E6-AP promotes misfolded polyglutamine proteins for proteasomal degradation and suppresses polyglutamine protein aggregation and toxicity

The accumulation of intracellular protein deposits as inclusion bodies is the common pathological hallmark of most age-related neurodegenerative disorders including polyglutamine diseases. Appearance of aggregates of the misfolded mutant disease proteins suggest that cells are unable to efficiently degrade them, and failure of clearance leads to the severe disturbances of the cellular quality control system. Recently, the quality control ubiquitin ligase CHIP has been shown to suppress the polyglutamine protein aggregation and toxicity. Here we have identified another ubiquitin ligase, called E6-AP, which is able to promote the proteasomal degradation of misfolded polyglutamine proteins and suppress the polyglutamine protein aggregation and polyglutamine protein-induced cell death. E6-AP interacts with the soluble misfolded polyglutamine protein and associates with their aggregates in both cellular and transgenic mouse models. Partial knockdown of E6-AP enhances the rate of aggregate formation and cell death mediated by the polyglutamine protein. Finally, we have demonstrated the up-regulation of E6-AP in the expanded polyglutamine protein-expressing cells as well as cells exposed to proteasomal stress. These findings suggest that E6-AP is a critical mediator of the neuronal response to misfolded polyglutamine proteins and represents a potential therapeutic target in the polyglutamine diseases.     

The length of polyglutamine tract, its level of expression, the rate of degradation, and the transglutaminase activity influence the formation of intracellular aggregates.

A common feature of CAG-expansion neurodegenerative diseases is the presence of intranuclear aggregates in neuronal cells. We have used a synthetic fusion protein containing at the NH2 terminus the influenza hemoagglutinin epitope (HA), a polyglutamine stretch (polyQ) of various size (17, 36, 43 CAG) and a COOH tail encoding the green fluorescent protein (GFP). The fusion proteins were expressed in COS-7 and neuroblastoma SK-N-BE cells. We found that the formation of aggregates largely depends on the length of polyglutamine tracts and on the levels of expression of the fusion protein. Moreover, transglutaminase overexpression caused an increase of insoluble aggregates only in cells expressing the mutant expanded protein. Conversely, treatment of cells with cystamine, a transglutaminase inhibitor, reduced the percentage of aggregates. We found also that the inhibition of the proteasome ubiquitin-dependent degradation increased the formation of intranuclear aggregates. These data suggest that length of polyglutamine tract, its expression, unbalance between cellular transglutaminase activity, and the ubiquitin-degradation pathway are key factors in the formation of intranuclear aggregates.     

Co-chaperone CHIP associates with expanded polyglutamine protein and promotes their degradation by proteasomes

A major hallmark of the polyglutamine diseases is the formation of neuronal intranuclear inclusions of the disease proteins that are ubiquitinated and often associated with various chaperones and proteasome components. But, how the polyglutamine proteins are ubiquitinated and degraded by the proteasomes are not known. Here, we demonstrate that CHIP (C terminus of Hsp70-interacting protein) co-immunoprecipitates with the polyglutamine-expanded huntingtin or ataxin-3 and associates with their aggregates. Transient overexpression of CHIP increases the ubiquitination and the rate of degradation of polyglutamine-expanded huntingtin or ataxin-3. Finally, we show that overexpression of CHIP suppresses the aggregation and cell death mediated by expanded polyglutamine proteins and the suppressive effect is more prominent when CHIP is overexpressed along with Hsc70.     

Hsp105alpha suppresses the aggregation of truncated androgen receptor with expanded CAG repeats and cell toxicity

Spinal and bulbar muscular atrophy (SBMA) is a neurodegenerative disorder caused by the expansion of a polyglutamine tract in the androgen receptor (AR). The N-terminal fragment of AR containing the expanded polyglutamine tract aggregates in cytoplasm and/or in nucleus and induces cell death. Some chaperones such as Hsp40 and Hsp70 have been identified as important regulators of polyglutamine aggregation and/or cell death in neuronal cells. Recently, Hsp105alpha, expressed at especially high levels in mammalian brain, has been shown to suppress apoptosis in neuronal cells and prevent the aggregation of protein caused by heat shock in vitro. However, its role in polyglutamine-mediated cell death and toxicity has not been studied. In the present study, we examined the effects of Hsp105alpha on the aggregation and cell toxicity caused by expansion of the polyglutamine tract using a cellular model of SBMA. The transient expression of truncated ARs (tARs) containing an expanded polyglutamine tract caused aggregates to form in COS-7 and SK-N-SH cells and concomitantly apoptosis in the cells with the nuclear aggregates. When Hsp105alpha was overexpressed with tAR97 in the cells, Hsp105alpha was colocalized to aggregates of tAR97, and the aggregation and cell toxicity caused by expansion of the polyglutamine tract were markedly reduced. Both beta-sheet and alpha-helix domains, but not the ATPase domain, of Hsp105alpha were necessary to suppress the formation of aggregates in vivo and in vitro. Furthermore, Hsp105alpha was found to localize in nuclear inclusions formed by ARs containing an expanded polyglutamine tract in tissues of patients and transgenic mice with SBMA. These findings suggest that overexpression of Hsp105alpha suppresses cell death caused by expansion of the polyglutamine tract without chaperone activity, and the enhanced expression of the essential domains of Hsp105alpha in brain may provide an effective therapeutic approach for CAG repeat diseases.     

Inhibition of polyglutamine protein aggregation and cell death by novel peptides identified by phage display screening

Proteins with expanded polyglutamine domains cause eight inherited neurodegenerative diseases, including Huntington's, but the molecular mechanism(s) responsible for neuronal degeneration are not yet established. Expanded polyglutamine domain proteins possess properties that distinguish them from the same proteins with shorter glutamine repeats. Unlike proteins with short polyglutamine domains, proteins with expanded polyglutamine domains display unique protein interactions, form intracellular aggregates, and adopt a novel conformation that can be recognized by monoclonal antibodies. Any of these polyglutamine length-dependent properties could be responsible for the pathogenic effects of expanded polyglutamine proteins. To identify peptides that interfere with pathogenic polyglutamine interactions, we screened a combinatorial peptide library expressed on M13 phage pIII protein to identify peptides that preferentially bind pathologic-length polyglutamine domains. We identified six tryptophan-rich peptides that preferentially bind pathologic-length polyglutamine domain proteins. Polyglutamine-binding peptide 1 (QBP1) potently inhibits polyglutamine protein aggregation in an in vitro assay, while a scrambled sequence has no effect on aggregation. QBP1 and a tandem repeat of QBP1 also inhibit aggregation of polyglutamine-yellow fluorescent fusion protein in transfected COS-7 cells. Expression of QBP1 potently inhibits polyglutamine-induced cell death. Selective inhibition of pathologic interactions of expanded polyglutamine domains with themselves or other proteins may be a useful strategy for preventing disease onset or for slowing progression of the polyglutamine repeat diseases.     

Autophagy genes protect against disease caused by polyglutamine expansion proteins in Caenorhabditis elegans

Expanded polyglutamine (polyQ) proteins aggregate intracellularly in Huntington's disease and other neurodegenerative disorders. The lysosomal degradation pathway, autophagy, is known to promote clearance of polyQ protein aggregates in cultured cells. Moreover, basal autophagy in neuronal cells in mice prevents neurodegeneration by suppressing the accumulation of abnormal intracellular proteins. However, it is not yet known whether autophagy genes play a role in vivo in protecting against disease caused by mutant aggregate-prone, expanded polyQ proteins. To examine this question, we used two models of polyQ-induced toxicity in C. elegans, including the expression of polyQ40 aggregates in muscle and the expression of a human huntingtin disease fragment containing a polyQ tract of 150 residues (Htn-Q150) in ASH sensory neurons. Here, we show that genetic inactivation of autophagy genes accelerates the accumulation of polyQ40 aggregates in C. elegans muscle cells and exacerbates polyQ40-induced muscle dysfunction. Autophagy gene inactivation also increases the accumulation of Htn-Q150 aggregates in C. elegans ASH sensory neurons and results in enhanced neurodegeneration. These data provide in vivo genetic evidence that autophagy genes suppress the accumulation of polyQ aggregates and protect cells from disease caused by polyQ toxicity.     

Destabilization of a non-pathological variant of ataxin-3 results in fibrillogenesis via a partially folded intermediate: a model for misfolding in polyglutamine disease

Ataxin-3 is a member of the polyglutamine family of proteins, which are associated with at least nine different neurodegenerative diseases. In the disease state, expansion of the polyglutamine tract leads to dysfunction and death of neurons, as well as formation of proteinaceous aggregates known as nuclear inclusions. Intriguingly, both expanded and non-expanded forms of ataxin-3 are observed within these nuclear inclusions. Ataxin-3 is the smallest of the polyglutamine disease proteins and in its expanded form causes the neurodegenerative disorder Machado-Joseph disease. Using a non-pathological variant containing 28 residues in its polyglutamine tract, we have probed the folding and misfolding pathways of ataxin-3. We describe here the first equilibrium folding pathway delineated for any polyglutamine protein and show that ataxin-3 folds reversibly via a single intermediate species. We have also explored further the misfolding potential of the protein and found that partial destabilization of ataxin-3 by chemical denaturation leads to the formation of fibrillar aggregates by the non-pathological variant. These results provide an insight into the possible mechanisms by which polyglutamine expansion may affect the stability and conformation of the protein. The implications of this are considered in the wider context of the development and pathogenesis of polyglutamine diseases.     

Autophagy Genes Protect Against Disease Caused by Polyglutamine Expansion Proteins in Caenorhabditis elegans

Expanded polyglutamine (polyQ) proteins aggregate intracellularly in Huntington’s disease and other neurodegenerative disorders. The lysosomal degradation pathway, autophagy, is known to promote clearance of polyQ protein aggregates in cultured cells. Moreover, basal autophagy in neuronal cells in mice prevents neurodegeneration by suppressing the accumulation of abnormal intracellular proteins. However, it is not yet known whether autophagy genes play a role in vivo in protecting against disease caused by mutant aggregate-prone, expanded polyQ proteins. To examine this question, we used two models of polyQ-induced toxicity in C. elegans, including the expression of polyQ40 aggregates in muscle and the expression of a human huntingtin disease fragment containing a polyQ tract of 150 residues (Htn-Q150) in ASH sensory neurons. Here, we show that genetic inactivation of autophagy genes accelerates the accumulation of polyQ40 aggregates in C. elegans muscle cells and exacerbates polyQ40-induced muscle dysfunction. Autophagy gene inactivation also increases the accumulation of Htn-Q150 aggregates in C. elegans ASH sensory neurons and results in enhanced neurodegeneration. These data provide in vivo genetic evidence that autophagy genes suppress the accumulation of polyQ aggregates and protect cells from disease caused by polyQ toxicity.     

Modulating huntingtin half-life alters polyglutamine-dependent aggregate formation and cell toxicity

A common finding among the expanded polyglutamine disorders is intracellular protein aggregates. Although the precise role of these aggregates in the disease process is unclear, they are generally ubiquitinated, implicating the ubiquitin-proteasome pathway in neuronal degeneration. To investigate the mechanism of aggregate formation, we have developed a cell culture model to express huntingtin designed to have an altered degradation rate through the ubiquitin-dependent N-end rule pathway. We fused the first 171 amino acids of huntingtin, containing either a pathogenic or normal polyglutamine tract, to the enhanced green fluorescent protein (EGFP). The half-life of soluble huntingtin-EGFP was dependent on the degradation signal and the polyglutamine tract length. However, once huntingtin-EGFP with a pathogenic tract had aggregated, the protein was extremely stable. Huntingtin-EGFP with a pathogenic glutamine tract and a shorter half-life displayed a delayed onset of aggregate formation and was more toxic to transfected cells. These data suggest that rapid clearance through the ubiquitin-proteasome pathway slows aggregate formation, yet increases cellular toxicity. Polyglutamine-induced neurotoxicity may therefore be triggered by non-aggregated protein, and aggregate formation itself may be a cellular defense mechanism.     

Critical role of the proline-rich region in Huntingtin for aggregation and cytotoxicity in yeast

Nine neurodegenerative diseases, such as Huntington, are caused by a polyglutamine (poly(Q)) expansion in otherwise unrelated proteins. Although poly(Q) expansion causes aggregation of the affected proteins, the protein context might determine the selective neuronal vulnerability found in each disease. Here we have report that, although expression of Huntingtin derivatives with a pathological poly(Q) expansion are innocuous in yeast, deletion of the flanking proline-rich region alters the shape and number of poly(Q) inclusions and unmasks toxic properties. Strikingly, deletion of Hsp104 increases the size of inclusions formed by expanded poly(Q) lacking the proline-rich region and abolishes toxicity. Overexpression of the chaperones Hsp104 or Hsp70 rescues growth defects in affected cells without resolving inclusions. However, aggregates formed by nontoxic Huntingtin derivatives or by toxic derivatives cured by chaperones are physically distinct from aggregates formed by toxic proteins. This study identifies the proline-rich region in Huntingtin as a profound cis-acting modulator of expanded poly(Q) toxicity and distinguishes between aggregates of toxic or non-toxic proteins.     

Reconsidering the mechanism of polyglutamine peptide aggregation

There are at least nine neurodegenerative diseases associated with proteins that contain an unusually expanded polyglutamine domain, the best known of which is Huntington's disease. In all of these diseases, the mutant protein aggregates into neuronal inclusions; it is generally, although not universally, believed that protein aggregation is an underlying cause of the observed neuronal degeneration. In an effort to examine the role of polyglutamine in facilitating protein aggregation, investigators have used synthetic polyglutamine peptides as model systems. Analysis of kinetic data led to the conclusions that aggregation follows a simple nucleation-elongation mechanism characterized by a significant lag time, during which the peptide is monomeric, and that the nucleus is a monomer in a thermodynamically unfavorable conformation [Chen, S. M., et al. (2002) Proc. Natl. Acad. Sci. U.S.A. 99, 11884-11889]. We re-examined this hypothesis by measuring the aggregation kinetics of the polyglutamine peptide K2Q23K2, using sedimentation, static and dynamic light scattering, and size exclusion chromatography. Our data show that during the lag time in sedimentation kinetics, there is substantial organization of the peptide into soluble linear aggregates. These aggregates have no regular secondary structure as measured by circular dichroism but have particle dimensions and morphologies similar to those of mature insoluble aggregates. The soluble aggregates constitute approximately 30% of the total peptide mass, form rapidly, and continue to grow over a period of hours to days, eventually precipitating. Once insoluble aggregates form, loss of monomer from the solution phase continues. Our data support an assembly mechanism for polyglutamine peptide more complex than that previously proposed.     

Circumvention of chaperone requirement for aggregate formation of a short polyglutamine tract by the co-expression of a long polyglutamine tract

Polyglutamine disease is now recognized as one of the conformational, amyloid-related diseases. In this disease, polyglutamine expansion in proteins has toxic effects on cells and also results in the formation of aggregates. Polyglutamine aggregate formation is accompanied by conversion of the polyglutamine from a soluble to an insoluble form. In yeast, the efficiency of the aggregate formation is determined by the balance of various parameters, including the length of the polyglutamine tract, the function of Hsp104, and the level of polyglutamine expression. In this study, we found that the co-expression of a long polyglutamine tract, which formed aggregates independently of the function of Hsp104, enhanced the formation of aggregates of a short polyglutamine tract in wild-type cells as well as in Deltahsp104 mutant cells. Thus, the expression of a long polyglutamine tract would be an additional parameter determining the efficiency of aggregate formation of a short polyglutamine tract. The co-localization of aggregates of long and short polyglutamine tracts suggests the possibility that the enhancement occurs due to the seeding of aggregates of the long polyglutamine tracts.     

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.     

Na+/H+ Exchangers Induce Autophagy in Neurons and Inhibit Polyglutamine-Induced Aggregate Formation

In polyglutamine diseases, an abnormally elongated polyglutamine results in protein misfolding and accumulation of intracellular aggregates. Autophagy is a major cellular degradative pathway responsible for eliminating unnecessary proteins, including polyglutamine aggregates. Basal autophagy constitutively occurs at low levels in cells for the performance of homeostatic function, but the regulatory mechanism for basal autophagy remains elusive. Here we show that the Na⁺/H⁺ exchanger (NHE) family of ion transporters affect autophagy in a neuron-like cell line (Neuro-2a cells). We showed that expression of NHE1 and NHE5 is correlated to polyglutamine accumulation levels in a cellular model of Huntington''s disease, a fatal neurodegenerative disorder characterized by accumulation of polyglutamine-containing aggregate formation in the brain. Furthermore, we showed that loss of NHE5 results in increased polyglutamine accumulation in an animal model of Huntington''s disease. Our data suggest that cellular pH regulation by NHE1 and NHE5 plays a role in regulating basal autophagy and thereby promotes autophagy-mediated degradation of proteins including polyglutamine aggregates.     

Rapamycin and mTOR-independent autophagy inducers ameliorate toxicity of polyglutamine-expanded huntingtin and related proteinopathies

The formation of intra-neuronal mutant protein aggregates is a characteristic of several human neurodegenerative disorders, like Alzheimer's disease, Parkinson's disease (PD) and polyglutamine disorders, including Huntington's disease (HD). Autophagy is a major clearance pathway for the removal of mutant huntingtin associated with HD, and many other disease-causing, cytoplasmic, aggregate-prone proteins. Autophagy is negatively regulated by the mammalian target of rapamycin (mTOR) and can be induced in all mammalian cell types by the mTOR inhibitor rapamycin. It can also be induced by a recently described cyclical mTOR-independent pathway, which has multiple drug targets, involving links between Ca(2+)-calpain-G(salpha) and cAMP-Epac-PLC-epsilon-IP(3) signalling. Both pathways enhance the clearance of mutant huntingtin fragments and attenuate polyglutamine toxicity in cell and animal models. The protective effects of rapamycin in vivo are autophagy-dependent. In Drosophila models of various diseases, the benefits of rapamycin are lost when the expression of different autophagy genes is reduced, implicating that its effects are not mediated by autophagy-independent processes (like mild translation suppression). Also, the mTOR-independent autophagy enhancers have no effects on mutant protein clearance in autophagy-deficient cells. In this review, we describe various drugs and pathways inducing autophagy, which may be potential therapeutic approaches for HD and related conditions.     

Ubiquilin overexpression reduces GFP-polyalanine-induced protein aggregates and toxicity

Several human disorders are associated with an increase in a continuous stretch of alanine amino acids in proteins. These so-called polyalanine expansion diseases share many similarities with polyglutamine-related disorders, including a length-dependent reiteration of amino acid induction of protein aggregation and cytotoxicity. We previously reported that overexpression of ubiquilin reduces protein aggregates and toxicity of expanded polyglutamine proteins. Here, we demonstrate a similar role for ubiquilin toward expanded polyalanine proteins. Overexpression of ubiquilin-1 in HeLa cells reduced protein aggregates and the cytotoxicity associated with expression of a transfected nuclear-targeted GFP-fusion protein containing 37-alanine repeats (GFP-A37), in a dose dependent manner. Ubiquilin coimmunoprecipitated more with GFP proteins containing a 37-polyalanine tract compared to either 7 (GFP-A7), or no alanine tract (GFP). Moreover, overexpression of ubiquilin suppressed the increased vulnerability of HeLa cell lines stably expressing the GFP-A37 fusion protein to oxidative stress-induced cell death compared to cell lines expressing GFP or GFP-A7 proteins. By contrast, siRNA knockdown of ubiquilin expression in the GFP-A37 cell line was associated with decreased cellular proliferation, and increases in GFP protein aggregates, nuclear fragmentation, and cell death. Our results suggest that boosting ubiquilin levels in cells might provide a universal and attractive strategy to prevent toxicity of proteins containing reiterative expansions of amino acids involved in many human diseases.     

Stochastic kinetics of intracellular huntingtin aggregate formation

Neurodegeneration in Huntington disease is described by neuronal loss in which the probability of cell death remains constant with time. However, the quantitative connection between the kinetics of cell death and the molecular mechanism initiating neurodegeneration remains unclear. One hypothesis is that nucleation of protein aggregates containing exon I fragments of the mutant huntingtin protein (mhttex1), which contains an expanded polyglutamine region in patients with the disease, is the explanation for the infrequent but steady occurrence of neuronal death, resulting in adult onset of the disease. Recent in vitro evidence suggests that sufficiently long polyglutamine peptides undergo a unimolecular conformational change to form a nucleus that seeds aggregation. Here we use this nucleation mechanism as the basis to derive a stochastic mathematical model describing the probability of aggregate formation in cells as a function of time and mhttex1 protein concentration, and validate the model experimentally. These findings suggest that therapeutic strategies for Huntington disease predicated on reducing the rate of mhttex1 aggregation need only make modest reductions in huntingtin expression level to substantially increase the delay time until aggregate formation.