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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)
We have identified a 26S
proteasome
-associated ubiquitin carboxyl-terminal hydrolase (UCH) in Schizosaccharomyces pombe. The gene (designated uch2+) encodes a protein containing a UCH catalytic domain at its N-terminus and a short extension at its C-terminus. uch2+ is nonessential as the uch2 null mutant strain showed no significant difference from the wild-type strain. The GFP-tagged Uch2p is localized predominantly to the nuclear periphery, which is similar to the 26S
proteasome
localization. Deletion of the C-terminal extension of Uch2p resulted in a drastic change of its subcellular localization: it showed a generally diffused distribution instead of a perinuclear pattern.
Glycerol
gradient centrifugation analysis and coimmunoprecipitation studies of fission yeast extracts using anti-Mts4p antiserum suggest that Uch2p is associated with the 26S
proteasome
and the association of Uch2p with the 26S
proteasome
is mediated by its C-terminal extension.
...
PMID:Identification of a 26S proteasome-associated UCH in fission yeast. 1087 38
A major metabolic effect of insulin is inhibition of cellular proteolysis, but the proteolytic systems involved are unclear. Tissues have multiple proteolytic systems, including the ATP- and ubiquitin-dependent
proteasome
pathway. The effect of insulin on this pathway was examined in vitro and in cultured cells. Insulin inhibited ATP- and ubiquitin-dependent lysozyme degradation more than 90% by reticulocyte extract, in a dose-dependent manner (IC50 approximately 50 nM). Insulin did not reduce the conjugation of ubiquitin to lysozyme and was not itself ubiquitin-conjugated. In HepG2 cells, insulin increased ubiquitin-conjugate accumulation 80%. The association between the 26S
proteasome
and an intracellular protease, the insulin-degrading enzyme (IDE), was examined by a purification scheme designed to enrich for the 26S
proteasome
. Copurification of IDE activity and immunoreactivity with the
proteasome
were detected through several chromatographic steps.
Glycerol
gradient analysis revealed cosedimentation of IDE with the 20S
proteasome
and possibly with the 26S
proteasome
. The
proteasome
-associated IDE was displaced when the samples were treated with insulin. These results suggest that insulin regulates protein catabolism, at least in part, by decreasing ubiquitin-mediated proteasomal activity, and provides a new target for insulin action. The displacement of IDE from the
proteasome
provides a mechanism for this insulin action.
...
PMID:Insulin inhibits the ubiquitin-dependent degrading activity of the 26S proteasome. 1087 52
The
proteasome
is an eukaryotic multi-subunit protease complex composed of one 20S core component and two 19S regulatory complexes. The regulatory complex contains 6 putative ATPases. We investigated tissue and cell distribution of one of these ATPases, MSS1 (mammalian suppressor of sgv1). MSS1 was ubiquitously present in rat tissues as was the 20S core component of
proteasome
. However, the ratio of MSS1 to 20S varied greatly among tissues and MSS1 was concentrated in the thymus.
Glycerol
gradient sedimentation analysis revealed that MSS1 is included in protein complexes whose density is lighter than that of the
proteasome
. MSS1 was distributed in mammalian cells ubiquitously, while
proteasome
was rather concentrated in the nuclei. Hence, a novel molecular status of MSS1 distinct from
proteasome
is implicated. Interestingly, multiple basal transcription factors for RNA polymerase II, including TBP, TFIIB, TFIIH, and TFIIF, were found to be associated with MSS1. These results suggest that MSS1, in addition to proteolysis, plays a role in DNA metabolism including transcriptional regulation.
...
PMID:Tissue and cell distribution of a mammalian proteasomal ATPase, MSS1, and its complex formation with the basal transcription factors. 1111 27
Loss of skeletal muscle is a major factor in the poor survival of patients with cancer cachexia. This study examines the mechanism of catabolism of skeletal muscle by a tumour product, proteolysis-inducing factor (PIF). Intravenous administration of PIF to normal mice produced a rapid decrease in body weight (1.55 +/- 0.12 g in 24 h) that was accompanied by increased mRNA levels for ubiquitin, the Mr 14 000 ubiquitin carrier-protein, E2, and the C9
proteasome
subunit in gastrocnemius muscle. There was also increased protein levels of the 20S
proteasome
core and 19S regulatory subunit, detectable by immunoblotting, suggesting activation of the ATP-ubiquitin-dependent proteolytic pathway. An increased protein catabolism was also seen in C(2)C(12)myoblasts within 24 h of PIF addition with a bell-shaped dose-response curve and a maximal effect at 2-4 nM. The enhanced protein degradation was attenuated by anti-PIF antibody and by the
proteasome
inhibitors MG115 and lactacystin.
Glycerol
gradient analysis of proteasomes from PIF-treated cells showed an elevation in chymotrypsin-like activity, while Western analysis showed a dose-related increase in expression of MSSI, an ATPase that is a regulatory subunit of the
proteasome
, with a dose-response curve similar to that for protein degradation. These results confirm that PIF acts directly to stimulate the
proteasome
pathway in muscle cells and may play a pivotal role in protein catabolism in cancer cachexia.
...
PMID:Activation of ATP-ubiquitin-dependent proteolysis in skeletal muscle in vivo and murine myoblasts in vitro by a proteolysis-inducing factor (PIF). 1146 Oct 93
The detailed mechanism of eukaryotic 20S
proteasome
assembly is currently unknown. In the present study, we demonstrate that the 20S
proteasome
subunits alpha4 and alpha7 interact with each other as well as all the alpha-subunits in vivo and in vitro. The N-terminal parts of alpha4 and alpha7 are essential for these newly discovered interactions in vitro.
Glycerol
gradient centrifugation of soluble extracts of HEK293 cells and Western blot analyses show that several alpha-subunits are found in non-proteasomal low-density fractions. The alpha4 and alpha7 subunits co-immunoprecipitate together from these low-density fractions. The unexpected interaction between alpha4 and alpha7 may provide a molecular basis for the formation of previously reported 13S and 16S assembly intermediates.
...
PMID:The alpha4 and alpha7 subunits and assembly of the 20S proteasome. 1522 36
Chaperones, particularly the heat-shock proteins, are considered as key players in the maintenance of protein homeostasis and are associated with longevity and cellular immortalization. In this study, we investigated the geroprotective activity of the chemical chaperone glycerol.
Glycerol
showed significant chaperoning activity in refolding heat-denatured luciferase in vivo and in protecting cells from heat stress-induced cytotoxicity. This was accompanied by decrease in p53, an upregulation of a stress chaperone mortalin/mtHsp70, and an increase in
proteasome
activity in the presence of oxidative stress.
...
PMID:Geroprotection by glycerol: insights to its mechanisms and clinical potentials. 1680 31
Aging is associated with accumulation of toxic intracellular and extracellular protein aggregates. Cells manage "aged" proteins by mobilizing their molecular chaperones or heat shock proteins that are also considered as determinants of lifespan in diverse species. In this study, we tested whether an exogenous addition of the non-toxic chemical chaperone 'glycerol' could elicit stress and geronto-protective activities. We found that glycerol enhanced chaperoning of heat-denatured proteins. In addition to stimulating
proteasome
activity, glycerol led to an increased expression of the stress chaperone 'mortalin' and decreased p53 function in human cells.
Glycerol
-fed worms exhibited thermo-tolerance and lower level of age-associated auto-fluorescence. Through the combined stimulation of the
proteasome
and chaperoning activities of mortalin, in particular, glycerol treatment resulted in increased survival and fitness against oxidative- and heat-stress. These results may have significant implications in the use of glycerol as a candidate geronto-modulator in development of practical interventions for "healthy aging".
...
PMID:Glycerol stimulates innate chaperoning, proteasomal and stress-resistance functions: implications for geronto-manipulation. 1834 10
Cholera toxin (CT) moves from the cell surface to the endoplasmic reticulum (ER) by retrograde vesicular transport. The catalytic subunit of CT (CTA1) then crosses the ER membrane and enters the cytosol in a process that involves the quality control mechanism of ER-associated degradation. The molecular details of this dislocation event have not been fully characterized. Here, we report that thermal instability in the CTA1 subunit-specifically, the loss of CTA1 tertiary structure at 37 degrees C-triggers toxin dislocation. Biophysical studies found that glycerol preferentially stabilized the tertiary structure of CTA1 without having any noticeable effect on the thermal stability of its secondary structure. The thermal disordering of CTA1 tertiary structure normally preceded the perturbation of its secondary structure, but in the presence of 10% glycerol the temperature-induced loss of CTA1 tertiary structure occurred at higher temperatures in tandem with the loss of CTA1 secondary structure. The glycerol-induced stabilization of CTA1 tertiary structure blocked CTA1 dislocation from the ER and instead promoted CTA1 secretion into the extracellular medium. This, in turn, inhibited CT intoxication.
Glycerol
treatment also inhibited the in vitro degradation of CTA1 by the core 20S
proteasome
. Collectively, these findings indicate that toxin thermal instability plays a key role in the intoxication process. They also suggest the stabilization of CTA1 tertiary structure is a potential goal for novel antitoxin therapeutic agents.
...
PMID:Stabilization of the tertiary structure of the cholera toxin A1 subunit inhibits toxin dislocation and cellular intoxication. 1974 10
Exposure of C. elegans to hypertonic stress-induced water loss causes rapid and widespread cellular protein damage. Survival in hypertonic environments depends critically on the ability of worm cells to detect and degrade misfolded and aggregated proteins. Acclimation of C. elegans to mild hypertonic stress suppresses protein damage and increases survival under more extreme hypertonic conditions. Suppression of protein damage in acclimated worms could be due to 1) accumulation of the chemical chaperone glycerol, 2) upregulation of protein degradation activity, and/or 3) increases in molecular chaperoning capacity of the cell.
Glycerol
and other chemical chaperones are widely thought to protect proteins from hypertonicity-induced damage. However, protein damage is unaffected by gene mutations that inhibit glycerol accumulation or that cause dramatic constitutive elevation of glycerol levels. Pharmacological or RNAi inhibition of
proteasome
and lyosome function and measurements of cellular protein degradation activity demonstrated that upregulation of protein degradation mechanisms plays no role in acclimation. Thus, changes in molecular chaperone capacity must be responsible for suppressing protein damage in acclimated worms. Transcriptional changes in chaperone expression have not been detected in C. elegans exposed to hypertonic stress. However, acclimation to mild hypertonicity inhibits protein synthesis 50-70%, which is expected to increase chaperone availability for coping with damage to existing proteins. Consistent with this idea, we found that RNAi silencing of essential translational components or acute exposure to cycloheximide results in a 50-80% suppression of hypertonicity-induced aggregation of polyglutamine-YFP (Q35::YFP). Dietary changes that increase protein production also increase Q35::YFP aggregation 70-180%. Our results demonstrate directly for the first time that inhibition of protein translation protects extant proteins from damage brought about by an environmental stressor, demonstrate important differences in aging- versus stress-induced protein damage, and challenge the widely held view that chemical chaperones are accumulated during hypertonic stress to protect protein structure/function.
...
PMID:Characterization of the proteostasis roles of glycerol accumulation, protein degradation and protein synthesis during osmotic stress in C. elegans. 2247 May 31
