Your search keyword '"Autophagosomes chemistry"' showing total 25 results

1. Membrane Curvature: The Inseparable Companion of Autophagy.

Author

Liu L, Tang Y, Zhou Z, Huang Y, Zhang R, Lyu H, Xiao S, Guo D, Ali DW, Michalak M, Chen XZ, Zhou C, and Tang J

Subjects

Protein Aggregates, Protein Domains, Lipid Bilayers, Humans, Autophagy, Cell Membrane chemistry, Cell Membrane metabolism, Proteolysis, Autophagosomes chemistry, Autophagosomes metabolism, Autophagy-Related Proteins chemistry, Autophagy-Related Proteins metabolism

Abstract

Autophagy is a highly conserved recycling process of eukaryotic cells that degrades protein aggregates or damaged organelles with the participation of autophagy-related proteins. Membrane bending is a key step in autophagosome membrane formation and nucleation. A variety of autophagy-related proteins (ATGs) are needed to sense and generate membrane curvature, which then complete the membrane remodeling process. The Atg1 complex, Atg2-Atg18 complex, Vps34 complex, Atg12-Atg5 conjugation system, Atg8-phosphatidylethanolamine conjugation system, and transmembrane protein Atg9 promote the production of autophagosomal membranes directly or indirectly through their specific structures to alter membrane curvature. There are three common mechanisms to explain the change in membrane curvature. For example, the BAR domain of Bif-1 senses and tethers Atg9 vesicles to change the membrane curvature of the isolation membrane (IM), and the Atg9 vesicles are reported as a source of the IM in the autophagy process. The amphiphilic helix of Bif-1 inserts directly into the phospholipid bilayer, causing membrane asymmetry, and thus changing the membrane curvature of the IM. Atg2 forms a pathway for lipid transport from the endoplasmic reticulum to the IM, and this pathway also contributes to the formation of the IM. In this review, we introduce the phenomena and causes of membrane curvature changes in the process of macroautophagy, and the mechanisms of ATGs in membrane curvature and autophagosome membrane formation.

Published

2023

2. Molecular and mesoscopic geometries in autophagosome generation. A review.

Author

Iriondo MN, Etxaniz A, Antón Z, Montes LR, and Alonso A

Subjects

Autophagosomes chemistry, Biophysics, Cell Communication genetics, Lysosomes chemistry, Lysosomes genetics, Membrane Fusion genetics, Autophagosomes genetics, Autophagy genetics, Lipid Bilayers chemistry, Phagocytosis genetics

Abstract

Autophagy is an essential process in cell self-repair and survival. The centre of the autophagic event is the generation of the so-called autophagosome (AP), a vesicle surrounded by a double membrane (two bilayers). The AP delivers its cargo to a lysosome, for degradation and re-use of the hydrolysis products as new building blocks. AP formation is a very complex event, requiring dozens of specific proteins, and involving numerous instances of membrane biogenesis and architecture, including membrane fusion and fission. Many stages of AP generation can be rationalised in terms of curvature, both the molecular geometry of lipids interpreted in terms of 'intrinsic curvature', and the overall mesoscopic curvature of the whole membrane, as observed with microscopy techniques. The present contribution intends to bring together the worlds of biophysics and cell biology of autophagy, in the hope that the resulting cross-pollination will generate abundant fruit., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

3. The expanding role of Atg8.

Author

Hawkins WD and Klionsky DJ

Subjects

Animals, Autophagosomes chemistry, Autophagosomes genetics, Autophagosomes physiology, Autophagy genetics, Autophagy-Related Protein 8 Family chemistry, Autophagy-Related Protein 8 Family genetics, Binding Sites genetics, Humans, Models, Molecular, Molecular Docking Simulation, Mutation, Autophagy physiology, Autophagy-Related Protein 8 Family physiology

Abstract

It would be quite convenient if every protein had one distinct function, one distinct role in just a single cellular process. In the field of macroautophagy/autophagy, however, we are increasingly finding that this is not the case; several autophagy proteins have two or more roles within the process of autophagy and many even "moonlight" as functional members of entirely different cellular processes. This is perhaps best exemplified by the Atg8-family proteins. These dynamic proteins have already been reported to serve several functions both within autophagy (membrane tethering, membrane fusion, binding to cargo receptors, binding to autophagy machinery) and beyond (LC3-associated phagocytosis, formation of EDEMosomes, immune signaling) but as Maruyama and colleagues suggest in their recent report, this list of functions may not yet be complete.

Published

2021

4. Selective increment of phosphatidylserine on the autophagic body membrane in the yeast vacuole.

Author

Yamakuchi Y, Kurokawa Y, Konishi R, Fukuda K, Masatani T, and Fujita A

Subjects

Autophagosomes chemistry, Autophagosomes metabolism, Autophagy, Freezing, Intracellular Membranes chemistry, Membrane Lipids chemistry, Microscopy, Electron, Phosphatidylinositol Phosphates chemistry, Phosphatidylinositol Phosphates metabolism, Receptors, Steroid chemistry, Receptors, Steroid genetics, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae metabolism, Vacuoles chemistry, Intracellular Membranes metabolism, Membrane Lipids metabolism, Phosphatidylserines metabolism, Saccharomyces cerevisiae cytology, Vacuoles metabolism

Abstract

In yeast cells, the autophagosome is a double-membrane structure; the inner membrane becomes the autophagic body membrane in the vacuole. Vacuolar enzymes degrade the autophagic body. There is no critical information regarding its selective degradation. Using the electron microscopy method, distributions of four phospholipids were examined in the autophagosomal and autophagic body membranes upon autophagy induction. The labeling of phosphatidylserine (PtdSer) in the autophagic body membrane dramatically increased after it converted from the autophagosome, but remained low in the vacuolar membrane. PtdSer in the autophagic body membrane also increased in atg15∆ yeast. These results suggest that the selective increment of PtdSer in the autophagic body, but not the vacuolar, membrane, can explain the selective degradation of the autophagic membrane., (© 2021 Federation of European Biochemical Societies.)

Published

2021

5. Isolation of autophagic fractions from mouse liver for biochemical analyses.

Author

Bains H and Singh R

Subjects

Animals, Autophagy physiology, Cell Extracts chemistry, Lipidomics, Mice, Mice, Inbred C57BL, Proteome analysis, Proteome chemistry, Proteomics, Autophagosomes chemistry, Cell Extracts analysis, Centrifugation, Density Gradient methods, Liver cytology, Lysosomes chemistry

Abstract

Isolation of autophagosomes, autolysosomes, and lysosomes allows mechanistic studies into the pathophysiology of autophagy-a lysosomal quality control pathway. Here, we outline a Nycodenz density gradient ultracentrifugation approach for high-yield isolation of autophagic fractions from mouse liver. These fractions can be used for immunoblotting, transmission electron microscopy, and proteomic and lipidomic analyses. For complete details on the use and execution of this protocol, please refer to Toledo et al. (2018)., Competing Interests: The authors declare no competing interests., (© 2021 The Author(s).)

Published

2021

6. Autophagosome content profiling using proximity biotinylation proteomics coupled to protease digestion in mammalian cells.

Author

Zellner S, Nalbach K, and Behrends C

Subjects

Biotinylation, HeLa Cells, Humans, Autophagosomes chemistry, Autophagosomes metabolism, DNA-(Apurinic or Apyrimidinic Site) Lyase chemistry, DNA-(Apurinic or Apyrimidinic Site) Lyase metabolism, Endonucleases chemistry, Endonucleases metabolism, Endopeptidase K chemistry, Multifunctional Enzymes chemistry, Multifunctional Enzymes metabolism, Proteolysis, Proteomics

Abstract

The ascorbate peroxidase APEX2 is commonly used to study the neighborhood of a protein of interest by proximity-dependent biotinylation. Here, we describe a protocol for sample processing compatible with immunoblotting and mass spectrometry, suitable to specifically map the content of autophagosomes and potentially other short-lived endomembrane transport vesicles without the need of subcellular fractionation. By combining live-cell biotinylation with proteinase K digestion of cell homogenates, proteins enriched in membrane-protected compartments can be readily enriched and identified. For complete details on the use and execution of this protocol, please refer to Zellner et al. (2021)., Competing Interests: The authors declare no competing interests., (© 2021 The Author(s).)

Published

2021

7. Lipid profiles of autophagic structures isolated from wild type and Atg2 mutant Drosophila.

Author

Laczkó-Dobos H, Maddali AK, Jipa A, Bhattacharjee A, Végh AG, and Juhász G

Subjects

Animals, Autophagosomes chemistry, Autophagosomes genetics, Autophagy, Autophagy-Related Proteins genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Female, Intracellular Membranes chemistry, Intracellular Membranes metabolism, Lipid Metabolism, Male, Mutation, Autophagosomes metabolism, Autophagy-Related Proteins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Lipids analysis

Abstract

Autophagy is mediated by membrane-bound organelles and it is an intrinsic catabolic and recycling process of the cell, which is very important for the health of organisms. The biogenesis of autophagic membranes is still incompletely understood. In vitro studies suggest that Atg2 protein transports lipids presumably from the ER to the expanding autophagic structures. Autophagy research has focused heavily on proteins and very little is known about the lipid composition of autophagic membranes. Here we describe a method for immunopurification of autophagic structures from Drosophila melanogaster (an excellent model to study autophagy in a complete organism) for subsequent lipidomic analysis. Western blots of several organelle markers indicate the high purity of the isolated autophagic vesicles, visualized by various microscopy techniques. Mass spectrometry results show that phosphatidylethanolamine (PE) is the dominant lipid class in wild type (control) membranes. We demonstrate that in Atg2 mutants (Atg2 - ), phosphatidylinositol (PI), negatively charged phosphatidylserine (PS), and phosphatidic acid (PA) with longer fatty acyl chains accumulate on stalled, negatively charged phagophores. Tandem mass spectrometry analysis of lipid species composing the lipid classes reveal the enrichment of unsaturated PE and phosphatidylcholine (PC) in controls versus PI, PS and PA species in Atg2 - . Significant differences in the lipid profiles of control and Atg2 - flies suggest that the lipid composition of autophagic membranes dynamically changes during their maturation. These lipidomic results also point to the in vivo lipid transport function of the Atg2 protein, pointing to its specific role in the transport of short fatty acyl chain PE species., (Copyright © 2020 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2021

8. Wetting regulates autophagy of phase-separated compartments and the cytosol.

Author

Agudo-Canalejo J, Schultz SW, Chino H, Migliano SM, Saito C, Koyama-Honda I, Stenmark H, Brech A, May AI, Mizushima N, and Knorr RL

Subjects

Adhesiveness, Autophagosomes chemistry, Cell Line, Cytosol chemistry, Humans, Intracellular Membranes chemistry, Intracellular Membranes metabolism, Sequestosome-1 Protein metabolism, Surface Tension, Autophagosomes metabolism, Autophagy, Cell Compartmentation, Cytosol metabolism, Wettability

Abstract

Compartmentalization of cellular material in droplet-like structures is a hallmark of liquid-liquid phase separation 1,2 , but the mechanisms of droplet removal are poorly understood. Evidence suggests that droplets can be degraded by autophagy 3,4 , a highly conserved degradation system in which membrane sheets bend to isolate portions of the cytoplasm within double-membrane autophagosomes 5-7 . Here we examine how autophagosomes sequester droplets that contain the protein p62 (also known as SQSTM1) in living cells, and demonstrate that double-membrane, autophagosome-like vesicles form at the surface of protein-free droplets in vitro through partial wetting. A minimal physical model shows that droplet surface tension supports the formation of membrane sheets. The model also predicts that bending sheets either divide droplets for piecemeal sequestration or sequester entire droplets. We find that autophagosomal sequestration is robust to variations in the droplet-sheet adhesion strength. However, the two sides of partially wetted sheets are exposed to different environments, which can determine the bending direction of autophagosomal sheets. Our discovery of this interplay between the material properties of droplets and membrane sheets enables us to elucidate the mechanisms that underpin droplet autophagy, or 'fluidophagy'. Furthermore, we uncover a switching mechanism that allows droplets to act as liquid assembly platforms for cytosol-degrading autophagosomes 8 or as specific autophagy substrates 9-11 . We propose that droplet-mediated autophagy represents a previously undescribed class of processes that are driven by elastocapillarity, highlighting the importance of wetting in cytosolic organization.

Published

2021

9. Atg9 is a lipid scramblase that mediates autophagosomal membrane expansion.

Author

Matoba K, Kotani T, Tsutsumi A, Tsuji T, Mori T, Noshiro D, Sugita Y, Nomura N, Iwata S, Ohsumi Y, Fujimoto T, Nakatogawa H, Kikkawa M, and Noda NN

Subjects

Autophagosomes metabolism, Autophagy-Related Proteins genetics, Autophagy-Related Proteins metabolism, Binding Sites, Biological Transport, Cryoelectron Microscopy, Gene Expression, Green Fluorescent Proteins chemistry, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Models, Molecular, Phospholipids metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Multimerization, Proteolipids chemistry, Proteolipids metabolism, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Vesicular Transport Proteins genetics, Vesicular Transport Proteins metabolism, Red Fluorescent Protein, Autophagosomes chemistry, Autophagy-Related Proteins chemistry, Membrane Proteins chemistry, Phospholipids chemistry, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, Vesicular Transport Proteins chemistry

Abstract

The molecular function of Atg9, the sole transmembrane protein in the autophagosome-forming machinery, remains unknown. Atg9 colocalizes with Atg2 at the expanding edge of the isolation membrane (IM), where Atg2 receives phospholipids from the endoplasmic reticulum (ER). Here we report that yeast and human Atg9 are lipid scramblases that translocate phospholipids between outer and inner leaflets of liposomes in vitro. Cryo-EM of fission yeast Atg9 reveals a homotrimer, with two connected pores forming a path between the two membrane leaflets: one pore, located at a protomer, opens laterally to the cytoplasmic leaflet; the other, at the trimer center, traverses the membrane vertically. Mutation of residues lining the pores impaired IM expansion and autophagy activity in yeast and abolished Atg9's ability to transport phospholipids between liposome leaflets. These results suggest that phospholipids delivered by Atg2 are translocated from the cytoplasmic to the luminal leaflet by Atg9, thereby driving autophagosomal membrane expansion.

Published

2020

10. Structure, lipid scrambling activity and role in autophagosome formation of ATG9A.

Author

Maeda S, Yamamoto H, Kinch LN, Garza CM, Takahashi S, Otomo C, Grishin NV, Forli S, Mizushima N, and Otomo T

Subjects

Animals, Autophagosomes metabolism, Autophagy-Related Proteins genetics, Autophagy-Related Proteins metabolism, Binding Sites, Biological Transport, Cell Line, Cryoelectron Microscopy, Fibroblasts metabolism, Fibroblasts ultrastructure, Gene Expression, Green Fluorescent Proteins chemistry, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, HEK293 Cells, HeLa Cells, Humans, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Mice, Molecular Dynamics Simulation, Phospholipids metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Multimerization, Proteolipids metabolism, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Vesicular Transport Proteins genetics, Vesicular Transport Proteins metabolism, Red Fluorescent Protein, Autophagosomes chemistry, Autophagy-Related Proteins chemistry, Membrane Proteins chemistry, Phospholipids chemistry, Proteolipids chemistry, Vesicular Transport Proteins chemistry

Abstract

De novo formation of the double-membrane compartment autophagosome is seeded by small vesicles carrying membrane protein autophagy-related 9 (ATG9), the function of which remains unknown. Here we find that ATG9A scrambles phospholipids of membranes in vitro. Cryo-EM structures of human ATG9A reveal a trimer with a solvated central pore, which is connected laterally to the cytosol through the cavity within each protomer. Similarities to ABC exporters suggest that ATG9A could be a transporter that uses the central pore to function. Moreover, molecular dynamics simulation suggests that the central pore opens laterally to accommodate lipid headgroups, thereby enabling lipids to flip. Mutations in the pore reduce scrambling activity and yield markedly smaller autophagosomes, indicating that lipid scrambling by ATG9A is essential for membrane expansion. We propose ATG9A acts as a membrane-embedded funnel to facilitate lipid flipping and to redistribute lipids added to the outer leaflet of ATG9 vesicles, thereby enabling growth into autophagosomes.

Published

2020

11. Reconstitution of autophagosome nucleation defines Atg9 vesicles as seeds for membrane formation.

Author

Sawa-Makarska J, Baumann V, Coudevylle N, von Bülow S, Nogellova V, Abert C, Schuschnig M, Graef M, Hummer G, and Martens S

Subjects

Autophagosomes chemistry, Autophagy-Related Protein 12 chemistry, Autophagy-Related Protein 12 metabolism, Autophagy-Related Protein 5 chemistry, Autophagy-Related Protein 5 metabolism, Autophagy-Related Protein 8 Family metabolism, Autophagy-Related Proteins chemistry, Lipid Metabolism, Membrane Proteins chemistry, Phosphatidylinositol 3-Kinases metabolism, Proteolipids chemistry, Proteolipids metabolism, Saccharomyces cerevisiae Proteins chemistry, Unilamellar Liposomes metabolism, Autophagosomes metabolism, Autophagy-Related Proteins metabolism, Cell Membrane metabolism, Membrane Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Autophagosomes form de novo in a manner that is incompletely understood. Particularly enigmatic are autophagy-related protein 9 (Atg9)-containing vesicles that are required for autophagy machinery assembly but do not supply the bulk of the autophagosomal membrane. In this study, we reconstituted autophagosome nucleation using recombinant components from yeast. We found that Atg9 proteoliposomes first recruited the phosphatidylinositol 3-phosphate kinase complex, followed by Atg21, the Atg2-Atg18 lipid transfer complex, and the E3-like Atg12-Atg5-Atg16 complex, which promoted Atg8 lipidation. Furthermore, we found that Atg2 could transfer lipids for Atg8 lipidation. In selective autophagy, these reactions could potentially be coupled to the cargo via the Atg19-Atg11-Atg9 interactions. We thus propose that Atg9 vesicles form seeds that establish membrane contact sites to initiate lipid transfer from compartments such as the endoplasmic reticulum., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

12. Autophagosome biogenesis: From membrane growth to closure.

Author

Melia TJ, Lystad AH, and Simonsen A

Subjects

Autophagosomes chemistry, Autophagy genetics, Autophagy physiology, Autophagy-Related Proteins genetics, Biological Transport, Active genetics, Biological Transport, Active physiology, Humans, Lipids biosynthesis, Lipids chemistry, Signal Transduction genetics, Signal Transduction physiology, Autophagosomes metabolism, Autophagy-Related Proteins metabolism, Endoplasmic Reticulum metabolism, Lipid Metabolism, Membranes metabolism

Abstract

Autophagosome biogenesis involves de novo formation of a membrane that elongates to sequester cytoplasmic cargo and closes to form a double-membrane vesicle (an autophagosome). This process has remained enigmatic since its initial discovery >50 yr ago, but our understanding of the mechanisms involved in autophagosome biogenesis has increased substantially during the last 20 yr. Several key questions do remain open, however, including, What determines the site of autophagosome nucleation? What is the origin and lipid composition of the autophagosome membrane? How is cargo sequestration regulated under nonselective and selective types of autophagy? This review provides key insight into the core molecular mechanisms underlying autophagosome biogenesis, with a specific emphasis on membrane modeling events, and highlights recent conceptual advances in the field., (© 2020 Melia et al.)

Published

2020

13. Phase separation organizes the site of autophagosome formation.

Author

Fujioka Y, Alam JM, Noshiro D, Mouri K, Ando T, Okada Y, May AI, Knorr RL, Suzuki K, Ohsumi Y, and Noda NN

Subjects

Adaptor Proteins, Signal Transducing chemistry, Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Autophagy, Autophagy-Related Proteins chemistry, Autophagy-Related Proteins genetics, Autophagy-Related Proteins metabolism, Mechanistic Target of Rapamycin Complex 1 chemistry, Mechanistic Target of Rapamycin Complex 1 metabolism, Multiprotein Complexes chemistry, Multiprotein Complexes genetics, Multiprotein Complexes metabolism, Phosphorylation, Point Mutation, Protein Binding, Protein Kinases chemistry, Protein Kinases genetics, Protein Kinases metabolism, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Vacuoles metabolism, Autophagosomes chemistry, Autophagosomes metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae metabolism

Abstract

Many biomolecules undergo liquid-liquid phase separation to form liquid-like condensates that mediate diverse cellular functions 1,2 . Autophagy is able to degrade such condensates using autophagosomes-double-membrane structures that are synthesized de novo at the pre-autophagosomal structure (PAS) in yeast 3-5 . Whereas Atg proteins that associate with the PAS have been characterized, the physicochemical and functional properties of the PAS remain unclear owing to its small size and fragility. Here we show that the PAS is in fact a liquid-like condensate of Atg proteins. The autophagy-initiating Atg1 complex undergoes phase separation to form liquid droplets in vitro, and point mutations or phosphorylation that inhibit phase separation impair PAS formation in vivo. In vitro experiments show that Atg1-complex droplets can be tethered to membranes via specific protein-protein interactions, explaining the vacuolar membrane localization of the PAS in vivo. We propose that phase separation has a critical, active role in autophagy, whereby it organizes the autophagy machinery at the PAS.

Published

2020

14. The LC3-conjugation machinery specifies the loading of RNA-binding proteins into extracellular vesicles.

Author

Leidal AM, Huang HH, Marsh T, Solvik T, Zhang D, Ye J, Kai F, Goldsmith J, Liu JY, Huang YH, Monkkonen T, Vlahakis A, Huang EJ, Goodarzi H, Yu L, Wiita AP, and Debnath J

Subjects

Adaptor Proteins, Vesicular Transport deficiency, Adaptor Proteins, Vesicular Transport genetics, Animals, Autophagosomes chemistry, Autophagy-Related Protein 7 deficiency, Autophagy-Related Protein 7 genetics, Autophagy-Related Proteins deficiency, Autophagy-Related Proteins genetics, Biological Transport, Biotinylation, Extracellular Vesicles chemistry, Gene Expression Profiling, Gene Expression Regulation, HEK293 Cells, Heterogeneous-Nuclear Ribonucleoprotein K genetics, Heterogeneous-Nuclear Ribonucleoprotein K metabolism, Humans, Intracellular Signaling Peptides and Proteins genetics, Intracellular Signaling Peptides and Proteins metabolism, Lysosomes chemistry, Lysosomes metabolism, Matrix Attachment Region Binding Proteins genetics, Matrix Attachment Region Binding Proteins metabolism, Mice, Microtubule-Associated Proteins metabolism, Nuclear Matrix-Associated Proteins genetics, Nuclear Matrix-Associated Proteins metabolism, Proteomics methods, RAW 264.7 Cells, RNA, Small Untranslated genetics, RNA, Small Untranslated metabolism, RNA-Binding Proteins classification, RNA-Binding Proteins metabolism, Receptors, Estrogen genetics, Receptors, Estrogen metabolism, Sphingomyelin Phosphodiesterase genetics, Sphingomyelin Phosphodiesterase metabolism, Autophagosomes metabolism, Autophagy genetics, Extracellular Vesicles metabolism, Microtubule-Associated Proteins genetics, RNA-Binding Proteins genetics

Abstract

Traditionally viewed as an autodigestive pathway, autophagy also facilitates cellular secretion; however, the mechanisms underlying these processes remain unclear. Here, we demonstrate that components of the autophagy machinery specify secretion within extracellular vesicles (EVs). Using a proximity-dependent biotinylation proteomics strategy, we identify 200 putative targets of LC3-dependent secretion. This secretome consists of a highly interconnected network enriched in RNA-binding proteins (RBPs) and EV cargoes. Proteomic and RNA profiling of EVs identifies diverse RBPs and small non-coding RNAs requiring the LC3-conjugation machinery for packaging and secretion. Focusing on two RBPs, heterogeneous nuclear ribonucleoprotein K (HNRNPK) and scaffold-attachment factor B (SAFB), we demonstrate that these proteins interact with LC3 and are secreted within EVs enriched with lipidated LC3. Furthermore, their secretion requires the LC3-conjugation machinery, neutral sphingomyelinase 2 (nSMase2) and LC3-dependent recruitment of factor associated with nSMase2 activity (FAN). Hence, the LC3-conjugation pathway controls EV cargo loading and secretion.

Published

2020

15. Selective Autophagy: ATG8 Family Proteins, LIR Motifs and Cargo Receptors.

Author

Johansen T and Lamark T

Subjects

Animals, Apoptosis Regulatory Proteins analysis, Apoptosis Regulatory Proteins metabolism, Autophagosomes chemistry, Autophagy-Related Protein 8 Family analysis, Humans, Macroautophagy, Microtubule-Associated Proteins analysis, Microtubule-Associated Proteins metabolism, Protein Interaction Domains and Motifs, Protein Interaction Maps, Autophagosomes metabolism, Autophagy, Autophagy-Related Protein 8 Family metabolism

Abstract

Selective autophagy relies on soluble or membrane-bound cargo receptors that recognize cargo and bring about autophagosome formation at the cargo. The cargo-bound receptors interact with lipidated ATG8 family proteins anchored in the membrane at the concave side of the forming autophagosome. The interaction is mediated by 15- to 20-amino-acid-long sequence motifs called LC3-interacting region (LIR) motifs that bind to the LIR docking site (LDS) of ATG8 proteins. In this review, we focus on LIR-ATG8 interactions and the soluble mammalian selective autophagy receptors. We discuss the roles of ATG8 family proteins as membrane scaffolds in autophagy and the LIR-LDS interaction and how specificity for binding to GABARAP or LC3 subfamily proteins is achieved. We also discuss atypical LIR-LDS interactions and a novel LIR-independent interaction. Recently, it has become clear that several of the soluble cargo receptors are able to recruit components of the core autophagy apparatus to aid in assembling autophagosome formation at the site of cargo sequestration. A model on phagophore recruitment and expansion on a selective autophagy receptor-coated cargo incorporating the latest findings is presented., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2020

16. FIP200 Claw Domain Binding to p62 Promotes Autophagosome Formation at Ubiquitin Condensates.

Author

Turco E, Witt M, Abert C, Bock-Bierbaum T, Su MY, Trapannone R, Sztacho M, Danieli A, Shi X, Zaffagnini G, Gamper A, Schuschnig M, Fracchiolla D, Bernklau D, Romanov J, Hartl M, Hurley JH, Daumke O, and Martens S

Subjects

Autophagosomes chemistry, Autophagy genetics, Autophagy-Related Proteins, Crystallography, X-Ray, Humans, Microtubule-Associated Proteins chemistry, Microtubule-Associated Proteins genetics, Protein Interaction Maps genetics, Protein-Tyrosine Kinases genetics, Proteolysis, Sequestosome-1 Protein genetics, Signal Transduction genetics, Ubiquitin chemistry, Ubiquitin genetics, Autophagosomes metabolism, Protein Conformation, Protein-Tyrosine Kinases chemistry, Sequestosome-1 Protein chemistry

Abstract

The autophagy cargo receptor p62 facilitates the condensation of misfolded, ubiquitin-positive proteins and their degradation by autophagy, but the molecular mechanism of p62 signaling to the core autophagy machinery is unclear. Here, we show that disordered residues 326-380 of p62 directly interact with the C-terminal region (CTR) of FIP200. Crystal structure determination shows that the FIP200 CTR contains a dimeric globular domain that we designated the "Claw" for its shape. The interaction of p62 with FIP200 is mediated by a positively charged pocket in the Claw, enhanced by p62 phosphorylation, mutually exclusive with the binding of p62 to LC3B, and it promotes degradation of ubiquitinated cargo by autophagy. Furthermore, the recruitment of the FIP200 CTR slows the phase separation of ubiquitinated proteins by p62 in a reconstituted system. Our data provide the molecular basis for a crosstalk between cargo condensation and autophagosome formation., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

17. The Atg2-Atg18 complex tethers pre-autophagosomal membranes to the endoplasmic reticulum for autophagosome formation.

Author

Kotani T, Kirisako H, Koizumi M, Ohsumi Y, and Nakatogawa H

Subjects

Autophagosomes chemistry, Autophagy-Related Proteins genetics, Intracellular Membranes metabolism, Membrane Proteins genetics, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Phosphatidylinositol Phosphates metabolism, Protein Domains, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Autophagosomes metabolism, Autophagy-Related Proteins metabolism, Endoplasmic Reticulum metabolism, Membrane Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The biogenesis of double-membrane vesicles called autophagosomes, which sequester and transport intracellular material for degradation in lysosomes or vacuoles, is a central event in autophagy. This process requires a unique set of factors called autophagy-related (Atg) proteins. The Atg proteins assemble to organize the preautophagosomal structure (PAS), at which a cup-shaped membrane, the isolation membrane (or phagophore), forms and expands to become the autophagosome. The molecular mechanism of autophagosome biogenesis remains poorly understood. Previous studies have shown that Atg2 forms a complex with the phosphatidylinositol 3-phosphate (PI3P)-binding protein Atg18 and localizes to the PAS to initiate autophagosome biogenesis; however, the molecular function of Atg2 remains unknown. In this study, we show that Atg2 has two membrane-binding domains in the N- and C-terminal regions and acts as a membrane tether during autophagosome formation in the budding yeast Saccharomyces cerevisiae An amphipathic helix in the C-terminal region binds to membranes and facilitates Atg18 binding to PI3P to target the Atg2-Atg18 complex to the PAS. The N-terminal region of Atg2 is also involved in the membrane binding of this protein but is dispensable for the PAS targeting of the Atg2-Atg18 complex. Our data suggest that this region associates with the endoplasmic reticulum (ER) and is responsible for the formation of the isolation membrane at the PAS. Based on these results, we propose that the Atg2-Atg18 complex tethers the PAS to the ER to initiate membrane expansion during autophagosome formation., Competing Interests: The authors declare no conflict of interest.

Published

2018

18. Autophagy Caught in the Act: A Supramolecular FRET Pair Based on an Ultrastable Synthetic Host-Guest Complex Visualizes Autophagosome-Lysosome Fusion.

Author

Li M, Lee A, Kim KL, Murray J, Shrinidhi A, Sung G, Park KM, and Kim K

Subjects

Amantadine chemistry, Autophagosomes chemistry, Bridged-Ring Compounds chemistry, Carbocyanines chemistry, Humans, Imidazoles chemistry, Lysosomes chemistry, MCF-7 Cells, Membrane Fusion, Microscopy, Confocal, Autophagosomes metabolism, Autophagy physiology, Fluorescence Resonance Energy Transfer, Fluorescent Dyes chemistry, Lysosomes metabolism

Abstract

A supramolecular FRET pair based on the ultrahigh binding affinity between cyanine 3 conjugated cucurbit[7]uril (CB[7]-Cy3) and cyanine 5 conjugated adamantylamine (AdA-Cy5) was exploited as a new synthetic tool for imaging cellular processes in live cells. Confocal laser scanning microscopy revealed that CB[7]-Cy3 and AdA-Cy5 were intracellularly translocated and accumulated in lysosomes and mitochondria, respectively. CB[7]-Cy3 and AdA-Cy5 then formed a host-guest complex, reported by a FRET signal, as a result of the fusion of lysosomes and mitochondria. This observation not only indicated that CB[7] forms a stable complex with AdA in a live cell, but also suggested that this FRET pair can visualize dynamic organelle fusion processes, such as those involved in the degradation of mitochondria through autophagy (mitophagy), by virtue of its small size, chemical stability, and ease of use., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

19. Macroautophagy occurs in distal TMV-uninfected root tip tissue of tomato taking place systemic PCD.

Author

Zhou S, Hong Q, Li Y, Li Q, Li R, Zhang H, Wang M, and Yuan X

Subjects

Autophagy, Autophagosomes chemistry, Solanum lycopersicum chemistry, Mitochondria chemistry, Plant Roots chemistry, Programmed Cell Death 1 Receptor chemistry

Abstract

Autophagy is an important mechanism for recycling cell materials upon encountering stress conditions. Our previous studies had shown that TMV infection could lead to systemic PCD in the distal uninfected tissues, including root tip and shoot tip tissues. But it is not clear whether there is autophagy in the distal apical meristem of TMV-induced plants. To better understand the autophagy process during systemic PCD, here we investigated the formation and type of autophagy in the root meristem cells occurring PCD. Transmission electron microscopy assay revealed that the autophagic structures formed by the fusion of vesicles, containing the sequestered cytoplasm, multilamellar bodies, and degraded mitochondria. In the PCD progress, many mitochondria appeared degradation with blurred inner membrane structure. And the endoplasmic reticulum was broke into small fragments. Finally, the damaged mitochodria were engulfed and degraded by the autophagosomes. These results indicated that during the systemic PCD process of root tip cells, the classical macroautophagy occurred, and the cell contents and damaged organelles (mitochondria) would be self-digested by autophagy.

Published

2018

20. Human ATG3 binding to lipid bilayers: role of lipid geometry, and electric charge.

Author

Hervás JH, Landajuela A, Antón Z, Shnyrova AV, Goñi FM, and Alonso A

Subjects

Adaptor Proteins, Signal Transducing chemistry, Apoptosis Regulatory Proteins, Autophagosomes chemistry, Autophagy genetics, Autophagy-Related Proteins chemistry, Biophysical Phenomena genetics, Cardiolipins chemistry, Cardiolipins genetics, Cell Membrane chemistry, Cell Membrane genetics, Humans, Lipids genetics, Microtubule-Associated Proteins chemistry, Protein Binding, Ubiquitin-Conjugating Enzymes chemistry, Adaptor Proteins, Signal Transducing genetics, Autophagy-Related Proteins genetics, Lipid Bilayers chemistry, Lipids chemistry, Microtubule-Associated Proteins genetics, Ubiquitin-Conjugating Enzymes genetics

Abstract

Specific protein-lipid interactions lead to a gradual recruitment of AuTophaGy-related (ATG) proteins to the nascent membrane during autophagosome (AP) formation. ATG3, a key protein in the movement of LC3 towards the isolation membrane, has been proposed to facilitate LC3/GABARAP lipidation in highly curved membranes. In this work we have performed a biophysical study of human ATG3 interaction with membranes containing phosphatidylethanolamine, phosphatidylcholine and anionic phospholipids. We have found that ATG3 interacts more strongly with negatively-charged phospholipid vesicles or nanotubes than with electrically neutral model membranes, cone-shaped anionic phospholipids (cardiolipin and phosphatidic acid) being particularly active in promoting binding. Moreover, an increase in membrane curvature facilitates ATG3 recruitment to membranes although addition of anionic lipid molecules makes the curvature factor relatively less important. The predicted N-terminus amphipathic α-helix of ATG3 would be responsible for membrane curvature detection, the positive residues Lys 9 and 11 being essential in the recognition of phospholipid negative moieties. We have also observed membrane aggregation induced by ATG3 in vitro, which could point to a more complex function of this protein in AP biogenesis. Moreover, in vitro GABARAP lipidation assays suggest that ATG3-membrane interaction could facilitate the lipidation of ATG8 homologues.

Published

2017

21. Scaffolding the cup-shaped double membrane in autophagy.

Author

Bahrami AH, Lin MG, Ren X, Hurley JH, and Hummer G

Subjects

Binding Sites, Computer Simulation, Membrane Fluidity, Membrane Fusion, Models, Chemical, Models, Molecular, Protein Binding, Protein Conformation, Autophagosomes chemistry, Autophagosomes ultrastructure, Autophagy, Autophagy-Related Proteins chemistry, Autophagy-Related Proteins ultrastructure, Cell Membrane chemistry, Cell Membrane ultrastructure, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins ultrastructure

Abstract

Autophagy is a physiological process for the recycling and degradation of cellular materials. Forming the autophagosome from the phagophore, a cup-shaped double-membrane vesicle, is a critical step in autophagy. The origin of the cup shape of the phagophore is poorly understood. In yeast, fusion of a small number of Atg9-containing vesicles is considered a key step in autophagosome biogenesis, aided by Atg1 complexes (ULK1 in mammals) localized at the preautophagosomal structure (PAS). In particular, the S-shaped Atg17-Atg31-Atg29 subcomplex of Atg1 is critical for phagophore nucleation at the PAS. To study this process, we simulated membrane remodeling processes in the presence and absence of membrane associated Atg17. We show that at least three vesicles need to fuse to induce the phagophore shape, consistent with experimental observations. However, fusion alone is not sufficient. Interactions with 34-nm long, S-shaped Atg17 complexes are required to overcome a substantial kinetic barrier in the transition to the cup-shaped phagophore. Our finding rationalizes the recruitment of Atg17 complexes to the yeast PAS, and their unusual shape. In control simulations without Atg17, with weakly binding Atg17, or with straight instead of S-shaped Atg17, the membrane shape transition did not occur. We confirm the critical role of Atg17-membrane interactions experimentally by showing that mutations of putative membrane interaction sites result in reduction or loss of autophagic activity in yeast. Fusion of a small number of vesicles followed by Atg17-guided membrane shape-remodeling thus emerges as a viable route to phagophore formation.

Published

2017

22. Proteomics Insights into Autophagy.

Author

Cudjoe EK Jr, Saleh T, Hawkridge AM, and Gewirtz DA

Subjects

Animals, Biomarkers, Cells metabolism, Homeostasis physiology, Humans, Lysosomes chemistry, Mass Spectrometry trends, Nobel Prize, Peptides analysis, Peptides metabolism, Autophagosomes chemistry, Autophagy physiology, Proteome analysis, Proteomics methods

Abstract

Autophagy, a conserved cellular process by which cells recycle their contents either to maintain basal homeostasis or in response to external stimuli, has for the past two decades become one of the most studied physiological processes in cell biology. The 2016 Nobel Prize in Medicine and Biology awarded to Dr. Ohsumi Yoshinori, one of the first scientists to characterize this cellular mechanism, attests to its importance. The induction and consequent completion of the process of autophagy results in wide ranging changes to the cellular proteome as well as the secretome. MS-based proteomics affords the ability to measure, in an unbiased manner, the ubiquitous changes that occur when autophagy is initiated and progresses in the cell. The continuous improvements and advances in mass spectrometers, especially relating to ionization sources and detectors, coupled with advances in proteomics experimental design, has made it possible to study autophagy, among other process, in great detail. Innovative labeling strategies and protein separation techniques as well as complementary methods including immuno-capture/blotting/staining have been used in proteomics studies to provide more specific protein identification. In this review, we will discuss recent advances in proteomics studies focused on autophagy., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

23. Hepatitis C Virus Induces the Localization of Lipid Rafts to Autophagosomes for Its RNA Replication.

Author

Kim JY, Wang L, Lee J, and Ou JJ

Subjects

Annexin A2 chemistry, Annexin A2 isolation & purification, Autophagosomes chemistry, Autophagosomes virology, Autophagy, Blotting, Western, Caveolin 1 chemistry, Caveolin 1 isolation & purification, Caveolin 2 chemistry, Caveolin 2 isolation & purification, Cell Line, Cholesterol analysis, Chromatography, Affinity, Host-Pathogen Interactions, Humans, Membrane Microdomains chemistry, Membrane Microdomains virology, Microscopy, Fluorescence, Microscopy, Immunoelectron, Proteomics, RNA, Viral physiology, Replicon, Viral Nonstructural Proteins metabolism, Autophagosomes physiology, Hepacivirus physiology, Membrane Microdomains physiology, Virus Replication

Abstract

Autophagy plays important roles in maintaining cellular homeostasis. It uses double- or multiple-membrane vesicles termed autophagosomes to remove protein aggregates and damaged organelles from the cytoplasm for recycling. Hepatitis C virus (HCV) has been shown to induce autophagy to enhance its own replication. Here we describe a procedure that combines membrane flotation and affinity chromatography for the purification of autophagosomes from cells that harbor an HCV subgenomic RNA replicon. The purified autophagosomes had double- or multiple-membrane structures with a diameter ranging from 200 nm to 600 nm. The analysis of proteins associated with HCV-induced autophagosomes by proteomics led to the identification of HCV nonstructural proteins as well as proteins involved in membrane trafficking. Notably, caveolin-1, caveolin-2, and annexin A2, which are proteins associated with lipid rafts, were also identified. The association of lipid rafts with HCV-induced autophagosomes was confirmed by Western blotting, immunofluorescence microscopy, and immunoelectron microscopy. Their association with autophagosomes was also confirmed in HCV-infected cells. The association of lipid rafts with autophagosomes was specific to HCV, as it was not detected in autophagosomes induced by nutrient starvation. Further analysis indicated that the autophagosomes purified from HCV replicon cells could mediate HCV RNA replication in a lipid raft-dependent manner, as the depletion of cholesterol, a major component of lipid rafts, from autophagosomes abolished HCV RNA replication. Our studies thus demonstrated that HCV could specifically induce the association of lipid rafts with autophagosomes for its RNA replication. IMPORTANCE HCV can cause severe liver diseases, including cirrhosis and hepatocellular carcinoma, and is one of the most important human pathogens. Infection with HCV can lead to the reorganization of membrane structures in its host cells, including the induction of autophagosomes. In this study, we developed a procedure to purify HCV-induced autophagosomes and demonstrated that HCV could induce the localization of lipid rafts to autophagosomes to mediate its RNA replication. This finding provided important information for further understanding the life cycle of HCV and its interaction with the host cells., (Copyright © 2017 American Society for Microbiology.)

Published

2017

24. Retromer localizes to autophagosomes during HCV replication.

Author

Yin P, Hong Z, Zhang L, and Ke Y

Subjects

Cell Line, Hepatocytes chemistry, Hepatocytes virology, Humans, Immunoblotting, Microscopy, Fluorescence, Autophagosomes chemistry, Hepacivirus physiology, Multienzyme Complexes analysis, Virus Replication

Published

2017

25. Detection of Autophagy in Plants by Fluorescence Microscopy.

Author

Pu Y and Bassham DC

Subjects

Arabidopsis chemistry, Arabidopsis Proteins isolation & purification, Autophagy-Related Protein 8 Family isolation & purification, Green Fluorescent Proteins, Microscopy, Fluorescence, Plants, Genetically Modified chemistry, Plants, Genetically Modified genetics, Proteolysis, Arabidopsis genetics, Arabidopsis Proteins genetics, Autophagosomes chemistry, Autophagy genetics, Autophagy-Related Protein 8 Family genetics

Abstract

Autophagy is a key process for degradation and recycling of proteins or organelles in eukaryotes. Autophagy in plants has been shown to function in stress responses, pathogen immunity, and senescence, while a basal level of autophagy plays a housekeeping role in cells. Upon activation of autophagy, vesicles termed autophagosomes are formed to deliver proteins or organelles to the vacuole for degradation. The number of autophagosomes can thus be used to indicate the level of autophagy. Here, we describe two common methods used for detection of autophagosomes, staining of autophagosomes with the fluorescent dye monodansylcadaverine, and expression of a fusion between GFP and the autophagosomal membrane protein ATG8.

Published

2016