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Bulletin Du Cancer Mar 2021Autophagy refers to the formation of autophagosomes by membrane wrapping part of the cytoplasm and the organelles and proteins that need to be degraded in the cells.... (Review)
Review
Autophagy refers to the formation of autophagosomes by membrane wrapping part of the cytoplasm and the organelles and proteins that need to be degraded in the cells. Autophagosomes are fused with lysosomes to form autophagolysosome, which degrade the contents of the inclusions, to achieve cell homeostasis and organelle renewal. The regulatory mechanism of autophagy is complex, and its upstream signaling pathway mainly involves mTOR dependent pathway and mTOR independent pathway (AMPK, PI3K, Ras-MAPK, p53, PTEN, endoplasmic reticulum stress). Autophagy is a phenomenon of "self-eating" in cells. Apoptosis is a phenomenon of "self-killing". Both of them share the same stimulating factors and regulatory proteins, but the threshold of induction is different. How to transform and coordinate is not clear at present. This paper summarizes the history of autophagy discovery, the structure and function of related molecules, the biological function of autophagy, the regulatory mechanism and the research results of the relationship between autophagy and apoptosis.
Topics: Apoptosis; Autophagosomes; Autophagy; Biomedical Research; Humans
PubMed: 33423775
DOI: 10.1016/j.bulcan.2020.11.004 -
Journal of Molecular Biology Apr 2020Macroautophagy is a conserved catabolic process observed in all eukaryotic cells, during which selected cellular components are transported to and broken down within... (Review)
Review
Macroautophagy is a conserved catabolic process observed in all eukaryotic cells, during which selected cellular components are transported to and broken down within lysosomes. The process starts with the capture of unnecessary material into autophagosomes, which is followed by autophagosome-lysosome fusion to generate autolysosomes that degrade the cargo. In the past quarter-century, our knowledge about autophagosome formation almost exponentially increased, while the later steps were much less studied. This fortunately changed in the past few years, with more and more publications focusing on the fate of the completed autophagosome. In this review, we aspire to summarize the current knowledge about the molecular mechanisms of autophagosome-lysosome fusion.
Topics: Animals; Autophagosomes; Autophagy; Humans; Lysosomes; Neurodegenerative Diseases; SNARE Proteins
PubMed: 31682838
DOI: 10.1016/j.jmb.2019.10.028 -
Nature Reviews. Molecular Cell Biology Aug 2020Autophagosomes are double-membrane vesicles newly formed during autophagy to engulf a wide range of intracellular material and transport this autophagic cargo to... (Review)
Review
Autophagosomes are double-membrane vesicles newly formed during autophagy to engulf a wide range of intracellular material and transport this autophagic cargo to lysosomes (or vacuoles in yeasts and plants) for subsequent degradation. Autophagosome biogenesis responds to a plethora of signals and involves unique and dynamic membrane processes. Autophagy is an important cellular mechanism allowing the cell to meet various demands, and its disruption compromises homeostasis and leads to various diseases, including metabolic disorders, neurodegeneration and cancer. Thus, not surprisingly, the elucidation of the molecular mechanisms governing autophagosome biogenesis has attracted considerable interest. Key molecules and organelles involved in autophagosome biogenesis, including autophagy-related (ATG) proteins and the endoplasmic reticulum, have been discovered, and their roles and relationships have been investigated intensely. However, several fundamental questions, such as what supplies membranes/lipids to build the autophagosome and how the membrane nucleates, expands, bends into a spherical shape and finally closes, have proven difficult to address. Nonetheless, owing to recent studies with new approaches and technologies, we have begun to unveil the mechanisms underlying these processes on a molecular level. We now know that autophagosome biogenesis is a highly complex process, in which multiple proteins and lipids from various membrane sources, supported by the formation of membrane contact sites, cooperate with biophysical phenomena, including membrane shaping and liquid-liquid phase separation, to ensure seamless segregation of the autophagic cargo. Together, these studies pave the way to obtaining a holistic view of autophagosome biogenesis.
Topics: Animals; Autophagosomes; Autophagy; Autophagy-Related Proteins; Cell Membrane; Endoplasmic Reticulum; Humans; Lysosomes; Macroautophagy; Protein Transport
PubMed: 32372019
DOI: 10.1038/s41580-020-0241-0 -
Protein & Cell Sep 2023Lipophagy, the selective engulfment of lipid droplets (LDs) by autophagosomes for lysosomal degradation, is critical to lipid and energy homeostasis. Here we show that...
Lipophagy, the selective engulfment of lipid droplets (LDs) by autophagosomes for lysosomal degradation, is critical to lipid and energy homeostasis. Here we show that the lipid transfer protein ORP8 is located on LDs and mediates the encapsulation of LDs by autophagosomal membranes. This function of ORP8 is independent of its lipid transporter activity and is achieved through direct interaction with phagophore-anchored LC3/GABARAPs. Upon lipophagy induction, ORP8 has increased localization on LDs and is phosphorylated by AMPK, thereby enhancing its affinity for LC3/GABARAPs. Deletion of ORP8 or interruption of ORP8-LC3/GABARAP interaction results in accumulation of LDs and increased intracellular triglyceride. Overexpression of ORP8 alleviates LD and triglyceride deposition in the liver of ob/ob mice, and Osbpl8-/- mice exhibit liver lipid clearance defects. Our results suggest that ORP8 is a lipophagy receptor that plays a key role in cellular lipid metabolism.
Topics: Animals; Mice; Lipid Droplets; Autophagy; Autophagosomes; Homeostasis; Triglycerides
PubMed: 37707322
DOI: 10.1093/procel/pwac063 -
Autophagy Jan 2020Many diseases are caused by aberrant accumulation of certain proteins that are misfolded and cytotoxic, and lowering the level of these proteins provides promising... (Review)
Review
Many diseases are caused by aberrant accumulation of certain proteins that are misfolded and cytotoxic, and lowering the level of these proteins provides promising treatment strategies for these diseases. We hypothesized that compounds that interact with both the disease-causing protein and the phagophore (autophagosome precursor) protein LC3 may tether the former to phagophores for subsequent autophagic degradation. If true, this uophagosome-thering ompound (ATTEC) concept could be applied to many disease-causing proteins to treat diseases. We tested this hypothesis in the scenario of Huntington disease (HD), a neurodegenerative disorder that is caused by the mutant HTT (mHTT) protein with an expanded polyglutamine (polyQ) stretch. In our recent study, we designed a small-molecule microarray-based screening and identified four mHTT-lowering compounds that interact with both mHTT and LC3, but not wild-type (WT) HTT. These compounds target mHTT to phagophores for autophagic degradation without influencing the WT HTT level, and rescue HD-relevant phenotypes in HD cells and in the fly and mouse HD models. Interestingly, these compounds interact with the expanded polyQ stretch directly and are able to reduce other disease-causing proteins with expanded polyQ. In summary, our study provides the initial validation of lowering mHTT by ATTEC, providing entry points to new treatment strategies of HD and similar diseases.
Topics: Animals; Autophagosomes; Autophagy; Disease Models, Animal; Humans; Huntingtin Protein; Huntington Disease; Nerve Tissue Proteins
PubMed: 31690177
DOI: 10.1080/15548627.2019.1688556 -
Advances in Experimental Medicine and... 2021Phagophore closure is a critical step during macroautophagy. However, the proteins and mechanisms to regulate this step have been elusive for a long time. In 2017, Rab5...
Phagophore closure is a critical step during macroautophagy. However, the proteins and mechanisms to regulate this step have been elusive for a long time. In 2017, Rab5 was affirmed to play a role in phagophore closure in yeast. Furthermore, in mammalian cells, ESCRT III was reported to have roles in phagophore closure and mitophagosome closure in vivo in 2018 and 2019, respectively. The role of ESCRT in phagophore closure was confirmed in yeast, both in vivo and in vitro, in 2019. Most importantly, the latter paper found that Atg17 recruited the ESCRT III subunit Snf7 to the phagophore to close it under the control of Rab5. To determine the closure characteristics of autophagosome-like membrane structures in ESCRT mutants, a traditional protease protection assay with immunoblotting was used, accompanied by new techniques that were developed, including immunofluorescence assays, autophagosome completion assays, and the optogenetic closure assay. This study delivered our current understanding of phagophore closure and provided more reference methods to detect membrane closure.
Topics: Animals; Autophagosomes; Autophagy; Endosomal Sorting Complexes Required for Transport; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins
PubMed: 34260020
DOI: 10.1007/978-981-16-2830-6_3 -
The Journal of Cell Biology Jul 2022The stimulator of interferon genes (STING) plays a critical role in innate immunity. Emerging evidence suggests that STING is important for DNA or cGAMP-induced...
The stimulator of interferon genes (STING) plays a critical role in innate immunity. Emerging evidence suggests that STING is important for DNA or cGAMP-induced non-canonical autophagy, which is independent of a large part of canonical autophagy machineries. Here, we report that, in the absence of STING, energy stress-induced autophagy is upregulated rather than downregulated. Depletion of STING in Drosophila fat cells enhances basal- and starvation-induced autophagic flux. During acute exercise, STING knockout mice show increased autophagy flux, exercise endurance, and altered glucose metabolism. Mechanistically, these observations could be explained by the STING-STX17 interaction. STING physically interacts with STX17, a SNARE that is essential for autophagosome biogenesis and autophagosome-lysosome fusion. Energy crisis and TBK1-mediated phosphorylation both disrupt the STING-STX17 interaction, allow different pools of STX17 to translocate to phagophores and mature autophagosomes, and promote autophagic flux. Taken together, we demonstrate a heretofore unexpected function of STING in energy stress-induced autophagy through spatial regulation of autophagic SNARE STX17.
Topics: Animals; Autophagosomes; Autophagy; Drosophila; Energy Metabolism; Lysosomes; Membrane Proteins; Mice; Mice, Knockout; Physical Conditioning, Animal; Qa-SNARE Proteins
PubMed: 35510944
DOI: 10.1083/jcb.202202060 -
Nature Cell Biology Apr 2022Autolysosomes contain components from autophagosomes and lysosomes. The contents inside the autolysosomal lumen are degraded during autophagy, while the fate of...
Autolysosomes contain components from autophagosomes and lysosomes. The contents inside the autolysosomal lumen are degraded during autophagy, while the fate of autophagosomal components on the autolysosomal membrane remains unknown. Here we report that the autophagosomal membrane components are not degraded, but recycled from autolysosomes through a process coined in this study as autophagosomal components recycling (ACR). We further identified a multiprotein complex composed of SNX4, SNX5 and SNX17 essential for ACR, which we termed 'recycler'. In this, SNX4 and SNX5 form a heterodimer that recognizes autophagosomal membrane proteins and is required for generating membrane curvature on autolysosomes, both via their BAR domains, to mediate the cargo sorting process. SNX17 interacts with both the dynein-dynactin complex and the SNX4-SNX5 dimer to facilitate the retrieval of autophagosomal membrane components. Our discovery of ACR and identification of the recycler reveal an important retrieval and recycling pathway on autolysosomes.
Topics: Autophagosomes; Autophagy; Dyneins; Lysosomes; Protein Transport
PubMed: 35332264
DOI: 10.1038/s41556-022-00861-8 -
Journal of Molecular Biology Jan 2020Selective autophagy relies on soluble or membrane-bound cargo receptors that recognize cargo and bring about autophagosome formation at the cargo. The cargo-bound... (Review)
Review
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.
Topics: Animals; Apoptosis Regulatory Proteins; Autophagosomes; Autophagy; Autophagy-Related Protein 8 Family; Humans; Macroautophagy; Microtubule-Associated Proteins; Protein Interaction Domains and Motifs; Protein Interaction Maps
PubMed: 31310766
DOI: 10.1016/j.jmb.2019.07.016 -
Developmental Cell Oct 2020In eukaryotic cells, various membrane-bound organelles compartmentalize diverse cellular activities in a spatially and temporally controlled manner. Numerous... (Review)
Review
In eukaryotic cells, various membrane-bound organelles compartmentalize diverse cellular activities in a spatially and temporally controlled manner. Numerous membraneless organelles assembled via liquid-liquid phase separation (LLPS), known as condensates, also facilitate compartmentalization of cellular functions. Emerging evidence shows that these two organelle types interact in many biological processes. Membranes modulate the biogenesis and dynamics of phase-separated condensates by serving as assembly platforms or by forming direct contacts. Phase separation of membrane-associated proteins participates in various trafficking events, such as clustering of vesicles for temporally controlled fusion and storage, and transport of membraneless condensates on membrane-bound organelles. Phase separation also acts in cargo trafficking pathways by sorting and docking cargos for translocon-mediated transport across membranes, by shuttling cargos through the nuclear pore complex, and by triggering the formation of surrounding autophagosomes for delivery to lysosomes. The coordinated actions of membrane-bound and membraneless organelles ensure spatiotemporal control of various cellular functions.
Topics: Autophagosomes; Biology; Biophysical Phenomena; Cell Physiological Phenomena; Humans; Membranes; Organelles
PubMed: 32726575
DOI: 10.1016/j.devcel.2020.06.033