Autophagy is an important homeostatic cellular recycling mechanism responsible for degrading injured or dysfunctional cellular organelles and proteins in all living cells. Aging is a universal phenomenon characterized by progressive deterioration of cells and organs due to accumulation of macromolecular and organelle damage. Growing evidences indicate that the rate of autophagosome formation and maturation and the efficiency of autophagosome/lysosome fusion decline with age. Dysfunctional autophagy has also been observed in age-related diseases. Autophagy disruption resulted accumulation of mutated or misfolded proteins is the essential feature of neurodegenerative disorders. However, in cancers, fibroproliferative diseases or cardiovascular diseases, autophagy can play either a protective or destructive role in different types of disease, and even in different stages of the same disease. The review will discuss the cellular and molecular mechanisms of autophagy and its important role in the pathogenesis of aging and age-related diseases, and the ongoing drug discovery strategies for therapeutic intervention.
Aging ; Autophagy ; Drug Discovery ; Humans ; Lysosomes ; metabolism ; Neurodegenerative Diseases ; Phagosomes ; metabolism ; Protein Folding

Diurnal changes of lysosomes including ultrastructural changes of phagosomes and acid phosphatase reactions in phagosomes, as well as diurnal biochemical changes in cathepsin D activity, were studied in the retinal pigment epithelium (RPE) of the rabbit. The rabbit was maintained on a natural light-dark cycle over seven days in fall and was sacrificed at various times during the day and night. The number of lysosomes or phagosomes in the RPE was the highest at 1.5 hours after exposure to sunlight (8:00 AM), and thereafter decreased with time. Three types of phagosomes were observed and acid phosphatase reactions were different in each type of phagosome; the fresh phagosomes were negative or positive, lamellar bodies positive, and dense bodies partially positive. The biochemical activity of cathepsin D was the highest at 8:00 AM, and this was consistent with the time of peak in phagocytic activity in the RPE. This report shows that phagocytic activity in the RPE occurred in the early stage after exposure to sunlight, and that fresh phagosomes were sequentially degraded to lamellar or dense bodies. Cathepsin D activity also increased, and this was consistent with the phagocytic activity in the RPE.
Acid Phosphatase/metabolism ; Animals ; Cathepsin D/metabolism ; Cell Count ; Choroid/metabolism/ultrastructure ; Circadian Rhythm/*physiology ; Lysosomes/*metabolism/ultrastructure ; Phagosomes/*metabolism/ultrastructure ; Pigment Epithelium of Eye/*metabolism/ultrastructure ; Rabbits

OBJECTIVETo study the role of autophagy in the death of dopaminergic neurons induced by 6-hydroxydopamine (6-OHDA).

METHODSRat models of Parkinson disease (PD) were established by stereotaxic administration of 6-OHDA (8 μg) into the unilateral substantia nigra par compact (SNpc). Autophagosomes in the SNpc were observed with transmission electron microscopy (TEM), and the expression of autophagy-related protein LC3 was determined with immunofluorescence (IF) assay.

RESULTSUnder TEM, the autophagosomes were found in the ipsilateral SNpc 6-24 h after 6-OHDA injection, which suggested the activation of autophagy. IF assay showed significantly increased LC3 expression in 6-OHDA-damaged TH-positive neurons as compared to the control group.

CONCLUSIONSThe increase of autophagosomes and activation of autophagy may play a role in dopaminergic neuron death induced by 6-OHDA.

Animals ; Autophagy ; drug effects ; Cell Death ; drug effects ; Disease Models, Animal ; Dopaminergic Neurons ; cytology ; drug effects ; Male ; Microtubule-Associated Proteins ; metabolism ; Oxidopamine ; pharmacology ; Parkinson Disease, Secondary ; chemically induced ; metabolism ; Phagosomes ; metabolism ; Rats ; Rats, Sprague-Dawley ; Substantia Nigra ; drug effects

Phospholipase D (PLD) catalyzes the hydrolysis of phosphatidylcholine to generate the lipid second messenger, phosphatidic acid. PLD is localized in most cellular organelles, where it is likely to play different roles in signal transduction. PLD1 is primarily localized in vesicular structures such as endosomes, lysosomes and autophagosomes. However, the factors defining its localization are less clear. In this study, we found that four hydrophobic residues present in the N-terminal HKD catalytic motif of PLD1, which is involved in intramolecular association, are responsible for vesicular localization. Site-directed mutagenesis of the residues dramatically disrupted vesicular localization of PLD1. Interestingly, the hydrophobic residues of PLD1 are also involved in the interruption of its nuclear localization. Mutation of the residues increased the association of PLD1 with importin-beta, which is known to mediate nuclear importation, and induced the localization of PLD1 from vesicles into the nucleus. Taken together, these data suggest that the hydrophobic amino acids involved in the interdomain association of PLD1 are required for vesicular localization and disturbance of its nuclear localization.
Amino Acid Motifs ; Amino Acid Sequence ; Amino Acids/chemistry ; Cell Nucleus/*enzymology ; Endosomes/enzymology ; HEK293 Cells ; Humans ; Hydrophobic and Hydrophilic Interactions ; Lysosomes/enzymology ; Phagosomes/enzymology ; Phospholipase D/chemistry/*metabolism ; Protein Interaction Domains and Motifs ; Protein Transport ; Transport Vesicles/*enzymology

Autophagy is an evolutionarily conserved cellular process which degrades intracellular contents. The Atg17-Atg31-Atg29 complex plays a key role in autophagy induction by various stimuli. In yeast, autophagy occurs with autophagosome formation at a special site near the vacuole named the pre-autophagosomal structure (PAS). The Atg17-Atg31-Atg29 complex forms a scaffold for PAS organization, and recruits other autophagy-related (Atg) proteins to the PAS. Here, we show that Atg31 is a phosphorylated protein. The phosphorylation sites on Atg31 were identified by mass spectrometry. Analysis of mutants in which the phosphorylated amino acids were replaced by alanine, either individually or in various combinations, identified S174 as the functional phosphorylation site. An S174A mutant showed a similar degree of autophagy impairment as an Atg31 deletion mutant. S174 phosphorylation is required for autophagy induced by various autophagy stimuli such as nitrogen starvation and rapamycin treatment. Mass spectrometry analysis showed that S174 is phosphorylated constitutively, and expression of a phosphorylation-mimic mutant (S174D) in the Atg31 deletion strain restores autophagy. In the S174A mutant, Atg9-positive vesicles accumulate at the PAS. Thus, S174 phosphorylation is required for formation of autophagosomes, possibly by facilitating the recycling of Atg9 from the PAS. Our data demonstrate the role of phosphorylation of Atg31 in autophagy.
Alanine ; chemistry ; metabolism ; Amino Acid Motifs ; Aspartic Acid ; chemistry ; metabolism ; Autophagy ; genetics ; Autophagy-Related Proteins ; Carrier Proteins ; chemistry ; metabolism ; Gene Expression Regulation, Fungal ; Membrane Proteins ; chemistry ; metabolism ; Models, Molecular ; Molecular Sequence Data ; Nitrogen ; deficiency ; Phagosomes ; chemistry ; drug effects ; metabolism ; Phosphorylation ; Protein Transport ; Saccharomyces cerevisiae ; drug effects ; genetics ; metabolism ; Saccharomyces cerevisiae Proteins ; chemistry ; genetics ; metabolism ; Serine ; chemistry ; metabolism ; Signal Transduction ; Sirolimus ; pharmacology

The accumulation of abnormal protein aggregates is a major characteristic of many neurodegenerative disorders, including Parkinson's disease (PD). The intracytoplasmic deposition of alpha-synuclein aggregates and Lewy bodies, often found in PD and other alpha-synucleinopathies, is thought to be linked to inefficient cellular clearance mechanisms, such as the proteasome and autophagy/lysosome pathways. The accumulation of alpha-synuclein aggregates in neuronal cytoplasm causes numerous autonomous changes in neurons. However, it can also affect the neighboring cells through transcellular transmission of the aggregates. Indeed, a progressive spreading of Lewy pathology among brain regions has been hypothesized from autopsy studies. We tested whether inhibition of the autophagy/lysosome pathway in alpha-synuclein-expressing cells would increase the secretion of alpha-synuclein, subsequently affecting the alpha-synuclein deposition in and viability of neighboring cells. Our results demonstrated that autophagic inhibition, via both pharmacological and genetic methods, led to increased exocytosis of alpha-synuclein. In a mixed culture of alpha-synuclein-expressing donor cells with recipient cells, autophagic inhibition resulted in elevated transcellular alpha-synuclein transmission. This increase in protein transmission coincided with elevated apoptotic cell death in the recipient cells. These results suggest that the inefficient clearance of alpha-synuclein aggregates, which can be caused by reduced autophagic activity, leads to elevated alpha-synuclein exocytosis, thereby promoting alpha-synuclein deposition and cell death in neighboring neurons. This finding provides a potential link between autophagic dysfunction and the progressive spread of Lewy pathology.
Adenine/analogs & derivatives/pharmacology ; Animals ; *Autophagy/drug effects ; Cell Line ; *Exocytosis/drug effects ; Extracellular Space/*metabolism ; Humans ; Mice ; Mice, Knockout ; Microtubule-Associated Proteins/deficiency/metabolism ; Phagosomes/drug effects/metabolism ; Protein Structure, Quaternary ; Protein Transport/drug effects ; alpha-Synuclein/chemistry/*metabolism/secretion/toxicity

Autophagy-related protein 8 (Atg8) is an essential component of autophagy formation and encystment of cyst-forming parasites, and some protozoa, such as, Acanthamoeba, Entamoeba, and Dictyostelium, have been reported to possess a type of Atg8. In this study, an isoform of Atg8 was identified and characterized in Acanthamoeba castellanii (AcAtg8b). AcAtg8b protein was found to encode 132 amino acids and to be longer than AcAtg8 protein, which encoded 117 amino acids. Real-time PCR analysis showed high expression levels of AcAtg8b and AcAtg8 during encystation. Fluorescence microscopy demonstrated that AcAtg8b is involved in the formation of the autophagosomal membrane. Chemically synthesized siRNA against AcAtg8b reduced the encystation efficiency of Acanthamoeba, confirming that AcAtg8b, like AcAtg8, is an essential component of cyst formation in Acanthamoeba. Our findings suggest that Acanthamoeba has doubled the number of Atg8 gene copies to ensure the successful encystation for survival when 1 copy is lost. These 2 types of Atg8 identified in Acanthamoeba provide important information regarding autophagy formation, encystation mechanism, and survival of primitive, cyst-forming protozoan parasites.
Acanthamoeba castellanii/cytology/*genetics/physiology ; Amebiasis/*parasitology ; Amino Acid Sequence ; Autophagy ; Cell Membrane/metabolism ; DNA, Protozoan/chemistry/genetics ; Gene Dosage ; Gene Silencing ; Genes, Reporter ; Humans ; Molecular Sequence Data ; Phagosomes/metabolism ; Protein Isoforms ; Protozoan Proteins/*genetics/metabolism ; RNA, Messenger/genetics ; RNA, Protozoan/genetics ; RNA, Small Interfering/chemical synthesis/genetics ; Recombinant Fusion Proteins ; Sequence Alignment

This study explored the role of radiation-induced autophagy in low-dose hyperradiosensitivity (HRS) in the human lung cancer cell line A549. A549 cells, either treated with an autophagic inhibitor 3-methyladenine (3-MA), or with a vehicle control, were irradiated at different low doses (≤0.5 Gy). The generation of autophagy was examined by laser scanning confocal microscopy. Western blotting was used to detect the expression of microtubule-associated protein l light chain 3B II (LC3B-II). Flow cytometry (FCM) and clonogenic assays were used to measure the fraction of surviving cells at the low irradiation doses. Our results showed that there was a greater inhibition of autophagic activity, but a higher degree of low-dose HRS in A549 cells treated with 3-MA than in control group. Our data demonstrated that radiation-induced autophagy is correlated with HRS in A549 cells, and is probably one of the mechanisms underlying HRS.
Adenine ; analogs & derivatives ; pharmacology ; Autophagy ; drug effects ; radiation effects ; Blotting, Western ; Cell Line, Tumor ; Cell Survival ; drug effects ; radiation effects ; Dose-Response Relationship, Radiation ; Flow Cytometry ; Green Fluorescent Proteins ; genetics ; metabolism ; Humans ; Lung Neoplasms ; genetics ; metabolism ; pathology ; Microscopy, Confocal ; Microscopy, Electron, Transmission ; Microtubule-Associated Proteins ; genetics ; metabolism ; Phagosomes ; drug effects ; radiation effects ; ultrastructure ; Radiation Tolerance ; drug effects ; radiation effects

Autophagy plays important roles in modulating viral replication and antiviral immune response. Coronavirus infection is associated with the autophagic process, however, little is known about the mechanisms of autophagy induction and its contribution to coronavirus regulation of host innate responses. Here, we show that the membrane-associated papain-like protease PLP2 (PLP2-TM) of coronaviruses acts as a novel autophagy-inducing protein. Intriguingly, PLP2-TM induces incomplete autophagy process by increasing the accumulation of autophagosomes but blocking the fusion of autophagosomes with lysosomes. Furthermore, PLP2-TM interacts with the key autophagy regulators, LC3 and Beclin1, and promotes Beclin1 interaction with STING, the key regulator for antiviral IFN signaling. Finally, knockdown of Beclin1 partially reverses PLP2-TM's inhibitory effect on innate immunity which resulting in decreased coronavirus replication. These results suggested that coronavirus papain-like protease induces incomplete autophagy by interacting with Beclin1, which in turn modulates coronavirus replication and antiviral innate immunity.
Apoptosis Regulatory Proteins ; antagonists & inhibitors ; genetics ; immunology ; Autophagy ; Beclin-1 ; Coronavirus NL63, Human ; genetics ; immunology ; Gene Expression Regulation ; HEK293 Cells ; HeLa Cells ; Host-Pathogen Interactions ; immunology ; Humans ; Immune Evasion ; Immunity, Innate ; Interferon-gamma ; genetics ; immunology ; Lysosomes ; metabolism ; virology ; MCF-7 Cells ; Membrane Fusion ; Membrane Proteins ; antagonists & inhibitors ; genetics ; immunology ; Microtubule-Associated Proteins ; genetics ; immunology ; Papain ; genetics ; immunology ; Phagosomes ; metabolism ; virology ; RNA, Small Interfering ; genetics ; immunology ; Signal Transduction ; Virus Replication