A cross-reactive material positive variant of coagulation factor XI (FXIP520L) with a catalytic defect

Inherited deficiency of the trypsin-like protease factor (F) XI is associated with a mild to moderate bleeding diathesis. In most cases, FXI protein is reduced in plasma, and examples of dysfunctional circulating FXI variants are rare. We characterized the defect in one such variant with a proline to leucine substitution at residue 520. FXI Pro520 corresponds to chymotrypsin Pro161, and is conserved in most members of the chymotrypsin protease family. Recombinant FXI containing this substitution will be referred to as FXI(P161L). k(cat) for cleavage of chromogenic substrates and for activation of the natural FXIa substrate FIX is approximately 3-fold lower for activated FXI(P161L) (FXIa(P161L)) than for wild-type FXIa (FXIa(WT)), consistent with an abnormal protease active site. Inhibition of FXIa(P161L) by diisopropyl fluorophosphate is 2.4-fold slower than for FXIa(WT), suggesting distortion of the protease oxyanion hole. Binding to p-aminobenzamidine, a probe for the integrity of the S1 substrate-binding site, was similar for FXIa(WT) and FXIa(P161L). Rates of carbamylation of Ile16 were also similar for FXIa(WT) and FXIa(P161L), indicating that the critical salt bridge between Ile16 and Asp194 forms normally during protease activation. Cumulatively, the data demonstrate that Pro161 is required for normal active site oxyanion hole conformation in FXIa. Examination of the FXIa crystal structure and modeling studies indicate that Pro161 forms several hydrophobic contacts with adjacent amino acids that stabilize active site conformation. Leucine can be incorporated at position 161 in FXIa, but would not form the extensive stabilizing network of hydrophobic interactions formed by Pro161.     

Severe factor XI deficiency caused by a Gly555 to Glu mutation (factor XI-Glu555): a cross-reactive material positive variant defective in factor IX activation.

During normal hemostasis, the coagulation protease factor (F)XIa activates FIX. Hereditary deficiency of the FXIa precursor, FXI, is usually associated with reduced FXI protein in plasma, and circulating dysfunctional FXI variants are rare. We identified a patient with < 1% normal plasma FXI activity and normal levels of FXI antigen, who is homozygous for a FXI Gly555 to Glu substitution. Gly555 is two amino acids N-terminal to the protease active site serine residue, and is highly conserved among serine proteases. Recombinant FXI-Glu555 is activated normally by FXIIa and thrombin, and FXIa-Glu555 binds activated factor IX similarly to wild type FXIa (FXIa(WT)). When compared with FXIa(WT), FXIa-Glu555 activates factor IX at a greatly reduced rate ( approximately 400-fold), and is resistant to inhibition by antithrombin. Interestingly, FXIa(WT) and FXIa-Glu555 cleave the small tripeptide substrate S-2366 with comparable k(cat)s. Modeling indicates that the side chain of Glu555 significantly alters the electrostatic charge around the active site, and would sterically interfere with the interaction between the FXIa S2' site and the P2' residues on factor IX and antithrombin. FXI-Glu555 is the first reported example of a naturally occurring FXI variant with a significant defect in FIX activation.     

Structural interpretation of 42 mutations causing factor XI deficiency using homology modeling.

BACKGROUND: Factor (F)XI is important in the consolidation phase of blood coagulation. The structural effects of mutations causing FXI deficiency have not been well described due to the lack of a structure for FXI. OBJECTIVES: To develop molecular models of the four apple (Ap) and serine protease (SP) domains in FXI in order to assess the structural effects of published FXI mutations in the light of their phenotypes. METHODS: The Ap domains were modeled using the NMR structure of an adhesin from Eimeria tenella. The SP domain was modeled using the crystal structure of beta-tryptase. RESULTS: The effect of 42 mutations causing FXI deficiency was analyzed using homology models for the Ap and SP domains in FXI. Protein misfolding was implicated as the likely structural mechanism of disease in six of 14 mutations in the four Ap domains with Type I phenotypes. Likewise, misfolding was implicated in eight of 14 mutations in the SP domain with Type I phenotypes. Unlike other coagulation factor deficiencies, Type II phenotypes based on a catalytically dysfunctional FXI are uncommon. The structural models indicated that two known Type II mutations in the Ap domains could be correlated with functional defects in substrate or cofactor binding, and likewise four Type II mutations in the SP domain would disrupt the active site. CONCLUSIONS: New FXI disease-causing mutations can now be structurally characterized to complement phenotypic data, and expression studies can be designed to verify the molecular basis of each deficiency.     

Factor XI apple domains and protein dimerization

Summary.  The coagulation protease zymogen factor (F)XI is a disulfide bond-linked homodimer, a configuration that is necessary for protein secretion and function. The non-catalytic portion of the FXI polypeptide contains four repeats called apple domains (A1–A4). It is clear that FXI A4 plays a key role in dimer formation, however, the importance of other apple domains to this process has not been examined. We prepared recombinant FXI molecules in which apple domains were exchanged with those of the structurally homologous monomeric protein prekallikrein (PK). As expected, FXI/PK chimeras containing FXI A4 are dimers, while those with PK A4 are monomers. FXI A4 contains cysteine at position 321 that forms the interchain disulfide bond, while Cys321 in PK is unavailable for interchain bond formation because it is paired with Cys326. FXI/PK chimeras containing PK A4 were modified by changing Cys326 to glycine, leaving Cys321 unpaired (PKA4-Gly326). FXI with a PK A4 domain is a monomer, however, introducing PKA4-Gly326 results in a disulfide bond-linked dimer. This indicates that dimer formation can occur in the absence of FXI A4. In proteins containing PKA4-Gly326, replacing FXI A3 with PK A3 partially interferes with dimer formation, while substitution of A2, or A2 and A3 prevents dimer formation. PKA4-Gly326 cannot induce the native PK molecule to dimerize. The data indicate that FXI A2 and A3 make contributions to dimer formation. As these domains are involved in activities that require dimeric protein, it seems reasonable that they stabilize this conformation.     

The function of factor XI in tissue factor-initiated thrombin generation

Summary.  The influence of plasma and platelet factor (F)XI on thrombin generation initiated with 10 p m tissue factor (TF) in a synthetic coagulation model was evaluated in the presence of either 2 × 10⁸ mL⁻¹ platelets or the equivalent (2 µ m ) phospholipids. In either system, with all proteins present at physiological concentrations, FXI (30 n m ) had no effect on thrombin generation. With phospholipids in the absence of FXI, an increase in vitamin K-dependent proteins (VKDP) (up to 500%) significantly prolonged the initiation phase of thrombin generation and decreased maximum thrombin levels. The inhibition was principally caused by the elevated prothrombin and FIX concentrations. When 30 n m FXI was added with elevated VKDP and phospholipids, the initiation phase was decreased and the maximum thrombin levels generated substantially increased. In experiments with platelets (with and without plasma FXI), an increase in VKDP had little effect on the initiation phase of thrombin generation. These data indicate that (i) FXI has no effect on thrombin generation at 10 p m TF and physiological concentrations of VKDP; (ii) platelets and plasma FXI are able to compensate for the inhibitory effects of elevated VKDP.     

The intrinsic pathway of coagulation: a target for treating thromboembolic disease?

Summary.  The classic intrinsic pathway of coagulation is triggered by contact activation of the plasma protease factor (F)XII, followed by sequential proteolytic activation of FX1 and FIX. While a key mechanism for initiating coagulation in some clinically useful in vitro assays, the absence of abnormal bleeding associated with congenital FXII deficiency indicates that the intrinsic pathway is not important for normal blood coagulation in vivo . However, recent work with mice lacking FXII or FXI suggest that these proteases make important contributions to formation of pathologic intravascular thrombi. In models of arterial injury, FXII or FXI null mice are protected from formation of platelet rich occlusive thrombi to a degree similar to that seen in FIX deficient mice (a model for the severe bleeding disorder hemophilia B) or to wild type mice treated with high dose heparin. FXII or FXI deficiency does not appear to prevent the initiation of thrombus formation in these models, but instead causes significant thrombus instability that prevents occlusion of the vessel. These findings raise the possibility that a pathway similar or identical to the intrinsic pathway may operate in vivo under some circumstances. Furthermore, the disproportionate importance of FXII and FXI to occlusive thrombus formation compared to normal hemostasis makes these proteases attractive candidates for therapeutic inhibitors to treat or prevent thromboembolic disorders.     

A proposal for managing bleeding in patients on therapeutic factor XI(a) inhibitors

Several drugs that reduce functional levels of the plasma protease zymogen factor XI (FXI), or that inhibit its activated form (FXIa), are being evaluated as treatments to prevent thrombosis. Based on the observation that individuals with inherited FXI deficiency have a relatively mild bleeding disorder, it is anticipated that therapeutic FXI(a) inhibitors will have a smaller impact on hemostasis than anticoagulants targeting thrombin or factor Xa. However, even if FXI(a) inhibitors are determined to be safer than currently used anticoagulants, some patients on these drugs will experience abnormal bleeding or require emergent surgery. Strategies for dealing with such situations are required. Treatment with antifibrinolytic agents and low doses of recombinant factor VIIa effectively prevent abnormal bleeding in FXI-deficient patients with alloantibody inhibitors to FXI who undergo surgery. We propose that a similar strategy can be used for patients on therapeutic FXI(a) inhibitors who are bleeding or require invasive procedures.     

Factor XI promotes hemostasis in factor IX‐deficient mice

Essentials

• Mice lacking factor IX (FIX) or factor XI (FXI) were tested in a saphenous vein bleeding model.
• FIX‐deficient mice displayed a hemostatic defect and FXI‐deficient mice were similar to wild type mice.
• Infusion of FXI or over‐expression of FXI in FIX‐deficient mice improved hemostasis.
• FXI may affect the phenotype of FIX‐deficiency (hemophilia B).

Summary

Background

In humans, deficiency of coagulation factor XI may be associated with a bleeding disorder, but, until recently, FXI‐deficient mice did not appear to have a hemostatic abnormality. A recent study, however, indicated that FXI‐deficient mice show a moderate hemostatic defect in a saphenous vein bleeding (SVB) model.

Objectives

To study the effect of FXI on bleeding in mice with normal levels of the FXI substrate FIX and in mice lacking FIX (a murine model of hemophilia B).

Methods

Wild‐type mice and mice lacking either FIX (F9^?) or FXI (F11^?/?) were tested in the SVB model. The plasma levels of FXI in F11^?/? mice were manipulated by infusion of FXI or its active form FXIa, or by overexpressing FXI by the use of hydrodynamic tail vein injection.

Results

F9^? mice showed a significant defect in the SVB model, whereas F11^?/? mice and wild‐type mice were indistinguishable. Intravenous infusion of FXI or FXIa into, or overexpression of FXI in, F9^? mice improved hemostasis in the SVB model. Overexpression of a FXI variant lacking a FIX‐binding site also improved hemostasis in F9^? mice.

Conclusions

Although we were unable to demonstrate a hemostatic defect in F11^?/? mice in the SVB model, our results support the premise that supraphysiological levels of FXI improve hemostasis in F9^? mice through FIX‐independent pathways.

     

Functional analysis of the EGF-like domain mutations Pro55Ser and Pro55Leu, which cause mild hemophilia B

Summary.  We studied the functional role of two mutations, Pro55Ser and Pro55Leu, located in the N-terminal Epidermal Growth Factor-like domain (EGF1) of coagulation factor (F) IX. Both mutations cause mild hemophilia B with habitual FIX coagulant activities of 10–12% and FIX antigen levels of 50%. We found that activation by FVIIa/TF and FXIa was normal for FIXPro55Ser, but resulted in proteolysis of FIXPro55Leu at Arg318-Ser319 with a concomitant loss of amidolytic activity, suggesting intramolecular communication between EGF1 and the serine protease domain in FIX. This was further supported by experiments using an anti-EGF1 monoclonal antibody. Activation of FX by FIXaPro55Ser was impaired in both the presence and the absence of phospholipid or FVIIIa, indicating that Pro55 is not directly involved in binding to FVIIIa. We also studied the effect of the two Pro55 mutations on Ca²⁺ affinity and found only small changes. Thus, the Pro55Ser mutation causes hemophilia primarily through to an impaired ability to activate FX whereas at least in vitro the Pro55Leu defect interferes with the activation of FIX.     

Factor XI contributes to thrombus propagation on injured neointima of the rabbit iliac artery

BACKGROUND: Thrombus formation through the activation of tissue factor (TF) and factor (F) XI is a critical event in the onset of cardiovascular disease. TF expressed in atherosclerotic plaques and circulating blood is an important determinant of thrombogenicity that contributes to fibrin-rich thrombus formation after plaque disruption. However, the contribution of FXI to thrombus formation on disrupted plaques remains unclear. METHODS: A mouse monoclonal antibody against FXI and activated FXI (FXIa) (XI-5108) was generated by immunization with activated human FXI. Prothrombin time (PT), activated partial thromboplastin time (APTT), bleeding time, and ex vivo platelet aggregation in rabbits were measured before and after an intravenous bolus injection of XI-5108. We investigated the role of FXI upon arterial thrombus growth in the rabbit iliac artery in the presence of repeated balloon injury. RESULTS: The XI-5108 antibody reacted to the light chain of human and rabbit FXI/FXIa, and inhibited FXIa-initiated FXa and FXIa generation. Fibrin-rich thrombi developed on the injured neointima that was obviously immunopositive for glycoprotein IIb-IIIa, fibrin, TF, and FXI. Intravenous administration of XI-5108 (3.0 mg kg(-1)) remarkably reduced thrombus growth, and the APTT was significantly prolonged. However, PT, bleeding time and platelet aggregation were not affected. CONCLUSIONS: These results indicate that plasma FXI plays a potent role in thrombus growth on the injured neointima. Inhibition of plasma FXI activity might help to reduce thrombus growth on ruptured plaques without prolonging bleeding time.     

Procoagulant protein levels are differentially increased during human endotoxemia

Summary.  On the basis of plasma interleukin levels it was suggested that there is an inflammatory component to the risk of venous thrombotic disease. Other evidence shows that elevated levels of coagulation factor (F)VIII, FIX, FX and FXI are risk indicators for venous thrombosis, but the reasons for elevation remain unclear. We tested the hypothesis that the elevated levels could reflect an inflammatory reaction by measuring coagulation factor levels during experimental human endotoxemia. Male volunteers received endotoxin (4 ng kg⁻¹), and blood samples were obtained before and at multiple time points after the challenge. Plasma was used for a panel of coagulation tests. Antigen levels of FVIII, von Willebrand factor (VWF), FIX, and FX were increased after endotoxin administration, reaching peak levels between 2 and 5 h. Within 24 h levels normalized, except for FVIII and VWF levels that remained at > 200%. Fibrinogen levels, and to a lesser extent FXI levels, also responded with an increase, but slower. These levels did not return to normal during the observation period. FVII levels were strongly depressed. FVIII, FIX and FX reacted immediately and strongly to endotoxin administration. The time pattern of this response is different from the slower so-called acute phase response, which appeared to be followed by FXI and fibrinogen. These increased levels of coagulation factors during an inflammatory state provide new ways of explaining why elevated levels of FVIII, FIX and FXI behave as risk indicators disease.     

Molecular modeling of the prekallikrein structure provides insights into high-molecular-weight kininogen binding and zymogen activation

BACKGROUND: Prekallikrein (PK) plays a central role in the contact system that activates blood coagulation and is involved in the regulation of blood pressure. OBJECTIVES: To provide three-dimensional structural data for PK and rationalize the molecular basis of substrate recognition and zymogen activation. PATIENTS/METHODS: The PK homology model was constructed using the coagulation factor (F) XI crystal structure as a template with the program SWISS-MODEL. RESULTS: The domain organization of the PK apple domains and serine protease is conserved compared to FXI. Surface charge calculations on the PK model revealed that ligand binding to high-molecular-weight kininogen (HK) is predicted to have two key determinants: a pocket within the apple 2 domain and a basic channel formed at the interface of apple domains 1 and 4. A hereditary mutation resulting in PK deficiency (Gly104Arg) and the Lys140 alpha-kallikrein cleavage site both disrupt HK binding and are shown to map to opposite sides of the apple 2 domain pocket. The model also describes the differences in the apple 4 domain that prevents dimer formation in PK vs. FXI. A C-terminal extension in the PK serine protease domain is described as a potential substrate for prolylcarboxypeptidase. CONCLUSIONS: The interaction between PK and HK is mediated by two discrete surfaces formed by the PK A1, A2 and A4 domains with charge likely to be a critical component of the binding. A novel mode of PK activation is postulated to involve prolylcarboxypeptidase cleaving at the C-terminus rather than the activation loop.     

Effects of acute liver injury on blood coagulation

Summary.  The mechanisms leading to the hemostatic changes of acute liver injury are poorly understood. To study these further we have assessed coagulation and immune changes in patients with acute paracetamol overdose and compared the results to patients with chronic cirrhosis and normal healthy controls. The results demonstrate that in paracetamol overdose coagulation factors (F)II, V, VII and X were reduced to a similar degree and were significantly lower than FIX and FXI (mean levels 0.28, 0.16, 0.13, 0.19, 0.51 and 0.72 IU mL⁻¹, respectively). In cirrhosis, by contrast, FII, FV, FVII, FIX and FX were equally reduced whilst FXI was lower than the other factors (mean levels 0.64, 0.69, 0.62, 0.60, 0.66 and 0.40 IU mL⁻¹, respectively). FVIII was raised in paracetamol overdose patients but normal in those with cirrhosis (mean levels 1.95 and 1.01 IU mL⁻¹, respectively). Interleukin-6 and tumor necrosis factor-α levels were raised in both patient groups, but higher levels were found in paracetamol overdose, compared to cirrhosis. Thrombin-antithrombin and soluble tissue factor levels were higher in those with acute liver injury but normal in cirrhosis. Antithrombin levels were reduced in both acute liver injury and cirrhosis. From these data we put forward a novel mechanism for the coagulation changes in acute paracetamol induced liver injury. We propose that immune activation leads to tissue factor-initiated consumption of FII, FV, FVII and FX, but that levels of FIX and FXI are better preserved because antithrombin inhibits the thrombin induced positive feedback loop that activates these latter factors.     

Laminin promotes coagulation and thrombus formation in a factor XII‐dependent manner

Summary. Background: Laminin is the most abundant non‐collagenous protein in the basement membrane. Recent studies have shown that laminin supports platelet adhesion, activation and aggregation under flow conditions, highlighting a possible role for laminin in hemostasis. Objective: To investigate the ability of laminin to promote coagulation and support thrombus formation under shear. Results and methods: Soluble laminin accelerated factor (F) XII activation in a purified system, and shortened the clotting time of recalcified plasma in a FXI‐ and FXII‐dependent manner. Laminin promoted phosphatidylserine exposure on platelets and supported platelet adhesion and fibrin formation in recalcified blood under shear flow conditions. Fibrin formation in laminin‐coated capillaries was abrogated by an antibody that interferes with FXI activation by activated FXII, or an antibody that blocks activated FXI activation of FIX. Conclusion: This study identifies a role for laminin in the initiation of coagulation and the formation of platelet‐rich thrombi under shear conditions in a FXII‐dependent manner.     

Factor XI and contact activation as targets for antithrombotic therapy

The most commonly used anticoagulants produce therapeutic antithrombotic effects either by inhibiting thrombin or factor Xa (FXa) or by lowering the plasma levels of the precursors of these key enzymes, prothrombin and FX. These drugs do not distinguish between thrombin generation contributing to thrombosis from thrombin generation required for hemostasis. Thus, anticoagulants increase bleeding risk, and many patients who would benefit from therapy go untreated because of comorbidities that place them at unacceptable risk for hemorrhage. Studies in animals demonstrate that components of the plasma contact activation system contribute to experimentally induced thrombosis, despite playing little or no role in hemostasis. Attention has focused on FXII, the zymogen of a protease (FXIIa) that initiates contact activation when blood is exposed to foreign surfaces, and FXI, the zymogen of the protease FXIa, which links contact activation to the thrombin generation mechanism. In the case of FXI, epidemiologic data indicate this protein contributes to stroke and venous thromboembolism, and perhaps myocardial infarction, in humans. A phase 2 trial showing that reduction of FXI may be more effective than low molecular weight heparin at preventing venous thrombosis during knee replacement surgery provides proof of concept for the premise that an antithrombotic effect can be uncoupled from an anticoagulant effect in humans by targeting components of contact activation. Here, we review data on the role of FXI and FXII in thrombosis and results of preclinical and human trials for therapies targeting these proteins.     

Effects of factor IX or factor XI deficiency on ferric chloride-induced carotid artery occlusion in mice.

Factor XI (FXI) and factor IX (FIX) are zymogens of plasma serine proteases required for normal hemostasis. The purpose of this work was to evaluate FXI and FIX as potential therapeutic targets by means of a refined ferric chloride (FeCl(3))-induced arterial injury model in factor-deficient mice. Various concentrations of FeCl(3) were used to establish the arterial thrombosis model in C57BL/6 mice. Carotid artery blood flow was completely blocked within 10 min in C57BL/6 mice by application of 3.5% FeCl(3). In contrast, FXI- and FIX-deficient mice were fully protected from occlusion induced by 5% FeCl(3), and were partially protected against the effect of 7.5% FeCl(3). The protective effect was comparable to very high doses of heparin (1000 units kg(-1)) and substantially more effective than aspirin. While FXI and FIX deficiencies were indistinguishable in the carotid artery injury model, there was a marked difference in a tail-bleeding-time assay. FXI-deficient and wild-type mice have similar bleeding times, while FIX deficiency was associated with severely prolonged bleeding times (>5.8-fold increase, P < 0.01). Given the relatively mild bleeding diathesis associated with FXI deficiency, therapeutic inhibition of FXI may be a reasonable strategy for treating or preventing thrombus formation.     

Three residues at the interface of factor XI (FXI) monomers augment covalent dimerization of FXI

Summary.  Background:  Human plasma factor XI is a homodimer, with each monomer comprising a catalytic domain and four homologous 'apple' domains. The monomers bind to each other through non-covalent bonds and through a disulfide bond between Cys321 residues in apple 4 domains. Objective:  To identify residues essential for dimerization in the FXI monomer interface. Methods:  Specificity-determining residues in apple 4 domains were sought by sequence alignment of FXI and prekallikrein apple domains in different species. Specific residues identified in apple 4 domains were mutagenized and expressed in baby hamster kidney (BHK) cells for evaluation of their effect on FXI dimerization, analyzed by non-reduced sodium dodecylsulfate polyacrylamide gel electrophoresis and size-exclusion chromatography. Results:  Among the 19 residues of the FXI monomer interface, Leu284, Ile290 and Tyr329 were defined as specificity-determining residues. Substitutions of these residues or pairs of residues did not affect FXI synthesis and secretion from transfected BHK cells, but did impair dimerization, despite the presence of cysteine at position 321. The double mutant 284A/290A yielded predominantly a monomer, whereas all other single or double mutants yielded monomers as well as disulfide-bonded dimers. Conclusions:  The data suggest that Leu284, Ile290 and Tyr329 in the interface of FXI monomers are essential for forming non-covalently bonded dimers that facilitate formation of a disulfide-bonded stable FXI dimer.     

Effects of factor XI deficiency on ferric chloride-induced vena cava thrombosis in mice

BACKGROUND: Increased plasma levels of coagulation factor (F) XI are a risk factor for venous thrombosis. OBJECTIVE: To further explore the relationship between FXI and venous thrombosis, we evaluated FXI-deficient and wild-type mice in a ferric chloride (FeCl(3))-induced vena cava thrombosis model. METHODS AND RESULTS: Thrombosis was induced by 3-min topical application of filter papers containing increasing concentrations of FeCl(3) and the thrombus was measured at 30 min. In contrast to wild-type mice, FXI-deficient mice failed to form a thrombus with 5% FeCl(3,) and were partially protected against 7.5% and 10% FeCl(3,) respectively. The protective effect was substantially stronger than a high dose of heparin (1,000 units kg(-1), i.v.), clopidogrel (30 mg kg(-1), p.o.) or argatroban (30 mg kg(-1), i.p.). These antithrombotic agents resulted in off-scale bleeding in a tail bleeding time assay, whereas the bleeding time of FXI-deficient mice was unchanged compared to wild-type mice. In addition to its known effect on the coagulation cascade, enhanced clot lysis was demonstrated in FXI-deficient mouse and human plasma compared to those supplemented with FXIa. CONCLUSION: Given the strong antithrombotic efficacy (possibly contributed by strong anticoagulant activity associated with increased fibrinolytic activity) and mild bleeding diathesis associated with FXI deficiency, therapeutic inhibition of FXI may be a reasonable therapeutic strategy to treat or prevent venous thrombosis.     

Binding studies of the enzyme (factor IXa) with the cofactor (factor VIIIa) in the assembly of factor-X activating complex on the activated platelet surface

Summary.  Activated platelet membranes expose binding sites for the enzyme factor (F)IXa, the substrate (FX) and the cofactor (FVIIIa) that colocalize to assemble the FX-activating complex and promote optimal rates of FX activation. To determine the stoichiometry and affinity of binding to activated platelets, coordinate, equilibrium binding studies with enzyme (¹²⁵I-FIXa) and cofactor (¹³¹I-FVIII or ¹³¹I-FVIIIa) were carried out in the presence of saturating concentrations of substrate (FX). Results of these studies indicate that in the presence of FX (1.5 µ m ), the enzyme (active-site-inhibited Glu-Gly-Arg-FIXa, EGR-FIXa) and procofactor (FVIII) bind to an equal number (approximately 700 sites/platelet) of receptors whereas the active cofactor (FVIIIa) binds an additional approximately 500 high-affinity FVIIIa binding sites per platelet (K_d approximately 0.8 n m ). With excess zymogen (FIX) to block shared FIX/FIXa-binding sites, the stoichiometry of ¹²⁵I-FIXa and ¹³¹I-FVIIIa binding was 1 : 4. These FIXa/FVIIIa binding studies together with previously reported evidence of the coordinate binding of FVIIIa and FX to equivalent numbers of binding sites on activated platelets provide strong evidence to support the conclusion that FVIIIa comprises the receptor that presents FX to FIXa for efficient catalysis on the activated platelet membrane.     

Inherited factor XI deficiency confers no protection against acute myocardial infarction

Summary.  Background and purpose : Factor XI (FXI) contributes to thrombin generation thereby affecting fibrin formation and to down regulation of fibrinolysis by activation of thrombin-activatable fibrinolysis inhibitor (TAFI). The purpose of this study was to evaluate whether patients with severe FXI deficiency are protected against acute myocardial infarction (AMI). Methods : The incidence of AMI in patients with severe FXI deficiency (FXI activity less than 15 U dL⁻¹) whose age was 35 years or more was compared to the incidence of AMI in age and gender matched persons of the general population. Atherosclerotic risk factors were assessed in FXI deficient patients and blood was tested for prothrombotic parameters such as FV Leiden, prothrombin G20210A, lupus anticoagulant, and platelet membrane polymorphisms. The common mutations causing FXI deficiency in Jews were also examined. Results : Of 96 patients with severe FXI deficiency (55 women and 41 men) 16 had a history of AMI (6 women and 10 men). The median age at the time of AMI was 64.5 for women and 58 for men. The calculated annual rate of AMI in men was similar to the expected in the general Israeli population, whereas in women it was almost 2-fold higher, but this difference did not reach statistical significance. One or more atherosclerotic risk factors were observed in 13 of 16 patients (81.3%) with AMI compared to 44 of 79 patients (55.7%) without AMI ( P  < 0.001). The frequency distributions of platelet polymorphisms and of prothrombotic polymorphisms were not different between patients with severe FXI deficiency who experienced or not an AMI. None of the patients had lupus anticoagulant. The common genotypes which cause FXI deficiency in Jews were similarly distributed in patients with and without AMI. Conclusions : Severe FXI deficiency does not confer protection against AMI.