Neurodegenerative lysosomal disorders: a continuum from development to late age

Neuronal survival requires continuous lysosomal turnover of cellular constituents delivered by autophagy and endocytosis. Primary lysosomal dysfunction in inherited congenital "lysosomal storage" disorders is well known to cause severe neurodegenerative phenotypes associated with accumulations of lysosomes and autophagic vacuoles (AVs). Recently, the number of inherited adult-onset neurodegenerative diseases caused by proteins that regulate protein sorting and degradation within the endocytic and autophagic pathways has grown considerably. In this Perspective, we classify a group of neurodegenerative diseases across the lifespan as disorders of lysosomal function, which feature extensive autophagic-endocytic-lysosomal neuropathology and may share mechanisms of neurodegeneration related to degradative failure and lysosomal destabilization. We highlight Alzheimer's disease as a disease within this group and discuss how each of the genes and other risk factors promoting this disease contribute to progressive lysosomal dysfunction and neuronal cell death.     

Autophagy in neurons: a review

Macroautophagy is a process of regulated turnover of cellular constituents that occurs during development and under conditions of stress such as starvation. Defects in autophagy have serious consequences, as they have been linked to neurodegenerative disease, cancer, and cardiomyopathy. This process, which exists in all eukaryotic cells, is tightly controlled, but in extreme cases results in the death of the cell. While major insights into the molecular and biochemical pathways involved have come from genetic studies in yeast, little is known about autophagic pathways in mammalian cells, particularly in neurons. Recently, research in neuronal culture models has begun to identify some characteristics of neuronal macroautophagy. The results suggest that macroautophagy in neurons may provide a neuroprotective mechanism. Here, we review the defining characteristics of autophagy with special attention to its role in neurodegenerative disorders, and recent efforts to delineate the pathway of autophagic protein degradation in neurons.     

Defective mitophagy in human Niemann-Pick Type C1 neurons is due to abnormal autophagy activation

Although traditionally regarded as a cellular adaptive process triggered by nutrient deprivation, autophagy in neurons appears to provide an important neuroprotective mechanism. Neurons in the brain are protected from starvation, and neuronal autophagy serves a critical role in the turnover of abnormal proteins and damaged organelles. As post-mitotic, highly polarized cells with active protein trafficking, neurons rely heavily on an efficient autophagic pathway. Using human embryonic stem cell-derived neurons engineered to mimic the cholesterol lysosomal storage disease Niemann Pick type C1 (NPC1), we have shown that excessive activation and impaired progression of the autophagic pathway conspire to cause abnormal mitochondrial clearance. Defective mitophagy is exceptionally severe in human NPC1 neurons, as compared with patient fibroblasts, and may explain the selective neuronal failure observed in NPC1 and related neurodegenerative disorders.     

Defective mitophagy in human Niemann-Pick Type C1 neurons is due to abnormal autophagy activation

Although traditionally regarded as a cellular adaptive process triggered by nutrient deprivation, autophagy in neurons appears to provide an important neuroprotective mechanism. Neurons in the brain are protected from starvation, and neuronal autophagy serves a critical role in the turnover of abnormal proteins and damaged organelles. As post-mitotic, highly polarized cells with active protein trafficking, neurons rely heavily on an efficient autophagic pathway. Using human embryonic stem cell-derived neurons engineered to mimic the cholesterol lysosomal storage disease Niemann Pick type C1 (NPC1), we have shown that excessive activation and impaired progression of the autophagic pathway conspire to cause abnormal mitochondrial clearance. Defective mitophagy is exceptionally severe in human NPC1 neurons, as compared with patient fibroblasts, and may explain the selective neuronal failure observed in NPC1 and related neurodegenerative disorders.     

Autophagy of Mitochondria: A Promising Therapeutic Target for Neurodegenerative Disease

The autophagic process is the only known mechanism for mitochondrial turnover and it has been speculated that dysfunction of autophagy may result in mitochondrial error and cellular stress. Emerging investigations have provided new understanding of how autophagy of mitochondria (also known as mitophagy) is associated with cellular oxidative stress and its impact on neurodegeneration. This impaired autophagic function may be considered as a possible mechanism in the pathogenesis of several neurodegenerative disorders including Parkinson’s disease, Alzheimer’s disease, multiple sclerosis, amyotrophic lateral sclerosis, and Huntington disease. It can be suggested that autophagy dysfunction along with oxidative stress is considered main events in neurodegenerative disorders. New therapeutic approaches have now begun to target mitochondria as a potential drug target. This review discusses evidence supporting the notion that oxidative stress and autophagy are intimately associated with neurodegenerative disease pathogenesis. This review also explores new approaches that can prevent mitochondrial dysfunction, improve neurodegenerative etiology, and also offer possible cures to the aforementioned neurodegenerative diseases.     

SIRT2 interferes with autophagy-mediated degradation of protein aggregates in neuronal cells under proteasome inhibition

Abnormal protein aggregates have been suggested as a common pathogenesis of many neurodegenerative diseases. Two well-known protein degradation pathways are responsible for protein homeostasis by balancing protein biosynthesis and degradative processes: the ubiquitin–proteasome system (UPS) and autophagy-lysosomal system. UPS serves as the primary route for degradation of short-lived proteins, but large-size protein aggregates cannot be degraded by UPS. Autophagy is a unique cellular process that facilitates degradation of bulky protein aggregates by lysosome. Recent studies have demonstrated that autophagy plays a crucial role in the pathogenesis of neurodegenerative diseases characterized by abnormal protein accumulation, suggesting that regulation of autophagy may be a valuable therapeutic strategy for the treatment of various neurodegenerative diseases. Sirtuin-2 (SIRT2) is a class III histone deacetylase that is expressed abundantly in aging brain tissue. Here, we report that SIRT2 increases protein accumulation in murine cholinergic SN56 cells and human neuroblastoma SH-SY5Y cells under proteasome inhibition. Overexpression of SIRT2 inhibits lysosome-mediated autophagic turnover by interfering with aggresome formation and also makes cells more vulnerable to accumulated protein-mediated cytotoxicity by MG132 and amyloid beta. Moreover, MG132-induced accumulation of ubiquitinated proteins and p62 as well as cytotoxicity are attenuated in siRNA-mediated SIRT2-silencing cells. Taken together, these results suggest that regulation of SIRT2 could be a good therapeutic target for a range of neurodegenerative diseases by regulating autophagic flux.     

Autophagy and mesenchymal cell fibrogenesis

Autophagy is a catabolic pathway essential for cellular energy homeostasis that involves the self-degradation of intracellular components in lysosomes. This process has been implicated in the pathophysiology of many human disorders, including infection, cancer, and fibrosis. Autophagy is also recognized as a mediator of survival and proliferation, and multiple pathways induce autophagy under conditions of cellular stress, including nutrient and energy depletion. High autophagic activity has been detected in fibrogenic cells from several tissues; however the role of autophagy in fibrogenesis and mesenchymal cells varies greatly in different tissues and settings, with contributions uncovered to energy metabolism and collagen turnover by fibrogenic cells. Because several chemical modulators of autophagy have already been identified, autophagy regulation constitutes a potential target for antifibrotic therapy. This article is part of a Special Issue entitled: Fibrosis: Translation of basic research to human disease.     

Autophagy,lipophagy and lysosomal lipid storage disorders

Autophagy is a catabolic process with an essential function in the maintenance of cellular and tissue homeostasis. It is primarily recognised for its role in the degradation of dysfunctional proteins and unwanted organelles, however in recent years the range of autophagy substrates has also been extended to lipids. Degradation of lipids via autophagy is termed lipophagy. The ability of autophagy to contribute to the maintenance of lipo-homeostasis becomes particularly relevant in the context of genetic lysosomal storage disorders where perturbations of autophagic flux have been suggested to contribute to the disease aetiology. Here we review recent discoveries of the molecular mechanisms mediating lipid turnover by the autophagy pathways. We further focus on the relevance of autophagy, and specifically lipophagy, to the disease mechanisms. Moreover, autophagy is also discussed as a potential therapeutic target in several key lysosomal storage disorders.     

Interplay of pathogenic forms of human tau with different autophagic pathways

Loss of neuronal proteostasis, a common feature of the aging brain, is accelerated in neurodegenerative disorders, including different types of tauopathies. Aberrant turnover of tau, a microtubule‐stabilizing protein, contributes to its accumulation and subsequent toxicity in tauopathy patients’ brains. A direct toxic effect of pathogenic forms of tau on the proteolytic systems that normally contribute to their turnover has been proposed. In this study, we analyzed the contribution of three different types of autophagy, macroautophagy, chaperone‐mediated autophagy, and endosomal microautophagy to the degradation of tau protein variants and tau mutations associated with this age‐related disease. We have found that the pathogenic P301L mutation inhibits degradation of tau by any of the three autophagic pathways, whereas the risk‐associated tau mutation A152T reroutes tau for degradation through a different autophagy pathway. We also found defective autophagic degradation of tau when using mutations that mimic common posttranslational modifications in tau or known to promote its aggregation. Interestingly, although most mutations markedly reduced degradation of tau through autophagy, the step of this process preferentially affected varies depending on the type of tau mutation. Overall, our studies unveil a complex interplay between the multiple modifications of tau and selective forms of autophagy that may determine its physiological degradation and its faulty clearance in the disease context.     

Understanding the importance of autophagy in human diseases using Drosophila

Autophagy is a lysosome-dependent intracellular degradation pathway that has been implicated in the pathogenesis of various human diseases, either positively or negatively impacting disease outcomes depending on the specific context. The majority of medical conditions including cancer, neurodegenerative diseases, infections and immune system disorders and inflammatory bowel disease could probably benefit from therapeutic modulation of the autophagy machinery. Drosophila represents an excellent model animal to study disease mechanisms thanks to its sophisticated genetic toolkit, and the conservation of human disease genes and autophagic processes. Here, we provide an overview of the various autophagy pathways observed both in flies and human cells(macroautophagy, microautophagy and chaperone-mediated autophagy), and discuss Drosophila models of the above-mentioned diseases where fly research has already helped to understand how defects in autophagy genes and pathways contribute to the relevant pathomechanisms.     

Role of autophagy in the clearance of mutant huntingtin: a step towards therapy?

Macroautophagy (henceforth referred to simply as autophagy) is a bulk degradation process involved in the clearance of long-lived proteins, protein complexes and organelles. A portion of the cytosol, with its contents to be degraded, is enclosed by double-membrane structures called autophagosomes/autophagic vacuoles, which ultimately fuse with lysosomes where their contents are degraded. In this review, we will describe how induction of autophagy is protective against toxic intracytosolic aggregate-prone proteins that cause a range of neurodegenerative diseases. Autophagy is a key clearance pathway involved in the removal of such proteins, including mutant huntingtin (that causes Huntington’s disease), mutant ataxin-3 (that causes spinocerebellar ataxia type 3), forms of tau that cause tauopathies, and forms of alpha-synuclein that cause familial Parkinson’s disease. Induction of autophagy enhances the clearance of both soluble and aggregated forms of such proteins, and protects against toxicity of a range of these mutations in cell and animal models. Interestingly, the aggregates formed by mutant huntingtin sequester and inactivate the mammalian target of rapamycin (mTOR), a key negative regulator of autophagy. This results in induction of autophagy in cells with these aggregates.     

Regulation of autophagy by polyphenols: Paving the road for treatment of neurodegeneration

In the present paper, we will discuss on the importance of autophagy in the central nervous system, and outline the relation between autophagic pathways and the pathogenesis of neurodegenerative disorders. The potential therapeutic benefits of naturally occurring phytochemicals as pharmacological modulators of autophagy will also be addressed. Our findings provide renewed insight on the molecular modes of protection by polyphenols, which is likely to be at least in part mediated not only by their potent antioxidant and anti-inflammatory effects, but also through modulation of autophagic processes to remove the aberrant protein aggregates.     

Computational model for autophagic vesicle dynamics in single cells

Macroautophagy (autophagy) is a cellular recycling program essential for homeostasis and survival during cytotoxic stress. This process, which has an emerging role in disease etiology and treatment, is executed in four stages through the coordinated action of more than 30 proteins. An effective strategy for studying complicated cellular processes, such as autophagy, involves the construction and analysis of mathematical or computational models. When developed and refined from experimental knowledge, these models can be used to interrogate signaling pathways, formulate novel hypotheses about systems, and make predictions about cell signaling changes induced by specific interventions. Here, we present the development of a computational model describing autophagic vesicle dynamics in a mammalian system. We used time-resolved, live-cell microscopy to measure the synthesis and turnover of autophagic vesicles in single cells. The stochastically simulated model was consistent with data acquired during conditions of both basal and chemically-induced autophagy. The model was tested by genetic modulation of autophagic machinery and found to accurately predict vesicle dynamics observed experimentally. Furthermore, the model generated an unforeseen prediction about vesicle size that is consistent with both published findings and our experimental observations. Taken together, this model is accurate and useful and can serve as the foundation for future efforts aimed at quantitative characterization of autophagy.     

Interplay of endoplasmic reticulum stress and autophagy in neurodegenerative disorders

The common underlying feature of most neurodegenerative diseases such as Alzheimer disease (AD), prion diseases, Parkinson disease (PD), and amyotrophic lateral sclerosis (ALS) involves accumulation of misfolded proteins leading to initiation of endoplasmic reticulum (ER) stress and stimulation of the unfolded protein response (UPR). Additionally, ER stress more recently has been implicated in the pathogenesis of HIV-associated neurocognitive disorders (HAND). Autophagy plays an essential role in the clearance of aggregated toxic proteins and degradation of the damaged organelles. There is evidence that autophagy ameliorates ER stress by eliminating accumulated misfolded proteins. Both abnormal UPR and impaired autophagy have been implicated as a causative mechanism in the development of various neurodegenerative diseases. This review highlights recent advances in the field on the role of ER stress and autophagy in AD, prion diseases, PD, ALS and HAND with the involvement of key signaling pathways in these processes and implications for future development of therapeutic strategies.     

Neuronal macroautophagy: from development to degeneration

Macroautophagy, a lysosomal pathway responsible for the turnover of organelles and long-lived proteins, has been regarded mainly as an inducible process in neurons, which is mobilized in states of stress and injury. New studies show, however, that macroautophagy is also constitutively active in healthy neurons and is vital to cell survival. Neurons in the brain, unlike cells in the periphery, are protected from large-scale autophagy induction because they can use several different energy sources optimally, receive additional nutrients and neurotrophin support from glial cells, and benefit from hypothalamic regulation of peripheral nutrient supplies. Due to its exceptional efficiency, constitutive autophagy in healthy neurons proceeds in the absence of easily detectable autophagic vacuole intermediates. These intermediates can accumulate rapidly, however, when late steps in the autophagic process are blocked. Autophagic vacuoles also accumulate abnormally in affected neurons of several major neurodegenerative diseases, including Alzheimer’s disease and Parkinson’s disease, where they have been linked to various aspects of disease pathogenesis including neuronal cell death. The build-up of autophagic vacuoles in these neurological disorders and others may reflect either heightened autophagy induction, impairment in later digestive steps in the autophagy pathway, or both. Determining the basis for AV accumulation is critical for understanding the pathogenic significance of autophagy in a given pathologic state and for designing possible therapies based on modulating autophagy. In this review, we discuss the special features of autophagy regulation in the brain, its suspected roles in neurodevelopment and plasticity, and recent progress toward understanding how dysfunctional autophagy contributes to neurodegenerative disease.     

Parkinson disease,LRRK2 and the endocytic-autophagic pathway

Neurons are quiescent cells that survive for several decades, many times the turnover time of most organelles and proteins, and so with advancing age neurons become affected by degenerative diseases. Autophagy is thought to be an important cellular mechanism preventing cell degeneration in such long-lived cells. We have recently found that the Parkinson disease (PD) gene leucine rich repeat kinase 2 (LRRK2) is directly involved in this process by acting as a negative regulator of autophagic activity. We created a novel genomic DNA reporter cellular model using a new recombineering strategy called Sequential insertion of Target with ovErlapping Primers (STEP) to express a genomic DNA locus YPet-LRRK2 fusion protein. Expression of the R1441C mutant form of LRRK2 induces a cellular phenotype of impaired autophagic balance at the convergent crossroads of the endocytic and autophagic avenues. Conversely, RNAi-induced knockdown of LRRK2 increases autophagic activity. Taken together, these data demonstrate the key role of LRRK2 in regulating autophagy and suggest modulation of LRRK2 function may represent a promising therapeutic target to help restore autophagic equilibrium in neurodegenerative diseases.     

Janus-faced autophagy: a dual role of cellular self-eating in neurodegeneration?

Autophagy is a highly regulated cellular pathway used by eukaryotic cells to consume parts of their constituents during development or starvation. It is associated with extensive rearrangements of intracellular membranes, and involves the cooperation of many gene products in the regulation and execution phase by largely unknown mechanisms. Recent results strongly indicate the role of autophagy in the degradation of damaged macromolecules, in particular misfolded, aberrant proteins, and in organelle turnover; in mutant mice with reduced autophagy, accumulation of abnormal cytosolic proteins as inclusion bodies and massive cell loss occur similarly to human neurodegenerative disorders. Thus, autophagy seems to prevent neurons from undergoing protein aggregation-induced degeneration. In contrast, we have shown that inactivation of genes involved in autophagosome formation suppresses neuronal demise induced by various hyperactivating ion channel mutations or by neurotoxins in the nematode Caenorhabditis elegans. These results raise the possibility that autophagy may also contribute to excitotoxic necrotic-like cell death. This way, autophagic degradation of cytoplasmic materials might have a dual role in the survival of neurons. Depending on the actual cellular milieu and insulting factor, it can act both as a protector and contributor to neuronal damage.     

Small molecule enhancers of autophagy for neurodegenerative diseases

Neurodegenerative disorders such as Alzheimer's disease, Parkinson's disease, amyotrophic lateral sclerosis, prion diseases and polyglutamine disorders, including Huntington's disease and various spinocerebellar ataxias, are associated with the formation of protein aggregates. These aggregates and/or their precursors are thought to be toxic disease-causing species. Autophagy is a major degradation pathway for intracytosolic aggregate-prone proteins, including those associated with neurodegeneration. It is a constitutive self-degradative process involved both in the basal turnover of cellular components and in response to nutrient starvation in eukaryotes. Enhancing autophagy may be a possible therapeutic strategy for neurodegenerative disorders where the mutant proteins are autophagy substrates. In cell and animal models, chemical induction of autophagy protects against the toxic insults of these mutant aggregate-prone proteins by enhancing their clearance. We will discuss various autophagy-inducing small molecules that have emerged in the past few years that may be leads towards the treatment of such devastating diseases.     

Mutant ataxin-3 promotes the autophagic degradation of parkin

There is growing evidence that autophagy plays a key role in neurodegenerative diseases. For instance, stimulating autophagy is neuroprotective both in vitro and in vivo in models of trinucleotide-repeat diseases such as Machado-Joseph disease (MJD). Similarly, proteins associated with familial forms of Parkinson disease (PD) such as parkin and PINK1 converge on the autophagy pathway. Yet, despite these shared mechanisms, it is not clear whether or how these disorders are related at a molecular level. We reported that the mutant form of ataxin-3, the protein responsible for MJD, promotes the autophagic degradation of parkin. Given that the loss of parkin function leads to PD, we propose that the increased turnover of parkin triggered by mutant ataxin-3 may explain some of the parkinsonian features observed in MJD. Moreover, the findings suggest that an increased clearance of parkin in MJD could mitigate the otherwise beneficial effects of autophagy in neurodegeneration.     

Polyglutamine tracts regulate autophagy

Expansions of polyglutamine (polyQ) tracts in different proteins cause 9 neurodegenerative conditions, such as Huntington disease and various ataxias. However, many normal mammalian proteins contain shorter polyQ tracts. As these are frequently conserved in multiple species, it is likely that some of these polyQ tracts have important but unknown biological functions. Here we review our recent study showing that the polyQ domain of the deubiquitinase ATXN3/ataxin-3 enables its interaction with BECN1/beclin 1, a key macroautophagy/autophagy initiator. ATXN3 regulates autophagy by deubiquitinating BECN1 and protecting it from proteasomal degradation. Interestingly, expanded polyQ tracts in other polyglutamine disease proteins compete with the shorter ATXN3 polyQ stretch and interfere with the ATXN3-BECN1 interaction. This competition results in decreased BECN1 levels and impaired starvation-induced autophagy, which phenocopies the loss of autophagic function mediated by ATXN3. Our findings describe a new autophagy-protective mechanism that may be altered in multiple neurodegenerative diseases.