SMART MODE:

NORMAL GENOMIC

• Dorfman R, Walsh PN
• Noncovalent interactions of the Apple 4 domain that mediate coagulation factor XI homodimerization.
• J Biol Chem. 2001; 276: 6429-38
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• The Apple 4 (A4) domain of human plasma factor XI (FXI) was used to investigate the process of FXI noncovalent dimer formation. Recombinant 6-histidine-tagged A4 domain proteins were prepared utilizing a bacterial expression system. Purification was accomplished under denaturing conditions, followed by a refolding protocol to facilitate correct disulfide bond formation. Analysis of the A4 domain (C321S mutant) by size exclusion chromatography indicated the presence of a slowly equilibrating reversible monomer-dimer equilibrium. The elution profiles reveal highly symmetrical peaks for both dimeric and monomeric species with elution times that were highly reproducible for varying amounts of both the dimeric and monomeric species. The monomer-dimer equilibrium was found to be dependent upon changes in both pH and salt concentration. Under conditions approximating physiologic salt concentration and pH (20 mm HEPES, 100 mm NaCl, and 1 mm EDTA, pH 7.4), it was determined that the monomer-dimer equilibrium was characterized by a dissociation constant (K(D)) value of 229 +/- 26 nm with a calculated Delta G value of 9.1 kcal/mol. This report identifies electrostatic contributions and the presence of a hydrophobic component that mediate interactions at the A4 domain interface. The rate of dissociation for the recombinant A4 domain C321S mutant was examined by monitoring the increase in 4,4'-dianilino-1,1'-binaphthyl-5,5'-disulfonic acid dipotassium salt fluorescence under dissociating conditions, giving a value for a dissociation rate constant (k(off)) of 4.3 x 10(-3) s(-1).

• Brown PJ, Gill AC, Nugent PG, McVey JH, Tomley FM
• Domains of invasion organelle proteins from apicomplexan parasites are homologous with the Apple domains of blood coagulation factor XI and plasma pre-kallikrein and are members of the PAN module superfamily.
• FEBS Lett. 2001; 497: 31-8
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• Micronemes are specialised organelles, found in all apicomplexan parasites, which secrete molecules that are essential for parasite attachment to and invasion of host cells. Regions of several microneme proteins have sequence similarity to the Apple domains (A-domains) of blood coagulation factor XI (FXI) and plasma pre-kallikrein (PK). We have used mass spectrometry on a recombinant-expressed, putative A-domain from the microneme protein EtMIC5 from Eimeria tenella, to demonstrate that three intramolecular disulphide bridges are formed. These bridges are analogous to those that stabilise A-domains in FXI and PK. The data confirm that the apicomplexan domains are structural homologues of A-domains and are therefore novel members of the PAN module superfamily, which also includes the N-terminal domains of members of the plasminogen/hepatocyte growth factor family. The role of A-domains/PAN modules in apicomplexan parasites is not known, but their presence in the microneme suggests that they may be important for mediating protein-protein or protein-carbohydrate interactions during parasite attachment and host cell invasion.

• Shariat-Madar Z, Mahdi F, Schmaier AH
• Factor XI assembly and activation on human umbilical vein endothelial cells in culture.
• Thromb Haemost. 2001; 85: 544-51
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• Biotin-FXI optimally bound to HUVEC in the presence of 40 nM high molecular weight kininogen (HK) and > or =7 microM Zn2+. There was little specific FXI binding in the absence of added HK and at concentrations of Zn2+ <15 microM. FXI and prekallikrein, but not prothrombin, blocked biotin-FXI binding to HUVEC in the presence of HK with an IC50 of 18 nM and 180 nM, respectively. Monoclonal antibody HKL16 and peptide SDD31 also inhibited biotin-XI binding in the presence of HK with an IC50 of 4.7 nM and 50 microM, respectively. Alternatively, peptide T249-F260 of FXI's apple domain 3 and heparin monosulfate were weak inhibitors of FXI binding to HUVEC. FXI bound to HUVEC with an apparent Kd of 6.9 +/- 3.0 nM and Bmax of 13 +/- 2.6 x 10(6) sites/cell. FXI bound to HK on HUVEC, but not prothrombin, became converted to FXIa. FXI activation on HUVEC resulted from tissue culture media bovine factor XIIa. HUVEC grown in human factor XI-deficient serum did not support FXI activation. FXI binding to HUVEC in culture was mostly mediated by HK and FXI activation on HUVEC is dependent on cell-associated factor XIIa.

• Sun MF et al.
• Defective binding of factor XI-N248 to activated human platelets.
• Blood. 2001; 98: 125-9
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• Variants of factor XI containing Gln226 to Arg (Q226 to R) and Ser248 to Asn (S248 to N) substitutions were first identified in an African American family with a history of excessive bleeding. The substitutions have recently been identified in unrelated individuals, suggesting they are relatively common. Both amino acids are located in the third apple domain of factor XI, an area implicated in binding interactions with factor IX and activated platelets. Recombinant factor XI-R226 and factor XI-N248 were compared with wild-type factor XI in assays for factor IX activation or platelet binding. Factor XI-R226 activates factor IX with a Michaelis-Menten constant (K(m)) about 5-fold greater than wild-type protein. The catalytic efficiency of factor IX activation is similar to wild-type protein, however, due to an increase in the turnover number (k(cat)) for the reaction. Iodinated factor XI-N248 binds to activated platelets with a dissociation constant (K(d)) more than 5-fold higher than wild-type protein (55 nM and 10 nM, respectively). Activation of factor XI-N248 by thrombin in the presence of activated platelets is slower and does not progress to the same extent as activation of the wild-type protein under similar conditions. Factor XI-N248 activates factor IX normally in a purified protein system and has relatively normal activity in activated partial thromboplastin time (aPTT) assays. Factor XI-N248 is the first factor XI variant described with a clear functional difference compared with wild-type protein. Importantly, the defect in platelet binding would not be detected by routine clinical evaluation with an aPTT assay.

• Perricone R, Modica S, Fontana L
• Coagulation factor XI and venous thrombosis.
• N Engl J Med. 2000; 343: 220-1

• Brown PJ, Billington KJ, Bumstead JM, Clark JD, Tomley FM
• A microneme protein from Eimeria tenella with homology to the Apple domains of coagulation factor XI and plasma pre-kallikrein.
• Mol Biochem Parasitol. 2000; 107: 91-102
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• Microneme organelles are present in all apicomplexan protozoa and contain proteins that are critical for parasite motility and host cell invasion. One apicomplexan-wide family of microneme proteins has been identified with members that are characterised by the possession of thrombospondin type I repeats, conserved adhesive motifs which are implicated in binding to glycosaminoglycan chains. In this paper we describe a micronemal glycoprotein, EtMIC 5, from Eimeria tenella which contains eleven cysteine-rich motifs that have striking similarity to the adhesive Apple (A-) domains of blood coagulation factor XI and plasma pre-kallikrein. EtMIC 5 is confined to an intracellular location in resting sporozoites but is translocated to the parasite surface and secreted into the culture supernatant during parasite infection of MDBK cells. During intracellular replication, the protein is switched off in early schizogony and is then re-expressed within the apical tips of newly formed merozoites. A-domain sequences were also found in microneme proteins from Sarcocystis muris and Toxoplasma gondii and in a protein of unknown localisation from Eimeria acervulina. These studies suggest that A-domain containing proteins may comprise a novel apicomplexan-wide family of microneme adhesins.

• Ho DH, Baglia FA, Walsh PN
• Factor XI binding to activated platelets is mediated by residues R(250), K(255), F(260), and Q(263) within the apple 3 domain.
• Biochemistry. 2000; 39: 316-23
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• To localize the platelet binding site on factor XI, rationally designed, conformationally constrained synthetic peptides were used to compete with [(125)I]factor XI binding to activated platelets. The major platelet binding energy resided within the sequence of amino acids T(249)-F(260). Homology scanning, using prekallikrein amino acid substitutions within the synthetic peptide T(249)-F(260), identified a major role for R(250) in platelet binding. Inhibition of [(125)I]factor XI binding to activated platelets by the recombinant Apple 3 domain of factor XI and inhibition by unlabeled factor XI were identical, whereas the recombinant Apple 3 domain of prekallikrein had little effect. A "gain-of-function" chimera in which the C-terminal amino acid sequence of the Apple 3 domain of prekallikrein was replaced with that of factor XI was as effective as the recombinant Apple 3 domain of factor XI and unlabeled factor XI in inhibiting [(125)I]factor XI binding to activated platelets. Alanine scanning mutagenic analysis of the recombinant Apple 3 domain of factor XI indicated that amino acids R(250), K(255), F(260), and Q(263) (but not K(252) or K(253)) are important for platelet binding. Thus, the binding energy mediating the interaction of factor XI with platelets is contained within the C-terminal amino acid sequence of the Apple 3 domain (T(249)-V(271)) and is mediated in part by amino acid residues R(250), K(255), F(260), and Q(263).

• Bouma BN, Meijers JC
• Role of blood coagulation factor XI in downregulation of fibrinolysis.
• Curr Opin Hematol. 2000; 7: 266-72
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• Factor XI is a component of the intrinsic pathway of coagulation. A deficiency of factor XI is associated with a mild to moderate bleeding disorder especially from tissues with a high local fibrinolytic activity. In contrast, high levels of factor XI are a risk factor for venous thrombosis. The recent finding that factor XI can be activated by thrombin led to a revised model of coagulation. In this model the primary thrombin generation that results in fibrin formation takes place via the extrinsic pathway. Additional thrombin generation takes place inside the fibrin clot via the intrinsic pathway after the activation of factor XI by thrombin. High concentrations of thrombin are formed that are necessary for the activation of thrombin activatable fibrinolysis inhibitor (TAFI). Activated TAFI protects the fibrin clot against lysis. The role of factor XI in hemostasis can therefore be seen as a combination of procoagulant and antifibrinolytic actions. The new insights in the role of factor XI in coagulation and fibrinolysis may lead to new strategies for the treatment of thrombotic disorders.

• Meijers JC, Tekelenburg WL, Bouma BN, Bertina RM, Rosendaal FR
• High levels of coagulation factor XI as a risk factor for venous thrombosis.
• N Engl J Med. 2000; 342: 696-701
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• BACKGROUND: Factor XI, a component of the intrinsic pathway of coagulation, contributes to the generation of thrombin, which is involved in both the formation of fibrin and protection against fibrinolysis. A deficiency of factor XI is associated with bleeding, but a role of high factor XI levels in thrombosis has not been investigated. METHODS: We determined factor XI antigen levels in the patients enrolled in the Leiden Thrombophilia Study, a large population-based, case-control study (with a total of 474 patients and 474 controls) designed to estimate the contributions of genetic and acquired factors to the risk of deep venous thrombosis. Odds ratios were calculated as a measure of relative risk. RESULTS: The age- and sex-adjusted odds ratio for deep venous thrombosis in subjects who had factor XI levels above the 90th percentile, as compared with those who had factor XI levels at or below that value, was 2.2 (95 percent confidence interval, 1.5 to 3.2). There was a dose-response relation between the factor XI level and the risk of venous thrombosis. Adjustment of the odds ratios for other risk factors such as oral-contraceptive use, homocysteine, fibrinogen, factor VIII, female sex, and older age did not alter the result. Also, when we excluded subjects who had known genetic risk factors for thrombosis (e.g., protein C or S deficiency, antithrombin deficiency, the factor V Leiden mutation, or the prothrombin G20210A mutation), the odds ratio remained the same, indicating that the risk of venous thrombosis associated with elevated levels of factor XI was not the result of one of the known risk factors for thrombosis. CONCLUSIONS: High levels of factor XI are a risk factor for deep venous thrombosis, with a doubling of the risk at levels that are present in 10 percent of the population.

• Baglia FA, Badellino KO, Ho DH, Dasari VR, Walsh PN
• A binding site for the kringle II domain of prothrombin in the apple 1 domain of factor XI.
• J Biol Chem. 2000; 275: 31954-62
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• Previously we defined binding sites for high molecular weight kininogen (HK) and thrombin in the Apple 1 (A1) domain of factor XI (FXI). Since prothrombin (and Ca(2+)) can bind FXI and can substitute for HK (and Zn(2+)) as a cofactor for FXI binding to platelets, we have attempted to identify a prothrombin-binding site in FXI. The recombinant A1 domain (rA1, Glu(1)-Ser(90)) inhibited the saturable, specific and reversible binding of prothrombin to FXI, whereas neither the rA2 domain (Ser(90)-Ala(181)), rA3 domain (Ala(181)-Val(271)), nor rA4 domain (Phe(272)-Glu(361)) inhibited prothrombin binding to FXI. Kinetic binding studies using surface plasmon resonance showed binding of FXI (K(d) approximately 71 nm) and the rA1 domain (K(d) approximately 239 nm) but not rA2, rA3, or rA4 to immobilized prothrombin. Reciprocal binding studies revealed that synthetic peptides (encompassing residues Ala(45)-Ser(86)) containing both HK- and thrombin-binding sites, inhibit (125)I-rA1 (Glu(1)-Ser(90)) binding to prothrombin, (125)I-prothrombin binding to FXI, and (125)I-prothrombin fragment 2 (Ser(156)-Arg(271)) binding to FXI. However, homologous prekallikrein-derived peptides (encompassing Pro(45)-Gly(86)) did not inhibit FXI rA1 binding to prothrombin. The peptides Ala(45)-Arg(54), Phe(56)-Val(71), and Asp(72)-Ser(86), derived from sequences of the A1 domain of FXI, acted synergistically to inhibit (125)I-rA1 binding to prothrombin. Mutant rA1 peptides (V64A and I77A), which did not inhibit FXI binding to HK, retained full capacity to inhibit rA1 domain binding to prothrombin, and mutant rA1 peptides Ala(45)-Ala(54) (D51A) and Val(59)-Arg(70) (E66A), which did not inhibit FXI binding to thrombin, retained full capacity to inhibit rA1 domain binding to prothrombin. Thus, these experiments demonstrate that a prothrombin binding site exists in the A1 domain of FXI spanning residues Ala(45)-Ser(86) that is contiguous with but separate and distinct from the HK- and thrombin-binding sites and that this interaction occurs through the kringle II domain of prothrombin.

• Baglia FA, Walsh PN
• Thrombin-mediated feedback activation of factor XI on the activated platelet surface is preferred over contact activation by factor XIIa or factor XIa.
• J Biol Chem. 2000; 275: 20514-9
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• To study the pathways for initiation of intrinsic blood coagulation, activated human platelets were compared with dextran sulfate as surfaces for factor XI activation by factor XIIa, factor XIa, or thrombin. Activated gel-filtered platelets promoted the activation of factor XI (60 nm) by thrombin (0.02-10 nm, EC(50) approximately 100 pm, threshold concentration approximately 10 pm) at initial rates 2- to 3-fold greater than those obtained with dextran sulfate in the presence of either high molecular weight kininogen (45 nm) and ZnCl(2) (25 micrometer) or prothrombin (1.2 micrometer) and CaCl(2) (2 mm). The maximum rates of factor XI activation achieved in the presence of activated gel-filtered platelets were 30 nm.min(-1) with thrombin, 6 nm.min(-1) with factor XIIa and 2 nm.min(-1) with factor XIa. Values of turnover number calculated at various enzyme concentrations (0.05-1 nm) were 24-167 (mean = 86) min(-1) for thrombin, 4.6-50 (mean = 21) min(-1) for factor XIIa, and 1.3-14 (mean = 8) min(-1) for factor XIa. A physiological concentration of fibrinogen (9.0 micrometer) inhibited factor XI activation by thrombin (but not by factor XIIa) in the presence of dextran sulfate but not in the presence of gel-filtered platelets. Compared with factors XIIa and XIa, thrombin is the preferred factor XI activator, and activated platelets are a relevant physiological surface for thrombin-mediated initiation of intrinsic coagulation in vivo.

• Ho DH et al.
• The role of high molecular weight kininogen and prothrombin as cofactors in the binding of factor XI A3 domain to the platelet surface.
• J Biol Chem. 2000; 275: 25139-45
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• We have reported that prothrombin (1 microm) is able to replace high molecular weight kininogen (45 nm) as a cofactor for the specific binding of factor XI to the platelet (Baglia, F. A., and Walsh, P. N. (1998) Biochemistry 37, 2271-2281). We have also determined that prothrombin fragment 2 binds to the Apple 1 domain of factor XI at or near the site where high molecular weight kininogen binds. A region of 31 amino acids derived from high molecular weight kininogen (HK31-mer) can also bind to factor XI (Tait, J. F., and Fujikawa, K. (1987) J. Biol. Chem. 262, 11651-11656). We therefore investigated the role of prothrombin fragment 2 and HK31-mer as cofactors in the binding of factor XI to activated platelets. Our experiments demonstrated that prothrombin fragment 2 (1 microm) or the HK31-mer (8 microm) are able to replace high molecular weight kininogen (45 nm) or prothrombin (1 &mgr;m) as cofactors for the binding of factor XI to the platelet. To localize the platelet binding site on factor XI, we used mutant full-length recombinant factor XI molecules in which the platelet binding site in the Apple 3 domain was altered by alanine scanning mutagenesis. The recombinant factor XI with alanine substitutions at positions Ser(248), Arg(250), Lys(255), Leu(257), Phe(260), or Gln(263) were defective in their ability to bind to activated platelets. Thus, the interaction of factor XI with platelets is mediated by the amino acid residues Ser(248), Arg(250), Lys(255), Leu(257), Phe(260), and Gln(263) within the Apple 3 domain.

• Shirk RA, Konkle BA, Walsh PN
• Nonsense mutation in exon V of the factor XI gene does not abolish platelet factor XI expression.
• Br J Haematol. 2000; 111: 91-5
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• Factor XI (FXI) is a plasma glycoprotein produced by the liver that plays an essential role in blood coagulation. Individuals deficient in this protein are prone to bleeding following trauma or surgery. Well-washed platelets possess FXI-like activity and FXI antigen that differs in molecular weight from plasma FXI and is associated with FXI mRNA from platelets in which exon V is absent. Some individuals deficient in plasma FXI produce the platelet form of the protein. The molecular basis for the presence of platelet FXI in plasma FXI-deficient patients is unknown. In the current study, to help determine the mechanism for this differential expression, the FXI genotype was determined for three plasma FXI-deficient individuals who express platelet FXI. All three individuals had a nonsense mutation encoding a stop codon in exon V of the FXI gene that would result in a severely truncated polypeptide. An exon V nonsense mutation in the FXI gene combined with the absence of exon V in platelet FXI mRNA provides a plausible mechanism for the differential expression of platelet FXI in plasma FXI-deficient patients.

• Ekdahl KN, Elgue G, Nilsson B
• Phosphorylation of coagulation factor XI by a casein kinase released by activated human platelets increases its susceptibility to activation by factor XIIa and thrombin.
• Thromb Haemost. 1999; 82: 1283-8
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• Previous studies suggest that activated platelets facilitate the cleavage of factor XI by both factor XIIa and thrombin. Extracellular phosphorylation is a mechanism by which the function of plasma proteins can be regulated. Phosphorylation is mediated by a casein kinase which is released by activated platelets concomitant with large amounts of ATP and Ca2+. The purpose of this study was to investigate if factor XI is phosphorylated by a platelet casein kinase and whether phosphorylation may affect its activation properties. It was shown that supernatants from platelets which contain platelet casein kinase phosphorylated factor XI. By Western blot analysis it was shown that phosphorylation of factor XI substantially increased its susceptibility to cleavage by factor XIIa, and, to a lesser extent, by thrombin. The generated factor XIa was functionally active in that it cleaved the chromogenic substrate S2366, and in that factor XIa-antithrombin and thrombin-antithrombin complexes were generated when phosphorylated factor XI was added to blood plasma. The present study indicates that platelet-mediated phosphorylation of factor XI enhances the cleavage of factor XI into XIa and that the generated XIa possesses functional activity. Phosphorylation of factor XI might be an essential regulatory mechanism by which platelets mediate amplification of the coagulation cascade.

• Mitropoulos KA
• The levels of factor XIIa generated in human plasma on an electronegative surfaceare insensitive to wide variation in the concentration of FXII, prekallikrein,high molecular weight kininogen or FXI.
• Thromb Haemost. 1999; 82: 1033-40
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• The contribution of the various components of the contact system in the generation of factor XIIa (FXIIa) and of kallikrein (KRN) on an electronegative surface and the release of the generated enzymes to the bulk phase was examined in mixtures of normal human plasma and plasmas congenitally deficient in these components. The incubation of normal human plasma in the presence of sulphatide vesicles (40 microM) resulted in a fast generation of amidolytic activities due to FXIIa and to KRN followed by slower first-order inactivation rates of FXIIa (k'FXIIa) and of KRN (k'KRN) due to the presence of esterase inhibitors. Variation of the levels of factor XII (FXII), over a wide range, showed little effect on levels of FXIIa and of KRN but no activities were detected in 100% FXII-deficient plasma. The variation of prekallikrein (PKRN) concentration showed little effect on the generation of FXIIa but the generation of KRN declined linearly with the decrease in the level of PKRN. No activities were detected on treatment of PKRN-deficient plasma. The variation in the concentration of high molecular weight kininogen (HK) showed effects on FXIIa and KRN that were qualitatively similar to those seen on variation of PKRN but 100% HK-deficient plasma generated considerable activities of both FXIIa and KRN. The variation in the concentration of factor XI (FXI) showed no effect on the generation of FXIIa, whereas KRN levels increased linearly with the contribution of FXI-deficient in normal plasma. The present results suggest that the contiguous binding of FXIIa, FXII, PKRN-HK and FXI-HK onto the electronegative surface induces a rapid generation of FXIIa and KRN. The bound PKRN-HK complex prevents the release of generated FXIIa and therefore further binding and activation of FXII from the bulk phase. Consequently, the turnover of FXII is independent of its levels in the bulk phase and is rather related to the concentration of contact surface. The generated KRN is also protected by HK. However, since the enzyme responsible for the activation of PKRN-HK is FXIIa, the levels of generated KRN are positively related to the concentration of substrate.

• Renne T, Dedio J, Meijers JC, Chung D, Muller-Esterl W
• Mapping of the discontinuous H-kininogen binding site of plasma prekallikrein. Evidence for a critical role of apple domain-2.
• J Biol Chem. 1999; 274: 25777-84
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• Plasma prekallikrein, a zymogen of the contact phase system, circulates in plasma as heterodimeric complex with H-kininogen. The binding is mediated by the prekallikrein heavy chain consisting of four apple domains, A1 to A4, to which H-kininogen binds with high specificity and affinity (K(D) = 1.2 x 10(-8) M). Previous work had demonstrated that a discontinuous kininogen-binding site is formed by a proximal part located in A1, a distal part exposed by A4, and other yet unidentified portion(s) of the kallikrein heavy chain. To detect relevant binding segment(s) we recombinantly expressed single apple domains and found a rank order of binding affinity for kininogen of A2 > A4 approximately A1 > A3. Removal of single apple domains in prekallikrein deletion mutants reduced kininogen binding by 21 (A1), 64 (A2), and 24% (A4), respectively, whereas deletion of A3 was without effect. Transposition of homologous A2 domain from prekallikrein to factor XI conferred high-affinity kininogen binding from the former to the latter. The principal role of A2 for H-kininogen docking to the prekallikrein heavy chain was further substantiated by the finding that cleavage of a single peptide bond in A2 drastically diminished the H-kininogen binding affinity. Furthermore, the epitope of monoclonal antibody PKH6 which blocks kallikrein-kininogen complex formation with an IC(50) of 8 nM mapped to the center portion of domain A2. Our data indicate that domain A2 and two flanking sequence segments of A1 and A4 form a discontinuous binding platform for H-kininogen on the prekallikrein heavy chain. Domain-specific antibodies directed to these critical sites efficiently interfered with contact phase-induced bradykinin release from H-kininogen.

• Minnema MC, Ten Cate H, Hack CE
• The role of factor XI in coagulation: a matter of revision.
• Semin Thromb Hemost. 1999; 25: 419-28
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• In 1991 it was demonstrated that, besides factor XII, thrombin is capable of activating factor XI in vitro. Thrombin-dependent activation of factor XI is an integral part of the revised theoretical model of coagulation in which coagulation is initiated by the extrinsic pathway and maintained by thrombin-induced activation of clotting factors V, VIII, and XI. In this review, special interest is given to the new role of factor XI in coagulation, with emphasise on data supporting the concept of thrombin-mediated factor XI activation in vivo. Furthermore, activation of factor XI in human disease, especially atherosclerotic disease, measured by newly developed immunologic assays, is discussed. The relation of factor XI to fibrinolysis through activation of the carboxypeptidase, thrombin-activatable fibrinolysis inhibitor (TAFI) by thrombin provides an explanation for the bleeding tendency observed in factor XI-deficient patients. The probable link with factor XI-mediated TAFI activation may have clinical and therapeutic consequences and deserves further study.

• Bouma BN, Meijers JC
• Fibrinolysis and the contact system: a role for factor XI in the down-regulation of fibrinolysis.
• Thromb Haemost. 1999; 82: 243-50

• Walsh PN
• Platelets and factor XI bypass the contact system of blood coagulation.
• Thromb Haemost. 1999; 82: 234-42

• Bouma BN, Mosnier LO, Meijers JC, Griffin JH
• Factor XI dependent and independent activation of thrombin activatable fibrinolysis inhibitor (TAFI) in plasma associated with clot formation.
• Thromb Haemost. 1999; 82: 1703-8
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• Thrombin Activatable Fibrinolysis Inhibitor (TAFI) also known as plasma procarboxypeptidase B is activated by relatively high concentrations of thrombin in a reaction stimulated by thrombomodulin. In plasma an intact factor XI-dependent feed back loop via the intrinsic pathway is necessary to generate sufficient thrombin for TAFI activation. This thrombin generation takes place after clot formation with consequent down-regulation of fibrinolysis. We developed a specific and sensitive assay for activated TAFI (TAFIa) and studied its factor XI-dependent generation during clot formation. In the absence of thrombomodulin, addition of 20 nM thrombin to normal plasma generated 5-10% of the amount of TAFIa generated by 20 nM thrombin in the presence of 8 nM thrombomodulin. Minimal activation of TAFI was detected in factor II deficient plasma when clotting was initiated by 20 nM thrombin. Addition of 320-640 nM of thrombin to factor II deficient plasma resulted in the same amount of TAFIa as in normal plasma, suggesting that approximately 50% of factor II has to be converted to thrombin for extensive activation of TAFI. A Mab that neutralizes activated factor XII had no effect on TAFI activation indicating that an intact contact system is not necessary for the activation of TAFI. The dependency of TAFI activation of factor XI was tested using a Mab that neutralizes activated factor XI. When plasmas from 13 healthy individuals were tested, this Mab reduced TAFI activation by 65% (range 35-89%). Our results indicate that activation of TAFI in serum after clot formation can be quantitated and that it takes place in both factor XI-dependent and factor XI-independent mechanisms.

• Sun MF, Zhao M, Gailani D
• Identification of amino acids in the factor XI apple 3 domain required for activation of factor IX.
• J Biol Chem. 1999; 274: 36373-8
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• Activated coagulation factor XI (factor XIa) proteolytically cleaves its substrate, factor IX, in an interaction requiring the factor XI A3 domain (Sun, Y., and Gailani, D. (1996) J. Biol. Chem. 271, 29023-29028). To identify key amino acids involved in factor IX activation, recombinant factor XIa proteins containing alanine substitutions for wild-type sequence were expressed in 293 fibroblasts and tested in a plasma clotting assay. Substitutions for Ile(183)-Val(191) and Ser(195)-Ile(197) at the N terminus and for Ser(258)-Ser(264) at the C terminus of the A3 domain markedly decreased factor XI coagulant activity. The plasma protease prekallikrein is structurally homologous to factor XI, but activated factor IX poorly. A chimeric factor XIa molecule with the A3 domain replaced with A3 from prekallikrein (FXI/PKA3) activated factor IX with a K(m) 35-fold greater than that of wild-type factor XI. FXI/PKA3 was used as a template for a series of proteins in which prekallikrein A3 sequence was replaced with factor XI sequence to restore factor IX activation. Clotting and kinetics studies using these chimeras confirmed the results obtained with alanine mutants. Amino acids between Ile(183) and Val(191) are necessary for proper factor IX activation, but additional sequence between Ser(195) and Ile(197) or between Phe(260) and Ser(265) is required for complete restoration of activation.

• Robinson JL et al.
• Characterization of the 3' end of the gene for bovine factor XI.
• J Dairy Sci. 1998; 81: 539-43

• Ho DH, Badellino K, Baglia FA, Walsh PN
• A binding site for heparin in the apple 3 domain of factor XI.
• J Biol Chem. 1998; 273: 16382-90
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• Since heparin potentiates activated factor XI (FXIa) inhibition by protease nexin-2 by providing a template to which both proteins bind (Zhang, Y., Scandura, J. M., Van Nostrand, W. E., and Walsh, P. N. (1997) J. Biol. Chem. 272, 26139-26144), we examined binding of factor XI (FXI) and FXIa to heparin. FXIa binds to heparin (Kd approximately 0.7 x 10(-9) M) >150-fold more tightly than FXI (Kd approximately 1.1 x 10(-7) M). To localize the heparin-binding site on FXI, rationally designed conformationally constrained synthetic peptides were used to compete with 125I-FXI binding to heparin. A peptide derived from the Apple 3 (A3) domain of FXI (Asn235-Arg266) inhibited FXI binding to heparin (Kd approximately 3.4 x 10(-6) M), whereas peptides from the A1 domain (Phe56-Ser86), A2 domain (Ala134-Ala176), and A4 domain (Ala317-Gly350) had no such effect. The recombinant A3 domain (rA3, Ala181-Val271) inhibited FXI binding to heparin (Ki approximately 1.4 x 10(-7) M) indicating that all the information necessary for FXI binding to heparin is contained entirely within the A3 domain. The A3 domain also contains a platelet-binding site (Asn235-Arg266), consisting of three surface-exposed loop structures, Pro229-Gln233, Thr741-Leu246, and Thr249-Phe260 (Baglia, F. A., Jameson, B. A., and Walsh, P. N. (1995) J. Biol. Chem. 270, 6734-6740). Only peptide Thr249-Phe260 (which contains a heparin binding consensus sequence, RIKKSKA) inhibits FXI binding to heparin (Ki = 2.1 x 10(-7) M), whereas peptides Pro229-Gln233 and Thr241- Leu246 had no effect. Fine mapping of the heparin-binding site using prekallikrein analogue amino acid substitutions of the synthetic peptide Thr249-Phe260 and alanine scanning of the recombinant A3 indicated that the amino acids Lys252 and Lys253 are important for heparin binding. Thus, the sequence Thr249-Phe260 which contains most of the binding energy for FXI interaction with platelets also mediates the binding of FXI to heparin.

• Bouma BN, von dem Borne PA, Meijers JC
• Factor XI and protection of the fibrin clot against lysis--a role for the intrinsic pathway of coagulation in fibrinolysis.
• Thromb Haemost. 1998; 80: 24-7

• Ahmad SS, Wong MY, Rawala R, Jameson BA, Walsh PN
• Coagulation factor IX residues G4-Q11 mediate its interaction with a shared factor IX/IXa binding site on activated platelets but not the assembly of the functional factor X activating complex.
• Biochemistry. 1998; 37: 1671-9
• Display abstract

• High-affinity, specific factor IX/IXa binding to platelets is mediated at least in part by amino acids (G4-Q11) exposed on the surface of the gamma-carboxyglutamic acid (Gla) domain. Rationally designed, conformationally constrained synthetic peptides were screened for their capacity to inhibit factor IXa binding to platelets. Each of these peptides (G4-Q11, S3-L6, and F9-Q11) acted alone to inhibit factor IXa binding to approximately 50% of the 500-600 sites/platelet with Ki values of 2.9 nM (G4-Q11), 24 nM (S3-L6), and 240 nM (F9-Q11), compared with native factor IXa (Ki approximately 2.5 nM). The two peptides S3-L6 and F9-Q11 added together at equimolar concentration demonstrated approximately 50-fold synergism (Ki = 2.4 nM). Although both factor IX and the Gla peptide (G4-Q11) displaced 100% of bound factor IX and approximately 50% of bound factor IXa, factor IX was ineffective (at > 1000-fold molar excess) and the Gla domain peptide (G4-Q11) was relatively ineffective (Ki = 165 microM) in inhibiting platelet receptor-mediated factor X activation by factor IXa. We conclude that the Gla domain (G4-Q11) of factor IXa contains two conformationally constrained loop structures that mediate binding of factor IX/IXa to a shared site on activated human platelets which is separate and distinct from the site used by the enzyme, factor IXa, for assembly of the factor X activating complex.

• Hu CJ, Baglia FA, Mills DC, Konkle BA, Walsh PN
• Tissue-specific expression of functional platelet factor XI is independent of plasma factor XI expression.
• Blood. 1998; 91: 3800-7
• Display abstract

• Platelet factor XI is an alternatively spliced product of the factor XI gene expressed specifically within megakaryocytes and platelets as an approximately 1.9-kb mRNA transcript (compared with approximately 2.1 kb in liver cells) lacking exon V. Flow cytometry with an affinity-purified factor XI antibody, with PAC1 antibody (to the GPIIb/IIIa complex on activated platelets), and with S12 antibody (to P-selectin, an alpha-granule membrane protein expressed on the platelet surface during secretion) on platelets activated with ADP, thrombin, thrombin receptor peptide (SFLLRN amide), or collagen at various concentrations exposed platelet factor XI and PAC1 antibody binding in parallel. Unactivated platelets expressed approximately 40% of total platelet factor XI but no PAC1 binding sites. Enhanced membrane exposure of platelet factor XI is independent of alpha-granule secretion, because ADP and collagen exposed platelet factor XI but no S12 binding sites. Platelets from four patients with plasma factor XI deficiency (<0.04 U/mL) had normal constitutive and activation-dependent expression of platelet factor XI. Well-washed platelets from normal and from factor XI-deficient donors incubated with low concentrations of thrombin (0. 05 to 0.1 U/mL) corrected the clotting defect observed with factor XI-deficient plasma. Thus, functionally active platelet factor XI is differentially expressed on platelet membranes in a tissue-specific manner both constitutively and in a concentration-dependent fashion by various agonists in the absence of detectable plasma factor XI.

• Baglia FA, Walsh PN
• Prothrombin is a cofactor for the binding of factor XI to the platelet surface and for platelet-mediated factor XI activation by thrombin.
• Biochemistry. 1998; 37: 2271-81
• Display abstract

• To study the physiological significance of thrombin as an initiator of intrinsic blood coagulation, activated human platelets were compared with dextran sulfate as a surface for thrombin-catalyzed factor XI activation. Activated gel-filtered platelets promoted factor XI activation by thrombin at initial rates 2-5-fold greater than dextran sulfate in the presence of high molecular weight kininogen (HK, 45 nM), ZnCl2 (25 microM), and CaCl2 (2 mM), conditions optimal for factor XI binding to platelets. Physiological concentrations of HK (636 nM) inhibited factor XI activation by thrombin in a concentration-dependent manner, and this inhibition was reversed by prothrombin (1-3 microM) and by prothrombin fragment 1.2 (PF1.2), but not by prothrombin fragment 1 (PF1). Since prothrombin and PF1.2 (but not PF1) also displaced HK from its binding site on the Apple 1 domain of factor XI, we conclude that the Kringle II domain of prothrombin competes with HK for binding to the Apple 1 domain of factor XI. Prothrombin (1-3 microM) and PF1.2 (but not PF1) in the presence of CaCl2 (2 mM) were able to replace HK (45 nM) in the presence of ZnCl2 (25 microM) as a cofactor for the specific, reversible, high-affinity (Kd approximately 25 nM) binding of factor XI to 947 +/- 150 sites per platelet. This binding is mediated by residues Asn 235-Arg 266 in the Apple 3 domain since a conformationally constrained, synthetic peptide analogue of this sequence inhibits both factor XI binding to activated platelets and platelet-mediated, thrombin-catalyzed factor XI activation in the presence of prothrombin and CaCl2. Finally, prothrombin (1.2 microM) and CaCl2 (2 mM) could substitute for HK (45 nM) and ZnCl2 (25 microM) in promoting optimal rates of thrombin-catalyzed factor XI activation on the platelet surface, thereby initiating the intrinsic coagulation pathway by mechanisms completely independent of the contact phase proteins, factor XII, HK, and prekallikrein.

• Heidtmann HH, Kontermann RE
• Cloning and recombinant expression of mouse coagulation factor X.
• Thromb Res. 1998; 92: 33-41
• Display abstract

• Engineering of recombinant coagulation factor X variants, which can be activated by tumor-associated proteinases may lead to the development of new therapeutic molecules. However, the evaluation of such variants requires an appropriate animal model. Therefore, we isolated the complete coding sequence of mouse coagulation factor X from mouse liver cDNA by polymerase chain reaction. The deduced amino acid sequence codes for a prepro protein of 481 amino acids homologous to factor X sequences from various species. Recombinant mouse factor X was expressed in human embryonic kidney cells and secreted into cell culture supernatant as zymogen, which could be converted to catalytically active factor Xa by Russell's viper venom. Purified recombinant mouse factor X restored coagulation in human factor X deficient plasma, demonstrating that mouse factor X is able to functionally interact with the human blood coagulation system. Recombinant mouse factor X opens the possibility to analyze therapeutically useful variants in the mouse system.

• Hsu TC, Shore SK, Seshsmma T, Bagasra O, Walsh PN
• Molecular cloning of platelet factor XI, an alternative splicing product of the plasma factor XI gene.
• J Biol Chem. 1998; 273: 13787-93
• Display abstract

• Platelet factor XI is associated with the platelet plasma membrane and has an apparent Mr (220,000 nonreduced, 55,000 reduced) different from that of plasma factor XI. However, the site of synthesis and the nature of platelet factor XI are not known. Using reverse transcriptase polymerase chain reaction, 12 out of 13 exons (all except exon V) coding for mature plasma factor XI were amplified from human platelet mRNA. The sequence of each of these exons was identical to that of plasma factor XI. In situ amplification and hybridization of factor XI mRNA was positive for exon III and negative for exon V in platelets and negative for both exons in other blood cells. By Northern hybridization, a factor XI mRNA transcript of approximately 1.9 kilobases was detected in megakaryocytic cells, and one of approximately 2.1 kilobases was detected in liver cells. Factor XI cDNA was cloned from a megakaryocyte library and sequenced. Exon V was absent, and the splicing of exon IV to exon VI maintained the open reading frame without alteration of the amino acid sequence except for the deletion of amino acids Ala91-Arg144 within the amino-terminal portion of the Apple 2 domain. Thus, platelet factor XI is an alternative splicing product of the factor XI gene, localized to platelets and megakaryocytes but absent from other blood cells.

• Richards EM, Makris MM, Cooper P, Preston FE
• In vivo coagulation activation following infusion of highly purified factor XI concentrate.
• Br J Haematol. 1997; 96: 293-7
• Display abstract

• The use of factor XI concentrates has been associated with thrombosis. Plasma markers of coagulation activation were measured before and 30, 60, 120 and 240 min after six infusions of the BPL factor XI concentrate. Five studies were completed before surgical intervention, one was undertaken in a patient with an intracerebral haemorrhage. Significant elevation of levels of fibrinopeptide A (FpA) (P < 0.05) and thrombin-antithrombin (TAT) were demonstrated following six infusions and prothrombin fragment F1.2 following four. Levels of all three markers had risen 60 min following concentrate administration and FpA levels remained elevated throughout the study period. Levels of D-dimer rose in four patients at 240 min. These results indicate significant thrombin generation by 60 min and subsequent plasmin generation consistent with coagulation activation by the factor XI concentrate. The greatest elevation of activation markers was seen in those subjects with pre-existing coagulation activation. We advise caution in the use of these products and awareness of the risks in patients who may already have activated coagulation states.

• Gailani D, Sun MF, Sun Y
• A comparison of murine and human factor XI.
• Blood. 1997; 90: 1055-64
• Display abstract

• Factor XI is a plasma glycoprotein that is required for contact activation initiated fibrin formation in vitro and for normal hemostasis in vivo. In preparation for developing a mouse model of factor XI deficiency to facilitate investigations into this protease's contributions to coagulation, we cloned the complementary DNA for murine factor XI, expressed the protein in a mammalian expression system, and compared its properties with human recombinant factor XI. The 2.8-kb murine cDNA codes for a protein of 624 amino acids with 78% homology to human factor XI. Both recombinant murine and human factor XI are 160 kD homodimers comprised of two 80 kD polypeptides connected by disulfide bonds. Murine factor XI shortens the clotting time of human factor XI deficient plasma in an activated partial thromboplastin time assay, with a specific activity 50% to 70% that of the human protein. In a purified system, murine factor XI is activated by human factor XIIa and thrombin in the presence of dextran sulfate. Murine factor XI differs from human factor XI in that it undergoes autoactivation slowly in the presence of dextran sulfate. This is due primarily to murine factor XIa preferentially cleaving a site on zymogen factor XI within the light chain, rather than the activation site between Arg371 and Val372. Northern blots of polyadenylated messenger RNA show that murine factor XI message is expressed, as expected, primarily in the liver. In contrast, messenger RNA for human factor XI was identified in liver, pancreas, and kidney. The studies show that murine and human factor XI have similar structural and enzymatic properties. However, there may be variations in tissue specific expression and subtle differences in enzyme activity across species.

• von dem Borne PA, Meijers JC, Bouma BN
• Effect of heparin on the activation of factor XI by fibrin-bound thrombin.
• Thromb Haemost. 1996; 76: 347-53
• Display abstract

• Fibrin-bound thrombin is protected from inactivation by antithrombin III, while its coagulant potential is retained. In the presence of heparin, ternary complexes between thrombin, fibrin and heparin are formed. In these complexes the coagulant activity of thrombin is retained, whereas the anticoagulant activity of fibrin-bound heparin is neutralized. The limited effectiveness of heparin in the prevention of both venous thrombosis and coronary reocclusion is probably related to the protective effect of fibrin on the inactivation of thrombin by anti-thrombin III. Recently, it has been shown that factor XI can be activated by thrombin, resulting in the generation of additional thrombin via the intrinsic pathway. This additional thrombin is capable of stabilizing the clot by protecting it from fibrinolysis. We studied the effect of heparin on the activation of factor XI by fibrin-bound thrombin. First, we used fibrin monomers coupled to Sepharose to which thrombin and unfractionated heparin (UFH) were bound. Factor XI activation by thrombin was the same in the presence of fibrin-Sepharose or control-Sepharose. The addition of heparin (0.1 U/ml) resulted in a 91 and 15-fold enhancement in the presence of control-Sepharose and fibrin-Sepharose, respectively. Next, we added complexes of heparin, thrombin and fibrin monomer to factor XII and XI double-deficient plasma in the presence or absence of a reconstituting amount of factor XI. In the presence of factor XI, additional fibrin formation was observed indicating that factor XI activation by thrombin in complex with fibrin and heparin can take place in plasma. We then studied the effect of other heparin-like anticoagulants on the thrombin-mediated factor XI activation. UFH enhanced thrombin-mediated factor XI activation 68-fold, LMWH (low molecular weight heparin, Fragmin) 12-fold, danaparoid (Orgaran) 3-fold, while the pentasaccharide ORG 31540 did not result in an enhancement. Binding studies of these anticoagulants to fibrin-Sepharose showed that LMWH bound with approximately the same affinity as UFH, while danaparoid and the pentasaccharide did not bind to fibrin. We conclude that fibrin-bound thrombin is capable of factor XI activation. Furthermore, heparin bound in a complex with fibrin can act as a cofactor for this activation. This factor XI activation capacity may play a role in the limited effectiveness of heparin. Provided that thrombin-mediated factor XI activation plays an important role in vivo, danaparoid and especially the pentasaccharide may be better anticoagulants than UFH and LMWH.

• Obraztsov IF, Popov AF, Khanin MA
• [Kinetics of activation of internal pathway of blood coagulation: the threshold effect]
• Dokl Akad Nauk. 1996; 349: 560-1

• Colman RW, Scott CF
• When and where is factor XI activated by thrombin?
• Blood. 1996; 87: 2089-2089

• Peretz H, Zivelin A, Usher S, Seligsohn U
• A 14-bp deletion (codon 554 del AAGgtaacagagtg) at exon 14/intron N junction of the coagulation factor XI gene disrupts splicing and causes severe factor XI deficiency.
• Hum Mutat. 1996; 8: 77-8

• Baglia FA, Walsh PN
• A binding site for thrombin in the apple 1 domain of factor XI.
• J Biol Chem. 1996; 271: 3652-8
• Display abstract

• Previously we defined a binding site for high molecular weight kininogen (HK) in the A1 domain of factor XI (FXI). Since thrombin can activate FXI and HK inhibits the activation of FXI by thrombin, we have identified a thrombin binding site in FXI. Both the recombinant A1 domain (Glu1-Ser90) and a synthetic peptide (Phe56-Ser86) containing the HK binding site inhibited FXI activation by thrombin. Both a monoclonal antibody, 5F7, recognizing the A1 domain, and the rA1 domain were shown to be competitive inhibitors of thrombin-catalyzed FXI activation. The peptides Ala45-Arg54 and Val59-Arg70 acted synergistically to inhibit FXI activation by thrombin. Mutant rA1 domain constructs (Val64 --> Ala and Ile77 --> Ala), which do not inhibit FXI binding to HK, retain full capacity to inhibit FXI activation by thrombin. The peptide Ala45-Arg54 inhibited thrombin-catalyzed FXI activation, whereas it had no effect on FXI binding to HK. In contrast, the peptide Asn72-Leu83 (which inhibited FXI binding to HK) did not inhibit FXI activation by thrombin. Thus, a thrombin binding site exists in the A1 domain of FXI spanning residues Ala45-Arg70 that is contiguous with but separate and distinct from the HK binding site. These sites may regulate which ligand is bound to FXI and through which pathway FXI is activated.

• Sun Y, Gailani D
• Identification of a factor IX binding site on the third apple domain of activated factor XI.
• J Biol Chem. 1996; 271: 29023-8
• Display abstract

• Activated factor XI (factor XIa) participates in blood coagulation by activating factor IX. Previous work has demonstrated that a binding site for factor IX is present on the noncatalytic heavy chain of factor XIa (Sinha, D., Seaman, F. S., and Walsh, P. N. (1987) Biochemistry 26, 3768-3775). Recombinant factor XI proteins were expressed in which each of the four apple domains of the heavy chain (designated A1 through A4) were individually replaced with the corresponding domain from the homologous but functionally distinct protease prekallikrein (PK). To identify the site of factor IX binding, the chimeric proteins were activated with factor XIIa and tested for their capacity to activate factor IX in plasma coagulation and purified protein assays. The chimera with the substitution in the third apple domain (factor XI/PKA3) had <1% of the coagulant activity of wild type factor XIa in a plasma coagulation assay, whereas the chimeras with substitutions in A1, A2, and A4 demonstrated significant activity (68-140% of wild type activity). The Km for activation of factor IX by factor XIa/PKA3 (12. 7 microM) is more than 30-fold higher than the Km for activation by wild type factor XIa or the other factor XI/PK chimeras (0.11-0.37 microM). Two monoclonal antibodies (2A12 and 11AE) that recognize epitopes on the factor XI A3 domain were potent inhibitors of factor IX activation by factor XIa, whereas antibodies against the A2 (1A6) and A4 (3G4) domains were poor inhibitors. The data indicate that a binding site for factor IX is present on the third apple domain of factor XIa.

• Bolton-Maggs PH
• Factor XI deficiency.
• Baillieres Clin Haematol. 1996; 9: 355-68
• Display abstract

• That factor XI has a role in normal blood coagulation is evidenced by the fact that patients with deficiency are prone to excessive bleeding after haemostatic challenge. The role of factor XI in physiological processes has become clearer since the discovery that it is activated by thrombin; this fact has contributed to a revised model of blood coagulation. Factor XI deficiency is particularly common in Ashkenazi Jews. Bleeding is typically provoked by surgery in areas of increased fibrinolysis, and is not restricted to individuals with severe deficiency. The bleeding tendency is variable and the reasons for this are not fully understood, although in severe deficiency there is some correlation between phenotype and genotype. The factor XI gene is 23 kb long, and two mutations are responsible for most factor XI deficiency in the Ashkenazi population. A total of 13 mutations have thus far been published. Factor XI deficient patients may need specific therapy to cover surgery and dental extractions. Although a factor XI concentrate is available there have been recent reports of coagulation activation and thrombosis indicating that it should be used cautiously. Fresh frozen plasma may be an acceptable alternative in some situations.

• de Raucourt E, Aurousseau MH, Denninger MH, Verroust F, Goudemand M, Fischer AM
• Use of a factor XI concentrate in three severe factor XI-deficient patients.
• Blood Coagul Fibrinolysis. 1995; 6: 486-7

• Pugh RE, McVey JH, Tuddenham EG, Hancock JF
• Six point mutations that cause factor XI deficiency.
• Blood. 1995; 85: 1509-16
• Display abstract

• We have identified six novel types of mutation that cause factor XI deficiency, an inherited bleeding disorder. Two are point mutations that interfere with the normal splicing of exons in the mRNA and four are point mutations that result in amino acid substitutions. One of these amino acid substitutions (Asp 16-->His) is near the amino terminal end of the protein. The other three amino acid substitutions (Leu 302-->Pro, Thr 304-->Ile, and Glu 323-->Lys) are in the fourth apple domain, a region that mediates dimerization of identical subunits of factor XI. All four amino acid substitutions cause a reduction in the amount of factor XI secreted from cells grown in vitro.

• Baglia FA, Seaman FS, Walsh PN
• The Apple 1 and Apple 4 domains of factor XI act synergistically to promote the surface-mediated activation of factor XI by factor XIIa.
• Blood. 1995; 85: 2078-83
• Display abstract

• Binding sites for high molecular weight kininogen (HK) and for factor XIIa are present in the Apple 1 (A1) and the A4 domains of factor XI, respectively. To define the roles of these two sites in surface-mediated factor-XI activation we prepared conformationally constrained synthetic peptides and recombinant A1 domain (rA1) and determined their effects on the activation of factor XI by factor XIIa in the presence of HK and either kaolin or dextran sulfate. Surface-mediated factor-XI activation by factor XIIa was inhibited by a conformationally constrained A4 peptide (Ala317-Gly350), by an A1 peptide (Phe56-Ser86), and by rA1 (Glu1-Ser90). When used in combination at equimolar concentrations, rA1 and A4 peptide were 10-fold more effective than either one alone in inhibiting surface-mediated activation of factor XI by factor XIIa. The A4 peptide was a competitive inhibitor of factor XIIa amidolytic activity and a noncompetitive inhibitor of factor-XI activation by factor XIIa, whereas rA1 and the A1 peptide did not inhibit factor XIIa. The rA1 domain inhibited factor XI binding to HK, whereas the A4 peptide did not. We conclude that specific sequences exposed on the surfaces of the A1 (Val59-Lys83) and A4 (Ala317-Gly350) domains of factor XI act synergistically to promote surface-mediated factor-XI activation by factor XIIa in the presence of HK by binding factor XI to surface-bound HK (A1 domain) and by binding factor XIIa near the cleavage site (Arg369-Ile370) of factor XI (A4 domain).

• Page JD, You JL, Harris RB, Colman RW
• Localization of the binding site on plasma kallikrein for high-molecular-weight kininogen to both apple 1 and apple 4 domains of the heavy chain.
• Arch Biochem Biophys. 1994; 314: 159-64
• Display abstract

• The C-terminal end of the heavy chain of human plasma prekallikrein or kallikrein contains a binding site for high-molecular-weight kininogen, the nonenzymatic procofactor of contact activation. To further map this binding site, a series of overlapping peptides were synthesized. The amount of kallikrein that bound to kininogen-coated microtiter plate wells in the presence of increasing concentrations of each peptide was determined by kallikrein amidolytic activity. A peptide encompassing Lys266-Gly295 of kallikrein, conformationally constrained by a disulfide bond, displayed the lowest Kd value (approximately 67 microM). The linear peptide, Leu262-Gly295, displayed lower affinity (129 microM). N-terminal or C-terminal truncation/extension peptides of this sequence diminished binding activity. Since the closely related protein, factor XI, has been shown to bind kininogen, a kallikrein-based peptide (Phe56-Gly86) homologous to the binding domain of FXI, was examined and found to possess less, but significant, binding affinity for kininogen (Kd 530 microM). Isothermal titration calorimetry was used to assess binding between the kallikrein-based peptides and a peptide encompassing the kallikrein binding domain in kininogen (Ser565-Lys595). Leu262-Gly295 possesses potent binding activity (Kd 52 microM), while Phe56-Gly86 displays poorer binding activity (Kd 400 microM). These interactions are endothermic and entropically favored, suggesting that a conformational rearrangement takes place upon binding. We conclude that the binding site for kininogen within prekallikrein is composed of discontinuous linear segments that form a contiguous surface in the folded protein.

• Mashiko H, Takahashi H
• Factor XI: purification from porcine plasma by affinity chromatography and some properties of factor XI and activated factor XI.
• Biol Chem Hoppe Seyler. 1994; 375: 481-4
• Display abstract

• Porcine factor XI and activated factor XI were purified by the introduction of affinity chromatography on high molecular mass kininogen. On the affinity chromatography, it was observed that high affinity exists between porcine factor XI and high molecular mass kininogen. In the preparation, however, factor XII, plasma prekallikrein and high molecular mass kininogen were not detected. The factor XI forms a dimer, and is a heterogeneous molecule, judging from sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Substrate specificity of activated factor XI and inhibition profile of activated factor XI against proteinase inhibitors were investigated by comparison with those of bovine and human activated factor XI. From these results, the properties of porcine activated factor XI show great similarities with those of bovine and human activated factor XI.

• von dem Borne PA, Koppelman SJ, Bouma BN, Meijers JC
• Surface independent factor XI activation by thrombin in the presence of high molecular weight kininogen.
• Thromb Haemost. 1994; 72: 397-402
• Display abstract

• A deficiency of one of the proteins of the contact system of blood coagulation does not result in a bleeding disorder. For this reason activation of blood coagulation via this system is believed to be an in vitro artefact. However, patients deficient in factor XI do suffer from variable bleeding abnormalities. Recently, an alternative pathway for factor XI activation has been described. Factor XI was found to be activated by thrombin in the presence of dextran sulfate as a surface. However, high molecular weight kininogen (HK), to which factor XI is bound in plasma, and fibrinogen were shown to block this activation suggesting it to be an in vitro phenomenon. We investigated the thrombin-mediated factor XI activation using an amplified detection system consisting of factors IX, VIII and X, which was shown to be very sensitive for factor XIa activity. This assay is approximately 4 to 5 orders of magnitude more sensitive than the normal factor XIa activity assay using a chromogenic substrate. With this assay we found that factor XI activation by thrombin could take place in the absence of dextran sulfate. The initial activation rate was approximately 0.3 pM/min (using 25 nM factor XI and 10 nM thrombin). The presence of dextran sulfate enhanced this rate about 8500-fold. A very rapid and complete factor X activation was observed in the presence of dextran sulfate. Although only minute amounts of factor XIa were formed in the absence of dextran sulfate, significant activation of factor X was detected in the amplification assay within a few minutes.(ABSTRACT TRUNCATED AT 250 WORDS)

• Gailani D
• Advances and dilemmas in factor XI.
• Curr Opin Hematol. 1994; 1: 347-53
• Display abstract

• Factor XI is a key component of the intrinsic pathway of blood coagulation in vitro. The poor correlation between the clinical bleeding diathesis in factor XI deficiency and abnormalities in clotting assays that measure intrinsic coagulation brings into question the role of this serine protease in in vivo hemostasis. The characterizations of the point mutations responsible for the majority of cases of severe factor XI deficiency in Ashkenazi Jews and subsequent epidemiologic studies have provided insight into the perplexing hemostatic abnormalities in this disorder. It appears that excessive bleeding in factor XI deficiency depends on the severity of the deficiency in certain situations and on the location of the hemostatic challenge in others. Additional coexisting abnormalities of hemostasis, such as von Willebrand's disease, may also be responsible for variation in clinical presentation, particularly in those individuals with mild factor XI deficiency. The absence of abnormal bleeding in congenital deficiency of factor XII, the protease that activates factor XI in the intrinsic cascade, has stimulated a search for other mechanisms for factor XI activation. Recent studies have pointed to the serine protease thrombin and autoactivation by activated factor XI as possible alternatives to factor XII as activators of factor XI. These findings suggest that factor XI, rather than operating in a pathway for the initiation of hemostasis, may function in the consolidation of clot formation after the initiation of the hemostatic process by other mechanisms.

• Herwald H, Jahnen-Dechent W, Alla SA, Hock J, Bouma BN, Muller-Esterl W
• Mapping of the high molecular weight kininogen binding site of prekallikrein. Evidence for a discontinuous epitope formed by distinct segments of the prekallikrein heavy chain.
• J Biol Chem. 1993; 268: 14527-35
• Display abstract

• Prekallikrein, a glycoprotein involved in contact phase activation, circulates in plasma in the form of a binary complex with high molecular weight kininogen (H-kininogen). The binding to H-kininogen is mediated by the prekallikrein heavy chain consisting of four repetitive domains, A1-A4. To define more precisely the region(s) involved in kininogen binding, we have employed an affinity cross-linking strategy with a synthetic peptide of 31 residues which mimics the prekallikrein binding site of H-kininogen. Cross-linking of the radiolabeled peptide to (pre)kallikrein revealed a binding segment in the NH2-terminal portion of the prekallikrein heavy chain; another binding segment was located in the COOH-terminal part of the heavy chain. The latter binding segment is harbored by a previously identified fragment of the kallikrein heavy chain involved in H-kininogen binding (Page, J.D., and Colman, R.W. (1991) J. Biol. Chem. 266, 8143-8148). Chemical cleavage of the heavy chain cross-linked with the radiolabeled peptide mapped the NH2-terminal binding segment to 60 residues (positions 53-112) of A1. Synthesis of a peptide (positions 56-86) and development of specific antibodies to this peptide narrowed down the kininogen binding segment to 31 residues of the center portion of A1. This NH2-terminal segment is equivalent to a kininogen binding site previously identified in factor XI (Baglia, F.A., Jameson, B.A., and Walsh, P.N. (1992) J. Biol. Chem. 267, 4247-4252). We conclude that prekallikrein exposes at least two segments on its heavy chain portion which form a continuous surface thereby facilitating the intimate binding of the zymogen to its nonenzymatic cofactor, H-kininogen.

• Walsh PN, Baglia FA, Jameson BA
• Factor XI: structure-function relationships utilizing monoclonal antibodies protein modification, computational chemistry, and rational synthetic peptide design.
• Methods Enzymol. 1993; 222: 65-96

• Brunnee T, La Porta C, Reddigari SR, Salerno VM, Kaplan AP, Silverberg M
• Activation of factor XI in plasma is dependent on factor XII.
• Blood. 1993; 81: 580-6
• Display abstract

• The activation of factor XI initiates the intrinsic coagulation pathway. Until recently it was believed that the main activator of factor XI is factor XIIa in conjunction with the cofactor high molecular weight kininogen on a negatively charged surface. Two recent reports have presented evidence that in a purified system factor XI is activatable by thrombin together with the soluble polyanion dextran sulfate. To assess the physiological relevance of these findings we studied the activation of factor XI in normal and factor XII-deficient plasma. We used either kaolin/cephalin or dextran sulfate as a surface for the intrinsic coagulation pathway, tissue factor to generate thrombin via the extrinsic pathway, or the addition of alpha-thrombin directly. 125I-factor XI, added to factor XI-deficient plasma at physiologic concentrations (35 nmol/L), is rapidly cleaved on incubation with kaolin. The kinetics appear to be exponential with half the maximum cleavage at 5 minutes. Similar kinetics of factor XI cleavage are seen when 40 nmol/L factor XIIa (equal to 10% of factor XII activation) is added to factor XII-deficient plasma if an activating surface is provided. Tissue factor (1:500) added to plasma did not induce cleavage of factor XI during a 90-minute incubation, although fibrin formation within 30 seconds indicated that thrombin was generated via the extrinsic pathway. Adding 1 mumol/L alpha-thrombin (equivalent to 50% prothrombin activation) directly to factor XII deficient or normal plasma (with or without kaolin/cephalin/Ca2+ or dextran sulfate) led to instantaneous fibrinogen cleavage, but again no cleavage of factor XI was observable. We conclude that in plasma surroundings factor XI is not activated by thrombin, and that proposals of thrombin initiation of the intrinsic coagulation cascade are not supportable.

• You JL, Page JD, Scarsdale JN, Colman RW, Harris RB
• Conformational analysis of synthetic peptides encompassing the factor XI and prekallikrein overlapping binding domains of high molecular weight kininogen.
• Peptides. 1993; 14: 867-76
• Display abstract

• High molecular weight kininogen, a plasma glycoprotein, circulates as a noncovalent complex with either prekallikrein or factor XI, two other plasma glycoproteins. The binding domain for factor XI within kininogen, Pro556-Met613 (58 residues), wholly contains the binding domain for prekallikrein, Ser565-Lys595 (31 residues), but Trp569-Lys595 (27 residues) retains some ability to bind prekallikrein. Complex formation between these proteins is mediated by recognition between complementary domains. The 58-residue factor XI peptide domain has now been prepared following a strategy of condensation of long-chain peptide fragments prepared using orthogonal chemistry protocols. The 58-, 31-, and 27-residue peptides assume very different structures in aqueous solution as revealed by differential scanning calorimetry, intrinsic fluorescence emission, and circular dichroism spectroscopies. Thus, the 31-residue peptide shows a broad endothermic transition in differential scanning calorimetry (DSC), but the 58-mer undergoes a well-defined, two-state transition (Tm 43 degrees C; transition enthalpy approximately 30 kcal/mol). The 58- and 27-residue peptides continuously lose structure with increasing temperature, but the 31-mer retains significant structure even at temperatures approaching 90 degrees C. Lys595 plays a critical role in maintaining structure through electrostatic contacts, probably with Asp572 in the N-terminal segment of the 31-residue sequence. Isothermal ligand titration calorimetry was used to directly assess the ability of the 31-, 27-, and 58-residue peptides to bind prekallikrein. The 31-residue peptide binds prekallikrein with 25-fold higher affinity (Kd = 1.0 x 10(-6) M) than the 58-residue peptide and with 5.4-fold higher affinity than the 27-residue peptide. Hence, the essential features of the 31-residue peptide domain required for binding prekallikrein are absent in the 58-residue peptide, which is optimized for binding factor XI. The results suggest that a conformational change may occur within kininogen that causes expression of one domain structure in preference to the other.

• Walsh PN, Baglia FA, Jameson BA
• Factor XI and platelets: activation and regulation.
• Thromb Haemost. 1993; 70: 75-9

• Ratnoff OD
• Activation of factor XI.
• Blood. 1993; 81: 3483-4

• Meijers JC, Davie EW, Chung DW
• Expression of human blood coagulation factor XI: characterization of the defect in factor XI type III deficiency.
• Blood. 1992; 79: 1435-40
• Display abstract

• Human factor XI (FXI) is a blood coagulation factor participating in the early phase of the intrinsic pathway of blood coagulation. It circulates in blood as a glycoprotein composed of two identical chains held together by a single disulfide bond between the fourth apple domains. FXI has been expressed in baby hamster kidney (BHK) cells, where it was synthesized as a single-chain molecule that was converted to the dimer before secretion. The recombinant protein was fully active in a clotting assay, indicating that it interacted readily with other components of the coagulation cascade. A mutant FXI in which Phe283 was converted to Leu (Phe283Leu) was also expressed in BHK cells. This amino acid change occurs in the fourth apple domain of FXI and corresponds to the type III deficiency in Ashkenazi Jews. The mutant protein was secreted at reduced levels (about 8%) compared with normal FXI. This was due to a defect in the dimerization of the molecule rather than a decrease in the transcription of type III messenger RNA. Once secreted, however, the mutant protein consisted of a dimer with full biologic activity. The in vitro expression of FXI indicated that the impaired dimerization and secretion of the Phe283Leu mutant can account for the defect found in patients who are homozygous for the type III FXI deficiency.

• Baglia FA, Jameson BA, Walsh PN
• Fine mapping of the high molecular weight kininogen binding site on blood coagulation factor XI through the use of rationally designed synthetic analogs.
• J Biol Chem. 1992; 267: 4247-52
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• Using immunological and chemical cleavage techniques, we have previously identified a domain contained within residues Phe56-Ser86 in the first tandem repeat (A1) of the heavy chain of factor XI which binds high Mr kininogen (Baglia, F. A., Jameson, B. A., and Walsh, P. N. (1990) J. Biol. Chem. 265, 4149-4154). We have now chemically synthesized peptides from corresponding homologous regions in the second (A2), third (A3), and fourth (A4) tandem repeats of the heavy chain (A2: Asn145-Ala176; A3: Asn235-Arg266; and A4: Gly326-Lys357). These peptides had no effect on the binding of factor XI to high Mr kininogen. Because of a lack of detailed structural information for the A1 domain, a molecular model of this region was constructed. This hypothetical model made distinct and testable predictions regarding potential surfaces and concomitant secondary structure. Specifically, the resulting structure depicted two juxtaposed beta-stranded stem-loops that, in conjunction with biological information, constitute a candidate surface for contact with high Mr kininogen. The hypothetical A1 model was, consequently, used as a predictive template in the rational design of two synthetic peptides (Val59-Arg70 and Asn72-Lys83). When both these peptides were added together and the binding of factor XI to high Mr kininogen was examined, a synergistic inhibitory effect was observed compared with each peptide added individually. Our data are consistent with the notion that the sequence of amino acids from Val59-Lys83 of the heavy chain of factor XI contains two antiparallel beta-strands connected by beta-turns that together comprise a continuous surface utilized for the binding of high Mr kininogen.

• Tanaka H et al.
• Activation of human plasma prekallikrein by Pseudomonas aeruginosa elastase. II. Kinetic analysis and identification of scissile bond of prekallikrein in the activation.
• Biochim Biophys Acta. 1992; 1138: 243-50
• Display abstract

• Activation of human plasma prekallikrein by a bacterial metalloendopeptidase, Pseudomonas aeruginosa elastase, was reported (Shibuya et al. (1991) Biochim. Biophys. Acta 1097, 23-27). Details of the activation process were presently studied. The activation accompanied limited proteolysis of a peptide bond inside of a disulfide bridge of prekallikrein molecule. Amino acid sequencing analysis of the newly generated amino-terminal revealed that the cleavage site was Arg371-Ile372 bond which is the scissile bond in the activation of prekallikrein with trypsin-type proteinases. A pentapeptide substrate, 2-aminobenzoyl-Ser-Thr-Arg-Ile-Val-4- nitrobenzylamide, which contained the amino acid sequence identical to that around the scissile bond of prekallikrein was synthesized. Pseudomonal elastase, indeed, hydrolyzed the substrate at Arg-Ile bond with the kinetic parameters of Km = 118 microM, kcat = 1.56/s and kcat/Km = 1.33.10(4)/s M. These results indicated that the Arg371-Ile372 bond was sensitive not only to trypsin-type serine proteinases, but also a bacterial metalloproteinase. Kinetic analysis of the prekallikrein activation by pseudomonal elastase, however, revealed that the activation rate was slow, though the Km values was good enough to expect an occurrence of this activation in vivo (Km = 248 nM, kcat = 6.8.10(-4)/s, and kcat/Km = 2.7.10(3)/s M). The activation rate of prekallikrein by pseudomonal elastase in Hageman factor deficient plasma was remarkably improved when the plasma was reconstituted with purified Hageman factor molecule. From the results, a biological significance of the proteinase cascade in the plasma kinin generation was also indicated. The present in vitro study might support the hypothesis that the Hageman factor/kallikrein-kinin system plays an important role in bacterial infection including the pseudomonal one.

• McMullen BA, Fujikawa K, Davie EW
• Location of the disulfide bonds in human coagulation factor XI: the presence of tandem apple domains.
• Biochemistry. 1991; 30: 2056-60
• Display abstract

• Factor XI is a plasma glycoprotein that participates in the blood coagulation cascade. Of the 19 disulfide bonds present in each of the subunits of the human protein, 16 were determined by amino acid sequence analysis of peptide fragments produced by chemical and enzymatic digestion. Four apple domains of 90 or 91 amino acids were identified in the tandem repeats present in the amino-terminal portion of each subunit of factor XI. The disulfide bonds in the carboxyl-terminal portion of the molecule were similar to those in the catalytic region of other serine proteases. The two identical subunits of factor XI were connected by a single disulfide bond at Cys321 linking each of the fourth apple domains while each of the Cys residues at position 11 in the first apple domains forms a disulfide bond with another Cys residue.

• Baglia FA, Jameson BA, Walsh PN
• Identification and chemical synthesis of a substrate-binding site for factor IX on coagulation factor XIa.
• J Biol Chem. 1991; 266: 24190-7
• Display abstract

• We have previously used monoclonal antibodies to identify an epitope on the heavy chain of factor XIa that is a substrate-binding site for factor IX (Sinha, D., Seaman, F.S., and Walsh, P.N. (1987) Biochemistry 26, 3768-3775; Baglia, F.A., Sinha, D., and Walsh, P.N. (1989) Blood 74, 244-251). To define the factor XIa domain that binds factor IX, we have now screened a panel of factor XI heavy chain-derived synthetic peptides for their capacity to inhibit the formation of an activation peptide reflecting factor IX activation by factor XIa. Peptide Asn145-Ala176 (which is located in the second tandem repeat or A2 domain of the factor XI heavy chain) is a competitive inhibitor of factor IX activation by factor XIa with a Ki of 30 nM, whereas structurally similar peptides in the A1, A3, and A4 domains were required at 10-1000-fold higher concentrations for similar effects, and a synthetic peptide identical with a highly homologous region of the heavy chain A2 domain of prekallikrein (Tyr143-Ala176) had no effect on factor IX activation by factor XIa. Because detailed structural information is lacking, a potential three-dimensional structure for the factor XI A2 domain was calculated based on its sequence information in conjunction with previously determined structural constraints. The resulting structure depicted three juxtaposed beta-stranded stem-loops that, based on biological information, constitute a candidate surface for contact with factor IX. The A2 model was therefore used as a template in the rational design of three synthetic peptides (Ala134-Ile146 (peptide a), Leu148-Arg159 (peptide b), and Ile160-Leu172 (peptide c]. When peptides a and b or a and c were added together and the activation of factor IX by factor XIa was examined, a synergistic inhibitory effect was observed, compared with each peptide added individually, whereas peptides b and c showed additive effects. Our data suggest that the sequence of amino acids from Ala134 through Leu172 of the heavy chain of factor XI contains three antiparallel beta-strands connected by beta-turns that together comprise a continuous surface utilized for the binding of factor IX.

• Naito K, Fujikawa K
• Activation of human blood coagulation factor XI independent of factor XII. Factor XI is activated by thrombin and factor XIa in the presence of negatively charged surfaces.
• J Biol Chem. 1991; 266: 7353-8
• Display abstract

• Human blood coagulation factor XI was activated by either autoactivation or thrombin. These reactions occurred only in the presence of negatively charged materials, such as dextran sulfate (approximately Mr 500,000), sulfatide, and heparin. During the activation, factor XI was cleaved at a single Arg-Ile bond by thrombin or factor XIa to produce an amino-terminal 50-kDa heavy chain and a carboxyl-terminal 35-kDa light chain. This activation pattern is identical to that produced by factor XIIa. The addition of a small amount of thrombin and sulfatide to factor XII-deficient plasma produced shorter clotting times than when these agents were added to factor XI/factor XII combined-deficient plasma. These results suggest that the activation of factor XI by thrombin and possibly the autoactivation of factor XI proceed in plasma to lead fibrin clot formation. These reactions may have a role on an appropriate negatively charged surface in normal hemostasis.

• Schiffman S, Yeh CH
• Purification and characterization of platelet factor XI.
• Thromb Res. 1990; 60: 87-97
• Display abstract

• Factor XI activity and antigen was purified about 300 fold from human platelets through chromatography on Con-A Sepharose, SP-Sephadex C-50, immobilized goat anti-factor XI, and SP-Sephadex. The partially purified platelet factor XI (Pt-XI) could be activated by activated factor XII generated in situ from single chain factor XI in a reaction requiring high molecular weight kininogen (HMWK) and a surface. Native Pt-XI migrated as a molecule of Mr = 245,000 on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) as identified by Western blotting. On reduction, Pt-XI appeared to have a Mr = 52,000. Neither form was affected by exposure to trypsin. Incubation of Pt-XI with purified factor XII, HMWK, and kaolin produced activated platelet factor XI clotting activity and, concomitantly, the generation over time of a new chain on reduced SDS-PAGE of Mr = 44,500. The coagulant activity of the activated form could be neutralized by diisopropyl flurophosphate (DFP). Incubation of the activated mixture with 3H-DFP followed by reduced SDS-PAGE showed the active site to be associated with a unit of Mr = 44,500. The adsorption domain as defined by adsorption to kaolin was localized to the Mr = 44,500 chain containing the active site. Hence, both active site and adsorption functions, properties of separate chains in plasma factor XI, reside in the same chain of Mr = 44,500 of platelet factor XI.

• Baglia FA, Jameson BA, Walsh PN
• Localization of the high molecular weight kininogen binding site in the heavy chain of human factor XI to amino acids phenylalanine 56 through serine 86.
• J Biol Chem. 1990; 265: 4149-54
• Display abstract

• We have previously demonstrated that a monoclonal antibody (5F7) directed against the heavy chain region of factor XI inhibits the binding of factor XI to high molecular weight kininogen (high Mr kininogen) and the surface-mediated proteolytic activation of factor XI by factor XIIa in the presence of high Mr kininogen. In order to identify the structural domain of factor XI that binds high Mr kininogen, CNBr-digested factor XI was passed over a 5F7 antibody affinity column. One of two CNBr peptides that bound to this 5F7 affinity column inhibited binding of 125I-factor XI to high Mr kininogen, as did intact factor XI. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate of an inhibitory peptide purified by high performance liquid chromatography revealed an Mr of 10,000-15,000. Gas-phase sequencing of this peptide revealed the following amino-terminal sequence: X-X-Val-Thr-Gln-Leu-Leu-Lys-Asp-Thr. These data together with the amino acid composition of the isolated peptide indicate that both the epitope recognized by antibody 5F7 and at least a portion of the high Mr kininogen binding site are contained within the amino-terminal portion of factor XI comprising residues Glu-1 through Met-102. Further cleavage of this peptide with o-iodosobenzoic acid at a tryptophanyl peptide bond revealed that an Mr 5,000 peptide (with the amino-terminal sequence Trp-Phe-Thr-Cys-Val-Leu) bound to a high Mr kininogen affinity column and inhibited binding of 125I-factor XI to high Mr kininogen. Finally, a synthetic peptide comprising residues Phe-56 through Ser-86 inhibited 125I-factor XI binding to high Mr kininogen. These experiments strongly suggest that the high Mr kininogen binding site is contained within the domain in the heavy chain region of factor XI comprising residues Phe-56 through Ser-86.

• Asakai R, Chung DW, Ratnoff OD, Davie EW
• Factor XI (plasma thromboplastin antecedent) deficiency in Ashkenazi Jews is a bleeding disorder that can result from three types of point mutations.
• Proc Natl Acad Sci U S A. 1989; 86: 7667-71
• Display abstract

• Factor XI (plasma thromboplastin antecedent) deficiency is a blood coagulation abnormality occurring in high frequency in Ashkenazi Jews. Three independent point mutations that result in a blood coagulation abnormality have been identified in the factor XI gene of six unrelated Ashkenazi patients. These mutations either disrupt normal mRNA splicing (type I), cause premature polypeptide termination (type II), or result in a specific amino acid substitution (type III). The three different genotypes were present in the six patients as type I/II, type II/III, and type III/III. Thus far no correlation was found between the three genotypes and the bleeding tendency in these patients.

• De La Cadena RA et al.
• Naturally occurring human antibodies against two distinct functional domains in the heavy chain of FXI/FXIa.
• Blood. 1988; 72: 1748-54
• Display abstract

• We have isolated and probed the mechanism of action of two naturally occurring antibodies (Baltimore and Winston-Salem) against factor XI (FXI), that developed in patients congenitally deficient in FXI after replacement therapy. Purification on immobilized protein A and neutralization with monospecific antibodies against IgG heavy and light chain subtypes indicated that both antibodies were of restricted heterogeneity. Both Winston-Salem (IgG3 kappa) and Baltimore (IgG1 kappa) completely inhibited FXI coagulant activity at titers of 200 and 8 Bethesda units, respectively. Immunoaffinity columns prepared from each antibody were able to bind the heavy but not the light chain of reduced and alkylated activated FXI (FXIa). The activation of purified FXI by activated bovine factor XII (FXIIa), a reaction independent of high molecular weight kininogen (HK), was not inhibited by either antibody. The active site on the FXIa light chain was unaffected by either patient's IgG, as measured by its amidolytic activity. In contrast, one antibody (Baltimore) or its Fab' blocked the surface-mediated proteolytic activation of FXI by human FXIIa in a concentration-dependent fashion by preventing its binding to HK, but had no effect on the rate of activation of FIX by FXIa. In contrast, the other antibody (Winston-Salem) or its Fab' inhibited the activation of FIX by FXIa in a concentration-dependent fashion but did not inhibit binding of FXI to HK. We conclude that each of these two naturally occurring antibodies is directed against a specific, separate, and distinct epitope located in the heavy chain of FXIa, one near or at the domain essential for the activation of FIX by FXIa and the other close to the domain required for binding to HK.

• Mannhalter CH
• Biochemical and functional properties of factor XI and prekallikrein.
• Semin Thromb Hemost. 1987; 13: 25-35

• Tait JF, Fujikawa K
• Primary structure requirements for the binding of human high molecular weight kininogen to plasma prekallikrein and factor XI.
• J Biol Chem. 1987; 262: 11651-6
• Display abstract

• We recently identified residues 185-224 of the light chain of human high molecular weight kininogen (HMWK) as the binding site for plasma prekallikrein (Tait, J.F., and Fujikawa, K. (1986) J. Biol. Chem. 261, 15396-15401). In the present study, we have further defined the primary structure requirements for binding of HMWK to factor XI and prekallikrein. In a competitive fluorescence polarization binding assay, a 31-residue synthetic peptide (residues 194-224 of the HMWK light chain) bound to prekallikrein with a Kd of 20 +/- 6 nM, indistinguishable from the previously determined value of 18 +/- 5 nM for the light chain. We also prepared three shorter synthetic peptides corresponding to different portions of the 31-residue peptide (residues 205-224, 212-224, and 194-211), but these peptides bound to prekallikrein more than 100-fold more weakly. Factor XI also bound to the same region of the HMWK light chain, but at least 58 residues (185-242) were required for optimal binding (Kd = 69 +/- 4 nM for the light chain; Kd = 130 +/- 50 nM for residues 185-242). The four synthetic peptides inhibited kaolin-activated clotting of blood plasma with potencies paralleling their affinities for prekallikrein and factor XI. Peptide 194-224 can also be used for rapid affinity purification of prekallikrein and factor XI from plasma.

• Asakai R, Davie EW, Chung DW
• Organization of the gene for human factor XI.
• Biochemistry. 1987; 26: 7221-8
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• Factor XI (plasma thromboplastin antecedent) is a plasma glycoprotein that participates in the early phase of blood coagulation. The gene for the human protein has been isolated from two different lambda phage genomic libraries. Four independent recombinant lambda phage carrying overlapping DNA inserts that coded for the entire gene for factor XI were isolated and characterized by restriction mapping, Southern blotting, and selective DNA sequencing to establish the number and location of the intron-exon boundaries. The gene for human factor XI was 23 kilobases in length and consisted of 15 exons (I-XV) and 14 introns (A-N). Exon I coded for the 5' untranslated region, and exon II coded for the signal peptide. The next eight exons (III-X) coded for the four tandem repeats of 90 or 91 amino acids that were present in the amino-terminal region of the mature protein. Each of these tandem repeats was coded by two exons that were interrupted by a single intron, and these introns were located in essentially the same position within each of the four tandem repeats. The carboxyl-terminal region of the protein, which contained the catalytic chain, was coded by five exons (XI-XV) that were interrupted by four introns. The last four introns were located in the same positions as those in the genes for human tissue plasminogen activator and human urokinase.

• Greengard JS, Heeb MJ, Ersdal E, Walsh PN, Griffin JH
• Binding of coagulation factor XI to washed human platelets.
• Biochemistry. 1986; 25: 3884-90
• Display abstract

• The binding of human coagulation factor XI to washed human platelets was studied in the presence of zinc ions, calcium ions, and high molecular weight kininogen. Significant factor XI binding occurred at physiological levels of these metal ions when high molecular weight kininogen was present. Binding required platelet stimulation and was specific, reversible, and saturable. Scatchard analysis of the binding yielded approximately 1500 binding sites per platelet with an apparent dissociation constant of approximately 10 nM. Since the concentration of factor XI in plasma is about 25 nM, this suggests that in plasma factor XI binding sites on stimulated platelets might be saturated. Calcium ions and high molecular weight kininogen acted synergistically to enhance the ability of low concentrations of zinc ions to promote factor XI binding. The similarity between the concentrations of metal ions optimal for factor XI binding and those optimal for high molecular weight kininogen binding, as well as the ability of high molecular weight kininogen to modulate these metal ion effects, implies that factor XI and high molecular weight kininogen may form a complex on the platelet surface as they do in solution and on artificial negatively charged surfaces.

• Chung DW, Fujikawa K, McMullen BA, Davie EW
• Human plasma prekallikrein, a zymogen to a serine protease that contains four tandem repeats.
• Biochemistry. 1986; 25: 2410-7
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• The amino acid sequence of human plasma prekallikrein was determined by a combination of automated Edman degradation and cDNA sequencing techniques. Human plasma prekallikrein was fragmented with cyanogen bromide, and 13 homogeneous peptides were isolated and sequenced. Cyanogen bromide peptides containing carbohydrate were further digested with trypsin, and the peptides containing carbohydrate were isolated and sequenced. Five asparagine-linked carbohydrate attachment sites were identified. The sequence determined by Edman degradation was aligned with the amino acid sequence predicted from cDNAs isolated from a lambda gt11 expression library. This library contained cDNA inserts prepared from human liver poly(A) RNA. Analysis of the cDNA indicated that human plasma prekallikrein is synthesized as a precursor with a signal peptide of 19 amino acids. The mature form of the protein that circulates in blood is a single-chain polypeptide of 619 amino acids. Plasma prekallikrein is converted to plasma kallikrein by factor XIIa by the cleavage of an internal Arg-Ile bond. Plasma kallikrein is composed of a heavy chain (371 amino acids) and a light chain (248 amino acids), and these 2 chains are held together by a disulfide bond. The heavy chain of plasma kallikrein originates from the amino-terminal end of the zymogen and is composed of 4 tandem repeats that are 90 or 91 amino acid residues in length. These repeat sequences are also homologous to those in human factor XI. The light chain of plasma kallikrein contains the catalytic portion of the enzyme and is homologous to the trypsin family of serine proteases.

• Veloso D, Shilling J, Shine J, Fitch WM, Colman RW
• Recent evolutionary divergence of plasma prekallikrein and factor XI.
• Thromb Res. 1986; 43: 153-60
• Display abstract

• The evolution in mammals of the zymogens of the contact activation system of coagulation (factor XII, prekallikrein and factor XI) has been investigated. The NH2-terminal sequences of human plasma prekallikrein and the heavy and light chains of kallikrein have been determined and compared with those of bovine prekallikrein and of human and bovine factors XII and XI. The human and bovine NH2-terminal sequences of the light chains (catalytic polypeptide) show striking similarities both among themselves and with those of the catalytic polypeptide chains of other coagulation and digestive proteases, indicating a common origin. Comparison of the NH2-terminal sequences of human prekallikrein with those of the bovine prekallikrein and human bovine factors XIa and XIIa indicates a common origin of the heavy chain of kallikrein and factor XIa, different from that of either factor XIIa or other known amino acid sequences. Ancestral sequences for human and bovine prekallikrein and factor XI, deduced by genetic analysis of the minimum number of base changes indicate that the NH2-terminus of prekallikrein and factor XI have evolved at about the same rate. The estimated time for the gene duplication was about 124 million years ago, a value consistent with the age of the mammals.

• Akiyama H, Sinha D, Seaman FS, Kirby EP, Walsh PN
• Mechanism of activation of coagulation factor XI by factor XIIa studied with monoclonal antibodies.
• J Clin Invest. 1986; 78: 1631-7
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• The interaction of Factor XIIa with Factor XI was investigated using two monoclonal antibodies, one (3Cl) directed against the heavy chain of Factor XIa and the other (5F4) against its light chain. 3C1 either as intact IgG or as Fab' fragment, enhanced the rate of Factor XIa generation in the fluid phase but inhibited it in the presence of kaolin and high molecular weight (HMW) kininogen. In contrast, the Fab' fragments of 5F4 inhibited only the fluid phase activation and had no effect on the surface-mediated activation. 3C1 was found to block the binding of Factor XI to HMW kininogen, whereas 5F4 did not. We conclude: a domain on the heavy chain region of Factor XI is essential for binding to HMW kininogen and for optimal surface-mediated activation by Factor XIIa; and binding of 3C1 to Factor XI changes its conformation rendering it a more favorable substrate for Factor XIIa in the fluid phase.

• Scott CF, Silver LD, Purdon AD, Colman RW
• Cleavage of human high molecular weight kininogen by factor XIa in vitro. Effect on structure and function.
• J Biol Chem. 1985; 260: 10856-63
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• We have recently demonstrated that human high molecular weight kininogen (HMWK) is a pro-cofactor that is cleaved by kallikrein to yield a two-chain cofactor (HMWKa) and the nanopeptide bradykinin. This proteolysis enhances its association with an activating surface, an event necessary for expression of its cofactor activity. We now report that factor XIa is capable of hydrolyzing HMWK and releasing bradykinin in a purified system as well as cleaving and inactivating HMWK in a plasma environment during the contact-activation process. The profile of proteolysis differs from that produced by kallikrein and by factor XIIa in that the first cleavage by factor XIa yields 75- and 45-kDa polypeptides, whereas both factor XIIa and kallikrein initially produce 65- and 56-kDa species. Further proteolysis by all three enzymes eventually produces similar heavy chains (Mr = 65,000) and light chains (Mr = 45,000). However, the amount of factor XIa generated in plasma during contact activation further degrades the light chain of HMWK, eventually destroying its coagulant activity. Furthermore, in a purified system, enhancement of the degradation of HMWK coagulant activity by factor XIa was achieved when kallikrein was included in the incubation mixture, suggesting that the preferred substrate for factor XIa is the active form of HMWK (HMWKa), and not the pro-cofactor. These data suggest that factor XIa has the potential to act as a regulator of contact-activated coagulation by virtue of its ability to destroy the cofactor function of HMWK after its generation by either kallikrein, factor XIIa, or to a lesser extent, factor XIa, itself.

• Sinha D, Koshy A, Seaman FS, Walsh PN
• Functional characterization of human blood coagulation factor XIa using hybridoma antibodies.
• J Biol Chem. 1985; 260: 10714-9
• Display abstract

• During the initiation of intrinsic coagulation factors XI and XIa interact intimately with several other coagulation proteins (factor XIIa, high Mr kininogen, and factor IX) as well as with the platelet surface. To help elucidate these complex intramolecular interactions, we have prepared a collection of monoclonal antibodies directed against various epitopes in factor XI. We have utilized these reagents to isolate factor XI and the light chain of factor XIa on affinity columns, and to probe structure-function relationships involved in the interactions of factor XIa with factor IX. The isolated light chain of factor XIa retained greater than 90% of its amidolytic activity against the oligopeptide substrate pyro-Glu-Pro-Arg-pNA (S-2366), but only 3.8% of its clotting activity in a factor XIa assay and 1% of its factor IX activating activity in an activation peptide release assay. This suggests that regions of the heavy chain are required for development of coagulant activity and specifically for the interaction of factor XIa with factor IX. To test this hypothesis, the effects of three of the monoclonal antibodies (5F4, 1F1, and 3C1) on the function of factor XIa were examined. The results show that in a clotting assay the light chain-specific antibody (5F4) inhibits 100% of the factor XIa activity, whereas of the heavy chain-specific antibodies, one (3C1) inhibits 75% and another (1F1) only 17%. Similarly in the factor IX activation peptide release assay, antibody 5F4 inhibits 100% of the factor XIa activity, whereas 3C1 inhibits 75% and 1F1 inhibits 33%. We conclude that regions located in the heavy chain, in addition to those in the light chain, are involved in the interaction of factor XIa with factor IX and in the expression of the coagulant activity of factor XI.

• Warn-Cramer BJ, Bajaj SP
• Stoichiometry of binding of high molecular weight kininogen to factor XI/XIa.
• Biochem Biophys Res Commun. 1985; 133: 417-22
• Display abstract

• Factor XI is a dimeric protein and circulates in plasma complexed with high molecular weight kininogen (HMWK). We investigated the binding of HMWK to factor XIa utilizing two active site directed fluorescent probes: nitrobenzoxadiazole aminopentyl methylphosphonofluoridate for serine and dansyl-glu-gly-arg-chloromethyl ketone for histidine. In the presence of saturating amounts of HMWK, the fluorescence of factor XIa-fluorophore was quenched by approximately 28% for each probe. Titrations of the fluorescent factor XIa with HMWK revealed that each subunit of factor XIa binds one molecule of HMWK with a Kd approximately 3.4 X 10(-8)M.

• Walsh PN, Tuszynski GP
• Potentiation of the activity of coagulation factor XI by human platelets.
• Thromb Res. 1985; 40: 257-65

• Ragni MV, Sinha D, Seaman F, Lewis JH, Spero JA, Walsh PN
• Comparison of bleeding tendency, factor XI coagulant activity, and factor XI antigen in 25 factor XI-deficient kindreds.
• Blood. 1985; 65: 719-24
• Display abstract

• The relationship of clinical bleeding tendency and factor XI antigen (XI:Ag) in factor XI deficiency was studied in 78 members of 25 factor XI-deficient kindreds. Factor XI:Ag was measured in a competitive radioimmunoassay, using monospecific, heterologous anti-factor XI antibody. 125I-labeled factor XI, and staphylococcal protein A as the precipitating agent. Deficiency of factor XI clotting activity (XI:C), less than 0.62 U/mL, occurred in 48 individuals, 22 of whom experienced postoperative or posttraumatic bleeding: Their mean factor XI:C was 0.21 +/- 0.04 U/mL (SEM), and factor XI:Ag was 0.23 +/- 0.04 U/mL. The remaining 26 had no clinical bleeding, many despite surgical challenge: Their mean factor XI:C was 0.30 +/- 0.04 U/mL, and factor XI:Ag was 0.34 +/- 0.05 U/mL. In all, 13 kindreds had between 1 and 11 members with bleeding; the other 12 had none with deficient hemostasis. Two heterozygous factor XI-deficient individuals appeared to be positive for cross-reacting material (CRM+). The slope of the regression line for factor XI:C and factor XI:Ag data points in the 78 individuals tested did not differ from control, and all points fell within 95% confidence limits derived from control. In conclusion, bleeding tendency appears to be consistent within a given kindred and is not determined exclusively by factor XI:C or factor XI:Ag levels.

• Morgan K, Schiffman S, Feinstein D
• Acquired factor XI inhibitors in two patients with hereditary factor XI deficiency.
• Thromb Haemost. 1984; 51: 371-5
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• Two patients with hereditary factor XI deficiency developed inhibitors following plasma transfusions. Neither had severe spontaneous bleeding. The patients' plasmas neutralized both factor XI in plasma, purified factor XI, and purified factor XIa. The inhibitor in both patients' plasmas adsorbed to Protein A-Sepharose. The inhibitors eluted from Protein A-Sepharose were partially neutralized by kappa and lambda light chain antisera indicating that they were polyclonal IgG antibodies. Both inhibitors markedly decreased adsorption of factor XI to glass surfaces. The cleavage of factor XI by trypsin was unaffected by the inhibitors. The lack of severe spontaneous bleeding in both of these patients strongly suggests that an alternate coagulation mechanism bypassing factor XI must compensate for this severe defect.

• Walsh PN, Tuszynski GP, Greengard JS, Griffin JH
• The possible role of platelets in bypassing the contact phase of blood coagulation.
• Haematologia (Budap). 1984; 17: 169-78
• Display abstract

• Data presented herein and previously support an active role for platelets in promoting the interaction and activation of the coagulation proteins of the contact phase of intrinsic coagulation. The platelet membrane, activated by ADP collagen or thrombin, can promote the proteolytic activation of factor XII to factor XIIa in the presence of kallikrein and high molecular weight kininogen. The zymogen factor XI associates with high molecular weight kininogen in plasma and becomes bound to a site on the membrane of thrombin or collagen activated platelets. Thereafter, platelet bound factor XI can be proteolytically activated to factor XIa either in the presence of factor XIIa or in the presence of kallikrein. These observations could explain the absence of bleeding complications in patients with factor XII deficiency. In addition, platelets contain a molecule which has a higher molecular weight than plasma factor XI and possibly consists of a tetramer of four identical subunits of 52000 daltons each of which is functionally and immunologically similar to plasma factor XI. Since this molecule is present in the platelets of patients with severe plasma factor XI deficiency and no evidence of bleeding, we postulate that platelet factor XI can substitute for plasma factor XI in hemostasis and possibly account for the considerable variability in clinical severity observed in patients with factor XI deficiency.

• Sinha D, Seaman FS, Koshy A, Knight LC, Walsh PN
• Blood coagulation factor XIa binds specifically to a site on activated human platelets distinct from that for factor XI.
• J Clin Invest. 1984; 73: 1550-6
• Display abstract

• Binding of 125I-Factor XIa to platelets required the presence of high molecular weight kininogen, was enhanced when platelets were stimulated with thrombin, and reached a plateau after 4-6 min of incubation at 37 degrees C. Factor XIa binding was specific: 50- to 100-fold molar excesses of unlabeled Factor XIa prevented binding, whereas Factor XI, prekallikrein, Factor XIIa, and prothrombin did not. When washed erythrocytes, added at concentrations calculated to provide an equivalent surface area to platelets, were incubated with Factor XIa, only a low level of nonspecific, nonsaturable binding was detected. Factor XIa binding to platelets was partially reversible and was saturable at concentrations of added Factor XIa of 0.2-0.4 microgram/ml (1.25-2.5 microM). The number of Factor XIa binding sites on activated platelets was estimated to be 225 per platelet (range, 110-450). We conclude that specific, high affinity, saturable binding sites for Factor XIa are present on activated platelets, are distinct from those previously demonstrated for Factor XI, and require the presence of high molecular weight kininogen.

• van der Graaf F, Greengard JS, Bouma BN, Kerbiriou DM, Griffin JH
• Isolation and functional characterization of the active light chain of activated human blood coagulation factor XI.
• J Biol Chem. 1983; 258: 9669-75
• Display abstract

• Human blood coagulation Factor XIa was reduced and alkylated under mild conditions. The mixture containing alkylated heavy and light chains was subjected to affinity chromatography on high Mr kininogen-Sepharose. Alkylation experiments using [14C]iodoacetamide showed that a single disulfide bridge between the light and heavy chains was broken to release the light chain. The alkylated light chain (Mr = 35,000) did not bind to high Mr kininogen-Sepharose while the heavy chain (Mr = 48,000), like Factors XI and XIa, bound with high affinity. The isolated light chain retained the specific amidolytic activity of native Factor XIa against the oligopeptide substrate, pyroGlu-Pro-Arg-p-nitroanilide. Km and kcat values for this substrate were 0.56 mM and 350 s-1 for both Factor XIa and its light chain, and the amidolytic assay was not affected by CaCl2. However, in clotting assays using Factor XI-deficient plasma in the presence of kaolin, the light chain was only 1% as active as native Factor XIa. Human coagulation Factor IX was purified and labeled with sodium [3H]borohydride on its carbohydrate moieties. When this radiolabeled Factor IX was mixed with Factor XIa, an excellent correlation was observed between the appearance of Factor IXa clotting activity and tritiated activation peptide that was soluble in cold trichloroacetic acid. Factor XIa in the presence of 5 mM CaCl2 activated 3H-Factor IX 600 times faster than Factor XIa in the presence of EDTA. In the absence of calcium, Factor XIa and its light chain were equally active in activating 3H-Factor IX. In contrast to Factor XIa, the light chain in this reaction was inhibited by calcium ions such that, in the presence of 5 mM CaCl2, Factor XIa was 2000 times more effective than its light chain. Neither phospholipid nor high Mr kininogen and kaolin affected the activity of Factor XIa or its light chain in the activation of 3H-Factor IX. These observations show that the light chain region of Factor XIa contains the entire enzymatic active site. The heavy chain region contains the high affinity binding site for high Mr kininogen. Furthermore the heavy chain region of Factor XIa plays a major role in the calcium-dependent mechanisms that contribute to the activation of Factor IX.

• Bouma BN, Vlooswijk RA, Griffin JH
• Immunological studies of human Factor XI and prekallikrein: demonstration of complex formation with high molecular weight kininogen.
• Adv Exp Med Biol. 1983; 156: 109-13

• Bouma BN, Vlooswijk RA, Griffin JH
• Immunologic studies of human coagulation factor XI and its complex with high molecular weight kininogen.
• Blood. 1983; 62: 1123-31
• Display abstract

• Coagulation factor XI was purified from human plasma using ion-exchange chromatography and affinity chromatography on high molecular weight kininogen-Sepharose. A monospecific precipitating antiserum was prepared and used to study factor XI antigen. Factor XI did not migrate during electrophoresis at pH 8.3. High molecular weight kininogen (HMWK), an alpha globulin, reversibly associates with factor XI. Complex formation between HMWK and factor XI was observed under conditions of crossed-immunoelectrophoresis. Using Laurell rocket immunoelectrophoresis, it was shown that the isolated alkylated light chain of kinin-free HMWK formed a complex with factor XI. In contrast to previous studies of prekallikrein, titrations of factor XI with increasing amounts of HMWK did not give a simple titration curve, suggesting that factor XI dissociates from the complex during electrophoresis. Prekallikrein and factor XI were shown to compete for the same HMWK molecules under the conditions of immunoelectrophoresis, and prekallikrein appeared to have a higher affinity for binding to HMWK than factor XI. Quantitative determinations of factor XI antigen in plasma by rocket immunoelectrophoresis were made. The average amount of factor XI measured in plasma samples from 20 normal individuals was 4.5 micrograms/ml (range 3-6). No factor XI antigen was detected in plasma from a patient deficient in factor XI. Normal factor XI antigen levels were detected in 3 different HMWK-deficient plasmas only if the plasmas were reconstituted with purified HMWK (2 U/ml). Addition of HMWK to normal plasma resulted in an increase of the factor XI antigen rocket. At HMWK levels of 2 U/ml, no further increase of the factor XI antigen rocket was observed. Therefore, accurate measurement of factor XI antigen by rocket immunoelectrophoresis is possible only if an excess of HMWK is present.

• Fujikawa K, McMullen BA
• Amino acid sequence of human beta-factor XIIa.
• J Biol Chem. 1983; 258: 10924-33
• Display abstract

• Human factor XII was activated by limited proteolysis with trypsin, and the resulting beta-factor XIIa (Mr = 30,000) was isolated by DEAE-Sephacel column chromatography. The complete amino acid sequence of beta-factor XIIa was then determined on peptides produced by enzymatic digestion with either trypsin, chymotrypsin, or Staphylococcus aureus V8 protease and by chemical cleavage at methionyl and tryptophyl bonds. beta-Factor XIIa is a glycoprotein composed of a heavy chain (243 amino acid residues) and a light chain (9 amino acid residues), and these two chains are held together by a disulfide bond. The carbohydrate is attached to asparagine residue 61 in the heavy chain. The amino acid sequence of the heavy chain shows a high degree of homology to the corresponding regions of other plasma serine proteases, such as plasmin, thrombin, factor IXa and factor Xa, as well as the pancreatic digestive enzymes. These results demonstrate that factor XII is the precursor of a typical serine protease that participates in the coagulation cascade.

• Mannhalter C, Schiffman S
• Surface adsorption of factor XI. II. Evidence that different mechanisms are involved in binding to glass and plastic materials.
• Thromb Haemost. 1982; 47: 214-7
• Display abstract

• Blood coagulation factors XI and XIa possess binding site(s) for glass and plastics, located in the heavy chain of the molecule. To elucidate the nature of binding, adsorption and desorption properties of factor XI and XIa to different surfaces have been studied. Desorption experiments with high salt (2.4 M NaC1) suggest participation of ionic forces in the binding to glass. This is consistent with the decreased adsorption of factor XI (pI-9.0) to glass with increasing pH. The non-ionic detergent Triton X-100, which splits hydrophobic bonds, desorbs factor XI very well from plastics and partially from glass. The anionic detergent SDS, which will split hydrophobic as well as ionic bonds, is the most effective agent tested for the elution of factor XI from glass. We, therefore infer, that the binding of factor XI to glass is the combined effect of ionic and hydrophobic binding, whereas the adsorption of factor XI to plastics is primarily hydrophobic.

• Morgan K, Schiffman S
• Role of charged groups in factor XI/XIa activity.
• J Biol Chem. 1982; 257: 11284-7
• Display abstract

• To elucidate the role of charged groups in expression of factor XI coagulant activity, the charged groups of purified human blood coagulation factor XI/XIa containing 125I-XI/XIa were derivatized: free amino groups by succinylation, guanido groups of arginine by reaction with phenylglyoxal hydrate, and free carboxyl groups by reaction with ethylenediamine. The modified proteins were tested for: 1) ability to adsorb to glass, 2) ability to be cleaved by trypsin or factor XII-high molecular weight kininogen, 3) coagulant activity. The amino group-modified factor XI had a significantly decreased ability to bind to glass; modification of arginine or carboxyl groups did not affect adsorption. Trypsin cleaved factor XI with modified free amino, guanido, or carboxyl groups. Factor XII-high molecular weight kininogen could cleave only the arginine-modified factor XI. Amino group-modified factor XI and carboxyl group-modified factor XI lost all their factor XI assay activity, whereas arginine-modified factor XI retained 50% of the original activity. Amino group-modified factor XI could not be activated by trypsin, but arginine-modified and carboxyl group-modified factor XI could be activated by trypsin to 50% of the original activity. Succinylation of the amino groups of factor XIa destroyed all its factor XIa activity. Arginine-modified and carboxyl group-modified factor XIa retained 50% of their factor XIa activity. We conclude that epsilon-amino groups are essential for adsorption; activation by factor XII-high molecular weight kininogen requires free amino and carboxyl but not guanido groups; free amino, carboxyl, and guanido groups in factor XIa all appear to be critical for interaction of factor XIa with factor IX.

• Tuszynski GP, Bevacqua SJ, Schmaier AH, Colman RW, Walsh PN
• Factor XI antigen and activity in human platelets.
• Blood. 1982; 59: 1148-56
• Display abstract

• Washed platelets, contaminated with less than 0.20% plasma factor XI, were examined for the presence of factor XI antigen and activity. These platelets contained a factor-XI-like coagulant activity (0.67 +/- 0.11 U/10(11) platelets) that remained constant after successive washes. By means of indirect immunofluorescence, a monospecific antibody to factor XI showed specific staining of both normal platelets and platelets from patients deficient in plasma factor XI. Radiolabeled Triton extracts of washed platelets and labeled purified factor XI solutions were analyzed for factor XI antigen by Staph A immunoprecipitation analysis using antibody to purified plasma factor XI followed by SDS gel electrophoresis. On unreduced gels, the platelet material ran as a single band having an apparent molecular weight of 220,000 daltons, whereas purified plasma factor XI gave a single band at 160,000 daltons. On reduced gels, the platelet material analyzed as a single band at 52,000 daltons, whereas purified factor XI gave a single band of 80,000 daltons. Analysis of a partially purified factor XI preparation from platelets by immunoelectrophoresis revealed that the platelet preparation displayed a slightly lower cathodal electrophoretic mobility at pH 8.6 than did plasma factor XI and yet appeared to possess complete antigenic identity with plasma factor XI. These results indicate that platelets possess a form of factor XI that exists as a disulfide-linked 52,000-dalton tetramer in contrast to the plasma form that circulates as a 80,000-dalton disulfide-linked dimer.

• Maki M
• [Biochemical mechanism of blood coagulation (author's transl)]
• Rinsho Byori. 1981; 29: 1-10

• Jacobs A, Mannhalter C, Margalit R, Schiffman S
• Contact activation of factor XI.
• Br J Haematol. 1981; 49: 77-86
• Display abstract

• Factor XI is a circulating trace plasma protein composed of two similar or identical chains of about 80 000 daltons which upon activation undergo proteolytic cleavage. Recently, we have shown that trypsin activation leads to an active factor XI (factor XIa) which, on reduction, yields three chains of 46 000, 37 000 and 26 000 daltons. Herein, we re-evaluate the effect of contact activation of factor XI at an activating surface both in normal human plasma and in a mixture of purified factors XI, XII, and high molecular weight kininogen (HMWK). Mixtures were analysed by coagulant activity and by reduced sodium dodecyl sulphate polyacrylamide gel electrophoresis using [125I]factor XI. In the purified system, fully activated factor XI on reduction yielded chains of 46 000, 37 000 and 23 000 daltons. In contrast, factor XI activated by surface contact in plasma yielded on reduction only chains of 46 000 and 37 000 daltons in addition to some uncleaved 80 000 chain. We propose that factor XIa containing only 46 000 and 37 000 chains be designated factor XIa alpha, and that factor XIa containing the third chain of 23 000 daltons be designated factor XI a beta. Sequential elution of contact activated plasma factor XI revealed that factor XIa was attached to the glass surface through the 46 000 dalton chain.

• Kurachi K, Fujikawa K, Davie EW
• Mechanism of activation of bovine factor XI by factor XII and factor XIIa.
• Biochemistry. 1980; 19: 1330-8

• Mannhalter C, Schiffman S, Jacobs A
• Trypsin activation of human factor XI.
• J Biol Chem. 1980; 255: 2667-9
• Display abstract

• Human factor XI circulates as a zymogen composed of two similar or identical chains of Mr = 80,000. Upon activation either by trypsin or by blood-clotting proteins involving clotting factors XII and high molecular weight kininogen, it undergoes proteolytic cleavage in which the Mr = 80,000 chain reportedly is cleaved to a heavy and light chain of Mr of about 48,000 and 33,000, respectively. In these studies, we have reinvestigated trypsin activation of factor XI and demonstrate that trypsin-activated factor XI contains three chains of apparent Mr = 46,000, 37,000, and 26,000. Kinetic studies lead to the conclusion that the parent chain of Mr = 80,000 is cleaved into chains of Mr = 46,000 and 37,000. This cleavage is followed by a second nondestructive cleavage, most probably of the chain of Mr = 46,000, to yield the third product which migrates as a band of Mr = 26,000.

• Mannhalter C, Schiffman S
• Surface adsorption of factor XI. Association of adsorption sites with the heavy chain of activated factor XI.
• Thromb Haemost. 1980; 43: 124-6
• Display abstract

• These experiments study surface adsorption of native and activated factor XI using purified radiolabelled human factor XI and trypsin activated factor XI. Both forms of factor XI adsorb not only to glass but also to polypropylene, polyethylene and polystyrene. Albumin (10 mg/ml) markedly reduces adsorption to plastics but not to glass. Sodium dodecyl sulfate prevents adsorption to all surfaces tested. Reduction of 125I-activated factor XI in the presence of sodium dodecyl sulfate yields labelled chains of molecular weight of about 46,000 (heavy chain), 37,000 (light chain) and a further breakdown product of about 26,000. Reduction of activated factor XI in glass or plastic in the absence of sodium dodecyl sulfate yields only light chain and breakdown product in solution; heavy chain is removed by adsorption. Therefore, we conclude that the adsorption site (s) in trypsin activated factor XI and presumably also in native factor XI is (are) located in the heavy chain subunit of the molecule.

• Margalit R, Schiffman S
• Factor XI adsorption to surface: interaction of high molecular weight kininogen (HMWK) and a plasma adsorption inhibitor.
• Blood. 1980; 56: 168-72

• Silverberg M, Nicoll JE, Kaplan AP
• The mechanism by which the light chain of cleaved HMW-kininogen augments the activation of prekallikrein, factor XI and Hageman factor.
• Thromb Res. 1980; 20: 173-89

• Kato H
• [Initiation mechanism of intrinsic blood coagulation: activation of factor XII and roles of high-molecular-weight kininogen (author's transl)]
• Seikagaku. 1980; 52: 1173-200

• Heimark RL, Davie EW
• Isolation and characterization of bovine plasma prekallikrein (Fletcher factor).
• Biochemistry. 1979; 18: 5743-50
• Display abstract

• Prekallikrein (Fletcher factor) has been purified from bovine plasma approximately 25 000-fold with an overall yield of 14%. Purification steps included ammonium sulfate fractionation and column chromatography on heparin-agarose, DEAE-Sephadex, CM-Sephadex, benzamidine-agarose, and arginine methyl ester-agarose. The purified protein was homogeneous as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and amino-terminal sequence analysis. Bovine plasma prekallikrein is a glycoprotein with a molecular weight of 82 000 as determined by sedimentation equilibrium centrifugation. It contains 12.9% carbohydrate, including 6.2% hexose, 4.5% N-acetylglucosamine, and 2.2% N-acetylneuraminic acid. Prekallikrein is a single polypeptide chain with an amino-terminal sequence of Gly-Cys-Leu-Thr-Gln-Leu-Tyr-His-Asn-Ile-Phe-Phe-Arg-Gly-Gly. This sequence is homologous to the amino-terminal sequence of human factor XI (plasma thromboplastin antecedent). Both prekallikrein and kallikrein require kaolin to correct Fletcher factor deficient plasma. Kallikrein, however, has a specific activity 3.5 times greater than prekallikrein. Prekallikrein does not correct plasma deficient in factor XII (Hageman factor), factor XI, or high molecular weight kininogen (Fitzgerald factor).

• Koide T, Kato H, Davie EW
• Isolation and characterization of bovine factor XI (plasma thromboplastin antecedent).
• Biochemistry. 1977; 16: 2279-86
• Display abstract

• Factor XI (plasma thromboplastic antecedent) has been purified approximately 28 000-fold from bovine plasma with an overall yield of about 30%. The isolation procedure involves barium sulfate adsorption of contaminants, ammonium sulfate precipitation, and chromatography on heparin-agarose, CM-Sephadex, and DEAE-Sephadex. The final product was homogeneous when examined by polyacrylamide gel electrophoresis and immunoelectrophoresis. A minimal mol wt of 124 000 was determined by sedimentation equilibrium. Factor XI is composed of two similar or identical polypeptide chain (mol wt of approximately 55 000), and these two chains are held together by a disulfide bond(s). Factor XI is a glycoprotein which contains approximately 11% carbohydrate including 5.4% heose, 4.7% N-acetylhexosamine, and 1.0% N-acetylneuraminic acid. Other properties of this coagulation factor including its amino acid composition and inhibition by antibodies prepared in rabbits are also reported.

• Koide T, Hermodson MA, Davie EW
• Active site of bovine factor XI (plasma thromboplastin antecedent).
• Nature. 1977; 266: 729-30

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