Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.21.4 (trypsin)
42,187 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mechanism by which negatively charged substances such as celite, kaolin, or ellagic acid contribute to the surface-dependent activation of Hageman factor (Factor XII) was studied. Kinetic studies of the proteolytic activation of (125)I-labeled human Hageman factor by human plasma kallikrein, plasma, activated Factor XI, and trypsin were performed in the presence and absence of high molecular weight kininogen and surface materials such as celite, kaolin, or ellagic acid. The results showed that surface-bound Hageman factor was 500 times more susceptible than soluble Hageman factor to proteolytic activation by kallikrein in the presence of high molecular weight kininogen. Surface binding of Hageman factor enhanced its cleavage by plasmin, activated Factor XI, and trypsin by 100-fold, 30-fold, and 5-fold, respectively. On a molar basis, trypsin was twice as potent as kallikrein in the cleavage of the surface-bound Hageman factor, while plasmin and activated Factor XI were an order of magnitude less potent than kallikrein. Kallikrein even at concentrations as low as 0.5 nM (i.e., 1/1000th of the concentration of prekallikrein in plasma) was very potent in the limited proteolysis of the surface-bound Hageman factor. These results suggest that substances classically known as "activating surfaces" promote the activation of Hageman factor indirectly by altering its structure such that it is much more susceptible to proteolytic activation by other plasma or cellular proteases.
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PMID:Role of surface in surface-dependent activation of Hageman factor (blood coagulation factor XII). 27 26

Recent studies of individuals with high molecular weight (HMW) kininogen deficiency established the importance of this plasma protein for in vitro initiation of blood coagulation. In the present study, HMW-kininogen was highly purified from human plasma by monitoring its clot-promoting activity, using Fitzgerald trait plasma as a substrate. This preparation of HMW-kininogen revealed a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (mol wt: 120,000) and released 1% of its weight as bradykinin upon incubation with plasma kallikrein. HMW-kininogen specifically repaired impaired surface-mediated plasma reactions of Fitzgerald trait plasma, but did not affect those of Hageman trait and Fletcher trait plasma. Kinin release from HMW-kininogen by trypsin, but not by plasma kallikrein, resulted in total loss of clot-promoting activity. No inhibitors of coagulation were found when all kinin activity was removed from HMW-kininogen by trypsin. The roles of HMW-kininogen, Hageman factor (HF, Factor XII), plasma prekallikrein (Fletcher factor), and plasma thromboplastin antecedent (PTA, Factor XI) in blood coagulation were studied in a purified system. HMW-kininogen was absolutely required for activation of PTA by HF and ellagic acid. The yield of activated PTA was proportional to the amount of HF, HMW-kininogen, and PTA in the mixtures, suggesting that, to activate PTA, these three proteins might form a complex in the presence of ellagic acid. No fragmentation of HF was found under these conditions. In contrast to HF, HF-fragments (mol wt: 30,000) activated PTA in the absence of HMW-kininogen and ellagic acid. Thus, it appears that in the present study PTA was activated in two distinct ways. Which pathway is the major one in whole plasma remains to be determined.
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PMID:Purification of high molecular weight kininogen and the role of this agent in blood coagulation. 89 64

A blood coagulation factor, Factor XIII, was highly purified from bovine fresh plasma by a method similar to those used for human plasma Factor XIII. The isolated Factor XIII consisted of two subunit polypeptides, a and b chains, with molecular weights of 79,000 +/- 2,000 and 75,000 +/- 2,000, respectively. In the conversion of Factor XIII to the active enzyme, Factor XIIIa, by bovine thrombin [EC 3.4.21.5], a peptide was liberated. This peptide, designated tentatively as "activation peptide," was isolated by gel-filtration on a Sephadex G-75 column. It contained a total of 37 amino acid residues with a masked N-terminal residue and C-terminal arginine. The whole amino acid sequence of "Activation peptide" was established by the dansyl-Edman method and standard enzymatic techniques, and the masked N-terminal residue was identified as N-acetylserine by using a rat liver acylamino acid-releasing enzyme. This enzyme specifically cleaved the N-acetylserylglutamyl peptide bond serine and the remaining peptide, which was now reactive to 1-dimethylamino-naphthalene-5-sulfonyl chloride. A comparison of the sequences of human and bovine "Activation peptide" revealed five amino acids replacements, Ser-3 to Thr; Gly-5 to Arg; Ile-14 to Val; Thr-18 to Asn, and Pro-26 to Leu. Another difference was the deletion of Leu-34 in the human peptide. Adsorption chromatography on a hydroxylapatite column in the presence of 0.1% sodium dodecyl sulfate was developed as a preparative procedure for the resolution of the two subunit polypeptides, a or a' chain and b chain, constituting the protein molecule of Factor XIII or Factor XIIIa. End group analyses on the isolated pure chains revealed that the structural change of Factor XIII during activation with thrombin occurs only in the N-terminal portion of the a chain, not in the N-terminal end of the b chain or in the C-terminal ends of the a and b chains. From these results, it was concluded that the activation of bovine plasma Factor XIII by thrombin must be accompanied by a limited proteolysis of the arginyl-glycyl bond located in the N-terminal region of the a chain, liberating the "Activation peptide." The possibility of activating Factor XII with other porteinases was examined using Factor Xa [EC 3.4.21.6], Factor XIIa, kallikreins [EC 3.4.21.8], urokinase [EC 3.4.99.26], trypsin [EC 3.4.21.4], ficin [EC 3.4.22.3], papain [EC 3.4.22.2], and bromelain [EC 3.4.22.4]. Among these enzymes, only bromelain and trypsin showed clear activating effects.
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PMID:On the activation of bovine plasma factor XIII. Amino acid sequence of the peptide released by thrombin and the terminal residues of the subunit polypeptides. 122 22

We studied the characteristics of two monoclonal antibodies (mAbs), F1 and F3, against human coagulation factor XII (Hageman factor). Experiments with trypsin-digested 125I-factor XII revealed that the epitope for mAb F1 is located in the NH2-terminal Mr 40,100 portion of factor XII, whereas that for mAb F3 resides in the COOH-terminal Mr 30,000 portion of this protein. Factor XII in fresh plasma (single-chain factor XII) bound approximately 190 times less to mAb F1 than factor XII in dextran sulfate-activated plasma (cleaved factor XII). However, no difference in accessibility of the epitope for mAb F1 was observed between cleaved and single-chain factor XII when bound to glass. mAb F3 appeared to bind to both single-chain and cleaved factor XII in plasma as well as when bound to glass. Neither mAb F1, nor F3 affected the amidolytic activity of factor XIIa, whereas both mAb F1 and F3 inhibited factor XII-coagulant activity to about 15 and 70%, respectively, at a molar ratio of mAb to factor XII of 20 to 1. mAb F1, as well as F(ab')2 and F(ab') fragments of this antibody induced activation of the contact system in plasma, as reflected by the generation of factor XIIa. C1 inhibitor and kallikrein. C1 inhibitor complexes. Activation was induced neither upon incubation with mAb F3, nor with that of control mAbs. mAb F1-induced contact activation required the presence of factor XII, prekallikrein, and high molecular weight kininogen and, in contrast to activation by negatively charged surfaces, was not inhibited by the presence of Polybrene. Based on these results we propose that a conformational change in factor XII is a key event in the activation process of this molecule. This conformational change can be induced by binding of factor XII to a surface as well as by proteolytic cleavage. As mAb F1 can also induce this conformational change, this antibody may provide a unique tool in studies of the activation of factor XII.
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PMID:Activation of the contact system of coagulation by a monoclonal antibody directed against a neodeterminant in the heavy chain region of human coagulation factor XII (Hageman factor). 247 84

The effect of tryptase, a neural protease released from human lung mast cell secretory granules, on purified human Hageman Factor (Factor XII) was examined. No increase in Hageman Factor enzymatic activity was detected after incubation with tryptase at 37 degrees C; activation of Hageman Factor by bovine trypsin served as a positive control. Furthermore, pre-incubation of Hageman Factor with tryptase did not diminish the subsequent activation of Hageman Factor by trypsin. Polyacrylamide gel electrophoresis was also performed to show that incubation with tryptase does not alter the molecular weight of Hageman Factor. Therefore, tryptase neither activates nor destroys human Hageman Factor.
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PMID:Tryptase from human mast cells does not activate purified human Hageman factor. 328 68

Plasma prekallikrein, a precursor protein of kallikrein [EC 3.4.21.8], was highly purified from porcine plasma by chromatography on a DEAE-Sephadex A-50 column, followed by rechromatography on a DEAE-Sephadex A-50 column, chromatography on a CM-Sephadex C-50 column and affinity chromatography on a p-aminobenzamidine-epsilon-aminocaproic acid-Sepharose 4B column. By this procedure, 3.3 mg of purified material was obtained from 1.6 liters of porcine plasma and about 240-fold purification was achieved from the first DEAE-Sephadex A-50 chromatography. The purified protein was found to give a single band on sodium dodecyl sulfate (SDS)-polyacrylamide gel disc electrophoresis. This preparation did not contain kallikrein, Factor XII (Hageman factor) of the blood coagulation system, high molecular weight (HMW) kininogen or plasma kininase. Thus, the material is presumed to be functionally pure. The molecular weight of prekallikrein was estimated to be about 88,000 by SDS-polyacrylamide gel electrophoresis, and prekallikrein consists of a single polypeptide chain. Activation of prekallikrein by trypsin [EC 3.4.21.4] was found to involve the cleavage of a single peptide bond on the disulfide-bridged polypeptide chain, and no change of molecular weight was observed during the activation. This trypsin-activated kallikrein released kinin rapidly from bovine HMW kininogen. However, liberation of kinin was extremely slow from bovine low molecular weight (LMW) kininogen. The kallikrein activity was inhibited by soybean trypsin inhibitor (SBTI) and Trasylol, but not by Polybrene or egg-white trypsin inhibitor (EWTI).
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PMID:Purification of prekallikrein from porcine plasma and its conversion to active kallikrein. 655 87

Fujiwara trait, the first case of kininogen deficiency in Japan previously reported which did not show any clinical symptom except the prolonged activated partial thromboplastin time was further examined. The activated partial thromboplastin time of the patient was corrected by addition of normal, Factor XII deficient or Fletcher plasma, but not corrected by Fitzgerald or Williams plasma. It was also corrected by addition of highly purified bovine or human high molecular weight (HMW) kininogen, but not by low molecular weight (LMW) kininogen. When total kininogen was measured as the amount of bradykinin released by trypsin, only a trace amount was detected in Fujiwara as well as Williams plasma. No immunoreactive protein against anti-human-HMW-kininogen nor anti-human-LMW-kininogen was found in Fujiwara plasma. Acetone-kaolin-activated plasma kallikrein was not generated by Fujiwara plasma. Substitution with normal plasma in various ratios showed the generation of various plasma kallikrein activities. Calculations with these activities of mixed plasma gave the prekallikrein content of Fujiwara trait plasma about 30% of the normal level. These results suggest that Fujiwara trait is very similar to Williams trait in that both plasmas were deficient in HMW and LMW kininogens with reduced content of prekallikrein.
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PMID:Abnormalities in the contact activation through factor XII in Fujiwara trait: a deficiency in both high and low molecular weight kininogens with low level of prekallikrein. 678 99

Exposure of human blood polymorphonuclear leukocytes (PMN) to purified active plasma kallikrein resulted in PMN aggregation when kallikrein was present at concentrations ranging from 0.4 to 0.6 U/ml (0.18-0.27 microM). Kallikrein-induced PMN aggregation was not mediated through C5-derived peptides, because identical responses were observed whether or not kallikrein had been preincubated with an antibody to C5. Moreover, kallikrein was specific for aggregating PMN, because no aggregation was observed with Factor XII active fragments (23 nM), Factor XIa (0.6 U/ml or 15nM), thrombin (1.6 microM), plasmin (2 microM), porcine pancreatic elastase (2 microM), bovine pancreatic chymotrypsin (2 microM), or bradykinin (1 microM). Bovine pancreatic trypsin (2 microM) aggregated PMN, but to a lesser extent than kallikrein (0.18 microM). Kallikrein was a potent aggregant agent for PMN because similar responses were observed with kallikrein (0.5 U/ml or 0.23 microM) and an optimal dose (0.2 microM) of N-formyl-methionyl-leucyl-phenylalanine. In addition, PMN incubation with kallikrein resulted in stimulation of their oxidative metabolism as assessed by an increased oxygen uptake. Neutropenia and leukostasis observed in diseases associated with activation of the contact phase system may be the result of PMN aggregation by plasma kallikrein.
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PMID:Purified human plasma kallikrein aggregates human blood neutrophils. 691 55

To elucidate the role of charged groups in expression of factor XI coagulant activity, the charged groups of purified human blood coagulation factor XI/XIa containing 125I-XI/XIa were derivatized: free amino groups by succinylation, guanido groups of arginine by reaction with phenylglyoxal hydrate, and free carboxyl groups by reaction with ethylenediamine. The modified proteins were tested for: 1) ability to adsorb to glass, 2) ability to be cleaved by trypsin or factor XII-high molecular weight kininogen, 3) coagulant activity. The amino group-modified factor XI had a significantly decreased ability to bind to glass; modification of arginine or carboxyl groups did not affect adsorption. Trypsin cleaved factor XI with modified free amino, guanido, or carboxyl groups. Factor XII-high molecular weight kininogen could cleave only the arginine-modified factor XI. Amino group-modified factor XI and carboxyl group-modified factor XI lost all their factor XI assay activity, whereas arginine-modified factor XI retained 50% of the original activity. Amino group-modified factor XI could not be activated by trypsin, but arginine-modified and carboxyl group-modified factor XI could be activated by trypsin to 50% of the original activity. Succinylation of the amino groups of factor XIa destroyed all its factor XIa activity. Arginine-modified and carboxyl group-modified factor XIa retained 50% of their factor XIa activity. We conclude that epsilon-amino groups are essential for adsorption; activation by factor XII-high molecular weight kininogen requires free amino and carboxyl but not guanido groups; free amino, carboxyl, and guanido groups in factor XIa all appear to be critical for interaction of factor XIa with factor IX.
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PMID:Role of charged groups in factor XI/XIa activity. 698 45

In a previous study we have shown that monoclonal antibody F1 (MoAb F1), directed against an epitope on the heavy chain of factor XII distinct from the binding site for anionic surfaces, is able to activate factor XII in plasma (Nuijens JH, et al: J Biol Chem 264; 12941, 1989). Here, we studied in detail the mechanism underlying the activation of factor XII by MoAb F1 using purified proteins. Formation of factor XIIa was assessed by measuring its amidolytic activity towards the chromogenic substrate H-D-Pro-Phe-Arg-pNA (S-2302) in the presence of soybean trypsin inhibitor and by assessing cleavage on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Upon incubation with MoAb F1 alone, factor XII was auto-activated in a time-dependent fashion, activation being maximal after 30 hours. Factor XII incubated in the absence of MoAb F1 was hardly activated by kallikrein, whereas in the presence of MoAb F1, but not in that of a control MoAb, the rate of factor XII activation by kallikrein was promoted at least 60-fold. Maximal activation of factor XII with kallikrein in the presence of MoAb F1 was reached within 1 hour. This effect of kallikrein on the cleavage of factor XII bound to MoAb F1 was specific because the fibrinolytic enzymes plasmin, urokinase, and tissue-type plasminogen activator could not substitute for kallikrein. Also, trypsin could easily activate factor XII, but in contrast to kallikrein, this activation was independent of MoAb F1. SDS-PAGE analysis showed that the appearance of amidolytic activity correlated well with cleavage of factor XII. MoAb F1-induced activation of factor XII in this purified system was not dependent on the presence of high-molecular-weight kininogen (HK), in contrast to the activation of the contact system in plasma by MoAb F1. Experiments with deletion mutants revealed that the epitopic region for MoAb F1 on factor XII is located on the kringle domain. Thus, this study shows that binding of ligands to the kringle domain, which does not contribute to the proposed binding site for negatively charged surfaces, may induce activation of factor XII. Therefore, these findings point to the existence of multiple mechanisms of activation of factor XII.
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PMID:Monoclonal antibody F1 binds to the kringle domain of factor XII and induces enhanced susceptibility for cleavage by kallikrein. 749 70


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