EC:3.4.24.56 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

The degradation of native and 125I-labeled human insulin (HI) was examined in the cytosolic fraction of human, monkey, and rat liver. The purpose of these studies was to provide a species comparison of the interaction of insulin-degrading enzyme (IDE) and protein disulfide isomerase (PDI) in the degradation of HI. Western-blot analysis with monoclonal antibodies indicated the presence of both IDE and PDI in the cytosolic fraction of human and monkey liver. In contrast, rat liver cytosol contained, detectable levels of IDE only. A species comparison of metabolic profiles was performed by fractionating peptide products with reversed-phase high-performance liquid chromatography. After a 60-min incubation, human liver cytosol degraded unlabeled HI into three major products. Two of these peptides coeluted with the products of the incubation of HI with purified rat liver PDI. The three peptides were isolated and determined by NH2-terminal sequence analysis to be intact A chain, B chain, and des(Phe1)-B chain. Human liver cytosol also formed 125I-A chain and 125I-B chain as major products when specifically labeled 125I-HI isomers were used as substrate. Significant proteolytic degradation was observed only when reactions with human liver cytosol were supplemented with Mn2+. In contrast, monkey and rat liver cytosol proteolytically degraded 125I-HI isomers to small peptide fragments. The rat and monkey metabolic profiles were similar to each other and to that observed with Mn(2+)-supplemented human liver cytosol. Proteolysis in monkey and rat was sensitive to inhibition by EDTA.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Mechanisms involved in degradation of human insulin by cytosolic fractions of human, monkey, and rat liver. 160 78

An insulin-degrading enzyme has been purified from human erythrocytes. This enzyme degraded 125I-labeled insulin-like growth factor I (IGF-I) more slowly than 125I-IGF-II and degraded IGF-II more slowly than 125I-insulin. The time course of 125I-insulin degradation suggested the presence of intermediates, each of which was itself shown to be a substrate for the enzyme. One of these intermediates appeared to be made up entirely of B-chain residues and had HisB10 as its NH2-terminal. The final major radiolabeled degradation product of A14-[125I]monoiodoinsulin was a peptide with TyrA14 at the A-chain NH2 terminal. This peptide could be reduced with dithiothreitol, suggesting that it contained amino acid residues from both A- and B-chains. It was partially precipitated by trichloroacetic acid and anti-insulin antibody but bound poorly to IM-9 lymphocytes. The final major degradation product of B26-[125I]monoiodoinsulin was a peptide whose NH2-terminal was TyrB26 and could not be reduced by dithiothreitol. It was partially precipitated by anti-insulin antibody but was precipitated poorly, if at all, by trichloroacetic acid and bound poorly to IM-9 lymphocytes. The results show that this enzyme degraded insulin by sequential cleavage of peptide bonds on both A- and B-chains. We identified LeuA13-TyrA14, SerB9-HisB10, and PheB25-TyrB26 as three of the bonds that are cleaved.
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PMID:Degradation of insulin and insulin-like growth factors by enzyme purified from human erythrocytes. Comparison of degradation products observed with A14- and B26-[125I]monoiodoinsulin. 264 37

A tumor antigen isolated from the cytosol of a methylcholanthrene-induced sarcoma (Meth A) has been purified to homogeneity by the criteria of two-dimensional gel analysis and NH2- and COOH-terminal sequencing. The purified antigen has a mol. wt of 82,000 by SDS gel electrophoresis. However, the apparent mol. mass of the antigen was found to be 71,600 and 67,700 by gel filtration chromatography and sedimentation analysis, respectively. It is not a glycoprotein, possesses an acidic isoelectric point (6.0) and exists as dimeric and monomeric species. The dimer is not held together by disulfide bonds. The purified protein retains its ability to induce transplantation immunity in syngeneic hosts when challenged with Meth A sarcomas. Chemical analyses of the NH2- and COOH-termini gave the following sequences: NH2-PKPINVRVTTMDAELEFAIQPN and IDE(F,A)EM-COOH, respectively.
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PMID:Characterization of a chemically homogeneous tumor antigen from a methylcholanthrene-induced sarcoma, Meth A. 374 14

Matrix metalloproteinases (MMPs) are involved in connective tissue turnover under physiological and pathological conditions. MMP activity is regulated by the requirement for zymogen activation. This report describes a proMMP-3 activator produced by articular cartilage. The activator initiates a step-wise processing of proMMP-3 to generate an array of active species. Sequencing of activation intermediates demonstrated cleavage on the NH2-terminal side of certain basic residues in the MMP-3 propeptide. Metal ion chelators inhibited activator-dependent proteolysis, and activity was restored by low levels of ZnCl2. These catalytic properties suggest similarity to members of the insulinase superfamily of metalloendopeptidases with in vitro specificity for single arginine or paired basic processing sites in a variety of prohormones. Dibasic sites also exist in the propeptides of several MMPs including proMMP-3. This is the first report that cartilage produces a potent MMP proenzyme activator, opening the possibility of a novel intrinsic activation pathway for catabolic processes in this avascular tissue.
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PMID:A matrix metalloproteinase proenzyme activator produced by articular cartilage. 964 25