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)

DPC423, 1-[3-(aminomethyl)phenyl]-N-[3-fluoro-2'-(methylsulfonyl)[1,1'-biphenyl]-4-yl]-3-(trifluoromethyl)-1H-pyrazole-5-carboxamide, is a synthetic, orally bioavailable, competitive, and selective inhibitor of human coagulation factor Xa (K(i) [nM]: factor Xa, 0.15; trypsin, 60; thrombin, 6000; plasma kallikrein, 61; activated protein C, 1800; factor IXa, 2200; factor VIIa, >15,000; chymotrypsin, >17,000; urokinase, >19,000; plasmin, >35,000; tissue plasminogen activator, >45,000; complement factor I, 44,000 [IC(50)]). In vitro, DPC423 produced anticoagulant effects in human plasma in which it doubled prothrombin time, activated partial thromboplastin time, and Heptest clotting time at 3.1 +/- 0.4, 3.1 +/- 0.4, and 1.1 +/- 0.5 microM, respectively. In dogs, DPC423 had a good pharmacokinetic profile with an oral bioavailability of 57%, a plasma clearance of 0.24 L/kg/h, and a plasma half-life of 7.5 h. In rabbit and rat models of arteriovenous shunt thrombosis, DPC423 was an effective antithrombotic agent with an IC(50) of 150 and 470 nM, respectively. The antithrombotic effect of DPC423 is likely to be related to the inhibition of factor Xa but not to the inhibition of thrombin or due to direct inhibition of platelet aggregation. Therefore, based on potency, selectivity, efficacy, and oral bioavailability, DPC423 was selected for clinical development as an oral anticoagulant for the potential treatment of thrombotic disorders. Preliminary human data suggest that DPC423 is orally bioavailable in humans and has a long plasma half-life.
Cardiovasc Drug Rev 2002
PMID:Nonpeptide factor Xa inhibitors: DPC423, a highly potent and orally bioavailable pyrazole antithrombotic agent. 1217 91

When Glu-plasminogen, the native circulating form of the zymogen, is bound to cell surfaces, its activation is markedly enhanced compared with the reaction in solution. This results in localization of the broad-spectrum proteolytic activity of plasmin on cell surfaces. The cell-associated plasmin plays a key role in fibrinolysis, cell migration, and prohormone processing. It is well established that the localization of plasminogen and plasminogen activators on cell surfaces promotes the enhanced plasminogen activation on the cell surface. The focus of this article is to review recent studies demonstrating that the conversion of Glu-plasminogen to the more readily activated Lys-plasminogen derivative is necessary for optimal stimulation of plasminogen activation on the cell surface, and that the interaction of Glu-plasminogen with cells serves to increase processing of Glu-plasminogen to Lys-plasminogen, thereby enhancing plasminogen activation on the cell surface.
Trends Cardiovasc Med 2003 Jan
PMID:Critical role for conversion of glu-plasminogen to Lys-plasminogen for optimal stimulation of plasminogen activation on cell surfaces. 1255 97

Thrombolytic agents are in widespread use for the dissolution of arterial and venous pathologic thrombi. Clinical settings where thrombolysis has played an important role include the acute coronary syndromes, peripheral arterial occlusion, ischemic stroke, deep venous thrombosis, and pulmonary embolism. Thrombolytic agents have been successfully employed in each of these areas, achieving dissolution of the occluding thrombus, reconstitution of blood flow, and improvement in the status of the tissue bed supplied or drained by the involved vascular segment. All clinically available thrombolytic agents act through cleavage of the plasminogen molecule to its active form, plasmin. Despite this similar mechanism of action, the thrombolytic agents differ in several biochemical parameters, including fibrin specificity, fibrin affinity, and relative resistance to inactivating factors in the plasma. Whether these differences account for significant differences in clinical outcome is a matter of some dispute. It is quite possible that in vitro biochemical differences do not have meaningful clinical correlates. However, there exists some evidence to suggest that differences in the risk of distant hemorrhage, idiosyncratic reactions, and the rapidity of clot dissolution do exist. An ideal agent for peripheral vascular thrombolysis would be one that was specific in its actions at the site of pathologic thrombi yet left the important and desirable pathologic thrombi that seal vascular defects unscathed. Although such an agent has not yet been identified, an understanding of the mechanism of action and principles underlying pharmacologic thrombolysis provides the necessary foundation of knowledge to choose a particular thrombolytic agent for a given clinical scenario.
Rev Cardiovasc Med 2002
PMID:Comparison of safety and efficacy of the various thrombolytic agents. 1255 39

Various thrombolytic agents have been studied as activators of the plasminogen-plasmin system for thrombolysis of thrombus formation. They include streptokinase, urokinase, tissue plasminogen activators, single-chain urokinase plasminogen activator, and anisoylated or acylated plasminogen-streptokinase activator complex (APSAC), only some of which are commercially available. All thrombolytic agents, including APSAC (not commercially available), recombinant tissue plasminogen activator, and prourokinase, generate great quantities of degradation products of fibrinogen or fibrin. All of the second-generation thrombolytic agents induce systemic activation of the entire fibrinolytic system, and none are capable of specifically activating the fibrinolytic system at the site of thrombus formation. The most systemically active agent known at the present time is APSAC. Trials show that bleeding occurs as frequently with the second-generation agents as with the older agents, and further studies may even find that the newer agents are associated with more bleeding than urokinase and streptokinase have been. With knowledge of the properties of the various thrombolytic agents available today, the physician can intelligently select the optimal agent for a given patient problem.
Rev Cardiovasc Med 2002
PMID:Present-day thrombolytic therapy: therapeutic agents--pharmacokinetics and pharmacodynamics. 1255 41

Cardiopulmonary bypass (CPB) leads to activation of the coagulation and fibrinolytic cascades, partially associated with foreign surface contact. Hemorrhage and the need for blood products is associated with rising cost and increased risk of infection. Treatment with surface modifying additives (SMA) has been shown to reduce thrombogenicity and improve biocompatibility. 76 elective CABG-patients were randomly assigned to surface modifying additives (group I, n=39) or untreated circuits that were otherwise identical (group II, n=37). Measurements of coagulation activity and fibrinolysis, platelet count and function were made. The postoperative blood loss and blood product replacement was also assessed. Thrombin formation measured by prothrombin fragments 1+2 (5.7+/-0.4 nmol/l vs. 5.6+/-0.4 nmol/l), fibrinolytic activity measured by plasmin-antiplasmin complex (1752.6+/-216.8 microg/l vs.1180.0+/-74.8 microg/l) and the postoperative platelet count and function did not differ significantly between the two groups. Blood loss and transfusion requirements were slightly lower in the SMA group. The treatment of extracorporeal surfaces with surface modifying additives does not appear to reduce coagulation disorders and bleeding after conventional CPB.
Cardiovasc Surg 2003 Apr
PMID:Do surface modifying additives (SMA) influence blood loss and thrombogenicity in conventional cardiopulmonary bypass for coronary artery bypass grafting? 1266 53

NK3201 is an orally active chymase inhibitor. Its inhibitory activity leads to formation of acyl-intermediate between active serine residue of the enzyme and di-ketone structure of NK3201. NK3201 inhibits human, dog and hamster chymases with IC(50) of 2.5, 1.2, and 28 nM, respectively. On the other hand, NK3201 does not inhibit other types of serine proteases, tryptase, thrombin, elastase, plasmin, and plasminogen activator. In dogs, at 8 h after oral administration of NK3201, 1 mg/kg, the drug levels in plasma, heart, and aorta reached 470, 195, and 78 nM, respectively. In a dog model NK3201, 5 mg/kg/day, increased chymase activity in grafted veins, and suppressed vascular proliferation. After balloon injury in dog vessels, chymase activity was increased locally, in the injured artery, and NK3201, 1 mg/kg/day was effective in preventing vascular proliferation. On the other hand, NK3201, unlike angiotensin converting enzyme inhibitors or angiotensin II receptor blockers, did not affect blood pressure. These findings indicate that local angiotensin II production by chymase is involved only in vascular proliferation, as seen in the injured vessels. Therefore, NK3201 may be useful for preventing vascular proliferation without affecting blood pressure.
Cardiovasc Drug Rev 2003
PMID:Application of a chymase inhibitor, NK3201, for prevention of vascular proliferation. 1293 Dec 53

Stroke is a heterogeneous disorder with significantly high morbidity and mortality. The relationship between serum cholesterol level and the incidence of stroke remains controversial. Recent evidence from primary and secondary prevention trials suggests that treatment with hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase inhibitors may reduce the incidence of stroke in patients with coronary artery disease (CAD). In this review, we attempt to outline and describe the potential mechanisms of HMG-CoA reductase inhibitors in the prevention of stroke. In addition to their lipid-lowering action HMG-CoA reductase inhibitors appear to exert their beneficial effects by various nonlipid-lowering mechanisms including anti-inflammatory effects, effect on endothelial function and coagulation cascade. Treatment with HMG-CoA reductase inhibitors is associated with decreased progression, plaque stablization and even regression of atheromatous plaque in the carotid arteries. HMG-CoA reductase inhibitors also inhibit the coagulation cascade at various levels such as activation of prothrombin, factor V, factor X and liberation of tissue factor in response to vascular injury. Inhibition of fibrinolysis occurs secondary to inhibition of plasmin generation. Pravastatin therapy is associated with a reduction in the size of aortic atheroma which is an independent risk factor for stroke. Lastly, left ventricular dysfunction after acute myocardial infarction is associated with an increased risk of stroke and HMG-CoA reductase inhibitors may indirectly decrease the incidence of stroke by reducing coronary events. Most of these effects are independent of the cholesterol-lowering effects of HMG-CoA reductase inhibitors. In conclusion, HMG-CoA reductase inhibitors may have a role in primary prevention of stroke in patients with CAD.
Am J Cardiovasc Drugs 2002
PMID:How do HMG-CoA reductase inhibitors prevent stroke? 1472 94

Tissue plasminogen activator is a serine protease that plays the dominant role in removal of fibrin from the vascular tree by activating plasminogen to the primary fibrinolytic enzyme, plasmin. Tissue plasminogen activator has a widespread neuroendocrine distribution in addition to its expression by endothelial cells. Within neuroendocrine cells, secretory proteins are sorted into one of two pathways: regulated or constitutive. Proteins entering the regulated pathway are concentrated and stored in vesicles, and subsequently released upon stimulation by a secretagogue. In contrast, in the constitutive pathway, newly synthesized protein is not stored but is transported directly to the cell surface and secreted even in the absence of an extracellular signal. The focus of this article is to review recent studies demonstrating that tissue plasminogen activator is targeted to the regulated secretory pathway in neuroendocrine cells and to discuss the physiological implications of the trafficking of tissue plasminogen activator to regulated secretory vesicles.
Trends Cardiovasc Med 1998 Oct
PMID:Targeting of tissue plasminogen activator to the regulated pathway of secretion. 1498 55

Tissue-type plasmingen activator (tPA) is a highly specific serine proteinase that activates the zymogen plasminogen to the broad-specificity proteinase plasmin. tPA is found in the blood, where its primary function is as a thrombolytic enzyme, as well as in the central nervous system (CNS), where it promotes events associated with synaptic plasticity and cell death in a number of settings, such as cerebral ischemia and seizures. Neuroserpin is a fully inhibitory serine proteinase inhibitor (serpin) that reacts preferentially with tPA, and is located in regions of the brain where either tPA message or tPA protein are also found, suggesting that neuroserpin is the selective inhibitor of tPA in the CNS. There is a growing body of evidence demonstrating the participation of tPA in a number of physiologic and pathologic events in the CNS, and the role of neuroserpin as the natural regulator of tPA's activity in these processes.
Trends Cardiovasc Med 2004 Jul
PMID:Tissue-type plasminogen activator and neuroserpin: a well-balanced act in the nervous system? 1526 88

Plasminogen (Plg) and its derivative serine protease, plasmin, together with the activators, inhibitors, modulators, and substrates of the Plg network, are postulated to regulate a wide variety of biologic responses that could influence cardiovascular disease. The development of Plg-deficient mice has provided an incisive approach to test these proposed functions in vivo. Several different models of atherosclerosis, restenosis, aneurysm, and thrombosis have been analyzed in these mice and have demonstrated profound effects of Plg on these events as well as on the inflammatory response, which contributes to these cardiovascular diseases. Plasmin (ogen) may influence the progression of cardiovascular diseases through its degradation of matrix proteins, including fibrin; its activation of matrix metalloproteinases; its regulation of growth factor and chemokine pathways; or its influence on directed cell migration. Dissection of these mechanisms represents a future challenge toward understanding the roles of Plg in vivo.
Trends Cardiovasc Med 2004 Jul
PMID:The functions of plasminogen in cardiovascular disease. 1526 89

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