The pleiotropic role of autophagy: from protein metabolism to bactericide

Autophagy is in principle a nonselective, bulk degradation system within cells, with a contribution to intracellular protein degradation estimated to be as large as that of the ubiquitin--proteasome system. The primary roles of autophagy are baseline turnover of intracellular proteins and organelles, production of amino acids in nutrient emergency, and regression of retired tissues. These functions guarantee rejuvenation and adaptation to adverse conditions, and even underlie dynamic processes such as development/metamorphosis. In addition, several other roles for autophagy have recently been discovered, such as presentation of endogenous antigens and degradation of invasive bacteria. This review will discuss the biological significance of autophagy from yeast to higher eukaryotes.     

Eating on the fly: function and regulation of autophagy during cell growth, survival and death in Drosophila

Significant progress has been made over recent years in defining the normal progression and regulation of autophagy, particularly in cultured mammalian cells and yeast model systems. However, apart from a few notable exceptions, our understanding of the physiological roles of autophagy has lagged behind these advances, and identification of components and features of autophagy unique to higher eukaryotes also remains a challenge. In this review we describe recent insights into the roles and control mechanisms of autophagy gained from in vivo studies in Drosophila. We focus on potential roles of autophagy in controlling cell growth and death, and describe how the regulation of autophagy has evolved to include metazoan-specific signaling pathways. We discuss genetic screening approaches that are being used to identify novel regulators and effectors of autophagy, and speculate about areas of research in this system likely to bear fruit in future studies.     

Eating on the fly: Function and regulation of autophagy during cell growth,survival and death in Drosophila

Significant progress has been made over recent years in defining the normal progression and regulation of autophagy, particularly in cultured mammalian cells and yeast model systems. However, apart from a few notable exceptions, our understanding of the physiological roles of autophagy has lagged behind these advances, and identification of components and features of autophagy unique to higher eukaryotes also remains a challenge. In this review we describe recent insights into the roles and control mechanisms of autophagy gained from in vivo studies in Drosophila. We focus on potential roles of autophagy in controlling cell growth and death, and describe how the regulation of autophagy has evolved to include metazoan-specific signaling pathways. We discuss genetic screening approaches that are being used to identify novel regulators and effectors of autophagy, and speculate about areas of research in this system likely to bear fruit in future studies.     

A perspective on the role of autophagy in cancer

Autophagy refers to a ubiquitous set of catabolic pathways required to achieve proper cellular homeostasis. Aberrant autophagy has been implicated in a multitude of diseases including cancer. In this review, we highlight pioneering and groundbreaking research that centers on delineating the role of autophagy in cancer initiation, proliferation and metastasis. First, we discuss the autophagy-related (ATG) proteins and their respective roles in the de novo formation of autophagosomes and the subsequent delivery of cargo to the lysosome for recycling. Next, we touch upon the history of cancer research that centers upon ATG proteins and regulatory mechanisms that control an appropriate autophagic response and how these are altered in the diseased state. Then, we discuss the various discoveries that led to the idea of autophagy as a double-edged sword when it comes to cancer therapy. This review also briefly narrates how different types of autophagy—selective macroautophagy and chaperone-mediated autophagy, have been linked to different cancers. Overall, these studies build upon a steadfast trajectory that aims to solve the monumentally daunting challenge of finding a cure for many types of cancer by modulating autophagy either through inhibition or induction.     

The BECN1-BCL2 complex regulates insulin secretion and storage in mice

Macroautophagy/autophagy abnormality has been recently associated with metabolic disorders, such as type 2 diabetes (T2D). However, the effect of autophagy activation in systemic energy metabolism was poorly understood. In our recent study, we demonstrated that autophagy plays different roles in distinct metabolic tissues, using an autophagy-hyperactive mouse model. In insulin-producing β cells, excess autophagy degrades insulin-containing vesicles (a process termed vesicophagy), resulting in decreased insulin contents and systemic glucose intolerance; whereas in insulin-responsive cells, activating autophagy decreases endoplasmic reticulum (ER) stress and improves insulin sensitivity.     

Autophagy and the ubiquitin-proteasome system: collaborators in neuroprotection

Protein degradation is an essential cellular function that, when dysregulated or impaired, can lead to a wide variety of disease states. The two major intracellular protein degradation systems are the ubiquitin-proteasome system (UPS) and autophagy, a catabolic process that involves delivery of cellular components to the lysosome for degradation. While the UPS has garnered much attention as it relates to neurodegenerative disease, important links between autophagy and neurodegeneration have also become evident. Furthermore, recent studies have revealed interaction between the UPS and autophagy, suggesting a coordinated and complementary relationship between these degradation systems that becomes critical in times of cellular stress. Here we describe autophagy and review evidence implicating this system as an important player in the pathogenesis of neurodegenerative disease. We discuss the role of autophagy in neurodegeneration and review its neuroprotective functions as revealed by experimental manipulation in disease models. Finally, we explore potential parallels and connections between autophagy and the UPS, highlighting their collaborative roles in protecting against neurodegenerative disease.     

Does Autophagy Contribute To Cell Death?

Autophagy (specifically macroautophagy) is an evolutionarily conserved catabolic process where the cytoplasmic contents of a cell are sequestered within double membrane vacuoles, called autophagosomes, and subsequently delivered to the lysosome for degradation. Autophagy can function as a survival mechanism in starving cells. At the same time, extensive autophagy is commonly observed in dying cells, leading to its classification as an alternative form of programmed cell death. The functional contribution of autophagy to cell death has been a subject of great controversy. However, several recent loss-of-function studies of autophagy (Atg) genes have begun to address the roles of autophagy in both cell death and survival. Here, we review the emerging evidence in favor of and against autophagic cell death, discuss the possible roles that autophagic degradation might play in dying cells, and identify salient issues for future investigation.     

Anti- and pro-microbial roles of autophagy in plant-bacteria interactions

Macroautophagy/autophagy and the ubiquitin-proteasome system (UPS) are major proteolytic pathways that are increasingly recognized as battlegrounds during host-microbe interactions in eukaryotes. In plants, the UPS has emerged as central component of innate immunity and is manipulated by bacterial pathogens to enhance virulence. Autophagy has been ascribed a similar importance for anti-bacterial immunity in animals, but the contribution of autophagy to host-bacteria interactions remained elusive in plants. Here, we present and discuss our recent findings that revealed anti- and pro-bacterial roles of autophagy pathways during bacterial infection in the model plant Arabidopsis thaliana. We discovered that selective autophagy mediated by the autophagy cargo receptor AT4G24690/NBR1 limits growth of Pseudomonas syringae pv. tomato DC3000 (Pst) by suppressing the establishment of an aqueous extracellular space (‘water-soaking’). In turn, Pseudomonas employs the effector protein HopM1 to activate autophagy and proteasome degradation (‘proteaphagy’), thereby enhancing its pathogenicity. Thus, our study demonstrates that distinct selective autophagy pathways contribute to host immunity and bacterial pathogenesis during Pst infection and provide evidence for an intimate crosstalk between the proteasome and autophagy system in plant-bacterial interactions.     

Emerging connections between RNA and autophagy

Macroautophagy/autophagy is a key catabolic process, essential for maintaining cellular homeostasis and survival through the removal and recycling of unwanted cellular material. Emerging evidence has revealed intricate connections between the RNA and autophagy research fields. While a majority of studies have focused on protein, lipid and carbohydrate catabolism via autophagy, accumulating data supports the view that several types of RNA and associated ribonucleoprotein complexes are specifically recruited to phagophores (precursors to autophagosomes) and subsequently degraded in the lysosome/vacuole. Moreover, recent studies have revealed a substantial number of novel autophagy regulators with RNA-related functions, indicating roles for RNA and associated proteins not only as cargo, but also as regulators of this process. In this review, we discuss widespread evidence of RNA catabolism via autophagy in yeast, plants and animals, reviewing the molecular mechanisms and biological importance in normal physiology, stress and disease. In addition, we explore emerging evidence of core autophagy regulation mediated by RNA-binding proteins and noncoding RNAs, and point to gaps in our current knowledge of the connection between RNA and autophagy. Finally, we discuss the pathological implications of RNA-protein aggregation, primarily in the context of neurodegenerative disease.     

Does autophagy contribute to cell death?

Autophagy (specifically macroautophagy) is an evolutionarily conserved catabolic process where the cytoplasmic contents of a cell are sequestered within double membrane vacuoles, called autophagosomes, and subsequently delivered to the lysosome for degradation. Autophagy can function as a survival mechanism in starving cells. At the same time, extensive autophagy is commonly observed in dying cells, leading to its classification as an alternative form of programmed cell death. The functional contribution of autophagy to cell death has been a subject of great controversy. However, several recent loss-of-function studies of autophagy (atg) genes have begun to address the roles of autophagy in both cell death and survival. Here, we review the emerging evidence in favor of and against autophagic cell death, discuss the possible roles that autophagic degradation might play in dying cells, and identify salient issues for future investigation.     

Bcl-2 and Bcl-xL play important roles in the crosstalk between autophagy and apoptosis

Autophagy and apoptosis play important roles in the development, cellular homeostasis and, especially, oncogenesis of mammals. They may be triggered by common upstream signals, resulting in combined autophagy and apoptosis. In other instances, they may be mutually exclusive. Recent studies have suggested possible molecular mechanisms for crosstalk between autophagy and apoptosis. Bcl-2 and Bcl-xL, the well-characterized apoptosis guards, appear to be important factors in autophagy, inhibiting Beclin 1-mediated autophagy by binding to Beclin 1. In addition, Beclin 1, Bcl-2 and Bcl-xL can cooperate with Atg5 or Ca(2+) to regulate both autophagy and apoptosis. Thus, Bcl-2 and Bcl-xL represent a molecular link between autophagy and apoptosis. Here, we discuss the possible roles of Bcl-2 and Bcl-xL in apoptosis and autophagy, and the crosstalk between them.     

The cell biology of autophagy in metazoans: a developing story

The cell biological phenomenon of autophagy (or ;self-eating') has attracted increasing attention in recent years. In this review, we first address the cell biological functions of autophagy, and then discuss recent insights into the role of autophagy in animal development, particularly in C. elegans, Drosophila and mouse. Work in these and other model systems has also provided evidence for the involvement of autophagy in disease processes, such as neurodegeneration, tumorigenesis, pathogenic infection and aging. Insights gained from investigating the functions of autophagy in normal development should increase our understanding of its roles in human disease and its potential as a target for therapeutic intervention.     

Eat your heart out: Role of autophagy in myocardial ischemia/reperfusion

Autophagy is an important process in the heart which is responsible for the normal turnover of long lived proteins and organelles. Inhibition of autophagy leads to the accumulation of protein aggregates and dysfunctional organelles which can cause cell death. Autophagy occurs at low basal levels under normal conditions in the heart, but is rapidly upregulated in response to stress such as nutrient deprivation, hypoxia, and pressure overload. Autophagy is a prominent feature of myocardial ischemia and reperfusion. Although enhanced autophagy is often seen in dying cardiac myocytes, the functional significance of autophagy under these conditions is not clear. Upregulation of autophagy has been reported to protect cardiac cells against death as well as be the cause of it. Here, we review the evidence that autophagy can have both beneficial and detrimental roles in the myocardium, and discuss potential mechanisms by which autophagy provides protection in cells.     

Eat your heart out: Role of autophagy in myocardial ischemia/reperfusion

Autophagy is an important process in the heart which is responsible for the normal turnover of long lived proteins and organelles. Inhibition of autophagy leads to the accumulation of protein aggregates and dysfunctional organelles which can cause cell death. Autophagy occurs at low basal levels under normal conditions in the heart, but is rapidly upregulated in response to stress such as nutrient deprivation, hypoxia, and pressure overload. Autophagy is a prominent feature of myocardial ischemia and reperfusion. Although enhanced autophagy is often seen in dying cardiac myocytes, the functional significance of autophagy under these conditions is not clear. Upregulation of autophagy has been reported to protect cardiac cells against death as well as be the cause of it. Here, we review the evidence that autophagy can have both beneficial and detrimental roles in the myocardium, and discuss potential mechanisms by which autophagy provides protection in cells.     

Mitophagy: mechanisms, pathophysiological roles, and analysis

Abstract Mitochondria are essential organelles that regulate cellular energy homeostasis and cell death. The removal of damaged mitochondria through autophagy, a process called mitophagy, is thus critical for maintaining proper cellular functions. Indeed, mitophagy has been recently proposed to play critical roles in terminal differentiation of red blood cells, paternal mitochondrial degradation, neurodegenerative diseases, and ischemia or drug-induced tissue injury. Removal of damaged mitochondria through autophagy requires two steps: induction of general autophagy and priming of damaged mitochondria for selective autophagic recognition. Recent progress in mitophagy studies reveals that mitochondrial priming is mediated either by the Pink1-Parkin signaling pathway or the mitophagic receptors Nix and Bnip3. In this review, we summarize our current knowledge on the mechanisms of mitophagy. We also discuss the pathophysiological roles of mitophagy and current assays used to monitor mitophagy.     

Oridonin: targeting programmed cell death pathways as an anti‐tumour agent

Oridonin, an active diterpenoid isolated from traditional Chinese herbal medicine, has drawn rising attention for its remarkable apoptosis‐ and autophagy‐inducing activity and relevant molecular mechanisms in cancer therapy. Apoptosis is a well known type of cell death, whereas autophagy can play either pro‐survival or pro‐death roles in cancer cells. Accumulating evidence has recently revealed relationships between apoptosis and autophagy induced by oridonin; however, molecular mechanisms behind them remain to be discovered. In this review, we focus on highlighting updated research on oridonin‐induced cell death signalling pathways implicated in apoptosis and autophagy, in many types of cancer. In addition, we further discuss cross‐talk between apoptosis and autophagy induced by oridonin, in cancer. Taken together, these findings open new perspectives for further exploring oridonin as a potential anti‐tumour agent targeting apoptosis and autophagy, in future anti‐cancer therapeutics.     

Multifaceted roles of COPII subunits in autophagy

COPII vesicles mediate anterograde ER-Golgi traffic of newly synthesized proteins in nutrient rich conditions. An accumulating body of results indicates that the secretory COPII vesicles can be shifted to the roles in autophagosome formation and selective ER-phagy (autophagy of ER), depending on their specific subunits, in response to environmental stresses. In this mini-review, we summarize and discuss the multifaceted roles of COPII vesicles in autophagy and the underlying molecular mechanisms.     

Autophagic and apoptotic response to stress signals in mammalian cells

Autophagy is a highly conserved catabolic programme for degrading proteins and organelles. This process has been shown to act as a pro-survival or pro-death mechanism in different physiological and pathological conditions. Several stress stimuli can induce autophagy, such as nutrient deprivation or critical steps in development of lower and higher eukaryotes. Apoptosis is an orchestrated form of cell death in which cells are actively involved in their own demise. Again, stress is a positive regulator of apoptosis and, in particular, of its apoptosome-mediated mitochondrial pathway. Besides discussing the individual roles played by the key molecules involved in autophagy in mammals in response to stress signals, we discuss here the interrelations between autophagy and apoptosis under these conditions.     

The role of autophagy in age-related neurodegeneration

Most age-related neurodegenerative diseases are characterized by accumulation of aberrant protein aggregates in affected brain regions. In many cases, these proteinaceous deposits are composed of ubiquitin conjugates, suggesting a failure in the clearance of proteins targeted for degradation. The 2 principal routes of intracellular protein catabolism are the ubiquitin proteasome system and the autophagy-lysosome system (autophagy). Both of these degradation pathways have been implicated as playing important roles in the pathogenesis of neurodegenerative disease. Here we describe autophagy and review the evidence suggesting that impairment of autophagy contributes to the initiation or progression of age-related neurodegeneration. We also review recent evidence indicating that autophagy may be exploited to remove toxic protein species, suggesting novel strategies for therapeutic intervention for a class of diseases for which no effective treatments presently exist.