Nicola Semeraro

Cultured human endothelial cells generate tissue factor in response to endotoxin.

Bacterial infection is associated with disseminated intravascular coagulation and fibrin deposition in the microcirculation; the mechanism of these effects in humans is still unclear. We have studied the generation of procoagulant activity (PCA) by cultured human endothelial cells (EC) in response to endotoxin. Cells from umbilical cord veins were grown in Eagles minimum essential medium with 20% fetal calf serum till confluence. Absence of fibroblasts and macrophages was carefully checked. Endotoxin (Salmonella enteritidis lipopolysaccharide (LPS) W or Escherichia coli 0111:B4 LPS W, 0.01-1.0 micrograms/ml) was added to culture dishes for 4-6 h. PCA of EC was measured by a one-stage clotting assay and/or a two-stage amidolytic assay with the chromogenic substrate S-2222. In the absence of endotoxin, EC generated little, if any PCA (2-5 units/10(5) cells). In contrast, the addition of endotoxin resulted in generation of strong PCA that reached a maximum within 4-6 h (185-241 units/10(5) cells) and was dose-dependent between 1 and 0.01 microgram endotoxin/ml of culture medium. The generation of PCA required RNA and protein synthesis but did not require the presence of serum. No activity was found in the culture medium. The activity was of tissue thromboplastin type, as indicated by biological and immunological criteria. These endotoxin effects were observed in the absence of endothelial damage, as shown by phase-contrast microscopy and lack of 51Cr release. These data could contribute to elucidate the pathogenesis of vascular complications associated with endotoxemia in man.

Sepsis, thrombosis and organ dysfunction.

Sepsis is often associated with haemostatic changes ranging from subclinical activation of blood coagulation (hypercoagulability), which may contribute to localized venous thromboembolism, to acute disseminated intravascular coagulation (DIC), characterized by widespread microvascular thrombosis and subsequent consumption of platelets and coagulation proteins, eventually causing bleeding manifestations. The key event underlying this life-threatening complication is the overwhelming inflammatory host response to the infectious agent leading to the overexpression of inflammatory mediators. The latter, along with the micro-organism and its derivatives are now believed to drive the major changes responsible for massive thrombin formation and fibrin deposition, namely 1) the aberrant expression of the TF by different cells (especially monocytes-macrophages), 2) the impairment of physiological anticoagulant pathways, orchestrated mainly by dysfunctional endothelial cells (ECs) and 3) the suppression of fibrinolysis due to overproduction of plasminogen activator inhibitor-1 (PAI-1) by ECs and likely also to thrombin-mediated activation of thrombin-activatable fibrinolysis inhibitor (TAFI). The ensuing microvascular thrombosis and ischemia are thought to contribute to tissue injury and multiple organ dysfunction syndrome (MODS). Recent evidence indicates that extracellular nuclear materials released from activated and especially apoptotic or necrotic cells, e.g. High Mobility Group Box-1 (HMGB-1) and histones, are endowed with cell toxicity, proinflammatory and clot-promoting properties and thus, during sepsis, they may represent late mediators that propagate further inflammation, coagulation, cell death and MODS. These insights into the pathogenesis of DIC and MODS may have implications for the development of new therapeutic agents potentially useful for the management of severe sepsis.

Activated human protein C prevents thrombin-induced thromboembolism in mice. Evidence that activated protein c reduces intravascular fibrin accumulation through the inhibition of additional thrombin generation.

Activated protein C (APC) is a potent physiologic anticoagulant with profibrinolytic properties, and has been shown to prevent thrombosis in different experimental models. We investigated the effect of human APC on thrombin-induced thromboembolism in mice, a model of acute intravascular fibrin deposition leading to death within minutes. APC given intravenously (i.v.) as a bolus 2 min before thrombin challenge (1,250 U/kg) reduced mortality in a dose-dependent manner despite the lack of thrombin inhibitor activity. Significant inhibition of thrombin-induced death was observed at the dose of 0.05 mg/kg, and maximal protection was obtained with 2 mg/kg (> 85% reduction in mortality rate). Histology of lung tissue revealed that APC treatment (2 mg/kg) reduced significantly vascular occlusion rate (from 89.2 to 46.6%, P < 0.01). The protective effect of APC was due to the inhibition of endogenous thrombin formation as indicated by the fact that (a) the injection of human thrombin caused a marked decrease in the coagulation factors of the intrinsic and common pathways (but not of Factor VII), suggesting the activation of blood clotting via the contact system; (b) APC pretreatment reduced markedly prothrombin consumption; (c) the lethal effect of thrombin was almost abolished when the animals were made deficient in vitamin K-dependent factors by warfarin treatment, and could be restored only by doubling the dose of thrombin, indicating that the generation of endogenous thrombin contributes significantly to death; and (d) APC failed to protect warfarin-treated animals, in which mortality is entirely due to injected thrombin, even after protein S supplementation. Other results suggest that APC protects from thrombin-induced thromboembolism by rendering the formed fibrin more susceptible to plasmin degradation rather than by reducing fibrin formation: in thrombin-treated mice, fibrinogen consumption was not inhibited by APC; and inhibition of endogenous fibrinolysis by epsilon-aminocaproic or tranexamic acid resulted in a significant reduction of the protective effect of APC. Since APC did not enhance plasma fibrinolytic activity, as assessed by the measurement of plasminogen activator (PA) or PA inhibitor (PAI) activities, PAI-1 antigen, or 125I-fibrin degrading activity, we speculate that the inhibition of additional (endogenous) thrombin formation by APC interrupts thrombin-dependent mechanisms that make fibrin clots more resistant to lysis, so that the intravascular deposited fibrin can be removed more rapidly by the endogenous fibrinolytic system.

Dabigatran enhances clot susceptibility to fibrinolysis by mechanisms dependent on and independent of thrombin‐activatable fibrinolysis inhibitor

Summary.  Background: Anticoagulants are expected to promote fibrinolysis by counteracting the antifibrinolytic effects of thrombin, which include thrombin‐activatable fibrinolysis inhibitor (TAFI) activation and clot structure enhancement. However, the efficiency of anticoagulants may vary remarkably, and the ability of direct thrombin inhibitors to facilitate clot lysis remains controversial. Objective: To evaluate the profibrinolytic effect of dabigatran, a new, direct thrombin inhibitor, using different in vitro models. Methods and Results: The resistance of tissue factor‐induced plasma clots to fibrinolysis by exogenous tissue‐type plasminogen activator (t‐PA) (turbidimetric method) was reduced by dabigatran in a concentration‐dependent manner, with ≥ 50% shortening of lysis time at clinically relevant concentrations (1–2 μm). A similar effect was observed in the presence of low (0.1 and 1 nm) but not high (10 nm) concentrations of thrombomodulin. Acceleration of clot lysis by dabigatran was associated with a reduction in TAFI activation and thrombin generation, and was largely, although not completely, negated by an inhibitor of activated TAFI, potato tuber carboxypeptidase inhibitor. The assessment of the viscoelastic properties of clots showed that those generated in the presence of dabigatran were more permeable, were less rigid, and consisted of thicker fibers. The impact of these physical changes on fibrinolysis was investigated using a model under flow conditions, which demonstrated that dabigatran made the clots markedly more susceptible to flowing t‐PA, by a mechanism that was largely TAFI‐independent. Conclusions: Dabigatran, at clinically relevant concentrations, enhances the susceptibility of plasma clots to t‐PA‐induced lysis by reducing TAFI activation and by altering the clot structure. These mechanisms might contribute to the antithrombotic activity of the drug.

Helicobacter pylori Neutrophil-Activating Protein Stimulates Tissue Factor and Plasminogen Activator Inhibitor-2 Production by Human Blood Mononuclear Cells

Helicobacter pylori neutrophil-activating protein (HP-NAP) is a virulence factor that activates phagocytic NADPH-oxidase. The effect of HP-NAP on the production of tissue factor (TF), plasminogen activator inhibitor-2 (PAI-2), and urokinase-type plasminogen activator (u-PA) by human blood mononuclear cells (MNC) was evaluated by using functional and immunological assays and mRNA analysis. HP-NAP induced time- and dose-dependent increases in TF and PAI-2, with a maximal effect at 300 nmol/L (>15-fold increase in antigens). No changes in u-PA were observed. When whole bacteria were used, an H. pylori mutant lacking HP-NAP was significantly less active than the wild-type strain. MNC from a patient with chronic granulomatous disease behaved as do normal cells, which indicates that HP-NAP effects can occur independently of NADPH-oxidase. HP-NAP, by inducing the coordinate expression of cell procoagulant and antifibrinolytic activities, might favor fibrin deposition and contribute to the inflammatory reaction of gastric mucosa elicited by H. pylori.

Warfarin inhibits both procoagulant activity and metastatic capacity of Lewis Lung Carcinoma cells: Role of vitamin K deficiency

Chronic vitamin K deficiency, either dietary or pharmacologically induced with warfarin, depressed significantly the growth of lung secondaries in a spontaneously metastasizing murine tumor, the Lewis Lung Carcinoma. This effect was associated with a marked depression of the procoagulant activity of cancer cells, which could contribute to fibrin deposition around the tumor. Cellular anticoagulation may thus be an important mechanism in the antimetastatic effect of warfarin.

Thrombin activatable fibrinolysis inhibitor: At the nexus of fibrinolysis and inflammation

TAFI (thrombin activatable fibrinolysis inhibitor) is the precursor of a basic carboxypeptidase (TAFIa) with strong antifibrinolytic and anti-inflammatory activity. Compelling evidence indicates that thrombin, either alone or in complex with thrombomodulin, is the main physiological activator of TAFI. For this reason derangements of thrombin formation, whatever the cause, may influence the fibrinolytic process too. Experimental models of thrombosis suggest that TAFI may participate in thrombus development and persistence under certain circumstances. In several models of pharmacological thrombolysis, the administration of TAFI inhibitors along with the fibrinolytic agent leads to a marked improvement of thrombus lysis, underscoring the potential of TAFI inhibitors as adjuvants for thrombolytic therapy. The role of TAFI in inflammatory diseases is more complex as it may serve as a defense mechanism, exacerbate the disease, or have no influence, depending on the nature of the model and the role played by the mediators controlled by TAFIa. Finally, the numerous clinical studies in patients with thrombotic disease support the idea that increased levels of TAFI and/or the enhancement of TAFI activation may represent a new risk factor for venous and arterial thrombosis.

SEPSIS-ASSOCIATED DISSEMINATED INTRAVASCULAR COAGULATION AND THROMBOEMBOLIC DISEASE

Sepsis is almost invariably associated with haemostatic abnormalities ranging from subclinical activation of blood coagulation (hypercoagulability), which may contribute to localized venous thromboembolism, to acute disseminated intravascular coagulation (DIC), characterized by massive thrombin formation and widespread microvascular thrombosis, partly responsible of the multiple organ dysfunction syndrome (MODS), and subsequent consumption of platelets and coagulation proteins causing, in most severe cases, bleeding manifestations. There is general agreement that the key event underlying this life-threatening sepsis complication is the overwhelming inflammatory host response to the infectious agent leading to the overexpression of inflammatory mediators. Mechanistically, the latter, together with the micro-organism and its derivatives, causes DIC by 1) up-regulation of procoagulant molecules, primarily tissue factor (TF), which is produced mainly by stimulated monocytes-macrophages and by specific cells in target tissues; 2) impairment of physiological anticoagulant pathways (antithrombin, protein C pathway, tissue factor pathway inhibitor), which is orchestrated mainly by dysfunctional endothelial cells (ECs); and 3) suppression of fibrinolysis due to increased plasminogen activator inhibitor-1 (PAI-1) by ECs and likely also to thrombin-mediated activation of thrombin-activatable fibrinolysis inhibitor (TAFI). Notably, clotting enzymes non only lead to microvascular thrombosis but can also elicit cellular responses that amplify the inflammatory reactions. Inflammatory mediators can also cause, directly or indirectly, cell apoptosis or necrosis and recent evidence indicates that products released from dead cells, such as nuclear proteins (particularly extracellular histones), are able to propagate further inflammation, coagulation, cell death and MODS. These insights into the pathogenetic mechanisms of DIC and MODS may have important implications for the development of new therapeutic agents that could be potentially useful particularly for the management of severe sepsis.

The role of thrombin activatable fibrinolysis inhibitor and factor XI in platelet-mediated fibrinolysis resistance: a thromboelastographic study in whole blood

Summary.  Background: The resistance of platelet‐rich thrombi to fibrinolysis is generally attributed to clot retraction and platelet PAI‐1 release. The role of TAFI in platelet‐mediated resistance to lysis is unclear. Objective: We investigated the contribution of TAFI to the antifibrinolytic effect of platelets in whole blood by thromboelastography. Methods: Platelet‐poor (PP‐WB, < 40 × 103 μL−1) and platelet‐rich (PR‐WB, > 400 × 103 μL−1) blood samples were obtained from normal human blood (N‐WB, 150–220 × 103 μL−1). Clot lysis time was measured by thromboelastography in recalcified blood supplemented with t‐PA (100 ng mL−1) and tissue factor (1:1000 Recombiplastin). Results: t‐PA‐induced lysis time increased in parallel with platelet concentration (up to 3‐fold). Neutralization of TAFI, but not of PAI‐1, shortened the lysis time by ∼ 50% in PR‐WB and by < 10% in PP‐WB. Accordingly, prothrombin F1+2 and TAFIa accumulation was greater in PR‐WB than in PP‐WB. A similar TAFI‐dependent inhibition of fibrinolysis was observed when clot retraction was prevented by cytochalasin D or abciximab, or when platelet membranes were tested. Moreover, in blood with an intact contact system, platelet‐mediated fibrinolysis resistance was attenuated by an anti‐FXI but not by an anti F‐XII antibody. Finally, platelets made the clots resistant to the profibrinolytic effect of heparin concentrations displaying a strong anticoagulant activity. Conclusions: Our data indicate that TAFI activation is one major mechanism whereby platelets make clots resistant to fibrinolysis and underscore the importance of TAFI inhibitors as new antithrombotic agents.

Cancer cell procoagulants and their pharmacological modulation

Cancer cells may promote fibrin formation in the tumor microenvironment through availability of procoagulant activities which are mainly of two types: tissue thromboplastin-like or direct activator of coagulation factor X. The pharmacological modulation of these activities could be potentially important in the control of metastasis growth. However, very limited information is available so far on this issue; it has recently been shown that the direct activator of coagulation factor X is a vitamin K-dependent activity which is depressed by warfarin treatment, not by anticoagulation with heparin or defibrinating enzymes. Whether the inhibition of this peculiar cancer procoagulant is involved in the antimetastatic activity of warfarin is a stimulating hypothesis which needs to be further substantiated.