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.     

Membrane markers of endoplasmic reticulum preserved in autophagic vacuolar membranes isolated from leupeptin-administered rat liver

We isolated membranes from leupeptin-induced autophagic vacuoles and compared them with lysosomal membranes purified from dextran-administered rats. In protein composition, autophagic vacuole membranes prepared from long term-starved (36 h) rats bear marked resemblance to lysosomal membranes, whereas vacuole membranes prepared from short term-starved (12 h) animals differ significantly from lysosomal membranes. Immunoblotting analyses showed that only autophagic vacuole membranes from short term-starved rats possess endoplasmic reticulum markers such as cytochrome P450 and NADPH-cytochrome c reductase. None of the membranes contain sialyltransferase, a Golgi membrane marker. In experiments in which rats were starved after feeding to induce autophagy, the appearance of the endoplasmic reticulum markers occurred during 6-12 h of starvation, concomitantly with increases in vacuolar proteins and sequestered cytosolic aldolase. The endoplasmic reticulum membrane markers and sequestered aldolase declined gradually after 20-36 h of starvation, suggesting that prolonged starvation causes no further increase in the formation of autophagic vacuoles but an increase in the population of matured autophagic vacuoles. Thus, the prominent markers of endoplasmic reticulum from which autophagosomes originate are well preserved in autophagic vacuole membranes, and retention of these markers is highly dependent on the formation and subsequent maturation process of autophagic vacuoles.     

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 autophagy in tobacco BY-2 cells under sucrose starvation conditions using the vacuolar H+-ATPase inhibitor concanamycin A and the autophagy-related protein Atg8

Tobacco BY-2 cells undergo autophagy in sucrose-free culture medium, which is the process mostly responsible for intracellular protein degradation under these conditions. Autophagy was inhibited by the vacuolar H⁺-ATPase inhibitors concanamycin A and bafilomycin A₁, which caused the accumulation of autophagic bodies in the central vacuoles. Such accumulation did not occur in the presence of the autophagy inhibitor 3-methyladenine, and concanamycin in turn inhibited the accumulation of autolysosomes in the presence of the cysteine protease inhibitor E-64c. Electron microscopy revealed not only that the autophagic bodies were accumulated in the central vacuole, but also that autophagosome-like structures were more frequently observed in the cytoplasm in treatments with concanamycin, suggesting that concanamycin affects the morphology of autophagosomes in addition to raising the pH of the central vacuole. Using BY-2 cells that constitutively express a fusion protein of autophagosome marker protein Atg8 and green fluorescent protein (GFP), we observed the appearance of autophagosomes by fluorescence microscopy, which is a reliable morphological marker of autophagy, and the processing of the fusion protein to GFP, which is a biochemical marker of autophagy. Together, these results suggest the involvement of vacuole type H⁺-ATPase in the maturation step of autophagosomes to autolysosomes in the autophagic process of BY-2 cells. The accumulation of autophagic bodies in the central vacuole by concanamycin is a marker of the occurrence of autophagy; however, it does not necessarily mean that the central vacuole is the site of cytoplasm degradation.     

基于自噬溶酶体形成机制调控缺血性脑卒中后神经元自噬流

脑卒中是由脑血管阻塞或出血引发的急性脑血管病，约84%的临床脑卒中患者由脑缺血引起。研究表明，自噬广泛参与并显著影响脑卒中病理生理进程。自噬是一个将陈旧蛋白质、损伤细胞器及多余胞质组分等呈递给溶酶体进行降解的代谢过程，其包括自噬的激活、自噬体的形成和成熟、自噬体与溶酶体融合、自噬产物在自噬溶酶体内消化和降解等过程。自噬流通常被定义为自噬/溶酶体信号机制。最近发现，自噬流障碍是导致缺血性脑卒中后神经元损伤的重要原因，而在自噬过程中任一步骤发生障碍均可导致自噬流损伤。本文重点对自噬体-溶酶体融合的机制，以及该机制在缺血性脑卒中后发生障碍的致病机理进行详细阐述，以期基于自噬体-溶酶体融合机制对神经元自噬流进行调节，进而诱导缺血性脑卒中后的神经保护。本文可为脑卒中病理机制研究指明方向，为脑卒中治疗探寻新的线索。     

Studies on the mechanisms of autophagy: maturation of the autophagic vacuole

Data presented in the accompanying paper suggests nascent autophagic vacuoles are formed from RER (Dunn, W. A. 1990. J. Cell Biol. 110:1923-1933). In the present report, the maturation of newly formed or nascent autophagic vacuoles into degradative vacuoles was examined using morphological and biochemical methods combined with immunological probes. Within 15 min of formation, autophagic vacuoles acquired acid hydrolases and lysosomal membrane proteins, thus becoming degradative vacuoles. A previously undescribed type of autophagic vacuole was also identified having characteristics of both nascent and degradative vacuoles, but was different from lysosomes. This intermediate compartment contained only small amounts of cathepsin L in comparison to lysosomes and was bound by a double membrane, typical of nascent vacuoles. However, unlike nascent vacuoles vet comparable to degradative vacuoles, these vacuoles were acidic and contained the lysosomal membrane protein, lgp120, at the outer limiting membrane. The results were consistent with the stepwise acquisition of lysosomal membrane proteins and hydrolases. The presence of mannose-6-phosphate receptor in autophagic vacuoles suggested a possible role of this receptor in the delivery of newly synthesized hydrolases from the Golgi apparatus. However, tunicamycin had no significant effect on the amount of mature acid hydrolases present in a preparation of autophagic vacuoles isolated from a metrizamide gradient. Combined, the results suggested nascent autophagic vacuoles mature into degradative vacuoles in a stepwise fashion: (a) acquisition of lysosomal membrane proteins by fusing with a vesicle deficient in hydrolytic enzymes (e.g., prelysosome); (b) vacuole acidification; and (c) acquisition of hydrolases by fusing with preexisting lysosomes or Golgi apparatus-derived vesicles.     

Morphometric evaluation of the turnover of autophagic vacuoles after treatment with Triton X-100 and vinblastine in murine pancreatic acinar and seminal vesicle epithelial cells

Large numbers of autophagic vacuoles were found in murine pancreatic acinar and seminal vesicle epithelial cells following the administration of Triton X-100 or vinblastine for 4 h. The autophagic vacuoles disappeared rapidly from the cells after the administration of cycloheximide to animals pretreated with Triton X-100. The decay in seminal vesicle cells appeared to follow first-order kinetics with an estimated t1/2 of 8.7 min. The regression in pancreatic cells was equally rapid and less than half the initial volume of autophagic vacuoles was found at the 12th min after cycloheximide injection. This time, the decay curve appeared to be linear rather than exponential. Our data, together with the work of others, support the view that the average half-life of autophagic vacuoles is a fairly constant parameter kept within the range of 6-9 min in various types of mouse and rat cell when the late steps of autophagocytosis (i.e. the fusion of autophagosomes and lysosomes and the degradation within lysosomes) are not affected. The regression of autophagic vacuoles was slow in mice pretreated with vinblastine (t1/2 of about 27-30 min) suggesting that this drug slows down the turnover of autophagic vacuoles. Morphometric evaluation of the regression of the autophagic vacuole compartment after cycloheximide treatment can be used as a tool to distinguish between treatments which elevate the amount of autophagic vacuoles within the cells by increasing the rate of sequestration from those which expand the autophagic vacuole compartment by causing accumulation of autophagic vacuoles as a result of blockade of the late steps of the autophagic process.     

Ultrastructural characterization of the delimiting membranes of isolated autophagosomes and amphisomes by freeze-fracture electron microscopy

The delimiting membranes of isolated autophagosomes from rat liver had extremely few transmembrane proteins, as indicated by the paucity of intramembrane particles in freeze-fracture images (about 20 particles/microm2, whereas isolated lysosomes had about 2000 particles/microm2). The autophagosomes also appeared to lack peripheral surface membrane proteins, since attempts to surface-biotinylate intact autophagosomes only yielded biotinylation of proteins from contaminating damaged mitochondria. All the membrane layers of multilamellar autophagosomes were equally particle-poor; the same was true of the autophagosome-forming, sequestering membrane complexes (phagophores). Isolated amphisomes (vacuoles formed by fusion between autophagosomes and endosomes) had more intramembrane particles than the autophagosomes (about 90 particles/microm2), and freeze-fracture images of these organelles frequently showed particle-rich endosomes fusing with particle-poor or particle-free autophagosomes. The appearence of multiple particle clusters suggested that a single autophagic vacuole could undergo multiple fusions with endosomes. Only the outermost membrane of bi- or multilamellar autophagic vacuoles appeared to engage in such fusions.     

Autophagy and acid phosphatase activity in the corpora allata of adult mated females of Diploptera punctata

The corpora allata exbibit cycles of synchronous cell growth and atrophy during ovarian cycles in adult females of the cockroach Diploptera punctata. In the present report, the process of synchronous autophagy of organelles which results in cellular atrophy was investigated. In general, unwanted organelles were sequentially sequestered by several different mechanisms and then targeted for destruction. Autophagy was initiated on day 4 when corpus allatum cells were largest and most actively synthesizing juvenile hormone. The first sign of the initiation of autophagy was aggregation of ribosomes in an isolation membrane. By day 5, many organelles were isolated in the autophagic vacuoles. The ribosomecontaining vacuoles were wrapped by flattened stacks of Golgi cisternae to form conspicuous whorl-like autophagosomes. This is a previously undescribed type of autophagic vacuole with the entire complex of Golgi cisternae forming part of the autophagic membranes. Smooth endoplasmic reticulum was wrapped into membranous autophagic vacuoles with concentric arrays of doubel membranes. Plasma membrane was invaginated and then isolated in a multivesicular body. These three different types of isolated vacuoles did not show acid phosphatase activity as indicated by histochemical staining with -glycerophosphate as substrate. Subsequently, these autophagosomes fused with each other and with 1° or 2° lysosomes to form giant autophagolysosomes. Some mitochondria appeared to have coalesced directly into autophagolysosomes. Golgi complexes were evident during this period; they actively participated in making lysosomal enzymes. Cytoskeletons were frequently observed in the vicinity of autophagic vacuoles and were presumably involved in the transport of the vacuoles. As a result of lysosomal degradation lipofuscins and dense bodies were frequently observed by days 9–12 indicating atrophy of corpus allatum cells. Structural parameters, especially those present early in autophagy, such as the isolation membrane, ribosome-containing vacuoles and whorl-like autophagosomes, can be used to search for potential growth regulators responsible for the induction of autophagy, of the corpora allata, and the subsequent termination in juvenile hormone synthesis.     

A Highlights from MBoC Selection: mTOR regulates phagosome and entotic vacuole fission

Macroendocytic vacuoles formed by phagocytosis, or the live-cell engulfment program entosis, undergo sequential steps of maturation, leading to the fusion of lysosomes that digest internalized cargo. After cargo digestion, nutrients must be exported to the cytosol, and vacuole membranes must be processed by mechanisms that remain poorly defined. Here we find that phagosomes and entotic vacuoles undergo a late maturation step characterized by fission, which redistributes vacuolar contents into lysosomal networks. Vacuole fission is regulated by the serine/threonine protein kinase mammalian target of rapamycin complex 1 (mTORC1), which localizes to vacuole membranes surrounding engulfed cells. Degrading engulfed cells supply engulfing cells with amino acids that are used in translation, and rescue cell survival and mTORC1 activity in starved macrophages and tumor cells. These data identify a late stage of phagocytosis and entosis that involves processing of large vacuoles by mTOR-regulated membrane fission.     

The small GTPases Rab9A and Rab23 function at distinct steps in autophagy during Group A Streptococcus infection

Autophagy mediates the degradation of cytoplasmic contents in the lysosome and plays a significant role in immunity. Here we identified the small GTPases Rab9A and Rab23 as novel autophagy regulators during Group A streptococcus (GAS) infection. Rab9A was recruited to GAS-containing autophagosome-like vacuoles (GcAVs) after autophagosomal maturation and its activity was required for GcAV enlargement and eventual lysosomal fusion. GcAV enlargement appeared to be related to homotypic fusion of GcAVs with Rab9A. Rab23 was recruited to GAS-capturing forming autophagosomes. Knockdown of Rab23 expression decreased both LC3- and Atg5-positive GAS formation and caused the accumulation of LC3-positive structures that did not associate with intracellular GAS. It was suggested, therefore, that Rab23 is required for GcAV formation and is involved in GAS targeting of autophagic vacuoles. Furthermore, knockdown of Rab9A or Rab23 expression impaired the degradation of intracellular GAS. Therefore, our data reveal that the Rab9A and Rab23 GTPases play crucial roles in autophagy of GAS. However, neither Rab9A nor Rab23 were localized to starvation-induced autophagosomes. Not only Rab9A but also Rab23 was dispensable for starvation-induced autophagosome formation. These findings demonstrate that specific Rab proteins function at distinct steps during autophagy in response to GAS infection.     

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.     

Distribution of electric charges and concanavalin A binding sites on autophagic vacuoles and lysosomes in mouse hepatocytes

The distributions of electric charges and Concanavalin A binding sites in autophagic vacuoles and lysosomes in mouse hepatocytes were studied by utilizing a frozen ultrathin section labeling method with cationized ferritin (CF) or anionized ferritin and ferritin-conjugated Concanavalin A (Con A-F) as visual probes. Our observations revealed that the inner surface of the autophagic vacuole membrane has more anionic sites (CF binding) than other organelle membranes. This suggests that if the limiting membranes of autophagic vacuoles originate from preexisting membranes, such membranes must undergo structural and compositional alternation during the formation of the autophagic vacuoles. In contrast to CF, Con A-F showed no distinct binding to the membranes of autophagic vacuoles, but the contents of vacuoles displayed varying Con A-F binding, depending on the stage of the autophagic process. Increased binding was seen in more mature autophagic vacuoles. Since lysosomes showed a preferential accumulation of Con A-F particles, molecules with Con A-F binding sites in autophagic vacuoles may be of lysosomal origin. Con A-F distribution varied from lysosome to lysosome in the same cell, indicating heterogeneity of lysosomal contents. These results suggest that ferritin-conjugated lectin labeling methods applied to frozen, ultrathin section are a useful new approach in analyzing the natural history of autophagic vacuoles and the heterogeneity of lysosomes.     

Live-cell imaging of Aspergillus nidulans autophagy

We exploited the amenability of the fungus Aspergillus nidulans to genetics and live-cell microscopy to investigate autophagy. Upon nitrogen starvation, GFP-Atg8-containing pre-autophagosomal puncta give rise to cup-shaped phagophores and circular (0.9-μm diameter) autophagosomes that disappear in the vicinity of the vacuoles after their shape becomes irregular and their GFP-Atg8 fluorescence decays. This ‘autophagosome cycle’ gives rise to characteristic cone-shaped traces in kymographs. Autophagy does not require endosome maturation or ESCRTs, as autophagosomes fuse with vacuoles directly in a RabS (homolog of Saccharomyces cerevisiae Ypt7 and mammalian RAB7; written hereafter as RabS^RAB7)-HOPS-(homotypic fusion and vacuole protein sorting complex)-dependent manner. However, by removing RabS^RAB7 or Vps41 (a component of the HOPS complex), we show that autophagosomes may still fuse, albeit inefficiently, with the endovacuolar system in a process almost certainly mediated by RabA^RAB5/RabB^RAB5 (yeast Vps21 homologs)-CORVET (class C core vacuole/endosome tethering complex), because acute inactivation of HbrA/Vps33, a key component of HOPS and CORVET, completely precludes access of GFP-Atg8 to vacuoles without affecting autophagosome biogenesis. Using a FYVE₂-GFP probe and endosomal PtdIns3P-depleted cells, we imaged PtdIns3P on autophagic membranes. PtdIns3P present on autophagosomes decays at late stages of the cycle, preceding fusion with the vacuole. Autophagy does not require Golgi traffic, but it is crucially dependent on RabO^RAB1. TRAPPIII-specific factor AN7311 (yeast Trs85) localizes to the phagophore assembly site (PAS) and RabO^RAB1 localizes to phagophores and autophagosomes. The Golgi and autophagy roles of RabO^RAB1 are dissociable by mutation: rabO^A136D hyphae show relatively normal secretion at 28°C but are completely blocked in autophagy. This finding and the lack of Golgi traffic involvement pointed to the ER as one potential source of membranes for autophagy. In agreement, autophagosomes form in close association with ring-shaped omegasome-like ER structures resembling those described in mammalian cells.     

Biogenesis of multilamellar bodies via autophagy

Transfection of Mv1Lu mink lung type II alveolar cells with beta1-6-N-acetylglucosaminyl transferase V is associated with the expression of large lysosomal vacuoles, which are immunofluorescently labeled for the lysosomal glycoprotein lysosomal-associated membrane protein-2 and the beta1-6-branched N-glycan-specific lectin phaseolis vulgaris leucoagglutinin. By electron microscopy, the vacuoles present the morphology of multilamellar bodies (MLBs). Treatment of the cells with the lysosomal protease inhibitor leupeptin results in the progressive transformation of the MLBs into electron-dense autophagic vacuoles and eventual disappearance of MLBs after 4 d of treatment. Heterologous structures containing both membrane lamellae and peripheral electron-dense regions appear 15 h after leupeptin addition and are indicative of ongoing lysosome-MLB fusion. Leupeptin washout is associated with the formation after 24 and 48 h of single or multiple foci of lamellae within the autophagic vacuoles, which give rise to MLBs after 72 h. Treatment with 3-methyladenine, an inhibitor of autophagic sequestration, results in the significantly reduced expression of multilamellar bodies and the accumulation of inclusion bodies resembling nascent or immature autophagic vacuoles. Scrape-loaded cytoplasmic FITC-dextran is incorporated into lysosomal-associated membrane protein-2-positive MLBs, and this process is inhibited by 3-methyladenine, demonstrating that active autophagy is involved in MLB formation. Our results indicate that selective resistance to lysosomal degradation within the autophagic vacuole results in the formation of a microenvironment propicious for the formation of membrane lamella.     

大鼠睾丸间质细胞的自体吞噬活动

本文结合超微结构和细胞化学观察,研究大鼠睾丸间质细胞(Leydig细胞)中溶酶体的结??构与功能。观察结果表明,大鼠睾丸间质细胞中高尔基体非常发达,在高尔基体的成熟面存在着CMP酶阳性反应的GERL系统,说明这种细胞有不断产生溶酶体的能力。细胞化学结果也证实在睾丸间质细胞有较多的初级和次级溶酶体。睾丸间质细胞不仅有较多的溶酶体,而且还有相当数量的自噬小体,存在着活跃的自体吞噬活动。自噬小体的界膜来源于特化的光面内质网或高尔基体膜囊,包围的内容物主要是光面内质网和少量线粒体。当自噬小体与溶酶体融合后即成为自体吞噬泡,由于酶的消化作用,自体吞噬泡内的细胞器有一系列形态变化。根据CMP酶细胞化学反应,可以区分自噬小体和自体吞噬泡,后者是一种次级溶酶体,呈CMP酶阳性反应。睾丸间质细胞是分泌雄性激素的内分泌细胞,其光面内质网和线粒体在类固醇激素分泌中起重要作用,自体吞噬活动的结果是去除部分内质网和线粒体,可能在细胞水平上起着对雄性激素分泌的调节作用。     

脑缺血后N-乙基马来酰亚胺敏感因子ATP酶失活致神经元自噬流障碍的病理机制

缺血性脑卒中是由脑血管梗塞引起的急性脑血管病,具有较高的发病率、致残率和致死率。研究发现,过度自噬或自噬不足均可导致细胞损伤。自噬包括自噬体的形成和成熟、自噬体与溶酶体融合、自噬底物在自噬溶酶体内的降解和清除,这些过程呈连续状态则称为自噬流。研究发现,脑缺血可导致自噬体与溶酶体间发生融合障碍,从而引发自噬流损伤。细胞内膜融合由3种核心组分介导,即N-乙基马来酰亚胺敏感因子（N-ethylmaleimide sensitive factor,NSF） ATP酶、可溶性NSF黏附蛋白（soluble NSF attachment protein,SNAP）及可溶性NSF黏附蛋白受体（soluble NSF attachment protein receptors,SNAREs）。当SNAREs介导自噬体与溶酶体融合后以非活性的复合体形式存留于自噬溶酶体膜,须被NSF再激活为单体后方可发挥新一轮的膜融合介导作用,而NSF是唯一可再激活SNAREs的ATP酶。新近研究表明,脑缺血可显著抑制NSF ATP酶活性,导致其对SNAREs再激活减少,这可能是自噬体与溶酶体间发生融合障碍并导致神经元自噬...     

Diversity of signaling controls of macroautophagy in mammalian cells

Macroautophagy is a major lysosomal catabolic process conserved from yeast to human. The formation of autophagic vacuoles is stimulated by a variety of intracellular and extracellular stress situations including amino acid starvation, aggregation of misfolded proteins, and accumulation of damaged organelles. Several signaling pathways control the formation of autophagic vacuoles. As some of them are engaged in the control of protein synthesis or cell survival this suggests that macroautophagy is intimately associated with the execution of cell proliferation and cell death programs. Whether or not these different signaling pathways converge to a unique point to trigger the formation of autophagic vacuole remains an open question.     

Neuronal macroautophagy: from development to degeneration

Macroautophagy, a lysosomal pathway responsible for the turnover of organelles and long-lived proteins, has been regarded mainly as an inducible process in neurons, which is mobilized in states of stress and injury. New studies show, however, that macroautophagy is also constitutively active in healthy neurons and is vital to cell survival. Neurons in the brain, unlike cells in the periphery, are protected from large-scale autophagy induction because they can use several different energy sources optimally, receive additional nutrients and neurotrophin support from glial cells, and benefit from hypothalamic regulation of peripheral nutrient supplies. Due to its exceptional efficiency, constitutive autophagy in healthy neurons proceeds in the absence of easily detectable autophagic vacuole intermediates. These intermediates can accumulate rapidly, however, when late steps in the autophagic process are blocked. Autophagic vacuoles also accumulate abnormally in affected neurons of several major neurodegenerative diseases, including Alzheimer’s disease and Parkinson’s disease, where they have been linked to various aspects of disease pathogenesis including neuronal cell death. The build-up of autophagic vacuoles in these neurological disorders and others may reflect either heightened autophagy induction, impairment in later digestive steps in the autophagy pathway, or both. Determining the basis for AV accumulation is critical for understanding the pathogenic significance of autophagy in a given pathologic state and for designing possible therapies based on modulating autophagy. In this review, we discuss the special features of autophagy regulation in the brain, its suspected roles in neurodevelopment and plasticity, and recent progress toward understanding how dysfunctional autophagy contributes to neurodegenerative disease.     

Binding of the Atg1/ULK1 kinase to the ubiquitin-like protein Atg8 regulates autophagy

Autophagy is an intracellular trafficking pathway sequestering cytoplasm and delivering excess and damaged cargo to the vacuole for degradation. The Atg1/ULK1 kinase is an essential component of the core autophagy machinery possibly activated by binding to Atg13 upon starvation. Indeed, we found that Atg13 directly binds Atg1, and specific Atg13 mutations abolishing this interaction interfere with Atg1 function in vivo. Surprisingly, Atg13 binding to Atg1 is constitutive and not altered by nutrient conditions or treatment with the Target of rapamycin complex 1 (TORC1)-inhibitor rapamycin. We identify Atg8 as a novel regulator of Atg1/ULK1, which directly binds Atg1/ULK1 in a LC3-interaction region (LIR)-dependent manner. Molecular analysis revealed that Atg13 and Atg8 cooperate at different steps to regulate Atg1 function. Atg8 targets Atg1/ULK1 to autophagosomes, where it may promote autophagosome maturation and/or fusion with vacuoles/lysosomes. Moreover, Atg8 binding triggers vacuolar degradation of the Atg1-Atg13 complex in yeast, thereby coupling Atg1 activity to autophagic flux. Together, these findings define a conserved step in autophagy regulation in yeast and mammals and expand the known functions of LIR-dependent Atg8 targets to include spatial regulation of the Atg1/ULK1 kinase.