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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)
Studies were carried out to characterize further the cytoplasmic ATP- and ubiquitin-independent proteolytic system in red blood cells that degrades hemoglobin damaged by exposure to oxidants (Fagan, J. M., Waxman, L., and Goldberg, A. L. (1986) J. Biol. Chem. 261, 5705-5713). Several proteases were ruled out as having a major role in the degradation of oxidant-treated hemoglobin (Ox-Hb). Acid hydrolases are not active in this process since the degradation of Ox-Hb has a pH optimum between 6 and 8. The calpains are also not involved since inhibitors of cysteine proteases (leupeptin and trans-epoxysuccinyl-L-leucylamido-(3-methyl)butane) did not diminish the increased proteolysis in intact erythrocytes treated with oxidants or in lysates to which Ox-Hb was added. The degradation of Ox-Hb was unaffected by inhibitors of serine and aspartic proteases. Removal of the high M(r)
multicatalytic proteinase
by immunoprecipitation also did not significantly affect the degradation of Ox-Hb in erythrocyte lysates. The degradation of Ox-Hb was sensitive to metal chelators and sulfhydryl-modifying reagents but not to specific inhibitors of known metalloproteases. Insulin, which is rapidly degraded in lysates, completely blocked the degradation of Ox-Hb. Insulin- and Ox-Hb-hydrolyzing activity was also inhibited following immunoprecipitation of the 100-kDa
metalloinsulinase
. The
metalloinsulinase
, which is inhibited by sulfhydryl-modifying reagents and which requires divalent metals, may therefore participate in the degradation of hemoglobin damaged by oxidants in erythrocytes.
...
PMID:The ATP-independent pathway in red blood cells that degrades oxidant-damaged hemoglobin. 142 49
Haemoglobin damaged by exposure of red blood cells to oxidants is rapidly degraded by a proteolytic pathway which does not require ATP [Fagan, Waxman & Goldberg (1986) J. Biol. Chem. 261, 5705-5713]. By fractionating erythrocyte lysates, we have purified two proteases which hydrolyse oxidatively damaged haemoglobin (Ox-Hb). One protease hydrolysed small fluorogenic substrates in addition to Ox-Hb. Its molecular mass was approximately 700 kDa and it consisted of several subunits ranging in size from 22 to 30 kDa. This enzyme may be related to the high-molecular-mass
multicatalytic proteinase
previously isolated from a variety of tissue and cell types. The other Ox-Hb-degrading activity had an apparent molecular mass of 400 kDa on gel filtration, a subunit size of 110 kDa and an isoelectric point between 4.5 and 5.0. This protease also hydrolysed the small polypeptides insulin and glucagon, as well as other large proteins such as lysozyme. Insulin blocked the degradation of Ox-Hb and Ox-Hb blocked the hydrolysis of insulin by the purified protease. Thiol reagents and metal chelators strongly inhibited the hydrolysis of both Ox-Hb and insulin, whereas inhibitors of serine, aspartic and thiol proteases had little effect. These properties suggest that the Ox-Hb-degrading activity purified from rabbit erythrocytes is the cytosolic
insulin-degrading enzyme
that is believed to play a role in the metabolism of insulin in several tissues. We propose that this enzyme may also function as a key component in a cytoplasmic degradative pathway responsible for removing proteins damaged by oxidants.
...
PMID:Purification of a protease in red blood cells that degrades oxidatively damaged haemoglobin. 187 13
The activity of
insulin-degrading enzyme
(
IDE
), a thiol metalloprotease degrading insulin in many insulin target cells, was determined in human colon adenocarcinoma (Caco-2) cells. Insulin-degrading activity was localized in the cytosol of Caco-2 cells, accounting for 88% of total activity. Western blots and immunoprecipitation showed that
IDE
was present in the cytosol of Caco-2 cells and contributed to more than 93% cytosolic insulin-degrading activity. Cytosolic insulin degradation was strongly inhibited by
IDE
inhibitors, including N-ethylmaleimide, 1,10-phenanthroline, p-chloromericuribenzoate, and EDTA, but was not significantly or not as extensively inhibited by strong inhibitors of
proteasome
, i.e., chymostatin, soybean trypsin inhibitor, leupeptin, and Dip-F. These results suggest that
IDE
is present in Caco-2 cells, that Caco-2
IDE
has properties similar to those of its counterparts in insulin-target tissues, and that it significantly contributes to intracellular insulin degradation.
...
PMID:Insulin-degrading enzyme in a human colon adenocarcinoma cell line (Caco-2). 759 85
The
insulin-degrading enzyme
(
IDE
) and the
multicatalytic proteinase
(
MCP
) can be isolated as components of a cytosolic proteolytic complex.
IDE
is the primary enzyme involved in cellular degradation of insulin, and insulin has been shown to interact with cytosolic
IDE
.
MCP
is believed to be important in non-ubiquitin pathways of cellular protein degradation. Insulin has a dose- and time-dependent inhibitory effect on
MCP
degradation of N-succinyl-Leu-Leu-Val-Tyr 7-amino-4-methylcoumarin (LLVY), a substrate for
MCP
. Proinsulin also inhibits LLVY degradation in a dose-dependent manner. The effect of insulin is immediate as measured in a continuously monitored assay of LLVY degradation. Purification of the
IDE
-
MCP
complex using a variety of approaches, including affinity and conventional chromatography, retains the insulin effect on LLVY degradation as long as the complex remains intact. After ion-exchange chromatography, which separates
IDE
and
MCP
, insulin no longer has an inhibitory effect. Recombination of purified
IDE
and
MCP
does not restore the effect of insulin, but inclusion of additional components from the ion-exchange column does. These results support the existence of a functional cytosolic complex that contains
IDE
and
MCP
. Insulin interacts with
IDE
and alters the activity of
MCP
, suggesting a functional relationship between these two components and a mechanism for an intracellular action of insulin.
...
PMID:A direct inhibitory effect of insulin on a cytosolic proteolytic complex containing insulin-degrading enzyme and multicatalytic proteinase. 792 29
The
insulin-degrading enzyme
(
IDE
) plays an important role in the cellular metabolism of insulin. Recent studies have also suggested a regulatory role for this protein in controlling the activity of cytoplasmic protein complexes, including the
proteasome
[
multicatalytic proteinase
(
MCP
)] and the glucocorticoid and androgen receptors. Binding of
IDE
to these complexes increases their activity, whereas the addition of substrates for
IDE
inhibits activity. This provides a potential mechanism of action for internalized insulin and other
IDE
substrates in the control of protein turnover. To examine further the interactions, partially purified
IDE
-
MCP
complex was treated with EDTA or EGTA, and activity was measured in the absence and presence of various divalent cations (Ca2+, Mn2+, Co2+, and Zn2+) and insulin. EDTA treatment reduced
MCP
activity and eliminated the effect of insulin on the complex. Divalent cations partially or completely restored
MCP
activity, but did not restore the effect of insulin. EGTA treatment had a lesser effect on
MCP
activity, but abolished insulin inhibition of activity. Divalent cations restored the insulin effect. Inhibitors of
IDE
also blocked the insulin effect on
MCP
activity, as did treatment with SDS. These findings suggest that conformational changes in the complex may play a role in the insulin control of
MCP
activity.
...
PMID:Regulation of multicatalytic enzyme activity by insulin and the insulin-degrading enzyme. 975 83
Insulin degradation is a regulated process that plays a role in controlling insulin action by removing and inactivating the hormone. Abnormalities in insulin clearance and degradation are present in various pathological conditions including type 2 diabetes and obesity and may be important in producing clinical problems. The uptake, processing, and degradation of insulin by cells is a complex process with multiple intracellular pathways. Most evidence supports
IDE
as the primary degradative mechanism, but other systems (PDI, lysosomes, and other enzymes) undoubtedly contribute to insulin metabolism. Recent studies support a multifunctional role for
IDE
, as an intracellular binding, regulatory, and degradative protein.
IDE
increases
proteasome
and steroid hormone receptor activity, and this activation is reversed by insulin. This raises the possibility of a direct intracellular interaction of insulin with
IDE
that could modulate protein and fat metabolism. The recent findings would place intracellular insulin-
IDE
interaction into the insulin signal transduction pathway for mediating the intermediate effects of insulin on fat and protein turnover.
...
PMID:Insulin degradation: progress and potential. 979 60
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
A pathological feature of Type 2 diabetes is deposits in the pancreatic islets primarily composed of amylin (islet amyloid polypeptide). Although much attention has been paid to the expression and secretion of amylin, little is known about the enzymes involved in amylin turnover. Recent reports suggest that
insulin-degrading enzyme
(
IDE
) may have specificity for amyloidogenic proteins, and therefore we sought to determine whether amylin is an
IDE
substrate. Amylin-degrading activity co-purified with
IDE
from rat muscle through several chromatographic steps. Metalloproteinase inhibitors inactivated amylin-degrading activity with a pattern consistent with the enzymatic properties of
IDE
, whereas inhibitors of acid and serine proteases, calpains, and the
proteasome
were ineffective. Amylin degradation was inhibited by insulin in a dose-dependent manner, whereas insulin degradation was inhibited by amylin. Other substrates of
IDE
such as atrial natriuretic peptide and glucagon also competitively inhibited amylin degradation. Radiolabeled amylin and insulin were both covalently cross-linked to a protein of 110 kDa, and the binding was competitively inhibited by either unlabeled insulin or amylin. Finally, a monoclonal anti-
IDE
antibody immunoprecipitated both insulin- and amylin-degrading activities. The data strongly suggest that
IDE
is an amylin-degrading enzyme and plays an important role in the clearance of amylin and the prevention of islet amyloid formation.
...
PMID:Degradation of amylin by insulin-degrading enzyme. 1097 71
Insulin-degrading enzyme is responsible for initiating insulin degradation in cells, but little is known about the factors controlling its activity. Because obesity and high levels of free fatty acids decrease insulin clearance, we examined the effect of some common free fatty acids and their acyl-coenzyme A thioesters on
insulin-degrading enzyme
partially purified from the livers of male Sprague Dawley rats. Octanoic acid (C8:0) had no effect on activity. Long-chain free fatty acids (C16-C20) inhibited between 50% and 90% of the insulin degradation with IC(50) values in the range of 10-50 micro M. In general, the corresponding acyl-coenzyme A thioesters had lower IC(50) values and were slightly more efficacious. (125)I-insulin cross-linking studies showed free fatty acids did not inhibit hormone binding to
insulin-degrading enzyme
. Kinetic analysis showed a noncompetitive type of inhibition. Furthermore, fatty acids eliminated the ability of insulin to inhibit the
proteasome
. These results suggest that when intracellular long-chain fatty acid concentrations are elevated, they may act directly on
insulin-degrading enzyme
to decrease insulin metabolism and alter insulin action in intact cells. This mechanism may contribute to the hyperinsulinemia and insulin resistance seen with elevated fatty acids and obesity.
...
PMID:In vitro inhibition of insulin-degrading enzyme by long-chain fatty acids and their coenzyme A thioesters. 1274 1
A consequence of insulin-dependent diabetes mellitus is the loss of lean muscle mass as a result of accelerated proteolysis by the
proteasome
. Insulin inhibition of proteasomal activity requires interaction with
insulin-degrading enzyme
(
IDE
), but it is unclear if
proteasome
inhibition is dependent merely on insulin-NIDE binding or if degradation of insulin by
IDE
is required. To test the hypothesis that degradation by
IDE
is required for
proteasome
inhibition, a panel of insulin analogues with variable susceptibility to degradation by
IDE
binding was used to assess effects on the
proteasome
. The analogues used were [Lys(B28), Pro(B29)]-insulin (lispro), [Asp(B10)]-insulin (Asp(B10)) and [Glu(B4), Gln(B16), Phe(B17)]-insulin (EQF). Lispro was as effective as insulin at inhibition of degradation of iodine-125 ((125)I)-labeled insulin, but Asp(B10) and EQF were somewhat more effective. All agents inhibited cross-linking of (125)I-insulin to
IDE
, suggesting that all were capable of
IDE
binding. In contrast, although insulin and lispro were readily degraded by
IDE
, Asp(B10) was degraded more slowly, and EQF degradation was undetectable. Both insulin and lispro inhibited the
proteasome
, but Asp(B10) was less effective, and EQF had little effect. In summary, despite effective
IDE
binding, EQF was poorly degraded by
IDE
, and was ineffective at
proteasome
inhibition. These data suggest that insulin inhibition of
proteasome
activity is dependent on degradation by
IDE
. The mechanism of
proteasome
inhibition may be the generation of inhibitory fragments of insulin, or by displacement of
IDE
from the
proteasome
.
...
PMID:Insulin inhibition of the proteasome is dependent on degradation of insulin by insulin-degrading enzyme. 1277 20
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