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 heme binding sites of rabbit histidine-rich glycoprotein (HRG), 94 kDa, were studied with rose bengal (RB), a fluorescein derivative that associates with histidine residues. Difference absorbance spectra indicate that HRG binds RB at two thermodynamically preferred sites (Kd approximately 2 microM) that are spectroscopically equivalent. Up to 18-22 equiv of RB can also be bound by a set of lower affinity sites. Mesoheme is capable of displacing RB from the two preferred sites (Kd = 0.6 microM) and provides evidence that the two sites are not identical. Two peptides isolated from plasmin-digested HRG, one 35-kDa peptide rich in histidine (approximately 30 mol %) and one 15-kDa peptide relatively poor in histidine (approximately 4 mol %), also bind RB and mesoheme. The two preferred RB binding sites of HRG are located on the 15-kDa histidine-poor peptide and the lower affinity "class" of sites on the 35-kDa histidine-rich peptide. Mesoheme or RB quenches the tryptophan fluorescence of HRG and the histidine-poor peptide with an apparent binding stoichiometry near 2. Fluorescence quenching also indicates that 1-2 equiv of Cu(II) binds to the 15-kDa peptide, and absorbance spectroscopy provides evidence that Cu(II) is capable of displacing heme from the peptide. The fluorescence lifetimes of RB, determined by phase-modulation fluorometry, indicate that the two preferred sites in the histidine-poor domain are more apolar than the more numerous sites located in the histidine-rich region of the protein.
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PMID:Preferred heme binding sites of histidine-rich glycoprotein. 408

The capacity of the human hepatoma cell line Hep G2 to synthesize and secrete components of the fibrinolytic system was examined. Although fibrinogen, plasminogen, and alpha 2-antiplasmin were present in culture supernatants, histidine-rich glycoprotein was not detected. Albumin was monitored for comparative purposes and was also secreted. Intracellular levels of the fibrinolytic proteins were not detected, suggesting that once synthesized, these proteins were rapidly secreted by the cell. The fibrinogen, plasminogen, alpha 2-antiplasmin, and albumin secreted by the cells were immunochemically identical to their plasma counterparts. The concentration of these four molecules increased exponentially with time in the culture medium when normalized to total cellular protein. The kinetics of their secretion were similar, but the amounts of each protein differed. On day 8 the culture medium contained 29.6, 0.64, 0.39, and 0.59 micrograms/ml albumin, fibrinogen, plasminogen, and alpha 2-antiplasmin, respectively, whereas the time required for doubling the concentrations of the proteins in the medium ranged from 2.20 to 2.49 days. A detailed characterization of alpha 2-antiplasmin demonstrated that this inhibitor was synthesized by the cells. The molecular weight of intrinsically labeled alpha 2-antiplasmin was 69,000. The secreted inhibitor was biologically active, since it could inhibit plasmin cleavage of a chromogenic substrate, and this inhibition was neutralized by monospecific antibodies to alpha 2-antiplasmin. In addition, intrinsically labeled alpha 2-antiplasmin and the plasma molecule behaved in an identical manner with respect to their capacity to form a complex with plasmin. These studies suggest that the Hep G2 cell line may provide a model for assessing the regulation of synthesis and secretion of components of the human fibrinolytic system.
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PMID:Synthesis and secretion of the fibrinolytic components, including alpha 2-antiplasmin, by a human hepatoma cell line. 618 56

Fibrinolytic factors were assessed during L-asparaginase administration, to study whether their changes may predispose to a haemorrhagic or thrombotic diathesis. The total level of alpha 2-antiplasmin declined, as well as the ratio of the plasminogen-binding form of alpha 2-antiplasmin to the non-plasminogen-binding form. After cessation of L-asparaginase administration, the ratio increased to 1.6 times that of the pretreatment value. These data indicate that the plasminogen-binding form of alpha 2-antiplasmin is the form primarily synthesized in vivo. L-Asparaginase therapy reduced plasma levels of plasminogen and histidine-rich glycoprotein ( HRG ) and influenced the equilibrium between HRG , plasminogen and HRG -plasminogen complex, with a more pronounced decrease of plasminogen (62% +/- 8) and HRG (76% +/- 11) in comparison to the free-plasminogen levels (51% +/- 6). alpha 2-Macroglobulin was only slightly influenced by L-asparaginase and may consequently play a more pronounced role in inhibition. This is suggested by moderate declines in functional tests of plasmin, urokinase and tissue activator inhibition by patients plasma, and by the ratio of inhibition of these enzymes over alpha 2-antiplasmin. Thus the bleeding tendency described during L-asparaginase therapy can be ascribed not only to a temporary deficiency of coagulation factors but also to temporary alpha 2-antiplasmin deficiency.
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PMID:The influence of L-asparaginase therapy on the fibrinolytic system. 620 49

Thrombospondin (TSP), a multifunctional alpha-granule glycoprotein of platelets, binds fibrinogen, fibronectin, heparin, and histidine-rich glycoprotein and thus may play an important role in regulating thrombotic influences at vessel surfaces. In this study we have demonstrated that purified human platelet TSP formed a complex with purified human plasminogen (Plg). Complex formation was detected by rocket immunoelectrophoresis of mixtures of the purified radiolabeled proteins. Significant complex formation of fluid-phase Plg with adsorbed TSP was also demonstrated by enzyme-linked immunosorbent assay (ELISA). The complex formation was specific, saturable, and inhibited by excess fluid-phase TSP, with an apparent KD of approximately 35 nM. In both ELISA and rocket immunoelectrophoresis systems, complex formation was inhibited by 10 mM epsilon-amino-n-caproic acid, implying that there is a role for the lysine binding sites of Plg in mediating the interaction. TSP also formed a complex with plasmin as detected by ELISA but did not directly inhibit plasmin activity measured with a synthetic fluorometric substrate or with a 125I-fibrin plate assay. TSP, when incubated with Plg before addition to 125I-fibrin plates significantly inhibited the generation of plasmin activity by tissue plasminogen activator (TPA) in a manner that was calcium dependent. A kinetic study of Plg activation by TPA in the presence of TSP demonstrated that Michaelis-Menten kinetics were followed and that TSP acted as a noncompetitive inhibitor. These studies support the hypothesis that TSP, acting as a multifunctional regulator in focal areas of active hemostasis, could serve as a prothrombotic influence, leading to increased deposition of fibrin.
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PMID:Complex formation of platelet thrombospondin with plasminogen. Modulation of activation by tissue activator. 643 54

Active-site-inhibited plasmin was prepared by inhibition with d-valyl-l-phenylalanyl-l-lysylchloromethane or by bovine pancreatic trypsin inhibitor (Kunitz inhibitor). Active-site-inhibited Glu-plasmin binds far more strongly to fibrin than Glu-plasminogen [native human plasminogen with N-terminal glutamic acid (residues 1-790)]. This binding is decreased by alpha(2)-plasmin inhibitor and tranexamic acid, and is, in the latter case, related to saturation of a strong lysine-binding site. In contrast, alpha(2)-plasmin inhibitor and tranexamic acid have only weak effects on the binding of Glu-plasminogen to fibrin. This demonstrates that its strong lysine-binding site is of minor importance to its binding to fibrin. Active-site-inhibited Lys-plasmin and Lys-plasminogen (Glu-plasminogen lacking the N-terminal residues Glu(1)-Lys(76), Glu(1)-Arg(67) or Glu(1)-Lys(77))display binding to fibrin similar to that of active-site inhibited Glu-plasmin. In addition, alpha(2)-plasmin inhibitor or tranexamic acid similarly decrease their binding to fibrin. Glu-plasminogen and active-site-inhibited Glu-plasmin have the same gross conformation, and conversion into their respective Lys- forms produces a similar marked change in conformation [Violand, Sodetz & Castellino (1975) Arch. Biochem. Biophys.170, 300-305]. Our results indicate that this change is not essential to the degree of binding to fibrin or to the effect of alpha(2)-plasmin inhibitor and tranexamic acid on this binding. The conversion of miniplasminogen (Glu-plasminogen lacking the N-terminal residues Glu(1)-Val(441)) into active-site-inhibited miniplasmin makes no difference to the degree of binding to fibrin, which is similarly decreased by the addition of tranexamic acid and unaffected by alpha(2)-plasmin inhibitor. Active-site-inhibited Glu-plasmin, Lys-plasmin and miniplasmin have lower fibrin-binding values in a plasma system than in a purified system. Results with miniplasmin(ogen) indicate that plasma proteins other than alpha(2)-plasmin inhibitor and histidine-rich glycoprotein decrease the binding of plasmin(ogen) to fibrin.
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PMID:Secondary-site binding of Glu-plasmin, Lys-plasmin and miniplasmin to fibrin. 645 79

In a prospective study of deep vein thrombosis (DVT), detected by the Tc-plasmin test, in 34 patients with acute myocardial infarction sequential determinations were made in plasma by immunologic methods of histidine-rich glycoprotein (HRG) and total plasminogen and the concentrations of free plasminogen calculated. Mean plasma HRG concentrations were consistently higher in the group of patients, in which Tc-plasmin scanning had revealed the existence of DVT. The effect of HRG caused the level of free plasminogen to be only 50-60% of the level of total plasminogen. Fluctuations of HRG caused only minor changes in free plasminogen concentrations. Our data suggest that HRG acts as a weak, negative acute phase reactant.
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PMID:A sequential study of plasma histidine-rich glycoprotein and plasminogen in patients with acute myocardial infarction and deep vein thrombosis. 671 93

The plasminogen activator systems in the blood, the coagulation system, and the complement pathways are reviewed. The review describes the role of the vascular intima in activation of coagulation and fibrinolysis and the interrelations between the complement system and haemostatic mechanisms. Physiological activation of fibrinolysis may be triggered by and limited to fibrin because of a special affinity of plasminogen and plasminogen activators. The binding of plasminogen to fibrin is regulated by histidine-rich glycoprotein, and the primary physiological inhibitor of generated plasmin is alpha 2-antiplasmin and especially the plasminogen-binding form of this immediate plasmin inhibitor. Plasminogen activator inhibitors in the blood, that is, notably plasminogen activator inhibitor type 1 (PAI-1), bind circulating tissue-type plasminogen activator (t-PA). However, local fibrinolysis in vivo mediated by t-PA may be independent of complex formation between plasminogen activator inhibitors and t-PA in the fluid phase. Circulating plasminogen activator inhibitors might regulate fibrinolysis by increasing the clearance of t-PA from the blood. The urokinase-type and factor XII-dependent fibrinolytic proactivator system can be activated following t-PA-mediated generation of plasmin, and could thus serve as an amplification system of t-PA-induced fibrinolysis. It is claimed that the as yet uncharacterized proactivator is essential for optimal generation of plasminogen activator activity by the factor XII-dependent fibrinolytic system. The normal antithrombotic condition of the vascular intima probably results from lack of tissue factor activity and the presence of significant antithrombotic components comprising, among others, antithrombin III and the protein C-protein S system. A number of pathophysiologic stimuli, notably mediators of the acute phase response such as the cytokines interleukin-1 and tumour necrosis factor-alpha (cachectin), have the potential to induce the vascular endothelium to express procoagulant activity. Vascular endothelium promoting coagulant activity releases increased amounts of t-PA antigen and PAI-1 antigen into the circulation, and elevated levels in the blood of both may be regarded as a marker of a generalized procoagulant condition involving the vascular endothelium. In a prospective study in patients with unstable angina pectoris, patients in whom disease progresses and acute myocardial infarction develops, have increased amounts of t-PA antigen and PAI-1 antigen in the blood. This suggests that the procoagulant potential and atherosclerotic process of the vascular intima is more pronounced in the risk group.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Fibrinolysis in patients with acute ischaemic heart disease. With particular reference to systemic effects of tissue-type plasminogen activator treatment on fibrinolysis, coagulation and complement pathways. 822 63

Anabolic steroids increase the activity of the fibrinolytic system by reducing plasma levels of inhibitors (plasminogen activator inhibitor type I, histidine-rich glycoprotein, alpha-2-macroglobulin) and increasing plasma levels of tissue-type plasminogen activator activity, plasminogen, and plasmin activity (B beta 15-42 fragment of fibrinogen). Plasminogen activator inhibitor levels are elevated, and tissue-type plasminogen activator activity is depressed, in a variety of disease states, including premature venous or arterial thrombosis, connective tissue disorders, and cancer. Such abnormalities can be reversed by anabolic steroids. However the clinical benefits and adverse effects of such treatment remain to be established by large, randomized controlled trials.
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PMID:Anabolic steroids and fibrinolysis. 825 52

High levels of histidine-rich glycoprotein (HRGP) and plasminogen activator inhibitor-1 (PAI-1) have been claimed to contribute to the hypofibrinolytic state observed in patients with venous thrombosis. These abnormalities were detected, respectively, in eight and 10 members of a family from which four of seven members with both abnormalities had venous thromboembolism. Binding of tissue plasminogen activator (t-PA) by PAI-1 may induce hypofibrinolysis. To determine whether plasminogen binding by HRGP may influence plasminogen activation, we studied the fibrinolytic activity of members of this family cohort with a system that detects modifications in plasmin generation by proteins interfering with the binding of plasminogen to fibrin. Plasminogen activation was performed by adding plasma to fibrin surfaces to which t-PA had been previously bound in the presence of 40 mg/ml bovine serum albumin and 20 mumol/L of the lysine analog trans-4-(aminomethyl)-cyclohexane carboxylic acid to prevent nonspecific binding and thereby the inhibitory effect of elevated PAI-1 levels. The generation of plasmin as a function of time was detected (1) by photometric analysis with a chromogenic substrate highly selective for plasmin and (2) by measuring the binding and activation of plasminogen at the fibrin surface with radiolabeled plasminogen. The amount of plasmin generated by plasma from patients having high levels of HRGP (160% to 280%) was similar to that of a control group having normal levels of HRGP (100% +/- 22%). Similar results were obtained with a plasma artificially depleted in HRGP and supplemented with various amounts of this protein. No correlation between HRGP level and t-PA-mediated plasminogen activation was observed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Familial association of high levels of histidine-rich glycoprotein and plasminogen activator inhibitor-1 with venous thromboembolism. 847 89

The complete primary structure of rabbit plasma histidine-proline-rich glycoprotein (HPRG), also known as histidine-rich glycoprotein, was determined by a combination of cDNA and peptide sequencing. Limited proteolysis with plasmin yielded three disulfide-linked fragments that were further purified. Reduction of the disulfide bonds with dithiothreitol under nondenaturing conditions releases the central, histidine-proline-rich domain, which contains 15 tandem repeats of the pentapeptide [H/P]-[H/P]PHG. The N-terminal fragment (295 amino acids), consisting of two cystatin-like modules, is bound to the proline-rich C-terminal fragment (105 amino acids) via a buried disulfide bond whose reduction requires prior denaturation. Far-UV circular dichroism spectra revealed beta-sheet with some alpha-helix, polyproline-II helix, and random coil in the secondary structure of the N-terminal, central, and C-terminal domains, respectively. The modular architecture of HPRG suggests that it may have several independent binding sites and that its biological role may be to bring two or more ligands together. The histidine-proline-rich domain, which contains 34 of the 53 histidine residues of HPRG, binds heparin and has an isoelectric point of 7.15 and a relatively high apparent pKa (7.0) of its histidine residues, and thus it probably mediates the interaction between HPRG and heparin, which is strikingly sensitive to pH in the range 7.0-7.4 [Peterson et al. (1987) J. Biol. Chem. 262, 7567-7574]. Solvent perturbation and second-derivative UV spectroscopy of HPRG revealed changes in the environment of tryptophan residues upon lowering the pH. This transition had a midpoint at pH 6.0 and required the disulfide bond bridging the histidine-proline-rich domain to the N/C fragment. The data are consistent with the mutual repulsion of protonated histidine residues in the histidine-proline-rich region causing a conformational change transmitted to the rest of the molecule via the disulfide bond.
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PMID:Domain structure and conformation of histidine-proline-rich glycoprotein. 863 76

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