Identifying polyglutamine protein species in situ that best predict neurodegeneration

Polyglutamine (polyQ) stretches exceeding a threshold length confer a toxic function to proteins that contain them and cause at least nine neurological disorders. The basis for this toxicity threshold is unclear. Although polyQ expansions render proteins prone to aggregate into inclusion bodies, this may be a neuronal coping response to more toxic forms of polyQ. The exact structure of these more toxic forms is unknown. Here we show that the monoclonal antibody 3B5H10 recognizes a species of polyQ protein in situ that strongly predicts neuronal death. The epitope selectively appears among some of the many low-molecular-weight conformational states assumed by expanded polyQ and disappears in higher-molecular-weight aggregated forms, such as inclusion bodies. These results suggest that protein monomers and possibly small oligomers containing expanded polyQ stretches can adopt a conformation that is recognized by 3B5H10 and is toxic or closely related to a toxic species.     

Surface plasmon resonance characterization of specific binding of polyglutamine aggregation inhibitors to the expanded polyglutamine stretch

Proteins with an abnormally expanded polyglutamine (polyQ) stretch are prone to change their conformations, leading to their aggregation, and cause inherited neurodegenerative diseases called the polyQ diseases. Although screening for polyQ aggregation inhibitors has been extensively performed, many common false-positive hits have been identified so far. In this study, we employed surface plasmon resonance (SPR) to characterize the binding specificities and affinities of polyQ aggregation inhibitors to the expanded polyQ stretch. SPR successfully detected specific binding of polyQ binding peptide 1 (QBP1) to the expanded polyQ stretch (K_d = 5.7 μM), and non-specific binding of Congo red to polyQ proteins independent of their polyQ-length. Binding affinities of polyQ aggregation inhibitors to the expanded polyQ stretch were correlated with their inhibitory effects on polyQ aggregation. We therefore conclude that SPR is a useful technique for screening for specific polyQ aggregation inhibitors as promising therapeutic candidates for the currently untreatable polyQ diseases.     

Evolution and function of CAG/polyglutamine repeats in protein-protein interaction networks

Expanded runs of consecutive trinucleotide CAG repeats encoding polyglutamine (polyQ) stretches are observed in the genes of a large number of patients with different genetic diseases such as Huntington's and several Ataxias. Protein aggregation, which is a key feature of most of these diseases, is thought to be triggered by these expanded polyQ sequences in disease-related proteins. However, polyQ tracts are a normal feature of many human proteins, suggesting that they have an important cellular function. To clarify the potential function of polyQ repeats in biological systems, we systematically analyzed available information stored in sequence and protein interaction databases. By integrating genomic, phylogenetic, protein interaction network and functional information, we obtained evidence that polyQ tracts in proteins stabilize protein interactions. This happens most likely through structural changes whereby the polyQ sequence extends a neighboring coiled-coil region to facilitate its interaction with a coiled-coil region in another protein. Alteration of this important biological function due to polyQ expansion results in gain of abnormal interactions, leading to pathological effects like protein aggregation. Our analyses suggest that research on polyQ proteins should shift focus from expanded polyQ proteins into the characterization of the influence of the wild-type polyQ on protein interactions.     

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.     

Androgen-dependent neurodegeneration by polyglutamine-expanded human androgen receptor in Drosophila

Spinal and bulbar muscular atrophy (SBMA) is an X-linked, adult-onset, neurodegenerative disorder affecting only males and is caused by expanded polyglutamine (polyQ) stretches in the N-terminal A/B domain of human androgen receptor (hAR). Although no overt phenotype was detected in adult fly eye photoreceptor neurons expressing mutant hAR (polyQ 52), ingestion of androgen or its known antagonists caused marked neurodegeneration with nuclear localization and structural alteration of the hAR mutant. Ligand-independent toxicity was detected with a truncated polyQ-expanded A/B domain alone, which was attenuated with cytosolic trapping by coexpression of the unliganded hAR E/F ligand binding domain. Thus, our findings suggest that the full binding of androgen to the polyQ-expanded hAR mutants leads to structural alteration with nuclear translocation that eventually results in the onset of SBMA in male patients.     

Disease-associated polyglutamine stretches in monomeric huntingtin adopt a compact structure

Abnormal polyglutamine (polyQ) tracts are the only common feature in nine proteins that each cause a dominant neurodegenerative disorder. In Huntington's disease, tracts longer than 36 glutamines in the protein huntingtin (htt) cause degeneration. In situ, monoclonal antibody 3B5H10 binds to different htt fragments in neurons in proportion to their toxicity. Here, we determined the structure of 3B5H10 Fab to 1.9?? resolution by X-ray crystallography. Modeling demonstrates that the paratope forms a groove suitable for binding two β-rich polyQ strands. Using small-angle X-ray scattering, we confirmed that the polyQ epitope recognized by 3B5H10 is a compact two-stranded hairpin within monomeric htt and is abundant in htt fragments unbound to antibody. Thus, disease-associated polyQ stretches preferentially adopt compact conformations. Since 3B5H10 binding predicts degeneration, this compact polyQ structure may be neurotoxic.     

A novel GTPase, CRAG, mediates promyelocytic leukemia protein-associated nuclear body formation and degradation of expanded polyglutamine protein

Polyglutamine diseases are inherited neurodegenerative diseases caused by the expanded polyglutamine proteins (polyQs). We have identified a novel guanosine triphosphatase (GTPase) named CRAG that contains a nuclear localization signal (NLS) sequence and forms nuclear inclusions in response to stress. After ultraviolet irradiation, CRAG interacted with and induced an enlarged ring-like structure of promyelocytic leukemia protein (PML) body in a GTPase-dependent manner. Reactive oxygen species (ROS) generated by polyQ accumulation triggered the association of CRAG with polyQ and the nuclear translocation of the CRAG-polyQ complex. Furthermore, CRAG promoted the degradation of polyQ at PML/CRAG bodies through the ubiquitin-proteasome pathway. CRAG knockdown by small interfering RNA in neuronal cells consistently blocked the nuclear translocation of polyQ and enhanced polyQ-mediated cell death. We propose that CRAG is a modulator of PML function and dynamics in ROS signaling and is protectively involved in the pathogenesis of polyglutamine diseases.     

The structural impact of a polyglutamine tract is location-dependent

Polyglutamine (polyQ) expansion leads to protein aggregation and neurodegeneration in Huntington's disease and eight other inherited neurological conditions. Expansion of the polyQ tract beyond a threshold of 37 glutamines leads to the formation of toxic nuclear aggregates. This suggests that polyQ expansion causes a conformational change within the protein, the nature of which is unclear. There is a trend in the disease proteins that the polyQ tract is located external to but not within a structured domain. We have created a model polyQ protein in which the repeat location mimics the flexible environment of the polyQ tract in the disease proteins. Our model protein recapitulates the aggregation features observed with the clinical proteins and allows structural characterization. With the use of NMR spectroscopy and a range of biophysical techniques, we demonstrate that polyQ expansion into the pathological range has no effect on the structure, dynamics, and stability of a domain adjacent to the polyQ tract. To explore the clinical significance of repeat location, we engineered a variant of the model protein with a polyQ tract within the domain, a location that does not mimic physiological context, demonstrating significant destabilization and structural perturbation. These different effects highlight the importance of repeat location. We conclude that protein misfolding within the polyQ tract itself is the driving force behind the key characteristics of polyQ disease, and that structural perturbation of flanking domains is not required.     

Solution structure of polyglutamine tracts in GST-polyglutamine fusion proteins

Aggregation of expanded polyglutamine (polyQ) seems to be the cause of various genetic neurodegenerative diseases. Relatively little is known as yet about the polyQ structure and the mechanism that induces aggregation. We have characterised the solution structure of polyQ in a proteic context using a model system based on glutathione S-transferase fusion proteins. A wide range of biophysical techniques was applied. For the first time, nuclear magnetic resonance was used to observe directly and selectively the conformation of polyQ in the pathological range. We demonstrate that, in solution, polyQs are in a random coil conformation. However, under destabilising conditions, their aggregation behaviour is determined by the polyQ length.     

Monitoring polyglutamine toxicity in yeast

Experiments in yeast have significantly contributed to our understanding of general aspects of biochemistry, genetics, and cell biology. Yeast models have also delivered deep insights in to the molecular mechanism underpinning human diseases, including neurodegenerative diseases. Many neurodegenerative diseases are associated with the conversion of a protein from a normal and benign conformation into a disease-associated and toxic conformation - a process called protein misfolding. The misfolding of proteins with abnormally expanded polyglutamine (polyQ) regions causes several neurodegenerative diseases, such as Huntington's disease and the Spinocerebellar Ataxias. Yeast cells expressing polyQ expansion proteins recapitulate polyQ length-dependent aggregation and toxicity, which are hallmarks of all polyQ-expansion diseases. The identification of modifiers of polyQ toxicity in yeast revealed molecular mechanisms and cellular pathways that contribute to polyQ toxicity. Notably, several of these findings in yeast were reproduced in other model organisms and in human patients, indicating the validity of the yeast polyQ model. Here, we describe different expression systems for polyQ-expansion proteins in yeast and we outline experimental protocols to reliably and quantitatively monitor polyQ toxicity in yeast.     

Quantitative connection between polyglutamine aggregation kinetics and neurodegenerative process in patients with Huntington's disease

ABSTRACT: BACKGROUND: Despite enormous progress in elucidating the biophysics of aggregation, no cause-and-effect relationship between protein aggregation and neurodegenerative disease has been unequivocally established. Here, we derived several risk-based stochastic kinetic models that assess genotype/phenotype correlations in patients with Huntington's disease (HD) caused by the expansion of a CAG repeat. Fascinating disease-specific aspects of HD include the polyglutamine (polyQ)-length dependence of both age at symptoms onset and the propensity of the expanded polyQ protein to aggregate. In vitro, aggregation of polyQ peptides follows a simple nucleated growth polymerization pathway. Our models that reflect polyQ aggregation kinetics in a nucleated growth polymerization divided aggregate process into the lengthdependent nucleation and the nucleation-dependent elongation. In contrast to the repeatlength dependent variability of age at onset, recent studies have shown that the extent of expansion has only a subtle effect on the rate of disease progression, suggesting possible differences in the mechanisms underlying the neurodegenerative process. RESULTS: Using polyQ-length as an index, these procedures enabled us for the first time to establish a quantitative connection between aggregation kinetics and disease process, including onset and the rate of progression. Although the complexity of disease process in HD, the time course of striatal neurodegeneration can be precisely predicted by the mathematical model in which neurodegeneration occurs by different mechanisms for the initiation and progression of disease processes. Nucleation is sufficient to initiate neuronal loss as a series of random events in time. The stochastic appearance of nucleation in a cell population acts as the constant risk of neuronal cell damage over time, while elongation reduces the risk by nucleation in proportion to the increased extent of the aggregates during disease progression. CONCLUSIONS: Our findings suggest that nucleation is a critical step in gaining toxic effects to the cell, and provide a new insight into the relationship between polyQ aggregation and neurodegenerative process in HD.     

A toxic monomeric conformer of the polyglutamine protein

Polyglutamine (polyQ) diseases are classified as conformational neurodegenerative diseases, like Alzheimer and Parkinson diseases, and they are caused by proteins with an abnormally expanded polyQ stretch. However, conformational changes of the expanded polyQ protein and the toxic conformers formed during aggregation have remained poorly understood despite their important role in pathogenesis. Here we show that a beta-sheet conformational transition of the expanded polyQ protein monomer precedes its assembly into beta-sheet-rich amyloid-like fibrils. Microinjection of the various polyQ protein conformers into cultured cells revealed that the soluble beta-sheet monomer causes cytotoxicity. The polyQ-binding peptide QBP1 prevents the toxic beta-sheet conformational transition of the expanded polyQ protein monomer. We conclude that the toxic conformational transition, and not simply the aggregation process itself, is a therapeutic target for polyQ diseases and possibly for conformational diseases in general.     

The structure of a polyQ-anti-polyQ complex reveals binding according to a linear lattice model

Huntington and related neurological diseases result from expansion of a polyglutamine (polyQ) tract. The linear lattice model for the structure and binding properties of polyQ proposes that both expanded and normal polyQ tracts in the preaggregation state are random-coil structures but that an expanded polyQ repeat contains a larger number of epitopes recognized by antibodies or other proteins. The crystal structure of polyQ bound to MW1, an antibody against polyQ, reveals that polyQ adopts an extended, coil-like structure. Consistent with the linear lattice model, multimeric MW1 Fvs bind more tightly to longer than to shorter polyQ tracts and, compared with monomeric Fv, bind expanded polyQ repeats with higher apparent affinities. These results suggest a mechanism for the toxicity of expanded polyQ and a strategy to link anti-polyQ compounds to create high-avidity therapeutics.