Dissection of the autophagosome maturation process by a novel reporter protein, tandem fluorescent-tagged LC3

During the process of autophagy, autophagosomes undergo a maturation process consisting of multiple fusions with endosomes and lysosomes, which provide an acidic environment and digestive function to the interior of the autophagosome. Here we found that a fusion protein of monomeric red-fluorescence protein and LC3, the most widely used marker for autophagosomes, exhibits a quite different localization pattern from that of GFP-LC3. GFP-LC3 loses fluorescence due to lysosomal acidic and degradative conditions but mRFP-LC3 does not, indicating that the latter can label the autophagic compartments both before and after fusion with lysosomes. Taking advantage of this property, we devised a novel method for dissecting the maturation process of autophagosomes. mRFP-GFP tandem fluorescent-tagged LC3 (tfLC3) showed a GFP and mRFP signal before the fusion with lysosomes, and exhibited only the mRFP signal subsequently. Using this method, we provided evidence that overexpression of a dominant negative form of Rab7 prevented the fusion of autophagosomes with lysosomes, suggesting that Rab7 is involved in this step. This method will be of general utility for analysis of the autophagosome maturation process.     

Dissection of the Autophagosome Maturation Process by a Novel Reporter Protein,Tandem Fluorescent-Tagged LC3

During the process of autophagy, autophagosomes undergo a maturation process consisting of multiple fusions with endosomes and lysosomes, which provide an acidic environment and digestive function to the interior of the autophagosome. Here we found that a fusion protein of monomeric Red-fluorescence protein and LC3, the most widely used marker for autophagosomes, exhibits a quite different localization pattern from that of GFP-LC3. GFP-LC3 loses fluorescence due to lysosomal acidic and degradative conditions but mRFP-LC3 does not, indicating that the latter can label the autophagic compartments both before and after fusion with lysosomes. Taking advantage of this property, we devised a novel method for dissecting the maturation process of autophagosomes. mRFP-GFP tandem fluorescent-tagged LC3 (tfLC3) showed a GFP and mRFP signal before the fusion with lysosomes, and exhibited only the mRFP signal subsequently. Using this method, we provided evidence that overexpression of a dominant negative form of Rab7 prevented the fusion of autophagosomes with lysosomes, suggesting that Rab7 is involved in this step. This method will be of general utility for analysis of the autophagosome maturation process.     

BORC coordinates encounter and fusion of lysosomes with autophagosomes

Whereas the mechanisms involved in autophagosome formation have been extensively studied for the past 2 decades, those responsible for autophagosome-lysosome fusion have only recently begun to garner attention. In this study, we report that the multisubunit BORC complex, previously implicated in kinesin-dependent movement of lysosomes toward the cell periphery, is required for efficient autophagosome-lysosome fusion. Knockout (KO) of BORC subunits causes not only juxtanuclear clustering of lysosomes, but also increased levels of the autophagy protein LC3B-II and the receptor SQSTM1. Increases in LC3B-II occur without changes in basal MTORC1 activity and autophagy initiation. Instead, LC3B-II accumulation largely results from decreased lysosomal degradation. Further experiments show that BORC KO impairs both the encounter and fusion of autophagosomes with lysosomes. Reduced encounters result from an inability of lysosomes to move toward the peripheral cytoplasm, where many autophagosomes are formed. However, BORC KO also reduces the recruitment of the HOPS tethering complex to lysosomes and assembly of the STX17-VAMP8-SNAP29 trans-SNARE complex involved in autophagosome-lysosome fusion. Through these dual roles, BORC integrates the kinesin-dependent movement of lysosomes toward autophagosomes with HOPS-dependent autophagosome-lysosome fusion. These findings reveal a requirement for lysosome dispersal in autophagy that is independent of changes in MTORC1 signaling, and identify BORC as a novel regulator of autophagosome-lysosome fusion.     

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.     

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.     

A mammalian autophagosome maturation mechanism mediated by TECPR1 and the Atg12-Atg5 conjugate

Autophagy is a major catabolic pathway in eukaryotes associated with a broad spectrum of human diseases. In autophagy, autophagosomes carrying cellular cargoes fuse with lysosomes for degradation. However, the molecular mechanism underlying autophagosome maturation is largely unknown. Here we report that TECPR1 binds to the Atg12-Atg5 conjugate and phosphatidylinositol 3-phosphate (PtdIns[3]P) to promote autophagosome-lysosome fusion. TECPR1 and Atg16 form mutually exclusive complexes with the Atg12-Atg5 conjugate, and TECPR1 binds PtdIns(3)P upon association with the Atg12-Atg5 conjugate. Strikingly, TECPR1 localizes to and recruits Atg5 to autolysosome membrane. Consequently, elimination of TECPR1 leads to accumulation of autophagosomes and blocks autophagic degradation of LC3-II and p62. Finally, autophagosome maturation marked by GFP-mRFP-LC3 is defective in TECPR1-deficient cells. Thus, we propose that the concerted interactions among TECPR1, Atg12-Atg5, and PtdIns(3)P provide the fusion specificity between autophagosomes and lysosomes and that the assembly of this complex initiates the autophagosome maturation process.     

Autophagosome precursor maturation requires homotypic fusion

Autophagy is a catabolic process in which lysosomes degrade intracytoplasmic contents transported in double-membraned autophagosomes. Autophagosomes are formed by the elongation and fusion of phagophores, which can be derived from preautophagosomal structures coming from the plasma membrane and other sites like the endoplasmic reticulum and mitochondria. The mechanisms by which preautophagosomal structures elongate their membranes and mature toward fully formed autophagosomes still remain unknown. Here, we show that the maturation of the early Atg16L1 precursors requires homotypic fusion, which is essential for subsequent autophagosome formation. Atg16L1 precursor homotypic fusion depends on the SNARE protein VAMP7 together with partner SNAREs. Atg16L1 precursor homotypic fusion is a critical event in the early phases of autophagy that couples membrane acquisition and autophagosome biogenesis, as this step regulates the size of the vesicles, which in turn appears to influence their subsequent maturation into LC3-positive autophagosomes.     

Dissecting the involvement of LC3B and GATE-16 in p62 recruitment into autophagosomes

Autophagy is a major intracellular trafficking pathway that delivers proteins and organelles from the cytoplasm into lysosomes for consequential degradation and recycling. Mammalian Atg8s are key autophagic factors that undergo a unique ubiquitin-like conjugation to the lipid phase of the autophagosomal membrane. In addition to their activity in autophagosome formation, several Atg8s directly bind p62/SQSTM1. Here we show that LC3 and GATE-16 differ in their mode of p62 binding. While the soluble form of both LC3 and GATE-16 bind p62, only the lipidated form of LC3 is directly involved in p62 recruitment into autophagosomes. Moreover, by utilizing chimeras of LC3 and GATE-16 where their N-terminus was swapped, we determined the regions responsible for this differential binding. Accordingly, we found that the chimera of GATE-16 containing the LC3 N-terminal region acts similarly to wild-type LC3 in recruiting p62 into autophagosomes. We therefore propose that LC3 is responsible for the final stages of p62 incorporation into autophagosomes, a process selectively mediated by its N-terminus.     

Human GABARAP can restore autophagosome biogenesis in a C. elegans lgg-1 mutant

We recently described in C. elegans embryos, the acquisition of specialized functions for orthologs of yeast Atg8 (e.g., mammalian MAP1LC3/LC3) in allophagy, a selective and developmentally regulated autophagic process. During the formation of double-membrane autophagosomes, the ubiquitin-like Atg8/LC3 proteins are recruited to the membrane through a lipidation process. While at least 6 orthologs and paralogs are present in mammals, C. elegans only possesses 2 orthologs, LGG-1 and LGG-2, corresponding to the GABARAP-GABARAPL2/GATE-16 and the MAP1LC3 families, respectively. During allophagy, LGG-1 acts upstream of LGG-2 and is essential for autophagosome biogenesis, whereas LGG-2 facilitates their maturation. We demonstrated that LGG-2 directly interacts with the HOPS complex subunit VPS-39, and mediates the tethering between autophagosomes and lysosomes, which also requires RAB-7. In the present addendum, we compared the localization of autophagosomes, endosomes, amphisomes, and lysosomes in vps-39, rab-7, and lgg-2 depleted embryos. Our results suggest that lysosomes interact with autophagosomes or endosomes through a similar mechanism. We also performed a functional complementation of an lgg-1 null mutant with human GABARAP, its closer homolog, and showed that it localizes to autophagosomes and can rescue LGG-1 functions in the early embryo.     

Development of LC3/GABARAP sensors containing a LIR and a hydrophobic domain to monitor autophagy

Macroautophagy allows for bulk degradation of cytosolic components in lysosomes. Overexpression of GFP/RFP-LC3/GABARAP is commonly used to monitor autophagosomes, a hallmark of autophagy, despite artifacts related to their overexpression. Here, we developed new sensors that detect endogenous LC3/GABARAP proteins at the autophagosome using an LC3-interacting region (LIR) and a short hydrophobic domain (HyD). Among HyD-LIR-GFP sensors harboring LIR motifs of 34 known LC3-binding proteins, HyD-LIR(TP)-GFP using the LIR motif from TP53INP2 allowed detection of all LC3/GABARAPs-positive autophagosomes. However, HyD-LIR(TP)-GFP preferentially localized to GABARAP/GABARAPL1-positive autophagosomes in a LIR-dependent manner. In contrast, HyD-LIR(Fy)-GFP using the LIR motif from FYCO1 specifically detected LC3A/B-positive autophagosomes. HyD-LIR(TP)-GFP and HyD-LIR(Fy)-GFP efficiently localized to autophagosomes in the presence of endogenous LC3/GABARAP levels and without affecting autophagic flux. Both sensors also efficiently localized to MitoTracker-positive damaged mitochondria upon mitophagy induction. HyD-LIR(TP)-GFP allowed live-imaging of dynamic autophagosomes upon autophagy induction. These novel autophagosome sensors can thus be widely used in autophagy research.     

Human GABARAP can restore autophagosome biogenesis in a C. elegans lgg-1 mutant

We recently described in C. elegans embryos, the acquisition of specialized functions for orthologs of yeast Atg8 (e.g., mammalian MAP1LC3/LC3) in allophagy, a selective and developmentally regulated autophagic process. During the formation of double-membrane autophagosomes, the ubiquitin-like Atg8/LC3 proteins are recruited to the membrane through a lipidation process. While at least 6 orthologs and paralogs are present in mammals, C. elegans only possesses 2 orthologs, LGG-1 and LGG-2, corresponding to the GABARAP-GABARAPL2/GATE-16 and the MAP1LC3 families, respectively. During allophagy, LGG-1 acts upstream of LGG-2 and is essential for autophagosome biogenesis, whereas LGG-2 facilitates their maturation. We demonstrated that LGG-2 directly interacts with the HOPS complex subunit VPS-39, and mediates the tethering between autophagosomes and lysosomes, which also requires RAB-7. In the present addendum, we compared the localization of autophagosomes, endosomes, amphisomes, and lysosomes in vps-39, rab-7, and lgg-2 depleted embryos. Our results suggest that lysosomes interact with autophagosomes or endosomes through a similar mechanism. We also performed a functional complementation of an lgg-1 null mutant with human GABARAP, its closer homolog, and showed that it localizes to autophagosomes and can rescue LGG-1 functions in the early embryo.     

Dissecting the involvement of LC3B and GATE-16 in p62 recruitment into autophagosomes

Autophagy is a major intracellular trafficking pathway that delivers proteins and organelles from the cytoplasm into lysosomes for consequential degradation and recycling. Mammalian Atg8s are key autophagic factors that undergo a unique ubiquitin-like conjugation to the lipid phase of the autophagosomal membrane. In addition to their activity in autophagosome formation, several Atg8s directly bind p62/SQSTM1. Here we show that LC3 and GATE-16 differ in their mode of p62 binding. While the soluble form of both LC3 and GATE-16 bind p62, only the lipidated form of LC3 is directly involved in p62 recruitment into autophagosomes. Moreover, by utilizing chimeras of LC3 and GATE-16 where their N-terminus was swapped, we determined the regions responsible for this differential binding. Accordingly, we found that the chimera of GATE-16 containing the LC3 N-terminal region acts similarly to wild-type LC3 in recruiting p62 into autophagosomes. We therefore propose that LC3 is responsible for the final stages of p62 incorporation into autophagosomes, a process selectively mediated by its N-terminus.     

Differing susceptibility to autophagic degradation of two LC3-binding proteins: SQSTM1/p62 and TBC1D25/OATL1

MAP1LC3/LC3 (a mammalian ortholog family of yeast Atg8) is a ubiquitin-like protein that is essential for autophagosome formation. LC3 is conjugated to phosphatidylethanolamine on phagophores and ends up distributed both inside and outside the autophagosome membrane. One of the well-known functions of LC3 is as a binding partner for receptor proteins, which target polyubiquitinated organelles and proteins to the phagophore through direct interaction with LC3 in selective autophagy, and their LC3-binding ability is essential for degradation of the polyubiquitinated substances. Although a number of LC3-binding proteins have been identified, it is unknown whether they are substrates of autophagy or how their interaction with LC3 is regulated. We previously showed that one LC3-binding protein, TBC1D25/OATL1, plays an inhibitory role in the maturation step of autophagosomes and that this function depends on its binding to LC3. Interestingly, TBC1D25 seems not to be a substrate of autophagy, despite being present on the phagophore. In this study we investigated the molecular basis for the escape of TBC1D25 from autophagic degradation by performing a chimeric analysis between TBC1D25 and SQSTM1/p62 (sequestosome 1), and the results showed that mutant TBC1D25 with an intact LC3-binding site can become an autophagic substrate when TBC1D25 is forcibly oligomerized. In addition, an ultrastructural analysis showed that TBC1D25 is mainly localized outside autophagosomes, whereas an oligomerized TBC1D25 mutant rather uniformly resides both inside and outside the autophagosomes. Our findings indicate that oligomerization is a key factor in the degradation of LC3-binding proteins and suggest that lack of oligomerization ability of TBC1D25 results in its asymmetric localization at the outer autophagosome membrane.     

Porcine reproductive and respiratory syndrome virus induces autophagy to promote virus replication

An increasing number of studies demonstrate that autophagy, an intrinsic mechanism that can degrade cytoplasmic components, is involved in the infection processes of a variety of pathogens. It can be hijacked by various viruses to facilitate their replication. In this study, we found that PRRSV infection significantly increases the number of double- or single-membrane vesicles in the cytoplasm of host cells in ultrastructural analysis. Our results showed the LC3-I was converted into LC3-II after virus infection, suggesting the autophagy machinery was activated. We further used pharmacological agents and shRNAs to confirm that autophagy promoted the replication of PRRSV in host cells. Confocal microscopy analysis showed that PRRSV inhibited the fusion between autophagosomes and lysosomes, suggesting that PRRSV induced incomplete autophagy. This suppression caused the accumulation of autophagosomes which may serve as replication site to enhance PRRSV replication. It has been shown that NSP2 and NSP3 of arterivirus are two components of virus replication complex. We also found in our studies that NSP2 colocalized with LC3 in MARC-145 cells by performing confocal microscopy analysis and continuous density gradient centrifugation. Our studies presented here indicated that autophagy was activated during PRRSV infection and enhanced PRRSV replication in host cells by preventing autophagosome and lysosome fusion.     

A quantitative assay for the monitoring of autophagosome accumulation in different phases of the cell cycle

Macroautophagy is a process accompanied by the formation of double-membrane vesicles known as autophagosomes. Although in recently published reviews various methods for the detection of autophagosomes were described, a reliable technique for the automated quantitative evaluation of autophagosome accumulation is still lacking. Here we developed a new assay which is based on the fact that the number of autophagosomes is correlated with the amount of the LC3-II protein, which is specifically associated with autophagosomal membranes. Monitoring of autophagosome: accumulation was performed by extracting the membrane-unbound LC3-I form of the protein from cells, followed by flow cytometric detection of the autophagosomal membrane-associated fraction of LC3-II. This assay could be used for monitoring autophagosomes by flow cytometry utilizing immunostaining with the antibody against the LC3 protein. It is also suitable for analysis of: cells expressing GFP-LC3. We showed that co-staining with propidium iodide allows detection of basal level of autophagosomes in different phases of the cell cycle. Autophagy activators, such as: rapamycin or cell starvation, were able to induce accumulation of autophagosomes in G0/G1, S and G2/M phases. Thus, utilization of this assay simplifies monitoring of autophagosome accumulation induced by different activators or inhibitors of macroautophagy and it is suggested as being useful in the detection of autophagosomes in different phases of the cell cycle.     

A quantitative assay for the monitoring of autophagosome accumulation in different phases of the cell cycle

Macroautophagy is a process accompanied by the formation of double-membrane vesicles known as autophagosomes. Although in recently published reviews various methods for the detection of autophagosomes were described, a reliable technique for the automated quantitative evaluation of autophagosome accumulation is still lacking. Here we developed a new assay which is based on the fact that the number of autophagosomes is correlated with the amount of the LC3-II protein, which is specifically associated with autophagosomal membranes. Monitoring of autophagosome accumulation was performed by extracting the membrane-unbound LC3-I form of the protein from cells, followed by flow cytometric detection of the autophagosomal membrane-associated fraction of LC3-II. This assay could be used for monitoring autophagosomes by flow cytometry utilizing immunostaining with the antibody against the LC3 protein. It is also suitable for analysis of

cells expressing GFP-LC3. We showed that co-staining with propidium iodide allows detection of basal level of autophagosomes in different phases of the cell cycle. Autophagy activators, such as rapamycin or cell starvation, were able to induce accumulation of autophagosomes in G₀/G₁, S and G₂/M phases. Thus, utilization of this assay simplifies monitoring of autophagosome accumulation induced by different activators or inhibitors of macroautophagy and it is suggested as being useful in the detection of autophagosomes in different phases of the cell cycle.     

Bulk autophagy,but not mitophagy,is increased in cellular model of mitochondrial disease

Oxidative phosphorylation system (OXPHOS) deficiencies are rare diseases but constitute the most frequent inborn errors of metabolism. We analyzed the autophagy route in 11 skin fibroblast cultures derived from patients with well characterized and distinct OXPHOS defects. Mitochondrial membrane potential determination revealed a tendency to decrease in 5 patients' cells but reached statistical significance only in 2 of them. The remaining cells showed either no change or a slight increase in this parameter. Colocalization analysis of mitochondria and autophagosomes failed to show evidence of increased selective elimination of mitochondria but revealed more intense autophagosome staining in patients' fibroblasts compared with controls. Despite the absence of increased mitophagy, Parkin recruitment to mitochondria was detected in both controls' and patients' cells and was slightly higher in cells harboring complex I defects. Western blot analysis of the autophagosome marker LC3B, confirmed significantly higher levels of the protein bound to autophagosomes, LC3B-II, in patients' cells, suggesting an increased bulk autophagy in OXPHOS defective fibroblasts. Inhibition of lysosomal proteases caused significant accumulation of LC3B-II in control cells, whereas in patients' cells this phenomenon was less pronounced. Electron microscopy studies showed higher content of late autophagic vacuoles and lysosomes in OXPHOS defective cells, accompanied by higher levels of the lysosomal marker LAMP-1. Our findings suggest that in OXPHOS deficient fibroblasts autophagic flux could be partially hampered leading to an accumulation of autophagic vacuoles and lysosomes.     

Using LC3 to monitor autophagy flux in the retinal pigment epithelium

Autophagy is a highly conserved housekeeping pathway that plays a critical role in the removal of aged or damaged intracellular organelles and their delivery to lysosomes for degradation.^1,2 Autophagy begins with the formation of membranes arising in part from the endoplasmic reticulum, that elongate and fuse engulfing cytoplasmic constituents into a classic double-membrane bound nascent autophagosome. These early autophagosomes undergo a stepwise maturation process to form the late autophagosome or amphisome that ultimately fuses with a lysosome. Efficient autophagy is dependent on an equilibrium between the formation and elimination of autophagosomes; thus, a deficit in any part of this pathway will cause autophagic dysfunction. Autophagy plays a role in aging and age-related diseases. ^1,2,7 However, few studies of autophagy in retinal disease have been reported.

Recent studies show that autophagy and changes in lysosomal activity are associated with both retinal aging and age-related macular degeneration (AMD).^3,4 This article describes methods which employ the target protein LC3 to monitor autophagic flux in retinal pigment epithelial cells. During autophagy, the cytosolic form of LC3 (LC3-I) is processed and recruited to the phagophore where it undergoes site specific proteolysis and lipidation near the C terminus to form LC3-II.⁵ Monitoring the formation of cellular autophagosome puncta containing LC3 and measuring the ratio of LC3-II to LC3-I provides the ability to monitor autophagy flux in the retina.     

Thapsigargin distinguishes membrane fusion in the late stages of endocytosis and autophagy

A close relationship exists between autophagy and endocytosis with both sharing lysosomes as their common end-point. Autophagy even requires a functional endocytic pathway. The point at which the two pathways merge, i.e., fusion of autophagosomes and endosomes with lysosomes is poorly understood. Early work in yeast and more recent studies in mammalian cells suggested that conventional membrane trafficking pathways control the fusion of autophagosomes with lysosomes; Rab GTPases are required to recruit tethering proteins which in turn coordinate the SNARE family of proteins that directly drive membrane fusion. Some components required for endosomes to fuse with lysosomes are also shared by autophagosomes; both are thought to require the GTPase Rab7 and the homotypic fusion and vacuole protein sorting (HOPS) complex. Essentially, the autophagosome becomes endosome-like, allowing it to recruit the common fusion machinery to deliver its contents to the lysosome. This raises an interesting question of how the cell determines when the autophagosome is ready to fuse with the endocytic system and bestows upon it the properties required to recruit the fusion machinery. Our recent work has highlighted this conundrum and shown that autophagosome fusion with lysosomes has specific distinctions from the parallel endosomal-lysosomal pathway.