EC:3.4.21.7 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.7 (plasmin)
9,023 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

Kallikrein activity in human stomach tissue was measured and found to be about threefold higher in cancer tissue than in normal tissue. To clarify the physiological role of this tissue kallikrein, we investigated its effects on the spontaneous metastasis and tumor growth of Lewis tumors (3LL). Antiprotease, aprotinin, and gabexate mesilate (FOY) inhibited spontaneous metastasis but did not inhibit tumor growth, while tissue kallikrein and plasmin enhanced the spontaneous metastasis of 3LL. The results suggest that the inhibitory effects of aprotinin and FOY on metastasis are not only due to an inhibition of tumor cells released by tissue kallikrein, but that tissue kallikrein, a protease, also participates in metastasis. We thus conclude that aprotinin or FOY should be administered either before or immediately after operation to inhibit spontaneous metastasis.
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PMID:Effect of aprotinin on metastasis of Lewis lung tumor in mice. 138 25

EDTA plasma from patients with hereditary angioedema (HAE), the genetic deficiency of C1-inhibitor, when incubated at 37 degrees produces a kinin-like activity which can induce contraction of oestrus rat uterus. The second component of complement (C2) has previously been suggested to be the source of this kinin-like activity, with the implication that C2-kinin is a normal product of complement activation. Our results show that purified human C2 is cleaved rapidly to C2a and C2b when added to HAE plasma, but not normal plasma or plasma from a danazol-treated HAE patient. However, the addition to HAE plasma of C2 at 20 X normal plasma concentration had no effect on the kinin activity generated on incubation at 37 degrees. In the presence of soya bean trypsin inhibitor, the rate of C2 cleavage and products were unaltered but no kinin activity was generated. C2 was cleaved by purified C1s to C2a and C2b. Incubation of C2 with trypsin resulted in cleavage to C2a and C2b followed by more extensive cleavage of both C2a and C2b. Kallikrein cleaved C2 to C2a and C2b but plasmin had no effect on C2. In no case was kinin activity generated. When C2 was cleaved by C1s to C2a and C2b then incubated with trypsin, kallikrein, or plasmin, no kinin activity was generated: only trypsin cleaved the C2 fragments further. The results suggest that C2 is not the source of the kinin-like activity generated in hereditary angioedema plasma.
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PMID:Cleavage of the second component of complement by plasma proteases: implications in hereditary C1-inhibitor deficiency. 293 17

The activation of Hageman factor in solid and fluid phase has been analyzed. Activation of highly purified Hageman factor occurred after it interacted with and became bound to a negatively charged surface. Activation was observed in the absence of enzymes that are inhibitable with diisopropylfluorophosphate, phenyl methyl sulfonyl fluoride and epsilon-amino-n-caproic acid. The binding of [(125)I]Hageman factor to the negatively charged surface was markedly inhibited by plasma or purified plasma proteins. Activation of Hageman factor in solution (fluid phase) was obtained with kallikrein, plasmin, and Factor XI (plasma thromboplastin antecedent). Kallikrein was greater than 10 times more active in its ability to activate Hageman factor than plasmin and Factor XI. The data offer a plausible explanation for the finding that highly purified kallikrein promotes clotting of normal plasma. In addition, the combined results of this and previously reported data from this laboratory indicate that the reciprocal activation of Hageman factor by kallikrein in fluid phase is essential for normal rate of activation of the intrinsic-clotting, kinin-forming, and fibrinolytic systems. Activation of Hageman factor was associated with three different structural changes in the molecule: (a) Purified Hageman factor, activated on negatively charged surfaces retained its native mol wt of 80-90,000. Presumably a conformational change accompanied activation. (b) In fluid phase, activation with kallikrein and plasmin did not result in cleavage of large fragments of rabbit Hageman factor, although the activation required hydrolytic capacity of the enzymes. (c) Activation of human Hageman factor with kallikrein or plasmin was associated with cleavage of the molecule to 52,000, 40,000, and 28,000 mol wt fragments. Activation of rabbit Hageman factor with trypsin resulted in cleavage of the molecule into three fragments, each of 30,000 mol wt as noted previously. This major cleavage occurred simultaneously with activation.
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PMID:Activation of Hageman factor in solid and fluid phases. A critical role of kallikrein. 427 29

Proteinases are classified into four groups according to their catalytic mechanisms: the serine, cysteine (thiol), aspartic (carboxyl), and metallo-proteinases. Neutrophil granulocytes contain a variety of neutral proteinases and two acid proteinases. Lysosomal proteinases are released from cells during phagocytosis, cell death, or exposure to antigen-antibody complexes, complement factors, and toxins. Under pathological conditions, massive proteinase release may cause tissue injury and degradation of plasma proteins. Plasma proteolytic activity is controlled by inhibitors of blood systems (antithrombin III, C1 inhibitor, and plasmin inhibitor) and by inhibitors against proteinases of various body cells (alpha 1-proteinase inhibitor, alpha 1-antichymotrypsin, beta 1-collagenase inhibitor, and inter-alpha-trypsin inhibitor). Intracellular proteinases are controlled by different cytosolic inhibitors. In hypercatabolic states (septicemia, trauma, burns), the concentrations of many plasma proteins, including proteinase inhibitors, are decreased. Kallikrein-kinin, complement, and fibrinolytic systems may be activated, probably due to enhanced proteinase activity. In acute renal failure, there is a release of granulocyte neutral proteinases. The plasma concentration of the elastase-alpha 1-proteinase inhibitor complex is simultaneously increased. Granulocytes of chronically uremic patients treated with diet or regular dialysis have a slightly to markedly reduced proteinase content as compared with normal controls. There is a dramatic rise of the plasma elastase alpha 1-proteinase inhibitor complex during hemodialysis treatment.
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PMID:Proteolytic enzymes and catabolism: enhanced release of granulocyte proteinases in uremic intoxication and during hemodialysis. 637 17

A protein extract was obtained from normal human serum by adsorption to unsubstituted Sepharose 4B. This extract contained one or several enzymes with SAA and AA degrading capacity. The optimal pH for degradation of SAA was about 7.3. On fractionation of the enzyme extract on Sephadex G-160, the active component was eluted in the V0 peak. The V0 fraction, which on double immunodiffusion analysis was found to contain alpha 2-macroglobulin, was also active against synthetic substrates used to determine the activity of thrombin and plasma kallikrein. Gel filtration under dissociating conditions and molecular weight estimation further indicated the presence of those enzymes in the preparation. Several serine proteases which are known to be inhibited by alpha 2-macroglobulin possessed AA and SAA degrading activity. On degradation of SAA, an intermediate split product with molecular weight similar to AA was formed. Kallikrein, plasmin and elastase were also able to degrade intact amyloid fibrils suspended in phosphate-buffered saline.
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PMID:Degradation of amyloid proteins by different serine proteases. 646 Oct 61

Two different plasma membrane enriched fractions were isolated from the homogenized rat kidney by differential centrifugation in dextran or sucrose. Marker enzymes and morphological studies indicated that one fraction (BLM) was enriched in membrane particles originating from the basolateral membrane of tubular cells, while the other, the PM fraction, contained membrane from the luminal side. Membrane-bound kallikrein and renin were found in both fractions. Kallikrein activity was enhanced by phospholipase A2, melittin and detergents. Renin activity was greatly increased after solubilization by the same agents. In addition to bound kallikrein and renin BLM contained a prekallikrein which was activated by trypsin or plasmin. BLM prekallikrein has a slower electrophoretic mobility and a higher molecular weight than urinary or glandular kallikrein. The basal membrane of tubular cells appears to contain all of the essential enzyme components of the kallikrein and renin systems. Kallikrein of the PM fraction is probably released into the urine, while prekallikrein and kallikrein from basal membrane may be the source of kallikrein in lymph and renal venous effluent. Membrane-bound renin could be a form of renin retained by the kidney.
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PMID:Prekallikrein, kallikrein and renin in membrane fractions of rat kidney. 675 83

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

Prekallikrein was purified from guinea-pig plasma. The prekallikrein appeared homogeneous as a single-chain protein on polyacrylamide gels in the presence of sodium dodecyl sulfate (SDS) and beta-mercaptoethanol. The apparent molecular weight was 82 000 by SDS-polyacrylamide gel electrophoresis, 99 000 by gel filtration on a Sephadex G-150 column and 84 500 (protein part) by amino acid analysis. The isoelectric point was approx. 9.0. The purification method yielded 3.8 mg (A280 3.800) of prekallikrein from 500 ml of plasma. Kallikrein was generated from the prekallikrein by limited proteolytic action of a prekallikrein activator which was derived from guinea-pig skin. From analysis using SDS-polyacrylamide gel electrophoresis, the kallikrein has two fragments with apparent molecular weights of 52 000 and 40 000 which are linked by disulfide bond(s). The 40 000 molecular weight fragment was shown to incorporate [3H]diisopropylfluorophosphate. The kallikrein hydrolyzed the synthetic substrates containing the Phe-Arg sequence at the COOH-terminal, and it cleaved carbobenzyloxy-Phe-Arg-4-methylcoumaryl-7-amide more readily than Pro-Phe-Arg-methylcoumaryl-7-amide. The Km for the kallikrein with carbobenzyloxy-Phe-Arg-methylcoumaryl amide was 2 times 104 M. Also, the kallikrein showed negligible activities on peptide-methylcoumaryl amide-substrate for alpha-thrombin, Factor Xa or plasmin.
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PMID:Purification of guinea-pig plasma prekallikrein. Activation by prekallikrein activator derived from guinea-pig skin. 696 37

Kallikrein is present in the renal tubule near the macula densa, and it has recently been shown to activate inactive renin in human plasma. We recently showed that kallikrein was a potent stimulus of renin release and increased renin secretion in a dose-dependent fashion. To study its effect on renal renin release, we superfused rat renal cortical slices with purified rat urinary kallikrein. Kallikrein-stimulated renin release was completely abolished by trasylol and by amiloride, but was not affected by soybean trypsin inhibitor. Indomethacin did not block kallikrein action, indicating that kallikrein's effect is not mediated via kinin generation and prostaglandins. Kallikrein-stimulated renin release was not blocked by propranolol, trasylol did not block isoproterenol, and dibutyryl cyclic AMP stimulated renin release, indicating that kallikrein may not play a role in the beta-adrenergic mechanism of renin release. There was no demonstrable acid-activatable or kallikrein activatable renin in the superfusate, suggesting that all of the renin release was in the active form. Cathepsin D and plasmin also stimulated renin release from kidney slices in pH 6.0 buffer, whereas trypsin and pepsin did not. Our results support the hypothesis that kallikrein may play a role in the secretion of renin by the kidney. Other proteases can also release renin from the kidney.
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PMID:Direct action of kallikrein and other proteases on the renin-angiotensin system. 702 11

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