Your search keyword '"phagophore"' showing total 373 results

1. The physiological relevance of autophagosome morphogenesis.

Author

Shatz, Oren and Elazar, Zvulun

Subjects

*MORPHOGENESIS

Abstract

Autophagy sequesters cytoplasmic portions into autophagosomes. While selective cargo is engulfed by elongation of cup-shaped isolation membranes (IMs), the morphogenesis of non-selective IMs remains elusive. Based on recent observations, we propose a novel model for autophagosome morphogenesis wherein active regulation of the IM rim serves the physiological roles of autophagy. [ABSTRACT FROM AUTHOR]

Published

2024

2. Quantitative analysis of the spatial distance between autophagy-related membrane structures and the endoplasmic reticulum in Saccharomyces cerevisiae.

Author

Shi, Yang and Suzuki, Kuninori

Subjects

ENDOPLASMIC reticulum, SACCHAROMYCES cerevisiae, HOMEOSTASIS, FLUORESCENCE microscopy, POLYMERASE chain reaction, QUANTITATIVE research

Abstract

Macroautophagy/autophagy is the process by which cells degrade their cytoplasmic proteins or organelles in vacuoles to maintain cellular homeostasis under severe environmental conditions. In the yeast Saccharomyces cerevisiae, autophagy-related (Atg) proteins essential for autophagosome formation accumulate near the vacuole to form the dot-shaped phagophore assembly site/pre-autophagosomal structure (PAS). The PAS then generates the phagophore/isolation membrane (PG), which expands to become a closed double-membrane autophagosome. Hereinafter, we refer to the PAS, PG, and autophagosome as autophagy-related structures (ARSs). During autophagosome formation, Atg2 is responsible for tethering the ARS to the endoplasmic reticulum (ER) via ER exit sites (ERESs), and for transferring phospholipids from the ER to ARSs. Therefore, ARS and the ER are spatially close in the presence of Atg2 but are separated in its absence. Because the contact of an ARS with the ER must be established at the earliest stage of autophagosome formation, it is important to know whether the ARS is tethered to the ER. In this study, we developed a rapid and objective method to estimate tethering of the ARS to the ER by measuring the distance between the ARS and ERES under fluorescence microscopy, and found that tethering of the ARS to the ER was lost without Atg1. This method might be useful to predict the tethering activity of Atg2. Abbreviation: ARS, autophagy-related structure; Dautas, automated measurement of the distance between autophagy-related structures and ER exit sites analysis system; ERES, endoplasmic reticulum exit site; PAS, phagophore assembly site/pre-autophagosomal structure; PCR, polymerase chain reaction; PG, phagophore/isolation membrane; prApe1, precursor of vacuolar aminopeptidase I; Qautas, quantitative autophagy-related structure analysis system; SD/CA; synthetic dextrose plus casamino acid medium; WT, wild-type [ABSTRACT FROM AUTHOR]

Published

2024

3. Omegasomes control formation, expansion, and closure of autophagosomes.

Author

Nähse, Viola, Stenmark, Harald, and Schink, Kay O.

Subjects

*AUTOPHAGY, *MEMBRANE lipids, *ENDOPLASMIC reticulum, *ORGANELLES, *HOMEOSTASIS

Abstract

Autophagy, an essential cellular process for maintaining cellular homeostasis and eliminating harmful cytoplasmic objects, involves the de novo formation of double‐membraned autophagosomes that engulf and degrade cellular debris, protein aggregates, damaged organelles, and pathogens. Central to this process is the phagophore, which forms from donor membranes rich in lipids synthesized at various cellular sites, including the endoplasmic reticulum (ER), which has emerged as a primary source. The ER‐associated omegasomes, characterized by their distinctive omega‐shaped structure and accumulation of phosphatidylinositol 3‐phosphate (PI3P), play a pivotal role in autophagosome formation. Omegasomes are thought to serve as platforms for phagophore assembly by recruiting essential proteins such as DFCP1/ZFYVE1 and facilitating lipid transfer to expand the phagophore. Despite the critical importance of phagophore biogenesis, many aspects remain poorly understood, particularly the complete range of proteins involved in omegasome dynamics, and the detailed mechanisms of lipid transfer and membrane contact site formation. [ABSTRACT FROM AUTHOR]

Published

2024

4. Is There a Place for Lewy Bodies before and beyond Alpha-Synuclein Accumulation? Provocative Issues in Need of Solid Explanations.

Author

Lenzi, Paola, Lazzeri, Gloria, Ferrucci, Michela, Scotto, Marco, Frati, Alessandro, Puglisi-Allegra, Stefano, Busceti, Carla Letizia, and Fornai, Francesco

Subjects

*DOPAMINE receptors, *ALPHA-synuclein, *PARKINSON'S disease, *DOPAMINERGIC neurons, *INDIVIDUALIZED medicine

Abstract

In the last two decades, alpha-synuclein (alpha-syn) assumed a prominent role as a major component and seeding structure of Lewy bodies (LBs). This concept is driving ongoing research on the pathophysiology of Parkinson's disease (PD). In line with this, alpha-syn is considered to be the guilty protein in the disease process, and it may be targeted through precision medicine to modify disease progression. Therefore, designing specific tools to block the aggregation and spreading of alpha-syn represents a major effort in the development of disease-modifying therapies in PD. The present article analyzes concrete evidence about the significance of alpha-syn within LBs. In this effort, some dogmas are challenged. This concerns the question of whether alpha-syn is more abundant compared with other proteins within LBs. Again, the occurrence of alpha-syn compared with non-protein constituents is scrutinized. Finally, the prominent role of alpha-syn in seeding LBs as the guilty structure causing PD is questioned. These revisited concepts may be helpful in the process of validating which proteins, organelles, and pathways are likely to be involved in the damage to meso-striatal dopamine neurons and other brain regions involved in PD. [ABSTRACT FROM AUTHOR]

Published

2024

5. ATG9B is a tissue-specific homotrimeric lipid scramblase that can compensate for ATG9A.

Author

Chiduza, George N., Garza-Garcia, Acely, Almacellas, Eugenia, De Tito, Stefano, Pye, Valerie E, van Vliet, Alexander R., Cherepanov, Peter, and Tooze, Sharon A.

Subjects

QUATERNARY structure, COMPUTATIONAL chemistry, MOLECULAR structure, MALTOSE, ROOT-mean-squares, MOLECULAR dynamics, ETHYLENE glycol

Abstract

Macroautophagy/autophagy is a fundamental aspect of eukaryotic biology, and the autophagy-related protein ATG9A is part of the core machinery facilitating this process. In addition to ATG9A vertebrates encode ATG9B, a poorly characterized paralog expressed in a subset of tissues. Herein, we characterize the structure of human ATG9B revealing the conserved homotrimeric quaternary structure and explore the conformational dynamics of the protein. Consistent with the experimental structure and computational chemistry, we establish that ATG9B is a functional lipid scramblase. We show that ATG9B can compensate for the absence of ATG9A in starvation-induced autophagy displaying similar subcellular trafficking and steady-state localization. Finally, we demonstrate that ATG9B can form a heteromeric complex with ATG2A. By establishing the molecular structure and function of ATG9B, our results inform the exploration of niche roles for autophagy machinery in more complex eukaryotes and reveal insights relevant across species. Abbreviation: ATG: autophagy related; CHS: cholesteryl hemisuccinate; cryo-EM: single-particle cryogenic electron microscopy; CTF: contrast transfer function: CTH: C- terminal α helix; FSC: fourier shell correlation; HDIR: HORMA domain interacting region; LMNG: lauryl maltose neopentyl glycol; MD: molecular dynamics simulations; MSA: multiple sequence alignment; NBD-PE: 1,2-dioleoyl-sn-glycero-3-phosphoethanolamine-N-(7-nitro-2–1,3-benzoxadiazol-4-yl ammonium salt); POPC: palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine; RBG: repeating beta groove domain; RMSD: root mean square deviation; SEC: size-exclusion chromatography; TMH: transmembrane helix [ABSTRACT FROM AUTHOR]

Published

2024

6. Phagophore closure, autophagosome maturation and autophagosome fusion during macroautophagy in the yeast Saccharomyces cerevisiae.

Author

Kraft, Claudine and Reggiori, Fulvio

Subjects

*YEAST, *LYSOSOMES, *AUTOPHAGY, *SACCHAROMYCES cerevisiae, *SACCHAROMYCES

Abstract

Macroautophagy, hereafter referred to as autophagy, is a complex process in which multiple membrane‐remodeling events lead to the formation of a cisterna known as the phagophore, which then expands and closes into a double‐membrane vesicle termed the autophagosome. During the past decade, enormous progress has been made in understanding the molecular function of the autophagy‐related proteins and their role in generating these phagophores. In this Review, we discuss the current understanding of three membrane remodeling steps in autophagy that remain to be largely characterized; namely, the closure of phagophores, the maturation of the resulting autophagosomes into fusion‐competent vesicles, and their fusion with vacuoles/lysosomes. Our review will mainly focus on the yeast Saccharomyces cerevisiae, which has been the leading model system for the study of molecular events in autophagy and has led to the discovery of the major mechanistic concepts, which have been found to be mostly conserved in higher eukaryotes. [ABSTRACT FROM AUTHOR]

Published

2024

7. Novel insights into autophagosome biogenesis revealed by cryo‐electron tomography.

Author

Eskelinen, Eeva‐Liisa

Subjects

*TOMOGRAPHY, *IMAGE analysis, *MEMBRANE lipids, *LIPID synthesis

Abstract

Autophagosome biogenesis, from the appearance of the phagophore to elongation and closure into an autophagosome, is one of the long‐lasting open questions in the autophagy field. Recent studies utilising cryo‐electron tomography and detailed analysis of the image data have revealed new information on the membrane dynamics of these events, including the shape and dimensions of omegasomes, phagophores and autophagosomes, and their relationships with the organelles around them. One of the important predictions from the new results is that 60–80% of the autophagosome membrane area is delivered by direct lipid transfer or lipid synthesis. Cryo‐electron tomography can be expected to provide new directions for autophagy research in the near future. [ABSTRACT FROM AUTHOR]

Published

2024

8. Mammalian phagophores with finger-like shapes emerge from recycling endosomes.

Author

Puri, Claudia and Rubinsztein, David C

Subjects

ENDOSOMES, CELL size, ELECTRON microscopy, AUTOPHAGY, LYSOSOMES

Abstract

Autophagosomes are double-membraned vesicles that engulf cytoplasmic contents, which are ultimately degraded after autophagosome-lysosome fusion. The prevailing view, largely inferred from EM-based studies, was that mammalian autophagosomes evolved from disc-shaped precursors that invaginated and then were closed at the single opening. Many site(s) of origin of these precursors have been proposed. Using superresolution structured illumination microscopy and electron microscopy, we find that mammalian autophagosomes derive from finger-like outgrowths from the recycling endosome. These "fingers" survey a large cell volume and then close into a "fist" and the openings are sealed in an ESCRT-dependent fashion, while the precursors are still attached to the recycling endosome. We call this transient recycling endosome-attached, closed, autophagic structure an "autophago-dome". DNM2-dependent scission of the autophago-dome from the recycling endosomes liberates free autophagosomes from this compartment. These data reveal unexpected morphologies of autophagosome precursors and raise new questions about the control of this process. [ABSTRACT FROM AUTHOR]

Published

2024

9. Calcium and Phosphate Ion Efflux from Cells: The Roles of Matrix Vesicles, Extracellular Vesicles, and Other Membrane-invested Transporters in Vertebrate Hard Tissue Mineralization

Author

Shapiro, Irving M., Landis, William J., Shapiro, Irving M., and Landis, William J.

Published

2023

10. The yeast dynamin-like GTPase Vps1 mediates Atg9 transport to the phagophore assembly site in Saccharomyces cerevisiae

Author

Yan Hu and Fulvio Reggiori

Subjects

autophagosome, autophagy, dnm2, phagophore, saccharomyces cerevisiae, traffic, Cytology, QH573-671

Abstract

Macroautophagy/autophagy is a degradative pathway that plays an important role in maintaining cellular homeostasis in eukaryotes. During autophagy, cisternal compartments called phagophores are generated to sequester intracellular components; these structures mature into autophagosomes, which deliver the cargo into lysosomes/vacuoles for degradation. Numerous autophagy-related (Atg) proteins are part of the core machinery that mediates autophagosome biogenesis. Atg9, a lipid scramblase and the only multispanning transmembrane protein among the core Atg machinery, traffics between cytoplasmic reservoirs and the phagophore assembly site (PAS) to provide membranes, recruit other Atg proteins and rearrange lipids on the phagophore membrane. However, the factors mediating Atg9 trafficking remain to be fully understood. In our recent study, we found that the yeast dynamin-like GTPase Vps1 (vacuolar protein sorting 1) is involved in autophagy and is important for Atg9 transport to the PAS. Moreover, we showed that Vps1 function in autophagy requires its GTPase and oligomerization activities. Interestingly, specific mutations in DNM2 (dynamin 2), one of the human homologs of Vps1 that have been linked with specific human diseases such as microcytic anemia and Charcot-Marie-Tooth, also impairs Atg9 transport to the PAS, suggesting that a defect in autophagy may underlay the pathophysiology of these severe human pathologies. Abbreviations Ape1, aminopeptidase I; APEX2, ascorbate peroxidase 2; Atg, autophagy-related; Cvt, cytoplasm-to-vacuole targeting; Dnm1, dynamin-related 1; DNM2, dynamin 2; PAS, phagophore assembly site; TAKA, transport of Atg9 after knocking out ATG1; Vps1, vacuolar protein sorting 1.

Published

2023

11. Vtc4 Promotes the Entry of Phagophores into Vacuoles in the Saccharomyces cerevisiae Snf7 Mutant Cell.

Author

Chen, Xiaofan and Liang, Yongheng

Subjects

*SACCHAROMYCES cerevisiae, *ENDOCYTOSIS, *LYSOSOMES, *AUTOPHAGY, *GUANOSINE triphosphatase, *COATED vesicles

Abstract

Endocytosis and autophagy are the main pathways to deliver cargoes in vesicles and autophagosomes, respectively, to vacuoles/lysosomes in eukaryotes. Multiple positive regulators but few negative ones are reported to regulate the entry of vesicles and autophagosomes into vacuoles/lysosomes. In yeast, the Rab5 GTPase Vps21 and the ESCRT (endosomal sorting complex required for transport) are positive regulators in endocytosis and autophagy. During autophagy, Vps21 regulates the ESCRT to phagophores (unclosed autophagosomes) to close them. Phagophores accumulate on vacuolar membranes in both vps21∆ and ESCRT mutant cells under a short duration of nitrogen starvation. The vacuolar transport chaperon (VTC) complex proteins are recently found to be negative regulators in endocytosis and autophagy. Phagophores in vps21∆ cells are promoted to enter vacuoles when the VTC complex proteins are absent. Phagophores are easily observed inside vacuoles when any of these VTC complex proteins (Vtc1, 2, 4, 5) are removed. However, it is unknown whether the removal of VTC complex proteins will also promote the entry of phagophores into vacuoles in ESCRT mutant cells under the same conditions. Snf7 is a core subunit of ESCRT subcomplex III (ESCRT-III), and phagophores accumulate in snf7∆ cells under a short duration of nitrogen starvation. We used green fluorescence protein (GFP) labeled Atg8 to display phagophores and FM4-64-stained or Vph1-GFP-labeled membrane structures to show vacuoles, then examined fluorescence localization and GFP-Atg8 degradation in snf7∆ and snf7∆vtc4∆ cells. Results showed that Vtc4 depletion promoted the entry of phagophores in snf7∆ cells into vacuoles as it did for vps21∆ cells, although the promotion level was more obvious in vps21∆ cells. This observation indicates that the VTC complex proteins may have a widespread role in negatively regulating cargos to enter vacuoles in yeast. [ABSTRACT FROM AUTHOR]

Published

2023

12. Phagophore-lysosome/vacuole fusion in mutant yeast and mammalian cells.

Author

Liang, Yongheng

Subjects

LYSOSOMES, TRANSMEMBRANE domains, CELL survival, FOCUSED ion beams, TRANSMISSION electron microscopy, YEAST

Abstract

Macroautophagy/autophagy is a process through which the phagophores engulf non-essential or damaged cellular materials, forming double-membrane autophagosomes (APs) and fusing with lysosomes/vacuoles, after which the materials are degraded for recycling purposes. Autophagy is associated with increased cell survival under different stress conditions. AP-lysosome/vacuole fusion is a critical step in autophagy. Some mutant cells can accumulate phagophores under autophagy-induction conditions. Autophagy is interrupted when accumulated phagophores cannot fuse with lysosomes/vacuoles, resulting in a significant decrease in cell survivability. However, phagophore-lysosome/vacuole fusion has been reported in related mammalian cells and yeast mutant cells. This observation indicates that it is possible to restore a partial autophagy process after interruption. Furthermore, these findings indicate that phagophore closure is not a prerequisite for its fusion with the lysosome/vacuole in the mutant cells. The phagophore-lysosome/vacuole fusion strategy can significantly rescue defective autophagy due to failed phagophore closure. This commentary discusses the fusion of phagophores and lysosomes/vacuoles and implications of such fusion events. Abbreviations: AB: autophagic body; AL: autolysosome; AP: autophagosome; ATG: autophagy related; EM: electron microscopy; ESCRT: endosomal sorting complex required for transport; ET: electron tomography; FIB: focus ion beam; IM: inner membrane; KO: knockout; LAMP1: lysosomal-associated membrane protein 1; OM; outer membrane; STX17: syntaxin 17; TEM: transmission electron microscopy; TM: transmembrane domain; Vps: vacuolar protein sorting; WT: wild-type [ABSTRACT FROM AUTHOR]

Published

2023

13. Guidelines for the use and interpretation of assays for monitoring autophagy (4th edition)1

Author

Klionsky, Daniel J, Abdel-Aziz, Amal Kamal, Abdelfatah, Sara, Abdellatif, Mahmoud, Abdoli, Asghar, Abel, Steffen, Abeliovich, Hagai, Abildgaard, Marie H, Abudu, Yakubu Princely, Acevedo-Arozena, Abraham, Adamopoulos, Iannis E, Adeli, Khosrow, Adolph, Timon E, Adornetto, Annagrazia, Aflaki, Elma, Agam, Galila, Agarwal, Anupam, Aggarwal, Bharat B, Agnello, Maria, Agostinis, Patrizia, Agrewala, Javed N, Agrotis, Alexander, Aguilar, Patricia V, Ahmad, S Tariq, Ahmed, Zubair M, Ahumada-Castro, Ulises, Aits, Sonja, Aizawa, Shu, Akkoc, Yunus, Akoumianaki, Tonia, Akpinar, Hafize Aysin, Al-Abd, Ahmed M, Al-Akra, Lina, Al-Gharaibeh, Abeer, Alaoui-Jamali, Moulay A, Alberti, Simon, Alcocer-Gómez, Elísabet, Alessandri, Cristiano, Ali, Muhammad, Al-Bari, M Abdul Alim, Aliwaini, Saeb, Alizadeh, Javad, Almacellas, Eugènia, Almasan, Alexandru, Alonso, Alicia, Alonso, Guillermo D, Altan-Bonnet, Nihal, Altieri, Dario C, Álvarez, Élida MC, Alves, Sara, da Costa, Cristine Alves, Alzaharna, Mazen M, Amadio, Marialaura, Amantini, Consuelo, Amaral, Cristina, Ambrosio, Susanna, Amer, Amal O, Ammanathan, Veena, An, Zhenyi, Andersen, Stig U, Andrabi, Shaida A, Andrade-Silva, Magaiver, Andres, Allen M, Angelini, Sabrina, Ann, David, Anozie, Uche C, Ansari, Mohammad Y, Antas, Pedro, Antebi, Adam, Antón, Zuriñe, Anwar, Tahira, Apetoh, Lionel, Apostolova, Nadezda, Araki, Toshiyuki, Araki, Yasuhiro, Arasaki, Kohei, Araújo, Wagner L, Araya, Jun, Arden, Catherine, Arévalo, Maria-Angeles, Arguelles, Sandro, Arias, Esperanza, Arikkath, Jyothi, Arimoto, Hirokazu, Ariosa, Aileen R, Armstrong-James, Darius, Arnauné-Pelloquin, Laetitia, Aroca, Angeles, Arroyo, Daniela S, Arsov, Ivica, Artero, Rubén, Asaro, Dalia Maria Lucia, Aschner, Michael, Ashrafizadeh, Milad, Ashur-Fabian, Osnat, Atanasov, Atanas G, Au, Alicia K, Auberger, Patrick, Auner, Holger W, and Aurelian, Laure

Subjects

Biochemistry and Cell Biology, Biological Sciences, Animals, Autophagosomes, Autophagy, Autophagy-Related Proteins, Biological Assay, Biomarkers, Humans, Lysosomes, English, grammar, spelling, writing, Autophagosome, cancer, flux, LC3, lysosome, macroautophagy, neurodegeneration, phagophore, stress, vacuole, Biochemistry & Molecular Biology, Biochemistry and cell biology

Abstract

In 2008, we published the first set of guidelines for standardizing research in autophagy. Since then, this topic has received increasing attention, and many scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Thus, it is important to formulate on a regular basis updated guidelines for monitoring autophagy in different organisms. Despite numerous reviews, there continues to be confusion regarding acceptable methods to evaluate autophagy, especially in multicellular eukaryotes. Here, we present a set of guidelines for investigators to select and interpret methods to examine autophagy and related processes, and for reviewers to provide realistic and reasonable critiques of reports that are focused on these processes. These guidelines are not meant to be a dogmatic set of rules, because the appropriateness of any assay largely depends on the question being asked and the system being used. Moreover, no individual assay is perfect for every situation, calling for the use of multiple techniques to properly monitor autophagy in each experimental setting. Finally, several core components of the autophagy machinery have been implicated in distinct autophagic processes (canonical and noncanonical autophagy), implying that genetic approaches to block autophagy should rely on targeting two or more autophagy-related genes that ideally participate in distinct steps of the pathway. Along similar lines, because multiple proteins involved in autophagy also regulate other cellular pathways including apoptosis, not all of them can be used as a specific marker for bona fide autophagic responses. Here, we critically discuss current methods of assessing autophagy and the information they can, or cannot, provide. Our ultimate goal is to encourage intellectual and technical innovation in the field.

Published

2021

14. Is There a Place for Lewy Bodies before and beyond Alpha-Synuclein Accumulation? Provocative Issues in Need of Solid Explanations

Author

Paola Lenzi, Gloria Lazzeri, Michela Ferrucci, Marco Scotto, Alessandro Frati, Stefano Puglisi-Allegra, Carla Letizia Busceti, and Francesco Fornai

Subjects

sequestosome (p62), poly-ubiquitin, phagophore, endosome, multivesicular bodies, retromer, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

In the last two decades, alpha-synuclein (alpha-syn) assumed a prominent role as a major component and seeding structure of Lewy bodies (LBs). This concept is driving ongoing research on the pathophysiology of Parkinson’s disease (PD). In line with this, alpha-syn is considered to be the guilty protein in the disease process, and it may be targeted through precision medicine to modify disease progression. Therefore, designing specific tools to block the aggregation and spreading of alpha-syn represents a major effort in the development of disease-modifying therapies in PD. The present article analyzes concrete evidence about the significance of alpha-syn within LBs. In this effort, some dogmas are challenged. This concerns the question of whether alpha-syn is more abundant compared with other proteins within LBs. Again, the occurrence of alpha-syn compared with non-protein constituents is scrutinized. Finally, the prominent role of alpha-syn in seeding LBs as the guilty structure causing PD is questioned. These revisited concepts may be helpful in the process of validating which proteins, organelles, and pathways are likely to be involved in the damage to meso-striatal dopamine neurons and other brain regions involved in PD.

Published

2024

15. The Organization and Function of the Phagophore-ER Membrane Contact Sites.

Author

Vargas Duarte, Prado and Reggiori, Fulvio

Subjects

*ENDOPLASMIC reticulum, *SACCHAROMYCES cerevisiae, *AUTOPHAGY, *IN vitro studies, *IN vivo studies

Abstract

Macroautophagy is characterized by the de novo formation of double-membrane vesicles termed autophagosomes. The precursor structure of autophagosomes is a membrane cistern called phagophore, which elongates through a massive acquisition of lipids until closure. The phagophore establishes membrane-contact sites (MCSs) with the endoplasmic reticulum (ER), where conserved ATG proteins belonging to the ATG9 lipid scramblase, ATG2 lipid transfer and Atg18/WIPI4 β-propeller families concentrate. Several recent in vivo and in vitro studies have uncovered the relevance of these proteins and MCSs in the lipid supply required for autophagosome formation. Although important conceptual advances have been reached, the functional interrelationship between ATG9, ATG2 and Atg18/WIPI4 proteins at the phagophore-ER MCSs and their role in the phagophore expansion are not completely understood. In this review, we describe the current knowledge about the structure, interactions, localizations, and molecular functions of these proteins, with a particular emphasis on the yeast Saccharomyces cerevisiae and mammalian systems. [ABSTRACT FROM AUTHOR]

Published

2023

16. The lipid flippase Drs2 regulates anterograde transport of Atg9 during autophagy

Author

Franziska Kriegenburg, Wouter Huiting, Fleur van Buuren-Broek, Emma Zwilling, Ralph Hardenberg, Muriel Mari, Claudine Kraft, and Fulvio Reggiori

Subjects

aminophospholipid, atg protein, autophagosome, flippase, lipid asymmetry, phagophore, phagophore assembly site, Cytology, QH573-671

Abstract

Macroautophagy/autophagy is a conserved catabolic pathway during which cellular material is sequestered within newly formed double-membrane vesicles called autophagosomes and delivered to the lytic compartment of eukaryotic cells for degradation. Autophagosome biogenesis depends on the core autophagy-related (Atg) machinery, and involves a massive supply and remodelling of membranes. To gain insight into the lipid remodelling mechanisms during autophagy, we have systematically investigated whether lipid flippases are required for this pathway in the yeast Saccharomyces cerevisiae. We found that the flippase Drs2, which transfers phosphatidylserine and phosphatidylethanolamine from the lumenal to the cytosolic leaflet of the limiting membrane at the trans-Golgi network, is required for normal progression of autophagy. We also show that Drs2 is important for the trafficking of the core Atg protein Atg9. Atg9 is a transmembrane protein important for autophagosome biogenesis and its anterograde transport from its post-Golgi reservoirs to the site of autophagosome formation is severely impaired in the absence of Drs2. Thus, our results identify a novel autophagy player and highlight that membrane asymmetry regulates early autophagy steps. Abbreviations: ABs: autophagic bodies; Atg: autophagy-related; BiFC: bimolecular fluorescence microscopy; Cvt: cytoplasm-to-vacuole targeting; ER: endoplasmic reticulum; P4-ATPases: type IV P-type ATPases; PAS: phagophore assembly site; PE: phosphatidylethanolamine; PS: phosphatidylserine; PtdIns3P: phosphatidylinositol-3-phosphate; TGN: trans-Golgi network; WT: wild type

Published

2022

17. --Atg9 interactions via its transmembrane domains are required for phagophore expansion during autophagy.

Author

Chumpen Ramirez, Sabrina, Gómez-Sánchez, Rubén, Verlhac, Pauline, Hardenberg, Ralph, Margheritis, Eleonora, Cosentino, Katia, Reggiori, Fulvio, and Ungermann, Christian

Subjects

TRANSMEMBRANE domains, GREEN fluorescent protein, AUTOPHAGY, ENDOPLASMIC reticulum, MEMBRANE proteins, LYSOSOMES, MICROTUBULES

Abstract

During macroautophagy/autophagy, precursor cisterna known as phagophores expand and sequester portions of the cytoplasm and/or organelles, and subsequently close resulting in double-membrane transport vesicles called autophagosomes. Autophagosomes fuse with lysosomes/vacuoles to allow the degradation and recycling of their cargoes. We previously showed that sequential binding of yeast Atg2 and Atg18 to Atg9, the only conserved transmembrane protein in autophagy, at the extremities of the phagophore mediates the establishment of membrane contact sites between the phagophore and the endoplasmic reticulum. As the Atg2-Atg18 complex transfers lipids between adjacent membranes in vitro, it has been postulated that this activity and the scramblase activity of the trimers formed by Atg9 are required for the phagophore expansion. Here, we present evidence that Atg9 indeed promotes Atg2-Atg18 complex-mediated lipid transfer in vitro, although this is not the only requirement for its function in vivo. In particular, we show that Atg9 function is dramatically compromised by a F627A mutation within the conserved interface between the transmembrane domains of the Atg9 monomers. Although Atg9F627A self-interacts and binds to the Atg2-Atg18 complex, the F627A mutation blocks the phagophore expansion and thus autophagy progression. This phenotype is conserved because the corresponding human ATG9A mutant severely impairs autophagy as well. Importantly, Atg9F627A has identical scramblase activity in vitro like Atg9, and as with the wild-type protein enhances Atg2-Atg18-mediated lipid transfer. Collectively, our data reveal that interactions of Atg9 trimers via their transmembrane segments play a key role in phagophore expansion beyond Atg9ʹs role as a lipid scramblase.Abbreviations: BafA1: bafilomycin A1; Cvt: cytoplasm-to-vacuole targeting; Cryo-EM: cryo-electron microscopy; ER: endoplasmic reticulum; GFP: green fluorescent protein; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; MCS: membrane contact site; NBD-PE: N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine; PAS: phagophore assembly site; PE: phosphatidylethanolamine; prApe1: precursor Ape1; PtdIns3P: phosphatidylinositol-3-phosphate; SLB: supported lipid bilayer; SUV: small unilamellar vesicle; TMD: transmembrane domain; WT: wild type [ABSTRACT FROM AUTHOR]

Published

2023

18. SQSTM1, lipid droplets and current state of their lipophagy affairs.

Author

Shroff, Ankit and Nazarko, Taras Y.

Subjects

LIPIDS, HEAT shock proteins, AUTOPHAGY, LYSOSOMES, PERILIPIN, UBIQUITINATION

Abstract

SQSTM1/p62 (sequestosome 1) is a well-established indicator of macroautophagic/autophagic flux. It was initially characterized as the ubiquitin-binding autophagic receptor in aggrephagy, the selective autophagy of ubiquitinated protein aggregates. Recently, several studies correlated its levels with the abundance of intracellular lipid droplets (LDs). In the absence of a bona fide receptor for the selective autophagy of LDs (lipophagy), a few studies demonstrated the role of SQSTM1 in lipophagy. Our analysis of these studies shows that SQSTM1 colocalizes with LDs, bridges them with phagophores, is co-degraded with them in the lysosomes, and affects LD abundance in a variety of cells and under diverse experimental conditions. Although only one study reported all these functions together, the overwhelming and complementary evidence from other studies suggests that the role of SQSTM1 in lipophagy via tagging, movement, aggregation/clustering and sequestration of LDs is rather a common phenomenon in mammalian cells. As ubiquitination of the LD-associated proteins under stress conditions is increasingly recognized as another common phenomenon, some other ubiquitin-binding autophagic receptors, such as NBR1 and OPTN, might soon join SQSTM1 on a list of the non-exclusive lipophagy receptors. Abbreviations: LD: lipid droplet; LIR: LC3-interacting region; PAT: Perilipin, ADRP and TIP47 domain; SAR: selective autophagy receptor. [ABSTRACT FROM AUTHOR]

Published

2023

19. The Organization and Function of the Phagophore-ER Membrane Contact Sites.

Author

Duarte, Prado Vargas and Reggiori, Fulvio

Subjects

*LIPID transfer protein, *MOLECULAR structure, *PROTEIN structure, *SNARE proteins, *PROTEIN structure prediction

Published

2023

20. The world's first (and probably last) autophagy video game.

Author

Hawkins, Wayne D., Grush, Emily R., and Klionsky, Daniel J.

Subjects

VIDEO games, PHAGOCYTOSIS, SACCHAROMYCES cerevisiae, LYSOSOMES, AUTOPHAGY, ILLUSTRATION (Art), NUCLEIC acids, PARKINSON'S disease

Abstract

Macroautophagy/autophagy is the process by which portions of the cytoplasm are sequestered within a transient compartment and delivered to the degradative organelle of the cell, the vacuole or lysosome. Autophagy is a fundamental cytoprotective mechanism, and defects in this process are associated with many diseases. For example, the inability to degrade certain cargo such as mitochondria may lead to neurodegenerative disorders such as Parkinson disease. Autophagic cargo can be many different things including organelles, but also proteins and protein aggregates, nucleic acids, and lipids. Much of our understanding of autophagy comes from studies in baker's yeast, Saccharomyces cerevisiae. In that organism, autophagy begins at the phagophore assembly site (PAS), which nucleates the initial sequestering compartment, referred to as a phagophore. With the help of autophagy-related (Atg) proteins and lipid addition, the phagophore membrane expands to enclose damaged or superfluous cytoplasmic components, eventually closing into a completed double-membrane vesicle called the autophagosome. The autophagosome is delivered to the degradative organelle where it fuses, releasing the encapsulated cargo into the interior of the organelle where it is broken down into macromolecular building blocks. The resulting building blocks are released back into the cytosol for reuse. Video games are modern expressions of art incorporating illustration, animation, and mechanistic design. While often underappreciated as a scientific art form, video games can beautifully express scientific topics in a way that is both intuitive and engaging, especially to a younger audience. [ABSTRACT FROM AUTHOR]

Published

2023

21. Membrane Contact Sites in Autophagy.

Author

Zwilling, Emma and Reggiori, Fulvio

Subjects

*ORGANELLE formation, *LYSOSOMES, *PLANT vacuoles, *AUTOPHAGY, *LIPID metabolism, *ORGANELLES

Abstract

Eukaryotes utilize different communication strategies to coordinate processes between different cellular compartments either indirectly, through vesicular transport, or directly, via membrane contact sites (MCSs). MCSs have been implicated in lipid metabolism, calcium signaling and the regulation of organelle biogenesis in various cell types. Several studies have shown that MCSs play a crucial role in the regulation of macroautophagy, an intracellular catabolic transport route that is characterized by the delivery of cargoes (proteins, protein complexes or aggregates, organelles and pathogens) to yeast and plant vacuoles or mammalian lysosomes, for their degradation and recycling into basic metabolites. Macroautophagy is characterized by the de novo formation of double-membrane vesicles called autophagosomes, and their biogenesis requires an enormous amount of lipids. MCSs appear to have a central role in this supply, as well as in the organization of the autophagy-related (ATG) machinery. In this review, we will summarize the evidence for the participation of specific MCSs in autophagosome formation, with a focus on the budding yeast and mammalian systems. [ABSTRACT FROM AUTHOR]

Published

2022

22. Phospholipid imbalance impairs autophagosome completion.

Author

Polyansky, Alexandra, Shatz, Oren, Fraiberg, Milana, Shimoni, Eyal, Dadosh, Tali, Mari, Muriel, Reggiori, Fulvio M, Qin, Chao, Han, Xianlin, and Elazar, Zvulun

Subjects

*PHOSPHATIDYLSERINES, *LYSOSOMES, *AUTOPHAGY, *HOMEOSTASIS, *LIPIDS, *METABOLISM, *LECITHIN

Abstract

Autophagy, a conserved eukaryotic intracellular catabolic pathway, maintains cell homeostasis by lysosomal degradation of cytosolic material engulfed in double membrane vesicles termed autophagosomes, which form upon sealing of single‐membrane cisternae called phagophores. While the role of phosphatidylinositol 3‐phosphate (PI3P) and phosphatidylethanolamine (PE) in autophagosome biogenesis is well‐studied, the roles of other phospholipids in autophagy remain rather obscure. Here we utilized budding yeast to study the contribution of phosphatidylcholine (PC) to autophagy. We reveal for the first time that genetic loss of PC biosynthesis via the CDP‐DAG pathway leads to changes in lipid composition of autophagic membranes, specifically replacement of PC by phosphatidylserine (PS). This impairs closure of the autophagic membrane and autophagic flux. Consequently, we show that choline‐dependent recovery of de novo PC biosynthesis via the CDP‐choline pathway restores autophagosome formation and autophagic flux in PC‐deficient cells. Our findings therefore implicate phospholipid metabolism in autophagosome biogenesis. Synopsis: The autophagic membrane has a characteristic lipid composition. Phospholipid imbalance within this membrane, especially the substitution of phosphatidylcholine (PC) by phosphatidylserine (PS), leads to phagophores which are unable to close. Loss of PC synthesis impairs autophagosome completion.Replacement of PC by PS in the phagophore maintains growth but impairs closure.De novo PC synthesis by the CDP‐Choline pathway restores autophagosome completion in CDP‐DAG mutant cells. [ABSTRACT FROM AUTHOR]

Published

2022

23. Vtc4 Promotes the Entry of Phagophores into Vacuoles in the Saccharomyces cerevisiae Snf7 Mutant Cell

Author

Xiaofan Chen and Yongheng Liang

Subjects

autophagy, ESCRT, phagophore, Snf7, vacuole, Vps21, Biology (General), QH301-705.5

Abstract

Endocytosis and autophagy are the main pathways to deliver cargoes in vesicles and autophagosomes, respectively, to vacuoles/lysosomes in eukaryotes. Multiple positive regulators but few negative ones are reported to regulate the entry of vesicles and autophagosomes into vacuoles/lysosomes. In yeast, the Rab5 GTPase Vps21 and the ESCRT (endosomal sorting complex required for transport) are positive regulators in endocytosis and autophagy. During autophagy, Vps21 regulates the ESCRT to phagophores (unclosed autophagosomes) to close them. Phagophores accumulate on vacuolar membranes in both vps21∆ and ESCRT mutant cells under a short duration of nitrogen starvation. The vacuolar transport chaperon (VTC) complex proteins are recently found to be negative regulators in endocytosis and autophagy. Phagophores in vps21∆ cells are promoted to enter vacuoles when the VTC complex proteins are absent. Phagophores are easily observed inside vacuoles when any of these VTC complex proteins (Vtc1, 2, 4, 5) are removed. However, it is unknown whether the removal of VTC complex proteins will also promote the entry of phagophores into vacuoles in ESCRT mutant cells under the same conditions. Snf7 is a core subunit of ESCRT subcomplex III (ESCRT-III), and phagophores accumulate in snf7∆ cells under a short duration of nitrogen starvation. We used green fluorescence protein (GFP) labeled Atg8 to display phagophores and FM4-64-stained or Vph1-GFP-labeled membrane structures to show vacuoles, then examined fluorescence localization and GFP-Atg8 degradation in snf7∆ and snf7∆vtc4∆ cells. Results showed that Vtc4 depletion promoted the entry of phagophores in snf7∆ cells into vacuoles as it did for vps21∆ cells, although the promotion level was more obvious in vps21∆ cells. This observation indicates that the VTC complex proteins may have a widespread role in negatively regulating cargos to enter vacuoles in yeast.

Published

2023

24. Autophagosomal Membrane Origin and Formation

Author

Yang, Yi, Zheng, Li, Zheng, Xiaoxiang, Ge, Liang, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Steinlein, Ortrud, Series Editor, Xiao, Junjie, Series Editor, and Xie, Zhiping, editor

Published

2021

25. Morphology of Phagophore Precursors by Correlative Light-Electron Microscopy.

Author

Gudmundsson, Sigurdur Runar, Kallio, Katri A., Vihinen, Helena, Jokitalo, Eija, Ktistakis, Nicholas, and Eskelinen, Eeva-Liisa

Subjects

*MICROSCOPY, *MORPHOLOGY, *FLUORESCENCE microscopy, *CELL imaging, *AUTOPHAGY, *ENDOPLASMIC reticulum, *CYTOSOL

Abstract

Autophagosome biogenesis occurs in the transient subdomains of the endoplasmic reticulum that are called omegasomes, which, in fluorescence microscopy, appear as small puncta, which then grow in diameter and finally shrink and disappear once the autophagosome is complete. Autophagosomes are formed by phagophores, which are membrane cisterns that elongate and close to form the double membrane that limits autophagosomes. Earlier electron-microscopy studies showed that, during elongation, phagophores are lined by the endoplasmic reticulum on both sides. However, the morphology of the very early phagophore precursors has not been studied at the electron-microscopy level. We used live-cell imaging of cells expressing markers of phagophore biogenesis combined with correlative light-electron microscopy, as well as electron tomography of ATG2A/B-double-deficient cells, to reveal the high-resolution morphology of phagophore precursors in three dimensions. We showed that phagophores are closed or nearly closed into autophagosomes already at the stage when the omegasome diameter is still large. We further observed that phagophore precursors emerge next to the endoplasmic reticulum as bud-like highly curved membrane cisterns with a small opening to the cytosol. The phagophore precursors then open to form more flat cisterns that elongate and curve to form the classically described crescent-shaped phagophores. [ABSTRACT FROM AUTHOR]

Published

2022

26. Biogenesis of omegasomes and autophagosomes in mammalian autophagy.

Author

Norell PN, Campisi D, Mohan J, and Wollert T

Subjects

Animals, Humans, Mammals metabolism, Autophagy physiology, Autophagosomes metabolism

Abstract

Autophagy is a highly conserved catabolic pathway that maintains cellular homeostasis by promoting the degradation of damaged or superfluous cytoplasmic material. A hallmark of autophagy is the generation of membrane cisternae that sequester autophagic cargo. Expansion of these structures allows cargo to be engulfed in a highly selective and exclusive manner. Cytotoxic stress or starvation induces the formation of autophagosomes that sequester bulk cytoplasm instead of selected cargo. This rather nonselective pathway is essential for maintaining vital cellular functions during adverse conditions and is thus a major stress response pathway. Both selective and nonselective autophagy rely on the same molecular machinery. However, due to the different nature of cargo to be sequestered, the involved molecular mechanisms are fundamentally different. Although intense research over the past decades has advanced our understanding of autophagy, fundamental questions remain to be addressed. This review will focus on molecular principles and open questions regarding the formation of omegasomes and phagophores in nonselective mammalian autophagy., (© 2024 The Author(s).)

Published

2024

27. Expanding the view of the molecular mechanisms of autophagy pathway.

Author

Majeed, Sheikh Tahir, Majeed, Rabiya, and Andrabi, Khurshid I.

Subjects

*PLANT vacuoles, *AUTOPHAGY, *LYSIS, *LYSOSOMES

Abstract

Autophagy is an evolutionarily conserved multistep degradation mechanism in eukaryotes, that maintains cellular homoeostasis by replenishing cells with nutrients through catabolic lysis of the cytoplasmic components. This critically coordinated pathway involves sequential processing events that begin with initiation, nucleation, and elongation of phagophores, followed by the formation of double‐membrane vesicles known as autophagosomes. Finally, autophagosomes migrate towards and fuse with lysosomes in mammals and vacuoles in yeast and plants, for the eventual degradation of the intravesicular cargo. Here, we review the recent advances in our understanding of the molecular events that define the process of autophagy. [ABSTRACT FROM AUTHOR]

Published

2022

28. Regulation of Autophagy Machinery in Magnaporthe oryzae.

Author

Asif, Nida, Lin, Fucheng, Li, Lin, Zhu, Xueming, and Nawaz, Sehar

Subjects

*RICE blast disease, *AUTOPHAGY, *APOPTOSIS, *PHYTOPATHOGENIC fungi, *PLANT diseases

Abstract

Plant diseases cause substantial loss to crops all over the world, reducing the quality and quantity of agricultural goods significantly. One of the world's most damaging plant diseases, rice blast poses a substantial threat to global food security. Magnaporthe oryzae causes rice blast disease, which challenges world food security by causing substantial damage in rice production annually. Autophagy is an evolutionarily conserved breakdown and recycling system in eukaryotes that regulate homeostasis, stress adaption, and programmed cell death. Recently, new studies found that the autophagy process plays a vital role in the pathogenicity of M. oryzae and the regulation mechanisms are gradually clarified. Here we present a brief summary of the recent advances, concentrating on the new findings of autophagy regulation mechanisms and summarize some autophagy-related techniques in rice blast fungus. This review will help readers to better understand the relationship between autophagy and the virulence of plant pathogenic fungi. [ABSTRACT FROM AUTHOR]

Published

2022

29. SHISA5/SCOTIN restrains spontaneous autophagy induction by blocking contact between the ERES and phagophores.

Author

Lee, Jee-Eun, Kim, Nari, Jung, Minkyo, Mun, Ji-Young, and Yoo, Joo-Yeon

Subjects

GREEN fluorescent protein, COAT proteins (Viruses), AUTOPHAGY, MEMBRANE proteins, PHYSIOLOGIC salines, RIBOSOMAL proteins, STREPTAVIDIN

Abstract

The phagophore expands into autophagosomes in close proximity to endoplasmic reticulum (ER) exit sites (ERESs). Here, we propose that a single-pass ER transmembrane protein, SHISA5/SCOTIN, acts as an autophagy suppressor under basal condition by blocking the contact between the phagophore and ERES. HeLa cells lacking SHISA5 displayed higher levels of macroautophagy/autophagy. The enhanced autophagy in SHISA5 KO cells requires class III phosphatidylinositol 3-kinase complex I (PtdIns3K-C1) activity and functional assembly of ERES, but not ULK1 activity. A proximity ligation assay (PLA) of SEC16A (Sec16 homolog A, endoplasmic reticulum export factor)-WIPI2 (WD repeat domain, phosphoinositide interacting 2) and SEC31A (Sec31 homolog A, COPII coat complex component)-MAP1LC3B/LC3B (microtubule-associated protein 1 light chain 3 beta) demonstrated that contact between the ERES and phagophore increased in SHISA5 KO cells, and the cytosolic domain of SHISA5 was sufficient to rescue this phenotype. Close proximity between ERES and phagophore in SHISA5 KO cells was also visualized by performing an ultrastructure correlative image analysis of SEC31A associated with LC3-positive membranes. Furthermore, we observed that SHISA5 was located near ERES under basal conditions, but displaced away from ERES under autophagy-inducing conditions. These data suggest that SHISA5 functions to block spontaneous contact between ERES and phagophore, and the blockage effect of SHISA5 should be relieved for the proper induction of autophagy. ATG2: autophagy related 2; BECN1: beclin 1; COPII: coat protein II; DMSO: dimethyl sulfoxide; EBSS: Earle's balanced salt solution; EGFP: enhanced green fluorescent protein; ER: endoplasmic reticulum; ERES: ER exit site(s); GFP: green fluorescent protein; H89: H-89 dihydrochloride hydrate; LAMP1: lysosomal-associated membrane protein 1; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; MTORC1: mechanistic target of rapamycin kinase complex 1; NS5A: nonstructural protein 5A; PIK3C3/VPS34: phosphatidylinositol 3-kinase catalytic subunit type 3; PLA: proximity ligation assay; PtdIns3P: phosphatidylionositol-3-phosphate; RB1CC1/FIP200: RB1 inducible coiled-coil 1; RFP: red fluorescent protein; RPS6KB1/S6K: ribosomal protein S6 kinase B1; SBP: streptavidin binding protein; SEC16A: SEC16 homolog A, endoplasmic reticulum export factor; SEC31A: SEC31 homolog A, COPII coat complex component; siRNA: small interfering RNA; Str: streptavidin; ULK1: unc-51-like autophagy activating kinase 1; VSVG: vesicular stomatitis virus glycoprotein; WIPI2: WD repeat domain, phosphoinositide interacting 2; WT: wild type [ABSTRACT FROM AUTHOR]

Published

2022

30. Autophagy: A self degradation system in plants

Author

Banoo, Muneeba, Sinha, Bhav Kumar, Chand, Gurdev, Reena, and Khan, Farooq Ahmad

Published

2021

31. Autophagic structures revealed by cryo-electron tomography: new clues about autophagosome biogenesis.

Author

Popelka, Hana and Klionsky, Daniel J.

Subjects

TOMOGRAPHY, ENDOPLASMIC reticulum, CYTOLOGY, AUTOPHAGY, ULTRASTRUCTURE (Biology)

Abstract

Transitions from the early to late phagophore, which occur to engulf cytoplasmic material within an autophagosome for macroautophagic/autophagic degradation, involve dynamic ultrastructural changes that are not fully understood. A recent study combined cryo-electron tomography (cryo-ET) with extensive computational analysis to get a better insight into autophagosome biogenesis in situ within yeast cells. This approach disclosed new information on the shape of autophagic structures, their contacts with surrounding organelles, membrane sources, and mechanisms of transition. Together, these results provide new directions for autophagy research, and show the potential of cryo-ET in cell biology. Abbreviations: Cryo-ET, cryo-electron tomography; ER, endoplasmic reticulum; IMDa, intermembrane distance in the autophagosome; IMDp, intermembrane distance in the phagophore; LD, lipid droplets [ABSTRACT FROM AUTHOR]

Published

2023

32. Guidelines for the use and interpretation of assays for monitoring autophagy (3rd edition)

Author

Klionsky, Daniel J, Abdelmohsen, Kotb, Abe, Akihisa, Abedin, Md Joynal, Abeliovich, Hagai, Acevedo Arozena, Abraham, Adachi, Hiroaki, Adams, Christopher M, Adams, Peter D, Adeli, Khosrow, Adhihetty, Peter J, Adler, Sharon G, Agam, Galila, Agarwal, Rajesh, Aghi, Manish K, Agnello, Maria, Agostinis, Patrizia, Aguilar, Patricia V, Aguirre-Ghiso, Julio, Airoldi, Edoardo M, Ait-Si-Ali, Slimane, Akematsu, Takahiko, Akporiaye, Emmanuel T, Al-Rubeai, Mohamed, Albaiceta, Guillermo M, Albanese, Chris, Albani, Diego, Albert, Matthew L, Aldudo, Jesus, Algül, Hana, Alirezaei, Mehrdad, Alloza, Iraide, Almasan, Alexandru, Almonte-Beceril, Maylin, Alnemri, Emad S, Alonso, Covadonga, Altan-Bonnet, Nihal, Altieri, Dario C, Alvarez, Silvia, Alvarez-Erviti, Lydia, Alves, Sandro, Amadoro, Giuseppina, Amano, Atsuo, Amantini, Consuelo, Ambrosio, Santiago, Amelio, Ivano, Amer, Amal O, Amessou, Mohamed, Amon, Angelika, An, Zhenyi, Anania, Frank A, Andersen, Stig U, Andley, Usha P, Andreadi, Catherine K, Andrieu-Abadie, Nathalie, Anel, Alberto, Ann, David K, Anoopkumar-Dukie, Shailendra, Antonioli, Manuela, Aoki, Hiroshi, Apostolova, Nadezda, Aquila, Saveria, Aquilano, Katia, Araki, Koichi, Arama, Eli, Aranda, Agustin, Araya, Jun, Arcaro, Alexandre, Arias, Esperanza, Arimoto, Hirokazu, Ariosa, Aileen R, Armstrong, Jane L, Arnould, Thierry, Arsov, Ivica, Asanuma, Katsuhiko, Askanas, Valerie, Asselin, Eric, Atarashi, Ryuichiro, Atherton, Sally S, Atkin, Julie D, Attardi, Laura D, Auberger, Patrick, Auburger, Georg, Aurelian, Laure, Autelli, Riccardo, Avagliano, Laura, Avantaggiati, Maria Laura, Avrahami, Limor, Awale, Suresh, Azad, Neelam, Bachetti, Tiziana, Backer, Jonathan M, Bae, Dong-Hun, Bae, Jae-Sung, Bae, Ok-Nam, Bae, Soo Han, Baehrecke, Eric H, Baek, Seung-Hoon, Baghdiguian, Stephen, and Bagniewska-Zadworna, Agnieszka

Subjects

Biochemistry and Cell Biology, Biological Sciences, Animals, Autophagy, Biological Assay, Computer Simulation, Humans, autolysosome, autophagosome, chaperone-mediated autophagy, flux, LC3, lysosome, macroautophagy, phagophore, stress, vacuole, Biochemistry & Molecular Biology, Biochemistry and cell biology

Published

2016

33. Phosphoregulation of the autophagy machinery by kinases and phosphatases.

Author

Licheva, Mariya, Raman, Babu, Kraft, Claudine, and Reggiori, Fulvio

Subjects

AUTOPHAGY, PHOSPHATASES, KINASES, POST-translational modification, EUKARYOTIC cells

Abstract

Eukaryotic cells use post-translational modifications to diversify and dynamically coordinate the function and properties of protein networks within various cellular processes. For example, the process of autophagy strongly depends on the balanced action of kinases and phosphatases. Highly conserved from the budding yeast Saccharomyces cerevisiae to humans, autophagy is a tightly regulated self-degradation process that is crucial for survival, stress adaptation, maintenance of cellular and organismal homeostasis, and cell differentiation and development. Many studies have emphasized the importance of kinases and phosphatases in the regulation of autophagy and identified many of the core autophagy proteins as their direct targets. In this review, we summarize the current knowledge on kinases and phosphatases acting on the core autophagy machinery and discuss the relevance of phosphoregulation for the overall process of autophagy. [ABSTRACT FROM AUTHOR]

Published

2022

34. Autophagy in a Nutshell.

Author

Shatz, Oren and Elazar, Zvulun

Subjects

*CYTOPLASM

Abstract

Autophagy is an intracellular catabolic process that eliminates cytoplasmic constituents selectively by tight engulfment in an isolation membrane or recycles bulk cytoplasm by nonselective sequestration. Completion of the isolation membrane forms a double membrane vesicle, termed autophagosome, that proceeds to fusion with the lysosome, where the inner membrane and its cytoplasmic content are degraded. Autophagosome biogenesis is unique in that the newly‐formed membrane, termed phagophore, is elongated by direct lipid flow from a proximal ER‐associated donor membrane. Recent years mark a tremendous advancement in delineating the direct regulation of this process by different lipid species and associated protein complexes. Here we schematically summarize the current view of autophagy and autophagosome biogenesis. [ABSTRACT FROM AUTHOR]

Published

2024

35. Senescence and Programmed Cell Death

Author

Kalra, Geetika, Bhatla, Satish C, Bhatla, Satish C, and A. Lal, Manju

Published

2018

36. Membrane Contact Sites in Autophagy

Author

Emma Zwilling and Fulvio Reggiori

Subjects

phagophore, autophagosome, endoplasmic reticulum, mitochondria, MAMs, plasma membrane, Cytology, QH573-671

Abstract

Eukaryotes utilize different communication strategies to coordinate processes between different cellular compartments either indirectly, through vesicular transport, or directly, via membrane contact sites (MCSs). MCSs have been implicated in lipid metabolism, calcium signaling and the regulation of organelle biogenesis in various cell types. Several studies have shown that MCSs play a crucial role in the regulation of macroautophagy, an intracellular catabolic transport route that is characterized by the delivery of cargoes (proteins, protein complexes or aggregates, organelles and pathogens) to yeast and plant vacuoles or mammalian lysosomes, for their degradation and recycling into basic metabolites. Macroautophagy is characterized by the de novo formation of double-membrane vesicles called autophagosomes, and their biogenesis requires an enormous amount of lipids. MCSs appear to have a central role in this supply, as well as in the organization of the autophagy-related (ATG) machinery. In this review, we will summarize the evidence for the participation of specific MCSs in autophagosome formation, with a focus on the budding yeast and mammalian systems.

Published

2022

37. Morphology of Phagophore Precursors by Correlative Light-Electron Microscopy

Author

Sigurdur Runar Gudmundsson, Katri A. Kallio, Helena Vihinen, Eija Jokitalo, Nicholas Ktistakis, and Eeva-Liisa Eskelinen

Subjects

autophagy, phagophore, isolation membrane, omegasome, ATG13, DFCP1, Cytology, QH573-671

Abstract

Autophagosome biogenesis occurs in the transient subdomains of the endoplasmic reticulum that are called omegasomes, which, in fluorescence microscopy, appear as small puncta, which then grow in diameter and finally shrink and disappear once the autophagosome is complete. Autophagosomes are formed by phagophores, which are membrane cisterns that elongate and close to form the double membrane that limits autophagosomes. Earlier electron-microscopy studies showed that, during elongation, phagophores are lined by the endoplasmic reticulum on both sides. However, the morphology of the very early phagophore precursors has not been studied at the electron-microscopy level. We used live-cell imaging of cells expressing markers of phagophore biogenesis combined with correlative light-electron microscopy, as well as electron tomography of ATG2A/B-double-deficient cells, to reveal the high-resolution morphology of phagophore precursors in three dimensions. We showed that phagophores are closed or nearly closed into autophagosomes already at the stage when the omegasome diameter is still large. We further observed that phagophore precursors emerge next to the endoplasmic reticulum as bud-like highly curved membrane cisterns with a small opening to the cytosol. The phagophore precursors then open to form more flat cisterns that elongate and curve to form the classically described crescent-shaped phagophores.

Published

2022

38. Membrane supply and remodeling during autophagosome biogenesis.

Author

Gómez-Sánchez, Rubén, Tooze, Sharon A., and Reggiori, Fulvio

Subjects

*MEMBRANE lipids, *ORGANELLE formation, *BIOLOGICAL transport, *AUTOPHAGY, *LIPIDS

Abstract

The de novo generation of double-membrane autophagosomes is the hallmark of autophagy. The initial membranous precursor cisterna, the phagophore, is very likely generated by the fusion of vesicles and acts as a membrane seed for the subsequent expansion into an autophagosome. This latter step requires a massive convoy of lipids into the phagophore. In this review, we present recent advances in our understanding of the intracellular membrane sources and lipid delivery mechanisms, which principally rely on vesicular transport and membrane contact sites that contribute to autophagosome biogenesis. In this context, we discuss lipid biosynthesis and lipid remodeling events that play a crucial role in both phagophore nucleation and expansion. [ABSTRACT FROM AUTHOR]

Published

2021

39. Mammalian BCAS3 and C16orf70 associate with the phagophore assembly site in response to selective and non-selective autophagy.

Author

Kojima, Waka, Yamano, Koji, Kosako, Hidetaka, Imai, Kenichiro, Kikuchi, Reika, Tanaka, Keiji, and Matsuda, Noriyuki

Subjects

AUTOPHAGY, LYSOSOMES, ENDOPLASMIC reticulum, MASS spectrometry, PROTEIN-protein interactions

Abstract

Macroautophagy/autophagy is an intracellular degradation process that delivers cytosolic materials and/or damaged organelles to lysosomes. De novo synthesis of the autophagosome membrane occurs within a phosphatidylinositol-3-phosphate-rich region of the endoplasmic reticulum, and subsequent expansion is critical for cargo encapsulation. This process is complex, especially in mammals, with many regulatory factors. In this study, by utilizing PRKN (parkin RBR E3 ubiquitin protein ligase)-mediated mitochondria autophagy (mitophagy)-inducing conditions in conjunction with chemical crosslinking and mass spectrometry, we identified human BCAS3 (BCAS3 microtubule associated cell migration factor) and C16orf70 (chromosome 16 open reading frame 70) as novel proteins that associate with the autophagosome formation site during both non-selective and selective autophagy. We demonstrate that BCAS3 and C16orf70 form a complex and that their association with the phagophore assembly site requires both proteins. In silico structural modeling, mutational analyses in cells and in vitro phosphoinositide-binding assays indicate that the WD40 repeat domain in human BCAS3 directly binds phosphatidylinositol-3-phosphate. Furthermore, overexpression of the BCAS3-C16orf70 complex affects the recruitment of several core autophagy proteins to the phagophore assembly site. This study demonstrates regulatory roles for human BCAS3 and C16orf70 in autophagic activity. Abbreviations: AO: antimycin A and oligomycin; Ash: assembly helper; ATG: autophagy-related; BCAS3: BCAS3 microtubule associated cell migration factor; C16orf70: chromosome 16 open reading frame 70; DAPI: 4',6-diamidino-2-phenylindole; DKO: double knockout; DMSO: dimethyl sulfoxide; ER: endoplasmic reticulum; fluoppi: fluorescent-based technology detecting protein-protein interactions; FIS1: fission, mitochondrial 1; FKBP: FKBP prolyl isomerase family member 1C; FRB: FKBP-rapamycin binding; hAG: humanized azami-green; IP: immunoprecipitation; IRES: internal ribosome entry site; KO: knockout; MAP1LC3B/LC3B: microtubule associated protein 1 light chain 3 beta; MFN2: mitofusin 2; MS: mass spectrometry; MT-CO2: mitochondrially encoded cytochrome c oxidase II; mtDNA: mitochondrial DNA; OPTN: optineurin; PFA: paraformaldehyde; PE: phosphatidylethanolamine; PtdIns3K: phosphatidylinositol 3-kinase; PtdIns3P: phosphatidylinositol-3-phosphate; PtdIns(3,5)P2: phosphatidylinositol-3,5-bisphosphate; PINK1: PTEN induced kinase 1; PRKN/Parkin: parkin RBR E3 ubiquitin protein ligase; PROPPIN: β-propellers that bind polyphosphoinositides; RB1CC1/FIP200: RB1 inducible coiled-coil 1; TOMM20: translocase of outer mitochondrial membrane 20; ULK1: unc-51 like autophagy activating kinase 1; WDR45B/WIPI3: WD repeat domain 45B; WDR45/WIPI4: WD repeat domain 45; WIPI: WD repeat domain, phosphoinositide interacting; WT: wild type; ZFYVE1/DFCP1: zinc finger FYVE-type containing 1 [ABSTRACT FROM AUTHOR]

Published

2021

40. Rim aperture of yeast autophagic membranes balances cargo inclusion with vesicle maturation.

Author

Shatz, Oren, Fraiberg, Milana, Isola, Damilola, Das, Shubhankar, Gogoi, Olee, Polyansky, Alexandra, Shimoni, Eyal, Dadosh, Tali, Dezorella, Nili, Wolf, Sharon G., and Elazar, Zvulun

Subjects

*FREIGHT & freightage, *COATED vesicles, *YEAST, *AUTOPHAGY, *SACCHAROMYCES cerevisiae

Abstract

Autophagy eliminates cytoplasmic material by engulfment in membranous vesicles targeted for lysosome degradation. Nonselective autophagy coordinates sequestration of bulk cargo with the growth of the isolation membrane (IM) in a yet-unknown manner. Here, we show that in the budding yeast Saccharomyces cerevisiae , IMs expand while maintaining a rim sufficiently wide for sequestration of large cargo but tight enough to mature in due time. An obligate complex of Atg24/Snx4 with Atg20 or Snx41 assembles locally at the rim in a spatially extended manner that specifically depends on autophagic PI(3)P. This assembly stabilizes the open rim to promote autophagic sequestration of large cargo in correlation with vesicle expansion. Moreover, constriction of the rim by the PI(3)P-dependent Atg2-Atg18 complex and clearance of PI(3)P by Ymr1 antagonize rim opening to promote autophagic maturation and consumption of small cargo. Tight regulation of membrane rim aperture by PI(3)P thus couples the mechanism and physiology of nonselective autophagy. [Display omitted] • The nonselective yeast phagophore expands spherically while maintaining a narrow rim • The Atg2-Atg18 complex maintains rim constriction during membrane expansion • Local assembly of an autophagy-specific Atg20-Atg24 stabilizes a widely open rim • Rim stabilization is essential for autophagic sequestration of large cytoplasmic cargo Autophagosome biogenesis couples sequestration of cargo to expansion of the autophagic membrane in an elusive manner. Shatz et al. show that the rim of the nonselective yeast phagophore is tightly regulated to balance the inclusion of large cytoplasmic cargo with productive maturation in due time. [ABSTRACT FROM AUTHOR]

Published

2024

41. Regulation of Autophagy Machinery in Magnaporthe oryzae

Author

Nida Asif, Fucheng Lin, Lin Li, Xueming Zhu, and Sehar Nawaz

Subjects

Magnaporthe oryzae, autophagy, pathogenesis, appressorium, phagophore, autophagosome, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Plant diseases cause substantial loss to crops all over the world, reducing the quality and quantity of agricultural goods significantly. One of the world’s most damaging plant diseases, rice blast poses a substantial threat to global food security. Magnaporthe oryzae causes rice blast disease, which challenges world food security by causing substantial damage in rice production annually. Autophagy is an evolutionarily conserved breakdown and recycling system in eukaryotes that regulate homeostasis, stress adaption, and programmed cell death. Recently, new studies found that the autophagy process plays a vital role in the pathogenicity of M. oryzae and the regulation mechanisms are gradually clarified. Here we present a brief summary of the recent advances, concentrating on the new findings of autophagy regulation mechanisms and summarize some autophagy-related techniques in rice blast fungus. This review will help readers to better understand the relationship between autophagy and the virulence of plant pathogenic fungi.

Published

2022

42. Guidelines for the use and interpretation of assays for monitoring autophagy (4th edition)1.

Author

Klionsky, Daniel J., Abdel-Aziz, Amal Kamal, Abdelfatah, Sara, Abdellatif, Mahmoud, Abdoli, Asghar, Abel, Steffen, Abeliovich, Hagai, Abildgaard, Marie H., Abudu, Yakubu Princely, Acevedo-Arozena, Abraham, Adamopoulos, Iannis E., Adeli, Khosrow, Adolph, Timon E., Adornetto, Annagrazia, Aflaki, Elma, Agam, Galila, Agarwal, Anupam, Aggarwal, Bharat B., Agnello, Maria, and Agostinis, Patrizia

Subjects

AUTOPHAGY, EUKARYOTES, APOPTOSIS, GENE targeting, NEURODEGENERATION

Abstract

In 2008, we published the first set of guidelines for standardizing research in autophagy. Since then, this topic has received increasing attention, and many scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Thus, it is important to formulate on a regular basis updated guidelines for monitoring autophagy in different organisms. Despite numerous reviews, there continues to be confusion regarding acceptable methods to evaluate autophagy, especially in multicellular eukaryotes. Here, we present a set of guidelines for investigators to select and interpret methods to examine autophagy and related processes, and for reviewers to provide realistic and reasonable critiques of reports that are focused on these processes. These guidelines are not meant to be a dogmatic set of rules, because the appropriateness of any assay largely depends on the question being asked and the system being used. Moreover, no individual assay is perfect for every situation, calling for the use of multiple techniques to properly monitor autophagy in each experimental setting. Finally, several core components of the autophagy machinery have been implicated in distinct autophagic processes (canonical and noncanonical autophagy), implying that genetic approaches to block autophagy should rely on targeting two or more autophagy-related genes that ideally participate in distinct steps of the pathway. Along similar lines, because multiple proteins involved in autophagy also regulate other cellular pathways including apoptosis, not all of them can be used as a specific marker for bona fide autophagic responses. Here, we critically discuss current methods of assessing autophagy and the information they can, or cannot, provide. Our ultimate goal is to encourage intellectual and technical innovation in the field. [ABSTRACT FROM AUTHOR]

Published

2021

43. Guidelines for the use and interpretation of assays for monitoring autophagy.

Author

Klionsky, Daniel J, Abdalla, Fabio C, Abeliovich, Hagai, Abraham, Robert T, Acevedo-Arozena, Abraham, Adeli, Khosrow, Agholme, Lotta, Agnello, Maria, Agostinis, Patrizia, Aguirre-Ghiso, Julio A, Ahn, Hyung Jun, Ait-Mohamed, Ouardia, Ait-Si-Ali, Slimane, Akematsu, Takahiko, Akira, Shizuo, Al-Younes, Hesham M, Al-Zeer, Munir A, Albert, Matthew L, Albin, Roger L, Alegre-Abarrategui, Javier, Aleo, Maria Francesca, Alirezaei, Mehrdad, Almasan, Alexandru, Almonte-Becerril, Maylin, Amano, Atsuo, Amaravadi, Ravi, Amarnath, Shoba, Amer, Amal O, Andrieu-Abadie, Nathalie, Anantharam, Vellareddy, Ann, David K, Anoopkumar-Dukie, Shailendra, Aoki, Hiroshi, Apostolova, Nadezda, Arancia, Giuseppe, Aris, John P, Asanuma, Katsuhiko, Asare, Nana YO, Ashida, Hisashi, Askanas, Valerie, Askew, David S, Auberger, Patrick, Baba, Misuzu, Backues, Steven K, Baehrecke, Eric H, Bahr, Ben A, Bai, Xue-Yuan, Bailly, Yannick, Baiocchi, Robert, Baldini, Giulia, Balduini, Walter, Ballabio, Andrea, Bamber, Bruce A, Bampton, Edward TW, Bánhegyi, Gábor, Bartholomew, Clinton R, Bassham, Diane C, Bast, Robert C, Batoko, Henri, Bay, Boon-Huat, Beau, Isabelle, Béchet, Daniel M, Begley, Thomas J, Behl, Christian, Behrends, Christian, Bekri, Soumeya, Bellaire, Bryan, Bendall, Linda J, Benetti, Luca, Berliocchi, Laura, Bernardi, Henri, Bernassola, Francesca, Besteiro, Sébastien, Bhatia-Kissova, Ingrid, Bi, Xiaoning, Biard-Piechaczyk, Martine, Blum, Janice S, Boise, Lawrence H, Bonaldo, Paolo, Boone, David L, Bornhauser, Beat C, Bortoluci, Karina R, Bossis, Ioannis, Bost, Frédéric, Bourquin, Jean-Pierre, Boya, Patricia, Boyer-Guittaut, Michaël, Bozhkov, Peter V, Brady, Nathan R, Brancolini, Claudio, Brech, Andreas, Brenman, Jay E, Brennand, Ana, Bresnick, Emery H, Brest, Patrick, Bridges, Dave, Bristol, Molly L, Brookes, Paul S, Brown, Eric J, and Brumell, John H

Subjects

Animals, Humans, Biological Assay, Models, Biological, Autophagy, Generic health relevance, autolysosome, autophagosome, flux, LC3, lysosome, phagophore, stress, vacuole, Biochemistry and Cell Biology, Biochemistry & Molecular Biology

Abstract

In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused on these processes. These guidelines are not meant to be a formulaic set of rules, because the appropriate assays depend in part on the question being asked and the system being used. In addition, we emphasize that no individual assay is guaranteed to be the most appropriate one in every situation, and we strongly recommend the use of multiple assays to monitor autophagy. In these guidelines, we consider these various methods of assessing autophagy and what information can, or cannot, be obtained from them. Finally, by discussing the merits and limits of particular autophagy assays, we hope to encourage technical innovation in the field.

Published

2012

44. Membrane targeting of core autophagy players during autophagosome biogenesis.

Author

Dudley, Leo J., Makar, Agata N., and Gammoh, Noor

Subjects

*ORGANELLE formation, *LYSOSOMES, *AUTOPHAGY, *ORGANELLES, *OPEN-ended questions, *HOMEOSTASIS

Abstract

Autophagosomes are vital organelles required to facilitate the lysosomal degradation of cytoplasmic cargo, thereby playing an important role in maintaining cellular homeostasis. A number of autophagy‐related (ATG) protein complexes are recruited to the site of autophagosome biogenesis where they act to facilitate membrane growth and maturation. Regulated recruitment of ATG complexes to autophagosomal membranes is essential for their autophagic activities and is required to ensure the efficient engulfment of cargo destined for lysosomal degradation. In this review, we discuss our current understanding of the spatiotemporal hierarchy between ATG proteins, examining the mechanisms underlying their recruitment to membranes. A particular focus is placed on the relevance of phosphatidylinositol 3‐phosphate and the extent to which the core autophagy players are reliant on this lipid for their localisation to autophagic membranes. In addition, open questions and potential future research directions regarding the membrane recruitment and displacement of ATG proteins are discussed here. [ABSTRACT FROM AUTHOR]

Published

2020

45. The multifaceted functions of ATG16L1 in autophagy and related processes.

Author

Gammoh, Noor

Subjects

*AUTOPHAGY, *LYSOSOMES, *PROTEIN-protein interactions

Abstract

Autophagy requires the formation of membrane vesicles, known as autophagosomes, that engulf cellular cargoes and subsequently recruit lysosomal hydrolases for the degradation of their contents. A number of autophagy-related proteins act to mediate the de novo biogenesis of autophagosomes and vesicular trafficking events that are required for autophagy. Of these proteins, ATG16L1 is a key player that has important functions at various stages of autophagy. Numerous recent studies have begun to unravel novel activities of ATG16L1, including interactions with proteins and lipids, and how these mediate its role during autophagy and autophagy-related processes. Various domains have been identified within ATG16L1 that mediate its functions in recognising single and double membranes and activating subsequent autophagy-related enzymatic activities required for the recruitment of lysosomes. These recent findings, as well as the historical discovery of ATG16L1, pathological relevance, unresolved questions and contradictory observations, will be discussed here. [ABSTRACT FROM AUTHOR]

Published

2020

46. Autophagosomes are formed at a distinct cellular structure.

Author

Hollenstein, David M. and Kraft, Claudine

Subjects

*CELL anatomy, *AUTOPHAGY, *GENERATING functions, *BULK solids, *PHASE separation, *ENDOPLASMIC reticulum

Abstract

Autophagy is characterized by the formation of double-membrane vesicles called autophagosomes, which deliver bulk cytoplasmic material to the lytic compartment of the cell for degradation. Autophagosome formation is initiated by assembly and recruitment of the core autophagy machinery to distinct cellular sites, referred to as phagophore assembly sites (PAS) in yeast or autophagosome formation sites in other organisms. A large number of autophagy proteins involved in the formation of autophagosomes has been identified; however, how the individual components of the PAS are assembled and how they function to generate autophagosomes remains a fundamental question. Here, we highlight recent studies that provide molecular insights into PAS organization and the role of the endoplasmic reticulum and the vacuole in autophagosome formation. [ABSTRACT FROM AUTHOR]

Published

2020

47. Birth, Growth, Maturation, and Demise of Plant Autophagic Vesicles.

Author

Kim, Jeong Hun, Jung, Hyera, and Chung, Taijoon

Abstract

Autophagy is a degradation pathway for cytoplasmic constituents, targeting various types of cargo to the vacuoles for recycling. Biogenesis and turnover of autophagic vesicles require a set of Autophagy-related (Atg) proteins, which are present in yeast, metazoans, and plants. Recent advances in autophagy research using yeast and mammalian cells have yielded better models describing how autophagic vesicles acquire membrane lipids and which molecules are involved in final steps in autophagy. These findings will further the understanding of how plant Atg homologs cooperate with other proteins to mediate autophagosome biogenesis and turnover. This mini-review provides an updated view of the molecular mechanisms underlying autophagosome dynamics in plant cells. Evidence supporting roles of actin filaments and microtubules in plant autophagosome biogenesis is also provided. [ABSTRACT FROM AUTHOR]

Published

2020

48. ESCRT-mediated phagophore sealing during mitophagy.

Author

Zhen, Yan, Spangenberg, Hélène, Munson, Michael J., Brech, Andreas, Schink, Kay O., Tan, Kia-Wee, Sørensen, Vigdis, Wenzel, Eva Maria, Radulovic, Maja, Engedal, Nikolai, Simonsen, Anne, Raiborg, Camilla, and Stenmark, Harald

Abstract

Inactivation of the endosomal sorting complex required for transport (ESCRT) machinery has been reported to cause autophagic defects, but the exact functions of ESCRT proteins in macroautophagy/autophagy remain incompletely understood. Using live-cell fluorescence microscopy we found that the filament-forming ESCRT-III subunit CHMP4B was recruited transiently to nascent autophagosomes during starvation-induced autophagy and mitophagy, with residence times of about 1 and 2 min, respectively. Correlative light microscopy and electron tomography revealed CHMP4B recruitment at a late step in mitophagosome formation. The autophagosomal dwell time of CHMP4B was strongly increased by depletion of the regulatory ESCRT-III subunit CHMP2A. Using a novel optogenetic closure assay we observed that depletion of CHMP2A inhibited phagophore sealing during mitophagy. Consistent with this, depletion of CHMP2A and other ESCRT-III subunits inhibited both PRKN/PARKIN-dependent and -independent mitophagy. We conclude that the ESCRT machinery mediates phagophore closure, and that this is essential for mitophagic flux. Abbreviations: BSA: bovine serum albumin; CHMP: chromatin-modifying protein; CLEM: correlative light and electron microscopy; EGFP: enhanced green fluorescent protein; ESCRT: endosomal sorting complex required for transport; HEPES: 2-[4-(2-hydroxyethyl)piperazin-1-yl]ethanesulfonic acid; HRP: horseradish peroxidase; ILV: intralumenal vesicle; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; LOV2: light oxygen voltage 2; MLS: mitochondrial localization sequence; MT-CO2: mitochondrially encoded cytochrome c oxidase II; O+A: oligomycin and antimycin A; PBS: phosphate-buffered saline; PIPES: piperazine-N,N-bis(2-ethanesulfonic acid); PRKN/PARKIN: parkin RBR E3 ubiquitin protein ligase; RAB: RAS-related in brain; SD: standard deviation; SEM: standard error of the mean; TOMM20: TOMM20: translocase of outer mitochondrial membrane 20; VCL: vinculin; VPS4: vacuolar protein sorting protein 4; Zdk1: Zdark 1; TUBG: Tubulin gamma chain [ABSTRACT FROM AUTHOR]

Published

2020

49. EI24 tethers endoplasmic reticulum and mitochondria to regulate autophagy flux.

Author

Yuan, Lin, Liu, Qi, Wang, Zhe, Hou, Junjie, and Xu, Pingyong

Subjects

*LIVER cells, *INTRACELLULAR calcium, *FLUX (Energy), *ENDOPLASMIC reticulum, *MITOCHONDRIAL membranes, *BLOOD sugar

Abstract

Etoposide-induced protein 2.4 (EI24), located on the endoplasmic reticulum (ER) membrane, has been proposed to be an essential autophagy protein. Specific ablation of EI24 in neuronal and liver tissues causes deficiency of autophagy flux. However, the molecular mechanism of the EI24-mediated autophagy process is still poorly understood. Like neurons and hepatic cells, pancreatic β cells are also secretory cells. Pancreatic β cells contain large amounts of ER and continuously synthesize and secrete insulin to maintain blood glucose homeostasis. Yet, the effect of EI24 on autophagy of pancreatic β cells has not been reported. Here, we show that the autophagy process is inhibited in EI24-deficient primary pancreatic β cells. Further mechanistic studies demonstrate that EI24 is enriched at the ER–mitochondria interface and that the C-terminal domain of EI24 is important for the integrity of the mitochondria-associated membrane (MAM) and autophagy flux. Overexpression of EI24, but not the EI24-ΔC mutant, can rescue MAM integrity and decrease the aggregation of p62 and LC3II in the EI24-deficient group. By mass spectrometry-based proteomics following immunoprecipitation, EI24 was found to interact with voltage-dependent anion channel 1 (VDAC1), inositol 1,4,5-trisphosphate receptor (IP3R), and the outer mitochondrial membrane chaperone GRP75. Knockout of EI24 impairs the interaction of IP3R with VDAC1, indicating that these proteins may form a quaternary complex to regulate MAM integrity and the autophagy process. [ABSTRACT FROM AUTHOR]

Published

2020

50. Ultrastructural insights into pathogen clearance by autophagy.

Author

Kishi‐Itakura, Chieko, Ktistakis, Nicholas T., and Buss, Folma

Subjects

*UBIQUITINATION, *AUTOPHAGY, *TRANSMISSION electron microscopy, *MITOCHONDRIAL membranes, *ENDOPLASMIC reticulum, *PATHOGENIC microorganisms

Abstract

Autophagy defends cells against proliferation of bacteria such as Salmonella in the cytosol. After escape from a damaged Salmonella‐containing vacuole (SCV) exposing luminal glycans that bind to Galectin‐8, the host cell ubiquitination machinery deposits a dense layer of ubiquitin around the cytosolic bacteria. The nature and spatial distribution of this ubiquitin coat in relation to other autophagy‐related membranes are unknown. Using transmission electron microscopy, we determined the exact localisation of ubiquitin, the ruptured SCV membrane and phagophores around cytosolic Salmonella. Ubiquitin was not predominantly present on the Salmonella surface, but enriched on the fragmented SCV. Cytosolic bacteria without SCVs were less efficiently targeted by phagophores. Single bacteria were contained in single phagophores but multiple bacteria could be within large autophagic vacuoles reaching 30 μm in circumference. These large phagophores followed the contour of the engulfed bacteria, they were frequently in close association with endoplasmic reticulum membranes and, within them, remnants of the SCV were seen associated with each engulfed particle. Our data suggest that the Salmonella SCV has a major role in the formation of autophagic phagophores and highlight evolutionary conserved parallel mechanisms between xenophagy and mitophagy with the fragmented SCV and the damaged outer mitochondrial membrane serving similar functions. [ABSTRACT FROM AUTHOR]

Published

2020