EC:3.4.25.1 - FACTA Search

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Query: EC:3.4.25.1 (proteasome)
28,817 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Huntington's disease can be used as a model to study neurodegenerative disorders caused by aggregation-prone proteins. It has been proposed that the entrapment of transcription factors in aggregates plays an important role in pathogenesis. We now report that the transcriptional activity of CBP is already repressed in the early time points by soluble mutant huntingtin, whereas the histone acetylase activity of CBP/p300 is gradually diminished over time. Mutant huntingtin bound much stronger to CBP than normal huntingtin, possibly contributing to repression. Especially at the later time points, CBP protein level was gradually reduced via the proteasome pathway. In sharp contrast, p300 was unaffected by mutant huntingtin. This selective degradation of CBP was absent in spinocerebellar ataxia 3. Thus, mutant huntingtin specifically affects CBP and not p300 both at the early and later time points, via multiple mechanisms. In addition to the reduction of CBP, also the altered ratio of these closely related histone acetyltransferases may affect chromatin structure and transcription and thus contribute to neurodegeneration.
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PMID:Mutant huntingtin represses CBP, but not p300, by binding and protein degradation. 1645 24

Many major neurodegenerative diseases, including Amyotrophic Lateral Sclerosis, Alzheimer's disease, Parkinson's disease, Huntington Disease and other polyglutamine expansion disorders, are associated with degeneration and death of specific neuronal populations due to accumulation of certain abnormal polypeptides. These misfolded species aggregate and form inclusion bodies and their neurotoxicity is associated with the aggregation. To handle a build-up of abnormal proteins cells employ a complicated machinery of molecular chaperones and various proteolytic systems. Chaperones facilitate refolding or degradation of misfolded polypeptides, prevent protein aggregation and play a role in formation of aggresome, a centrosome-associated body to which small cytoplasmic aggregates are transported. The ubiquitin-proteasome proteolytic system is critical for reducing the levels of soluble abnormal proteins, while autophagy plays the major role in clearing of cells from protein aggregates. Accumulation of the aggregation prone proteins activates signal transduction pathways that control cell death, including JNK pathway that controls viability of a cell in various models of Parkinson's and Huntington's diseases. The major chaperone Hsp72 can interfere with this signalling pathway, thus promoting survival. A very important consequence of a build-up and aggregation of misfolded proteins is impairment of the ubiquitin-proteasome degradation system and suppression of the heat shock response. Such an inhibition of the major cell defense systems may play a critical role in neurodegeneration. Here, it is suggested that these changes may reflect a senescence-like programme initiated by the aggregated abnormal polypeptides. Pathways that control the fate of misfolded proteins, for example molecular chaperones or proteolytic systems, may become interesting novel targets for therapy of neurodegenerative disorders.
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PMID:Role of molecular chaperones in neurodegenerative disorders. 1604 38

Huntington's disease (HD) and other polyglutamine (polyQ) neurodegenerative diseases are characterized by neuronal accumulation of the disease protein, suggesting that the cellular ability to handle abnormal proteins is compromised. As both a cochaperone and ubiquitin ligase, the C-terminal Hsp70 (heat shock protein 70)-interacting protein (CHIP) links the two major arms of protein quality control, molecular chaperones, and the ubiquitin-proteasome system. Here, we demonstrate that CHIP suppresses polyQ aggregation and toxicity in transfected cell lines, primary neurons, and a novel zebrafish model of disease. Suppression by CHIP requires its cochaperone function, suggesting that CHIP acts to facilitate the solubility of mutant polyQ proteins through its interactions with chaperones. Conversely, HD transgenic mice that are haploinsufficient for CHIP display a markedly accelerated disease phenotype. We conclude that CHIP is a critical mediator of the neuronal response to misfolded polyQ protein and represents a potential therapeutic target in this important class of neurodegenerative diseases.
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PMID:CHIP suppresses polyglutamine aggregation and toxicity in vitro and in vivo. 1620 74

It is increasingly appreciated that failures in the ubiquitin-proteasome system play a pivotal role in the neuropathogenesis of many neurological disorders. This system, involved in protein quality control, should degrade misfolded proteins, but apparently during neuropathogenesis, it is unable to cope with a number of proteins that, by themselves, can consequently accumulate. Ubiquitin is essential for ATP-dependent protein degradation by the proteasome. Ubiquitin+1 (UBB+1) is generated by a dinucleotide deletion (DeltaGU) in UBB mRNA. The aberrant protein has a 19 amino acid extension and has lost the ability to ubiquitinate. Instead of targeting proteins for degradation, it has acquired a dual substrate-inhibitor function; ubiquitinated UBB+1 is a substrate for proteasomal degradation, but can at higher concentrations inhibit, proteasomal degradation. Furthermore, UBB+1 protein accumulates in neurons and glial cells in a disease-specific way, and this event is an indication for proteasomal dysfunction. Many neurological and non-neurological conformational diseases have the accumulation of misfolded proteins and of UBB+1 in common, and this combined accumulation results in the promotion of insoluble protein deposits and neuronal cell death as shown in a cellular model of Huntington's disease.
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PMID:Conformational diseases: an umbrella for various neurological disorders with an impaired ubiquitin-proteasome system. 1622 48

The main histopathological feature of Huntington's disease (HD) is the presence of protein aggregates that are gathered into inclusion bodies. So far the mechanisms that lead to inclusion formation as well as their role in the pathogenesis of HD are not totally understood. However, it is well established that inclusion bodies contain components of the ubiquitin-proteasome system. Accordingly, it has been postulated that impairment of this machinery can be one of the causes of this disorder. In this review, the authors summarize the state of current knowledge about this hypothesis.
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PMID:The ubiquitin-proteasome system in Huntington's disease. 1628 99

Huntington's disease (HD) is one of a group of neurodegenerative disorders caused by the pathological expansion of a glutamine tract. A hallmark of these so-called polyglutamine diseases is the presence of ubiquitylated inclusion bodies, which sequester various components of the 19S and 20S proteasomes. In addition, the ubiquitin-proteasome system (UPS) has been shown to be severely impaired in vitro in cells overexpressing mutant huntingtin. Thus, because of its fundamental housekeeping function, impairment of the UPS in neurons could contribute to neurotoxicity. We have recently proposed that the proteasome activator REGgamma could contribute to UPS impairment in polyglutamine diseases by suppressing the proteasomal catalytic sites responsible for cleaving Gln-Gln bonds. Capping of proteasomes with REGgamma could therefore contribute to a potential 'clogging' of the proteasome by pathogenic polyglutamines. We show here that genetic reduction of REGgamma has no effect on the well-defined neurological phenotype of R6/2 HD mice and does not affect inclusion body formation in the R6/2 brain. Surprisingly, we observe increased proteasomal 'chymotrypsin-like' activity in 13-week-old R6/2 brains relative to non-R6/2, irrespective of REGgamma levels. However, assays of 26S proteasome activity in mouse brain extracts reveal no difference in proteolytic activity regardless of R6/2 or REGgamma genotype. These findings suggest that REGgamma is not a viable therapeutic target in polyglutamine disease and that overall proteasome function is not impaired by trapped mutant polyglutamine in R6/2 mice.
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PMID:Proteasome impairment does not contribute to pathogenesis in R6/2 Huntington's disease mice: exclusion of proteasome activator REGgamma as a therapeutic target. 1631 Dec 53

Protein conformational diseases, such as Alzheimer's, Parkinson's and Huntington's, affect a large portion of our aging population. Cells have evolved mechanisms for rescuing and recycling misfolded proteins, but these systems are not perfect. Chaperones can rescue misfolded proteins by breaking up aggregates and assisting in the refolding process. Proteins that cannot be rescued by refolding can be delivered to the proteasome by chaperones to be recycled. One class of 'misfolded' proteins, prions, appears to evade detection by this machinery and persist in a misfolded state. In fact, it seems that the prions usurp the refolding machinery and actually employ chaperones to propagate the prion state. Recent data has begun to uncover the mechanism behind this unique relationship.
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PMID:The battle of the fold: chaperones take on prions. 1637 56

Huntington's disease can be used as a model to study neurodegenerative disorders caused by aggregation-prone proteins. It has been proposed that the entrapment of transcription factors in aggregates plays an important role in pathogenesis. We now report that the transcriptional activity of CBP is already repressed in the early time points by soluble mutant huntingtin, whereas the histone acetylase activity of CBP/p300 is gradually diminished over time. Mutant huntingtin bound much stronger to CBP than normal huntingtin, possibly contributing to repression. Especially at the later time points, CBP protein level was gradually reduced via the proteasome pathway. In sharp contrast, p300 was unaffected by mutant huntingtin. This selective degradation of CBP was absent in spinocerebellar ataxia 3. Thus, mutant huntingtin specifically affects CBP and not p300 both at the early and later time points, via multiple mechanisms. In addition to the reduction of CBP, also the altered ratio of these closely related histone acetyl transferases may affect chromatin structure and transcription and thus contribute to neurodegeneration.
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PMID:Mutant huntingtin represses CBP, but not p300, by binding and protein degradation. 1599 95

Protein aggregation is a prominent feature of many neurodegenerative diseases, such as Alzheimer's, Huntington's, and Parkinson's diseases, as well as spongiform encephalopathies and systemic amyloidoses. These diseases are sometimes called protein misfolding diseases, but the latter term begs the question of what is the "folded" state of proteins for which normal structure and function are unknown. Amyloid consists of linear, unbranched protein or peptide fibrils of approximately 100 A diameter. These fibrils are composed of a wide variety of proteins that have no sequence homology, and no similarity in three-dimensional structures--and yet, as fibrils, they share a common secondary structure, the beta-sheet. Because of the prominence of amyloid deposits in many of these diseases, much effort has gone into elucidation of fibril structure. Recent advances in solid-state NMR spectroscopy and other biophysical techniques have led to the partial elucidation of fibril structure. Surprisingly at the time, for beta-amyloid, a set of 39-43-amino-acid peptides believed to play a pathogenic role in Alzheimer's disease, the beta-sheets are parallel with all amino acids of the sheets in-register. Since the time of those observations, however, it has become clear that there is no universal structure for amyloid fibrils. While many of the amyloid fibrils described thus far have a parallel beta-sheet structure, some have antiparallel beta-sheets, and other, more subtle structural differences among amyloids exist as well. Amyloids demonstrate conformational plasticity, the ability to adopt more than one stable tertiary fold. Conformational plasticity could account for "strain" differences in prions, and for the fact that a single polypeptide can form different fibril types with conformational differences at the atomic level. More recent data now indicate that the fibrils may not be the most potent or proximate mediators of cyto- and neurotoxicity. This damage is not confined to cell death, but also includes more subtle forms of damage, such as disruption of synaptic plasticity in the central nervous system. Rather than fibrils, prefibrillar aggregates, variously called "micelles," "protofibrils," or ADDLs (beta-amyloid-derived diffusible ligands in the case of beta-amyloid) may be the more proximate mediators of cell damage. These are soluble oligomers of aggregating peptides or proteins, but their structure is very challenging to study, because they are generally difficult to obtain in large enough quantities for high-resolution structural techniques, and they are temporally unstable, rapidly changing into more mature, and eventually fibrillar forms. Consequently, the mechanisms by which they disrupt cellular function are also not well understood. Nevertheless, three broad, overlapping, nonexclusive sets of mechanisms have been proposed as responsible for the cellular damage caused by soluble, oligomeric protein aggregates. These are: (1) disruption of cell membranes and their functions [e.g., by inserting into membranes and disrupting normal ion gradients]; (2) inactivation of normally folded, functional proteins [e.g., by sequestering or localizing transcription factors to the wrong cellular compartment]; and (3) "gumming up the works," by binding to and inactivating components of the quality-control system of cells, such as the proteasome or chaperone proteins.
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PMID:Protein denaturation and aggregation: Cellular responses to denatured and aggregated proteins. 1653 27

Misfolded proteins accumulate in many neurodegenerative diseases, including huntingtin in Huntington's disease and alpha-synuclein in Parkinson's disease. The disease-causing proteins can take various conformations and are prone to aggregate and form larger cytoplasmic or nuclear inclusions. One approach to the development of therapeutic intervention for these diseases has been to identify chemical compounds that reduce the size or number of inclusions. We have, however, identified a compound that promotes inclusion formation in cellular models of both Huntington's disease and Parkinson's disease. Of particular interest, this compound prevents huntingtin-mediated proteasome dysfunction and reduces alpha-synuclein-mediated toxicity. These results demonstrate that compounds that increase inclusion formation may actually lessen cellular pathology in both Huntington's and Parkinson's diseases, suggesting a therapeutic approach for neurodegenerative diseases caused by protein misfolding.
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PMID:Pharmacological promotion of inclusion formation: a therapeutic approach for Huntington's and Parkinson's diseases. 1653 16

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