Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.5 (thrombin)
 33,306 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have studied the effect of streptokinase on platelets in platelet-rich plasma (PRP) and of plasmin on washed platelets. By three and one-half minutes after the addition of 50,000 IU/mL streptokinase to PRP, the maximum rate of ristocetin-induced platelet agglutination declined 40%, and by 60 minutes, it declined 70%. During the same time interval, the thrombin time increased from 20 seconds to over 120 seconds. At a concentration as low as 50 IU/mL, streptokinase reduced the maximum rate of ristocetin-induced platelet agglutination by 50% and prolonged the thrombin time to 1.5 times control value. Streptokinase added to PRP also caused inhibition of platelet aggregation following stimulation by 2.9 mumol/L adenosine diphosphate, 0.25 U/mL thrombin, and 0.025 mg/mL collagen. Plasmin, 0.05 to 1.0 CU/mL, reduced ristocetin-mediated agglutination of washed platelets in the presence of von Willebrand factor (vWF) from 66% of control to 2% of control, following a one-hour incubation. Autoradiograms produced following sodium dodecyl-polyacrylamide gel electrophoresis (SDS-PAGE) of plasmin-treated 125I-surface-labeled platelets demonstrated progressive loss of a protein with a molecular weight (mol wt) of 180,000; simultaneously, a protein with mol wt 135,000 appeared on autoradiograms produced following SDS-PAGE of the surrounding platelet medium. These proteins are similar in molecular weight to glycoprotein (gp) Ib, a platelet surface receptor for vWF, and glycocalicin, a proteolytic fragment of gpIb. By use of an enzyme-linked immunosorbent assay (ELISA) based immunoinhibition assay for glycocalicin, we were able to demonstrate that plasmin treatment of washed platelets released a glycocalicin-related antigen into the surrounding medium and that appearance of this material corresponding to loss of vWF-dependent, ristocetin-induced agglutination.
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PMID:Plasmin effect on platelet glycoprotein Ib-von Willebrand factor interactions. 315 89

To study interactions between platelets and the fibrinolytic system, we examined the effects of human plasmin on human platelets washed by gel filtration. Plasmin concentrations that did not affect platelet shape change, release, or aggregation (less than 1.0 caseinolytic units [CU]/ml) caused a dose- and time-dependent inhibition of platelet aggregation in response to thrombin, ionophore A23187, and collagen. Complete loss of aggregation occurred at 0.1-0.5 CU/ml of plasmin. In a parallel dose-dependent manner, plasmin likewise inhibited thrombin, ionophore, and collagen-stimulated thromboxane B2 production. In contrast, neither aggregation nor thromboxane B2 formation induced by arachidonate was inhibited by plasmin pretreatment of the platelets. Plasmin blocked the thrombin-induced release of [3H]arachidonic acid from platelet membrane phospholipids and the thrombin-induced platelet oxygen burst. However, plasmin did not inhibit the arachidonate-induced oxygen burst. Inhibition of arachidonic acid release by plasmin was not mediated by increase in platelet cyclic AMP. These results suggest that plasmin inhibits platelet function, at least in part, by blocking the mobilization of arachidonic acid from membrane phospholipid pools. The effects of plasmin on platelets may contribute to the hemostatic abnormalities seen in pathologic and pharmacologic fibrinolysis.
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PMID:Plasmin inhibition of platelet function and of arachidonic acid metabolism. 315 49

The effects of plasmin have been examined because platelets may be exposed to plasmin in vivo and treatment of platelets with plasmin shortens platelet survival. Rabbit plasmin was prepared by urokinase activation of plasminogen immobilized on lysine-Sepharose. Plasmin caused rabbit platelets to aggregate and release the contents of their amine storage granules, but aggregation was slower than in response to ADP or thrombin. EDTA, prostaglandin E1, or creatine phosphate/creatine phosphokinase were inhibitory, but indomethacin was not. Deaggregation did not occur when platelets had been aggregated by a concentration of plasmin that caused extensive release of granule contents. EDTA or prostaglandin E1 caused deaggregation. Low concentrations of ADP and plasmin acted synergistically in causing platelet aggregation. Plasmin decreased the amounts of platelet membrane glycoproteins that stained with periodic acid-Schiff reagent; glycoprotein I was more susceptible than glycoprotein II and III. Concentrations of plasmin that induced the release of amine storage granule contents also released PAS-staining granule glycoproteins. Platelets incubated with plasmin, washed and resuspended, were not aggregated by ADP, but were aggregated strongly by the combination of fibrinogen and ADP, and bound 125I-fibrinogen to a greater extent than untreated platelets. Platelets preincubated with a high concentration of plasmin were unresponsive to thrombin, but were sometimes aggregated by fibrinogen. Plasmin decreased the buoyant density and increased the median size of platelets. Thus plasmin, as well as ADP and thrombin, may contribute to the density shift observed in platelets from rabbits in which thrombosis and continuous vessel injury have been induced.
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PMID:Effects of plasmin on rabbit platelets. 315 94

The capacity of purified tryptase from human lung mast cells to metabolize human fibrinogen, fibrin, and plasminogen was evaluated. Tryptase (5 micrograms/ml) inactivated the thrombin-induced clotting activity of fibrinogen (100 micrograms/ml) with essentially similar t 1/2 values of 4.6 min in the absence of heparin and 5.8 min in the presence of heparin (20 micrograms/ml) that were not appreciably different than with lysine-Sepharose-purified plasmin (5 micrograms/ml). Fibrinogen treated with tryptase together with heparin lost all detectable clotting activity by 4 hr at 37 degrees C, whereas fibrinogen treated with tryptase alone resulted in destruction of only 80% of fibrinogen clotting equivalents after 16 hr. Tryptase alone was observed to cleave only the alpha-chains of fibrinogen by electrophoresis of tryptase-treated, denatured, and reduced fibrinogen in polyacrylamide gradient gels. Tryptase together with heparin cleaved first the alpha-chain and then the beta-chain, the latter cleavage corresponding to complete loss of fibrinogen clotting activity by 4 hr. No fibrinogen fragments with anticoagulant activity were generated by tryptase. In contrast, plasmin left no residual clotting activity after 4 hr of incubation and generated fibrinogen fragments with anticoagulant activity. Plasmin sequentially cleaved the alpha, beta, and gamma subunits of fibrinogen. Tryptase alone (6 micrograms/ml) or together with heparin (20 micrograms/ml) failed to activate plasminogen (0.6 mg/ml) after a 60-min incubation at 37 degrees C. Addition of urokinase to tryptase-treated or untreated plasminogen resulted in essentially identical plasmin activities (0.32 and 0.34 U/ml, respectively), indicating that tryptase neither activates nor destroys plasminogen. Tryptase (700 ng) also failed to substantially solubilize cross-linked fibrin (2.6 micrograms) or the corresponding amount of fibrinogen bound to plastic microtiter plates with or without heparin. The failure to solubilize fibrinogen and, possibly, fibrin is consistent with the observation that the apparent m.w. by SDS polyacrylamide gel electrophoresis of unreduced fibrinogen is not appreciably altered by prior treatment with tryptase, even though cleavage of alpha-and beta-chains is revealed after reduction. Fibrinogenolysis by tryptase complements other mast cell mediators with anticoagulant properties such as heparin and suggests a significant prevention of coagulation by activated mast cells.
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PMID:The fibrinogenolytic activity of purified tryptase from human lung mast cells. 316 48

There exist different ways of assays of plasminogen which give information about different properties of this proenzyme. The concentration of plasminogen can be determined by its antigenicity. Since the normal concentration of plasminogen in plasma is between 15 and 25 mg/dl the test can be carried out by simple methods such as radial immunodiffusion on Partigen plates. The possibility of errors is small and there is no need of special apparatus. The disadvantages are the lapse of 24 h until the result is available and the fact that the knowledge of the concentration does not give any information about the activity. The activity can be measured by different coagulation tests. A typical assay would involve activation of plasminogen to plasmin, addition of plasminogen-free thrombin and measuring of the lysis time. The result is however, dependent on more than one variable. Plasmin is rapidly inhibited by alpha-2-antiplasmin (APL) and there is also a dependence of the lysis time on the amount of clottable fibrinogen in the test system. Better results can be obtained by the use of diluted test plasma and addition of a constant amount of plasminogen-free fibrinogen. A different way would be the use of the euglobulin fraction instead of plasma. This has however, the possible disadvantage of incomplete precipitation of plasminogen. Instead of coagulation tests the activity can also be determined when diluted activated plasma is placed on plasminogen-free fibrin plates and the amount of lysis in the plate is recorded. All assays of this group also depend on the method of activation of plasminogen.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Basics and practice in evaluating plasminogen. 328 Apr 24

Adult rat hepatocytes cultured on type IV collagen, fibronectin, or laminin and maintained in serum-free medium were examined by indirect immunofluorescence using polyclonal antibodies against extracellular matrix proteins. An extensive fibrillar matrix containing fibronectin and fibrin was detected in all hepatocyte cultures irrespective of the exogenous matrix substratum used to support cell adhesion. Fibrils radiated from the cell periphery and covered the entire culture substratum. In addition, thicker fibers or bundles of fibers were localized on top of hepatocytes. This matrix did not contain laminin or the major types of collagen found in the liver biomatrix (types I, III, and IV). Isolation of the fibrillar matrix and analysis on polyacrylamide gels under reducing conditions demonstrated a major 58-kD polypeptide, derived from beta-fibrinogen as indicated by immunoblotting and two-dimensional peptide mapping. Plasmin rapidly dissolved the matrix. Deposition of the fibrin matrix in hepatocyte cultures was arrested by hirudin, by specific heparin oligosaccharides that potentiate thrombin inhibition by antithrombin III, and by dermatan sulfate, an activator of heparin cofactor II-mediated inhibition of thrombin. The results indicate that hepatocytes in culture synthesize and activate coagulation zymogens. In the absence of inhibitory and fibrinolytic mechanisms, a fibrin clot is formed by the action of thrombin on fibrinogen. Fibronectin attaches to this fibrin clot but fails to elaborate a fibrillar matrix on its own in the presence of coagulation inhibitors.
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PMID:Rat hepatocytes in serum-free primary culture elaborate an extensive extracellular matrix containing fibrin and fibronectin. 331 51

The two final phases in the haemostatic process, plasma coagulation with the formation of a fibrin clot, and fibrinolysis leading to the dissolution of fibrin clots, are reviewed. Coagulation may be initiated either by reactions occurring between components of the blood alone, the intrinsic pathway, or by reactions which also involve tissue components, termed the extrinsic pathway. In the diagnosis of coagulation disorders, it is convenient to divide the intrinsic pathway into three phases. In phase 1, resulting in the activation of factor (f) X, are involved f XII, XI, VIII and IX, platelet phospholipids, and calcium. In phase 2, prothrombin is converted to thrombin by f Xa in conjunction with f V, phospholipids, calcium. In phase 3, thrombin converts fibrinogen to fibrin, which is then stabilized by f XIII. Antithrombin III is the most important inhibitor. The key component in fibrinolysis is plasminogen, which under the influence of various activators is converted to plasmin. Plasmin is a serine protease and its main in vivo target is fibrin. Alpha 2-antiplasmin and a fast-acting inhibitor of tissue plasminogen activator are the most important inhibitors.
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PMID:Coagulation and fibrinolysis. 332

Plasmin-catalyzed modification of the native plasma zymogen Glu1-plasminogen to its more reactive Lys78 form has been shown to be enhanced in the presence of fibrin. The aim of the present work has been to characterize the influence of fibrinopeptide release, fibrin polymerization, and plasmin cleavage of fibrin on the rate of Lys78-plasminogen formation. 125I-Labeled Glu1- to Lys78-plasminogen conversion was catalyzed by performed Lys78-plasmin, or by plasmin generated during plasminogen activation with tissue plasminogen activator or urokinase. The two forms of plasminogen were quantitated following separation by polyacrylamide gel electrophoresis in acetic acid/urea. Plasmin generated by plasminogen activator was monitored by a fixed-time amidolytic assay. The rate of Lys78-plasminogen formation was correlated, in separate experiments, to the simultaneous, plasmin-catalyzed cleavage of 125I-labeled fibrinogen or fibrin to fragments X, Y, and D. The radiolabeled components were quantitated after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The results show that the formation of both bathroxobin-catalyzed des-A-fibrin and thrombin-catalyzed des-AB-fibrin leads to marked stimulation of Lys78-plasminogen formation, whereas inhibition of fibrin polymerization, with Gly-Pro-Arg-Pro, abolishes the stimulatory effect. The rate of Lys78-plasminogen formation varies markedly in the course of fibrinolysis. The apparent second-order rate constant of the reaction undergoes a transient increase upon transformation of fibrin to des-A(B) fragment X polymer and decreases about 10-fold to the level observed during fibrinogenolysis upon further degradation to soluble fragments Y and D.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The course and prerequisites of Lys-plasminogen formation during fibrinolysis. 338 32

Lipoprotein lipases from human, bovine or guinea-pig milk were purified, judged for domain relationships by characterization of sites sensitive to proteases, and structurally compared. The subunit of human lipoprotein lipase migrated slightly slower than those of bovine or guinea-pig lipoprotein lipases on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Bovine lipoprotein lipase is known to be a dimer of two non-covalently linked subunits of equal size, and the lipases from all three sources now yielded homogeneous N-terminal amino acid sequences (followed for 15-27 residues). The results indicate that the two subunits are identical. Bovine lipoprotein lipase had two additional N-terminal residues, Asp-Arg, compared to the human and guinea-pig enzymes, and the next two positions revealed residue differences, but further on homologies were extensive between all three enzymes as far as presently traced. Exposure of bovine lipoprotein lipase to trypsin led to production of three fragments (T1, T2a, and T2b), suggesting cleavage at exposed segments delineating domain borders. Time studies gave no evidence for precursor-product relationships between the fragments, and prolonged digestion did not lead to further cleavage. Fragments T2a and T2b had the same N-terminal sequence as intact lipase. Fragment T1 revealed a new sequence, and represents the C-terminal half of the molecule. Plasmin caused a similar cleavage as trypsin, whereas thrombin, factor Xa, and tissue plasminogen activator did not cleave the enzyme. Chymotrypsin cleaved off a relatively small fragment from the C-terminal of the molecule, after which exposure to trypsin still resulted in cleavage at the same sites as in intact lipase. Tryptic cleavage of guinea-pig lipoprotein lipase yielded two fragments. One had a similar size as bovine fragment T2b; the other had a similar size as bovine fragment T1 and an N-terminal sequence homologous with that of T1. Thus, trypsin recognizes the same unique site in guinea-pig lipoprotein lipase as in the bovine enzyme. This confirms the conclusion that this segment is the border between two domains in the subunit. The binding site for heparin was retained after both tryptic and chymotryptic cleavages and was identified as localized in the C-terminal part of the molecule.
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PMID:Lipoprotein lipases from cow, guinea-pig and man. Structural characterization and identification of protease-sensitive internal regions. 353 11

Binding of 125-I-fibrinmonomer to peritoneal macrophages was investigated in dependence of plasma fibronectin and of its thrombin- or plasmin-derived fragments. Plasma fibronectin failed to enhance cell binding of 125-I-fibrinmonomer. In contrast, 30kD-fragments derived from the N-termini of the fibronectin subunits improved binding considerably. The association with the cell surface was completely inhibited by EDTA, 2-5 mM putrescine and to about 40 per cent by 0.1 mM dansylcadaverine suggesting that a transamidase-catalyzed cross-linking reaction was involved. Thrombin-derived 200kD-remnants of the fibronectin subunit chains failed to mediate cell binding of 125-I-fibrinmonomer provided they had been deprived of residual thrombin activity. Otherwise they were active and their activity was inhibited by the thrombin inhibitor hirudin. Plasmin-derived 200 kD-fragments were inactive as well.
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PMID:Fibrinmonomer binding to macrophages mediated by fibrin-binding fibronectin fragments. 392 11


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