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)

Aprotinin reduces blood loss after cardiac operations and decreases the bleeding time. The mechanism of action of aprotinin that produces these effects is not clear. During simulated extracorporeal circulation the contact and complement systems, platelets, and neutrophils are activated. We investigated the effect of aprotinin on kallikrein-C1-inhibitor complex and C1-C1-inhibitor complex formation, neutrophil degranulation, and platelet release and aggregation during simulated extracorporeal circulation. Fresh heparinized human blood was recirculated at 37 degrees C for 2 hours in a spiral coil membrane oxygenator-roller pump perfusion circuit. Changes in platelet count, leukocyte count, platelet response to adenosine diphosphate, and plasma levels of beta-thromboglobulin, kallikrein-C1-inhibitor complexes, C1-C1-inhibitor complexes, and neutrophil elastase were measured before and at 5, 30, 60, and 120 minutes of recirculation at 0, 0.015, 0.03, 0.06, and 0.12 mg/ml doses of aprotinin. Platelet counts decreased to 36% +/- 12% of control values at 5 minutes and increased to 56% +/- 13% at 120 minutes without aprotinin. Aprotinin did not affect platelet counts, but it did prevent the decrease in sensitivity of platelets to adenosine diphosphate and it attenuated beta-thromboglobulin release. In the absence of aprotinin, kallikrein-C1-inhibitor and C1-C1-inhibitor complexes increased progressively to 0.53 +/- 0.14 U/ml and 2.38 +/- 0.33 U/ml, respectively, at 120 minutes. Kallikrein-C1-inhibitor complexes were completely inhibited and C1-C1-inhibitor complexes were partially inhibited at aprotinin concentrations of 0.03 mg/ml or greater. Release of neutrophil elastase was partially but not completely inhibited at the highest dose of aprotinin and was 50% inhibited at a dose of 0.03 mg/ml. Because activation of the fibrinolytic system does not occur in this system, the changes were independent of the inhibition of plasmin. We conclude that aprotinin in high doses completely inhibited kallikrein-induced activation of neutrophils and partially inhibited complement-induced activation. Aprotinin did not directly affect platelet adhesion or aggregation, but it indirectly preserved platelet sensitivity to agonists and also attenuated release of alpha-granule contents. The data indicate that in the presence of aprotinin platelet function was partially preserved, kallikrein production was totally inhibited, complement activation was partially inhibited, and neutrophil release was partially inhibited, thus attenuating the "whole body inflammatory response" associated with cardiopulmonary bypass.
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PMID:Aprotinin inhibits the contact, neutrophil, and platelet activation systems during simulated extracorporeal perfusion. 768 93

The aim of this study was to synthesize and investigate hybrid peptides which contain the RGD (Arg-Gly-Asp) sequence coupled with lysine residues in special arrangements (antiplasmin carboxyterminal peptide) in an effort to simultaneously inhibit platelet aggregation and promote fibrinolysis. The in vitro haemostatic modifying properties of the synthesized peptides were tested by ADP-induced platelet aggregation, plasmin-generation tests and fibrin-clot lysis assays. The hybrid peptide RGDFAP, composed of RGDF (Arg-Gly-Asp-Phe) coupled to a synthetic peptide residue of the carboxyterminal part of antiplasmin (AP26) inhibited platelet activation and increased plasmin generation and in vitro fibrin-clot lysis.
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PMID:Hybrid peptide containing RGDF (Arg-Gly-Asp-Phe) coupled with the carboxy terminal part of alpha 2-antiplasmin capable of inhibiting platelet aggregation and promoting fibrinolysis. 779 48

We studied the effect of antiplatelet therapy not only on the secondary prevention of stroke but also on the suppression of vascular damages in patients with cerebral thrombosis at the chronic phase. We measured von Willebrand factor (vWF) as a marker for the endothelial system, and coagulation and fibrinolytic parameters in addition to platelet functions. The platelet aggregation and markers for platelet activation were monitored for the adequate inhibition of platelets. Twenty-one patients were treated with 200 mg ticlopidine. 9 patients with 100 mg ticlopidine and 60-150 mg acetylsalicylic acid, and 18 patients with 200 mg cilostazol daily. The mean duration of follow up was 8.4 +/- 3.0 months. A patient was attacked by a recurrent stroke, but no fatal vascular events occurred during the period. A significant decrease was observed in the collagen- and ADP-induced platelet aggregation and markers for platelet activation such as platelet factor 4 (PF4) and beta-thromboglobulin (beta TG) by the antiplatelet therapy. In addition, the activities of coagulation factor VIII (FVIII) and vWF, markers for vascular damages, showed a significant decrease. The results suggest that the antiplatelet therapy could ameliorate the vascular damage through the inhibition of platelet function. Moreover, thrombin-antithrombin III complex (TAT) and alpha 2-plasmin inhibitor-plasmin complex (PIC), markers for the activation of coagulation and fibrinolytic systems, decreased significantly, suggesting that the treatment inhibits the activation of coagulation and fibrinolytic systems induced by the platelet activation. The activities of FVIII and vWF decreased significantly when the level of beta TG or that of PF4 lowered sufficiently by the treatment.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Antiplatelet therapy in patients with cerebral thrombosis at the chronic phase--assessment of its effect on coagulation and fibrinolytic parameters]. 799 82

Plasminogen and tissue-type plasminogen activator bind to the platelet surface, and as a result, the catalytic efficiency of plasminogen activation is significantly enhanced. The plasmin that is generated on or near the platelet is known to affect a number of platelet surface events. For this reason, we examined the effect of plasmin on platelet-surface plasminogen activation and its determinants. Specifically, we measured the effects of plasmin treatment of platelets (1 caseinolytic unit/mL for 1 h at 37 degrees C) on plasminogen, tissue-type plasminogen activator, and plasmin binding to the unactivated and ADP-activated platelet surface; and on the kinetics of plasminogen activation on the platelet surface. Following plasmin treatment, the number of plasminogen binding sites on unactivated platelets increased by 78% (from 46,000 +/- 4000 to 88,000 +/- 9000 sites/platelet), while the number of tissue-type plasminogen activator sites did not change, and the number of diisopropyl fluorophosphate (DFP)-inactivated plasmin (DFP-plasmin) binding sites decreased by 31% (from 92,000 +/- 11,000 to 65,000 +/- 7000 sites/platelet); the dissociation constants (Kds) for each of these binding processes did not change significantly following treatment. On ADP-activated platelets, plasmin treatment increased the number of plasminogen binding sites by 41% (from 188,000 +/- 17,000 to 265,000 +/- 25,000 sites/platelet), decreased the number of plasmin binding sites by 28% (from 219,000 +/- 41,000 to 157,000 +/- 24,000 sites/platelet), and did not affect the number of tissue-type plasminogen activator sites; again, the Kds for each of these binding processes did not change significantly following treatment.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Kinetics and mechanism of platelet-surface plasminogen activation by tissue-type plasminogen activator. 813 Feb 11

Normal human platelets aggregated by thrombin undergo the release reaction and are not readily deaggregated by the combination of inhibitors hirudin, prostaglandin E1 (PGE1) and chymotrypsin. Released adenosine diphosphate (ADP) plays an important role in the stabilization of thrombin-induced human platelet aggregates. Since ticlopidine inhibits the platelet responses to ADP, we studied thrombin-induced aggregation and deaggregation of 14C-serotonin-labeled platelets from 12 patients with cardiovascular disease before and 7 days after the oral administration of ticlopidine, 250 mg b.i.d. Before and after ticlopidine, platelets stimulated with 1 U/ml thrombin aggregated, released about 80-90% 14C-serotonin and did not deaggregate spontaneously within 5 min from stimulation. Before ticlopidine, hirudin (5x the activity of thrombin) and PGE1 (10 mumol/l) plus chymotrypsin (10 U/ml) or plasmin (0.06 U/ml), added at the peak of platelet aggregation, caused slight or no platelet deaggregation. After ticlopidine, the extent of platelet deaggregation caused by the same inhibitors was significantly greater than before ticlopidine. The addition of ADP (10 mumol/l) to platelet suspensions 5 s after thrombin did not prevent the deaggregation of ticlopidine-treated platelets. Thus, ticlopidine facilitates the deaggregation of thrombin-induced human platelet aggregates, most probably because it inhibits the effects of ADP on platelets.
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PMID:Ticlopidine facilitates the deaggregation of human platelets aggregated by thrombin. 816 51

The experiments reported here were carried out to define in greater detail actin's stimulation of plasmin generation by t-PA. Actin did not alter t-PA's hydrolysis of a synthetic substrate, and thus is unlikely to have a direct effect upon t-PA's proteolytic activity. When studied in a single-stage assay, actin accelerated t-PA-mediated plasmin generation from both Glu-plasminogen and Lys-plasminogen, indicating the central role of ternary complex formation. Although actin does not appear to bind two-chain urokinase (tcu-PA), it stimulates tcu-PA's cleavage of Glu-plasminogen. This finding suggests that actin alters the conformation of Glu-plasminogen to an open form. The failure of actin to increased plasmin generation by tcu-PA acting on Lys-plasminogen, which is in an open configuration, is consistent with this interpretation. Immunoglobin G, which shares with actin the property of binding to Glu-plasminogen after nicking by plasmin, did not stimulate tcu-PA's cleavage of Glu-plasminogen, indicating the uniqueness of actin's effects and suggesting interactions between actin and plasminogen at multiple binding sites. Unlike fibrin and heparin, whose stimulation of t-PA is related to polymer length actin is able to stimulate t-PA when presented in either a monomeric or polymeric form. Denaturation of actin by exposure to urea and guanidine increased its ability to stimulate plasmin generation by t-PA. Because actin's structure is maintained by a noncovalently bound adenine nucleotide (ATP or ADP), exposure to ATP/ADPases found in plasma and on cell membranes might also result in its denaturation. Actin treated with an enzyme functionally similar to such ecto-ATP/ADPases, potato apyrase, was more potent than native actin in stimulating plasmin generation by t-PA. The effects of apyrase were blocked by the addition of the plasma actin-binding proteins, gelsolin and the vitamin D-binding protein (DBP). Thus, denaturation of actin may occur in under physiologic conditions, with potential biological consequences. Actin thus appears to be unique with regard to its interactions with the fibrinolytic system and plasma actin-binding proteins may serve to protect the host from the effects of denatured actin.
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PMID:Actin stimulates plasmin generation by tissue and urokinase-type plasminogen activators. 823 51

The use of first generation plasminogen activators, urokinase, streptokinase and tissue plasminogen activator has revolutionized thrombolytic therapy for myocardial infarction and ischaemia, and potentially stroke. However, thrombolytic therapy employing these activators is limited by reocclusion of the very arteries being opened, which follows in a small but significant number of patients. The development of second generation plasminogen activators, e.g. staphylokinase and anisoylated plasminogen streptokinase activator complex, has not alleviated the problems encountered with classical plasminogen activators. It is now widely recognized that aberrant platelet aggregation induced primarily by thrombin, rather than plasmin, is one of the major causes of recurrent thrombosis following pharmacologic thrombolysis. Agents that (a) inhibit enzymatic and/or coagulant activity of thrombin, (b) block binding of thrombin to its receptor, and (c) interfere with the generation of thrombin by the prothrombinase complex may compromise haemostasis resulting in haemorrhage. We recently demonstrated that thrombin-induced platelet aggregation is accompanied by cleavage of aggregin, a putative ADP-receptor on the platelet surface, and that these events are indirectly mediated by intracellularly activated calpain expressed on the surface. In this review, we discuss the known mechanisms of thrombin-induced platelet aggregation and suggest relative advantages of potential pharmacological agents, being developed in our laboratory, over those that have been previously developed and tested. These inhibitors selectively prevent aggregation of platelets induced by thrombin by inhibiting calpain expressed on the surface. Moreover, one of these inhibitors which blocks thrombin-induced platelet aggregation does not interfere with other platelet responses mediated by thrombin or platelet aggregation induced by other agonists, such as, ADP, collagen, phorbol myristate acetate and thromboxane A2 mimetics. This selectivity could reduce the chances of perturbing the formation of a haemostatic plug.
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PMID:Reocclusion after thrombolytic therapy: strategies for inhibiting thrombin-induced platelet aggregation. 832 74

Infusion of the thrombolytic agents streptokinase (SK, 666 units/kg per minute for 60 minutes) and tissue-type plasminogen activator (t-PA, 10 micrograms/kg per minute for 15 minutes) in rabbits induced a significant hypotension and decrease in platelet count that were completely prevented by treatment with platelet-activating factor (PAF) receptor antagonists SDZ 63-675 and WEB 2170. PAF synthesis by vascular tissue was suggested by its extraction from blood-free heart and aorta of rabbits treated in vivo with SK or t-PA but not of control rabbits. In contrast, PAF was not detected in peripheral blood. Ex vivo studies on platelet aggregation response to ADP and PAF performed on platelet-rich plasma obtained before and after SK and t-PA infusion demonstrated an early hyperaggregable phase, abrogated by PAF receptor antagonists and followed by reduced sensitivity of platelets to PAF. The ED50 values for the aggregation of washed rabbit platelets induced by PAF but not thrombin were significantly increased at 60 and 120 minutes after SK and t-PA infusion, suggesting a specific desensitization of platelets to PAF. In contrast to PAF receptor antagonists, aspirin did not significantly modify the hypotension and the platelet hyperaggregability induced by SK or t-PA or the platelet hypoaggregability induced by t-PA. Thrombocytopenia induced by t-PA, but not by SK, was partially prevented by aspirin. The effect of SK, t-PA, and plasmin on the aggregation of washed platelets from untreated rabbits and from humans was also studied. Whereas SK and t-PA were inactive, plasmin induced dose-dependent platelet aggregation that was inhibited by platelet pretreatment with PAF receptor antagonists. In conclusion, the effect of PAF receptor antagonists observed in the present experimental model suggests that the hypotension and activation of platelets induced by SK and t-PA infusion are mediated by PAF.
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PMID:Role of platelet-activating factor in hypotension and platelet activation induced by infusion of thrombolytic agents in rabbits. 838 25

Fibrin(ogen) (FGN) is important for hemostasis and wound healing and is cleared from sites of injury primarily by the plasminogen activator system. However, there is emerging evidence in plasminogen activator-deficient transgenic mice that nonplasmin pathways may be important in fibrin(ogen)olysis, as well. Given the proximity of FGN and monocytes within the occlusive thrombus at sites of vascular injury, we considered the possibility that monocytes may play an ancillary role in the degradation and clearance of fibrin. We found that monocytes possess an alternative fibrinolytic pathway that uses the integrin Mac-1, which directly binds and internalizes FGN, resulting in its lysosomal degradation. At 4 degrees C, FGN binds to U937 monocytoid cells in a specific and saturable manner with a kd of 1.8 mumol/L. Binding requires adenosine diphosphate stimulation and is calcium-dependent. At 37 degrees C, FGN and fibrin monomer (FM) are internalized and degraded at rates of 0.37 +/- 0.13 and 0.55 +/- 0.03 microgram/10(6) cells/h by U937 cells, 1.38 +/- 0.02 and 1.20 +/- 0.30 microgram/10(6) cells/h by THP-1 cells, and 2.10 +/- 0.20 and 2.52 +/- 0.18 micrograms/10(6) cells/h by human peripheral blood mononuclear cells, respectively. The serine protease inhibitors, PPACK and aprotinin, and the specific elastase inhibitor, AAPVCK, do not significantly inhibit degradation. However, degradation is inhibited by chloroquine, suggesting that a lysosomal pathway is involved. Factor X, a competitive ligand with FGN for the Mac-1 receptor, also blocks degradation, as does a monoclonal antibody to the alpha-subunit of Mac-1. Autoradiography of radioiodinated, internalized FGN shows that FGN proteolysis by the pathway produces a unique degradation pattern distinct from that observed with plasmin. In a fibrin clot lysis assay, Mac-1-mediated fibrinolysis contributed significantly to total fibrinolysis. In summary, FGN is internalized and degraded by activated human monocytoid cells via Mac-1 in the absence of plasmin, thereby providing an alternative fibrinolytic pathway. Thus, in addition to the function of cell adhesion, integrins may also act as receptors that mediate the internalization and degradation of bound ligands.
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PMID:Fibrin(ogen) is internalized and degraded by activated human monocytoid cells via Mac-1 (CD11b/CD18): a nonplasmin fibrinolytic pathway. 840 Feb 91

Lipoprotein(a) [Lp(a)] is a unique lipoprotein consisting of a low-density lipoprotein moiety (LDL) covalently linked to apoprotein(a). Previous work has demonstrated that Lp(a) can compete with plasminogen (PGN) for binding to endothelial and mononuclear cells and can inhibit PGN activation in cell-free systems. We have assessed the binding of Lp(a) to platelets and the influence of binding on the activation of PGN by tissue-type plasminogen activator (t-PA) in this system. In direct binding experiments, Lp(a) bound specifically, saturably, and reversibly to platelets with an estimated apparent Kd of 0.20 microM. Scatchard analysis revealed a single class of binding sites with 81,000 +/- 22,000 particles of Lp(a) bound at saturation. Interestingly, Lp(a) bound to a similar extent to thromboasthenic platelets. Activation of platelets with ADP or thrombin reduced Lp(a) binding capacity by approximately 50% without changing affinity. Lp(a) also inhibited the binding of PGN to platelets with an IC50 of approximately 0.23 microM. Over a similar concentration range, LDL did not inhibit PGN binding to platelets. In addition, Lp(a) inhibited PGN binding to plasmin-treated platelets with an IC50 of approximately 0.2 microM. Kinetic experiments demonstrated that Lp(a) acted as a competitive inhibitor of PGN activation by t-PA on the platelet surface, with an estimated Ki of 0.49 microM. In the presence of platelets, Lp(a) decreased the kcat/Km for t-PA by 3-fold, owing primarily to an increase in the Km of t-PA for PGN. In contrast, LDL did not alter the kinetics of PGN activation by t-PA on the platelet surface.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Lipoprotein(a) binds to human platelets and attenuates plasminogen binding and activation. 848 40


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