Endosomal microautophagy is an integrated part of the autophagic response to amino acid starvation

Starvation is a fundamental type of stress naturally occurring in biological systems. All organisms have therefore evolved different safeguard mechanisms to cope with deficiencies in various types of nutrients. Cells, from yeast to humans, typically respond to amino acid starvation by initiating degradation of cellular components by inducing autophagy. This degradation releases metabolic building blocks to sustain essential core cellular processes. Increasing evidence indicates that starvation-induced autophagy also acts to prepare cells for prolonged starvation by degrading key regulators of different cellular processes. In a recent study, we found that within the first hours of amino acid starvation cells elicit an autophagic response causing rapid degradation of specific proteins. The response is executed independently of both MTOR and canonical macroautophagy. Based on RNAi-mediated knockdown of essential components of the Endosomal Sorting Complex Required for Transport (ESCRT) machinery and electron microscopy we conclude that the response relies on some sort of endosomal microautophagy, hence vesicle budding into endosomes. Substantiated by the different substrates that are selectively degraded by this novel pathway we propose that the response predominantly acts to prepare cells for prolonged starvation. Intriguingly, this includes shutting down selective macroautophagy in preparation for a massive induction of bulk macroautophagy.     

Autophagy defects contribute to neurodegeneration induced by dysfunctional ESCRT-III

The endosomal sorting complex required for transport (ESCRT) machinery is involved in multiple cellular processes, including autophagy (macroautophagy). Autophagy is an important intracellular pathway that involves the formation and maturation of autophagosomes and their fusion with lysosomes for bulk degradation of cytoplasmic contents and organelles. In flies and cultured mammalian cells, autophagosomes accumulate when ESCRT-III is rendered dysfunctional by reduced activity of its subunits or by ectopic expression of mutant CHMP2B associated with frontotemporal dementia linked to chromosome 3 (FTD3). Compromised ESCRT-III function results in eventual neuronal cell loss; however, the mechanism of this form of neurodegeneration is largely unknown. Recently, we found that inhibiting autophagy induction in cultured cortical neurons, either by small-molecule inhibitors of phosphatidylinositol 3-kinases (PtdIns3K) or by loss of atg5 or atg7 activity, delays but does not completely suppress neuronal cell loss caused by dysfunctional ESCRT-III. These findings indicate that excess accumulation of autophagosomes is detrimental to neuronal survival, and dysfunctional ESCRT-III appears to cause neurodegeneration through multiple mechanisms.     

ATG5-knockout mutants of Physcomitrella provide a platform for analyzing the involvement of autophagy in senescence processes in plant cells

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted ATG5, an autophagy-related gene, in Physcomitrella, and confirmed that atg5 mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, atg5 colonies turned yellow earlier than the wild-type (WT) colonies, showing that Physcomitrella atg5 mutants, like yeast and Arabidopsis, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in atg5 colonies than WT colonies. The sugar content was almost the same between WT and atg5 colonies, indicating that the early-senescence phenotype of atg5 is not explained by sugar deficiency. However, the levels of 7 amino acids showed significantly different alteration between atg5 and WT in the dark: 6 amino acids, particularly arginine and alanine, were much more deficient in the atg5 mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in atg5 mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in Physcomitrella.     

Autophagy proteins play cytoprotective and cytocidal roles in leucine starvation-induced cell death in Saccharomyces cerevisiae

Autophagy is essential for prolonging yeast survival during nutrient deprivation; however, this report shows that some autophagy proteins may also be accelerating population death in those conditions. While leucine starvation caused YCA1-mediated apoptosis characterized by increased annexin V staining, nitrogen deprivation triggered necrotic death characterized by increased propidium iodide uptake. Although a Δatg8 strain died faster than its parental strain during nitrogen starvation, this mutant died slower than its parent during leucine starvation. Conversely, a Δatg11 strain died slower than its parent during nitrogen starvation, but faster during leucine starvation. Curiously, although GFP-Atg8 complemented the Δatg8 mutation, this protein made ATG8 cells more sensitive to nitrogen starvation, and less sensitive to leucine starvation. These results were difficult to explain if autophagy only extended life but could be an indication that a second form of autophagy could concurrently facilitate either apoptotic or necrotic cell death.     

ATG8 lipidation and ATG8‐mediated autophagy in Arabidopsis require ATG12 expressed from the differentially controlled ATG12A AND ATG12B loci

Autophagic recycling of intracellular plant constituents is maintained at a basal level under normal growth conditions but can be induced in response to nutritional demand, biotic stress, and senescence. One route requires the ubiquitin‐fold proteins Autophagy‐related (ATG)‐8 and ATG12, which become attached to the lipid phosphatidylethanolamine (PE) and the ATG5 protein, respectively, during formation of the engulfing vesicle and delivery of its cargo to the vacuole for breakdown. Here, we genetically analyzed the conjugation machinery required for ATG8/12 modification in Arabidopsis thaliana with a focus on the two loci encoding ATG12. Whereas single atg12a and atg12b mutants lack phenotypic consequences, atg12a atg12b double mutants senesce prematurely, are hypersensitive to nitrogen and fixed carbon starvation, and fail to accumulate autophagic bodies in the vacuole. By combining mutants eliminating ATG12a/b, ATG5, or the ATG10 E2 required for their condensation with a method that unequivocally detects the ATG8‐PE adduct, we also show that ATG8 lipidation requires the ATG12–ATG5 conjugate. Unlike ATG8, ATG12 does not associate with autophagic bodies, implying that its role(s) during autophagy is restricted to events before the vacuolar deposition of vesicles. The expression patterns of the ATG12a and ATG12b genes and the effects of single atg12a and atg12b mutants on forming the ATG12–ATG5 conjugate reveal that the ATG12b locus is more important during basal autophagy while the ATG12a locus is more important during induced autophagy. Taken together, we conclude that the formation of the ATG12–ATG5 adduct is essential for ATG8‐mediated autophagy in plants by promoting ATG8 lipidation.     

Lipophagy maintains energy homeostasis in the kidney proximal tubule during prolonged starvation

Macroautophagy/autophagy is a self-degradation process that combats starvation. Lipids are the main energy source in kidney proximal tubular cells (PTCs). During starvation, PTCs increase fatty acid (FA) uptake, form intracellular lipid droplets (LDs), and hydrolyze them for use. The involvement of autophagy in lipid metabolism in the kidney remains largely unknown. Here, we investigated the autophagy-mediated regulation of renal lipid metabolism during prolonged starvation using PTC-specific Atg5-deficient (atg5-TSKO) mice and an in vitro serum starvation model. Twenty-four h of starvation comparably induced LD formation in the PTCs of control and atg5-TSKO mice; however, additional 24 h of starvation reduced the number of LDs in control mice, whereas increases were observed in atg5-TSKO mice. Autophagic degradation of LDs (lipophagy) in PTCs was demonstrated by electron microscopic observation and biochemical analysis. In vitro pulse-chase assays demonstrated that lipophagy mobilizes FAs from LDs to mitochondria during starvation, whereas impaired LD degradation in autophagy-deficient PTCs led to decreased ATP production and subsequent cell death. In contrast to the in vitro assay, despite impaired LD degradation, kidney ATP content was preserved in 48-h starved atg5-TSKO mice, probably due to increased utilization of ketone bodies. This compensatory mechanism was accompanied by a higher plasma FGF21 (fibroblast growth factor 21) level and its expression in the PTCs; however, this was not essential for the production of ketone bodies in the liver during prolonged starvation. In conclusion, lipophagy combats prolonged starvation in PTCs to avoid cellular energy depletion.     

Starvation‐induced MTMR13 and RAB21 activity regulates VAMP8 to promote autophagosome–lysosome fusion

Autophagy, the process for recycling cytoplasm in the lysosome, depends on membrane trafficking. We previously identified Drosophila Sbf as a Rab21 guanine nucleotide exchange factor (GEF) that acts with Rab21 in endosomal trafficking. Here, we show that Sbf/MTMR13 and Rab21 have conserved functions required for starvation‐induced autophagy. Depletion of Sbf/MTMR13 or Rab21 blocked endolysosomal trafficking of VAMP8, a SNARE required for autophagosome–lysosome fusion. We show that starvation induces Sbf/MTMR13 GEF and RAB21 activity, as well as their induced binding to VAMP8 (or closest Drosophila homolog, Vamp7). MTMR13 is required for RAB21 activation, VAMP8 interaction and VAMP8 endolysosomal trafficking, defining a novel GEF‐Rab‐effector pathway. These results identify starvation‐responsive endosomal regulators and trafficking that tunes membrane demands with changing autophagy status.     

Sustained activation of autophagy suppresses adipocyte maturation via a lipolysis-dependent mechanism

ABSTRACT

Dysregulation of macroautophagy/autophagy is implicated in obesity and insulin resistance. However, it remains poorly defined how autophagy regulates adipocyte development. Using adipose-specific rptor/raptor knockout (KO), atg7 KO and atg7 rptor double-KO mice, we show that inhibiting MTORC1 by RPTOR deficiency led to autophagic sequestration of lipid droplets, formation of LD-containing lysosomes, and elevation of basal and isoproterenol-induced lipolysis in vivo and in primary adipocytes. Despite normal differentiation at an early phase, progressive degradation and shrinkage of cellular LDs and downregulation of adipogenic markers PPARG and PLIN1 occurred in terminal differentiation of rptor KO adipocytes, which was rescued by inhibiting lipolysis or lysosome. In contrast, inactivating autophagy by depletion of ATG7 protected adipocytes against RPTOR deficiency-induced formation of LD-containing lysosomes, LD degradation, and downregulation of adipogenic markers in vitro. Ultimately, atg7 rptor double-KO mice displayed decreased lipolysis, restored adipose tissue development, and upregulated thermogenic gene expression in brown and inguinal adipose tissue compared to RPTOR-deficient mice in vivo. Collectively, our study demonstrates that autophagy plays an important role in regulating adipocyte maturation via a lipophagy and lipolysis-dependent mechanism.     

Antioxidant role of autophagy in maintaining the integrity of glomerular capillaries

Autophagy is a lysosomal degradation system by which cytosolic materials and damaged organelles are broken down into basic components. To explore the physiological role of autophagy in glomerular endothelial cells (GEnCs), we compared the autophagic flux among cells in the kidney under starvation. Inhibition of autophagy by chloroquine administration significantly increased the number of autophagosomes or autolysosomes in GEnCs and proximal tubular cells, but not in podocytes, suggesting that the GEnCs exhibit substantial autophagic activity. Next, we analyzed endothelial and hematopoietic cell-specific atg5-deficient mice (atg5-conditional KO [cKO] mice). Glomeruli of 4-wk-old atg5-cKO mice exhibited slightly distended capillary loops accompanied by an accumulation of reactive oxygen species (ROS). Glomeruli of 8-wk-old atg5-cKO mice showed a lobular pattern with thickening of the capillary loops and mesangial matrix expansion; however, the vasculature of other organs was preserved. The atg5-cKO mice died by 12 wk of age, presumably due to pancytopenia resulting from the defect in their hematopoietic lineages. Therefore, we subjected 4-wk atg5-cKO mice to irradiation followed by bone marrow transplantation from normal littermates. Transplanted mice recapitulated the glomerular phenotypes of the atg5-cKO mice with no obvious histological changes in other organs. Twelve-mo-old transplanted mice developed mesangiolysis and glomerulosclerosis with significant deterioration of kidney function. Administration of N-acetyl-l-cysteine, a ROS scavenger, to atg5-cKO mice rescued the glomerular phenotypes. These data suggest that endothelial autophagy protects glomeruli from oxidative stress and maintains the integrity of glomerular capillaries. Enhancing endothelial autophagy may provide a novel therapeutic approach to minimizing glomerular diseases.     

Microautophagy of cytosolic proteins by late endosomes

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Highlights? Late endosomes take up cytosolic proteins through membrane invaginations ? Endosomal microautophagy (eMI) requires multivesicular body formation ? hsc70 mediates selective targeting of cytosolic proteins during eMI ? hsc70 binds to the endosomal membrane through its polybasic cluster     

Evolutionarily conserved role and physiological relevance of a STX17/Syx17 (syntaxin 17)-containing SNARE complex in autophagosome fusion with endosomes and lysosomes

Phagophores engulf cytoplasmic material and give rise to autophagosomes, double-membrane vesicles mediating cargo transport to lysosomes for degradation. The regulation of autophagosome fusion with endosomes and lysosomes during autophagy has remained poorly characterized. Two recent papers conclude that STX17/syntaxin 17 (Syx17 in Drosophila) has an evolutionarily conserved role in autophagosome fusion with endosomes and lysosomes, acting in one SNARE complex with SNAP29 (ubisnap in Drosophila) and the endosomal/lysosomal VAMP8 (CG1599/Vamp7 in Drosophila). Surprisingly, a third report suggests that STX17 might also contribute to proper phagophore assembly. Although several experiments presented in the two human cell culture studies yielded controversial results, the essential role of STX17 in autophagic flux is now firmly established, both in cultured cells and in an animal model. Based on these data, we propose that genetic inhibition of STX17/Syx17 may be a more specific tool in autophagic flux experiments than currently used drug treatments, which impair all lysosomal degradation routes and also inactivate MTOR (mechanistic target of rapamycin), a major negative regulator of autophagy. Finally, the neuronal dysfunction and locomotion defects observed in Syx17 mutant animals point to the possible contribution of defective autophagosome clearance to various human diseases.     

Autophagy in plants

Autophagy is a highly conserved processing mechanism in eukaryotes whereby cytoplasmic components are engulfed in double-membrane vesicles called autophagosomes and are delivered into organelles such as lysosomes (mammal) or vacuoles (yeast/plant) for degradation and recycling of the resulting molecules. Isolation of yeastAUTOPHAGY (ATG) genes has facilitated the identification of correspondingArabidopsis ATG genes based on sequence similarity. Genetic and molecular analyses using knockout and/or knockdown mutants of those genes have unraveled the biological functions of autophagy during plant development, nutrient recycling, and environmental stress responses. Additional roles for autophagy have been suggested in the degradation of oxidized proteins during oxidative stress and the regulation of hypersensitive response (HR)-programmed cell death (PCD) during innate immunity. Our review summarizes knowledge about the structure and function of autophagic pathways andATG components, and the biological roles of autophagy in plants.     

The Hansenula polymorpha ATG25 Gene Encodes a Novel Coiled-Coil Protein that is Required for Macropexophagy

We have isolated the Hansenula polymorpha ATG11 and ATG25 genes, which are both required for glucose-induced selective peroxisome degradation (macropexophagy). ATG11 was identified before in other yeast species and shown to be involved in the Cvt pathway in Saccharomyces cerevisiae and glucose-induced micropexophagy in Pichia pastoris. Our data indicate that HpATG11 is required for macropexophagy. ATG25 represents a novel gene that encodes a 45 kDa coiled-coil protein. We show that this protein co-localizes with Atg11 on a small structure, which most likely represents the pre-autophagosomal structure (PAS). Cells of a constructed ATG25 deletion strain (atg25) displayed relatively slow, continuous degradation of peroxisomes by microautophagy during growth on methanol in the presence of excess nitrogen that also continued after induction of selective peroxisome degradation. This suggests that the processes of selective and non-selective autophagy are dysregulated in atg25 cells.     

PLIC proteins or ubiquilins regulate autophagy‐dependent cell survival during nutrient starvation

Ubiquilins (UBQLNs) are adaptor proteins thought to deliver ubiquitinated substrates to proteasomes. Here, we show a role for UBQLN in autophagy: enforced expression of UBQLN protects cells from starvation‐induced death, whereas depletion of UBQLN renders cells more susceptible. The UBQLN protective effect requires the autophagy‐related genes ATG5 and ATG7, two essential components of autophagy. The ubiquitin‐associated domain of UBQLN mediates both its association with autophagosomes and its protective effect against starvation. Depletion of UBQLN delays the delivery of autophagosomes to lysosomes. This study identifies a new role for UBQLN in regulating the maturation of autophagy, expanding the involvement of ubiquitin‐related proteins in this process.     

Atg17/FIP200 localizes to perilysosomal Ref(2)P aggregates and promotes autophagy by activation of Atg1 in Drosophila

Phagophore-derived autophagosomes deliver cytoplasmic material to lysosomes for degradation and reuse. Autophagy mediated by the incompletely characterized actions of Atg proteins is involved in numerous physiological and pathological settings including stress resistance, immunity, aging, cancer, and neurodegenerative diseases. Here we characterized Atg17/FIP200, the Drosophila ortholog of mammalian RB1CC1/FIP200, a proposed functional equivalent of yeast Atg17. Atg17 disruption inhibits basal, starvation-induced and developmental autophagy, and interferes with the programmed elimination of larval salivary glands and midgut during metamorphosis. Upon starvation, Atg17-positive structures appear at aggregates of the selective cargo Ref(2)P/p62 near lysosomes. This location may be similar to the perivacuolar PAS (phagophore assembly site) described in yeast. Drosophila Atg17 is a member of the Atg1 kinase complex as in mammals, and we showed that it binds to the other subunits including Atg1, Atg13, and Atg101 (C12orf44 in humans, 9430023L20Rik in mice and RGD1359310 in rats). Atg17 is required for the kinase activity of endogenous Atg1 in vivo, as loss of Atg17 prevents the Atg1-dependent shift of endogenous Atg13 to hyperphosphorylated forms, and also blocks punctate Atg1 localization during starvation. Finally, we found that Atg1 overexpression induces autophagy and reduces cell size in Atg17-null mutant fat body cells, and that overexpression of Atg17 promotes endogenous Atg13 phosphorylation and enhances autophagy in an Atg1-dependent manner in the fat body. We propose a model according to which the relative activity of Atg1, estimated by the ratio of hyper- to hypophosphorylated Atg13, contributes to setting low (basal) vs. high (starvation-induced) autophagy levels in Drosophila.     

植物ATG8结合蛋白

ATG8（自噬相关蛋白8）结合蛋白通过ATG8相互作用基序（ATG8 interaction motif,AIM）或泛素相互作用基序（ubiquitin interaction motif,UIM）与ATG8相互作用,在自噬、选择性自噬和非自噬过程中起关键作用。ATG8结合蛋白在酵母和哺乳动物研究中取得了巨大进展,但在植物领域仍然滞后。本文首先概括了植物ATG8蛋白结构及特征,其次,重点阐述了作为植物选择性自噬受体的ATG8结合蛋白的结构和功能,最后,总结了参与自噬小体闭合、转运和人工合成ATG8结合蛋白研究状况。本文结合最新研究,系统总结了目前发现的植物ATG8结合蛋白结构和功能,以期为植物选择性自噬和自噬的研究提供新思路。     

Cytosol to lysosome transport of intracellular antigens during immune surveillance

The delivery of intracellular substrates such as misfolded proteins and damaged organelles from the cytosol to the lysosome for degradation is crucial for cell survival. Multiple transport pathways including bulk autophagy (microautophagy and macroautophagy) and chaperone-mediated autophagy (CMA) have been identified to efficiently facilitate this transit of macromolecules from the cytoplasm to acidic vacuolar organelles. While autophagy plays a role in the general housekeeping of cells, it also functions in more specialized processes such as development and differentiation, responses to physiological stress and immunity. The presentation of both exogenous and endogenous antigens (Ag) by major histocompatibility complex (MHC) class II molecules to CD4(+) T lymphocytes is critical for the induction of tolerance to self Ag as well as the development of immunity against intracellular pathogens and tumors. Here, we discuss the class II-mediated presentation of several endogenous Ag, dependent on either macroautophagy or CMA for their transport from the cytosol to endosomal/lysosomal compartments. Thus, the various pathways of autophagy as routes of cytoplasmic Ag delivery to lysosomes have significant implications for the MHC class II-mediated immune response to intracellular pathogens and cancer.     

Effects of Small Molecules on Chaperone-Mediated Autophagy

Autophagy, including macroautophagy (MA), chaperone-mediated autophagy (CMA), crinophagy, pexophagy and microautophagy, are processes by which cells select internal components such as proteins, secretory vesicles, organelles, or foreign bodies, and deliver them to lysosomes for degradation. MA and CMA are activated during conditions of serum withdrawal in cell culture and during short-term (MA) and prolonged (CMA) starvation in organisms. Although MA and CMA are activated under similar conditions, they are regulated by different mechanisms. We used pulse/chase analysis under conditions in which most intracellular proteolysis is due to CMA to test a variety of compounds for effects on CMA. We show that inhibitors of MA such as 3-methyladenine, wortmannin, and LY294002 have no effect on CMA. Protein degradation by MA is sensitive to microtubule inhibitors such as colcemide and vinblastine, but protein degradation by CMA is not. Activators of MA such as rapamycin also have no effect on CMA. We demonstrate that CMA, like MA, is inhibited by protein synthesis inhibitors anisomycin and cycloheximide. CMA is also partially inhibited when the P38 mitogen activated protein kinase is blocked. Finally we demonstrate that the glucose-6-phophate dehydrogenase inhibitor, 6-aminonicotinamide, and heat shock protein of 90 kilodaltons inhibitor, geldanamycin, have the ability to activate CMA.