Molecular cloning and characterization of rat LC3A and LC3B--two novel markers of autophagosome

Rat microtubule-associated protein light chain 3 (LC3) is a homologue of yeast Atg8, an essential component of autophagy. Following synthesis, the C-terminus of rat LC3 is cleaved by a cysteine protease-Atg4, to produce LC3-I, which is located in cytosolic fraction. LC3-I can be converted to LC3-II through the processing by Atg7 (E1-like enzyme) and Atg3 (E2-like enzyme). LC3-II is modified by phosphatidylethanolamine on C-terminus and binds tightly to autophagosomal membrane. Here we reported the cloning of two novel variants of rat LC3, named LC3A and LC3B, respectively, and LC3B is an alternative splicing variant of LC3. LC3A, LC3B, and LC3 showed different expression patterns in rat tissues, suggesting a functional divergence among these proteins. When LC3A and LC3B were overexpressed, both exhibited two forms (18 and 16 kDa, representing types of I and II, separately), which might be due to post-translational modification including the characteristic C-terminal cleavage at these two proteins as similar to that found in rat LC3 and yeast Atg8. Subcellular localization demonstrated that both LC3A and LC3B are colocalized with LC3 and associated with the autophagic membranes. Mutation analysis further revealed that the conserved Gly120 residues of LC3A and LC3B are essential for their characteristic C-terminal cleavage and localization to autophagic membranes. Present data suggested that LC3A and LC3B could also be used as two novel autophagosomal markers.     

How to Interpret LC3 Immunoblotting

Microtubule-associated protein light chain 3 (LC3) is now widely used to monitor autophagy. One approach is to detect LC3 conversion (LC3-I to LC3-II) by immunoblot analysis because the amount of LC3-II is clearly correlated with the number of autophagosomes. However, LC3-II itself is degraded by autophagy, making interpretation of the results of LC3 immunoblotting problematic. Furthermore, the amount of LC3 at a certain time point does not indicate autophagic flux, and therefore, it is important to measure the amount of LC3-II delivered to lysosomes by comparing LC3-II levels in the presence and absence of lysosomal protease inhibitors. Another problem with this method is that LC3-II tends to be much more sensitive to be detected by immunoblotting than LC3-I. Accordingly, simple comparison of LC3-I and LC3-II, or summation of LC3-I and LC3-II for ratio determinations, may not be appropriate, and rather, the amount of LC3-II can be compared between samples.     

How to interpret LC3 immunoblotting

Microtubule-associated protein light chain 3 (LC3) is now widely used to monitor autophagy. One approach is to detect LC3 conversion (LC3-I to LC3-II) by immunoblot analysis because the amount of LC3-II is clearly correlated with the number of autophagosomes. However, LC3-II itself is degraded by autophagy, making interpretation of the results of LC3 immunoblotting problematic. Furthermore, the amount of LC3 at a certain time point does not indicate autophagic flux, and therefore, it is important to measure the amount of LC3-II delivered to lysosomes by comparing LC3-II levels in the presence and absence of lysosomal protease inhibitors. Another problem with this method is that LC3-II tends to be much more sensitive to be detected by immunoblotting than LC3-I. Accordingly, simple comparison of LC3-I and LC3-II, or summation of LC3-I and LC3-II for ratio determinations, may not be appropriate, and rather, the amount of LC3-II can be compared between samples.     

LC3, a mammalian homologue of yeast Apg8p, is localized in autophagosome membranes after processing

Little is known about the protein constituents of autophagosome membranes in mammalian cells. Here we demonstrate that the rat microtubule-associated protein 1 light chain 3 (LC3), a homologue of Apg8p essential for autophagy in yeast, is associated to the autophagosome membranes after processing. Two forms of LC3, called LC3-I and -II, were produced post-translationally in various cells. LC3-I is cytosolic, whereas LC3-II is membrane bound. The autophagic vacuole fraction prepared from starved rat liver was enriched with LC3-II. Immunoelectron microscopy on LC3 revealed specific labelling of autophagosome membranes in addition to the cytoplasmic labelling. LC3-II was present both inside and outside of autophagosomes. Mutational analyses suggest that LC3-I is formed by the removal of the C-terminal 22 amino acids from newly synthesized LC3, followed by the conversion of a fraction of LC3-I into LC3-II. The amount of LC3-II is correlated with the extent of autophagosome formation. LC3-II is the first mammalian protein identified that specifically associates with autophagosome membranes.     

"Autophagic flux" in normal mouse tissues: focus on endogenous LC3A processing

Autophagy is a major intracellular pathway for the degradation and recycling of long-lived proteins, mature ribosomes and even entire organelles. The best studied autophagic marker is the LC3B and it is believed that only the amount of the LC3B-II correlates with the amount of the autophagic membranes. Whether the LC3A processing, aside to LC3B, is a valuable endogenous 'autophagic flux' marker is far less clear. The specificity of rabbit polyclonal antibodies to the LC3A and the LC3B was tested against the commercial available human recombinant proteins LC3A and LC3B. In order to measure 'autophagic flux' in mouse liver, lung, kidney and heart we used: (1) a lysosomotropic reagent chloroquine, which inhibit the intra-lysosomal acidification or their fusion with autophagosome, (2) nutrient starvation as an autophagic stimulus and (3) ionizing radiation, which is known to destabilize lysosomes. According to the immunoblotting work the LC3A protein follows discrete patterns of LC3A-I and LC3A-II changes in liver, lung, kidney and heart tissues of mice, whereas the LC3B protein didn't follow the same pattern under stressor conditions. We conclude that the endogenous LC3A processing is a major marker of autophagy flux in mouse model. Fractionated samples (soluble vs. membrane fractions) should be used in immunoblotting to allow discrimination between the LC3-I soluble and the LC3-II membrane protein and kinetics. Further, when dealing with in vivo models it is necessary to check the specificity of the antibodies used against the LC3A and LC3B proteins as their expression and responsiveness is not overlapping.     

"Autophagic flux" in normal mouse tissues: Focus on endogenous LC3A processing

Autophagy is a major intracellular pathway for the degradation and recycling of long-lived proteins, mature ribosomes and even entire organelles. The best studied autophagic marker is the LC3B and it is believed that only the amount of the LC3B-II correlates with the amount of the autophagic membranes. Whether the LC3A processing, aside to LC3B, is a valuable endogenous 'autophagic flux' marker is far less clear. The specificity of rabbit polyclonal antibodies to the LC3A and the LC3B was tested against the commercial available human recombinant proteins LC3A and LC3B. In order to measure 'autophagic flux' in mouse liver, lung, kidney and heart we used: i. a lysosomotropic reagent chloroquine, which inhibit the intra-lysosomal acidification or their fusion with autophagosome, ii. nutrient starvation as an autophagic stimulus and iii. ionizing radiation, which is known to destabilize lysosomes. According to the immunoblotting work the LC3A protein follows discrete patterns of LC3A-I and LC3A-II changes in liver, lung, kidney and heart tissues of mice, whereas the LC3B protein didn't follow the same pattern under stressor conditions. We conclude that the endogenous LC3A processing is a major marker of autophagy flux in mouse model. Fractionated samples (soluble vs. membrane fractions) should be used in immunobloting to allow discrimination between the LC3-I soluble and the LC3-II membrane protein and kinetics. Further, when dealing with in vivo models it is necessary to check the specificity of the antibodies used against the LC3A and LC3B proteins as their expression and responsiveness is not overlapping.     

Selective MAP1LC3C (LC3C) autophagy requires noncanonical regulators and the C-terminal peptide

LC3s are canonical proteins necessary for the formation of autophagosomes. We have previously established that two paralogs, LC3B and LC3C, have opposite activities in renal cancer, with LC3B playing an oncogenic role and LC3C a tumor-suppressing role. LC3C is an evolutionary late gene present only in higher primates and humans. Its most distinct feature is a C-terminal 20-amino acid peptide cleaved in the process of glycine 126 lipidation. Here, we investigated mechanisms of LC3C-selective autophagy. LC3C autophagy requires noncanonical upstream regulatory complexes that include ULK3, UVRAG, RUBCN, PIK3C2A, and a member of ESCRT, TSG101. We established that postdivision midbody rings (PDMBs) implicated in cancer stem-cell regulation are direct targets of LC3C autophagy. LC3C C-terminal peptide is necessary and sufficient to mediate LC3C-dependent selective degradation of PDMBs. This work establishes a new noncanonical human-specific selective autophagic program relevant to cancer stem cells.     

Consideration about negative controls for LC3 and expression vectors for four colored fluorescent protein-LC3 negative controls

A cytosolic form of LC3 is conjugated to phosphatidylethanolamine by Atg7, an E1-like enzyme, and Atg3, an E2-like enzyme, during autophagy. To monitor intracellular autophagosomes and autolysosomes, GFP-LC3 is a useful tool. However, GFP-LC3 can aggregate without being conjugated to phosphatidylethanolamine, especially when GFP-LC3 is transiently expressed (Kuma A, Matsui M, Mizushima N. Autophagy 2007; 3:323-8). Therefore, as a negative control, we investigated a mutant human LC3DeltaG protein in which the C-terminal Gly(120) essential for LC3-lipidation is deleted, and generated a set of expression plasmids for wild-type human LC3 and mutant LC3DeltaG fused to either CFP, GFP, YFP, or HcRed at the N terminus. We found that the mutant LC3DeltaG protein does not react with human Atg7 and Atg3, indicating that LC3-lipidation does not occur, and few puncta containing mutant LC3DeltaG form under starvation conditions. As observed with wildtype HcRed-LC3, mutant HcRed-LC3DeltaG also co-localizes with polyQ150-aggregates suggesting that the colocalization of HcRed- LC3 to polyQ150-aggregates is independent of LC3-lipidation. These mutant LC3DeltaG proteins will be useful negative controls in recognizing non-specific fluorescent protein-LC3 aggregates.     

The autophagy-related protein LC3 is processed in stallion spermatozoa during short-and long-term storage and the related stressful conditions

Use of cooled and frozen semen is becoming increasingly prevalent in the equine industry. However, these procedures cause harmful effects in the sperm cell resulting in reduced cell lifespan and fertility rates. Apoptosis and necrosis-related events are increased during semen cryopreservation. However, a third type of cell death, named autophagy, has not been studied during equine semen storage. Light chain (LC)3 protein is a key component of the autophagy pathway. Under autophagy activation, LC3-I is lipidated and converted to LC3-II. The ratio of LC3-II/LC3-I is widely used as a marker of autophagy activation. The main objective of this study was to investigate whether LC3 is processed during cooling, freezing and the stressful conditions associated with these technologies. A secondary objective was to determine if LC3 processing can be modulated and if that may improve the quality of cryopreserved semen. LC3 processing was studied by Western blot with a specific antibody that recognized both LC3-I and LC3-II. Viability was assessed by flow cytometry. Modulation of LC3-I to LC3-II was studied with known autophagy activators (STF-62247 and rapamycin) or inhibitors (chloroquine and 3-MA) used in somatic cells. The results showed that conversion of LC3-I to LC3-II increased significantly during cooling at 4°C, freezing/thawing and each of the stressful conditions tested (UV radiation, oxidative stress, osmotic stress and changes in temperature). STF-62247 and rapamycin increased the LC3-II/LC3-I ratio and decreased the viability of equine sperm, whereas chloroquine and 3-MA inhibited LC3 processing and maintained the percentage of viable cells after 2 h of incubation at 37°C. Finally, refrigeration at 4°C for 96 h and freezing at −196°C in the presence of chloroquine and 3-MA resulted in higher percentages of viable cells. In conclusion, results showed that an ‘autophagy-like’ mechanism may be involved in the regulation of sperm viability during equine semen cryopreservation. Modulation of autophagy during these reproductive technologies may result in an improvement of semen quality and therefore in higher fertility rates.     

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

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

Solution structure of microtubule-associated protein light chain 3 and identification of its functional subdomains

Microtubule-associated protein (MAP) light chain 3 (LC3) is a human homologue of yeast Apg8/Aut7/Cvt5 (Atg8), which is essential for autophagy. MAP-LC3 is cleaved by a cysteine protease to produce LC3-I, which is located in cytosolic fraction. LC3-I, in turn, is converted to LC3-II through the actions of E1- and E2-like enzymes. LC3-II is covalently attached to phosphatidylethanolamine on its C terminus, and it binds tightly to autophagosome membranes. We determined the solution structure of LC3-I and found that it is divided into N- and C-terminal subdomains. Additional analysis using a photochemically induced dynamic nuclear polarization technique also showed that the N-terminal subdomain of LC3-I makes contact with the surface of the C-terminal subdomain and that LC3-I adopts a single compact conformation in solution. Moreover, the addition of dodecylphosphocholine into the LC3-I solution induced chemical shift perturbations primarily in the C-terminal subdomain, which implies that the two subdomains have different sensitivities to dodecylphosphocholine micelles. On the other hand, deletion of the N-terminal subdomain abolished binding of tubulin and microtubules. Thus, we showed that two subdomains of the LC3-I structure have distinct functions, suggesting that MAP-LC3 can act as an adaptor protein between microtubules and autophagosomes.     

The Evolutionarily Conserved Interaction Between LC3 and p62 Selectively Mediates Autophagy-Dependent Degradation of Mutant Huntingtin

Mammalian p62/sequestosome-1 protein binds to both LC3, the mammalian homologue of yeast Atg8, and polyubiquitinated cargo proteins destined to undergo autophagy-mediated degradation. We previously identified a cargo receptor-binding domain in Atg8 that is essential for its interaction with the cargo receptor Atg19 in selective autophagic processes in yeast. We, thus, sought to determine whether this interaction is evolutionally conserved from yeast to mammals. Using an amino acid replacement approach, we demonstrate that cells expressing mutant LC3 (LC3-K30D, LC3-K51A, or LC3-L53A) all exhibit defective lipidation of LC3, a disrupted LC3–p62 interaction, and impaired autophagic degradation of p62, suggesting that the p62-binding site of LC3 is localized within an evolutionarily conserved domain. Importantly, whereas cells expressing these LC3 mutants exhibited similar overall autophagic activity comparable to that of cells expressing wild-type LC3, autophagy-mediated clearance of the aggregation-prone mutant Huntingtin was defective in the mutant-expressing cells. Together, these results suggest that p62 directly binds to the evolutionarily conserved cargo receptor-binding domain of Atg8/LC3 and selectively mediates the clearance of mutant Huntingtin.     

Processing of autophagic protein LC3 by the 20S proteasome

Ubiquitin-proteasome system and autophagy are the two major mechanisms for protein degradation in eukaryotic cells. LC3, a ubiquitin-like protein, plays an essential role in autophagy through its ability to be conjugated to phosphatidylethanolamine. In this study, we discovered a novel LC3-processing activity, and biochemically purified the 20S proteasome as the responsible enzyme. Processing of LC3 by the 20S proteasome is ATP- and ubiquitin-independent, and requires both the N-terminal helices and the ubiquitin fold of LC3; and addition of the N-terminal helices of LC3 to the N terminus of ubiquitin renders ubiquitin susceptible to 20S proteasomal activity. Further, the 20S proteasome processes LC3 in a stepwise manner, it first cleaves LC3 within its ubiquitin fold and thus disrupt the conjugation function of LC3; subsequently and especially at high concentrations of the proteasome, LC3 is completely degraded. Intriguingly, proteolysis of LC3 by the 20S proteasome can be inhibited by p62, an LC3-binding protein that mediates autophagic degradation of polyubiquitin aggregates in cells. Therefore, our study implicates a potential mechanism underlying interplay between the proteasomal and autophagic pathways. This study also provides biochemical evidence suggesting relevance of the controversial ubiquitin-independent proteolytic activity of the 20S proteasome.     

Human light chain 3/MAP1LC3B is cleaved at its carboxyl-terminal Met121 to expose Gly120 for lipidation and targeting to autophagosomal membranes

Human light chain 3/MAP1LC3B, an autophagosomal ortholog of yeast Atg8, is conjugated to phospholipid (PL) via ubiquitylation-like reactions mediated by human Atg7 and Atg3. Since human Atg4B was found to cleave the carboxyl terminus of MAP1LC3B in vitro, we hypothesized that this exposes its carboxyl-terminal Gly(120). It was recently reported, however, that when Myc-MAP1LC3B-His is expressed in HEK293 cells, its carboxyl terminus is not cleaved. (Tanida, I., Sou, Y.-s., Ezaki, J., Minematsu-Ikeguchi, N., Ueno, T., and Kominami, E. (2004) J. Biol. Chem. 279, 36268-36276). To clarify this contradiction, we sought to determine whether the carboxyl terminus of MAP1LC3B is cleaved to expose Gly(120) for further ubiquitylation-like reactions. When MAP1LC3B-3xFLAG and Myc-MAP1LC3B-His were expressed in HEK293 cells, their carboxyl termini were cleaved, whereas there was little cleavage of mutant proteins MAP1LC3B(G120A)-3xFLAG and Myc-MAP1LC3B(G120A)-His, containing Ala in place of Gly(120). An in vitro assay showed that Gly(120) is essential for carboxyl-terminal cleavage by human Atg4B as well as for formation of the intermediates Atg7-MAP1LC3B (ubiquitin-activating enzyme-substrate) and Atg3-MAP1LC3B (ubiquitin carrier protein-substrate). Recombinant MAP1LC3B-PL was fractionated into the 100,000 x g pellet in a manner similar to that shown for endogenous MAP1LC3B-PL. RNA interference of MAP1LC3B mRNA resulted in a decrease in both endogenous MAP1LC3B-PL and MAP1LC3B. These results indicate that the carboxyl terminus of MAP1LC3B is cleaved to expose Gly(120) for further ubiquitylation-like reactions.     

Cytosolic LC3 ratio as a sensitive index of macroautophagy in isolated rat hepatocytes and H4-II-E cells

Macroautophagy, an intracellular bulk degradation process in eukaryotes, is sensitive to nutrient supply and deprivation. Microtubule-associated protein 1 light chain 3 (LC3), a mammalian homologue of yeast Atg8, plays an indispensable role in macroautophagy formation and is a suitable marker for this process. Through analysis of the subcellular distribution of LC3, we determined that the cytosolic fraction contained not only a precursor form (LC3-I), but also an apparent active form (LC3-IIs). Both cytosolic LC3-I and LC3-IIs were more responsive to amino acids than those of total homogenate. Moreover, changes in the LC3-IIs/I ratio reflected those in the total proteolytic flux remarkably in both fresh rat hepatocytes and H4-II-E cell lines. Thus, in addition to a sensitive index of macroautophagy, calculating the cytosolic LC3 ratio became an easy and quick quantitative method for monitoring its regulation in hepatocytes and H4-II-E cells.     

Cytosolic LC3 Ratio as a Sensitive Index of Macroautophagy in Isolated Rat Hepatocytes and H4-II-E Cells

Macroautophagy, an intracellular bulk degradation process in eukaryotes, is sensitive to nutrient supply and deprivation. Microtubule-associated protein 1 light chain 3 (LC3), a mammalian homologue of yeast Atg8, plays an indispensable role in macroautophagy formation and is a suitable marker for this process. Through analysis of the subcellular distribution of LC3, we determined that the cytosolic fraction contained not only a precursor form (LC3-I), but also an apparent active form (LC3-IIs). Both cytosolic LC3-I and LC3-IIs were more responsive to amino acids than those of total homogenate. Moreover, changes in the LC3-IIs/I ratio reflected those in the total proteolytic flux remarkably in both fresh rat hepatocytes and H4-II-E cell lines. Thus, in addition to a sensitive index of macroautophagy, calculating the cytosolic LC3 ratio became an easy and quick quantitative method for monitoring its regulation in hepatocytes and H4-II-E cells.     

LC3, an autophagosome marker, can be incorporated into protein aggregates independent of autophagy: caution in the interpretation of LC3 localization

Autophagy is an intracellular bulk degradation system, through which a portion of the cytoplasm is delivered to lysosomes to be degraded. Microtuble-associated protein light chain 3 (LC3), a mammalian homolog of yeast Atg8, has been used as a specific marker to monitor autophagy. Upon induction of autophagy, LC3 is conjugated to phosphatidylethanolamine and targeted to autophagic membranes. Therefore, changes in LC3 localization have been used to measure autophagy. However, this method has some limitations. In this report, we show that LC3 protein tends to aggregate in an autophagy-independent manner when it is transiently overexpressed by transfection. In addition, LC3 is easily incorporated into intracellular protein aggregates, such as inclusion bodies induced by polyQ expression or formed in autophagy-deficient hepatocytes, neurons, or senescent fibroblasts. These findings demonstrate that punctate dots containing LC3 do not always represent autophagic structures. Therefore, LC3 localization should be carefully interpreted, particularly if LC3 is overexpressed by transient transfection or if aggregates are formed within cells.     

Protein kinase C inhibits autophagy and phosphorylates LC3

During autophagy, the microtubule-associated protein light chain 3 (LC3), a specific autophagic marker in mammalian cells, is processed from the cytosolic form (LC3-I) to the membrane-bound form (LC3-II). In HEK293 cells stably expressing FLAG-tagged LC3, activation of protein kinase C inhibited the autophagic processing of LC3-I to LC3-II induced by amino acid starvation or rapamycin. PKC inhibitors dramatically induced LC3 processing and autophagosome formation. Unlike autophagy induced by starvation or rapamycin, PKC inhibitor-induced autophagy was not blocked by the PI-3 kinase inhibitor wortmannin. Using orthophosphate metabolic labeling, we found that LC3 was phosphorylated in response to the PKC activator PMA or the protein phosphatase inhibitor calyculin A. Furthermore, bacterially expressed LC3 was directly phosphorylated by purified PKC in vitro. The sites of phosphorylation were mapped to T6 and T29 by nanoLC-coupled tandem mass spectrometry. Mutations of these residues significantly reduced LC3 phosphorylation by purified PKC in vitro. However, in HEK293 cells stably expressing LC3 with these sites mutated either singly or doubly to Ala, Asp or Glu, autophagy was not significantly affected, suggesting that PKC regulates autophagy through a mechanism independent of LC3 phosphorylation.     

Autophagosome Proteins LC3A,LC3B and LC3C Have Distinct Subcellular Distribution Kinetics and Expression in Cancer Cell Lines

LC3s (MAP1-LC3A, B and C) are structural proteins of autophagosomal membranes, widely used as biomarkers of autophagy. Whether these three LC3 proteins have a similar biological role in autophagy remains obscure. We examine in parallel the subcellular expression patterns of the three LC3 proteins in a panel of human cancer cell lines, as well as in normal MRC5 fibroblasts and HUVEC, using confocal microscopy and western blot analysis of cell fractions. In the cytoplasm, there was a minimal co-localization between LC3A, B and C staining, suggesting that the relevant autophagosomes are formed by only one out of the three LC3 proteins. LC3A showed a perinuclear and nuclear localization, while LC3B was equally distributed throughout the cytoplasm and localized in the nucleolar regions. LC3C was located in the cytoplasm and strongly in the nuclei (excluding nucleoli), where it extensively co-localized with the LC3A and the Beclin-1 autophagy initiating protein. Beclin 1 is known to contain a nuclear trafficking signal. Blocking nuclear export function by Leptomycin B resulted in nuclear accumulation of all LC3 and Beclin-1 proteins, while Ivermectin that blocks nuclear import showed reduction of accumulation, but not in all cell lines. Since endogenous LC3 proteins are used as major markers of autophagy in clinical studies and cell lines, it is essential to check the specificity of the antibodies used, as the kinetics of these molecules are not identical and may have distinct biological roles. The distinct subcellular expression patterns of LC3s provide a basis for further studies.