Mechanism of protein C-dependent clot lysis: role of plasminogen activator inhibitor

The mechanism by which activated protein C stimulates fibrinolysis was studied in a simple radiolabeled clot lysis assay system containing purified tissue-type plasminogen activator, bovine endothelial plasminogen activator inhibitor (PAI), plasminogen, 125I-fibrinogen and thrombin. Fibrinolysis was greatly enhanced by the addition of purified bovine activated protein C; however, in the absence of PAI, activated protein C did not stimulate clot lysis, thus implicating this inhibitor in the mechanism. In clot lysis assay systems containing washed human platelets as a source of PAI, bovine-activated protein C-dependent fibrinolysis was associated with a marked decrease in PAI activity as detected using reverse fibrin autography. Bovine-activated protein C also decreased PAI activity of whole blood and of serum. In contrast to the bovine molecule, human-activated protein C was much less profibrinolytic in these clot lysis assay systems and much less potent in causing the neutralization of PAI. This species specificity of activated protein C in clot lysis assays reflect the known in vivo profibrinolytic species specificity. When purified bovine-activated protein C was mixed with purified PAI, complex formation was demonstrated using immunoblotting techniques after polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. These observations suggest that a major mechanism for bovine protein C- dependent fibrinolysis in in vitro clot lysis assays involves a direct neutralization of PAI by activated protein C.     

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.     

High dose factor VIIa improves clot structure and stability in a model of haemophilia B

Factor IX (FIX) deficiency results in haemophilia B and high dose recombinant activated factor VII (rFVIIa) can decrease bleeding. Previously, we showed that FIX deficiency results in a reduced rate and peak of thrombin generation. We have now used plasma and an in vitro coagulation model to examine the effect of these changes in thrombin generation on fibrin clot structure and stability. Low FIX delayed the clot formation onset and reduced the fibrin polymerisation rate. Clots formed without FIX were composed of thicker fibrin fibres than normal. rFVIIa shortened the clot formation onset time and improved the fibre structure of haemophilic clots. We also examined clot formation in the presence of a fibrinolytic challenge by including tissue plasminogen activator or plasmin in the reaction milieu. In these assays, normal FIX levels supported clot formation; however, clots did not form in the absence of FIX. rFVIIa partially restored haemophilic clot formation. These results were independent of the effects of the thrombin-activatable fibrinolysis inhibitor. Our data suggest that rFVIIa enhances haemostasis in haemophiliacs by increasing the thrombin generation rate to both promote formation of a structurally normal clot and improve clot formation and stability at sites with high endogenous fibrinolytic activities.     

Secretion of plasminogen activator inhibitor by normal rat pleural leukocytes in culture

The normal balance between coagulation and fibrinolysis in the pleural cavity is poorly understood despite the critical role of the pleura in the movement of the lungs. To determine the fibrinolytic activity and the interaction between plasminogen activators and their inhibitors in the normal pleural space, we tested normal rat pleural leukocytes, principally macrophages and mast cells, and their supernatants, for activity in an [¹²⁵I]fibrin degradation assay. It was found that pleural leukocytes did not release plasminogen activator, but the leukocytes and their supernatants inhibited the plasminogen-dependent fibrinolysis caused by both alveolar leukocytes and mesothelial cells. Further experiments demonstrated that pleural leukocytes produce a protein inhibitor primarily against urokinase-induced fibrinolysis in culture and that macrophages are the main source of the inhibitor. The lysate of mast cell-enriched population exhibited high plasminogen activator activity while no such activity could be determined in macrophage-enriched lysate. These data show that normal rat pleural leukocytes contain plasminogen activator inside the cells and synthesize a urokinase-type plasminogen activator inhibitor in culture that may be important in the fibrinolysis/coagulation balance in the pleural space.     

Secretion of plasminogen activator inhibitor by normal rat pleural leukocytes in culture

The normal balance between coagulation and fibrinolysis in the pleural cavity is poorly understood despite the critical role of the pleura in the movement of the lungs. To determine the fibrinolytic activity and the interaction between plasminogen activators and their inhibitors in the normal pleural space, we tested normal rat pleural leukocytes, principally macrophages and mast cells, and their supernatants, for activity in an [125I]fibrin degradation assay. It was found that pleural leukocytes did not release plasminogen activator, but the leukocytes and their supernatants inhibited the plasminogen-dependent fibrinolysis caused by both alveolar leukocytes and mesothelial cells. Further experiments demonstrated that pleural leukocytes produce a protein inhibitor primarily against urokinase-induced fibrinolysis in culture and that macrophages are the main source of the inhibitor. The lysate of mast cell-enriched population exhibited high plasminogen activator activity while no such activity could be determined in macrophage-enriched lysate. These data show that normal rat pleural leukocytes contain plasminogen activator inside the cells and synthesize a urokinase-type plasminogen activator inhibitor in culture that may be important in the fibrinolysis/coagulation balance in the pleural space.     

Enhancement of fibrinolytic potential in vitro by anticoagulant drugs targeting activated factor X, but not by those inhibiting thrombin or tissue factor.

Tissue factor-induced coagulation leads to the generation of a small amount of thrombin, resulting in the formation of a fibrin clot. After clot formation, thrombin generation continues resulting in the activation of thrombin activatable fibrinolysis inhibitor, leading to downregulation of fibrinolysis. In this study, the effect of anticoagulant drugs targeting different steps in the coagulation cascade on clot formation and subsequent breakdown was investigated using a plasma-based clot lysis assay. All drugs tested significantly delayed clot formation; only those drugs targeting activated factor X (FXa) (tissue factor pathway inhibitor, fondaparinux, and low molecular weight heparin) accelerated fibrinolysis. Anticoagulant drugs targeting tissue factor (active site-inactivated recombinant activated factor VII) or thrombin (hirudin and d-phenylalanyl-l-prolyl-l-arginyl chloromethyl ketone) did not affect clot lysis time. In accordance with these findings, it was shown that total thrombin generation, as quantified by the endogenous thrombin potential, was only affected by anticoagulant drugs targeting FXa when all drugs were used in a concentration resulting in doubling of clotting time. Induction of hyperfibrinolysis by anticoagulant drugs directed against FXa might be beneficial as increased clot breakdown might facilitate thrombolysis or prevent re-occlusion. On the other hand, the induction of hyperfibrinolysis by these compounds might increase the risk of bleeding complications.     

Pharmacological manipulation of gastric juice: thrombelastographic assessment and implications for treatment of gastrointestinal haemorrhage.

The impairment of formation and maintenance of a formed fibrin clot contributes to the prolonged bleeding and high incidence of rebleeding in upper gastrointestinal haemorrhage. To investigate the basis for the use of drug therapy in gastric bleeding, this study used thrombelastography to determine the effects of pharmacological manipulation of gastric juice on coagulation and fibrinolysis. The thrombelastograph is a mechanical device that provides a visual assessment of all stages of coagulation and fibrinolysis. The effects of fresh and pharmacologically changed gastric juice was assessed after its addition to fresh whole blood in the thrombelastograph cuvette. Pharmacological manipulation was achieved through alkalisation or through addition of tranexamic acid, aprotinin, or sucralfate. Fresh gastric juice delayed clot formation, decreased maximum clot amplitude, and stimulated clot lysis. Alkalisation inhibited the lytic effects of fresh gastric juice and improved the induced abnormalities in coagulation. Tranexamic acid partially inhibited gastric juice induced clot lysis but did not exhibit a beneficial effect on coagulation. Sucralfate, and to a lesser extent aprotinin significantly inhibited fibrinolysis but exacerbated the detrimental effect of gastric juice on the parameters of coagulation. Alkalisation of gastric juice reduces the adverse effect on coagulation and fibrinolysis. Tranexamic acid, aprotinin, and sucralfate can all reduce or inhibit clot lysis, but the adverse effects on clot formation may outweigh any potential benefit in the treatment of gastrointestinal bleeding.     

Acceleration of fibrinolysis by the N-terminal peptide of alpha 2- plasmin inhibitor

When blood plasma containing the NH2-terminal 12-residue peptide (N- peptide) of alpha 2-plasmin inhibitor (alpha 2PI; alpha 2-antiplasmin) was clotted in the presence of calcium ions, the N-peptide and alpha 2PI were cross-linked to fibrin by activated coagulation factor XIII. The amount of N-peptide cross-linked to fibrin was proportional to the concentration of N-peptide present in plasma. On the other hand, the amount of alpha 2PI cross-linked to fibrin was decreased by the presence of N-peptide, and the decrease was in reverse relationship to the increase of cross-linking of N-peptide. Spontaneous fibrinolysis or fibrinolysis induced by tissue plasminogen activator was accelerated by the presence of N-peptide, and the acceleration was dependent on the concentrations of N-peptide and directly proportional to inhibition of alpha 2PI cross-linking exerted by N-peptide. The acceleration was more pronounced when the clot was compacted by platelet-mediated clot retraction or by a squeeze. Fibrinolysis of an alpha 2PI-deficient or a factor XIII-deficient plasma clot was not accelerated by N-peptide. These findings were substantiated in a purified system and support the previous proposal that alpha 2PI is cross-linked to fibrin at the glutamine residue that is next to the NH2-terminus of alpha 2PI, and this factor XIII-mediated cross-linking of alpha 2PI is significant in inhibition of physiologically occurring endogenous fibrinolysis.     

Feedback activation of factor XI by thrombin in plasma results in additional formation of thrombin that protects fibrin clots from fibrinolysis

Recently, an alternative pathway for factor XI activation has been described in which factor XI is activated by thrombin. Patients with a factor XI deficiency bleed mostly from tissues with high local fibrinolytic activity. Therefore, the role of thrombin-mediated factor XI activation in both fibrin formation and fibrinolysis was studied in a plasma system. Clotting was induced by the addition of tissue factor or thrombin to recalcified plasma in the presence or absence of tissue- type plasminogen activator, after which clot formation and lysis were measured using turbidimetry. Thrombin-mediated activation of factor XI was found to take place in plasma under physiologic conditions in the absence of a dextran sulfate-like cofactor. At high tissue factor concentrations, no effect of factor XI was seen on the rate of fibrin formation. Decreasing amounts of tissue factor resulted in a gradually increasing contribution of factor XI to the rate of fibrin formation. In addition, thrombin-mediated factor XI activation resulted in an inhibition of tissue-type plasminogen activator-induced lysis of the clot. This inhibition occurred even at tissue factor concentrations at which no effect of factor XI was observed on fibrin formation. Trace amounts of activated factor XI (1.25 pmol/L, representing 0.01% activation) were capable of completely inhibiting fibrinolysis in our system. The inhibitory effect was found to be mediated by thrombin that is additionally generated in a factor XI-dependent manner via the intrinsic pathway and is capable of protecting the clot against lysis. We also observed that formation of additional thrombin continued after the clot had been formed. We conclude that thrombin-mediated factor XI activation can take place in plasma. The presence of factor XI during coagulation results in the formation of additional thrombin within the clot capable of protecting this clot from fibrinolytic attack. The large amounts of thrombin that are formed by the intrinsic pathway via factor XI may play an important role in the procoagulant and thrombogenic state of clots and may therefore have important clinical and therapeutic implications.     

Evaluation of the overall haemostatic effect of recombinant factor VIIa by measuring thrombin generation and stability of fibrin clots

Summary. It has been reported that thrombin generation test (TGT) may be a useful tool to monitor recombinant factor VIIa (rFVIIa). However, TGT does not reflect the stability of fibrin clot and its resistance to fibrinolysis which are crucial. Using whole‐blood thromboelastography (TEG) and tissue plasminogen activator (tPA), we developed an in‐vitro model to assess fibrin clot stability. Fibrin fibres were thicker in haemophiliacs compared with controls (P < 0.0001). After addition of rFVIIa 90 μg kg^?1, the diameter of fibrin fibres was dramatically decreased (P = 0.006). TEG‐tPA assay showed a dose‐dependent improvement of clot stability in the presence of rFVIIa. These data demonstrate a significant correlation between fibrin clot structure and its stability (P = 0.001). We also showed a correlation between thrombin generating capacity and clot resistance to fibrinolysis. Despite this overall correlation, a relatively large spreading around a general trend was observed, suggesting that the two assays bring complementary information on the haemostatic effect of rFVIIa.     

Biochemical and physiologic principles of tissue-type plasminogen activator

After wound healing the protective fibrin clot is removed by the fibrinolytic system. In addition fibrinolysis is one of the most important counter-reactions of blood coagulation. Fibrinolysis is controlled by activation and inhibition processes. Tissue type plasminogen activator (t-PA) and Pro-urokinase (single chain urokinase; scu-PA) hold a key position in physiological plasminogen activation. Plasmin itself is a rather unspecific protease capable of degrading a great variety of proteins besides fibrin. In vivo however--except for certain pathological situations--the fibrinolytic process is restricted to its actual target the fibrin clot. This surprising situation in terms of structure function interrelation is physiologically managed by N-terminal modules in the protein structure of the essential factors providing fibrin affinity. Free plasmin will be immediately inactivated by alpha 2-antiplasmin. Therefore fibrin plays a central role as cofactor in the fibrinolytic system in determining initiation and localization of the fibrinolytic process. Because of the superior properties of t-PA and scu-PA with respect to fibrin specificity both activators must be regarded as the future thrombolytic agents for therapy.     

A novel hemostasis assay for the simultaneous measurement of coagulation and fibrinolysis

Abstract

Thrombin and plasmin are the key enzymes involved in coagulation and fibrinolysis. A novel hemostasis assay (NHA) was developed to measure thrombin and plasmin generation in a single well by a fluorimeter. The NHA uses two fluorescent substrates with non-interfering fluorescent excitation and emission spectra. The assay was tested in vitro using modulators like heparin, hirudin, epsilon-aminocaproic acid, gly-pro-arg-pro peptide and reptilase and validated by measurement of prothrombin fragment 1+2 and plasmin-alpha₂-antiplasmin levels. Intra- and inter-assay coefficients of variation were <9% and 6–25%, respectively. Interplay between coagulation and fibrinolysis was demonstrated by the effect of tissue-type plasminogen activator on thrombin generation and by the different responses of activated protein C and thrombomodulin on fibrinolysis. The last responses showed the linkage between coagulation and fibrinolysis by thrombin activatable fibrinolysis inhibitor. In conclusion, this strategy allows detection of coagulation, fibrinolysis and their interplay in a single assay.     

Reduced activity of TAFI (thrombin-activatable fibrinolysis inhibitor) in acute promyelocytic leukaemia

Acute promyelocytic leukaemia (APL) is a disease that is distinguished from other leukaemias by the high potential for early haemorrhagic death. Several processes are involved, such as disseminated intravascular coagulation and hyperfibrinolysis. Recently, TAFI (thrombin-activatable fibrinolysis inhibitor) was identified as a link between coagulation and fibrinolysis. TAFI can be activated by thrombin, and in its activated form potently attenuates fibrinolysis by removing C-terminal lysine and arginine residues that are important for the binding and activation of plasminogen. Activation of TAFI by the coagulation system results in a down-regulation of fibrinolytic activity and, thereby, prevents a rapid dissolution of the fibrin clot. To establish whether TAFI was involved in the severity of the bleeding complications in APL, the TAFI antigen and activity levels were determined in a group of 15 patients. The TAFI antigen concentration was normal, but the activity of TAFI was severely reduced in APL by approximately 60%. The reduction of TAFI activity was most probably caused by the action of plasmin on TAFI because in vitro experiments revealed that plasmin slightly reduced antigen levels but severely reduced TAFI activity. The acquired functional TAFI deficiency in APL may contribute to the severity of the haemorrhagic diathesis because of the impaired capacity of the coagulation system to protect the fibrin clot from fibrinolysis.     

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.     

Regulation of fibrinolysis by platelet-released plasminogen activator inhibitor 1: light scattering and ultrastructural examination of lysis of a model platelet-fibrin thrombus

We have investigated the role of plasminogen activator inhibitor 1 (PAI- 1) in the regulation of fibrinolysis using a model thrombus composed of thrombin-stimulated platelets, fibrin(ogen), plasminogen, and recombinant tissue-type plasminogen activator. Laser light scattering kinetic measurements showed that clot lysis was significantly delayed both by thrombin-stimulated platelets and their cell-free releasate. This delay in lysis was almost fully reversed by the addition of a PAI- 1-specific monoclonal antibody that blocks the ability of PAI-1 to inhibit plasminogen activators. Lysis half-times exhibited a linear dependence on the concentration of PAI-1 antigen present, as determined by enzyme-linked immunosorbent assay (ELISA). Sodium dodecylsulfate- polyacrylamide gel electrophoresis (SDS-PAGE) followed by immunoblotting confirmed the presence of PAI-1 antigen in the platelet releasates. Scanning electron micrographs of the model thrombus components sampled late in lysis showed considerable unproteolyzed fibrin still attached to platelets. Immunogold cytochemistry detected large amounts of PAI-1 antigen in the partially lysed platelet-fibrin thrombi. This PAI-1 appeared to be bound to the fibrin network rather than to the platelet surface itself. We conclude that the residual clots observed late in lysis represent platelet-associated fibrin to which platelet-released PAI-1 has bound, rendering it less susceptible to degradation.     

The frequent Marburg I polymorphism impairs the pro-urokinase activating potency of the factor VII activating protease (FSAP).

The recently reported plasmatic, Factor Seven Activating Protease (FSAP), has also been found to be a potent activator of pro-urokinase [single-chain plasminogen activator, urinary type (scuPA)]. An initial epidemiological study surprisingly showed that plasmas of 5-10% of healthy blood donors had an impaired potential to activate scuPA. Analysis of the respective genomic DNAs revealed one particular single nucleotide polymorphism of FSAP resulting in an identical amino acid exchange (G511E), which correlates with the reduced activities. The corresponding mutation was named FSAP Marburg I. Thrombelastographies of wild-type and mutant plasmas were performed, facilitating the auto-activation of the intrinsic FSAP pro-enzymes by addition of dextran sulfate (DXS) and accelerated clot lysis by addition of scuPA. On these conditions, tissue-factor-induced coagulation revealed that clot lysis was significantly delayed in the Marburg I mutant plasmas as compared with wild-type plasmas. Furthermore, in the presence of DXS and scuPA, a FSAP-deficient plasma revealed significantly prolonged plasma clot lysis times, whereas the addition of purified FSAP pro-enzyme plus scuPA reversed this effect. These results support the hypothesis that FSAP contributes to the scuPA-dependent plasma fibrinolytic potential, which can be impaired in plasmas containing the FSAP Marburg I polymorphism, for instance.     

Effects of recombinant activated factor VII on thrombin-mediated feedback activation of coagulation

Thrombin is a key hemostatic enzyme, which propagates its own generation by activating factors V, VIII, and XI. Sustained thrombin generation also activates thrombin-activatable fibrinolysis inhibitor (TAFI), which stabilizes fibrin clot against fibrinolysis. Recombinant activated factor VII (rFVIIa) is considered a novel hemostatic intervention for refractory bleeding, but rebleeding episodes related to fibrinolysis still occur. The present study aimed to investigate the antifibrinolytic effects of rFVIIa in relation to thrombin generation. Using thrombelastography, the effects of rFVIIa on thrombin-activated fibrin formation and on fibrinolysis induced by tissue plasminogen activator were evaluated in various factor-deficient plasma samples. A Thrombinoscope was used to quantitate thrombin generation. Thrombin increased antifibrinolytic activity in a concentration-dependent manner as demonstrated by a longer clot lysis time. In plasma deficient in factors V, VIII, IX, X, or XI, clot lysis occurred early (< 20 min), and rFVIIa addition had minimal effect, except for improved antifibrinolytic effect in factor-XI-deficient plasma. A normal clot lysis time was observed in factor-XIII-deficient or dual antithrombin/factor-VIII-deficient plasma. Inhibition of TAFI increased the rate of fibrinolysis. Thrombin generation was delayed or decreased in single factor-deficient plasma except for factor XIII deficiency. After rFVIIa addition, the peak thrombin generation reached over 100 nmol/l in factor-XI-deficient plasma, but not in plasma deficient in factors V, VIII, IX, or X. Thrombin generation and subsequent activation of TAFI were important for clot stability. We conclude that rFVIIa therapy does not compensate for increased susceptibility to fibrinolysis due to lack of factor(s) necessary for the formation of tenase and prothrombinase.     

Plasminogen-independent fibrinolysis by proteases produced by transformed chick embryo fibroblasts.

The fibrinolytic activity of proteases secreted by chick embryo fibroblasts infected with Rous sarcoma virus was studied by use of a procedure in which a fibrin clot was formed with highly purified fibrinogen and thrombin above the cell layer. This procedure results in the formation of fibrin that is apparently a more suitable substrate for studies on fibrinolysis than is fibrin prepared by other methods. Since neither plasminogen nor serum were included in the assay system in the present studies, the fibrinolytic activity observed cannot be ascribed to the conversion of the plasminogen in serum to plasmin by a plasminogen activator produced by transformed cells. Our procedure, therefore, measures proteolytic activities other than those reported by previous investigators. Maintenance of some of the transformed phenotypes of Rous sarcoma virus transformed chick embryo fibroblasts such as morpholigical change and increased rate of glucose uptake apparently does not depend on the presence of plasminogen in the culture medium.     

HYPOFIBRINOGENEMIA DUE TO INCREASED FIBRINOLYSIS IN TWO PATIENTS WITH ACUTE PROMYELOCYTIC LEUKEMIA

Two patients with acute promyelocytic leukemia and severe bleeding associated with hypofibrinogenemia were studied. The markedly shortened whole blood clot lysis time and dilute clot lysis time suggested that the defect was an increase in fibrinolysis. Although disseminated intravascular coagulation could not be totally excluded as an alternative mechanism, excessive fibrinolysis was confirmed as the pathogenic cause by the prompt response to the administration of tranexamic acid. The low circulating plasminogen, α₂ plasmin inhibitor level and the presence of α₂ plasmin inhibitor-protease complex in both patients suggested that the increased fibrinolysis probably resulted from the liberation of plasminogen activator from the promyelocyte.     

The cofactor role of protein S in the acceleration of whole blood clot lysis by activated protein C in vitro

The effect of purified human activated protein C (APC) and protein S on fibrinolysis was studied by using an in vitro blood clot lysis technique. Blood clots were formed from citrated blood (supplemented with 125I-fibrinogen) by adding thrombin and Ca2+-ions; lysis of the clots was achieved by adding tissue-type plasminogen activator. The release of labeled fibrin degradation products from the clots into the supernatant was followed in time. We clearly demonstrated that APC accelerates whole blood clot lysis in vitro. The effect of APC was completely quenched by antiprotein C IgG, pretreatment of APC with diisopropylfluorophosphate, and preincubation of the blood with antiprotein S IgG. This demonstrates that both the active site of APC and the presence of the cofactor, protein S, are essential for the expression of the profibrinolytic properties. At present, the substrate of APC involved in the regulation of fibrinolysis is not yet known. Analysis of the radiolabeled fibrin degradation products demonstrated that APC had no effect on the fibrin cross-linking capacity of factor XIII.