UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Staphylococcus aureus strain V8 protease is a serine endopeptidase which cleaves peptide bonds at the carboxyl side of Glu and Asp. Specific cleavage at Glu has previously been achieved in ammonium bicarbonate whereas in sodium phosphate cleavage at both Glu and Asp was observed. However, it is shown here that bicarbonate does not restrict the specificity to Glu-X bonds, it simply inhibits the enzyme. The degradation of a mixture of oxidized insulin and glucagon proceeds similarly in the two buffers, although faster in phosphate.
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PMID:Fragmentation of proteins by S. aureus strain V8 protease. Ammonium bicarbonate strongly inhibits the enzyme but does not improve the selectivity for glutamic acid. 168 51

Glucagon-(19-29) is 1000-fold more potent that glucagon as an inhibitor of the liver plasma membrane calcium pump, which suggests that this peptide fragment is naturally occurring. Since glucagon-(19-29) is undetectable in plasma, the processing of glucagon into its (19-29) fragment may occur upon interaction of glucagon with its target tissues. The use of a specific radioimmunoassay for glucagon-(19-29) in association with the separation and identification of peptides by high performance liquid chromatography revealed that, upon incubation at 37 degrees C with hepatic plasma membranes, glucagon is processed into its (19-29) C-terminal fragment. The identity of the fragment was confirmed by amino acid sequencing. The processing activity was inhibited by reagents of the thiol group and by 1,10-phenanthroline, suggesting that a thiol endopeptidase containing a catalytically active metal is involved in this processing. Following its production, glucagon-(19-29) was degraded with a half-life of less than 10 s. This degradation was inhibited by bacitracin and by the aminopeptidase inhibitors bestatin and amastatin. When glucagon was incubated with liver plasma membranes in the absence of inhibitors, the accumulation of glucagon-(19-29) reached a maximum at 2 min (1% of initial glucagon), followed by a slow decline. In the presence of bacitracin and bestatin, the amounts of glucagon-(19-29) obtained from glucagon increased continuously, 1 and 2% of glucagon being transformed after 10 and 30 min, respectively. The production of glucagon-(19-29) did not appear to be associated with the binding of glucagon to its receptors, since (i) guanosine 5'-(3-O-thio)triphosphate, a compound which decreases the glucagon-receptor interaction, could not decrease the conversion of glucagon into glucagon-(19-29); (ii) a glucagon analogue which displays a strongly decreased affinity for the hepatic glucagon receptors was processed similarly to glucagon. The conversion also occurs upon incubation with intact hepatoma cells in monolayer culture. These observations suggest that, under physiological conditions, glucagon is processed in liver by cleavage of the Arg17-Arg18 basic doublet, leading to the production of a fragment which is known to display an original biological specificity, namely the modulation of the hepatocyte plasma membrane calcium pump.
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PMID:Glucagon-(19-29), a Ca2+ pump inhibitory peptide, is processed from glucagon in the rat liver plasma membrane by a thiol endopeptidase. 214 84

Recent studies using inhibitors or synthetic substrates of serine protease suggest that membrane protease activity may be essential for neutrophil chemotaxis, phagocytosis, degranulation, and superoxide production. However, little is known about the nature and localization of the proteases. In this study, we demonstrated that intact human neutrophils hydrolyzed [125I]glucagon. The degradation of glucagon was temperature dependent and was not dependent on the release of lysosomal enzymes. Two endopeptidases were demonstrated: a metalloendopeptidase which accounted for two thirds of the intact cell activity, and a serine endopeptidase, accounting for the rest of the activity. Both enzymes had a neutral to alkaline pH optimum (pH 7-9). The metalloendopeptidase had a Km of 15.3 microM and Vmax of 5.9 nmol/5 X 10(6) cells/45 min. The corresponding values for the serine endopeptidase were 33.3 microM and 5.0 nmol/5 X 10(6) cells/45 min, respectively. Inhibition of the membrane metalloendopeptidase or serine endopeptidase by 1,10-phenanthroline or diisopropylfluorophosphate, respectively, did not inhibit the production of superoxide by phorbol myristate acetate-stimulated neutrophils.
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PMID:Membrane endopeptidases of human neutrophil. 298 72

Cathepsin-D has been previously reported to cleave intact PTH into PTH-(1-34) and -(35-84) in membranous fractions of rat and bovine kidney. Whether PTH degradation occurs by intact kidney cells, however, has not been examined in detail. We have, therefore, examined this possibility using an opossum kidney (OK) cell line which possesses the characteristics of proximal renal tubules and responds to PTH. PTH radioimmunoreactivity recovered in trichloroacetic acid-soluble products and in fractions eluted from reverse phase HPLC was measured using an antibody directed to the midregion and C-terminus of PTH. In this study, intact OK cells, but not extracellular enzymes, cleaved human (h) PTH-(1-84) into three discrete fragments which were released into the medium in a time- and temperature-dependent fashion. Half-maximal velocity of PTH-degrading activity (PTHDA) was observed at 9 nM hPTH-(1-84). A 1000-fold molar excess of PTH antagonists [hPTH-(3-34) and [Tyr34]hPTH-(7-34)amide] markedly inhibited PTHDA, whereas ACTH, glucagon, or big gastrin did not suppress it, suggesting an involvement of the PTH receptor in PTHDA. This PTHDA was strongly inhibited by phenylmethylsulfonylfluoride and chymostatin, but not by trypsin inhibitor, elastatinal, or inhibitors of aspartic, cysteine, or metalloproteinases, suggesting that it is due to a seryl chymotrypsin-like endopeptidase. Analysis of chymotrypsin-digested products of hPTH-(1-84) eluted from HPLC exhibited five fragments detected by UV absorbance (210 nm), three of which were measurable by PTH RIA, and each corresponded to the three PTH fragments produced by OK cells. All three fragments were predominantly suppressed in the presence of chymostatin, suggesting that chymotrypsin-like activity is solely responsible for PTHDA in intact OK cells. To further explore the cleavage sites of PTH by chymotrypsin, amino acid analysis of chymotrypsin-cleaved products was performed. The results strongly support the conclusion that a chymotrypsin-like enzyme in OK cells cleaved the hormone between residues 23-24, and 34-35 to produce, at least, hPTH-(24-84) and -(35-84). Lysosomal blockers (chloroquine, ammonium chloride, or monensin) did not affect this PTHDA. Our present study indicates that chymotrypsin-like endopeptidase, but not other endopeptidase or lysosomal enzymes, is responsible for the limited hydrolysis of PTH by intact OK cells.
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PMID:Parathyroid hormone degradation by chymotrypsin-like endopeptidase in the opossum kidney cell. 305 60

An endopeptidase (LEP-II), which has a unique substrate specificity, was purified to homogeneity by conventional chromatographic techniques from Streptococcus cremoris H61. The enzyme was a metalloendopeptidase since it was inhibited by EDTA and 1,10-phenanthroline; the metal-depleted enzyme could be fully reactivated by micromolar levels of Zn2+ and was not inhibited by specific inhibitors for serine or thiol protease. The molecular mass of the enzyme was estimated to be 80 kDa by Sephacryl S-300 gel filtration and high-performance liquid chromatography with a TSK-G3000SW column. The enzyme consisted of two identical subunits and the N-terminal sequence of LEP-II was determined up to the 19th residue. Although the enzyme had a broad substrate specificity it specifically hydrolyzed the peptide bonds involving the amino groups of hydrophobic amino acid residues. Various small polypeptides, such as alpha s1-CN(f1-23), alpha s1-CN(f91-100), oxidized insulin B chain, glucagon and some biologically active peptides were hydrolyzed. However, a variety of larger polypeptides or proteins, such as alpha s1-CN(f1-54), alpha s1-CN(f61-123), alpha s1-CN(f136-196), alpha s1-casein, beta-casein, and kappa-casein were not hydrolyzed. LEP-II recognized the size of its substrates, which were limited below a molecular mass of about 3.5 kDa.
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PMID:Purification and characterization of a novel metalloendopeptidase from Streptococcus cremoris H61. A metalloendopeptidase that recognizes the size of its substrate. 354 30

1. A neutral peptidase, previously shown to be located in the brush border of the proximal tubule, and assayed by its ability to hydrolyse [(125)I]iodoinsulin B chain was purified from rabbit kidney. 2. The starting material for the purification was a microsomal pellet prepared from a homogenate of cortical tissue. The membrane-bound enzymes were solubilized by treatment with toluene and trypsin. About half the neutral peptidase activity was released by this treatment in a form that no longer sedimented with the microsomal pellet and which penetrated polyacrylamide gels when subjected to disc electrophoresis. Other treatments with detergents or proteolytic enzymes either inactivated the peptidase or failed to convert it into a genuinely soluble form. 3. Chromatography with successive columns of Sephadex G-200, DEAE-cellulose and hydroxyl-apatite yielded an enzyme that was free of other brush-border peptidase activities and which was homogeneous on disc electrophoresis and ultracentrifugation. 4. The purified enzyme attacked [(125)I]iodoglucagon at a rate comparable with that for [(125)I]iodoinsulin B chain. It did not appear to attack proteins (insulin, albumin and casein) that had been similarly iodinated. 5. Unlabelled insulin B chain and unlabelled glucagon were substantially hydrolysed by the endopeptidase, whereas insulin and albumin released only trivial amounts of ninhydrin-reacting material. The resistance of insulin to attack by endopeptidase, even after prolonged incubation, was confirmed by biological and immunoassay. 6. The specificity of the peptidase was determined by analysis of the products after incubating unlabelled insulin B chain, and some oligopeptide substrates, including pentagastrin, with the enzyme. All of the bonds readily cleaved were those involving the alpha-amino group of hydrophobic residues, i.e. x-Leu-, x-Val-, x-Tyr-, x-Phe- and x-Met-, provided that the residues were not C-terminal. 7. The enzyme showed only endopeptidase activity. Substrates suitable for aminopeptidases, carboxypeptidases or esterases were not attacked.
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PMID:The purification and specificity of a neutral endopeptidase from rabbit kidney brush border. 442 92

Previous studies have shown that a neutral metallo-endopeptidase purified from rat kidney degrades the B chain of insulin, glucagon, ACTH and, at a markedly slower rate, the A chain of insulin. In contrast the enzyme does not attack native insulin, oxytocin, vasopressin, ribonuclease, albumin or denatured hemoglobin. The current studies demonstrate that the neutral peptidase also degrades the isolated C-peptide of proinsulin and cleaves certain peptide bonds in and near the C-peptide moiety of native proinsulin. Time courses of the formation of fluorescamine-reactive material during digestion of proinsulin and isolated C-peptide with the peptidase were identical. However, structural analysis of the peptidase-digested proinsulin showed that the enzyme does not convert proinsulin to insulin but that the peptidase cleaves one bond, Tyr26-Thr27, in the B chain moiety and five bonds in the C-peptide moiety, producing four split proinsulins. One of the split proinsulins is des-octacosa-peptide (27-54) porcine proinsulin or des-tetracosapeptide (27-50) bovine proinsulin. Each is a derivative of the insulin molecule having an extension of nine residues (ten residues in the case of the derivative from bovine proinsulin) at the N-terminus of A chain and lacking four residues at the C-terminus of B chain. This two chain derivative retains full immunoreactivity with insulin antibodies and exhibits 2.4-times more biological activity (promotion of glycogenesis in primary cultured hepatocytes) than proinsulin and about two-thirds the activity of insulin.
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PMID:Degradation of proinsulin and isolated C-peptide by rat kidney neutral metallo-endopeptidase. 702 23

The proteolytic specificity of cathepsin L on glucagon was determined. Major cleavages are found between Thr7 and Ser8, Asp15 and Ser16, and between Met27 and Asn28. The bonds Ser11-Lys12, Val23-Gln24, and Gln24-Trp25 are hydrolyzed to a relatively low extent only. Whereas cathepsin B hydroxyzes glucagon at the C-terminus by a peptidyldipeptidase mechanism, cathepsin L cleaves the same substrate clearly as endopeptidase.
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PMID:Action of rat liver cathepsin L on glucagon. 734 Mar 37

Sixty-four kinds of cell lines were examined as to their ability to degrade glucagon using conditioned-media obtained from their protein-free cultures. Two human tumor cell lines were shown to produce this activity, and the cell line, HPC-YO, established from a human pancreatic carcinoma was shown to produce the highest level of activity. The glucagon-degrading enzyme (GDE) was purified from HPC-YO conditioned-medium by a combination of ion-exchange, gel filtration, and hydroxylapatite column chromatographies. The purified GDE also degraded vasoactive intestinal polypeptide (VIP) and secretin, however, it did not cleave EGF, gastrin, insulin, somatostatin, substance P, neurotensin, or growth hormone. The molecular weight of GDE is 83,000, as determined on SDS-polyacrylamide gel electrophoresis. The N-terminal amino acid sequence of GDE was blocked, and the five partial amino acid sequences obtained on lysyl-endopeptidase digestion were determined to be N-L-T-E-E-Y-D-V-S-D-G-E-I-E-L-L-Y-E-K, V-E-T-Y-Y-D-L-L-F-E-K, L-Y-W-F-L-D-E-A-K, S-N-S-T-S-Y-V-K, and Y-Y-A-S-T-S-Y-D-D-T-Y-K. The same or homologous amino acid sequences have not been found in known proteins, demonstrating that GDE is a novel peptidase that degrades the secretin family: glucagon, VIP, and secretin.
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PMID:A novel proteinase, glucagon-degrading enzyme, secreted by a human pancreatic cancer cell line, HPC-YO. 777 1

The acidic glucagon-degrading activity of hepatic endosomes has been attributed to membrane-bound forms of cathepsins B and D. Endosomal lysates processed full-length nonradiolabeled glucagon to 32 different peptides that were identified by amino acid analysis and full-length sequencing. These indicated C-terminal carboxypeptidase, endopeptidase as well as N-terminal tripeptidyl-aminopeptidase activities in endosomes. Glucagon proteolysis was inhibited 95% by E-64 and pepstatin A, inhibitors of cathepsins B and D, respectively. This was confirmed by the pH 6-dependent chemical cross-linking of [125I]iodoglucagon to a polypeptide of 30 kDa, which was immunodepleted by polyclonal anti-cathepsin B antibody, and the removal of greater than 80% of glucagon-degrading activity by polyclonal antibodies to cathepsins B and D. By similar criteria, insulin-degrading enzyme was ruled out as a candidate enzyme for endosomal proteolysis of glucagon. Lysosomal contamination was unlikely since all forms of cathepsin B in endosomes, i.e. the major 45-kDa inactive precursor as well as the lesser amounts of the 32- and 28-kDa active forms, were tightly bound to endosomal membranes. Furthermore the mature 29-kDa single-chain and 22-kDa heavy-chain forms of cathepsin L were undetectable in endosomes, although high levels of the 37-kDa proform were observed. Membrane association of the cathepsins B and D was not to the mannose 6-phosphate receptor since association was unaffected by mannose 6-phosphate and/or EDTA, thereby indicating a distinct endosomal receptor. Hence, a pool of active cathepsins B and D as well as a poorly defined tripeptidyl aminopeptidase is maintained in endosomes by selective membrane retention. These hydrolases degrade glucagon internalized into liver parenchyma early in endocytosis.
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PMID:Proteolysis of glucagon within hepatic endosomes by membrane-associated cathepsins B and D. 779 82

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