciculation and elongation protein zeta 1 (FEZ1), an ULK1-binding protein. SCOC forms a starvation-sensitive trimeric complex with UVRAG (UV radiation resistance associated gene) and FEZ1 and may regulate ULK1 and Beclin 1 complex activities. A second candidate WAC is required for starvation-induced autophagy but also acts as a potential negative regulator of the ubiquitin-proteasome system. The identification of these novel regulatory proteins with diverse functions in autophagy contributes towards a fuller understanding of autophagosome formation.     

Atg17 functions in cooperation with Atg1 and Atg13 in yeast autophagy

In eukaryotic cells, nutrient starvation induces the bulk degradation of cellular materials; this process is called autophagy. In the yeast Saccharomyces cerevisiae, most of the ATG (autophagy) genes are involved in not only the process of degradative autophagy, but also a biosynthetic process, the cytoplasm to vacuole (Cvt) pathway. In contrast, the ATG17 gene is required specifically in autophagy. To better understand the function of Atg17, we have performed a biochemical characterization of the Atg17 protein. We found that the atg17delta mutant under starvation condition was largely impaired in autophagosome formation and only rarely contained small autophagosomes, whose size was less than one-half of normal autophagosomes in diameter. Two-hybrid analyses and coimmunoprecipitation experiments demonstrated that Atg17 physically associates with Atg1-Atg13 complex, and this binding was enhanced under starvation conditions. Atg17-Atg1 binding was not detected in atg13delta mutant cells, suggesting that Atg17 interacts with Atg1 through Atg13. A point mutant of Atg17, Atg17(C24R), showed reduced affinity for Atg13, resulting in impaired Atg1 kinase activity and significant defects in autophagy. Taken together, these results indicate that Atg17-Atg13 complex formation plays an important role in normal autophagosome formation via binding to and activating the Atg1 kinase.     

Syntaxin 17

The phagophore (also called isolation membrane) elongates and encloses a portion of cytoplasm, resulting in formation of the autophagosome. After completion of autophagosome formation, the outer autophagosomal membrane becomes ready to fuse with the lysosome for degradation of enclosed cytoplasmic materials. However, the molecular mechanism for how the fusion of completed autophagosomes with the lysosome is regulated has not been fully understood. We discovered syntaxin 17 (STX17) as an autophagosomal soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE). STX17 has a hairpin-type structure mediated by two transmembrane domains, each containing glycine zipper motifs. This unique transmembrane structure contributes to its specific localization to completed autophagosomes but not to phagophores. STX17 interacts with SNAP29 and the lysosomal SNARE VAMP8, and all of these proteins are required for autophagosome–lysosome fusion. The late recruitment of STX17 to completed autophagosomes could prevent premature fusion of the lysosome with unclosed phagophores.     

Control of GABARAP‐mediated autophagy by the Golgi complex,centrosome and centriolar satellites

Within minutes of induction of autophagy by amino‐acid starvation in mammalian cells, multiple autophagosomes form throughout the cell cytoplasm. During their formation, the autophagosomes sequester cytoplasmic material and deliver it to lysosomes for degradation. How these organelles can be so rapidly formed and how their formation is acutely regulated are major questions in the autophagy field. Protein and lipid trafficking from diverse cell compartments contribute membrane to, or regulate the formation of the autophagosome. In addition, recruitment of Atg8 (in yeast), and the ATG8‐family members (in mammalian cells) to autophagosomes is required for efficient autophagy. Recently, it was discovered that the centrosome and centriolar satellites regulate autophagosome formation by delivery of an ATG8‐family member, GABARAP, to the forming autophagosome membrane, the phagophore. We propose that GABARAP regulates phagophore expansion by activating the ULK complex, the amino‐acid controlled initiator complex. This finding reveals a previously unknown link between the centrosome, centriolar satellites and autophagy.     

Live Cell Imaging of Early Autophagy Events: Omegasomes and Beyond

Autophagy is a cellular response triggered by the lack of nutrients, especially the absence of amino acids. Autophagy is defined by the formation of double membrane structures, called autophagosomes, that sequester cytoplasm, long-lived proteins and protein aggregates, defective organelles, and even viruses or bacteria. Autophagosomes eventually fuse with lysosomes leading to bulk degradation of their content, with the produced nutrients being recycled back to the cytoplasm. Therefore, autophagy is crucial for cell homeostasis, and dysregulation of autophagy can lead to disease, most notably neurodegeneration, ageing and cancer.Autophagosome formation is a very elaborate process, for which cells have allocated a specific group of proteins, called the core autophagy machinery. The core autophagy machinery is functionally complemented by additional proteins involved in diverse cellular processes, e.g. in membrane trafficking, in mitochondrial and lysosomal biology. Coordination of these proteins for the formation and degradation of autophagosomes constitutes the highly dynamic and sophisticated response of autophagy. Live cell imaging allows one to follow the molecular contribution of each autophagy-related protein down to the level of a single autophagosome formation event and in real time, therefore this technique offers a high temporal and spatial resolution.Here we use a cell line stably expressing GFP-DFCP1, to establish a spatial and temporal context for our analysis. DFCP1 marks omegasomes, which are precursor structures leading to autophagosomes formation. A protein of interest (POI) can be marked with either a red or cyan fluorescent tag. Different organelles, like the ER, mitochondria and lysosomes, are all involved in different steps of autophagosome formation, and can be marked using a specific tracker dye. Time-lapse microscopy of autophagy in this experimental set up, allows information to be extracted about the fourth dimension, i.e. time. Hence we can follow the contribution of the POI to autophagy in space and time.     

Microtubules facilitate autophagosome formation and fusion of autophagosomes with endosomes

Nutrient deprivation of eukaryotic cells provokes a variety of stress responses, including autophagy. Autophagy is carried out by autophagosomes which sequester cytosolic components and organelles for degradation after fusion with protease-containing endosomes. To determine the role of microtubules in autophagy, we used nocodazole and vinblastine to disrupt microtubules and independently measured formation and fusion of autophagsosomes in primary rat hepatocytes. By measuring the translocation of GFP-LC3, an autophagosomal marker, to autophagosomes and the lipidation of GFP-LC3, we quantified the rate and magnitude of autophagosome formation. Starvation increased both the rate of autophagosome formation over the basal level and the total number of autophagosomes per cell. Maximal autophagosome formation required an intact microtubule network. Fusion of autophagosomes with endosomes, assayed by acquisition of protease-inhibitor sensitivity as well as overlap with LysoTracker Red-positive endosomes, required intact microtubules. Live-cell imaging demonstrated that autophagosomes were motile structures, and their movement also required microtubules. Interestingly, vinblastine stimulated autophagosome formation more than twofold before any discernable change in the microtubule network was observed. Stimulation of autophagosome formation by vinblastine was independent of nutrients and mTOR activity but was inhibited by depletion of the Autophagy proteins Atg5 and Atg6, known to be required for autophagy.     

Accumulation of autophagosomes in Semliki Forest virus-infected cells is dependent on expression of the viral glycoproteins

Autophagy is a cellular process that sequesters cargo in double-membraned vesicles termed autophagosomes and delivers this cargo to lysosomes to be degraded. It is enhanced during nutrient starvation to increase the rate of amino acid turnover. Diverse roles for autophagy have been reported for viral infections, including the assembly of viral replication complexes on autophagic membranes and protection of host cells from cell death. Here, we show that autophagosomes accumulate in Semliki Forest virus (SFV)-infected cells. Despite this, disruption of autophagy had no effect on the viral replication rate or formation of viral replication complexes. Also, viral proteins rarely colocalized with autophagosome markers, suggesting that SFV did not utilize autophagic membranes for its replication. Further, we found that SFV infection, unlike nutrient starvation, did not inactivate the constitutive negative regulator of autophagosome formation, mammalian target of rapamycin, suggesting that SFV-dependent accumulation of autophagosomes was not a result of enhanced autophagosome formation. In starved cells, addition of NH(4)Cl, an inhibitor of lysosomal acidification, caused a dramatic accumulation of starvation-induced autophagosomes, while in SFV-infected cells, NH(4)Cl did not further increase levels of autophagosomes. These results suggest that accumulation of autophagosomes in SFV-infected cells is due to an inhibition of autophagosome degradation rather than enhanced rates of autophagosome formation. Finally, we show that the accumulation of autophagosomes in SFV-infected cells is dependent on the expression of the viral glycoprotein spike complex.     

Dual function of CALCOCO2/NDP52 during xenophagy

During xenophagy, pathogens are selectively targeted by autophagy receptors to the autophagy machinery for their subsequent degradation. In infected cells, the autophagy receptor CALCOCO2/NDP52 targets Salmonella Typhimurium to the phagophore membrane by concomitantly interacting with LC3C and binding to ubiquitinated cytosolic bacteria or to LGALS8/GALECTIN 8 adsorbed on damaged vacuoles that contain bacteria. We recently reported that in addition, CALCOCO2 is also necessary for the maturation step of Salmonella Typhimurium-containing autophagosomes. Interestingly, the role of CALCOCO2 in maturation is independent of its role in targeting, as these functions rely on distinct binding domains and protein partners. Indeed, to mediate autophagosome maturation CALCOCO2 binds on the one hand to LC3A, LC3B, or GABARAPL2, and on the other hand to MYO6/MYOSIN VI, whereas the interaction with LC3C is dispensable. Therefore, the autophagy receptor CALCOCO2 plays a dual function during xenophagy first by targeting bacteria to nascent autophagosomes and then by promoting autophagosome maturation in order to destroy bacteria.Xenophagy is the process referring to the selective degradation of intracellular microorganisms by autophagy. Xenophagy is a very potent intrinsic cellular line of defense to fight pathogens and requires first the detection and targeting of microorganisms to growing phagophores prior to autophagosome maturation leading to microbial destruction. The targeting step can be achieved by cytosolic autophagy receptors, which bind on the one hand to the pathogen and on the other hand to LC3, a phagophore membrane-anchored protein. Once entrapped within an autophagosome, bacteria can survive or escape, unless they are rapidly destroyed. Therefore, autophagosome maturation allows the discharge of lysosomal enzymes in autolysosomes, allowing destruction of the bacteria. It is, however, not well known how autophagosomes mature, especially in the context of xenophagy. Recently, the endosomal membrane-bound protein TOM1 and the dynein motor MYO6 have been both shown to be implicated in the transport of endosomes into the vicinity of autophagosomes in order to ensure fusion of autophagosomes with vesicles of the endo/lysosomal pathway. Moreover, the concomitant absence of 3 autophagy receptors, CALCOCO2, TAX1BP1/T6BP, and OPTN/OPTINEURIN, impairs autophagosome biogenesis and maturation. As CALCOCO2 was already shown to have a MYO6 binding domain, we wondered whether CALCOCO2 could also be implicated in autophagosome maturation per se to promote bacterial degradation.We first observed that the binding site of CALCOCO2 to MYO6 was required for cells to control Salmonella Typhimurium intracellular growth. Nevertheless, when the binding of CALCOCO2 to MYO6 was abolished, bacteria were still efficiently targeted to autophagosomes, but yet still able to replicate to levels similar to the one observed in CALCOCO2-depleted cells. Strikingly, in noninfected cells the absence of CALCOCO2 perturbs the autophagy flux, resulting in a strong accumulation of autophagosomes, suggesting a positive role for CALCOCO2 in the autophagosome-lysosome fusion process. Surprisingly, we found that CALCOCO2 binding to LC3C, through its noncanonical LC3 interacting region (CLIR), is not involved in the maturation of autophagosomes. Instead, we identified another motif in the primary sequence of CALCOCO2, which mediates binding to at least LC3A, LC3B, and GABARAPL2 (but not LC3C). We referred to this motif as “LIR-like” as it differs from the canonical LIR motif by the absence of a hydrophobic residue in position X₃. This LIR-like motif was necessary for autophagosome maturation, along with the domain of CALCOCO2 responsible for its binding to MYO6. Eventually, mutation of this LIR-like motif also resulted in an increased Salmonella Typhimurium intracellular proliferation, whereas bacteria were still efficiently targeted within nondegradative autophagosomes. Interestingly, the absence of the autophagy receptor OPTN also led to the accumulation of nondegradative autophagosomes, suggesting that other autophagy receptors could share CALCOCO2 dual functions in xenophagy.Having autophagy receptors ensuring both targeting and degradation of pathogens could be an important evolutionary advantage against infections. Indeed, this mechanism could help to reduce the delay necessary for maturation, thus avoiding adaptation of the pathogen to its new environment (as proposed for Coxiella burnetti, Listeria monocytogenes, and Legionella pneumophila) or its escape from the autophagosome. Conversely, pathogens could avoid autophagy entrapment or autophagic degradation by targeting CALCOCO2 or any other autophagy receptors, which could play similar roles. For instance Chikungunya virus was reported to target CALCOCO2 in human cells leading to increased virus replication. Nevertheless, redundancy among autophagy receptors could also ensure a selective immune advantage against pathogens targeting any one of these receptors.Our results and those from others suggest for now that CALCOCO2 serves as a docking platform for MYO6-bound endosomes, thus facilitating autophagosome maturation (Fig. 1). How this action is coordinated with CALCOCO2 directing pathogens to the phagophore membranes remains unclear. During xenophagy against Salmonella Typhimurium, CALCOCO2 interaction first with LC3C is necessary to further recruit other ATG8 orthologs and ensure the final degradation of bacteria. Since the LIR-like motifs bind several ATG8s, whereas the CLIR motif only mediates binding to LC3C, it is possible that binding of CALCOCO2 to LC3C induces conformational changes and uncovers the LIR-like motif that can be then engaged with other ATG8 orthologs to trigger autophagosome maturation. Moreover, it is still unclear whether the action of CALCOCO2 in autophagosome maturation is coordinated with other partners, such as STX17/SYNTAXIN 17, which is recruited on the external membrane of autophagosomes and regulate fusion with lysosomes. Open in a separate windowFigure 1.Schematic model for the dual role of CALCOCO2 in xenophagy. CALCOCO2 targets bacteria to the phagophore through its LC3C binding site (CLIR motif), and, independently, regulates autophagosome maturation through its LC3A, LC3B, or GABARAPL2 binding site (LIR-like motif) and its MYO6 interacting region.Our findings reveal a new role for the autophagy receptor CALCOCO2 in autophagosome maturation, unravelling another function for CALCOCO2 in cell autonomous defense against pathogens: CALCOCO2 not only targets pathogens to phagophore membranes, but also regulates subsequent maturation of pathogen-containing autophagosomes, thus assuring efficient degradation of autophagy-targeted pathogens.     

Autophagosomes are formed at a distinct cellular structure

Autophagy is characterized by the formation of double-membrane vesicles called autophagosomes, which deliver bulk cytoplasmic material to the lytic compartment of the cell for degradation. Autophagosome formation is initiated by assembly and recruitment of the core autophagy machinery to distinct cellular sites, referred to as phagophore assembly sites (PAS) in yeast or autophagosome formation sites in other organisms. A large number of autophagy proteins involved in the formation of autophagosomes has been identified; however, how the individual components of the PAS are assembled and how they function to generate autophagosomes remains a fundamental question. Here, we highlight recent studies that provide molecular insights into PAS organization and the role of the endoplasmic reticulum and the vacuole in autophagosome formation.     

Coronavirus NSP6 restricts autophagosome expansion

Autophagy is a cellular response to starvation that generates autophagosomes to carry long-lived proteins and cellular organelles to lysosomes for degradation. Activation of autophagy by viruses can provide an innate defense against infection, and for (+) strand RNA viruses autophagosomes can facilitate assembly of replicase proteins. We demonstrated that nonstructural protein (NSP) 6 of the avian coronavirus, infectious bronchitis virus (IBV), generates autophagosomes from the ER. A statistical analysis of MAP1LC3B puncta showed that NSP6 induced greater numbers of autophagosomes per cell compared with starvation, but the autophagosomes induced by NSP6 had smaller diameters compared with starvation controls. Small diameter autophagosomes were also induced by infection of cells with IBV, and by NSP6 proteins of MHV and SARS and NSP5, NSP6, and NSP7 of arterivirus PRRSV. Analysis of WIPI2 puncta induced by NSP6 suggests that NSP6 limits autophagosome diameter at the point of omegasome formation. IBV NSP6 also limited autophagosome and omegasome expansion in response to starvation and Torin1 and could therefore limit the size of autophagosomes induced following inhibition of MTOR signaling, as well as those induced independently by the NSP6 protein itself. MAP1LC3B-puncta induced by NSP6 contained SQSTM1, which suggests they can incorporate autophagy cargos. However, NSP6 inhibited the autophagosome/lysosome expansion normally seen following starvation. Taken together the results show that coronavirus NSP6 proteins limit autophagosome expansion, whether they are induced directly by the NSP6 protein, or indirectly by starvation or chemical inhibition of MTOR signaling. This may favor coronavirus infection by compromising the ability of autophagosomes to deliver viral components to lysosomes for degradation.     

Monitoring autophagy in wheat living cells by visualization of fluorescence protein-tagged ATG8

Autophagy is a highly conserved eukaryotic degradation process during which bulk cytoplasmic materials are transported by double-membrane autophagosomes into the vacuole for degradation. Methods of monitoring autophagy are indispensable in studying the mechanism and functions of autophagy. AuTophaGy-related protein 8 (ATG8) functions in autophagosome assembly by decorating on autophagic membranes, and the inner membrane-bound ATG8 proteins enter the vacuole via active autophagy flux. Fluorescence protein (FP)-tagged forms of ATG8 have been explored as visual markers to monitor autophagy in animals and several plant species. Here, we evaluated and modified this FP-ATG8-based autophagy monitoring method in wheat (Triticum aestivum L.) by fluorescence observation of green fluorescence protein (GFP)-tagged and Discosoma red fluorescent protein (DsRED)-tagged forms of one wheat ATG8, TaATG8h, in wheat mesophyll protoplasts. Under a nutrient-starvation condition, punctate GFP/DsRED- TaATG8h fluorescence representing autophagosomes was clearly observed in the cytoplasm. The accumulation of GFP-TaATG8h-labeled autophagosomes was impaired by the autophagosome biogenesis inhibitor 3-methyladenine but enhanced by the vacuolar degradation inhibitor concanamycin A. In addition, accumulated spreading fluorescence was observed in the vacuole, indicating active autophagy fluxes which led to continuous degradation of GFP/DsRED-TaATG8h fusions and release of protease-tolerant free GFP/DsRED proteins in the vacuole. To observe FP-tagged TaATG8h in other types of wheat cell, we also expressed GFP-TaATG8h in leaf epidermal cells. Consistent with its performance in protoplasts, GFP-TaATG8h showed punctate fluorescence representing autophagosomes in leaf epidermal cells. Taken together, our results proved the feasibility of using FP-tagged ATG8 to monitor both autophagosome accumulation and autophagy flux in living wheat cells.     

Toward an understanding of autophagosome-lysosome fusion: The unsuspected role of ATG14

Although largely overlooked relative to the process of phagophore formation, the mechanism through which autophagosomes fuse with lysosomes is a critical aspect of macroautophagy that is not fully understood. In particular, this step must be carefully regulated to prevent premature fusion of an incomplete autophagosome (that is, a phagophore) with a lysosome, because such an event would not allow access of the partially sequestered cargo to the lysosome lumen. The identification of the autophagosome-associated SNARE protein STX17 (syntaxin 17) provided some clue in the understanding of this process. STX17 is recruited specifically to mature autophagosomes, and functions in mediating autophagosome-lysosome fusion by forming a complex with the Qbc SNARE SNAP29 and the lysosomal R-SNARE VAMP8. Additionally, STX17 plays a role in the early events of autophagy by interacting with the phosphatidylinositol 3-kinase complex component ATG14. Upon autophagy induction STX17 is strictly required for ATG14 recruitment to the ER-mitochondria contact sites, a critical step for the assembly of the phagophore and therefore for autophagosome formation. In their recent paper, Diao and collaborators now show that the ATG14-STX17-SNAP29 interaction mediates autophagosome-lysosome tethering and fusion events, thus revealing a novel function of ATG14 in the later steps of the autophagy pathway.     

Coronavirus NSP6 restricts autophagosome expansion

Autophagy is a cellular response to starvation that generates autophagosomes to carry long-lived proteins and cellular organelles to lysosomes for degradation. Activation of autophagy by viruses can provide an innate defense against infection, and for (+) strand RNA viruses autophagosomes can facilitate assembly of replicase proteins. We demonstrated that nonstructural protein (NSP) 6 of the avian coronavirus, infectious bronchitis virus (IBV), generates autophagosomes from the ER. A statistical analysis of MAP1LC3B puncta showed that NSP6 induced greater numbers of autophagosomes per cell compared with starvation, but the autophagosomes induced by NSP6 had smaller diameters compared with starvation controls. Small diameter autophagosomes were also induced by infection of cells with IBV, and by NSP6 proteins of MHV and SARS and NSP5, NSP6, and NSP7 of arterivirus PRRSV. Analysis of WIPI2 puncta induced by NSP6 suggests that NSP6 limits autophagosome diameter at the point of omegasome formation. IBV NSP6 also limited autophagosome and omegasome expansion in response to starvation and Torin1 and could therefore limit the size of autophagosomes induced following inhibition of MTOR signaling, as well as those induced independently by the NSP6 protein itself. MAP1LC3B-puncta induced by NSP6 contained SQSTM1, which suggests they can incorporate autophagy cargos. However, NSP6 inhibited the autophagosome/lysosome expansion normally seen following starvation. Taken together the results show that coronavirus NSP6 proteins limit autophagosome expansion, whether they are induced directly by the NSP6 protein, or indirectly by starvation or chemical inhibition of MTOR signaling. This may favor coronavirus infection by compromising the ability of autophagosomes to deliver viral components to lysosomes for degradation.     

Foot-and-Mouth Disease Virus Induces Autophagosomes during Cell Entry via a Class III Phosphatidylinositol 3-Kinase-Independent Pathway

Autophagy is an intracellular pathway that can contribute to innate antiviral immunity by delivering viruses to lysosomes for degradation or can be beneficial for viruses by providing specialized membranes for virus replication. Here, we show that the picornavirus foot-and-mouth disease virus (FMDV) induces the formation of autophagosomes. Induction was dependent on Atg5, involved processing of LC3 to LC3II, and led to a redistribution of LC3 from the cytosol to punctate vesicles indicative of authentic autophagosomes. Furthermore, FMDV yields were reduced in cells lacking Atg5, suggesting that autophagy may facilitate FMDV infection. However, induction of autophagosomes by FMDV appeared to differ from starvation, as the generation of LC3 punctae was not inhibited by wortmannin, implying that FMDV-induced autophagosome formation does not require the class III phosphatidylinositol 3-kinase (PI3-kinase) activity of vps34. Unlike other picornaviruses, for which there is strong evidence that autophagosome formation is linked to expression of viral nonstructural proteins, FMDV induced autophagosomes very early during infection. Furthermore, autophagosomes could be triggered by either UV-inactivated virus or empty FMDV capsids, suggesting that autophagosome formation was activated during cell entry. Unlike other picornaviruses, FMDV-induced autophagosomes did not colocalize with the viral 3A or 3D protein. In contrast, ∼50% of the autophagosomes induced by FMDV colocalized with VP1. LC3 and VP1 also colocalized with the cellular adaptor protein p62, which normally targets ubiquitinated proteins to autophagosomes. These results suggest that FMDV induces autophagosomes during cell entry to facilitate infection, but not to provide membranes for replication.     

Ubiquilins accelerate autophagosome maturation and promote cell survival during nutrient starvation

Ubiquilins (UBQLN), a family of adaptor proteins with partial homology with ubiquitin, are proposed to facilitate proteasomal degradation of ubiquitinated substrates. We now demonstrate a novel role for UBQLN in promoting autophagosome maturation during nutrient deprivation. Ectopic expression of UBQLN protects cells against starvation-induced cell death, while depletion renders cells more susceptible. This protective function requires the essential autophagy regulators, Atg5 and Atg7. The ubiquitin-associated (UBA) domain of UBQLN is required for its association with autophagosomes as well as for its prosurvival functions. Remarkably, during starvation-induced autophagy, UBQLN promotes the fusion of early autophagosomes with lysosomes. Overall, this work illustrates an important function for UBQLN in cell survival during nutrient starvation, which requires a newly recognized function for UBQLN in autophagosome maturation.     

Regulation of macroautophagy by mTOR and Beclin 1 complexes

Macroautophagy or autophagy is a vacuolar degradative pathway terminating in the lysosomal compartment after forming a cytoplasmic vacuole or autophagosome that engulfs macromolecules and organelles. The original discovery that ATG (AuTophaGy related) genes in yeast are involved in the formation of autophagosomes has greatly increased our knowledge of the molecular basis of autophagy, and its role in cell function that extends far beyond non-selective degradation. The regulation of autophagy by signaling pathways overlaps the control of cell growth, proliferation, cell survival and death. The evolutionarily conserved TOR (Target of Rapamycin) kinase complex 1 plays an important role upstream of the Atg1 complex in the control of autophagy by growth factors, nutrients, calcium signaling and in response to stress situations, including hypoxia, oxidative stress and low energy. The Beclin 1 (Atg6) complex, which is involved in the initial step of autophagosome formation, is directly targeted by signaling pathways. Taken together, these data suggest that multiple signaling checkpoints are involved in regulating autophagosome formation.     

ATG14 controls SNARE-mediated autophagosome fusion with a lysosome

Autophagosome fusion with a lysosome constitutes the last barrier for autophagic degradation. It is speculated that this fusion process is precisely and tightly regulated. Recent genetic evidence suggests that a set of SNARE proteins, including STX17, SNAP29, and VAMP8, are essential for the fusion between autophagosomes and lysosomes. However, it remains unclear whether these SNAREs are fusion competent and how their fusogenic activity is specifically regulated during autophagy. Using a combination of biochemical, cell biology, and genetic approaches, we demonstrated that fusogenic activity of the autophagic SNARE complex is temporally and spatially controlled by ATG14/Barkor/Atg14L, an essential autophagy-specific regulator of the class III phosphatidylinositol 3-kinase complex (PtdIns3K). ATG14 directly binds to the STX17-SNAP29 binary complex on autophagosomes and promotes STX17-SNAP29-VAMP8-mediated autophagosome fusion with lysosomes. ATG14 homo-oligomerization is required for SNARE binding and fusion promotion, but is dispensable for PtdIns3K stimulation and autophagosome biogenesis. Consequently, ATG14 homo-oligomerization is required for autophagosome fusion with a lysosome, but is dispensable for autophagosome biogenesis. These data support a key role of ATG14 in controlling autophagosome fusion with a lysosome.     

Unraveling the role of myosin in forming autophagosomes

Macroautophagy (hereafter autophagy) is a membrane-mediated catabolic process that occurs in response to a variety of intra- and extra-cellular stresses. It is characterized by the formation of specialized double-membrane vesicles, autophagosomes, which engulf organelles and long-lived proteins, and in turn fuse with lysosomes for degradation and recycling. How autophagosomes emerge is still unclear. The Atg1 kinase plays a crucial role in the induction of autophagosome formation. While several Atg (autophagy-related) proteins have been associated with, and have been found to regulate, Atg1 kinase activity, the downstream targets of Atg1 that trigger autophagy remain unknown. Our recent studies have identified a myosin light chain kinase (MLCK)-like kinase as the Atg1 kinase effector that induces the activation of myosin II, and have found it to be required for autophagosome formation during nutrient deprivation. We further demonstrated that Atg1-mediated myosin II activation is crucial for the movement of the Atg9 transmembrane protein between the Golgi and the forming autophagosome, which provides a membrane source for the formation of autophagosomes during starvation.