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Query: EC:3.4.24.56 (
insulin-degrading enzyme
)
737
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Exposure of insulin to
insulin protease
(
insulinase
, EC 3.4.22.11), a degradative enzyme with considerable specificity toward insulin, results in alterations in the properties of the insulin molecule. Limited degradation by the enzyme results in a decrease in the ability of insulin to bind to membrane receptors with less change in the immunoprecipitability or trichloracetic acid precipitability of the hormone. Limited degradation by
insulin protease
also alters insulin so that the molecule becomes susceptible to attack by nonspecific endopeptidases which have no effect on unaltered insulin. These data demonstrate the production of an intermediate in the proteolytic degradation of insulin. By labeling with [14C]dansyl chloride, an insulin intermediate with three amino-terminal residues, glycine,
phenylalanine
, and leucine, was identified. Analysis of this intermediate demonstrated that it was composed of an intact A chain and a B chain cleaved between residues B16 and B17, with the three peptide chains held together by disulfide bonds. Based on these findings, we hypothesize that a stepwise degradation of insulin occurs in vivo and that an early step in the process is the cleavage between B16 and B17 that renders the molecule sucseptible to further degradation by nonspecific proteases.
...
PMID:Initial site of insulin cleavage by insulin protease. 28 88
The enzymatic mechanisms for insulin breakdown by hepatocytes have not been established, nor have the degradation products been identified. Several lines of evidence have suggested that the enzyme
insulin protease
is involved in insulin degradation by hepatocytes. To identify the products of insulin generated by
insulin protease
and to compare them with those produced by hepatocytes, we have incubated insulin specifically iodinated at either the B-16 or the B-26 tyrosines with
insulin protease
and with isolated hepatocytes, separated the products on high performance liquid chromatography (HPLC), and identified the B-chain cleavages. Insulin-sized products were obtained by Sephadex G-50 filtration. These insulin-sized products were injected on reverse-phase HPLC, and the peaks of radioactivity were identified. The product patterns generated by the enzyme and by hepatocytes were essentially identical with both isomers. The products were also sulfitolized to prepare the S-sulfonate derivatives of the B-chain and B-chain peptides. Again, the patterns on HPLC generated by the enzyme and by hepatocytes with both isomers were identical. Each of the original product peaks was also sulfitolized and injected separately on HPLC to relate B-chain peptides with product peaks. Again, the peptide compositions of the product peaks for both enzyme and hepatocytes were essentially identical. To identify the cleavage sites in the B-chain of insulin produced by
insulin protease
, the peptides from the degradation of [125I]iodo(B-26)insulin were purified and submitted to automated Edman degradation to identify the cycle in which radioactivity appeared. Seven peptides with cleavages on the amino side of the B26 residue were identified, and the cleavage sites were determined. Cleavages were found between B-9 and B-10 (Ser-His), B-10 and B-11 (His-Leu), B-14 and B-15 (Ala-Leu), B-13 and B-14 (Glu-Ala), B-16 and B-17 (Tyr-Leu), B-24 and B-25 (
Phe
-
Phe
), and B-25 and B-26 (
Phe
-Tyr). Peptides were also isolated from [125I]iodoinsulin incubated with isolated hepatocytes, and the cleavage sites in several of these were determined. These agreed exactly with the cleavage sites identified generated by the enzyme. The major peptides generated by the degradation of [125I]iodo(B-16)insulin were also isolated and sequenced, again showing identical cleavage sites.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Degradation products of insulin generated by hepatocytes and by insulin protease. 327 79
The mechanism by which the liver degrades insulin has not yet been completely clarified. In intact, non-"leaky" cells the primary process seems to be mediated by initial receptor binding. We now demonstrate that isolated rat hepatocytes in primary culture are suitable for examining insulin degradation. Hepatocytes did not leak degrading activity into the medium, and thus, the degradation seen was essentially exclusively cell mediated. [125I]Iodoinsulin degradation by these cells was dependent on time and cell concentration. There was a short lag time before degradation products could be detected in the medium. After incubation with the hepatocytes, three peaks of 125I-labeled material could be separated by chromatography on Sephadex G-50. The same three peaks were seen with 125I-labeled material extracted from the cells. When [3H]insulin, labeled exclusively at the B-1
phenylalanine
residue, was incubated with the cells, additional peaks of labeled material were recovered from the column. These additional peaks were intermediate in size between insulin and iodotyrosine, suggesting the production of products smaller than insulin but larger than individual amino acids. In order to begin to characterize the subcellular mechanisms for insulin metabolism, the effect of various potential inhibitors on insulin degradation were examined. The most effective inhibitors were N-ethylmaleimide, bacitracin, and Kunitz pancreatic trypsin inhibitor. Chloroquine decreased degradation only 10%, and NH4Cl had no detectable effect. The effect of the inhibitors on the purified
insulin-degrading enzyme
,
insulin protease
, was also examined. The purified enzyme responded essentially identically as the intact cells to the various inhibitors. From all these data it would seem that lysosomal degradation of insulin in the hepatocyte may be a relatively minor pathway and the neutral protease may play a major role.
...
PMID:Insulin degradation by hepatocytes in primary culture. 700 45
The signal transduction of the formyl-Met-Leu-
Phe
(FMLP) receptor in polymorphonuclear leukocytes (PMNLs) from patients with non-insulin-dependent diabetes mellitus (NIDDM) was compared to that of PMNLs obtained from healthy volunteers. According to our previous studies in this group of patients neither the decrease in insulin binding capacity nor the enhanced
insulin-degrading enzyme
activity was involved. In control PMNLs, 10 nM FMLP induced a pertussis toxin-sensitive increase in phosphatidyl inositol (PI) cleavage and a subsequent Ca2+ signaling from the intracellular pools. On the other hand, the FMLP-induced protein kinase C (PKC) activation and translocation into the membrane could not be detected in these cells via the measurement of 32P incorporation into histone. In contrast, in PMNLs of this special group of patients suffering from NIDDM the FMLP stimulus produced a significantly low increase in PI cleavage and Ca2+ signaling from the intracellular pools. Moreover, in resting PMNLs of these patients with NIDDM, not only the [Ca2+]i but also the membrane-bound PKC activity was found to be significantly increased. In addition, PKC translocation into the cell membrane of diabetic PMNLs could be further triggered with FMLP as judged by the measurement of 32P incorporation into histone. Based on these results, it appears that the signaling of FMLP receptors in PMNLs of some NIDDM patients may have an alternative pathway through Ca2+ influx from extracellular medium, arachidonic acid cascade, and PKC activation.
...
PMID:Altered postreceptor signal transduction of formyl-Met-Leu-Phe receptors in polymorphonuclear leukocytes of patients with non-insulin-dependent diabetes mellitus. 943 1
Amyloid beta-protein (Abeta) has been implicated as an early and essential factor in the pathogenesis of Alzheimer's disease. Although its cellular production has been studied extensively, little is known about Abeta clearance. Recently,
insulin-degrading enzyme
(
IDE
), a 110-kDa metalloendopeptidase, was found to degrade both endogenously secreted and synthetic Abeta peptides. Surprisingly,
IDE
-mediated proteolysis of [(125)I]Abeta(1-40) in microglial cell-culture media was accompanied by the formation of (125)I-labelled peptides with higher apparent molecular masses, raising the possibility that the degradation products act as 'seeds' for Abeta oligomerization. To directly address the role of
IDE
in Abeta degradation and oligomerization, we investigated the action of purified recombinant wild-type and catalytically inactive IDEs. Our data demonstrate that (i)
IDE
alone is sufficient to cleave purified Abeta that is either unlabelled, iodinated or (35)S-labelled; (ii) the initial cleavage sites are His(14)-Gln(15),
Phe
(19)-
Phe
(20) and
Phe
(20)-Ala(21); and (iii) incubation of
IDE
with [(125)I]Abeta, but not with [(35)S]-Abeta, leads to the formation of slower migrating species on gels. Since iodination labels N-terminal fragments of Abeta, and (35)S labels C-terminal products, we analysed unlabelled synthetic fragments of Abeta and determined that only the N-terminal fragments migrate with anomalously high molecular mass. These results indicate that
IDE
alone is sufficient to degrade Abeta at specific sites, and that its degradation products do not promote oligomerization of the intact Abeta peptide.
...
PMID:Purified recombinant insulin-degrading enzyme degrades amyloid beta-protein but does not promote its oligomerization. 1102 38
Recombinant rat
insulysin
was shown to cleave the internally quenched fluorogenic peptide 2-aminobenzyl-GGFLRKVGQ-ethylenediamine-2,4-dinitrophenol at the R-K bond, exhibiting a K(m) of 13 microm and a V(max) of 2.6 micromol min(-1) mg(-1). Derivatives of this peptide in which the P(2) leucine or the P(2)' valine were replaced with other residues were used to probe the subsite specificity of the enzyme. Varying the P(2) residue produced a 4-fold range in K(m) and a 7-fold range in k(cat). The nature of the P(2) residue had a significant effect on the site of cleavage. Leucine, isoleucine, valine, and aspartate produced cleavage at the R-K bond. Asparagine produced 36% cleavage at the N-R bond and 64% cleavage at the R-K bond, whereas with alanine or serine the A-R and S-R bonds were the major cleavage sites. With tyrosine,
phenylalanine
, methionine, or histidine representing the varied residue X, cleavages at F-X, X-R, and R-K were seen, whereas with tryptophan equal cleavage occurred at the F-W and W-R bonds. Variable P(2)' residues produce less of a change in both K(m) and k(cat) and have little influence on the cleavage site. Exceptions are
phenylalanine
, tyrosine, leucine, and isoleucine, which in addition to producing cleavage at the R-K bond, produce significant cleavage at the L-R bond. Alanine and tyrosine were unique in producing cleavage at the F-L bond. Taken together, these data suggest that
insulysin
specificity is directed toward the amino side of hydrophobic and basic residues and that the enzyme has an extended substrate binding site.
...
PMID:Analysis of the subsite specificity of rat insulysin using fluorogenic peptide substrates. 1104 90
Insulysin (EC. 3.4.22.11) has been implicated in the clearance of beta amyloid peptides through hydrolytic cleavage. To further study the action of
insulysin
on Abeta peptides recombinant rat
insulysin
was used. Cleavage of both Abeta(1-40) and Abeta(1-42) by the recombinant enzyme was shown to initially occur at the His(13)-His(14), His(14)-Gln(15), and
Phe
(19)-
Phe
(20) bonds. This was followed by a slower cleavage at the Lys(28)-Gly(29), Val(18)-
Phe
(19), and
Phe
(20)-Ala(21) positions. None of the products appeared to be further metabolized by
insulysin
. Using a rat cortical cell system, the action of
insulysin
on Abeta(1-40) and Abeta(1-42) was shown to eliminate the neurotoxic effects of these peptides. Insulysin was further shown to prevent the deposition of Abeta(1-40) onto a synthetic amyloid. Taken together these results suggest that the use of
insulysin
to hydrolyze Abeta peptides represents an alternative gene therapeutic approach to the treatment of Alzheimer's disease.
...
PMID:Insulysin hydrolyzes amyloid beta peptides to products that are neither neurotoxic nor deposit on amyloid plaques. 1110 81
The endosomal compartment of hepatic parenchymal cells contains an acidic endopeptidase, endosomal acidic
insulinase
(EAI), which hydrolyzes internalized insulin at a limited number of sites. Although the positions of these cleavages are partially known, the residues of insulin important in its binding to and proteolysis by EAI have not been defined. To this end, we have studied the degradation over time of native human insulin and three insulin-analog peptides using a soluble endosomal extract from rat liver parenchyma followed by purification of the products by HPLC and determination of their structure by mass spectrometry. We found variable rates of ligand processing, i.e. high ([Asp(B10)]- and [Glu(A13),Glu(B10)]-insulin), moderate (insulin) and low (the H2-analog). On the basis of IC(50) values, competition studies revealed that human and mutant insulins display nearly equivalent affinity for the EAI. Proteolysis of human and mutant insulins by EAI resulted in eight cleavages in the B-chain which occurred in the central region (Glu(B13)-Leu(B17)) and at the C-terminus (Arg(B22)-Thr(B27)), the latter region comprising the initial cleavages at
Phe
(B24)-
Phe
(B25) (major pathway) and
Phe
(B25)-Tyr(B26) (minor pathway) bonds. Except for the [Glu(A13),Glu(B10)]-insulin mutant, only one cleavage on the A-chain was observed at residues Gln(A15)-Leu(A16). Analysis of the nine cleavage sites showed a preference for hydrophobic and aromatic amino acid residues on both the carboxyl and amino sides of a cleaved peptide bond. Using the B-chain alone as a substrate resulted in a 30-fold increase in affinity for EAI and a 6-fold increase in the rate of hydrolysis compared with native insulin. A similar role for the C-terminal region of the B-chain of insulin in the high-affinity recognition of EAI was supported by the use of the corresponding B(22)-B(30) peptide, which displayed an increase in EAI affinity similar to the entire B-chain vs. wild-type insulin. Thus, we have identified a highly specific molecular interaction of insulin with EAI at the aromatic locus
Phe
(B24)-
Phe
(B25)-Tyr(B26). Analytical subfractionation of a postmitochondrial supernatant fraction showed that a pulse of internalized [(125)I]Tyr(A14)-H2-analog, a protease-resistant insulin analog, undergoes a greater lysosomal transfer and lesser degradation than [(125)I]Tyr(A14)-insulin, confirming that endosomal sorting is regulated directly or indirectly by endosomal proteolysis.
...
PMID:Identification of insulin domains important for binding to and degradation by endosomal acidic insulinase. 1114 91
The endosomal compartment of hepatic parenchymal cells contains an acidic endopeptidase, endosomal acidic
insulinase
, which hydrolyzes internalized insulin and generates the major primary end product A(1--21)-B(1--24) insulin resulting from a major cleavage at residues
Phe
(B24)-
Phe
(B25). This study addresses the nature of the relevant endopeptidase activity in rat liver that is responsible for most receptor-mediated insulin degradation in vivo. The endosomal activity was shown to be aspartic acid protease cathepsin D (CD), based on biochemical similarities to purified CD in 1) the rate and site of substrate cleavage, 2) pH optimum, 3) sensitivity to pepstatin A, and 4) binding to pepstatin A-agarose. The identity of the protease was immunologically confirmed by removal of greater than 90% of the insulin-degrading activity associated with an endosomal lysate using polyclonal antibodies to CD. Moreover, the elution profile of the endosomal acidic
insulinase
activity on a gel-filtration TSK-GEL G3000 SW(XL) high performance liquid chromatography column corresponded exactly with the elution profile of the immunoreactive 45-kDa mature form of endosomal CD. Using nondenaturating immunoprecipitation and immunoblotting procedures, other endosomal aspartic acid proteases such as cathepsin E and beta-site amyloid precursor protein-cleaving enzyme (BACE) were ruled out as candidate enzymes for the endosomal degradation of internalized insulin. Immunofluorescence studies showed a largely vesicular staining pattern for internalized insulin in rat hepatocytes that colocalized partially with CD. In vivo pepstatin A treatment was without any observable effect on the insulin receptor content of endosomes but augmented the phosphotyrosine content of the endosomal insulin receptor after insulin injection. These results suggest that CD is the endosomal acidic
insulinase
activity which catalyzes the rate-limiting step of the in vivo cleavage at the
Phe
(B24)-
Phe
(B25) bond, generating the inactive A(1--21)-B(1--24) insulin intermediate.
...
PMID:Endosomal proteolysis of internalized insulin at the C-terminal region of the B chain by cathepsin D. 1177 65
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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