Synergism of thrombolytic agents in vivo

The existence of significant synergism between tissue-type plasminogen activator (t-PA) and single-chain urokinase-type plasminogen activator (scu-PA), and between t-PA and urokinase in thrombolysis in vivo is described. In a quantitative preparation of thrombolysis, consisting of rabbits in which a blood clot was induced in the jugular vein with 125I-labeled fibrin, intravenous infusion over 4 hr of t-PA, scu-PA, or urokinase in amounts of 0.5, 1.0, or 2.0 mg/kg body weight resulted in significant thrombolysis (30% to 60%). The simultaneous infusion of t-PA and scu-PA or of t-PA and urokinase had a significantly greater (p less than .001) thrombolytic effect than could be anticipated on the basis of the added effects of each agents alone. However, no synergism was observed between scu-PA and urokinase. The observed alpha 2-antiplasmin consumption and fibrinogen breakdown after urokinase at higher doses did not occur with the equivalent thrombolytic combinations of t-PA and urokinase. The combined use of synergic thrombolytic agents in patients may permit a significant reduction in total administered doses, probably with elimination of the systemic activation of the fibrinolytic system and the concomitant fibrinogen breakdown that is unavoidable with the currently used thrombolytic doses of each agent.     

Comparison of the effects of fibrin binding on the biochemical properties of single-chain tissue-type plasminogen activator (t-PA) and single-chain chimeric plasminogen activator (t-PA/scu-PA).

The effect of the binding of the single-chain chimeric plasminogen activator t-PA/scu-PA, which contains amino acids 1 to 274 of tissue-type plasminogen activator (t-PA) and amino acids 138 to 411 of single-chain urokinase-type plasminogen activator (scu-PA), to fibrin on its biochemical properties was investigated in a purified system. In contrast to the binding of single-chain tissue-type plasminogen activator (sct-PA) on fibrin, which causes an increase in its intrinsic activity, t-PA/scu-PA enzyme activity is not elevated. In contrast to sct-PA which retains its single-chain form during fibrin-binding, t-PA/scu-PA is converted to its more active two-chain form. The activating process of t-PA/scu-PA is accelerated by increasing fibrin concentrations. With constant concentrations of fibrin monomer, the activation velocity also increases with time. Since this effect is inhibited by epsilon-aminocaproic acid and by a monoclonal antibody directed against the fibrin-binding site of t-PA, the activation process depends on the fibrin-binding of the molecule. The results point to the fact that t-PA/scu-PA is autocatalytically converted to its two-chain form during fibrin-binding. The conspicuous differences of the effect of the fibrin-binding on the biochemical properties of sct-PA and t-PA/scu-PA are caused obviously by small differences in the structures of the protease-domains and/or by different communications between the identical A-chains and the protease domains of the enzymes.     

Inactivation of single-chain urokinase (pro-urokinase) by thrombin and thrombin-like enzymes: relevance of the findings to the interpretation of fibrin-binding experiments

Whereas crude bovine thrombin activated single-chain urokinase-type plasminogen activator (scu-PA), otherwise called pro-urokinase (pro- UK), purified human thrombin converted pro-UK (scu-PA) to a two-chain form that had no amidolytic activity. The two chains (Mr approximately 33,000 and 22,000) were disulfide linked and resistant to subsequent activation by plasmin. By contrast, thrombin did not inactivate tissue plasminogen activator or two-chain urokinase. The enzyme from snake venom Agkistrodon contortrix, relatively specific for fibrinopeptide B, had an effect similar to thrombin, whereas the enzyme from Agkistrodon rhodostoma (ancrod), specific for fibrinopeptide A, did not. When pro- UK (scu-PA) was present during thrombin clotting of fibrinogen, degradation of 125I-pro-UK (scu-PA) in the clot supernatant was seen, whereas virtually full recovery (95%) of radioactivity was found. A loss of latent amidolytic activity in the clot supernatant was also found, the extent of which could be correlated with the degree of degradation of the radiolabeled probe. It was concluded that thrombin inactivation of pro-UK (scu-PA) accounts for the loss of amidolytic activity in the clot supernatant, which has been attributed to fibrin binding. Further confirmation was obtained from experiments in which ancrod was used as the clotting agent. Full recovery of both radioactivity and latent amidolytic activity of pro-UK (scu-PA) in the supernatant was obtained under these conditions. These findings indicate that thrombin may introduce an artifact in the results of certain experiments designed to study the fibrin affinity or fibrinolytic effect of pro-UK (scu-PA).     

Future directions in plasminogen activator therapy

Thrombotic disorders such as myocardial infarction and stroke are the leading causes of death and disability in industrialized nations. Timely institution of thrombolytic therapy can achieve a reduction of infarct size, a preservation of left ventricular function, and a reduction in mortality. The administration of streptokinase, urokinase, and acylated plasminogen-streptokinase activator complex (APSAC) can be associated with a complete breakdown of the hemostatic system. Tissue-type plasminogen activator (t-PA) and single-chain urokinase-type plasminogen activator (scu-PA, prourokinase) are more fibrin specific; however, at the large dosages of activator needed for therapeutic efficacy, bleeding complications are still a problem. New approaches to optimizing the risk/benefit ratio for the patient by improving efficacy without sacrificing specificity include the use of synergistic combinations of plasminogen activators, mutants of t-PA and scu-PA, chimeric molecules, and antibody-targeted thrombolytic agents. The last approach opens the possibility of targeting several different components of the clot with either fibrinolytic or antiplatelet effector functions in one optimized molecule.     

Pro-urokinase: a study of its stability in plasma and of a mechanism for its selective fibrinolytic effect

Highly purified pro-urokinase (pro-UK) or single-chain urokinase-type plasminogen activator (scu-PA) was treated with diisopropylfluorophosphate (1 mmol/L) to eliminate traces of two-chain UK activity. This preparation was found to retain a low activity against a chromogenic substrate (S2444), equivalent to 0.1% to 0.5% of the activity of its plasmin-activated derivative. Evidence is presented that the intrinsic activity of pro-UK (scu-PA) was sufficient to activate plasminogen on a fibrin plate or in buffer and was far more reactive against Lys-plasminogen than against Glu-plasminogen. The relative resistance of Glu-plasminogen to activation was overcome by the addition of lysine (25 mmol/L) to the reaction mixture. By contrast, in plasma, pro-UK (scu-PA) was stable and nonreactive for greater than 72 hours when incubated (37 degrees C). Pro-UK (scu-PA) did not form sodium dodecyl sulfate-stable inhibitor complexes, whereas complexation occurred rapidly with UK. Only at high concentrations of pro-UK (scu-PA) (greater than or equal to 250 IU/mL) did plasminogen activation in plasma occur. The relative inertness of pro-UK (scu-PA) in plasma, in contrast to its low-grade enzymatic activity in buffer, was attributed to the effect of inhibitors. The addition of EDTA or the removal of divalent cations by dialysis was associated with a lower threshold for nonspecific plasminogen activation by pro-UK (scu-PA) in plasma. Replacement of Ca++ but not other cations restored baseline conditions. In the presence of a clot, fibrin-selective plasminogen activation and clot lysis were triggered. Lysis was accompanied by less than 10% conversion of pro-UK (scu-PA) to two-chain UK, suggesting that the intrinsic activity of pro-UK (scu-PA) itself may have been responsible for fibrinolysis, although a contribution by the small amount of UK generated could not be excluded. Similarly, pro-UK (scu- PA) supported clot lysis for several days in the same plasma before the effect dissipated as a result of degradation to UK. When Glu- plasminogen in plasma was replaced by Lys-plasminogen, or when lysine was added to normal plasma, nonselective plasminogen activation and fibrinogenolysis occurred. It was concluded that under the experimental conditions, the fibrin specificity of pro-UK (scu-PA) can be explained by its selective activation of fibrin-bound plasminogen and is due to the latter's Lys-plasminogen-like conformation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antithrombotic regulation in human endothelial cells by fibrinolytic factors

Vascular endothelial cells (ECs) modulate the blood fibrinolytic system by secreting tissue-type plasminogen activator (t-PA), urokinase-type plasminogen activator (u-PA), and their inhibitor, type-1 plasminogen activator inhibitor (PAI-1). ECs also express t-PA receptors (t-PAR) and u-PA receptors (u-PAR) on their cell surfaces, assembling both enzymes to regulate the cellular fibrinolytic activity. In addition, ECs modulate these factors in response to several stimuli. Fibrin clots on ECs induce the up- and downregulation of t-PA and PAI-1 production, respectively, thus causing an effective lysis of the fibrin clot. Heat shock (43 degrees C) increases the expression of u-PA, t-PA, PAI-1, and u-PAR by which ECs become more fibrinolytic around the cells. Furthermore, because ECs possess t-PAR and u-PAR on their cell surfaces, the binding of t-PA and u-PA is a critical event, which affords ECs the localized and condensed fibrinolytic potential. Therefore, ECs play a central role in antithrombotic activity by regulating the levels of these fibrinolytic factors.     

Potential approaches for therapeutic intervention of thrombosis by fibrinolytic agents

Fibrin-specific thrombolytic agents are being developed based on a better understanding of the molecular mechanisms that regulate in vivo fibrinolysis. These agents may be more effective than those available currently and may induce less systemic fibrinolysis. In this respect, t-PA has been extensively investigated. Another fibrinolytic substance with anticipated fibrin-selectivity is scu-PA. Although scu-PA has been much less extensively investigated than t-PA, sufficient knowledge is available to evaluate its potential as a fibrin-specific thrombolytic agent. Both t-PA and scu-PA are single-chain glycoproteins with a catalytic mechanism common to all serine proteases (active site composed of the charge relay system). Both molecules occur as single-chain forms but are converted easily to two-chain disulfide bonded molecules by digestion with plasmin. Unlike most other serine proteases for which the single-chain molecular form is a zymogen with little or no activity toward its natural substrate, both single-chain t-PA and scu-PA have inherent plasminogen-activating potential. Both t-PA and scu-PA induce fibrin-specific thrombolysis in a plasma environment and in animal models of thrombosis. However, the fibrin specificity of t-PA- and scu-PA-induced thrombolysis is based on different molecular mechanisms. The effectiveness and fibrin specificity of t-PA obtained by recombinant DNA technology recently were established by three randomized multicenter trials in patients with acute myocardial infarction. For scu-PA, clinical results are presently more limited.     

Lipoprotein(a) inhibits plasminogen activation in a template-dependent manner.

Lipoprotein(a) [Lp(a)] is a low density lipoprotein whose plasma levels strongly correlate with the occurrence of atherosclerotic disease. Structural studies have demonstrated that Lp(a) contains two disulphide bonded subunits, one of which has structural similarity to plasminogen. This subunit, designed apo-lipoprotein(a), contains multiple repeat copies of a kringle homologous to kringle-4 of plasminogen, one copy of a kringle-5-like structure and a domain homologous to the catalytic light chain of plasmin. This subunit, however, lacks the site where plasminogen activators cleave plasminogen to generate the active proteinase. Recent studies demonstrate that Lp(a) competes with plasminogen for binding to endothelial cells and macrophages and thus prevents assembly of the fibrinolytic system on cell surfaces. Lp(a) also inhibits activation of plasminogen by streptokinase, urokinase-type plasminogen activator or tissue-type plasminogen activator (t-PA). Inhibition of plasminogen activation by t-PA requires the presence of a template on which activation occurs. This template can be either fibrin or heparin. This review considers the role of Lp(a) as an inhibitor of template-dependent activation of the fibrinolytic system.     

An Analysis of Mechanisms Underlying the Antifibrinolytic Properties of Radiographic Contrast Agents

Background: Radiographic contrast agents inhibit fibrinolysis, although by poorly defined pathways. The purpose of this study was to define specific mechanisms by which contrast agents inhibit clot lysis. Methods and Results: Diatrizoate (high osmolar ionic agent), ioxaglate (low osmolar ionic), and ioversol (nonionic) were studied in vitro. Diatrizoate inhibited clot lysis by 81.3±0.6% vs. control (p<0.001). Ioxaglate inhibited clot lysis by 41.7±11.9%, which was of borderline significance (p=0.07). Ioversol did not significantly inhibit clot lysis (14.9±11.5% decrease vs. control; p>0.3). Inhibition of fibrinolysis was not explained by the high osmolarities of contrast agents, by their iodine content, or by their effects on the amidolytic activities of t-PA, urokinase, or plasmin. However, plasminogen activation by t-PA, urokinase, or streptokinase was significantly inhibited by contrast agents. Diatrizoate, ioxaglate, and ioversol inhibited plasminogen binding to plasma clots by 51±4% (p<0.001), 30.1±4% (p<0.01), and 19.4±7% (p=0.07), respectively. Plasma clots formed in the presence of contrast agents were resistant to lysis by plasmin. Diatrizoate produced the most potent effect, inhibiting clot lysis by 40±5.7% (p<0.03). Contrast agents did not inhibit plasminogen binding to fibrin or plasmin-mediated fibrinolysis if they were added after clot formation. Contrast agents altered clot turbidity, an index of fibrin structure, if present during clot formation, but not if added to preformed clots. Contrast agents did not affect plasminogen activator inhibitor-1 or ₂-antiplasmin function. Conclusions: Contrast agents inhibit clot lysis by inhibiting plasminogen activation and by disrupting interactions of plasminogen and plasmin with fibrin by altering fibrin structure. Significant variation in antifibrinolytic properties exists between different contrast agents. Abbreviated Abstract. The purpose of this study was to define specific mechanisms by which contrast agents inhibit clot lysis. In both a purified clot lysis system and a plasma clot lysis system, diatrizoate, an ionic agent, produced the most potent inhibition of fibrinolysis. Contrast agents did not inhibit the active sites of plasminogen activators or plasmin, but did inhibit plasminogen activation. Binding of plasminogen to fibrin and lysis of fibrin by plasmin were inhibited by contrast agents if they were present during clot formation, but not if they were added after clot formation was complete. Contrast agents altered clot turbidity, an index of fibrin structure, if present during clot formation, but not if added to preformed clots. Contrast agents did not affect plasminogen activator inhibitor-1 or ₂-antiplasmin function. The effects of contrast agents on fibrinolytic parameters were not explained by their high osmolarities. These results suggest that contrast agents inhibit clot lysis by inhibiting plasminogen activation and by disrupting interactions of plasminogen and plasmin with fibrin by altering fibrin structure.     

Inhibition of clot lysis and decreased binding of tissue-type plasminogen activator as a consequence of clot retraction.

Tissue-type plasminogen activator (t-PA) is less active in vivo and in vitro against clots that are enriched in platelets, even at therapeutic concentrations. The release of radioactivity from 125I-fibrin-labeled clots was decreased by 47% 6 hours after the addition of t-PA 400 U/mL when formed in platelet-rich versus platelet-poor plasma. This difference was not due to the release of plasminogen activator inhibitor-1 (PAI-1) by platelets. Thus, the fibrinolytic activity of t-PA in the supernatant was similar in the two preparations and fibrin autography demonstrated only a minor degree of t-PA-PAI-1 complex formation. Furthermore, a similar platelet-dependent reduction in clot lysis was seen with a t-PA mutant resistant to inhibition by PAI-1. The reduction in t-PA activity correlated with a decrease in t-PA binding to platelet-enriched clot (60% +/- 3% v platelet-poor clot, n = 5). This reduction in binding was also shown using t-PA treated with the chloromethylketone, D-Phe-Pro-Arg-CH2Cl (PPACK) (36% +/- 13%, n = 3), and with S478A, a mutant t-PA in which the active site serine at position 478 has been substituted by alanine (43% +/- 6%, n = 3). In contrast, fixed platelets and platelet supernatants had no effect on the binding or lytic activity of t-PA. Pretreatment with cytochalasin D 1 mumol/L, which inhibits clot retraction, also abolished the platelet-induced inhibition of lysis and t-PA binding by platelets. These data suggest that platelets inhibit clot lysis at therapeutic concentrations of t-PA as a consequence of clot retraction and decreased access of fibrinolytic proteins.     

Resistance of porcine blood clots to lysis relates to poor activation of porcine plasminogen by tissue plasminogen activator.

In-vitro experimentation was performed on porcine and human blood to determine their comparative responsiveness to a novel fibrinolytic inhibitor and thereby assess whether the pig is a suitable animal model for subsequent in-vivo testing of this inhibitor. Thromboelastography showed the clots formed from porcine whole blood to be highly resistant to tissue plasminogen activator (t-PA)-catalyzed lysis, and this communication offers the resistance of porcine plasminogen to activation by t-PA as an explanation. Porcine blood containing 100 and 1500 IU/ml added t-PA lysed very slowly, having LY30 values of 1.9 +/- 1.4 and 2.9 +/- 1.9%, respectively. In contrast, the LY30 values for the human clots containing 100 and 1500 IU/ml t-PA were 77.1 +/- 6.3 and 93.3 +/- 1.3%, respectively. Moreover, purified porcine plasminogen was activated very slowly by added t-PA in the presence of both human and porcine fibrin. Activation of plasminogen by the endogenous activators, as measured by the euglobulin clot lysis time, was greatly prolonged for the pig (22 +/- 3 h) compared with the human (3.5 +/- 1.5 h). These results suggest caution in using the pig as an experimental model when studying the effects of various agents on fibrinolysis.     

Comparative thrombolytic properties of bolus injections and continuous infusions of a chimeric (t-PA/u-PA) plasminogen activator in a hamster pulmonary embolism model

The recombinant chimeric plasminogen activator, rt-PA-delta FE/scu-PA- e, consisting of amino acids 1 to 3 and 87 to 274 of tissue-type plasminogen activator (t-PA) and amino acids 138 to 411 of single-chain urokinase-type plasminogen activator (scu-PA), has a markedly increased thrombolytic potency following its continuous intravenous infusion in animal models of venous thrombosis (Collen et al, Circulation, in press). In the present study, the thrombolytic potencies of intravenous bolus injections of rt-PA-delta FE/scu-PA-e, of recombinant t-PA (rt- PA), and of recombinant scu-PA (rscu-PA), given alone or in combination, were compared with those of intravenous infusions in a hamster pulmonary embolism model. Dose-dependent clot lysis was obtained in the absence of systemic activation of the fibrinolytic system and fibrinogen breakdown. In bolus injection experiments, the maximal rate of clot lysis, expressed in percent clot lysis per milligrams per kilogram compound administered, was 120 +/- 10 for rt- PA, 54 +/- 8 for rscu-PA, and 2,100 +/- 500 for rt-PA-delta FE/scu-PA-e (P less than .01 v rt-PA or rscu-PA). Comparative results with continuous infusion over 1 hour were 270 +/- 64, 99 +/- 18, and 1,500 +/- 250 (P less than .01 v rt-PA or rscu-PA) percent lysis per mg/kg compound infused for rt-PA, rscu-PA, and rt-PA-delta FE/scu-PA-e, respectively. Thus, rt-PA and rscu-PA are more potent when administered as an infusion than as a bolus, whereas rt-PA-delta FE/scu-PA-e is at least as potent when administered as a bolus. Combined bolus injections of rt-PA and rscu-PA had a 2.2-fold synergistic effect on clot lysis, but no synergism was observed with combined bolus injections or with combined infusions of rt-PA and rt-PA-delta FE/scu-PA-e, or of rscu-PA and rt-PA-delta FE/scu-PA-e. The present study thus shows that rt-PA- delta FE/scu-PA-e is much more potent for clot lysis than rt-PA or rscu- PA when administered as a bolus injection, but no synergistic interaction is observed between the chimera and either rt-PA or rscu-PA.     

Validity of enzyme-linked immunosorbent assays of cross-linked fibrin degradation products as a measure of clot lysis

Concentrations of cross-linked fibrin degradation products (XL-FDPs) in plasma, measured by enzyme-linked immunosorbent assays (ELISAs) based on monoclonal antibodies (MAbs) raised against fragment D-dimer of cross-linked fibrin, increase when patients are given fibrinolytic agents. Whether XL-FDPs derive from circulating cross-linked fibrin polymers in plasma, compared with clot-associated fibrin, has been questioned because increases in XL-FDP are measured by some assays after fibrinolysis in vitro in the absence of clot. We characterized the source of XL-FDP immunoreactivity in plasma of patients with acute myocardial infarction and ischemic heart disease and the response to plasminogen activation in vitro induced by pharmacological concentrations of tissue-type plasminogen activator (t-PA) and streptokinase. XL-FDPs were measured with two different ELISA. One, "pan-specific tag ELISA," was based on a capture MAb specific for XL-FDP and a tag MAb that recognizes an epitope exposed in the fragment D region of both fibrin and fibrinogen, whereas the other, "fibrin-specific tag ELISA," was based on a capture and tag MAbs both specific for fibrin. After plasminogen activation was induced in vitro in plasma from patients with myocardial infarction, increased concentrations of XL-FDP were measured by the pan-specific tag ELISA; however, concentrations measured with the fibrin-specific tag ELISA were not increased. To determine the mechanism for this discrepancy, plasma was subjected to immunoadsorption with a MAb specific for fragment D-dimer before and after in vitro activation of the fibrinolytic system and immunoblotting with a fragment D-dimer-specific MAb and with the pan-specific MAb. Increased concentrations of fragment D-dimer, as well as fibrinogen fragment D at high concentrations, were recognized by the specific MAb. Non-cross-linked fragments were also shown by immunoblotting with the pan-specific MAb to coprecipitate with cross-linked fibrin fragments. This suggested the increased concentrations of XL-FDP measured by the pan-specific tag ELISA after in vitro activation of the fibrinolytic system were due to detection of non-cross-linked fibrinogen fragments. However, fibrin fragment D-dimer concentrations were found to increase in plasma of 15 patients given t-PA for acute myocardial infarction. We conclude fragment D-dimer in plasma of patients during thrombolysis does not originate from circulating soluble cross-linked fibrin but rather is a marker of solid-phase fibrin dissolution, which may be quantitated with assays based on capture and tag antibodies that do not detect fibrinogen or its degradation products.     

Dusart syndrome: a new concept of the relationship between fibrin clot architecture and fibrin clot degradability: hypofibrinolysis related to an abnormal clot structure

Fibrinogen Dusart is a congenital dysfibrinogenemia (A-alpha 554 Arginine-->Cysteine) associated with severe thrombotic disorder, high incidence of thrombotic embolism, and abnormal fibrin polymerization. This thrombotic disorder was attributed to an abnormal clot thrombolysis with reduced plasminogen binding to fibrin and defective plasminogen activation by tissue plasminogen activator. The purpose of this work was to assess whether clot architecture could be involved in the thromboresistance of the fibrin Dusart and the high incidence of embolism. An important change in Dusart fibrin clot structure was identified with dramatic decrease of gel porosity (Ks), fiber diameters (d), and fiber mass-length ratios (mu) derived from permeation analysis. In addition, rigidity of the Dusart clot was found to be greatly increased compared with normal fibrin. We provide evidence that both thrombolysis resistance and abnormal rigidity of the fibrin Dusart are related to this abnormal architecture, which impairs the access of fibrinolytic enzymes to the fibrin and which is responsible for a brittle clot that breaks easily, resulting in a high incidence of embolism. Indeed, when restoring a normal clot structure by adding dextran 40 (30 mg/mL) before coagulation, clot thrombolysis and clot rigidity recovered normal values. This effect was found to be dose- dependent. We conclude that clot architecture is crucial for the propensity of blood clot to be degraded and that abnormal clot structure can be highly thrombogenic in vivo. The alpha-C domains of fibrinogen are determinant in fibrin clot structure.     

The interaction of plasminogen activator inhibitor 1 with plasminogen activators (tissue-type and urokinase-type) and fibrin: localization of interaction sites and physiologic relevance.

Plasminogen activator inhibitor 1 (PAI-1), an essential regulatory protein of the fibrinolytic system, harbors interaction sites for plasminogen activators (tissue-type [t-PA] and urokinase-type [u-PA]) and for fibrin. In this study, anti-PAI-1 monoclonal antibodies (MoAbs) were used to identify interaction sites of PAI-1 with these components. The binding sites of 18 different MoAbs were established and are located on five distinct "linear" areas of PAI-1. MoAbs, binding to two distinct areas of PAI-1, are able to prevent the inhibition of t-PA by PAI-1. In addition, two interaction sites for fibrin were identified on PAI-1. The area located between amino acids 110 and 145 of PAI-1 contains a binding site for both components and its significance is discussed in the context of the t-PA inhibition by fibrin-bound PAI-1. Subsequently, the MoAbs were used to assess the role of platelet-PAI-1 in clot-lysis. An in vitro clot-lysis system was used to demonstrate that clot-lysis resistance is dependent on the presence of activated platelets and that PAI-1 is a major determinant for lysis-resistance. We propose that, upon activation of platelets, PAI-1 is fixed within the clot by binding to fibrin and retains its full capacity to inhibit t-PA and u-PA.     

A monoclonal antibody preventing binding of tissue-type plasminogen activator to fibrin: useful to monitor fibrinogen breakdown during t-PA infusion

One (MA-1C8) of 36 monoclonal antibodies obtained by fusion of P3X63- Ag8-6.5.3 myeloma cells with spleen cells of mice immunized with purified human tissue-type plasminogen activator (t-PA) blocked the activity of t-PA on fibrin plates but not on chromogenic substrates. MA- 1C8 at a concentration of 200 micrograms/mL inhibited plasma clot lysis and binding of t-PA to the clot. MA-1C8 had no influence on the activation of plasminogen by t-PA, which obeys Michaelis-Menten kinetics with Km = 105 mumol/L and kcat = 0.05 s-1; however, it abolished the influence of CNBr-digested fibrinogen on Km. These findings confirm that the stimulatory effect of fibrin on the activation of plasminogen by t-PA is mediated by binding of t-PA to fibrin and provide additional support for the kinetic model. Addition of t-PA to pooled fresh human plasma to a concentration of 5 micrograms/mL resulted in extensive fibrinogen breakdown after incubation for one hour at 37 degrees C or during storage at -20 degrees C for one day. In both instances, fibrinogen degradation was completely prevented by addition of MA-1C8 to a concentration of 200 micrograms/mL of plasma. MA-1C8 also effectively prevented in vitro fibrinogen degradation and in vitro plasminogen activation in plasma samples obtained during infusion of recombinant t-PA in patients with thromboembolic disease. Thus, MA-1C8 is a useful tool for discriminating between in vivo and in vitro fibrinolysis during thrombolytic therapy with t-PA.     

Fibrinolysis at the fluid-solid interface of thrombi

Thrombolysis is conventionally regarded as dissolution of the fibrin matrix of thrombi by plasmin, a protease generated by plasminogen activators from its inactive precursor, plasminogen. Typically plasminogen activation occurs on the surface of the clot, where fibrin behaves as a cofactor in this process, and plasmin also initiates its proteolytic action at the fluid-solid interface. Although the basic reactions of the plasminogen/plasmin system in fluid phase are well characterized in terms of classical enzymology, they cannot explain completely the interfacial fibrinolytic events. Recently new methods have been introduced for quantitative evaluation of plasminogen activation on gel-phase fibrin and heterogenous-phase proteolysis, an overview of the new methodology is presented. Following formation of an interfacial lytic zone, fibrin dissolution proceeds through propagation of this zone to the core of the clot, which depends on diffusion and permeation phenomena affected by the composition of thrombi. Phospholipids (originating from platelets) form a diffusion barrier to the thrombolytic agents and also bind some of them; structural cellular proteins (namely myosin) interact with the fibrin fibers masking their cofactor and plasmin-cleavage sites. The contribution of these recent findings to our understanding of the limitations of current thrombolytic therapy is discussed. Finally, attention is focused on the termination of thrombus-associated proteolytic action in an environment abundant in proteinase inhibitors. Thus, combining together the interfacial events in the initiation, progress and termination of thrombolysis, a concept for modeling the thrombus as a temporary fibrinolytic compartment is presented.     

New strategies in the development of thrombolytic agents

Summary Recombinant DNA technology has allowed large-scale production of the physiological, fibrin-specific, plasminogen activators tissue-type plasminogen activator (t-PA) and single-chain urokinase-type plasminogen activator (scu-PA). The results of clinical trials with these agents, mainly for the treatment of acute myocardial infarction, have revealed a limited fibrin specificity at the large therapeutic doses required for efficient thrombolysis. Mutants and variants of t-PA and scu-PA have given important information on structure-function relationships in these proteins and have resulted in rt-PA variants with significantly prolonged half-lives in vivo. Construction of chimaeric plasminogen activators containing various portions of t-PA and scu-PA has produced functionally active enzymes, however with a lower fibrin-affinity than wild-type t-PA. The promise of antibody targeting and the use of synergistic combinations of thrombolytic agents remains to be further investigated. We anticipate that eventually these research lines will yield artificial plasminogen activators with improved efficacy, risk/benefit and cost/benefit ratios.     

Fibrin-associated plasminogen activation in alpha 2-plasmin inhibitor deficiency

The clot formed from the plasma of a patient with congenital deficiency of alpha 2-plasmin inhibitor underwent a spontaneous extensive fibrinolysis. Radiolabeled fibrinogen was added to the plasma before clotting, and the whole process of the fibrinolysis was followed by measuring the release of radiolabels. Plasminogen activation was also followed by measuring the amidolytic activity that developed. There was an initial latent period, followed by an exponential increase of fibrinolytic activity. During the latent period, there was little or no release of radiolabels and no development of amidolytic activity. During the latent period, the clot was washed thoroughly to remove unbound proteins from fibrin and was incubated in buffered saline. The washed clot still underwent fibrinolysis, similar to the original plasma clot, suggesting that the plasminogen/plasminogen activators bound to fibrin during the initial latent period are responsible for fibrinolysis. The amount of plasminogen bound to fibrin during the latent period was close to the amount of plasminogen activated during the whole process of fibrinolysis. When the amount of plasminogen bound to fibrin was decreased by epsilon aminocaproic acid, the extent of fibrinolysis was decreased in parallel with the decrease of the amount of the bound plasminogen. This suggests that the amount of plasminogen bound to fibrin is one of the determinants of the rate of the fibrinolytic process.     

Fibrinolysis during normal human pregnancy: complex inter-relationships between plasma levels of tissue plasminogen activator and inhibitors and the euglobulin clot lysis time

Although it has been previously considered that blood fibrinolytic capacity is reduced during pregnancy, this has been disputed. Also the mechanisms underlying any change in fibrinolysis in pregnancy require clarification. We have therefore measured the plasma activity of tissue plasminogen activator (t-PA) and inhibitors (t-PAi) and the concentration of the pregnancy specific inhibitor (PA12) antigen, as well as the euglobulin clot lysis time (ECLT) during normal pregnancy. Plasma concentrations of fibrinogen, plasminogen, fibrin(ogen) degradation products (FDP) and cross-linked products (D-dimer) were also monitored. We confirm a marked reduction of the fibrinolytic activity of the plasma euglobulin fraction from the second trimester, and a parallel reduction in t-PA and increase in t-PAi activities, with rapid return to non-pregnant levels post-partum. In contrast, PAI2, whilst undetectable in non-pregnant control plasma, was already measurable in the first trimester, increased through pregnancy, and remained at a high concentration up to at least 48 h post-partum. Fibrinogen and plasminogen concentrations rose progressively through pregnancy and FDP and D-dimer were frequently detectable in late pregnancy plasma. Changes in the ECLT and plasma t-PA and t-PAi activities in pregnancy cannot therefore be directly related to the concentration of PAI2 antigen. Also, despite the apparent marked reduction in fibrinolytic capacity fibrin(ogen) breakdown products are frequently present in increased plasma concentrations in late pregnancy.