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

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

Mobilization of rubisco and stroma-localized fluorescent proteins of chloroplasts to the vacuole by an ATG gene-dependent autophagic process

During senescence and at times of stress, plants can mobilize needed nitrogen from chloroplasts in leaves to other organs. Much of the total leaf nitrogen is allocated to the most abundant plant protein, Rubisco. While bulk degradation of the cytosol and organelles in plants occurs by autophagy, the role of autophagy in the degradation of chloroplast proteins is still unclear. We have visualized the fate of Rubisco, stroma-targeted green fluorescent protein (GFP) and DsRed, and GFP-labeled Rubisco in order to investigate the involvement of autophagy in the mobilization of stromal proteins to the vacuole. Using immunoelectron microscopy, we previously demonstrated that Rubisco is released from the chloroplast into Rubisco-containing bodies (RCBs) in naturally senescent leaves. When leaves of transgenic Arabidopsis (Arabidopsis thaliana) plants expressing stroma-targeted fluorescent proteins were incubated with concanamycin A to inhibit vacuolar H(+)-ATPase activity, spherical bodies exhibiting GFP or DsRed fluorescence without chlorophyll fluorescence were observed in the vacuolar lumen. Double-labeled immunoelectron microscopy with anti-Rubisco and anti-GFP antibodies confirmed that the fluorescent bodies correspond to RCBs. RCBs could also be visualized using GFP-labeled Rubisco directly. RCBs were not observed in leaves of a T-DNA insertion mutant in ATG5, one of the essential genes for autophagy. Stroma-targeted DsRed and GFP-ATG8 fusion proteins were observed together in autophagic bodies in the vacuole. We conclude that Rubisco and stroma-targeted fluorescent proteins can be mobilized to the vacuole through an ATG gene-dependent autophagic process without prior chloroplast destruction.     

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.     

Monitoring autophagic flux by an improved tandem fluorescent-tagged LC3 (mTagRFP-mWasabi-LC3) reveals that high-dose rapamycin impairs autophagic flux in cancer cells

Monitoring autophagic flux is important for the analysis of autophagy. Tandem fluorescent-tagged LC3 (mRFP-EGFP-LC3) is a convenient assay for monitoring autophagic flux based on different pH stability of EGFP and mRFP fluorescent proteins. However, it has been reported that there is still weak fluorescence of EGFP in acidic environments (pH between 4 and 5) or acidic lysosomes. So it is possible that autolysosomes are labeled with yellow signals (GFP⁺RFP⁺ puncta), which results in misinterpreting autophagic flux results. Therefore, it is desirable to choose a monomeric green fluorescent protein that is more acid sensitive than EGFP in the assay of autophagic flux. Here, we report on an mTagRFP-mWasabi-LC3 reporter, in which mWasabi is more acid sensitive than EGFP and has no fluorescence in acidic lysosomes. Meanwhile, mTagRFP-mWasabi-LC3ΔG was constructed as the negative control for this assay. Compared with mRFP-EGFP-LC3, our results showed that this reporter is more sensitive and accurate in detecting the accumulation of autophagosomes and autolysosomes. Using this reporter, we find that high-dose rapamycin (30 μM) will impair autophagic flux, inducing many more autophagosomes than autolysosomes in HeLa cells, while low-dose rapamycin (500 nM) has an opposite effect. In addition, other chemical autophagy inducers (cisplatin, staurosporine and Z18) also elicit much more autophagosomes at high doses than those at low doses. Our results suggest that the dosage of chemical autophagy inducers would obviously influence autophagic flux in cells.     

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.     

Alkaline stress-induced autophagy is mediated by mTORC1 inactivation

The activation of autophagic pathway by alkaline stress was investigated. Various types of mammalian cells were subjected to alkaline stress by incubation in bicarbonate buffered media in humidified air containing atmospheric 0.04% CO(2) . The induction of autophagy following alkaline stress was evaluated by assessing the conversion of cytosolic LC3-I into lipidated LC3-II, the accumulation of autophagosomes, and the formation of autolysosomes. Colocalization of GFP-LC3 with endolysosomal marker in HeLa GFP-LC3 cells undergoing autophagic process by alkaline stress further demonstrates that autophagosomes triggered by alkaline stress matures into autolysosomes for the lysosome dependent degradation. We found that the inactivation of mTORC1 is important for the pathway leading to the induction of autophagy by alkaline stress since the expression of RhebQ64L, a constitutive activator of mTORC1, downregulates the induction of autophagy after alkaline stress in transfected human 293T cells. These results imply that activation of autophagic pathway following the inactivation of mTORC1 is important cellular events governing alkaline stress-induced cytotoxicity and clinical symptoms associated with alkalosis.     

Visualization of autophagy in Arabidopsis using the fluorescent dye monodansylcadaverine and a GFP-AtATG8e fusion protein

Autophagy is a process that is thought to occur in all eukaryotes in which cells recycle cytoplasmic contents when subjected to environmental stress conditions or during certain stages of development. Upon induction of autophagy, double membrane-bound structures called autophagosomes engulf portions of the cytoplasm and transfer them to the vacuole or lysosome for degradation. In this study, we have characterized two potential markers for autophagy in plants, the fluorescent dye monodansylcadaverine (MDC) and a green fluorescent protein (GFP)-AtATG8e fusion protein, and propose that they both label autophagosomes in Arabidopsis. Both markers label the same small, apparently membrane-bound structures found in cells under conditions that are known to induce autophagy such as starvation and senescence. They are usually seen in the cytoplasm, but occasionally can be observed within the vacuole, consistent with a function in the transfer of cytoplasmic material into the vacuole for degradation. MDC-staining and the GFP-AtATG8e fusion protein can now be used as very effective tools to complement biochemical and genetic approaches to the study of autophagy in plant systems.     

In vivo imaging and quantitative monitoring of autophagic flux in tobacco BY-2 cells

Autophagy has been shown to play essential roles in the growth, development and survival of eukaryotic cells. However, simple methods for quantification and visualization of autophagic flux remain to be developed in living plant cells. Here, we analyzed the autophagic flux in transgenic tobacco BY-2 cell lines expressing fluorescence-tagged NtATG8a as a marker for autophagosome formation. Under sucrose-starved conditions, the number of punctate signals of YFP-NtATG8a increased, and the fluorescence intensity of the cytoplasm and nucleoplasm decreased. Conversely, these changes were not observed in BY-2 cells expressing a C-terminal glycine deletion mutant of the NtATG8a protein (NtATG8aΔG). To monitor the autophagic flux more easily, we generated a transgenic BY-2 cell line expressing NtATG8a fused to a pH-sensitive fluorescent tag, a tandem fusion of the acid-insensitive RFP and the acid-sensitive YFP. In sucrose-rich conditions, both fluorescent signals were detected in the cytoplasm and only weakly in the vacuole. In contrast, under sucrose-starved conditions, the fluorescence intensity of the cytoplasm decreased, and the RFP signal clearly increased in the vacuole, corresponding to the fusion of the autophagosome to the vacuole and translocation of ATG8 from the cytoplasm to the vacuole. Moreover, we introduce a novel simple easy way to monitor the autophagic flux non-invasively by only measuring the ratio of fluorescence of RFP and YFP in the cell suspension using a fluorescent image analyzer without microscopy. The present in vivo quantitative monitoring system for the autophagic flux offers a powerful tool for determining the physiological functions and molecular mechanisms of plant autophagy induced by environmental stimuli.     

Activation of autophagy of aggregation-prone ubiquitinated proteins by timosaponin A-III

Chemical modulators of autophagy provide useful pharmacological tools for examination of autophagic processes, and also may lead to new therapeutic agents for diseases in which control of cellular sequestration and degradation capacity are beneficial. We have identified that timosaponin A-III (TAIII), a medicinal saponin reported to exhibit anticancer properties and improve brain function, is a pronounced activator of autophagy. In this work, the salient features and functional role of TAIII-induced autophagy were investigated. In TAIII-treated cells, autophagic flux with increased formation of autophagosomes and conversion into autolysosomes is induced in association with inhibition of mammalian target of rapamycin activity and elevation of cytosolic free calcium. The TAIII-induced autophagy is distinct from conventional induction by rapamycin, exhibiting large autophagic vacuoles that appear to contain significant contents of endosomal membranes and multivesicular bodies. Furthermore, TAIII stimulates biosynthesis of cholesterol, which is incorporated to the autophagic vacuole membranes. The TAIII-induced autophagic vacuoles capture ubiquitinated proteins, and in proteasome-inhibited cells TAIII promotes autophagy of aggregation-prone ubiquitinated proteins. Our studies demonstrate that TAIII induced a distinct form of autophagy, and one of its pharmacological actions is likely to enhance the cellular quality control capacity via autophagic clearance of otherwise accumulated ubiquitinated protein aggregates.     

Autophagic degradation of nuclear components in mammalian cells

Autophagy is an evolutionally conserved intracellular mechanism for the degradation of organelles and proteins. Here we demonstrate the presence of perinuclear autophagosomes/autolysosomes containing nuclear components in nuclear envelopathies caused by mutations in the genes encoding A-type lamins (LMNA) and emerin (EMD). These autophagosomes/autolysosomes were sometimes bigger than nucleus. The autophagic nature is further supported by up-regulation of LC3-II in Lmna^H222P/H222P fibroblasts. In addition, inhibition of autophagy led to the accumulation of nuclear abnormalities and reduced cell viability, highly suggesting a beneficial role of autophagy, at least in these cells. Similar giant autophagosomes/autolysosomes were seen even in wild-type cells, albeit rarely, implying that this “nucleophagy” is not confined to the diseased condition, but may be seen even in physiologic conditions to clean up nuclear wastes produced by nuclear damage.     

Do plastids in Dendrobium cv. Lucky Duan petals function similar to autophagosomes and autolysosomes?

In animal cells a double-membrane-bound structure, the autophagosome, encloses a portion of the cytoplasm. The encapsulated material becomes digested after fusion of the autophagosome with a vesicle containing lytic enzymes. The autophagosome is then termed autolysosome. In intact plants, structures similar to animal autophagosomes/autolysosomes have been found only in a few types of cells. Additionally, some early papers indicated that plastids can function similar to autophagosomes/autolysosomes. Here, we report that plastids in Dendrobium cv. Lucky Duan petals produced an endocytosis-like invagination of the two outer membranes. The opening between the invagination space and the cytoplasm was almost isodiametric, less than 0.2 μm in diameter. The volume of the space formed by the invagination had a maximum of about half of the total plastid volume. Staining of the invagination lumen for acid phosphatase, a marker of organelles showing autophagic activity, was positive. Membranes and numerous ribosomes were observed inside the lumen of the invagination. The structure of the material inside the lumen varied from that of the cytoplasm to uniform electron-translucent, indicating that the enclosed cytoplasmic material became completely digested. No support was found for the idea that the material engulfed by the plastid or the whole plastid became transferred to a vacuole. Taken together, the data suggested the hypothesis that plastids in Dendrobium petal mesophyll cells can function in a way similar to both autophagosomes and autolysosomes in animal cells.     

GFP‐LC3 labels organised smooth endoplasmic reticulum membranes independently of autophagy

Disruption of autophagy leads to accumulation of intracellular multilamellar inclusions morphologically similar to organised smooth endoplasmic reticulum (OSER) membranes. However, the relation of these membranous compartments to autophagy is unknown. The purpose of this study was to test whether OSER plays a role in the autophagic protein degradation pathway. Here, GFP‐LC3 is shown to localise to the OSER membranes induced by calnexin expression both in transiently transfected HEK293 cells and in mouse embryo fibroblasts. In contrast to GFP‐LC3, endogenous LC3 is excluded from these membranes under normal conditions as well as after cell starvation. Furthermore, YFP‐Atg5, a protein essential for autophagy and known to reside on autophagic membranes, is excluded from the calnexin‐positive inclusion structures. In cells devoid of Atg5, a protein essential for autophagy and known to reside on autophagic membranes, colocalisation of calnexin with GFP‐LC3 within the multilamellar bodies is preserved. I show that calnexin, a protein enriched in the OSER, is not subject to autophagic or lysosomal degradation. Finally, GFP‐LC3 targeting to these membranes is independent of its processing and insensitive to drugs modulating autophagic and lysosomal protein degradation. These observations are inconsistent with a role of autophagic/lysosomal degradation in clearance of multilamellar bodies comprising OSER. Furthermore, GFP‐LC3, a fusion protein widely used as a marker for autophagic vesicles and pre‐autophagic compartments, may be trapped in this compartment and this artefact must be taken into account if the construct is used to visualise autophagic membranes. J. Cell. Biochem. 107: 86–95, 2009. © 2009 Wiley‐Liss, Inc.     

Do plastids in Dendrobium cv. Lucky Duan petals function similar to autophagosomes and autolysosomes?

In animal cells a double-membrane-bound structure, the autophagosome, encloses a portion of the cytoplasm. The encapsulated material becomes digested after fusion of the autophagosome with a vesicle containing lytic enzymes. The autophagosome is then termed autolysosome. In intact plants, structures similar to animal autophagosomes/autolysosomes have been found only in a few types of cells. Additionally, some early papers indicated that plastids can function similar to autophagosomes/autolysosomes. Here, we report that plastids in Dendrobium cv. Lucky Duan petals produced an endocytosis-like invagination of the two outer membranes. The opening between the invagination space and the cytoplasm was almost isodiametric, less than 0.2 μm in diameter. The volume of the space formed by the invagination had a maximum of about half of the total plastid volume. Staining of the invagination lumen for acid phosphatase, a marker of organelles showing autophagic activity, was positive. Membranes and numerous ribosomes were observed inside the lumen of the invagination. The structure of the material inside the lumen varied from that of the cytoplasm to uniform electron-translucent, indicating that the enclosed cytoplasmic material became completely digested. No support was found for the idea that the material engulfed by the plastid or the whole plastid became transferred to a vacuole. Taken together, the data suggested the hypothesis that plastids in Dendrobium petal mesophyll cells can function in a way similar to both autophagosomes and autolysosomes in animal cells.     

Origin and function of the stalk-cell vacuole in Dictyostelium

Large vacuoles are characteristic of plant and fungal cells, and their origin has long attracted interest. The cellular slime mould provides a unique opportunity to study the de novo formation of vacuoles because, in its life cycle, a subset of the highly motile animal-like cells (prestalk cells) rapidly develops a single large vacuole and cellulosic cell wall to become plant-like cells (stalk cells). Here we describe the origin and process of vacuole formation using live-imaging of Dictyostelium cells expressing GFP-tagged ammonium transporter A (AmtA-GFP), which was found to reside on the membrane of stalk-cell vacuoles. We show that stalk-cell vacuoles originate from acidic vesicles and autophagosomes, which fuse to form autolysosomes. Their repeated fusion and expansion accompanied by concomitant cell wall formation enable the stalk cells to rapidly develop turgor pressure necessary to make the rigid stalk to hold the spores aloft. Contractile vacuoles, which are rich in H⁺-ATPase as in plant vacuoles, remained separate from these vacuoles. We further argue that AmtA may play an important role in the control of stalk-cell differentiation by modulating the pH of autolysosomes.     

Protein aggregates are transported to vacuoles by a macroautophagic mechanism in nutrient-starved plant cells

When a fusion protein of cytochrome b5 (Cyt b5) and the red fluorescent protein (RFP) are expressed in tobacco BY-2 cells, the expressed protein forms intracellular aggregates that emit red fluorescence. When such cells are grown to the stationary phase or incubated in nutrient limited medium, RFP fluorescence can be detected in the vacuolar lumen. We investigated this transport mechanism using a limited-nitrogen model. E-64 and 3-methyladenine, which inhibit autophagic processes, blocked the transport of the RFP signal to the vacuole. We next traced the autophagic process in tobacco cells using YFP fused with the tobacco Atg8 homologue (YFP-NtAtg8) and analyzed the contribution of autophagy to the vacuolar transport of the aggregates. Under limited-nitrogen conditions, the aggregates were degraded in preference to other organelles, and the autophagosomes colocalized with the aggregates at a higher frequency than with mitochondria. This is the first demonstration that selective macroautophagic degradation can occur in plant cells.     

Lysosomal turnover, but not a cellular level, of endogenous LC3 is a marker for autophagy

During starvation-induced autophagy in mammals, autophagosomes form and fuse with lysosomes, leading to the degradation of the intra-autophagosomal contents by lysosomal proteases. During the formation of autophagosomes, LC3 is lipidated, and this LC3-phospholipid conjugate (LC3-II) is localized on autophagosomes and autolysosomes. While intra-autophagosomal LC3-II may be degraded by lysosomal hydrolases, recent studies have regarded LC3-II accumulation as marker of autophagy. The effect of lysosomal turnover of endogenous LC3-II in this process, however, has not been considered. We therefore investigated the lysosomal turnover of endogenous LC3-II during starvation-induced autophagy using E64d and pepstatin A, which inhibit lysosomal proteases, including cathepsins B, D and L. We found that endogenous LC3-II significantly accumulated in the presence of E64d and pepstatin A under starvation conditions, increasing about 3.5 fold in HEK293 cells and about 6.7 fold in HeLa cells compared with that in their absence, whereas the amount of LC3-II in their absence is cell-line dependent. Morphological analyses indicated that endogenous LC3-positive puncta and autolysosomes increased in HeLa cells under starvation conditions in the presence of these inhibitors. These results indicate that endogenous LC3-II is considerably degraded by lysosomal hydrolases after formation of autolysosomes, and suggest that lysosomal turnover, not a transient amount, of this protein reflects starvation-induced autophagic activity.     

Alpha tonoplast intrinsic protein is specifically associated with vacuole membrane involved in an autophagic process

Autophagy in plant cells is induced by nutrient starvation. Initially, double membrane-bound organelles, termed autophagosomes, enclose a portion of cytoplasm, and then fuse with a vacuole or lysosome to give an autolysosome. Autolysosomes can be visualized by incubating cells in the presence of a membrane-permeable cysteine protease inhibitor. The inhibitor presumably decreases proteolytic degradation of the autolysosome contents that are composed of portions of cytoplasm enclosed by the membrane originating from the inner membrane of autophagosomes, and allows them to accumulate. The origin of membranes that give rise to autophagosomes and autolysosomes is unknown. Here we use an acidotropic fluorescent dye, LysoTracker Red, to label autolysosomes specifically. We demonstrate that autolysosome membranes are marked by the presence of alpha-tonoplast intrinsic protein (alpha-TIP) but not by gamma-TIP or delta-TIP. The identification of a TIP specifically associated with membranes derived from an autophagic process may help our understanding of how plant cells generate and maintain functionally distinct types of vacuoles.     

3-methyladenine inhibits autophagy in tobacco culture cells under sucrose starvation conditions

Tobacco (Nicotiana tabacum) culture cells perform autophagy and degrade cellular proteins in response to sucrose starvation. When protein degradation is blocked by the cysteine protease inhibitor E-64c, lysosomes containing particles of cytoplasm (autolysosomes) accumulate in the cells. Therefore, using light microscopy, we can determine whether cells have performed autophagy. In this study, we investigated whether or not 3-methyladenine (3-MA), which is a known inhibitor of autophagy in mammalian cells, blocks autophagy in tobacco culture cells. The accumulation of autolysosomes was blocked by the addition to the culture media of 5 mM 3-MA together with E-64c. We did not detect autolysosomes or structures thought to be involved with autophagy, such as autophagosomes, accumulating in these cells, as observed by electron microscopy. 3-MA blocked cellular protein degradation without any effect on cellular protease activity. In mammalian cells, phosphatidylinositol 3-kinase (PtdIns 3-kinase) is a putative target of 3-MA. The PtdIns 3-kinase inhibitors wortmannin and LY294002 also inhibited the accumulation of autolysosomes in tobacco culture cells. These results suggest that (1) 3-MA inhibits autophagy by blocking the formation of autophagosomes in tobacco culture cells, and (2) PtdIns 3-kinase is essential for autophagy in tobacco cells.     

Inhibitory Effect of mTOR Activator MHY1485 on Autophagy: Suppression of Lysosomal Fusion

Autophagy is a major degradative process responsible for the disposal of cytoplasmic proteins and dysfunctional organelles via the lysosomal pathway. During the autophagic process, cells form double-membraned vesicles called autophagosomes that sequester disposable materials in the cytoplasm and finally fuse with lysosomes. In the present study, we investigated the inhibition of autophagy by a synthesized compound, MHY1485, in a culture system by using Ac2F rat hepatocytes. Autophagic flux was measured to evaluate the autophagic activity. Autophagosomes were visualized in Ac2F cells transfected with AdGFP-LC3 by live-cell confocal microscopy. In addition, activity of mTOR, a major regulatory protein of autophagy, was assessed by western blot and docking simulation using AutoDock 4.2. In the result, treatment with MHY1485 suppressed the basal autophagic flux, and this inhibitory effect was clearly confirmed in cells under starvation, a strong physiological inducer of autophagy. The levels of p62 and beclin-1 did not show significant change after treatment with MHY1485. Decreased co-localization of autophagosomes and lysosomes in confocal microscopic images revealed the inhibitory effect of MHY1485 on lysosomal fusion during starvation-induced autophagy. These effects of MHY1485 led to the accumulation of LC3II and enlargement of the autophagosomes in a dose- and time- dependent manner. Furthermore, MHY1485 induced mTOR activation and correspondingly showed a higher docking score than PP242, a well-known ATP-competitive mTOR inhibitor, in docking simulation. In conclusion, MHY1485 has an inhibitory effect on the autophagic process by inhibition of fusion between autophagosomes and lysosomes leading to the accumulation of LC3II protein and enlarged autophagosomes. MHY1485 also induces mTOR activity, providing a possibility for another regulatory mechanism of autophagy by the MHY compound. The significance of this study is the finding of a novel inhibitor of autophagy with an mTOR activating effect.     

Lysosomal Turnover,but Not a Cellular Level,of Endogenous LC3 is a Marker for Autophagy

During starvation-induced autophagy in mammals, autophagosomes form and fuse with lysosomes, leading to the degradation of the intra-autophagosomal contents by lysosomal proteases. During the formation of autophagosomes, LC3 is lipidated, and this LC3-phospholipid conjugate (LC3-II) is localized on autophagosomes and autolysosomes. While intra-autophagosomal LC3-II may be degraded by lysosomal hydrolases, recent studies have regarded LC3-II accumulation as marker of autophagy. The effect of lysosomal turnover of endogenous LC3-II in this process, however, has not been considered. We therefore investigated the lysosomal turnover of endogenous LC3-II during starvation-induced autophagy using E64d and pepstatin A, which inhibit lysosomal proteases, including cathepsins B, D, and L. We found that endogenous LC3-II significantly accumulated in the presence of E64d and pepstatin A under starvation conditions, increasing about 3.5 fold in HEK293 cells and about 6.7 fold in HeLa cells compared with that in their absence, whereas the amount of LC3-II in their absence is cell-line dependent. Morphological analyses indicated that endogenous LC3-positive puncta and autolysosomes increased in HeLa cells under starvation conditions in the presence of these inhibitors. These results indicate that endogenous LC3-II is considerably degraded by lysosomal hydrolases after formation of autolysosomes, and suggest that lysosomal turnover, not a transient amount, of this protein reflects starvation-induced autophagic activity.