A monitoring method for Atg4 activation in living cells using peptide-conjugated polymeric nanoparticles

To date, several principal methods are presently used to monitor the autophagic process, but they have some potential experimental pitfalls or limitations that make them not applicable to living cells. In order to improve on the currently developed detection methods for autophagy, we report here fluorescent peptide-conjugated polymeric nanoparticles loaded with a lysosome staining dye in their core. The fluorescent peptide is designed to be specifically cleaved by the Atg4 cysteine protease, which plays a crucial role in autophagy activation. In this study, we demonstrate that peptide-conjugated polymeric nanoparticles can be used to visualize Atg4 activity in both cell-free and cell culture systems. The fluorescence imaging of cells incubated with nanoparticles demonstrates that Atg4 activity is activated in the autophagy-induced conditions, but suppressed in the autophagy-inhibited conditions. These results indicate that Atg4 activity is correlated with autophagic flux through its own regulatory pathway. Therefore, our strategy provides an alternative detection method that can clearly distinguish between an “autophagy active” and “autophagy inactive” state in cultured cells. As our nanoparticles are highly cell-permeable and biocompatible, this detection system has general applicability to living cells and can be extended to cell-based screening to evaluate newly developed compounds.     

Rab7b modulates autophagic flux by interacting with Atg4B

Autophagy (macroautophagy) is a highly conserved eukaryotic degradation pathway in which cytosolic components and organelles are sequestered by specialized autophagic membranes and degraded through the lysosomal system. The autophagic pathway maintains basal cellular homeostasis and helps cells adapt during stress; thus, defects in autophagy can cause detrimental effects. It is therefore crucial that autophagy is properly regulated. In this study, we show that the cysteine protease Atg4B, a key enzyme in autophagy that cleaves LC3, is an interactor of the small GTPase Rab7b. Indeed, Atg4B interacts and co‐localizes with Rab7b on vesicles. Depletion of Rab7b increases autophagic flux as indicated by the increased size of autophagic structures as well as the magnitude of macroautophagic sequestration and degradation. Importantly, we demonstrate that Rab7b regulates LC3 processing by modulating Atg4B activity. Taken together, our findings reveal Rab7b as a novel negative regulator of autophagy through its interaction with Atg4B.     

A high-throughput FRET-based assay for determination of Atg4 activity

Atg4 is required for cleaving Atg8, allowing it to be conjugated to phosphatidylethanolamine on phagophore membranes, a key step in autophagosome biogenesis. Deconjugation of Atg8 from autophagosomal membranes could be also a regulatory step in controlling autophagy. Therefore, the activity of Atg4 is important for autophagy and could be a target for therapeutic intervention. In this study, a sensitive and specific method to measure the activity of two Atg4 homologs in mammalian cells, Atg4A and Atg4B, was developed using a fluorescence resonance energy transfer (FRET)-based approach. Thus LC3B and GATE-16, two substrates that could be differentially cleaved by Atg4A and Atg4B, were fused with CFP and YFP at the N- and C-terminus, respectively, allowing FRET to occur. The FRET signals decreased in proportion to the Atg4-mediated cleavage, which separated the two fluorescent proteins. This method is highly efficient for measuring the enzymatic activity and kinetics of Atg4A and Atg4B under in vitro conditions. Applications of the assay indicated that the activity of Atg4B was dependent on its catalytic cysteine and expression level, but showed little changes under several common autophagy conditions. In addition, the assays displayed excellent performance in high throughput format and are suitable for screening and analysis of potential modulators. In summary, the FRET-based assay is simple and easy to use, is sensitive and specific, and is suitable for both routine measurement of Atg4 activity and high-throughput screening.     

A high-throughput FRET-based assay for determination of Atg4 activity

Atg4 is required for cleaving Atg8, allowing it to be conjugated to phosphatidylethanolamine on phagophore membranes, a key step in autophagosome biogenesis. Deconjugation of Atg8 from autophagosomal membranes could be also a regulatory step in controlling autophagy. Therefore, the activity of Atg4 is important for autophagy and could be a target for therapeutic intervention. In this study, a sensitive and specific method to measure the activity of two Atg4 homologs in mammalian cells, Atg4A and Atg4B, was developed using a fluorescence resonance energy transfer (FRET)-based approach. Thus LC3B and GATE-16, two substrates that could be differentially cleaved by Atg4A and Atg4B, were fused with CFP and YFP at the N- and C-terminus, respectively, allowing FRET to occur. The FRET signals decreased in proportion to the Atg4-mediated cleavage, which separated the two fluorescent proteins. This method is highly efficient for measuring the enzymatic activity and kinetics of Atg4A and Atg4B under in vitro conditions. Applications of the assay indicated that the activity of Atg4B was dependent on its catalytic cysteine and expression level, but showed little changes under several common autophagy conditions. In addition, the assays displayed excellent performance in high throughput format and are suitable for screening and analysis of potential modulators. In summary, the FRET-based assay is simple and easy to use, is sensitive and specific, and is suitable for both routine measurement of Atg4 activity and high-throughput screening.     

Endoplasmic reticulum stress triggers autophagy

Eukaryotic cells have evolved strategies to respond to stress conditions. For example, autophagy in yeast is primarily a response to the stress of nutrient limitation. Autophagy is a catabolic process for the degradation and recycling of cytosolic, long lived, or aggregated proteins and excess or defective organelles. In this study, we demonstrate a new pathway for the induction of autophagy. In the endoplasmic reticulum (ER), accumulation of misfolded proteins causes stress and activates the unfolded protein response to induce the expression of chaperones and proteins involved in the recovery process. ER stress stimulated the assembly of the pre-autophagosomal structure. In addition, autophagosome formation and transport to the vacuole were stimulated in an Atg protein-dependent manner. Finally, Atg1 kinase activity reflects both the nutritional status and autophagic state of the cell; starvation-induced autophagy results in increased Atg1 kinase activity. We found that Atg1 had high kinase activity during ER stress-induced autophagy. Together, these results indicate that ER stress can induce an autophagic response.     

Tissue-specific autophagy alterations and increased tumorigenesis in mice deficient in Atg4C/autophagin-3

Atg4C/autophagin-3 is a member of a family of cysteine proteinases proposed to be involved in the processing and delipidation of the mammalian orthologues of yeast Atg8, an essential component of an ubiquitin-like modification system required for execution of autophagy. To date, the in vivo role of the different members of this family of proteinases remains unclear. To gain further insights into the functional relevance of Atg4 orthologues, we have generated mutant mice deficient in Atg4C/autophagin-3. These mice are viable and fertile and do not display any obvious abnormalities, indicating that they are able to develop the autophagic response required during the early neonatal period. However, Atg4C-/--starved mice show a decreased autophagic activity in the diaphragm as assessed by immunoblotting studies and by fluorescence microscopic analysis of samples from Atg4C-/- GFP-LC3 transgenic mice. In addition, animals deficient in Atg4C show an increased susceptibility to develop fibrosarcomas induced by chemical carcinogens. Based on these results, we propose that Atg4C is not essential for autophagy development under normal conditions but is required for a proper autophagic response under stressful conditions such as prolonged starvation. We also propose that this enzyme could play an in vivo role in events associated with tumor progression.     

Dissecting the function of Atg1 complex in Dictyostelium autophagy reveals a connection with the pentose phosphate pathway enzyme transketolase

The network of protein–protein interactions of the Dictyostelium discoideum autophagy pathway was investigated by yeast two-hybrid screening of the conserved autophagic proteins Atg1 and Atg8. These analyses confirmed expected interactions described in other organisms and also identified novel interactors that highlight the complexity of autophagy regulation. The Atg1 kinase complex, an essential regulator of autophagy, was investigated in detail here. The composition of the Atg1 complex in D. discoideum is more similar to mammalian cells than to Saccharomyces cerevisiae as, besides Atg13, it contains Atg101, a protein not conserved in this yeast. We found that Atg101 interacts with Atg13 and genetic disruption of these proteins in Dictyostelium leads to an early block in autophagy, although the severity of the developmental phenotype and the degree of autophagic block is higher in Atg13-deficient cells. We have also identified a protein containing zinc-finger B-box and FNIP motifs that interacts with Atg101. Disruption of this protein increases autophagic flux, suggesting that it functions as a negative regulator of Atg101. We also describe the interaction of Atg1 kinase with the pentose phosphate pathway enzyme transketolase (TKT). We found changes in the activity of endogenous TKT activity in strains lacking or overexpressing Atg1, suggesting the presence of an unsuspected regulatory pathway between autophagy and the pentose phosphate pathway in Dictyostelium that seems to be conserved in mammalian cells.     

Atg22 recycles amino acids to link the degradative and recycling functions of autophagy

In response to stress conditions (such as nutrient limitation or accumulation of damaged organelles) and certain pathological situations, eukaryotic cells use autophagy as a survival mechanism. During nutrient stress the main purpose of autophagy is to degrade cytoplasmic materials within the lysosome/vacuole lumen and generate an internal nutrient pool that is recycled back to the cytosol. This study elucidates a molecular mechanism for linking the degradative and recycling roles of autophagy. We show that in contrast to published studies, Atg22 is not directly required for the breakdown of autophagic bodies within the lysosome/vacuole. Instead, we demonstrate that Atg22, Avt3, and Avt4 are partially redundant vacuolar effluxers, which mediate the efflux of leucine and other amino acids resulting from autophagic degradation. The release of autophagic amino acids allows the maintenance of protein synthesis and viability during nitrogen starvation. We propose a "recycling" model that includes the efflux of macromolecules from the lysosome/vacuole as the final step of autophagy.     

Advantages and Limitations of Different p62-Based Assays for Estimating Autophagic Activity in Drosophila

Levels of the selective autophagy substrate p62 have been established in recent years as a specific readout for basal autophagic activity. Here we compared different experimental approaches for using this assay in Drosophila larvae. Similar to the more commonly used western blots, quantifying p62 dots in immunostained fat body cells of L3 stage larvae detected a strong accumulation of endogenous p62 aggregates in null mutants for Atg genes and S6K. Importantly, genes whose mutation or silencing results in early stage lethality can only be analyzed by microscopy using clonal analysis. The loss of numerous general housekeeping genes show a phenotype in large-scale screens including autophagy, and the p62 assay was potentially suitable for distinguishing bona fide autophagy regulators from silencing of a DNA polymerase subunit or a ribosomal gene that likely has a non-specific effect on autophagy. p62 accumulation upon RNAi silencing of known autophagy regulators was dependent on the duration of the knockdown effect, unlike in the case of starvation-induced autophagy. The endogenous p62 assay was more sensitive than a constitutively overexpressed p62-GFP reporter, which showed self-aggregation and large-scale accumulation even in control cells. We recommend western blots for following the conversion of overexpressed p62-GFP reporters to estimate autophagic activity if sample collection from mutant larvae or adults is possible. In addition, we also showed that overexpressed p62 or Atg8 reporters can strongly influence the phenotypes of each other, potentially giving rise to false or contradicting results. Overexpressed p62 aggregates also incorporated Atg8 reporter molecules that might lead to a wrong conclusion of strongly enhanced autophagy, whereas expression of an Atg8 reporter transgene rescued the inhibitory effect of a dominant-negative Atg4 mutant on basal and starvation-induced autophagy.     

The Atg18-Atg2 complex is recruited to autophagic membranes via phosphatidylinositol 3-phosphate and exerts an essential function

Atg18 is essential for both autophagy and the regulation of vacuolar morphology. The latter process is mediated by phosphatidylinositol 3,5-bisphosphate binding, which is dispensable for autophagy. Atg18 also binds to phosphatidylinositol 3-phosphate (PtdIns(3)P) in vitro. Here, we investigate the relationship between PtdIns(3)P-binding of Atg18 and autophagy. Using an Atg18 variant, Atg18(FTTG), which is unable to bind phosphoinositides, we found that PtdIns(3)P binding of Atg18 is essential for full activity in both selective and nonselective autophagy. Atg18(FTTG) formed a complex with Atg2 in a normal manner, and Atg18-Atg2 complex formation occurred in cells in the absence of PtdIns(3)P, indicating that Atg18-Atg2 complex formation is independent of PtdIns(3)P-binding of Atg18. Atg18 localized to endosomes, the vacuolar membrane, and autophagic membranes, whereas Atg18(FTTG) did not localize to these structures. The localization of Atg2 to autophagic membranes was also lost in Atg18(FTTG) cells. These data indicate that PtdIns(3)P-binding of Atg18 is involved in directing the Atg18-Atg2 complex to autophagic membranes. Connection of a 2xFYVE domain, a specific PtdIns(3)P-binding domain, to the C terminus of Atg18(FTTG) restored the localization of Atg18-Atg2 to autophagic membranes and full autophagic activity, indicating that PtdIns(3)P-binding by Atg18 is dispensable for the function of the Atg18-Atg2 complex but is required for its localization. This also suggests that PtdIns(3)P does not act allosterically on Atg18. Taken together, Atg18 forms a complex with Atg2 irrespective of PtdIns(3)P binding, associates tightly to autophagic membranes by interacting with PtdIns(3)P, and plays an essential role.     

Autophagy plays a critical role in kidney tubule maintenance, aging and ischemia-reperfusion injury

Autophagy is responsible for the degradation of protein aggregates and damaged organelles. Several studies have reported increased autophagic activity in tubular cells after kidney injury. Here, we examine the role of tubular cell autophagy in vivo under both physiological conditions and stress using two different tubular-specific Atg5-knockout mouse models. While Atg5 deletion in distal tubule cells does not cause a significant alteration in kidney function, deleting Atg5 in both distal and proximal tubule cells results in impaired kidney function. Already under physiological conditions, Atg5-null tubule cells display a significant accumulation of p62 and oxidative stress markers. Strikingly, tubular cell Atg5-deficiency dramatically sensitizes the kidneys to ischemic injury, resulting in impaired kidney function, accumulation of damaged mitochondria as well as increased tubular cell apoptosis and proliferation, highlighting the critical role that autophagy plays in maintaining tubular cell integrity during stress conditions.     

Autophagy plays a protective role during zVAD-induced necrotic cell death

The aim of this study is to examine the role of autophagy in cell death by using a well-established system in which zVAD, a pan-caspase inhibitor, induces necrotic cell death in L929 murine fibrosarcoma cells. First, we observed the presence of autophagic hallmarks, including an increased number of autophagosomes and the accumulation of LC3-II in zVAD-treated L929 cells. Since the presence of such autophagic hallmarks could be the result of either increased flux of autophagy or blockage of autophagosome maturation (lysosomal fusion and degradation), we next tested the effect of rapamycin, a specific inhibitor for mTOR, and chloroquine, a lysosomal enzyme inhibitor, on zVAD-induced cell death. To our surprise, rapamycin, known to be an autophagy inducer, blocked zVAD-induced cell death, whereas chloroquine greatly sensitized zVAD-induced cell death in L929 cells. Moreover, similar results with rapamycin and chloroquine were also observed in U937 cells when challenged with zVAD. Consistently, induction of autophagy by serum starvation offered significant protection against zVAD-induced cell death, whereas knockdown of Atg5, Atg7 or Beclin 1 markedly sensitized zVAD-induced cell death in L929 cells. More importantly, Atg genes knockdown completely abolished the protective effect of serum starvation on zVAD-induced cell death. Finally, we demonstrated that zVAD was able to inhibit lysosomal enzyme cathepsin B activity, and subsequently blocked autophagosome maturation. Taken together, in contrast to the previous conception that zVAD induces autophagic cell death, here we provide compelling evidence suggesting that autophagy serves as a cell survival mechanism and suppression of autophagy via inhibition of lysosomal function contributes to zVAD-induced necrotic cell death.     

Essential role for the ATG4B protease and autophagy in bleomycin-induced pulmonary fibrosis

Autophagy is a critical cellular homeostatic process that controls the turnover of damaged organelles and proteins. Impaired autophagic activity is involved in a number of diseases, including idiopathic pulmonary fibrosis suggesting that altered autophagy may contribute to fibrogenesis. However, the specific role of autophagy in lung fibrosis is still undefined. In this study, we show for the first time, how autophagy disruption contributes to bleomycin-induced lung fibrosis in vivo using an Atg4b-deficient mouse as a model. Atg4b-deficient mice displayed a significantly higher inflammatory response at 7 d after bleomycin treatment associated with increased neutrophilic infiltration and significant alterations in proinflammatory cytokines. Likewise, we found that Atg4b disruption resulted in augmented apoptosis affecting predominantly alveolar and bronchiolar epithelial cells. At 28 d post-bleomycin instillation Atg4b-deficient mice exhibited more extensive and severe fibrosis with increased collagen accumulation and deregulated extracellular matrix-related gene expression. Together, our findings indicate that the ATG4B protease and autophagy play a crucial role protecting epithelial cells against bleomycin-induced stress and apoptosis, and in the regulation of the inflammatory and fibrotic responses.     

Direct induction of autophagy by Atg1 inhibits cell growth and induces apoptotic cell death

BACKGROUND: To survive starvation and other forms of stress, eukaryotic cells undergo a lysosomal process of cytoplasmic degradation known as autophagy. Autophagy has been implicated in a number of cellular and developmental processes, including cell-growth control and programmed cell death. However, direct evidence of a causal role for autophagy in these processes is lacking, resulting in part from the pleiotropic effects of signaling molecules such as TOR that regulate autophagy. Here, we circumvent this difficulty by directly manipulating autophagy rates in Drosophila through the autophagy-specific protein kinase Atg1. RESULTS: We find that overexpression of Atg1 is sufficient to induce high levels of autophagy, the first such demonstration among wild-type Atg proteins. In contrast to findings in yeast, induction of autophagy by Atg1 is dependent on its kinase activity. We find that cells with high levels of Atg1-induced autophagy are rapidly eliminated, demonstrating that autophagy is capable of inducing cell death. However, this cell death is caspase dependent and displays DNA fragmentation, suggesting that autophagy represents an alternative induction of apoptosis, rather than a distinct form of cell death. In addition, we demonstrate that Atg1-induced autophagy strongly inhibits cell growth and that Atg1 mutant cells have a relative growth advantage under conditions of reduced TOR signaling. Finally, we show that Atg1 expression results in negative feedback on the activity of TOR itself. CONCLUSIONS: Our results reveal a central role for Atg1 in mounting a coordinated autophagic response and demonstrate that autophagy has the capacity to induce cell death. Furthermore, this work identifies autophagy as a critical mechanism by which inhibition of TOR signaling leads to reduced cell growth.     

Insulin withdrawal-induced cell death in adult hippocampal neural stem cells as a model of autophagic cell death

The term "autophagic cell death" was coined to describe a form of cell death associated with the massive formation of autophagic vacuoles without signs of apoptosis. However, questions about the actual role of autophagy and its molecular basis in cell death remain to be elucidated. We recently reported that adult hippocampal neural stem (HCN) cells undergo autophagic cell death following insulin withdrawal. Insulin-deprived HCN cells exhibit morphological and biochemical markers of autophagy, including accumulation of Beclin 1 and the type II form of microtubule-associated protein 1 light chain 3 (LC3) without evidence of apoptosis. Suppression of autophagy by knockdown of Atg7 reduces cell death, whereas promotion of autophagy with rapamycin augments cell death in insulin-deficient HCN cells. These data reveal a causative role of autophagy in insulin withdrawal-induced HCN cell death. HCN cells have intact apoptotic capability despite the lack of apoptosis following insulin withdrawal. Our study demonstrates that autophagy is the default cell death mechanism in insulin-deficient HCN cells, and provides a genuine model of autophagic cell death in apoptosis-intact cells. Novel insight into molecular mechanisms of this underappreciated form of programmed cell death should facilitate the development of therapeutic methods to cope with human diseases caused by dysregulated cell death.     

Autophagy plays a protective role during zVAD-induced necrotic cell death

The aim of this study is to examine the role of autophagy in cell death by using a well-established system in which zVAD, a pan-caspase inhibitor, induces necrotic cell death in L929 murine fibrosarcoma cells. First, we observed the presence of autophagic hallmarks, including an increased number of autophagosomes and the accumulation of LC3-II in zVAD-treated L929 cells. Since the presence of such autophagic hallmarks could be the result of either increased flux of autophagy or blockage of autophagosome maturation (lysosomal fusion and degradation), we next tested the effect of rapamycin, a specific inhibitor for mTOR, and chloroquine, a lysosomal enzyme inhibitor, on zVAD-induced cell death. To our surprise, rapamycin, known to be an autophagy inducer, blocked zVAD-induced cell death, whereas chloroquine greatly sensitized zVAD-induced cell death in L929 cells. Moreover, similar results with rapamycin and chloroquine were also observed in U937 cells when challenged with zVAD. Consistently, induction of autophagy by serum starvation offered significant protection against zVAD-induced cell death, whereas knockdown of Atg5, Atg7 or Beclin 1 markedly sensitized zVAD-induced cell death in L929 cells. More importantly, Atg genes knockdown completely abolished the protective effect of serum starvation on zVAD-induced cell death. Finally, we demonstrated that zVAD was able to inhibit lysosomal enzyme cathepsin B activity, and subsequently blocked autophagosome maturation. Taken together, in contrast to the previous conception that zVAD induces autophagic cell death, here we provide compelling evidence suggesting that autophagy serves as a cell survival mechanism and suppression of autophagy via inhibition of lysosomal function contributes to zVAD-induced necrotic cell death.     

Utilizing flow cytometry to monitor autophagy in living mammalian cells

Autophagy is a major intracellular catabolic pathway that takes part in diverse biological events including response to amino acid starvation, protein and organelle turnover, development, aging, pathogen infection and cell death. However, experimental methods to monitor this process in mammalian cells are limited due to lack of autophagic markers. Recently, MAP1-LC3 (LC3), a mammalian homologue of the ubiquitin-like (UBL) protein Atg8, was shown to selectively incorporate into autophagosome, thus serving as a unique bona fide marker of autophagosomes in mammals. However, current methods to quantify autophagic activity using LC3 are time-consuming, labor-intensive and require much experience for accurate interpretation. Here we took advantage of the Fluorescence Activated Cell Sorter (FACS) to quantify the turnover of GFP-LC3 as an assay to measure autophagic activity in living mammalian cells. We showed that during induction of autophagy by rapamycin, tunicamycin or starvation to amino acids, fluorescence intensity of GFP-LC3 is reduced in a time-dependent manner. This decrease occurred specifically in wild type LC3, but not in mutant LC3^G120A, and was inhibited by autophagic or lysosomal inhibitors, indicating that this signal is specific to selective autophagy-mediated delivery of LC3 into lysosomes. By utilizing this assay, we tested the minimal nutrient requirement for the autophagic process and determined its induction by deprivation of specific single amino acids. We conclude that this approach can be successfully applied to different cell-lines as a reliable and simple method to quantify autophagic activity in living mammalian cells.     

Utilizing flow cytometry to monitor autophagy in living mammalian cells

Autophagy is a major intracellular catabolic pathway that takes part in diverse biological events including response to amino acid starvation, protein and organelle turnover, development, aging, pathogen infection and cell death. However, experimental methods to monitor this process in mammalian cells are limited due to lack of autophagic markers. Recently, MAP1-LC3 (LC3), a mammalian homologue of the ubiquitin-like (UBL) protein Atg8, was shown to selectively incorporate into autophagosome, thus serving as a unique bona fide marker of autophagosomes in mammals. However, current methods to quantify autophagic activity using LC3 are time-consuming, labor-intensive and require much experience for accurate interpretation. Here we took advantage of the Fluorescence Activated Cell Sorter (FACS) to quantify the turnover of GFP-LC3 as an assay to measure autophagic activity in living mammalian cells. We showed that during induction of autophagy by rapamycin, tunicamycin or starvation to amino acids, fluorescence intensity of GFP-LC3 is reduced in a time-dependent manner. This decrease occurred specifically in wild type LC3, but not in mutant LC3(G120A), and was inhibited by autophagic or lysosomal inhibitors, indicating that this signal is specific to selective autophagy-mediated delivery of LC3 into lysosomes. By utilizing this assay, we tested the minimal nutrient requirement for the autophagic process and determined its induction by deprivation of specific single amino acids. We conclude that this approach can be successfully applied to different cell-lines as a reliable and simple method to quantify autophagic activity in living mammalian cells.     

An Atg1/Atg13 Complex with Multiple Roles in TOR-mediated Autophagy Regulation

The TOR kinases are conserved negative regulators of autophagy in response to nutrient conditions, but the signaling mechanisms are poorly understood. Here we describe a complex containing the protein kinase Atg1 and the phosphoprotein Atg13 that functions as a critical component of this regulation in Drosophila. We show that knockout of Atg1 or Atg13 results in a similar, selective defect in autophagy in response to TOR inactivation. Atg1 physically interacts with TOR and Atg13 in vivo, and both Atg1 and Atg13 are phosphorylated in a nutrient-, TOR- and Atg1 kinase-dependent manner. In contrast to yeast, phosphorylation of Atg13 is greatest under autophagic conditions and does not preclude Atg1-Atg13 association. Atg13 stimulates both the autophagic activity of Atg1 and its inhibition of cell growth and TOR signaling, in part by disrupting the normal trafficking of TOR. In contrast to the effects of normal Atg13 levels, increased expression of Atg13 inhibits autophagosome expansion and recruitment of Atg8/LC3, potentially by decreasing the stability of Atg1 and facilitating its inhibitory phosphorylation by TOR. Atg1-Atg13 complexes thus function at multiple levels to mediate and adjust nutrient-dependent autophagic signaling.     

Mitochondria regulate autophagy by conserved signalling pathways

Autophagy is a conserved degradative process that is crucial for cellular homeostasis and cellular quality control via the selective removal of subcellular structures such as mitochondria. We demonstrate that a regulatory link exists between mitochondrial function and autophagy in Saccharomyces cerevisiae. During amino-acid starvation, the autophagic response consists of two independent regulatory arms-autophagy gene induction and autophagic flux-and our analysis indicates that mitochondrial respiratory deficiency severely compromises both. We show that the evolutionarily conserved protein kinases Atg1, target of rapamycin kinase complex I, and protein kinase A (PKA) regulate autophagic flux, whereas autophagy gene induction depends solely on PKA. Within this regulatory network, mitochondrial respiratory deficiency suppresses autophagic flux, autophagy gene induction, and recruitment of the Atg1-Atg13 kinase complex to the pre-autophagosomal structure by stimulating PKA activity. Our findings indicate an interrelation of two common risk factors-mitochondrial dysfunction and autophagy inhibition-for ageing, cancerogenesis, and neurodegeneration.