Structural and functional features of factor XI

Summary.  Factor XI (FXI) has structural and mechanistic features that distinguish it from other coagulation proteases. A relatively recent addition to vertebrate plasma coagulation, FXI is a homodimer, with each subunit containing four apple domains and a protease domain. The apple domains form a disk structure with binding sites for platelets, high molecular weight kininogen, and the substrate factor IX (FIX). FXI is converted to the active protease FXIa by cleavage of the Arg³⁶⁹−Ile³⁷⁰ bond on each subunit. This converts the catalytic domains to the active forms, and unmasks exosites on the apple domains required for FIX binding. FXI activation by factor XIIa or thrombin proceeds through an intermediate with only one activated submit (1/2-FXIa). 1/2-FXIa activates FIX in a similar manner to FXIa. While the importance of the homodimeric structure of FXI is not certain, it may represent a strategy for binding to FIX and a platelet surface simultaneously.     

Factor XI deficiency in humans

Summary.  Factor XI (FXI) deficiency is an autosomal recessive injury-related bleeding tendency, which is common in Jews particularly of Ashkenazi origin. To date, 152 mutations in the FXI gene have been reported with four exhibiting founder effects in specific populations, Glu117stop in Ashkenazi and Iraqi Jews and Arabs, Phe283Leu in Ashkenazi Jews, Cys38Arg in Basques, and Cys128stop in the United Kingdom. Severe FXI deficiency does not confer protection against acute myocardial infarction, but is associated with a reduced incidence of ischemic stroke. Inhibitors to FXI develop in one-third of patients with very severe FXI deficiency following exposure to blood products. Therapy for prevention of bleeding during surgery in patients with severe FXI deficiency consists of plasma, factor XI concentrates, fibrin glue and antifibrinolytic agents. In patients with an inhibitor to FXI, recombinant factor VIIa is useful.     

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.     

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.     

Factor XI deficiency in animal models

Summary.  The blood coagulation system forms fibrin to limit blood loss from sites of injury, but also contributes to occlusive diseases such as deep vein thrombosis, myocardial infarction, and stroke. In the current model of a coagulation balance, normal hemostasis and thrombosis represent two sides of the same coin; however, data from coagulation factor XI-deficient animal models have challenged this dogma. Gene targeting of factor XI, a serine protease of the intrinsic pathway of coagulation, severely impairs arterial thrombus formation but is not associated with excessive bleeding. Mechanistically, factor XI may be activated by factor XII following contact activation or by thrombin in a feedback activation loop. This review focuses on the role of factor XI, and its deficiency states as novel target for prevention of thrombosis with low bleeding risk in animal models.     

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.     

Evolution of the contact phase of vertebrate blood coagulation

Summary. Background: Previous reports have noted that factor (F) XI and FXII and prekallikrein (the contact phase proteases) are absent in fish. Objectives: A broad survey of recently completed genomes was undertaken to find where during the course of vertebrate evolution these coagulation factors appeared. Methods: BLAST searches were conducted for the various factors on genomes of lamprey, puffer fish, zebra fish, frog, chicken, platypus, and opossum. Results: It was confirmed that FXII is absent from fish; it is present in frog, platypus, and opossum, but is absent in chicken, an apparent example of gene loss. A single gene corresponding to the evolutionary predecessor of FXI and prekallikrein occurs in frog, chicken, and platypus. The opossum (a marsupial) has both prekallikrein and FXI, completing the full complement of these genes that occurs in eutherian mammals. Conclusions: The step‐by‐step accrual of genes for these factors by a series of timely gene duplications has been confirmed by phylogenetic analysis and other considerations.     

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.     

Molecular basis of severe factor XI deficiency in seven families from the west of France. Seven novel mutations, including an ancient Q88X mutation

Summary.  Inherited factor (F)XI deficiency is a rare disorder in the general population, though it is commonly found in individuals of Ashkenazi Jewish ancestry. In particular, two mutations—a stop mutation (type II) and a missense mutation (type III)—which are responsible for FXI deficiency, predominate. The bleeding tendency associated with plasma FXI deficiency in patients is variable, with ∼ 50% of patients exhibiting excessive post-traumatic or postsurgical bleeding. In this study, we identified the molecular basis of FXI deficiency in 10 patients belonging to six unrelated families of the Nantes area in France and one family of Lebanese origin. As in Ashkenazi Jewish or in French Basque patients, we have identified a new ancient mutation in exon 4 resulting in Q88X, specific to patients from Nantes, that can result in a severely truncated polypeptide. Homozygous Q88X was found in a severely affected patient with an inhibitor to FXI and in three other unrelated families, either as homozygous, heterozygous or compound heterozygous states. Other identified mutations are two nonsense mutations in the FXI gene, in exon 7 and 15, resulting in R210X and C581X, respectively, which were identified in three families. A novel insertion in exon 3 (nucleotide 137 + G), which causes a stop codon, was characterized. Finally, sequence analysis of all 15 exons of the FXI gene revealed three missense mutations resulting in G336R and G350A (exon 10) and T575M (exon 15). Two mutations (T575M and G350A) with discrepant antigen and functional values are particularly interesting because most of the described mutations are associated with the absence of secreted protein.     

Point mutations regarded as missense mutations cause splicing defects in the factor XI gene

See also Duga S, Asselta R. Mutations in disguise. This issue, pp 1973–6. Summary. Background: Point mutations within exons are frequently defined as missense mutations. In the factor (F)XI gene, three point mutations, c.616C>T in exon 7, c.1060G>A in exon 10 and c.1693G>A in exon 14 were reported as missense mutations P188S, G336R and E547K, respectively, according to their exonic positions. Surprisingly, expression of the three mutations in cells yielded substantially higher FXI antigen levels than was expected from the plasma of patients bearing these mutations. Objectives: To test the possibility that the three mutations, albeit their positions within exons, cause splicing defects. Methods and results: Platelet mRNA analysis of a heterozygous patient revealed that the c.1693A mutation caused aberrant splicing. Platelet mRNA of a second compound heterozygote for c.616T and c.1060A mutations was undetectable suggesting its degradation. Cells transfected with a c.616T minigene favored production of an aberrantly spliced mRNA that skips exon 7. Cells transfected with a mutated minigene spanning exons 8–10 exhibited a significant decrease in the amount of normally spliced mRNA. In silico analysis revealed that the three mutations are located within sequences of exonic splicing enhancers (ESEs) that bind special proteins and are potentially important for correct splicing. Compensatory mutations created near the natural mutations corrected the putative function of ESEs thereby restoring normal splicing of exons 7 and 10. Conclusions: The present findings define a new mechanism of mutations in F11 and underscore the need to perform expression studies and mRNA analysis of point mutations before stating that they are missense mutations.     

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.     

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.     

人血浆凝血因子Ⅺ的纯化

目的分离纯化人血浆中凝血因子Ⅺ(FⅪ),为制备该蛋白质的单克隆抗体(McAb)提供抗原。方法将血浆进行前处理后,采用CM-Sepharose fast flow和Heparin CL-6B 2步层析法,从人血浆中粗纯FⅪ。结果FⅪ回收率为(21.02±5.04)%,比活性为(17.59±1.96)U/mg,浓缩倍数为(1162.29±129.64)倍(n=7)。结论2步层析法能较有效地浓缩血浆中的FⅪ,从而满足制备FⅪ单克隆抗体所需。