Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Newly synthesized proteins in the living cell must go through a folding process to attain their functional structure. To achieve this in an efficient fashion, all organisms, including humans, have evolved a large set of molecular chaperones that assist the folding as well as the maintenance of the functional structure of cellular proteins. Aberrant proteins, the result of production errors, inherited or acquired amino acid substitutions or damage, especially oxidative modifications, can in many cases not fold correctly and will be trapped in misfolded conformations. To rid the cell of misfolded proteins, the living cell contains a large number of intracellular proteases, e.g. the proteasome, which together with the chaperones comprise the cellular protein quality control systems. Many inherited disorders due to amino acid substitutions exhibit loss-of-function pathogenesis because the aberrant protein is eliminated by one of the protein quality control systems. Examples are cystic fibrosis and phenylketonuria. However, not all aberrant proteins can be eliminated and the misfolded protein may accumulate and form toxic oligomeric and/or aggregated inclusions. In this case the loss of function may be accompanied by a gain-of-function pathogenesis, which in many cases determines the pathological and clinical features. Examples are Parkinson and Huntington diseases. Although a number of strategies have been tried to decrease the amounts of accumulated and aggregated proteins, a likely future strategy seems to be the use of chemical or pharmacological chaperones with specific effects on the misfolded protein in question. Positive examples are enzyme enhancement in a number of lysosomal disorders.
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PMID:Protein misfolding disorders: pathogenesis and intervention. 1676 18

In Huntington's disease (HD), as in the rest of CAG triplet-repeat disorders, the expanded polyglutamine (polyQ)-containing proteins form intraneuronal fibrillar aggregates that are gathered into inclusion bodies (IBs). Since IBs contain ubiquitin and proteasome subunits, it was proposed that inhibition of proteasome activity might underlie pathogenesis of polyQ disorders. Recent in vitro enzymatic studies revealed the inability of eukaryotic proteasomes to digest expanded polyQ, thus suggesting that occasional failure of polyQ to exit the proteasome may interfere with its proteolytic function. However, it has also recently been found that in vitro assembled aggregates made of synthetic polyQ fail to inhibit proteasome activity. Because synthetic polyQ aggregates lack the post-translational modifications found inside affected neurons, such as poly ubiquitylation, we decided to study the effect of mutant huntingtin (htt) aggregates isolated from the Tet/HD94 mouse model and from human HD brain tissue. Here, we show that isolated ubiquitylated filamentous htt aggregates, extracted from IBs by a previously reported method, selectively inhibited the in vitro peptidase activity of the 26S but not of the 20S proteasome in a non-competitive manner. In good agreement, immuno-electron microscopy revealed a direct interaction of htt filaments with the 19S ubiquitin-interacting regulatory caps of the 26S proteasome. Here, we also report a new method for isolation of IBs based on magnetic sorting. Interestingly, isolated IBs did not modify proteasome activity. Our results therefore show that mutant htt filamentous aggregates can inhibit proteasome activity, but only when not recruited into IBs, thus strengthening the notion that IB formation is protective by neutralizing toxicity of dispersed filamentous htt aggregates.
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PMID:Inhibition of 26S proteasome activity by huntingtin filaments but not inclusion bodies isolated from mouse and human brain. 1678 6

Ubiquitinated protein aggregates are observed in the brains of Alzheimer's, Parkinson's and Huntington's disease patients and in other neurodegenerative disorders. These aggregates indicate that the ubiquitin proteasome system may be impaired in these diseases. To date no therapy is available that specifically targets this system, although preventing aggregate formation or stimulating the degradation of already formed aggregates by targeting components of the ubiquitin proteasome system is an attractive therapeutic approach. Here, we review the role of the ubiquitin proteasome system in aggregate formation with respect to neurodegenerative diseases, discussing the unfolded protein response, endoplasmic reticulum-associated degradation, aggresome formation and accumulation as well as aggregation and neurotoxicity of proteins involved in neurodegeneration. The potential of pharmacological intervention within this system in patients suffering from neurodegenerative diseases will be evaluated.
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PMID:Ubiquitin proteasome system as a pharmacological target in neurodegeneration. 1700 21

Many late-onset neurodegenerative diseases, including Parkinson's disease and Huntington's disease, are associated with the formation of intracellular aggregates by toxic proteins. It is therefore crucial to understand the factors that regulate the steady-state levels of these 'toxins', at both the synthetic and degradation stages. The degradation pathways acting on such aggregate-prone cytosolic proteins include the ubiquitin-proteasome system and macroautophagy. Dysfunction of the ubiquitin-proteasome or macroautophagy pathways might contribute to the pathology of various neurodegenerative conditions. However, enhancing macroautophagy with drugs such as rapamycin could offer a tractable therapeutic strategy for a number of these diseases.
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PMID:The roles of intracellular protein-degradation pathways in neurodegeneration. 1705 Dec 4

Neuronal homoeostasis requires a constant balance between biosynthetic and catabolic processes. Eukaryotic cells primarily use two distinct mechanisms for degradation: the proteasome and autophagy of aggregates by the lysosomes. We focused on the UPS (ubiquitin-proteasome system). As a result of molecular misreading, misframed UBB (ubiquitin B) (UBB+1) is generated. UBB+1 accumulates in the neuritic plaques and neurofibrillary tangles in all patients with AD (Alzheimer's disease) and in the neuronal and glial hallmarks of other tauopathies and in polyglutamine diseases such as Huntington's disease. UBB+1 is not present in synucleinopathies such as Parkinson's disease. We showed that UBB+1 causes UPS dysfunction, aggregation and apoptotic cell death. UBB+1 is also present in non-neurological cells, hepatocytes of the diseased liver and in muscles during inclusion body myositis. Other frequently occurring (age-related) diseases such as Type 2 (non-insulin-dependent) diabetes mellitus are currently under investigation. These findings point to the importance of the UPS in diseases and open new avenues for target identification of the main players of the UPS. Treatment of these diseases with tools (e.g. viral RNA interference constructs) to intervene with specific targets is the next step.
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PMID:Molecular misreading: the occurrence of frameshift proteins in different diseases. 1705 86

Polyglutamine diseases are characterized by neuronal intranuclear inclusions of expanded polyglutamine proteins, which are also ubiquitinated, indicating impairment of the ubiquitin-proteasome system. E2-25K (Hip2), an ubiquitin-conjugating enzyme, interacts directly with huntingtin and may mediate ubiquitination of the neuronal intranuclear inclusions in Huntington disease. E2-25K could thus modulate aggregation and toxicity of expanded huntingtin. Here we show that E2-25K is involved in aggregate formation of expanded polyglutamine proteins and polyglutamine-induced cell death. Both a truncated mutant, lacking the catalytic tail domain, as well as a full antisense sequence, reduce aggregate formation. Strikingly, both E2-25K mutants also reduced polyglutamine-induced cell death. In postmortem brain material of both Huntington disease and SCA3, E2-25K staining of polyglutamine aggregates was observed in a subset of neurons bearing intranuclear neuronal inclusions. These results demonstrate that targeting by ubiquitination plays an important role in the pathology of polyglutamine diseases.
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PMID:Ubiquitin-conjugating enzyme E2-25K increases aggregate formation and cell death in polyglutamine diseases. 1709 42

The accumulation of oxidized proteins is known to be linked to some severe neurodegenerative diseases like Alzheimer's, Parkinson's and Huntington's disease. Furthermore, the aging process is also accompanied by an ongoing aggregation of misfolded and damaged proteins. Therefore, mammalian cells have developed potent degradation systems, which selectively degrade damaged and misfolded proteins. The proteasomal system is largely responsible for the removal of oxidatively damaged proteins form the cellular environment. Not only cytosolic proteins are prone to oxidative stress, also nuclear proteins are readily oxidized. The nuclear proteasomal system is responsible for the degradation of these proteins. This review is focused on the specific degradation of oxidized nuclear proteins, the role of the proteasome in this process and the regulation of the nuclear proteasomal system under oxidative conditions.
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PMID:The nuclear proteasome and the degradation of oxidatively damaged proteins. 1710 19

Intracellular protein misfolding/aggregation are features of many late-onset neurodegenerative diseases, called proteinopathies. These include Alzheimer's disease, Parkinson's disease, tauopathies, and polyglutamine expansion diseases [e.g., Huntington's disease; and various spinocerebellar ataxias (SCAs), like SCA3]. There are no effective strategies to slow or prevent the neurodegeneration resulting from these diseases in humans. The mutations causing many proteinopathies (e.g., polyglutamine diseases and tauopathies) confer novel toxic functions on the specific protein, and disease severity frequently correlates with the expression levels of the protein. Thus, the factors regulating the synthesis and clearance of these aggregate-prone proteins are putative therapeutic targets. The proteasome and autophagy-lysosomal pathways are the major routes for mutant huntingtin fragment clearance. While the narrow proteasome barrel precludes entry of oligomers/aggregates of mutant huntingtin (or other aggregate-prone intracellular proteins), such substrates can be degraded by macroautophagy (which we will call autophagy). We showed that the autophagy inducer rapamycin reduced the levels of soluble and aggregated huntingtin and attenuated its toxicity in cells, and in transgenic Drosophila and mouse models. We extended the range of intracellular proteinopathy substrates that are cleared by autophagy to a wide range of other targets, including proteins mutated in certain SCAs, forms of alpha-synuclein mutated in familial forms of Parkinson's disease, and tau mutants that cause frontotemporal dementia/tauopathy. In this chapter, we consider the therapeutic potential of autophagy upregulation for various proteinopathies, and describe how this strategy may act both by removing the primary toxin (the misfolded/aggregate-prone protein) and by reducing susceptibility to apoptotic insults.
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PMID:Aggregate-prone proteins are cleared from the cytosol by autophagy: therapeutic implications. 1711 64

The histological hallmark feature of Huntington's disease (HD) and other polyglutamine repeat diseases is the presence of intracellular inclusions. Much work has been devoted to trying to determine the relationship between inclusion formation and neuronal injury. However, little attention has been paid to the variability and characteristics of inclusions themselves. Here, we characterize the morphological and biochemical composition of inclusions in both a transgenic mouse model (R6/2 line) and an inducible cell culture model of HD (iPC12Q74). We identified several morphologically distinct kinds of inclusions in different locations (nuclei, cytoplasm and cellular processes). Ubiquitin colocalized completely with all of these inclusions in both the iPC12Q72 and R6/2 models. In the inclusions in iPC12Q74 cells, the 20S and 11S proteasome subunits colocalized variably, and the 19S subunit did not colocalize at all. In inclusions in R6/2 mouse neurons, the 20S subunit colocalized completely, but neither the 11S nor the 19S subunits colocalized at all. While the role of inclusions in the pathogenesis of HD continues to be debated, we suggest that the content and structure of inclusions vary considerably, not only from cell to cell but even within individual cells. Their role in the pathogenesis of HD is likely to depend on their location as well as their composition.
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PMID:Differential morphology and composition of inclusions in the R6/2 mouse and PC12 cell models of Huntington's disease. 1728 42

For over fifty years lithium has been a fundamental component of therapy for patients with bipolar disorders. Lithium has been considered recently for its potential to alleviate neuronal loss and other neurodegeneration processes. For instance, lithium reduces the severity of some behavioral complications of Alzheimer's disease (AD). And there are growing indications that lithium may be of benefit to the underlying pathology of AD, as well as an array of other common CNS disorders, including stroke, Parkinson's disease, and Huntington's disease. Despite these demonstrated and prospective therapeutic benefits, lithium's mechanism of action remains elusive, and opinions differ regarding the most relevant molecular targets. Lithium inhibits several enzymes; significant among these are inositol monophosphatase (IMPase), glycogen synthase kinase-3 (GSK-3), and the proteasome. Most recent publications discussing the medical application of lithium have converged on GSK-3, so this article reviews data and discussions regarding the roles and interactions of GSK-3 with other proteins and its proposed role in the pathogenesis of Alzheimer's disease.
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PMID:Glycogen synthase kinase-3 in neurodegeneration and neuroprotection: lessons from lithium. 1731 63


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