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.     

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.     

SKD1 AAA ATPase-dependent endosomal transport is involved in autolysosome formation

Mouse SKD1 AAA ATPase is involved in the sorting and transport from endosomes; cells overexpressing a dominant-negative mutant, SKD1(E235Q) were defective in endosomal transport to both the plasma membranes and lysosomes (Yoshimori et al., 2000). In the present study, we demonstrated that overexpression of SKD1(E235Q) using an adenovirus delivery system caused a defect in autophagy-dependent bulk protein degradation. Morphological observations suggested that this inhibition of autophagy results from an impairment of autolysosome formation. SKD1(E235Q) overexpression also inhibited transport from endosomes to autophagosomes, an event normally occurring prior to fusion with lysosomes. These results indicate that SKD1-dependent endosomal membrane trafficking is required for formation of autolysosomes.     

Absence of cytochrome P-450 and presence of autolysosomal membrane antigens on the isolation membranes and autophagosomal membranes in rat hepatocytes

We wished to determine if phenobarbital (PB)-inducible cytochrome P-450 [P-450(PB)] and autolysosomal membrane antigens could be localized immunocytochemically on the isolation membranes and the limiting membranes of autophagosomes in rat hepatocytes by the post-embedding protein A-gold method. P-450(PB) was maximally induced by PB treatment; then formation of autophagosomes and accumulation of autolysosomes were induced by cessation of PB treatment and by injection of leupeptin, respectively. P-450(PB) was detected neither on the isolation membranes nor on the limiting membranes of autophagosomes and autolysosomes. Autolysosomal membrane antigens, which were localized by the immunogold technique exclusively in post-Golgi compartments such as lysosomes, endosomes, and plasma membrane but were not found in pre-Golgi compartments such as endoplasmic reticulum (ER) and nuclear envelope, were detected in large amounts on the isolation membranes. These results suggest that the isolation membranes originate not from ER membranes but from post-Golgi membranes. We also present direct immunoelectron microscopic evidence that P-450(PB) is indeed degraded in the autolysosomes: when rats were treated with leupeptin, P-450(PB) was detected not only within the autophagosomes but also within the autolysosomes, whereas without leupeptin treatment, P-450(PB) was detectable only within the autophagosomes.     

Autolysosomes and caspase-3 control the biogenesis and release of immunogenic apoptotic exosomes

Apoptotic exosome-like vesicles (ApoExos) are a novel type of extracellular vesicle that contribute to the propagation of inflammation at sites of vascular injury when released by dying cells. ApoExos are characterized by the presence of the C-terminal perlecan LG3 fragment and 20S proteasome, and they are produced downstream of caspase-3 activation. In the present study, we assessed the relative roles of autophagy and caspase-3-mediated pathways in controlling the biogenesis and secretion of immunogenic ApoExos. Using electron microscopy and confocal immunofluorescence microscopy in serum-starved endothelial cells, we identified large autolysosomes resulting from the fusion of lysosomes, multivesicular bodies, and autophagosomes as a site of ApoExo biogenesis. Inhibition of autophagy with ATG7 siRNA or biochemical inhibitors (wortmannin and bafilomycin) coupled with proteomics analysis showed that autophagy regulated the processing of perlecan into LG3 and its loading onto ApoExos but was dispensable for ApoExo biogenesis. Caspase-3 activation was identified using caspase-3-deficient endothelial cells or caspase inhibitors as a pivotal regulator of fusion events between autolysosomes and the cell membrane, therefore regulating the release of immunogenic ApoExos. Collectively, these findings identified autolysosomes as a site of ApoExo biogenesis and caspase-3 as a crucial regulator of autolysosome cell membrane interactions involved in the secretion of immunogenic ApoExos.Subject terms: Proteomics, Macroautophagy, Apoptosis, Lysosomes     

Autophagy in tobacco BY-2 cells cultured under sucrose starvation conditions: isolation of the autolysosome and its characterization

Tobacco culture cells carry out a large-scale degradation of intracellular proteins in order to survive under sucrose starvation conditions. We have previously suggested that this bulk degradation of cellular proteins is performed by autophagy, where autolysosomes formed de novo act as the major lytic compartments. The digestion process in autolysosomes can be retarded by addition of the cysteine protease inhibitor E-64c to the culture medium, resulting in the accumulation of autolysosomes. In the present study, we have investigated several properties of autolysosomes in tobacco cells. Electron microscopy showed that the autolysosomes contain osmiophilic particles, some of which resemble partially degraded mitochondria. It also revealed the presence of two kinds of autolysosome precursor structures; one resembled the isolation membrane and the other the autophagosome of mammalian cells. Immunofluorescence microscopy showed that autolysosomes contain acid phosphatase, in accordance with cytochemical enzyme analyses by light and electron microscopy in a previous study. Autolysosomes isolated by cell fractionation on Percoll gradients showed the localization of acid phosphatase, vacuolar H(+)-ATPase and cysteine protease. These results show that starvation-induced autophagy in tobacco cells follows a macroautophagic-type response similar to that described for other eukaryotes. However, our results indicate that, although the plant vacuole is often described as being equivalent to the lysosome of the animal cell, a new low pH lytic compartment-the autolysosome-also contributes to proteolytic degradation when tobacco cells are subjected to sucrose deprivation.     

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.     

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.     

Aurantiamide acetate suppresses the growth of malignant gliomas in vitro and in vivo by inhibiting autophagic flux

We aim to investigate the effect of aurantiamide acetate isolated from the aerial parts of Clematis terniflora DC against gliomas. Human malignant glioma U87 and U251 cells were incubated with different concentrations (0–100 μM) of aurantiamide acetate. Aurantiamide acetate greatly decreased the cell viability in a dose‐ and time‐dependent manner. It induced moderate mitochondrial fragmentation and the loss of mitochondrial membrane potential. No significant difference was found in the alternation of other intracellular organelles, although F‐actin structure was slightly disturbed. Apparent ultrastructure alternation with increased autophagosome and autolysosome accumulation was observed in aurantiamide acetate‐treated cells. The expression of LC3‐II was greatly up‐regulated in cells exposed to aurantiamide acetate (P < 0.05 compared with control). The cytoplasmic accumulation of autophagosomes and autolysosomes induced by aurantiamide acetate treatment was confirmed by fluorescent reporter protein labelling. Administration of chloroquine (CQ), which inhibits the fusion step of autophagosomes, further increased the accumulation of autophagosomes in the cytoplasm of U87 cells. Autophagy inhibition by 3‐methyladenine, Bafilomycin A1 or CQ had no influence on aurantiamide acetate‐induced cytotoxicity, whereas autophagy stimulator rapamycin significantly suppressed aurantiamide acetate‐induced cell death. The anti‐tumour effects of aurantiamide acetate were further evaluated in tumour‐bearing nude mice. Intratumoural injection of aurantiamide acetate obviously suppressed tumour growth, and increased number of autophagic vacuoles was observed in tumour tissues of animals receiving aurantiamide acetate. Our findings suggest that aurantiamide acetate may suppress the growth of malignant gliomas by blocking autophagic flux.     

Microtubule and kinesin/dynein-dependent, bi-directional transport of autolysosomes in neurites of PC12 cells

Autophagy, a major degradative pathway of the lysosomal system, has been implicated in various neurodegenerative diseases. During autophagic process, organelles and proteins are encapsulated in double-membrane vacuoles called autophagosomes, which finally fuse with lysosomes to form autolysosomes where incorporated materials are degraded. Despite extensive investigations in identifying the molecular components that participate in autophagy, little is known about routes and dynamics of autophagosomes/autolysosomes in the neurites of live cells. Hence, in the present study, we aim to investigate the biophysical characteristics of neuritic transport of autolysosomes in PC12 cells. Our study demonstrated that monomeric red fluorescence protein-light chain 3 (mRFP-LC3)-labeled autolysosomes were motile and moved along PC12 neurites in both anterograde and retrograde directions with a bias towards the nucleus during starvation. By using image processing, quantitative analysis was made to show the dynamic biophysical characteristics of these vesicles. The average velocity of anterograde and retrograde transport was 0.33±0.04μm/s and 0.39±0.05μm/s, respectively. Disruption of microtubules by nocodazole completely abolished their movements, suggesting the neuritic transport of autolysosomes depends on microtubules. The directional transport of autolysosomes was also affected by blockage of motor protein activity. Altogether, our study documents many aspects of the highly dynamic movement of autolysosome in PC12 neurites. Autolysosomes transported in a bi-directional manner along microtubules by dynein and kinesin motor proteins. These findings provide valuable insight into understanding the mechanism and control of autophagy in neurites under physiological and pathological conditions.     

Contribution of the plasma membrane and central vacuole in the formation of autolysosomes in cultured tobacco cells

Autolysosomes accumulate in tobacco cells cultured under sucrose starvation conditions in the presence of a cysteine protease inhibitor. We characterized these plant autolysosomes using fluorescent dyes and green fluorescent protein (GFP). Observation using the endocytosis markers, FM4-64 and Lucifer Yellow CH, suggested that there is a membrane flow from the plasma membrane to autolysosomes. Using these dyes as well as GFP-AtVam3p, sporamin-GFP and gamma-VM23-GFP fusion proteins as markers of the central vacuole, we found transport of components of the central vacuole to autolysosomes. Thus endocytosis and the supply from the central vacuole may contribute to the formation of autolysosomes.     

Evidence for the involvement of GD3 ganglioside in autophagosome formation and maturation

Sphingolipids are structural lipid components of cell membranes, including membrane of organelles, such as mitochondria or endoplasmic reticulum, playing a role in signal transduction as well as in the transport and intermixing of cell membranes. Sphingolipid microdomains, also called lipid rafts, participate in several metabolic and catabolic cell processes, including apoptosis. However, the defined role of lipid rafts in the autophagic flux is still unknown. In the present study we analyzed the role of gangliosides, a class of sphingolipids, in autolysosome morphogenesis in human and murine primary fibroblasts by means of biochemical and analytical cytology methods. Upon induction of autophagy, by using amino acid deprivation as well as tunicamycin, we found that GD3 ganglioside, considered as a paradigmatic raft constituent, actively contributed to the biogenesis and maturation of autophagic vacuoles. In particular, fluorescence resonance energy transfer (FRET) and coimmunoprecipitation analyses revealed that this ganglioside interacts with phosphatidylinositol 3-phosphate and can be detected in immature autophagosomes in association with LC3-II as well as in autolysosomes associated with LAMP1. Hence, it appears as a structural component of autophagic flux. Accordingly, we found that autophagy was significantly impaired by knocking down ST8SIA1/GD3 synthase (ST8 α-N-acetyl-neuraminide α-2,8-sialyltransferase 1) or by altering sphingolipid metabolism with fumonisin B1. Interestingly, exogenous administration of GD3 ganglioside was capable of reactivating the autophagic process inhibited by fumonisin B1. Altogether, these results suggest that gangliosides, via their molecular interaction with autophagy-associated molecules, could be recruited to autophagosome and contribute to morphogenic remodeling, e.g., to changes of membrane curvature and fluidity, finally leading to mature autolysosome formation.     

Evidence for the involvement of GD3 ganglioside in autophagosome formation and maturation

Sphingolipids are structural lipid components of cell membranes, including membrane of organelles, such as mitochondria or endoplasmic reticulum, playing a role in signal transduction as well as in the transport and intermixing of cell membranes. Sphingolipid microdomains, also called lipid rafts, participate in several metabolic and catabolic cell processes, including apoptosis. However, the defined role of lipid rafts in the autophagic flux is still unknown. In the present study we analyzed the role of gangliosides, a class of sphingolipids, in autolysosome morphogenesis in human and murine primary fibroblasts by means of biochemical and analytical cytology methods. Upon induction of autophagy, by using amino acid deprivation as well as tunicamycin, we found that GD3 ganglioside, considered as a paradigmatic raft constituent, actively contributed to the biogenesis and maturation of autophagic vacuoles. In particular, fluorescence resonance energy transfer (FRET) and coimmunoprecipitation analyses revealed that this ganglioside interacts with phosphatidylinositol 3-phosphate and can be detected in immature autophagosomes in association with LC3-II as well as in autolysosomes associated with LAMP1. Hence, it appears as a structural component of autophagic flux. Accordingly, we found that autophagy was significantly impaired by knocking down ST8SIA1/GD3 synthase (ST8 α-N-acetyl-neuraminide α-2,8-sialyltransferase 1) or by altering sphingolipid metabolism with fumonisin B1. Interestingly, exogenous administration of GD3 ganglioside was capable of reactivating the autophagic process inhibited by fumonisin B1. Altogether, these results suggest that gangliosides, via their molecular interaction with autophagy-associated molecules, could be recruited to autophagosome and contribute to morphogenic remodeling, e.g., to changes of membrane curvature and fluidity, finally leading to mature autolysosome formation.     

Shigella and autophagy

Bacterial invasion of eukaryotic cells, and host recognition and elimination of the invading bacteria, determines the fate of bacterial infection. Once inside mammalian cells, many pathogenic bacteria enter the host cytosol to escape from the lytic compartment and gain a replicative niche. Recent studies indicate that autophagy also recognizes intracellular bacteria. Although autophagy is a conserved membrane trafficking pathway in eukaryotic cells that sequesters undesirable or recyclable cytoplasmic components or organelles and delivers them to lysosomes, autophagy has recently been described as playing a pivotal role as an intracellular surveillance system for recognition and eradication of the pathogens that have invaded the cytoplasm. Indeed, unless they are able to circumvent entrapping by autophagosomes, bacteria ultimately undergo degradation by delivery into autolysosomes. In this review we discuss recent discoveries regarding Shigella strategies for infecting mammalian cells, and then focus on recent studies of an elegant bacterial survival strategy against autophagic degradation.     

A sensitive and quantitative autolysosome probe for detecting autophagic activity in live and prestained fixed cells

Autophagy is a complex, multi-step and biologically important pathway mediated by autophagosomes and autolysosomes. Accurately dissecting and detecting different stages of autophagy is important to elucidate its molecular mechanism and thereby facilitate the discovery of pharmaceutical molecules. We herein reported a small-molecule synthetic probe, Zn-G₄, which is only fluorescent upon starvation- or chemical agent-induced autophagy within the autolysosome or possible the late endosome/lysosome networks. The probe can be detected by one-photon microscopy, which gives a high signal-to-noise ratio readout of autophagic activity. The pH gradient-independent fluorescence can be detected both in live and prestained fixed cells. Moreover, the fluorescent recording can be used to quantify autophagic activity at a single point without transfection or false positive signals due to protein aggregation. Furthermore, autophagy-induced fluorescence in autolysosomes can also be detected by two-photon microscopy, suggesting potential applications in deep tissue and in vivo. In conclusion, we have developed a sensitive and specific autolysosomal probe that can be used for monitoring autophagy during later stages along with quantitative assays together with widely used early markers or microtubule-associated protein 1 light chain 3 (LC3)-based probes.     

A 60 kDa plasma membrane protein changes its localization to autophagosome and autolysosome membranes during induction of autophagy in rat hepatoma cell line, H-4-II-E cells.

We previously reported the preparation and characterization of an antibody against membrane fraction of autolysosomes from rat liver (J. Histochem. Cytochem. 38, 1571-1581, 1990). Immunoblot analyses of total membrane fraction of a rat hepatoma cell line, H-4-II-E cells by this antibody suggested that H-4-II-E cells expressed several autolysosomal proteins, including a protein with apparent molecular weight of 60 kDa. It was suggested that this 60 kDa protein was a peripheral membrane protein, because it was eluted from the membrane by sodium carbonate treatment. We prepared an antibody against this 60 kDa protein by affinity purification method, and examined its behavior during induction of autophagy. Autophagy was induced by transferring the cells from Dulbecco's modified Eagle medium (DMEM) containing 12% fetal calf serum into Hanks' balance salt solution. In DMEM, the 60 kDa protein showed diffused immunofluorescence pattern, and immunoelectron microscopy suggested that this protein was located on the extracellular side of the plasma membrane. After inducing autophagy, the immunofluorescence configuration of the 60 kDa protein changed from the diffused pattern to a granulous one. Immunoelectron microscopy showed that the 60 kDa protein was localized on the luminal side of the limiting membrane of autolysosomes and endosomes. In the presence of bafilomycin A1 which prevents fusion between autophagosomes and lysosomes, the 60 kDa protein was localized on the limiting membrane of the autophagosomes and endosomes. These results suggest that the 60 kDa protein is transported from the plasma membrane to the autophagosome membrane through the endosomes.     

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.     

Characterization of the isolation membranes and the limiting membranes of autophagosomes in rat hepatocytes by lectin cytochemistry

The isolation membranes and the limiting membranes of autophagosomes in rat hepatocytes were characterized by lectin cytochemistry using concanavalin A (ConA), Ricinus communis agglutinin 120 (RCA-120), and wheat germ agglutinin (WGA). We found that RCA-120, ConA, and WGA bind to these membranes. The distribution of the lectins on the isolation membranes was heterogeneous, mainly found on the rims, which we referred to as the peripheral dilated portion. When the rims fused and thus formed autophagosomes the apparent sites of fusion were strongly labeled by the lectins. After autophagosomes were transformed to autolysosomes by fusion with lysosomes, the limiting membranes became more densely and homogeneously labeled with the lectins. We previously reported that cytochrome P-450 does not exist on the limiting membranes of the autophagosomes. Taken together, these results suggest that the isolation membranes may originate not from endoplasmic reticulum membranes but from some post-Golgi membranes that contain complex type N and/or O-linked oligosaccharide chains.     

Classes of programmed cell death in plants, compared to those in animals

Relatively little is known about programmed cell death (PCD) in plants. It is nonetheless suggested here that tonoplast rupture and the subsequent rapid destruction of the cytoplasm can distinguish two large PCD classes. One class, which is here called 'autolytic', shows this feature, whilst the second class (called 'non-autolytic') can include tonoplast rupture but does not show the rapid cytoplasm clearance. Examples of the 'autolytic' PCD class mainly occur during normal plant development and after mild abiotic stress. The 'non-autolytic' PCD class is mainly found during PCD that is due to plant-pathogen interactions. Three categories of PCD are currently recognized in animals: apoptosis, autophagy, and necrosis. An attempt is made to reconcile the recognized plant PCD classes with these groups. Apoptosis is apparently absent in plants. Autophagic PCD in animals is defined as being accompanied by an increase in the number of autophagosomes, autolysosomes, and small lytic vacuoles produced by autolysosomes. When very strictly adhering to this definition, there is no (proof for) autophagic PCD in plants. Upon a slightly more lenient definition, however, the 'autolytic' class of plant PCD can be merged with the autophagic PCD type in animal cells. The 'non-autolytic' class of plant PCD, as defined here, can be merged with necrotic PCD in animals.     

LC3 fluorescent puncta in autophagosomes or in protein aggregates can be distinguished by FRAP analysis in living cells

LC3 is a marker protein that is involved in the formation of autophagosomes and autolysosomes, which are usually characterized and monitored by fluorescence microscopy using fluorescent protein-tagged LC3 probes (FP-LC3). FP-LC3 and even endogenous LC3 can also be incorporated into intracellular protein aggregates in an autophagy-independent manner. However, the dynamic process of LC3 associated with autophagosomes and autolysosomes or protein aggregates in living cells remains unclear. Here, we explored the dynamic properties of the two types of FP-LC3-containing puncta using fluorescence microscopy techniques, including fluorescence recovery after photobleaching (FRAP) and fluorescence resonance energy transfer (FRET). The FRAP data revealed that the fluorescent signals of FP-LC3 attached to phagophores or in mature autolysosomes showed either minimal or no recovery after photobleaching, indicating that the dissociation of LC3 from the autophagosome membranes may be very slow. In contrast, FP-LC3 in the protein aggregates exhibited nearly complete recovery (more than 80%) and rapid kinetics of association and dissociation (half-time < 1 sec), indicating a rapid exchange occurs between the aggregates and cytoplasmic pool, which is mainly due to the transient interaction of LC3 and SQSTM1/p62. Based on the distinct dynamic properties of FP-LC3 in the two types of punctate structures, we provide a convenient and useful FRAP approach to distinguish autophagosomes from LC3-involved protein aggregates in living cells. Using this approach, we find the FP-LC3 puncta that adjacently localized to the phagophore marker ATG16L1 were protein aggregate-associated LC3 puncta, which exhibited different kinetics compared with that of autophagic structures.