Rab11 facilitates cross-talk between autophagy and endosomal pathway through regulation of Hook localization

During autophagy, double-membrane autophagosomes deliver sequestered cytoplasmic content to late endosomes and lysosomes for degradation. The molecular mechanism of autophagosome maturation is still poorly characterized. The small GTPase Rab11 regulates endosomal traffic and is thought to function at the level of recycling endosomes. We show that loss of Rab11 leads to accumulation of autophagosomes and late endosomes in Drosophila melanogaster. Rab11 translocates from recycling endosomes to autophagosomes in response to autophagy induction and physically interacts with Hook, a negative regulator of endosome maturation. Hook anchors endosomes to microtubules, and we show that Rab11 facilitates the fusion of endosomes and autophagosomes by removing Hook from mature late endosomes and inhibiting its homodimerization. Thus induction of autophagy appears to promote autophagic flux by increased convergence with the endosomal pathway.     

Early endosomes and endosomal coatomer are required for autophagy

Autophagy, an intracellular degradative pathway, maintains cell homeostasis under normal and stress conditions. Nascent double-membrane autophagosomes sequester and enclose cytosolic components and organelles, and subsequently fuse with the endosomal pathway allowing content degradation. Autophagy requires fusion of autophagosomes with late endosomes, but it is not known if fusion with early endosomes is essential. We show that fusion of AVs with functional early endosomes is required for autophagy. Inhibition of early endosome function by loss of COPI subunits (β′, β, or α) results in accumulation of autophagosomes, but not an increased autophagic flux. COPI is required for ER-Golgi transport and early endosome maturation. Although loss of COPI results in the fragmentation of the Golgi, this does not induce the formation of autophagosomes. Loss of COPI causes defects in early endosome function, as both transferrin recycling and EGF internalization and degradation are impaired, and this loss of function causes an inhibition of autophagy, an accumulation of p62/SQSTM-1, and ubiquitinated proteins in autophagosomes.     

In vitro reconstitution of fusion between immature autophagosomes and endosomes

Autophagy is a highly conserved degradative pathway whereby a double membrane engulfs cytoplasmic constituents to form an autophagic vacuole or autophagosome. An essential requirement for efficient autophagy is the acquisition of an adequate degradative capacity by the autophagosomes. To acquire this capacity the immature autophagic vacuoles (AVis) obtain lysosomal hydrolases by fusion with endosomes. The current models suggest that at least two types of endosomes, early and late, fuse with AVis to form mature, degradative AVds. This fusion and maturation requires proteins also involved in endosome maturation such as Rab7. However, it is not known if there are molecular requirements unique to AVi-endosome fusion. To identify and investigate the molecular requirements of this fusion we developed a cell-free fusion assay based on content mixing, which occurs after fusion of isolated AVis and different endosomal fractions. Our assay shows that isolated AVis can fuse to a similar extent in vitro with both early and late endosomes. Furthermore, fusion between autophagosomes and endosomes requires cytosolic and endosomal proteins, but does not show a nucleotide-dependence, and is partially N-ethylmaleimide sensitive. We also demonstrate that the lipidated form of the autophagosomal protein LC3 is dispensable for this fusion event.     

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.     

Autophagy and formation of tubulovesicular autophagosomes provide a barrier against nonviral gene delivery

Cationic liposome (lipoplex) and polymer (polyplex)-based vectors have been developed for nonviral gene delivery. These vectors bind DNA and enter cells via endosomes, but intracellular transfer of DNA to the nucleus is inefficient. Here we show that lipoplex and polyplex vectors enter cells in endosomes, activate autophagy and generate tubulovesicular autophagosomes. Activation of autophagy was dependent on ATG5, resulting in lipidation of LC3, but did not require the PtdIns 3-kinase activity of PIK3C3/VPS34. The autophagosomes generated by lipoplex fused with each other, and with endosomes, resulting in the delivery of vectors to large tubulovesicular autophagosomes, which accumulated next to the nucleus. The tubulovesicular autophagosomes contained autophagy receptor protein SQSTM1/p62 and ubiquitin, suggesting capture of autophagy cargoes, but fusion with lysosomes was slow. Gene delivery and expression from both lipoplex and polyplex increased 8-fold in atg5^?/? cells unable to generate tubulovesicular autophagosomes. Activation of autophagy and capture within tubulovesicular autophagosomes therefore provides a new cellular barrier against efficient gene transfer and should be considered when designing efficient nonviral gene delivery vectors.     

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.     

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.     

Beclin1-binding UVRAG targets the class C Vps complex to coordinate autophagosome maturation and endocytic trafficking

Autophagic and endocytic pathways are tightly regulated membrane rearrangement processes that are crucial for homeostasis, development and disease. Autophagic cargo is delivered from autophagosomes to lysosomes for degradation through a complex process that topologically resembles endosomal maturation. Here, we report that a Beclin1-binding autophagic tumour suppressor, UVRAG, interacts with the class C Vps complex, a key component of the endosomal fusion machinery. This interaction stimulates Rab7 GTPase activity and autophagosome fusion with late endosomes/lysosomes, thereby enhancing delivery and degradation of autophagic cargo. Furthermore, the UVRAG-class-C-Vps complex accelerates endosome-endosome fusion, resulting in rapid degradation of endocytic cargo. Remarkably, autophagosome/endosome maturation mediated by the UVRAG-class-C-Vps complex is genetically separable from UVRAG-Beclin1-mediated autophagosome formation. This result indicates that UVRAG functions as a multivalent trafficking effector that regulates not only two important steps of autophagy - autophagosome formation and maturation - but also endosomal fusion, which concomitantly promotes transport of autophagic and endocytic cargo to the degradative compartments.     

Acinus

Fusion with lysosomes is the common last step of endocytic trafficking and autophagy. Accordingly, several proteins are required in both pathways for cargoes to reach their destinations. Among these proteins, Drosophila Acinus stands out, as it exerts opposite effects on these two pathways, and thus establishes a new paradigm. Loss of Acinus function destabilizes early endosomes, thereby promoting the delivery of their cargo to lysosomes. By contrast, the maturation of autophagosomes to autolysosomes is inhibited in acn mutant cells. The increase in autophagy upon Acinus overexpression and its location to the nucleus are consistent with Acinus being a novel regulator of autophagy.     

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.     

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.     

ESCRTs and Fab1 regulate distinct steps of autophagy

Eukaryotes use autophagy to turn over organelles, protein aggregates, and cytoplasmic constituents. The impairment of autophagy causes developmental defects, starvation sensitivity, the accumulation of protein aggregates, neuronal degradation, and cell death [1, 2]. Double-membraned autophagosomes sequester cytoplasm and fuse with endosomes or lysosomes in higher eukaryotes [3], but the importance of the endocytic pathway for autophagy and associated disease is not known. Here, we show that regulators of endosomal biogenesis and functions play a critical role in autophagy in Drosophila melanogaster. Genetic and ultrastructural analysis showed that subunits of endosomal sorting complex required for transport (ESCRT)-I, -II and -III, as well as their regulatory ATPase Vps4 and the endosomal PtdIns(3)P 5-kinase Fab1, all are required for autophagy. Although the loss of ESCRT or Vps4 function caused the accumulation of autophagosomes, probably because of inhibited fusion with the endolysosomal system, Fab1 activity was necessary for the maturation of autolysosomes. Importantly, reduced ESCRT functions aggravated polyglutamine-induced neurotoxicity in a model for Huntington's disease. Thus, this study links ESCRT function with autophagy and aggregate-induced neurodegeneration, thereby providing a plausible explanation for the fact that ESCRT mutations are involved in inherited neurodegenerative disease in humans [4].     

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.     

Host Cell Autophagy Modulates Early Stages of Adenovirus Infections in Airway Epithelial Cells

Human adenoviruses typically cause mild infections in the upper or lower respiratory tract, gastrointestinal tract, or ocular epithelium. However, adenoviruses may be life-threatening in patients with impaired immunity and some serotypes cause epidemic outbreaks. Attachment to host cell receptors activates cell signaling and virus uptake by endocytosis. At present, it is unclear how vital cellular homeostatic mechanisms affect these early steps in the adenovirus life cycle. Autophagy is a lysosomal degradation pathway for recycling intracellular components that is upregulated during periods of cell stress. Autophagic cargo is sequestered in double-membrane structures called autophagosomes that fuse with endosomes to form amphisomes which then deliver their content to lysosomes. Autophagy is an important adaptive response in airway epithelial cells targeted by many common adenovirus serotypes. Using two established tissue culture models, we demonstrate here that adaptive autophagy enhances expression of the early region 1 adenovirus protein, induction of mitogen-activated protein kinase signaling, and production of new viral progeny in airway epithelial cells infected with adenovirus type 2. We have also discovered that adenovirus infections are tightly regulated by endosome maturation, a process characterized by abrupt exchange of Rab5 and Rab7 GTPases, associated with early and late endosomes, respectively. Moreover, endosome maturation appears to control a pool of early endosomes capable of fusing with autophagosomes which enhance adenovirus infection. Many viruses have evolved mechanisms to induce autophagy in order to aid their own replication. Our studies reveal a novel role for host cell autophagy that could have a significant impact on the outcome of respiratory infections.     

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.     

Phagophores evolve from recycling endosomes

The membrane origins of autophagosomes have been a key unresolved question in the field. The earliest morphologically recognizable structure in the macroautophagy/autophagy itinerary is the double-membraned cup-shaped phagophore. Newly formed phosphatidylinositol 3-phosphate (PtdIns3P) on the membranes destined to become phagophores recruits WIPI2, which, in turn, binds ATG16L1 to define the sites of autophagosome formation. Here we review our recent study showing that membrane recruitment of WIPI2 requires coincident detection of PtdIns3P and RAB11A, a protein that marks recycling endosomes. We found that multiple core autophagy proteins are more tightly associated with the recycling endosome compartment than with endoplasmic reticulum (ER)-mitochondrial contact sites. Furthermore, biochemical isolation of the recycling endosomes confirmed that they recruit autophagy proteins. Finally, fixed and live-cell imaging data revealed that recycling endosomes engulf autophagic substrates. Indeed, the sequestration of mitochondria after mitophagy stimulation depends on early autophagy regulators. These data suggest that autophagosomes evolve from the RAB11A compartment.     

Acinus: A nuclear regulator of autophagy and endocytic trafficking

Fusion with lysosomes is the common last step of endocytic trafficking and autophagy. Accordingly, several proteins are required in both pathways for cargoes to reach their destinations. Among these proteins, Drosophila Acinus stands out, as it exerts opposite effects on these two pathways, and thus establishes a new paradigm. Loss of Acinus function destabilizes early endosomes, thereby promoting the delivery of their cargo to lysosomes. By contrast, the maturation of autophagosomes to autolysosomes is inhibited in acn mutant cells. The increase in autophagy upon Acinus overexpression and its location to the nucleus are consistent with Acinus being a novel regulator of autophagy.Key words: fat body, endosomes, lysosomes, nuclear protein, Notch signaling, EGF ReceptorMuch of the core machinery that is required for the formation and maturation of autophagosomes and endosomes has been identified by genetic screens in yeast. But as both types of organelles are charged with more complex functions in multicellular organisms, it is not surprising to find additional layers of regulation imposed on them. One such regulatory element was revealed by a genetic screen we conducted in Drosophila.The screen''s original idea was to take advantage of the observation that many proteins acting in trafficking to lysosomes also function in the biogenesis of lysosome-related organelles. Among these, the pigment granules—responsible for the characteristic color of the fly eye—are easily scored for defects. Thus, we set up a primary screen for eye color mutants. Among the more than 500 original hits, a secondary screen identified those mutants that altered endocytic trafficking. Importantly, the genetic tool kit assembled by the fly community allowed us to screen homozygous mutant eyes in otherwise heterozygous flies. This schema made it possible to identify mutations that are homozygous lethal as one might expect for null alleles of genes required for lysosomal delivery.One of the unexpected genes identified by this screen was acinus (acn). The Acn protein lacks any domain signatures and is most similar to human Acinus, which had been implicated in the destruction of chromatin during apoptosis. It is not clear yet whether the Drosophila protein contributes to this function as well, but in acn null alleles chromatin condensation and fragmentation during apoptosis appear normal.There is, however, a profound effect on endocytic trafficking, as acn is required for stabilization of early endosomes. Staining for endocytosed ligands, such as Boss or Delta, is drastically reduced, concomitant with a reduction in early endosomes marked by Rab5 or the SNARE Avl. By contrast, late endosomes marked by Rab7 appear normal. These changes do not represent a block in the initial internalization of the ligands, as inhibition of lysosomal degradation reveals the same accumulation of internalized ligands in wild-type and acn mutant cells.Reduced stability of early endosomes also causes reduced signaling from EGF receptors and Notch, consistent with the emerging notion that signaling from these receptors may be linked to their uptake into early endosomes.Many mutants that disrupt endocytic trafficking also affect autophagy. We found that this theme extends to acn. The most accessible form of autophagy in Drosophila is found in fat bodies after a short period of starvation. Activation of the AKT1/TOR pathway triggers the formation of autophagosomes, which mature into autolysosomes by fusing with lysosomes. Loss of acn interferes with this maturation step, as shown by the reduction in LysoTracker staining and also by quantitative electron microscopy. Consistent with an effect on the maturation of autophagosomes, acn is required downstream of TOR signaling. For example, expression of dominant-negative TOR kinase is a powerful tool to induce autophagy in the fat body of wild-type, but not acn larvae.Interestingly, overexpression of Acn induces autophagy. This does not appear to be merely a side effect. Ubiquitous expression of Acn is lethal, but flies survive when autophagy is suppressed by knockdown of ATG5, a core element of the autophagy machinery. We find that this enhanced autophagy is also independent of the TOR pathway.Taken together, this analysis of the first null mutant of an acinus gene in any system reveals its function as a regulator of endosomal and autophagosomal dynamics, modulating developmental signaling and the cellular response to starvation. Our investigation of acn loss-of-function phenotypes reveals defects in membrane trafficking during endocytosis and autophagy. We were therefore surprised that Acn protein localized to the nucleus, and that we failed to detect any consistent localization to endocytic or autophagic structures. This unexpected finding was further tested with transgenes expressing Myc-tagged Acn in the context of a genomic rescue construct. This tagged protein, under control of its endogenous enhancer/promoter elements, rescued all aspects of Acn function, and, nevertheless, localized to the nucleus, rather than any endosomal compartment.These findings suggest that the mechanism by which Acinus proteins modify endocytosis and autophagy may be indirect. One model for such an indirect effect is suggested by the interaction of mammalian Acinus proteins with several RNA binding proteins. Modulation of the levels or structure of RNAs that encode specific elements of the endocytosis or autophagy pathways may constitute an exciting new element of their regulation. Testing this possibility and identifying potential targets regulated by this Acn-dependent mechanism are important challenges that we have just begun to address.     

Maturation of Autophagic Vacuoles in Mammalian Cells

The autophagic process was first described in mammalian cells several decades ago. After their formation as double-membraned vacuoles containing cytoplasmic material, autophagic vacuoles or autophagosomes undergo a stepwise maturation including fusion with both endosomal and lysosomal vesicles. However, the molecular mechanisms regulating these fusion steps have begun to emerge only recently. The list of newly discovered molecules that regulate the maturation of autophagosomes to degradative autolysosomes includes the AAA ATPase SKD1, the small GTP binding protein Rab7, and possibly also the Alzheimer-linked presenilin 1. This review combines previous data on the endo/lysosomal fusion steps during autophagic vacuole maturation with recent findings on the molecules regulating these fusion steps. Interestingly, autophagic vacuole maturation appears to be blocked in certain human diseases including neuronal ceroid lipofuscinosis and Danon disease. This suggests that autophagy has important housekeeping or protective functions, because a block in autophagic maturation causes a disease.     

Maturation of autophagic vacuoles in Mammalian cells

The autophagic process was first described in mammalian cells several decades ago. After their formation as double-membraned vacuoles containing cytoplasmic material, autophagic vacuoles or autophagosomes undergo a stepwise maturation including fusion with both endosomal and lysosomal vesicles. However, the molecular mechanisms regulating these fusion steps have begun to emerge only recently. The list of newly discovered molecules that regulate the maturation of autophagosomes to degradative autolysosomes includes the AAA ATPase SKD1, the small GTP binding protein Rab7, and possibly also the Alzheimer-linked presenilin 1. This review combines previous data on the endo/lysosomal fusion steps during autophagic vacuole maturation with recent findings on the molecules regulating these fusion steps. Interestingly, autophagic vacuole maturation appears to be blocked in certain human diseases including neuronal ceroid lipofuscinosis and Danon disease. This suggests that autophagy has important housekeeping or protective functions because a block in autophagic maturation causes a disease.