Imaging analyses of coagulation-dependent initiation of fibrinolysis on activated platelets and its modification by thrombin-activatable fibrinolysis inhibitor.

Using intravital confocal microscopy, we observed previously that the process of platelet phosphatidylserine (PS) exposure, fibrin formation and lysine binding site-dependent plasminogen (plg) accumulation took place only in the centre of thrombi, not at their periphery. These findings prompted us to analyse the spatiotemporal regulatory mechanisms underlying coagulation and fibrinolysis. We analysed the fibrin network formation and the subsequent lysis in an in vitro experiment using diluted platelet-rich plasma supplemented with fluorescently labelled coagulation and fibrinolytic factors, using confocal laser scanning microscopy. The structure of the fibrin network formed by supplemented tissue factor was uneven and denser at the sites of coagulation initiation regions (CIRs) on PS-exposed platelets. When tissue-type plasminogen activator (tPA; 7.5 nM) was supplemented, labelled plg (50 nM) as well as tPA accumulated at CIRs, from where fibrinolysis started and gradually expanded to the peripheries. The lysis time at CIRs and their peripheries (50 µm from the CIR) were 27.9 ± 6.6 and 44.4 ± 9.7 minutes (mean ± SD, n=50 from five independent experiments) after the addition of tissue factor, respectively. Recombinant human soluble thrombomodulin (TMα; 2.0 nM) attenuated the CIR-dependent plg accumulation and strongly delayed fibrinolysis at CIRs. A carboxypeptidase inhibitor dose-dependently enhanced the CIR-dependent fibrinolysis initiation, and at 20 µM it completely abrogated the TMα-induced delay of fibrinolysis. Our findings are the first to directly present crosstalk between coagulation and fibrinolysis, which takes place on activated platelets' surface and is further controlled by thrombin-activatable fibrinolysis inhibitor (TAFI).

Design and characterization of a selenium-containing inhibitor of activated thrombin-activatable fibrinolysis inhibitor (TAFIa), a zinc-containing metalloprotease.

Available therapies for thromboembolic disorders include thrombolytics, anticoagulants, and antiplatelets, but these are associated with complications such as bleeding. To develop an alternative drug which is clinically safe, we focused on activated thrombin-activatable fibrinolysis inhibitor (TAFIa) as the target molecule. TAFIa is a zinc-containing carboxypeptidase that significantly inhibits fibrinolysis. Here we designed and synthesized selenium-containing compounds 5-13 to discover novel TAFIa inhibitors having a superior zinc-coordinating group. Compounds 5-13 significantly inhibited TAFIa activity (IC(50) 2.2 × 10(-12) M - 2.6 × 10(-6) M). We found that selenol is a better functional group than thiol for coordinating to zinc at the active site of TAFIa. Furthermore, compound 12, which has an amino-chloro-pyridine ring, was found to be a potent and selective TAFIa inhibitor that lacks carboxypeptidase N inhibitory activity. Therefore, compound 12 is a promising candidate for the treatment of thromboembolic disorders. This is the first report of a selenium-containing inhibitor for TAFIa.

Carbon monoxide-releasing molecule-2 decreases fibrinolysis in human plasma.

Carbon monoxide, derived from carbon monoxide-releasing molecules, has been recently demonstrated to enhance the velocity of formation and strength of plasma thrombi. We tested the hypothesis that carbon monoxide-releasing molecule-2 would modulate fibrinolysis of plasma thrombi. Normal plasma was exposed to 0, 25, 50, 100 or 200 micromol/l carbon monoxide-releasing molecule-2, with coagulation activated with tissue factor and fibrinolysis initiated with tissue-type plasminogen activator. Additional experiments utilized factor XIII, plasminogen activator inhibitor-1, thrombin activatable fibrinolysis inhibitor or alpha2-antiplasmin-deficient plasmas. Thrombus growth/disintegration kinetics was monitored with thrombelastography. Carbon monoxide-releasing molecule-2, in a concentration-dependent fashion, increased the velocity of thrombus formation and strength, and markedly attenuated fibrinolysis in normal plasma. In factor XIII-deficient plasma, carbon monoxide-releasing molecule-2 mediated effects on thrombus growth/disintegration kinetics were similar to that seen with normal plasma; however, carbon monoxide-releasing molecule-2 had a less marked effect on thrombus growth/disintegration in both plasminogen activator inhibitor-1 and thrombin activatable fibrinolysis inhibitor-deficient plasma, with even less carbon monoxide-releasing molecule-2-mediated effects noted in alpha2-antiplasmin-deficient plasma. Carbon monoxide-releasing molecule-2 attenuated fibrinolysis by enhancing the velocity of clot growth and strength while augmenting the effects of plasminogen activator inhibitor-1, thrombin activatable fibrinolysis inhibitor and alpha2-antiplasmin. These findings serve as the rationale for further investigations to determine if carbon monoxide-releasing molecules could be utilized as hemostatic agents.

Fibrinolytic efficacy of Amediplase, Tenecteplase and scu-PA in different external plasma clot lysis models: sensitivity to the inhibitory action of thrombin activatable fibrinolysis inhibitor (TAFI).

In this study, the in-vitro fibrinolytic efficacy of Tenecteplase, Amediplase and scu-PA was investigated in different external lysis models by measuring the lysis of human plasma clots after the addition of the plasminogen activators (PAs) to the surrounding plasma. The effect of TAFI was examined for each PA by neutralising TAFIa with potato carboxypeptidase inhibitor (PCI). The lytic efficacy of Amediplase was lower than that of Tenecteplase at low PA concentrations but slightly higher at therapeutic concentrations. The activity of scu-PA was clearly lower than that of either Tenecteplase or Amediplase. The TAFI system inhibited external clot lysis mediated by all the PAs when thrombomodulin was present in the model. In the therapeutic range (5-10 mug/ml) however, the TAFIa effect was negligible for both Amediplase and Tenecteplase. At lower PA concentrations the effect of TAFI on Amediplase was slightly stronger than that on Tenecteplase. Under static conditions the lysis rates were lower than with stirring. The role of TAFI was similar under both conditions. In conclusion, at therapeutic concentrations Amediplase was slightly more active than Tenecteplase and scu-PA under all conditions used. Therefore, Amediplase might possibly be a more potent thrombolytic agent at these concentrations and increase the efficacy of thrombolysis. The potential of TAFI for inhibiting thrombolytic therapy is probably low. However in conditions where the local PA concentrations are sub-optimal TAFI might affect the lysis rate.

Thrombin activatable fibrinolysis inhibitor (TAFI) affects fibrinolysis in a plasminogen activator concentration-dependent manner. Study of seven plasminogen activators in an internal clot lysis model.

TAFIa was shown to attenuate fibrinolysis. In our in vitro study, we investigated how the inhibitory effect of TAFIa depended on the type and concentration of the plasminogen activator (PA). We measured PA-mediated lysis times of plasma clots under conditions of maximal TAFI activation by thrombin-thrombo-modulin in the absence and presence of potato carboxypeptidase inhibitor. Seven different PAs were compared comprising both tPA-related (tPA, TNK-tPA, DSPA), bacterial PA-related (staphylokinase and APSAC) and urokinase-related (tcu-PA and k2tu-PA) PAs. The lysis times and the retardation factor were plotted against the PA concentration. The retardation factor plots were bell-shaped. At low PA concentrations, the retardation factor was low, probably due to the limited stability of TAFIa. At intermediate PA concentrations the retardation factor was maximal (3-6 depending on the PA), with TNK-tPA, APSAC and DSPA exhibiting the strongest effect. At high PA concentrations, the retardation factor was again low, possibly due to inactivation of TAFIa by plasmin or to a complete conversion of glu-plasminogen into lys-plasminogen. Using individual plasmas with a reduced plasmin inhibitor activity (plasmin inhibitor Enschede) the bell-shaped curve of the retardation factor shifted towards lower tPA and DSPA concentrations, but the height did not decrease. In conclusion, TAFIa delays the lysis of plasma clots mediated by all the plasminogen activators tested. This delay is dependent on the type and concentration of the plasminogen activator, but not on the fibrin specificity of the plasminogen activator. Furthermore, plasmin inhibitor does not play a significant role in the inhibition of plasma clot lysis by TAFI.