The heavy metal cadmium induces valosin-containing protein (VCP)-mediated aggresome formation

Cadmium (Cd2+) is a heavy metal ion known to have a long biological half-life in humans. Accumulating evidence shows that exposure to Cd2+ is associated with neurodegenerative diseases characterized by the retention of ubiquitinated and misfolded proteins in the lesions. Here, we report that Cd2+ directly induces the formation of protein inclusion bodies in cells. The protein inclusion body is an aggresome, a major organelle for collecting ubiquitinated or misfolded proteins. Our results show that aggresomes are enriched in the detergent-insoluble fraction of Cd2+-treated cell lysates. Proteomic analysis identified 145 proteins in the aggresome-enriched fractions. One of the proteins is the highly conserved valosin-containing protein (VCP), which has been shown to colocalize with aggresomes and bind ubiquitinated proteins through its N domain (#1-200). Our subsequent examination of VCP's role in the formation of aggresomes induced by Cd2+ indicates that the C-terminal tail (#780-806) of VCP interacts with histone deacetylase HDAC6, a mediator for aggresome formation, suggesting that VCP participates in transporting ubiquitinated proteins to aggresomes. This function of VCP is impaired by inhibition of the deacetylase activity of HDAC6 or by over-expression of VCP mutants that do not bind ubiquitinated proteins or HDAC6. Our results indicate that Cd2+ induces the formation of protein inclusion bodies by promoting the accumulation of ubiquitinated proteins in aggresomes through VCP and HDAC6. Our delineation of the role of VCP in regulating cell responses to ubiquitinated proteins has important implications for understanding Cd2+ toxicity and associated diseases.     

组蛋白脱乙酰基酶6在聚集小体和神经变性疾病中的作用

组蛋白脱乙酰基酶6(HDAC6)是主要存在于胞浆中的微管脱乙酰基酶,在体内参与多种重要的生物学过程。研究表明,错误折叠和聚集的蛋白质组成的聚集小体是神经变性疾病的主要病理特征,聚集小体在早期通过自吞噬作用,对细胞起着保护性作用,而HDAC6能调节聚集小体的形成并且参与自噬性降解。本文综述了近几年HDAC6参与聚集小体以及神经变性疾病发生发展的研究进展,为神经变性疾病的治疗提供新的研究思路,并为新药研发提供更多的理论依据。     

The role of chaperones in Parkinson's disease and prion diseases

The etiologies of neurodegenerative diseases, such as Alzheimer's disease, Parkinson's disease, polyglutamine diseases, or prion diseases may be diverse; however, aberrations in protein folding, processing, and/or degradation are common features of these entities, implying a role of quality control systems, such as molecular chaperones and the ubiquitin-proteasome pathway. There is substantial evidence for a causal role of protein misfolding in the pathogenic process coming from neuropathology, genetics, animal modeling, and biophysics. The presence of protein aggregates in all neurodegenerative diseases gave rise to the hypothesis that protein aggregates, be it intracellular or extracellular deposits, may perturb the cellular homeostasis and disintegrate neuronal function (Table 1). More recently, however, an increasing number of studies have indicated that protein aggregates are not toxic per se and might even serve a protective role by sequestering misfolded proteins. Specifically, experimental models of polyglutamine diseases, Alzheimer's disease, and Parkinson's disease revealed that the appearance of aggregates can be dissociated from neuronal toxicity, while misfolded monomers or oligomeric intermediates seem to be the toxic species. The unique features of molecular chaperones to assist in the folding of nascent proteins and to prevent stress-induced misfolding was the rationale to exploit their effects in different models of neurodegenerative diseases. This chapter concentrates on two neurodegenerative diseases, Parkinson's disease and prion diseases, with a special focus on protein misfolding and a possible role of molecular chaperones.     

Immune-Directed Gene Therapeutic Development for Alzheimer’s, Prion, and Parkinson’s Diseases

The development of novel immune-based therapeutics for neurodegenerative diseases is an area of intense focus. Neurodegenerative diseases represent a particular challenge since in many cases the onset of symptoms occurs after considerable degeneration has ensued. Based on human genetic and histopathological evidence from patients with neurodegenerative diseases, animal models that recapitulate specific pathologic features have been developed. Utilizing these animal models in combination with viral vector-based gene therapeutics, specific epochs of disease can be targeted. One common feature of several neurodegenerative diseases is misfolded proteins. The mechanism by which these altered protein conformers lead to neurodegeneration is not completely understood but much effort has been put forward to either degrade aberrant protein or prevent the formation of misfolded conformers. In this review, we will summarize work that employs viral vector gene therapeutics to modulate the brain’s response to misfolded proteins with a specific focus on neurodegeneration. This work was presented by KMZ in Symposium I at the SNIP 14th Annual Conference, March 13, 2008. Authors who are guarantors of the work: Kathleen A. Maguire-Zeiss and Howard J. Federoff. Source of support: NIEHS R01ES014470 (KMZ); DAMD17-03-1-0009 (HJF).     

Nanopolyphenol rejuvenates microglial surveillance of multiple misfolded proteins through metabolic reprogramming

Microglial surveillance plays an essential role in clearing misfolded proteins such as amyloid-beta, tau, and α-synuclein aggregates in neurodegenerative diseases. However, due to the complex structure and ambiguous pathogenic species of the misfolded proteins, a universal approach to remove the misfolded proteins remains unavailable. Here, we found that a polyphenol, α-mangostin, reprogrammed metabolism in the disease-associated microglia through shifting glycolysis to oxidative phosphorylation, which holistically rejuvenated microglial surveillance capacity to enhance microglial phagocytosis and autophagy-mediated degradation of multiple misfolded proteins. Nanoformulation of α-mangostin efficiently delivered α-mangostin to microglia, relieved the reactive status and rejuvenated the misfolded-proteins clearance capacity of microglia, which thus impressively relieved the neuropathological changes in both Alzheimer's disease and Parkinson's disease model mice. These findings provide direct evidences for the concept of rejuvenating microglial surveillance of multiple misfolded proteins through metabolic reprogramming, and demonstrate nanoformulated α-mangostin as a potential and universal therapy against neurodegenerative diseases.     

The role of ubiquitin C-terminal hydrolase L1 in neurodegenerative disorders

Impairment of the ubiquitin-proteasome system (UPS) results in the failure to remove and degrade misfolded proteins and consequently causes the accumulation of misfolded proteins in the cell. The aberrant interactions between misfolded proteins and normal intracellular proteins are thought to underlie the pathogenesis in many neurodegenerative diseases. Ubiquitin C-terminal hydrolase L1 (UCH-L1) is an important component of the UPS. Its major function is related to mono-ubiquitin recycling and thereby, sustaining protein degradation. Mutations of the UCH-L1 gene and alterations of its proteins' activity have been found to associate with several neurodegenerative disorders. In this review, we will discuss a link between UCH-L1 and Parkinson's, Huntington's and Alzheimer's diseases. We will also present a potential strategy for the treatment of Alzheimer's disease by boosting endogenous UCH-L1 activity.     

Therapeutic induction of autophagy to modulate neurodegenerative disease progression

There is accumulating evidence that aggregating, misfolded proteins may have an impact on autophagic function, suggesting that this could be a secondary pathological mechanism in many diseases. In this review, we focus on the role of autophagy in four major neurodegenerative diseases: Alzheimer disease (AD), Huntington''s disease (HD), Parkinson''s disease (PD) and amyotropic lateral sclerosis.     

Generalization of the prion hypothesis to other neurodegenerative diseases: an imperfect fit

Protein misfolding diseases have been classically understood as diffuse errors in protein folding, with misfolded protein arising autonomously throughout a tissue due to a pathologic stressor. The field of prion science has provided an alternative mechanism whereby a seed of pathologically misfolded protein, arising exogenously or through a rare endogenous structural fluctuation, yields a template to catalyze misfolding of the native protein. The misfolded protein may then spread intercellularly to communicate the misfold to adjacent areas and ultimately infect a whole tissue. Mounting evidence implicates a prion-like process in the propagation of several neurodegenerative diseases, including Alzheimer's, Parkinson's, Huntington's, amyotrophic lateral sclerosis, and the tauopathies. However, the parallels between the events observed in these conditions and those in prion disease are often incomplete. The aim of this review was to examine the current state of knowledge concerning the mechanisms of protein misfolding and aggregation for neurodegeneration-associated proteins. In addition, possible methods of intercellular spread are described that focus on the hypothesis that released microvesicles function as misfolded protein delivery vehicles, and the therapeutic options enabled by viewing these diseases from the prion perspective.     

Neuroprotective Effect of Chebulagic Acid via Autophagy Induction in SH-SY5Y Cells

Autophagy is a series of catabolic process mediating the bulk degradation of intracellular proteins and organelles through formation of a double-membrane vesicle, known as an autophagosome, and fusing with lysosome. Autophagy plays an important role of death-survival decisions in neuronal cells, which may influence to several neurodegenerative disorders including Parkinson’s disease. Chebulagic acid, the major constituent of Terminalia chebula and Phyllanthus emblica, is a benzopyran tannin compound with various kinds of beneficial effects. This study was performed to investigate the autophagy enhancing effect of chebulagic acid on human neuroblastoma SH-SY5Y cell lines. We determined the effect of chebulagic acid on expression levels of autophago-some marker proteins such as, DOR/TP53INP2, Golgi-associated ATPase Enhancer of 16 kDa (GATE 16) and Light chain 3 II (LC3 II), as well as those of its upstream pathway proteins, AMP-activated protein kinase (AMPK), mammalian target of rapamycin (mTOR) and Beclin-1. All of those proteins were modulated by chebulagic acid treatment in a way of enhancing the autophagy. Additionally in our study, chebulagic acid also showed a protective effect against 1-methyl-4-phenylpyridinium (MPP⁺) - induced cytotoxicity which mimics the pathological symptom of Parkinson’s disease. This effect seems partially mediated by enhanced autophagy which increased the degradation of aggregated or misfolded proteins from cells. This study suggests that chebulagic acid is an attractive candidate as an autophagy-enhancing agent and therefore, it may provide a promising strategy to prevent or cure the diseases caused by accumulation of abnormal proteins including Parkinson’s disease.     

Rapamycin inhibits polyglutamine aggregation independently of autophagy by reducing protein synthesis

Accumulation of misfolded proteins and protein assemblies is associated with neuronal dysfunction and death in several neurodegenerative diseases such as Alzheimer's, Parkinson's, and Huntington's disease (HD). It is therefore critical to understand the molecular mechanisms of drugs that act on pathways that modulate misfolding and/or aggregation. It is noteworthy that the mammalian target of rapamycin inhibitor rapamycin or its analogs have been proposed as promising therapeutic compounds clearing toxic protein assemblies in these diseases via activation of autophagy. However, using a cellular model of HD, we found that rapamycin significantly decreased aggregation-prone polyglutamine (polyQ) and expanded huntingtin and its inclusion bodies (IB) in both autophagy-proficient and autophagy-deficient cells (by genetic knockout of the atg5 gene in mouse embryonic fibroblasts). This result suggests that rapamycin modulates the levels of misfolded polyQ proteins via pathways other than autophagy. We show that rapamycin reduces the amount of soluble polyQ protein via a modest inhibition of protein synthesis that in turn significantly reduces the formation of insoluble polyQ protein and IB formation. Hence, a modest reduction in huntingtin synthesis by rapamycin may lead to a substantial decrease in the probability of reaching the critical concentration required for a nucleation event and subsequent toxic polyQ aggregation. Thus, in addition to its beneficial effect proposed previously of reducing polyQ aggregation/toxicity via autophagic pathways, rapamycin may alleviate polyQ disease pathology via its effect on global protein synthesis. This finding may have important therapeutic implications.     

Role of FK506 binding proteins in neurodegenerative disorders

Protein misfolding has been implicated in the pathophysiology of several neurodegenerative 'amyloidoses' that includes Alzheimer's, Parkinson's, Huntington's disease, frontotemporal dementia and amyotrophic lateral sclerosis. Accumulation of misfolded proteins into ordered fibrillar intra- or extracellular amyloids results in brain lesions that in turn lead to injury and neuronal loss. The appearance of protein aggregates in the diseased brain hints at an inability of cellular chaperones to properly assist folding of client proteins. Not surprisingly, studies involving cell-based and animal models of the neurodegenerative diseases have shown that overexpression of molecular chaperones can provide neuroprotection. Together with identification of new targets for symptomatic relief of motor and non-motor defects in neurodegenerative disorders, there is a critical unmet clinical need for the development of novel neuroprotective molecules. One such promising class of compounds are neuroimmunophilin ligands (NILs). Derived from FK506 (tacrolimus), NILs have been shown to be efficacious in a number of neurodegenerative disorders. The ability of these nonimmunosuppressive NILs to protect neurons is modulated, in part, by a large family of co-chaperone proteins called the FK506 binding proteins (FKBPs). This review focuses on the roles of FKBPs in neurodegenerative disorders with an emphasis on the cellular mechanisms responsible for their neuroprotective and neurotrophic activities. We discuss the structural features of FKBPs and the mode of action of NILs. For brevity, we limit our discussion to those FKBPs that are particularly enriched in the nervous system. We hope that such information will aid in the rational design of new and improved NILs for ameliorating neurodegenerative disorders.     

Alzheimer��s Disease: Pathological Mechanisms and Recent Insights

Amyloidopathies cause neurodegeneration in a substantial portion of the elderly population. Improvements in long term health care have made elderly individuals a large and growing demographic group, marking these diseases as a major public health concern. Alzheimer’s Disease (AD) is the most studied form of neurodegenerative amyloidopathy. Although our understanding of AD is far from complete, several decades of research have advanced our knowledge to the point where it is conceivable that some form of disease modifying therapy may be available in the near future. These advances have been built on a strong mechanistic understanding of the disease from its underlying genetics, molecular biology and clinical pathology. Insights derived from the study of other neurodegenerative diseases, such as some forms of frontotemporal dementia, have been critical to this process. This knowledge has allowed researchers to construct animal models of the disease process that have paved the way towards the development of therapeutics. However, what was once thought to be a straightforward problem has evolved into a series of disappointing outcomes. Examination of pathways common to all neurodegenerative diseases, including the cellular mechanisms that clear misfolded proteins and their regulation, may be the best way to move forward.     

细胞骨架与神经退行性疾病

神经退行性疾病(Neurodegenerative disease)是一种以神经元退行性病变为基础的慢性进行性神经系统疾病,其病因十分复杂,其中线粒体功能障碍学说、氧化应激学说、蛋白质发生错误折叠聚集、炎症、免疫功能缺陷,基因突变等已经得到普遍认可。近年来的研究发现,细胞骨架在神经元变性过程中发挥了重要作用。细胞骨架是细胞质内蛋白质丝组成的纤维网架体系,其决定和维持着细胞的形态结构,同时参与细胞运动、分裂、胞浆运输等生命活动,对信号传导具有重要的意义。该文就其在神经退行性疾病方面的研究进行综述。     

Tissue transglutaminase: a novel pharmacological target in preventing toxic protein aggregation in neurodegenerative diseases

Alzheimer's disease, Parkinson's disease and Huntington's disease are neurodegenerative diseases, characterized by the accumulation and deposition of neurotoxic protein aggregates. The capacity of specific proteins to self-interact and form neurotoxic aggregates seems to be a common underlying mechanism leading to pathology in these neurodegenerative diseases. This process might be initiated and/or accelerated by proteins that interact with these aggregating proteins. The transglutaminase (TG) family of proteins are calcium-dependent enzymes that catalyze the formation of covalent ε-(γ-glutamyl)lysine isopeptide bonds, which can result in both intra- and intermolecular cross-links. Intramolecular cross-links might modify self-interacting proteins, and make them more prone to aggregate. In addition, intermolecular cross-links could link self-aggregating proteins and thereby initiate and/or stimulate the aggregation process. So far, increased levels and activity of tissue transglutaminase (tTG), the best characterized member of the TG family, have been observed in many neurodegenerative diseases, and the self-interacting proteins, characteristic of Alzheimer's disease, Parkinson's disease and Huntington's disease, are known substrates of tTG. Here, we focus on the role of tTG in the initiation of the aggregation process of self-interacting proteins in these diseases, and promote the notion that tTG might be an attractive novel target for treatment of neurodegenerative diseases.     

The case for therapeutic proteostasis modulators

A functional ubiquitin proteasome pathway (UPP) is vital for all eukaryotic cellular systems and therefore any alteration in this critical component of proteostasis machinery has rpotential pathological consequences. A proteostasis imbalance can be induced by environmental pollutants, age or genetic factors. Though the exact underlying mechanisms are unclear, a decrease in proteasome activity weakens the homeostatic cellular capacity to remove proteins that are either misfolded or need to be replenished, which favors the development of neurodegenerative, cardiac and other conformational diseases. In contrast, induction of proteasome activity is an attribute of many diseases including muscle wasting, sepsis, cachexia and uraemia. In the case of misfolded protein disorders, higher degradation of a single protein leads to the pathophysiological consequences due to the absence of functional protein. Therefore, selective proteostasis inhibition is a potential treatment strategy for misfolded protein disorders, while broad-spectrum proteasome inhibitor drugs are designed to target tumor metastasis. In contrast, for muscle wasting and neurodegeneration, the use of proteostasis-activating or modulating compounds could be more effective.     

The case for therapeutic proteostasis modulators

A functional ubiquitin proteasome pathway (UPP) is vital for all eukaryotic cellular systems and therefore any alteration in this critical component of proteostasis machinery has rpotential pathological consequences. A proteostasis imbalance can be induced by environmental pollutants, age or genetic factors. Though the exact underlying mechanisms are unclear, a decrease in proteasome activity weakens the homeostatic cellular capacity to remove proteins that are either misfolded or need to be replenished, which favors the development of neurodegenerative, cardiac and other conformational diseases. In contrast, induction of proteasome activity is an attribute of many diseases including muscle wasting, sepsis, cachexia and uraemia. In the case of misfolded protein disorders, higher degradation of a single protein leads to the pathophysiological consequences due to the absence of functional protein. Therefore, selective proteostasis inhibition is a potential treatment strategy for misfolded protein disorders, while broad-spectrum proteasome inhibitor drugs are designed to target tumor metastasis. In contrast, for muscle wasting and neurodegeneration, the use of proteostasis-activating or modulating compounds could be more effective.     

Drosophila models of proteinopathies: the little fly that could

Alzheimer's, Parkinson's, and Huntington's disease are complex neurodegenerative conditions with high prevalence characterized by protein misfolding and deposition in the brain. Considerable progress has been made in the last two decades in identifying the genes and proteins responsible for several human 'proteinopathies'. A wide variety of wild type and mutant proteins associated with neurodegenerative conditions are structurally unstable, misfolded, and acquire conformations rich in ?-sheets (?-state). These conformers form highly toxic self-assemblies that kill the neurons in stereotypical patterns. Unfortunately, the detailed understanding of the molecular and cellular perturbations caused by these proteins has not produced a single disease-modifying therapy. More than a decade ago, several groups demonstrated that human proteinopathies reproduce critical features of the disease in transgenic flies, including protein mis-folding, aggregation, and neurotoxicity. These initial reports led to an explosion of research that has contributed to a better understanding of the molecular mechanisms regulating conformational dynamics and neurotoxic cascades. To remain relevant in this competitive environment, Drosophila models will need to expand their flexible, innovative, and multidisciplinary approaches to find new discoveries and translational applications.     

Transgenic animal models of neurodegenerative diseases and their application to treatment development

Neurodegenerative disorders of the aging population affect over 5 million people in the US and Europe alone. The common feature is the progressive accumulation of misfolded proteins with the formation of toxic oligomers. Previous studies show that while in Alzheimer's disease (AD) misfolded amyloid-beta protein accumulates both in the intracellular and extracellular space, in Lewy body disease (LBD), Parkinson's disease (PD), Multiple System Atrophy (MSA), Fronto-Temporal dementia (FTD), prion diseases, amyotrophic lateral sclerosis (ALS) and trinucleotide repeat disorders (TNRD), the aggregated proteins accumulate in the plasma membrane and intracellularly. Protein misfolding and accumulation is the result of an altered balance between protein synthesis, aggregation rate and clearance. Based on these studies, considerable advances have been made in the past years in developing novel experimental models of neurodegenerative disorders. This has been in part driven by the identification of genetic mutations associated with familial forms of these conditions and gene polymorphisms associated with the more common sporadic variants of these diseases. Transgenic and knock out rodents and Drosophila as well as viral vector driven models of Alzheimer's disease (AD), PD, Huntington's disease (HD) and others have been developed, however the focus for this review will be on rodent models of AD, FTD, PD/LBD, and MSA. Promising therapeutic results have been obtained utilizing amyloid precursor protein (APP) transgenic (tg) models of AD to develop therapies including use of inhibitors of the APP-processing enzymes beta- and gamma-secretase as well as vaccine therapies.     

Cyclophilin D as a drug target

The mitochondrial permeability transition (MPT) plays an important role in damage-induced cell death, and agents inhibiting the MPT may have a therapeutic potential for treating human conditions such as ischemia/reperfusion injury, trauma, and neurodegenerative diseases. The mitochondrial matrix protein, cyclophilin D (CYP D), a member of a family of highly homologous peptidylprolyl cis-trans isomerases (PPIases), plays a decisive role in MPT, being an integral constituent of the MPT pore. Other putative MPT pore proteins include the adenine nucleotide translocator (ANT) and the voltage-dependent anion channel (VDAC). In an alternative model, the MPT pore is formed by clusters of misfolded membrane proteins outlining aqueous channels that are regulated by CYP D and other chaperone-like proteins. Like cyclophilin A (CYP A) and other cyclophilin family members, CYP D is targeted by the immunosuppressant cyclosporin A (CsA). CsA is cytoprotective in many cellular and animal models, but protection may result from either inhibition of the MPT through an interaction with CYP D or inhibition of calcineurin-mediated dephosphorylation of BAD through an interaction with CYP A. The relevance of MPT inhibition by CsA for its cytoprotective effects is well documented in many cellular models. Mechanisms of action in vivo are more difficult to define, and accordingly the evidence is as yet less compelling in in vivo animal models of ischemia/reperfusion injury, trauma and neurodegenerative diseases. Notwithstanding, CYP D is a drug target of high interest. Structural considerations suggest feasibility of designing CYP D ligands without immunosuppressant properties. This is highly desirable, since they have the potential of being useful therapeutic agents in a variety of disease states. It might be a tougher challenge to obtain compounds specific for CYP D vs. other cyclophilins, and/or of small molecular weight, allowing brain penetration to make them suitable for treating neurodegenerative diseases.