The fibrinolytic system in children

The fibrinolytic system comprises a cascade of serine proteinase activation events that culminate in the generation of plasmin and, subsequently, degradation of fibrin. Although all components of the fibrinolytic system are present at birth, plasma concentrations of key components in infants and children differ physiologically from those in adults. Until the age of 6 months, plasma concentrations of plasminogen and alpha (2)-antiplasmin are decreased to 50% and 80% of adult values, respectively, while plasma concentrations of tissue-type plasminogen activator are decreased and plasminogen activator inhibitor-1 are increased throughout childhood. In addition, the rate of plasmin generation in newborns and the overall fibrinolytic activity during childhood are decreased compared with adults. Strong evidence suggests that age-dependent differences in the fibrinolytic system critically influence the effectiveness and safety of thrombolytic agents. In addition, recent studies suggest that impaired fibrinolysis may play an important role in the pathogenesis of several diseases such as venous and arterial diseases and vasculitis, which are associated with both endothelial cell damage and increased thrombotic risk. This article will discuss the ontogenic features of the fibrinolytic system in children and summarize the available information on the effect of developmental fibrinolysis on both the course of specific disease states and the response to thrombolytic therapy in children.     

Platelet-dependent thrombin generation after in vitro fibrinolytic treatment.

BACKGROUND. Fibrinolytic therapy is associated with frequent rethrombosis. There is evidence of both increased coagulation and platelet activation. METHODS AND RESULTS. Platelet-rich plasma (PRP) or washed platelets were incubated with the fibrinolytic agents urokinase, recombinant tissue-type plasminogen activator (rt-PA), or plasmin at concentrations consistent with those in the plasma of patients treated for myocardial infarction. All of the fibrinolytic agents induced a more rapid generation of thrombin and decreased the clotting times of non-contact-activated PRP than in untreated PRP. This effect was not blocked by the inclusion of thrombin inhibitors during the fibrinolytic treatment. Washed platelets derived from rt-PA-treated PRP induced more rapid thrombin generation when resuspended in untreated plasma or treated plasma. Washed platelets were treated with plasmin, rt-PA, and urokinase and added to platelet-poor plasma. Platelets treated with either plasmin or rt-PA increased the ability of washed platelets to support thrombin generation, but urokinase was without significant effect. CONCLUSIONS. These results indicate not only that plasmin can cause increased platelet support of prothrombin activation but also that rt-PA in the absence of plasminogen can have a direct effect on the platelet, which increases thrombin generation.     

Mini-plasminogen: a mechanism for leukocyte modulation of plasminogen activation by urokinase

Urokinase activation of blood fibrinolysis involves polymorphonuclear leukocytes. To determine if a leukocyte proteinase can modulate plasminogen activation, plasminogen was digested with leukocyte elastase. A major product was a small, approximately 34,000 dalton fragment (mini-plasminogen), without lysine-binding function, but with fibrin-binding activity. After urokinase activation, the resulting mini- plasmin had amidolytic activity for a tripeptide plasmin substrate and fibrinolytic activity. By 125I-fibrin assay, activities of mini-plasmin and plasmin (12 nmole/liter) were 38 and 20 ng fibrin lysed/min, respectively. Lysis times of fibrin clots containing urokinase, and mini-plasminogen or plasminogen (800 nmole/liter), were 282 and 290 sec, respectively. Mini-plasmin and plasmin were inhibited similarly by epsilon-aminocaproic acid and normal plasma, but differed in responses to gel filtration fractions of plasma containing alpha 2-antiplasmin and alpha 2-macroglobulin, the primary and secondary plasmin inhibitors. With purified inhibitors, mini-plasmin required higher concentrations of, or longer preincubation with, alpha 2-antiplasmin, and lower concentrations of, or shorter preincubation with, alpha 2- macroglobulin, to produce inhibition equivalent to that observed with plasmin. Leukocyte elastase digests plasminogen to generate a mini- plasminogen which, when activated by urokinase, has a novel pattern of response to the major plasmin inhibitors in plasma.     

Activation of Plasma Prorenin by Plasminogen Activators in Vitro and Increase in Plasma Renin After Stimulation of Fibrinolytic Activity in Vivo

Plasminogen can be activated by intrinsic activators that circulate in plasma in a precursor form, by extrinsic activator originating from tissues or the vessel wall and by the exogenous activators, urokinase and streptokinase. Tissue activator and vascular activator are probably identical. Dialysis of plasma against pH 4.0 buffer causes denaturation of the plasmin inhibitors, α₂-antiplasmin and C1-inhibitor, while α₂-macroglobulin is left intact. Incubation of pH 4.0-pretreated plasma with urokinase or streptokinase at pH 7.5 led to activation of plasminogen and prorenin. Incubation of a plasma fraction, which contained plasminogen and prorenin but no α₂-antiplasmin and renin, with highly purified tissue plasminogen activator also led to activation of prorenin. The vasopressin analogue, 1-des-amino-8-D-arginine vasopressin (DDAVP), is a potent stimulant for the release of extrinsic activator into the bloodstream. After infusion of DDAVP, 0.4 μg/kg, into normal subjects, parallel increments in plasma fibrinolytic activity and renin were observed. Infusion of DDAVP into patients with type IV hyperlipoproteinaemia had little effect on plasma fibrinolytic activity and the response of plasma renin was also subnormal. These observations warrant further studies on a possible role for plasminogen activators in prorenin activation in vivo.     

Inhibition of vascular endothelial cell prostacyclin synthesis by plasmin

Vascular endothelial cells (EC) play an active role in the synthesis and assembly of components of the fibrinolytic system and the generation of the major fibrinolytic protease plasmin. However, the reciprocal effects of plasmin on EC function have not been previously examined. We have studied the actions of plasmin on the production of prostacyclin (PGI2) by cultured human umbilical vein (HUVEC) and bovine aortic (BAEC) endothelial cells. Plasmin causes little or no direct stimulation of PGI2 formation by EC. Preincubation of EC with plasmin, however, produces a time- and concentration-dependent inhibition of ionophore A23187-, thrombin-, and histamine-induced PGI2 synthesis; a smaller inhibitory effect on arachidonate- and PGH2-induced PGI2 synthesis is found. Incubation of HUVEC or BAEC with a physiologic concentration of plasminogen (180 micrograms/mL) and recombinant tissue plasminogen activator (tPA) generates tPA dose-dependent plasmin activity that exceeds that generated in the absence of EC. In the presence of plasminogen, tPA also causes a tPA dose-dependent inhibition of thrombin- and ionophore A23187-stimulated PGI2 production. PGI2 inhibitory plasmin activity is generated within the concentration range of tPA achieved in plasma during pharmacologic therapy with tPA. These findings suggest that vascular endothelial cells not only regulate activation of the fibrinolytic system but may also be targets of plasmin action on PGI2 synthesis in the modulation of hemostasis and thrombosis.     

The fibrinolytic system in man

The fibrinolytic system comprises a proenzyme, plasminogen, which can be activated to the active enzyme plasmin, that will degrade fibrin by different types of plasminogen activators. Inhibition of fibrinolysis may occur at the level of plasmin or at the level of the activators. Fibrinolysis in human blood seems to be regulated by specific molecular interactions between these components. In plasma, normally no systemic plasminogen activation occurs. When fibrin is formed, small amounts of plasminogen activator and plasminogen adsorb to the fibrin, and plasmin is generated in situ. The formed plasmin, which remains transiently complexed to fibrin, is only slowly inactivated by alpha 2-antiplasmin, while plasmin, which is released from digested fibrin, is rapidly and irreversibly neutralized. The fibrinolytic process, thus, seems to be triggered by and confined to fibrin. Thrombus formation may occur as the result of insufficient activation of the fibrinolytic system and (or) the presence of excess inhibitors, while excessive activation and/or deficiency of inhibitors might cause excessive plasmin formation and a bleeding tendency. Evidence obtained in animal models suggests that tissue-type plasminogen activator, obtained by recombinant DNA technology, may constitute a specific clot-selective thrombolytic agent with higher specific activity and fewer side effects than those currently in use.     

Hemostatic and fibrinolytic effects of systemic prostaglandin E1 therapy in patients with peripheral arterial disease

BACKGROUND: The study was designed to evaluate if there is any evidence of a hyperfibrinolytic bleeding-risk under systemic treatment with prostaglandin E1 (PGE1) of patients with peripheral arterial disease (PAD). PATIENTS AND METHODS: The in vivo effect of PGE1 on the fibrinolytic and hemostatic process was tested on 15 patients before and after treatment with Alprostadil for 21 days using D-dimers (DD), fibrinogen, prothrombin time (PT), partial thromboplastin time (PTT), antithrombin (AT), ProC-Global, plasminogen, plasminogen activator inhibitor activity (PAI), alpha 2-antiplasmin, coagulation factor XII, basal and activated fibrinolytic capacity (fib. cap.). RESULTS: There was no significant difference in DD, fibrinogen, PT, PTT, AT, ProC-Global, plasminogen, PAI, alpha 2-antiplasmin, coagulation factor XII, basal and activated fibrinolytic capacity observed after the treatment. CONCLUSION: Summarizing this study there is no hyperfibrinolytic bleeding-risk after the systemic therapy with Alprostadil to be expected.     

Anticoagulant and fibrinolytic activities are promoted, not retarded, in vivo after thrombin generation in the presence of a monoclonal antibody that inhibits activation of protein C.

This study examines the assumption that both the anticoagulant and fibrinolytic activity that follow the generation of thrombin induced by infusion of factor Xa/PCPS are due to generation of activated protein C. Untreated controls or animals given unrelated antibody were compared with animals pretreated with a specific monoclonal antibody to protein C (HPC4). Compared with untreated controls excess HPC4 substantially reduced the level of protein C activation as observed by protein C immunoblotting and enzyme-linked immunosorbent assay for antitrypsin/activated protein C complexes. Despite this, the anticoagulant activity as reflected by the decline of factors Va and VIIIa levels (as observed by coagulation assays and by factor V immunoblotting) was significantly greater than controls. The fibrinolytic activity (as observed by assays of tissue plasminogen activator, D-Dimer, alpha 2-antiplasmin) also was significantly greater than controls. We conclude that neutralization of the protein C anticoagulant system while resulting in a significantly more intense coagulant response to Xa/PCPS does not preclude inactivation of factors Va and VIIIa and the full expression of the fibrinolytic response. We conclude further that after thrombin generation in vivo, protein C activation is not a prerequisite for the promotion of the fibrinolytic response previously observed, and that the inactivation of factors Va/VIIIa may be mediated by enzymes other than activated protein C. The reduction in alpha 2-antiplasmin levels in association with increased tissue plasminogen activator activity suggests that plasmin is a likely candidate.     

Leukocyte- and endothelial-derived microparticles: a circulating source for fibrinolysis

Background

We recently assigned a new fibrinolytic function to cell-derived microparticles in vitro. In this study we explored the relevance of this novel property of microparticles to the in vivo situation.

Design and Methods

Circulating microparticles were isolated from the plasma of patients with thrombotic thrombocytopenic purpura or cardiovascular disease and from healthy subjects. Microparticles were also obtained from purified human blood cell subpopulations. The plasminogen activators on microparticles were identified by flow cytometry and enzyme-linked immunosorbent assays; their capacity to generate plasmin was quantified with a chromogenic assay and their fibrinolytic activity was determined by zymography.

Results

Circulating microparticles isolated from patients generate a range of plasmin activity at their surface. This property was related to a variable content of urokinase-type plasminogen activator and/or tissue plasminogen activator. Using distinct microparticle subpopulations, we demonstrated that plasmin is generated on endothelial and leukocyte microparticles, but not on microparticles of platelet or erythrocyte origin. Leukocyte-derived microparticles bear urokinase-type plasminogen activator and its receptor whereas endothelial microparticles carry tissue plasminogen activator and tissue plasminogen activator/inhibitor complexes.

Conclusions

Endothelial and leukocyte microparticles, bearing respectively tissue plasminogen activator or urokinase-type plasminogen activator, support a part of the fibrinolytic activity in the circulation which is modulated in pathological settings. Awareness of this blood-borne fibrinolytic activity conveyed by microparticles provides a more comprehensive view of the role of microparticles in the hemostatic equilibrium.Key words: fibrinolytic microparticles, plasmin, plasminogen, uPA, tPA     

The fibrinogen Aalpha R16C mutation results in fibrinolytic resistance

The fibrinogen Aalpha R16C mutation is a common cause of dysfibrinogenaemia and has been previously associated with both bleeding and thrombosis. However, the mechanism underlying the thrombotic phenotype has not yet been elucidated. This report characterises the defect in fibrinolysis seen as a result of the Aalpha R16C mutation. A young patient with dysfibrinogenaemia (fibrinogen Hershey III) was found to be heterozygous for the Aalpha R16C mutation. Functional assays were performed on the purified fibrinogen to characterise clot formation and lysis with plasmin and trypsin. Consistent with previous results, clot formation was diminished. Unexpectedly, fibrinolysis was also delayed. Plasminogen activation was normal, ruling out decreased plasmin generation as the mechanism behind the fibrinolytic resistance. Western blot analysis showed no difference in the amount of bound alpha2-antiplasmin or albumin. When clot lysis was assayed with trypsin substituted for plasminogen, a significant delay was also observed, indicating that defective binding to plasminogen could not explain the fibrinolytic resistance. These results suggest that the defective fibrinolysis is due to increased proteolytic resistance, most likely reflecting changes in clot structure.     

Effects of porcine plasmin on the coagulation and fibrinolytic systems in humans.

Pig plasmin (Lysofibrin) was given to 11 patients with phlebographically verified venous thrombosis, 2 of whom were treated two and three times, respectively. The effect on coagulation and fibrinolytic parameters was studied. The platelet count, Owren's P&P (prothrombin plus factors VII and X), plasminogen, factor XIII, and antithrombin III did not change during the treatment. All patients developed a proteolytic activity demonstrable on both unheated and heated fibrin plates. The fibrinogen decreased successively to very low levels, and parallel to this an increase in fibrin/fibrinogen degradation products was found. The factor VIII and factor V activities decreased immediately after each Lysofibrin infusion but normalized rapidly again. The factor VIII molecule, however, retained its reactivity to rabbit antiserum against factor VIII. Immediately after the plasmin infusion a decrease of both alpha2-macroglobulin (alpha2-M) and the rapidly reacting alpha2-antiplasmin was observed. alpha2-M decreased successively and in several of the patients values were unmeasurable for a period of some days. A complex formation between pig plasmin and the alpha2-antiplasmin was demonstrated in crossed immunoelectrophoresis. The complexes were rapidly cleared from the circulation. No interaction between the pig plasmin and the inhibitor of the plasminogen activation, alpha1-antitrypsin or inter-alpha-inhibitor, was found.     

Abnormalities of pathways of fibrin turnover in the human pleural space

The potential importance of pleural fibrin deposition in the pathogenesis of pleural injury is supported by both clinical and experimental observations. We hypothesized that the local equilibrium between procoagulant and fibrinolytic activities is disrupted to favor fibrin deposition in exudative pleuritis. To test this hypothesis, we characterized procoagulant and fibrinolytic activities in pleural exudates from patients with pneumonia, lung cancer, or empyema and transudates from patients with congestive heart failure. Procoagulant activity was generally increased in exudative processes and was due mainly to tissue factor. All effusions contained antithrombin III and inhibited factor Xa and thrombin, but endogenous prothrombinase or thrombin activities were variably detected. Pleural fluid fibrinolytic activity was increased in congestive heart failure and was due to both tissue plasminogen activator and urokinase. Depressed fibrinolytic activity was found in pleural exudates despite increased concentrations of plasminogen, mainly glu-1-plasminogen, and was due to inhibition of plasminogen activation by plasminogen activator inhibitors 1 and 2 and of plasmin, in part by alpha 2-antiplasmin. Concentrations of PAI-1 in exudative pleural fluids were increased up to 913-fold, compared with normal pooled plasma. Exudative pleural effusions are characterized by increased procoagulant and depressed fibrinolytic activity, favoring fibrin deposition in the pleural space. The balance of these activities is reversed and favors fibrin clearance in congestive heart failure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Streptokinase-producing streptococci grown in human plasma acquire unregulated cell-associated plasmin activity.

Group A streptococci grown in the presence of human plasma generated plasmin from plasminogen and captured the functional enzyme to a specific cell-surface receptor. Bacteria-bound plasmin was not regulated by alpha 2-antiplasmin present in the medium. The ability of the bacteria to acquire cell-associated plasmin activity was dependent on both the presence of plasminogen in the culture medium and the production of a bacterial plasminogen activator, streptokinase. The ability of group A streptococci to produce a plasminogen activator and capture resulting plasmin in an unregulatable form could provide the organism with a mechanism for invasion of normal tissue barriers.     

Effects of streptokinase and recombinant tissue plasminogen activator on platelet aggregation in whole blood

Streptokinase (SK) frequently induced platelet aggregation when added to citrated whole blood in vitro, but aggregation did not occur in corresponding samples of platelet-rich plasma (PRP). The aggregation occurred at concentrations of SK that are achieved after systemic infusion and was significantly more extensive in blood from men than women. SK-induced aggregation was accompanied by TXB(2) formation and release of (14)C-5HT and was inhibited by aspirin, by sulotroban, a TXA(2) antagonist, and by apyrase, an enzyme which removed ADP from plasma. Aggregation was also inhibited by each of three agents that interrupt the fibrinolytic pathway: epsilon-aminocaproic acid (ACA), aprotinin and alpha-2-antiplasmin. It is suggested that the aggregation is consequent to platelet activation by plasmin formed on the platelet surface, with ADP from red cells playing a part. In contrast to results obtained in vitro, prior administration of SK to man resulted in inhibition of the aggregation that occurs when this agent is added to whole blood. This effect was reproduced in vitro by pre-incubating blood with SK prior to carrying out aggregation studies. Similar inhibition was obtained when plasmin was added to blood and it is suggested that this effect of SK may be mediated by plasmin formed in plasma. In contrast to the pro-aggregatory effects of SK in vitro, recombinant tissue plasminogen activator (rt-PA) only inhibited platelet aggregation in whole blood. rt-PA inhibited the aggregation induced by a wide range of agents suggesting a central mechanism of action. Inhibition of aggregation was prevented by ACA, suggesting that this is also mediated by plasmin formed in plasma. The relevance of these observations is discussed in relation to the increasing use of fibrinolytic therapy in acute thrombosis in man. It is suggested that slow infusion of SK should always be performed so as to maximise the inhibitory rather than potentiatory effect of this agent on platelet aggregation, and that SK should only be used after prior administration of an anti-platelet agent.     

The effect of exercise on thrombin and plasmin generation in middle-aged men

Plasma levels of B beta 15-42 peptide and fibrinopeptide A (FPA) were measured as indicators of plasmin-mediated fibrin(ogen)olysis and thrombin activity of fibrinogen in 34 middle-aged men, at rest and following a standard exercise test. In the group as a whole no significant changes in B beta 15-42 or FPA were noted after exercise. When the group was subdivided into men with (n = 20) and without (controls n = 14) coronary heart disease, exercise-stimulated thrombin and plasmin generation was found only in the control group who exercised for a significantly longer duration. The rise in B beta 15-42 was related to both the intensity and duration of exercise. Similar increases in plasma fibrinolytic activity (fibrin plate) occurred in both groups and no other differences in the components of the fibrinolytic system (plasminogen, alpha 2-antiplasmin, fibrin degradation product) were noted either after exercise or between the groups. Exercise in normal middle-aged men is associated with modest thrombin and plasmin activation.     

Inactivation of purified human alpha 2-antiplasmin and purified human C1 inhibitor by synthetic fibrinolytic agents

3-Hydroxypropyl flufenamide (Flu-HPA) is one of a series of flufenamic acid derivatives that enhances blood clot lysis in vitro. Studies of possible mechanisms of action of Flu-HPA were undertaken. The profibrinolytic activity of Flu-HPA in clot lysis assays was found to be dependent on plasminogen. The influence of Flu-HPA on the ability of purified alpha 2-antiplasmin to inhibit purified plasmin was studied. Plasmin activity was determined using 125I-fibrin plates or the spectrophotometric tripeptide substrate, Val-Leu-Lys-paranitroanilide. At Flu-HPA concentrations greater than 1 mM, the inhibitory activity of alpha 2-antiplasmin was abolished in a time-dependent and concentration- dependent manner. The influence of Flu-HPA on the ability of purified Cl inhibitor to inhibit purified plasma kallikrein and beta-Factor XIIa was also studied. Cl inhibitor activity was abolished by Flu-HPA at concentrations greater than 2 mM. Notably, Flu-HPA up to 60 mM did not affect the amidolytic activities of plasmin, kallikrein, or beta-Factor XIIa. Flu-HPA did not release enzyme activity from preformed complexes of either alpha 2-antiplasmin and plasmin of Cl inhibitor and kallikrein. A water-soluble derivative of flufenamic acid, N-flufenamyl- glutamic acid, also inactivated alpha 2-antiplasm and Cl inhibitor. This inactivation was shown to be reversible. These results indicate that synthetic fibrinolytic compounds such as flufenamic acid derivatives may promote fibrinolysis by directly inactivating alpha 2- antiplasmin and Cl inhibitor.     

Inhibition of cell surface mediated plasminogen activation by a monoclonal antibody against alpha-Enolase

Localization of plasmin activity on leukocyte surfaces plays a critical role in fibrinolysis as well as in pathological and physiological processes in which cells must degrade the extracellular matrix in order to migrate. The binding of plasminogen to leukocytic cell lines induces a 30- to 80-fold increase in the rate of plasminogen activation by tissue-type (tPA) and urokinase-type (uPA) plasminogen activators. In the present study we have examined the role of alpha-enolase in plasminogen activation on the cell surface. We produced and characterized a monoclonal antibody (MAb) 11G1 against purified alpha-enolase, which abrogated about 90% of cell-dependent plasminogen activation by either uPA or tPA on leukocytoid cell lines of different lineages: B-lymphocytic, T-lymphocytic, granulocytic, and monocytic cells. In addition, MAb 11G1 also blocked enhancement of plasmin formation by peripheral blood neutrophils and monocytes. In contrast, MAb 11G1 did not affect plasmin generation in the presence of fibrin, indicating that this antibody did not interact with fibrinolytic components in the absence of cells. These data suggest that, although leukocytic cells display several molecules that bind plasminogen, alpha-enolase is responsible for the majority of the promotion of plasminogen activation on the surfaces of leukocytic cells.     

Plasmin inhibitors in the prevention of systemic effects during thrombolytic therapy: specific role of the plasminogen-binding form of alpha 2-antiplasmin.

To delineate the role of plasmin inhibitors, especially the two molecular forms of alpha 2-antiplasmin (that is, the plasminogen-binding and the nonplasminogen-binding forms), in the control of systemic effects during thrombolytic therapy, the consumption of plasmin inhibitors and the degree of fibrinogen breakdown were studied in 35 patients with acute myocardial infarction treated with recombinant tissue-type plasminogen activator (rt-PA) or streptokinase. At a low degree of plasminogen activation (in six patients treated with rt-PA), plasminogen-binding alpha 2-antiplasmin was consumed first. At a higher degree of plasminogen activation (in 20 patients), plasminogen-binding alpha 2-antiplasmin became exhausted (less than 20%) and other plasmin inhibitors (that is, nonplasminogen-binding alpha 2-antiplasmin and alpha 2-macroglobulin) were consumed. After extensive plasminogen activation (in nine patients treated with streptokinase), plasminogen-binding alpha 2-antiplasmin consumption was complete and nonplasminogen-binding alpha 2-antiplasmin and alpha 2-macroglobulin were consumed to about 30% to 50% of the pretreatment level. No significant C1-inactivator consumption occurred, even at extreme degrees of plasminogen activation. Fibrinogen breakdown as a marker for systemic effects correlated strongly with consumption of plasminogen-binding alpha 2-antiplasmin. Fibrinogen breakdown did occur, but only when the amount of plasminogen-binding alpha 2-antiplasmin was decreased to less than 20% of the pretreatment level. The other plasmin inhibitors could not prevent fibrinogen breakdown. These results were confirmed by in vitro studies. It is concluded that plasminogen-binding alpha 2-antiplasmin is the most important inhibitor of plasmin in the circulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of Streptokinase and Recombinant Tissue Plasminogen Activator on Platelet Aggregation in Whole Blood

Streptokinase (SK) frequently induced platelet aggregation when added to citrated whole blood in vitro, but aggregation did not occur in corresponding samples of platelet-rich plasma (PRP). The aggregation occurred at concentrations of SK that are achieved after systemic infusion and was significantly more extensive in blood from men than women. SK-induced aggregation was accompanied by TXB₂ formation and release of ¹⁴C-5HT and was inhibited by aspirin, by sulotroban, a TXA₂ antagonist, and by apyrase, an enzyme which removed ADP from plasma. Aggregation was also inhibited by each of three agents that interrupt the fibrinolytic pathway: epsilon-aminocaproic acid (ACA), aprotinin and alpha-2-antiplasmin. It is suggested that the aggregation is consequent to platelet activation by plasmin formed on the platelet surface, with ADP from red cells playing a part.

In contrast to results obtained in vitro, prior administration of SK to man resulted in inhibition of the aggregation that occurs when this agent is added to whole blood. This effect was reproduced in vitro by pre-incubating blood with SK prior to carrying out aggregation studies. Similar inhibition was obtained when plasmin was added to blood and it is suggested that this effect of SK may be mediated by plasmin formed in plasma.

In contrast to the pro-aggregatory effects of SK in vitro, recombinant tissue plasminogen activator (rt-PA) only inhibited platelet aggregation in whole blood. rt-PA inhibited the aggregation induced by a wide range of agents suggesting a central mechanism of action. Inhibition of aggregation was prevented by ACA, suggesting that this is also mediated by plasmin formed in plasma.

The relevance of these observations is discussed in relation to the increasing use of fibrinolytic therapy in acute thrombosis in man. It is suggested that slow infusion of SK should always be performed so as to maximise the inhibitory rather than potentiatory effect of this agent on platelet aggregation, and that SK should only be used after prior administration of an anti-platelet agent.     

Annexin II: a mediator of the plasmin/plasminogen activator system

The annexins constitute a family of calcium-dependent membrane binding proteins. Recently, annexin II has been shown to accelerate the activation of the clot-dissolving protease plasmin by complexing with the plasmin precursor plasminogen and with tissue plasminogen activator. Binding of plasminogen to annexin II is inhibited by the atherogenic lipoprotein, lipoprotein(a), while binding of tissue plasminogen activator to annexin II is blocked by the thiol amino acid homocysteine. Formation of the plasminogen/tissue plasminogen activator/annexin II complex may represent a key regulatory mechanism in fibrinolytic surveillance.