The epidermal growth factor-like domains of factor IX. Effect on blood clotting and endothelial cell binding of a fragment containing the epidermal growth factor-like domains linked to the gamma-carboxyglutamic acid region

The binding of factor IX to cultured bovine endothelial cells was characterized using isolated domains of bovine factor IX. An NH2-terminal fragment that consists of the gamma-carboxyglutamic acid (Gla) region linked to the two epidermal growth factor (EGF)-like domains bound to the endothelial cells with the same affinity as intact factor IX, indicating that the serine protease part of factor IX is not involved in binding. This fragment also inhibited the factor IXa beta'-induced clotting of plasma at a concentration that would suggest a competition for phospholipid binding sites. However, after proteolytic removal of the Gla region from the fragment, the two EGF-like domains inhibited clotting almost as effectively, suggesting a direct interaction between this part of the molecule and the cofactor, factor VIIIa. Using affinity-purified Fab fragments against the Gla region, the EGF-like domains, and the serine protease part, it was observed that the serine protease part of the molecule undergoes a large conformational change upon activation, whereas the Gla region and the EGF-like domains appear to be unaffected. All three classes of Fab fragments were equally efficient as inhibitors of the factor IXa beta'-induced clotting reaction. Part of factor Va and factor VIIIa have significant sequence homology to a lectin. We therefore investigated the effect on in vitro clotting of the recently identified unique disaccharide Xyl alpha 1-3Glc, that is O-linked to a serine residue in the NH2-terminal EGF-like domain of human factor IX (Hase, S., Nishimura, H., Kawabata, S.-I., Iwanaga, S., and Ikenaka, T. (1990) J. Biol. Chem. 265, 1858-1861). However, no effect on blood clotting was observed in the assay system used. Our results are compatible with a model in which the serine protease part provides the specificity of the binding of factor IXa to factor VIIIa-phospholipid, but that the EGF-like domain(s) also contributes to the interaction of the enzyme with its cofactor.     

An anti-EGF monoclonal antibody that detects intramolecular communication in factor IX

Coagulation factor IX contains a gamma-carboxyglutamic acid (Gla) module, two epidermal growth factor-like (EGF) modules, and a serine protease region. We have characterized a mouse monoclonal antibody that binds the N-terminal EGF-like module of human factor IX with high affinity. Studies of recombinant factor IX mutants indicated that the epitope is located in the C-terminal end of the EGF-like module, which is consistent with the binding being non-Ca(2+)-dependent. The antibody bound factor IXa (K(D) = 7.6 x 10(-10) M) with about 10-fold higher affinity than factor IX (K(D) = 6.2 x 10(-9) M). Binding of the antibody to factor IXa did not affect the amidolytic activity of the protein, nor was binding affected by active site inhibition of factor IXa. These results are consistent with long-range interactions between the serine protease region and the N-terminal EGF-like module in factor IX.     

Construction, expression, and characterization of a chimera of factor IX and factor X. The role of the second epidermal growth factor domain and serine protease domain in factor Va binding.

The prothrombinase complex, which catalyzes the conversion of prothrombin to thrombin, consists of activated Factor X, Factor Va, a membrane surface and Ca2+. To examine the structures that support Factor Va binding to Factor X, we used in vitro mutagenesis to construct a chimeric molecule that includes regions of Factor IX and Factor X. This chimera (IXGla,E1XE2,SP) was prepared from cDNA encoding the second epidermal growth factor (EGF) and serine protease domains of Factor X linked downstream from the cDNA encoding the signal peptide, propeptide, Gla domain, and first EGF domain of Factor IX. The cDNAs encoding the Factor IX/X chimera and wild-type Factor X were each expressed in Chinese hamster ovary cells and the secreted proteins purified by affinity chromatography using polyclonal anti-Factor X antibodies. The chimera migrated as a single major band corresponding to a molecular weight of 68,000. By Western blotting, the chimeric protein stained with both polyclonal anti-Factor X and anti-Factor IX antibodies. gamma-Carboxyglutamic acid analysis demonstrated near complete carboxylation of both the wild-type Factor X and the Factor IX/X chimera. Compared with Factor X, the rate of zymogen activation of the Factor IX/X chimera was about 50% that of Factor X when activated by Factor IXa, Factor VIIIa, phospholipid, and Ca2+. The enzyme form of the Factor IX/X chimera, activated Factor IX/X, generated using the coagulant protein of Russell's viper venom, expressed full amidolytic activity compared with Factor Xa. The activated Factor IX/X chimera had about 14% of the activity of Factor Xa when employed in a prothrombinase assay; this activity reached 100% with increasing concentrations of Factor Va. A binding assay was employed to test the ability of the active site-inactivated Factor IX/Xa chimera to inhibit the binding of Factor Xa to the Factor Va-phospholipid complex, thus inhibiting the activation of prothrombin to thrombin. In this assay the active site-inactivated form of the chimera competed with Factor Xa completely but with decreased affinity for the Factor Va-phospholipid complex. These data indicate that the second EGF domain and the serine protease domain of Factor Xa are sufficient to interact with Factor Va. The Factor IX/X chimera is a good substrate for the tenase complex; the defective enzymatic activity of the activated Factor IX/X chimera can be accounted for by its decreased affinity for Factor Va relative to Factor Xa.     

Structural requirements for Ca2+ binding to the gamma-carboxyglutamic acid and epidermal growth factor-like regions of factor IX. Studies using intact domains isolated from controlled proteolytic digests of bovine factor IX

Blood coagulation factor IX is composed of discrete domains with an NH2-terminal vitamin K-dependent gamma-carboxyglutamic acid (Gla)-containing region, followed by two domains that are homologous with the epidermal growth factor (EGF) precursor and a COOH-terminal serine protease part. Calcium ions bind to the Gla-containing region and to the NH2-terminal EGF-like domain. To be able to determine the structure and function of the Gla- and EGF-like domains, we have devised a method for cleaving factor IX under controlled conditions and isolating the intact domains in high yield, either separately or linked together. The Ca2+ and Mg2+ binding properties of these fragments were examined by monitoring the metal ion-induced changes in intrinsic protein fluorescence. A fragment, consisting of the Gla region linked to the two EGF-like domains, bound Ca2+ in a manner that was indistinguishable from that of the intact molecule, indicating a native conformation. The Ca2+ affinity of the isolated Gla region was lower, suggesting that the EGF-like domains function as a scaffold for the folding of the Gla region. The Gla-independent high affinity metal ion binding site in the NH2-terminal EGF-like domain was shown to bind Ca2+ but not Mg2+. A comparison with similar studies of factor X (Persson, E., Bj?rk, I., and Stenflo, J. (1991) J. Biol. Chem. 266, 2444-2452) suggests that the Ca2(+)-induced fluorescence quenching is due to an altered environment primarily around the tryptophan residue in position 42.     

The Gla domain of factor IXa binds to factor VIIIa in the tenase complex

During blood coagulation factor IXa binds to factor VIIIa on phospholipid membranes to form an enzymatic complex, the tenase complex. To test whether there is a protein-protein contact site between the gamma-carboxyglutamic acid (Gla) domain of factor IXa and factor VIIIa, we demonstrated that an antibody to the Gla domain of factor IXa inhibited factor VIIIa-dependent factor IXa activity, suggesting an interaction of the factor IXa Gla domain with factor VIIIa. To study this interaction, we synthesized three analogs of the factor IXa Gla domain (FIX1-47) with Phe-9, Phe-25, or Val-46 replaced, respectively, with benzoylphenylalanine (BPA), a photoactivatable cross-linking reagent. These factor IX Gla domain analogs maintain native tertiary structure, as demonstrated by calcium-induced fluorescence quenching and phospholipid binding studies. In the absence of phospholipid membranes, FIX1-47 was able to inhibit factor IXa activity. This inhibition is dependent on the presence of factor VIIIa, suggesting a contact site between the factor IXa Gla domain and factor VIIIa. To demonstrate a direct interaction we did cross-linking experiments with FIX1-479BPA, FIX1-4725BPA, and FIX1-4746BPA. Covalent cross-linking to factor VIIIa was observed primarily with FIX1-4725BPA and to a much lesser degree with FIX1-4746BPA. Immunoprecipitation experiments with an antibody to the C2 domain of factor VIIIa indicate that the factor IX Gla domain cross-links to the A3-C1-C2 domain of factor VIIIa. These results suggest that the factor IXa Gla domain contacts factor VIIIa in the tenase complex through a contact site that includes phenylalanine 25 and perhaps valine 46.     

Zymogen factor IX potentiates factor IXa-catalyzed factor X activation

Intrinsic factor X activation is accelerated >10(7)-fold by assembly of the entire complex on the activated platelet surface. We have now observed that increasing the concentration of zymogen factor IX to physiologic levels ( approximately 100 nM) potentiates factor IXa-catalyzed activation of factor X on both activated platelets and on negatively charged phospholipid vesicles. In the presence and absence of factor VIIIa, factor IX (100 nM) lowered the K(d,appFIXa) approximately 4-fold on platelets and 2-10-fold on lipid vesicles. Treatment of two factor IX preparations with active-site inhibitors did not affect these observations. Autoradiographs of PAGE-separated reactions containing either (125)I-labeled factor IX or (125)I-labeled factor X showed that the increased factor X activation was not due to factor Xa-mediated feedback activation of factor IX and that there was increased cleavage of factor X heavy chain in the presence of factor IX in comparison with control reactions but only in the presence of both the enzyme and the surface. Since plasma concentrations of prothrombin, factor VII, protein C, or protein S did not by themselves potentiate factor Xa generation and did not interfere with the potentiation of the reaction of factor IX, the effect is specific for factor IX and is not attributable to the Gla domain of all vitamin K-dependent proteins. These observations indicate that under physiologic conditions, plasma levels of the zymogen factor IX specifically increase the affinity of factor IXa for the intrinsic factor X activation complex.     

The gamma-carboxyglutamic acid and epidermal growth factor-like domains of factor X. Effect of isolated domains on prothrombin activation and endothelial cell binding of factor X

Factor Xa is the enzymatically active constituent of the prothrombinase complex, which catalyzes the conversion of prothrombin to thrombin. We have isolated fragments, from tryptic digests of factor X, that consists of the gamma-carboxyglutamic acid (Gla) region linked to one or two epidermal growth factor (EGF)-like domains. Calcium ion binding measurements indicated that these fragments have a native conformation. The factor X-GlaEGF fragments inhibit factor Xa-induced blood clotting in a manner suggesting that they compete with factor Xa for phospholipid binding sites. The same conclusion was reached when thrombin generation was studied in a system of purified components (factor Xa, factor Va, prothrombin, phospholipid, and Ca2+). There was no evidence for a strong interaction between the EGF-like domains of factor Xa and factor Va in either system. However, experiments in the purified system without phospholipid indicated a direct, albeit weak, interaction between the Gla region of factor Xa and factor Va and between the COOH-terminal EGF-like domain of factor Xa and factor Va. Using domain-specific Fab fragments, we have confirmed that the conformation of the serine protease region alters dramatically upon activation of factor X. Furthermore, we have demonstrated that the conformation of the Gla region is affected by the activation, whereas the EGF-like domains appear to be unaltered. The association constant for factor X binding to endothelial cells was two orders of magnitude lower than that for binding of factor IX to these cells. Binding of the Gla and GlaEGF fragments suggested Gla-mediated binding to phospholipid rather than binding to a specific receptor.     

The insect salivary protein, prolixin-S, inhibits factor IXa generation and Xase complex formation in the blood coagulation pathway

Prolixin-S is a salivary anticoagulant of the blood-sucking insect, Rhodnius prolixus, and known as an inhibitor of the intrinsic Xase. We report here its inhibitory mechanisms with additional important anticoagulation activities. We found prolixin-S specifically bound to factor IX/IXa in the presence of Ca(2+) ions. Light scattering and surface plasmon resonance studies showed that prolixin-S interfered with factor IX/IXa binding to the phospholipid membrane, indicating that prolixin-S inhibit Xase activity of factor IXa by interference with its Xase complex formation. Furthermore, reconstitution experiments showed that prolixin-S binding to factor IX strongly inhibited factor IXa generation by factor XIa. We also found that prolixin-S inhibited factor IXa generation by factor VIIa-tissue factor complex and factor IXalpha generation by factor Xa. These results suggest that prolixin-S inhibits both intrinsic and extrinsic coagulations by sequential inhibition of all coagulation pathways in which factor IX participates. It was also suggested that prolixin-S may bind to factor IX/IXa by recognizing conformational change of the Gla domain induced by Ca(2+) binding.     

The N-terminal epidermal growth factor-like domain of coagulation factor IX. Probing its functions in the activation of factor IX and factor X with a monoclonal antibody

The absence or reduced activity of coagulation factor IX (FIX) causes the severe bleeding disorder hemophilia B. FIX contains an N-terminal Gla domain followed by two epidermal growth factor-like (EGF) domains and a serine protease domain. In this study, the epitope of monoclonal antibody AW, which is directed against the C-terminal part of the first EGF domain in human FIX, was defined, and the antibody was used to study interactions between the EGF domain of FIX and other coagulation proteins. Antibody AW completely blocks activation of FIX by activated factor XI, but activation by activated factor FVII-tissue factor is inhibited only slightly. The antibody also causes a marginal reduction in the apparent k(cat) for factor X both in the presence and absence of activated factor VIII. Based on these results, we produced a preliminary model of the structure of the activated factor IX-activated factor VIII-AW complex on the surface of phospholipid. The model suggests that in the Xase complex, EGF1 of activated factor IX is not involved in direct binding to activated factor VIII. Studies of the interaction of antibody AW with a mutated FIX molecule (R94D) also suggest that the Glu(78)-Arg(94) salt bridge is not important for maintaining the structure of FIX.     

Protein structural requirements for Ca2+ binding to the light chain of factor X. Studies using isolated intact fragments containing the gamma-carboxyglutamic acid region and/or the epidermal growth factor-like domains

Coagulation factor X is a multidomain proenzyme of a serine protease. Calcium ions bind to the vitamin K-dependent gamma-carboxyglutamic acid (Gla) residues and to a site in the NH2-terminal of two epidermal growth factor (EGF)-like domains. To study structure-function relationships in the NH2-terminal part of factor X and to determine the structure of isolated domains, we have developed methods that allow the subsequent isolation of the first or both EGF-like domains with or without an attached Gla domain from controlled proteolytic digests of the protein. The Ca2(+)-induced changes of the intrinsic protein fluorescence were measured to elucidate whether the isolated fragments retain their native conformation. Changes in the fluorescence caused by Ca2+ binding were found to result from perturbations of the environment of the Trp residue in position 41. Calcium ion binding to the Gla-containing region linked to the NH2-terminal EGF-like domain was identical with that to intact factor X, indicating a native orientation of the ligand binding groups in the fragment. In contrast, the isolated Gla peptide had a lower affinity for Ca2+, suggesting that the NH2-terminal EGF-like domain serves as a scaffold for the folding of the Gla region. Similarly, the presence of the Gla region was found to increase the affinity of the Gla-independent site in the first EGF-like domain for Ca2+. The metal ion-induced resistance against chymotryptic cleavage COOH-terminal of Tyr-44 in intact factor X is similar in the isolated fragment that contains the Gla region linked to one EGF-like domain, indicating a native conformation of the fragment in the presence of Ca2+. Furthermore, the Gla-independent metal ion binding site binds Ca2+ but does not appear to bind Mg2+.     

Kinetic comparison of bovine blood coagulation factors IXa alpha and IXa beta toward bovine factor X

The Vmax/Km (microM -1 min -1.) for bovine factor X activation by bovine factor IXa alpha, in the presence of sufficient [Ca2+] to saturate the initial reaction rate, was 0.007. When factor IXa beta was substituted for factor IXa alpha in this reaction, the Vmax/Km decreased to 0.001, suggesting that factor IXa alpha was a more potent catalyst under these conditions. When phospholipid (PL) vesicles (egg phosphatidylcholine/bovine brain phosphatidylserine, 4:1 w/w) were added to these same systems, at levels sufficient to saturate their effects, little change in the Vmax/Km occurred when factor IXa alpha was the enzyme. However, when factor IXa beta was employed, the Vmax/Km dramatically increased to 0.023, demonstrating that factor IXa beta responded to PL addition to a much greater extent than did factor IXa alpha. Upon addition of thrombin-activated factor VIII (factor VIIIa,t), at a suboptimal level, to the above systems, the Vmax/Km for factor X activation by factor IXa alpha/Ca2+/PL/factor VIIIa,t was increased to 1.0, whereas this parameter for factor X activation by factor IXa beta/Ca2+/PL/factor VIIIa,t under the same conditions was found to be 27.3. During these studies, it was discovered that the factor X which became activated to factor Xa during the course of reaction participated in several feedback reactions: activation of factor X, activation of factor VIII, and conversion of factor IXa alpha to factor IXa beta. All feedback reactions, which are capable of complicating the kinetic interpretation, were inhibited by performing the studies in a system which contained a rapid factor Xa inhibitor, Glu-Gly-Arg-CH2Cl, thus allowing kinetic constants to be accurately determined. The results show that while factor IXa alpha is a more efficient enzyme than factor IXa beta toward factor X activation in the absence of cofactors, the response of factor IXa beta to the reaction cofactors, PL and factor VIIIa,t, is much greater than that of factor IXa alpha.     

Reactivity of bovine blood coagulation factor IXa beta, factor Xa beta, and factor XIa toward fluorogenic peptides containing the activation site sequences of bovine factor IX and factor X

The published activation site sequences of bovine factors IX and X have been utilized to synthesize a number of peptides specifically designed respectively as substrates for bovine factors XIa and IXa beta. The substrates contain a fluorophore (2-aminobenzoyl group, Abz) and a quenching group (4-nitrobenzylamide, Nba) that are separated upon enzymatic hydrolysis with a resultant increase in fluorescence that was utilized to measure hydrolysis rates. Factor XIa cleaved all of the peptides bearing factor IX activation site sequences with Abz-Glu-Phe-Ser-Arg-Val-Val-Gly-Nba having the highest kcat/KM value. The kinetic behavior of factor XIa toward the synthetic peptide substrate indicates that it has a minimal extended substrate recognition site at least five residues long spanning S4 to S1' and has favorable interactions over seven subsites. The hexapeptide Abz-Glu-Phe-Ser-Arg-Val-Val-Nba was the most specific factor XIa substrate and was not hydrolyzed by factors IXa beta or Xa beta or thrombin. Factor IXa beta failed to hydrolyze any of the synthetic peptides bearing the activation site sequence of factor X. This enzyme slowly cleaved four hexa- and heptapeptide substrates with factor IX activation site sequences extending from P4 or P3 to P3'. Factor Xa beta poorly hydrolyzed all but one of the factor XIa substrates and failed to cleave any of the factor IXa beta substrates. Thrombin failed to hydrolyze any of the peptides examined while trypsin, as expected, was highly reactive and not very specific. Phospholipids had no effect on the reactivity of either factors IXa beta or Xa beta toward synthetic substrates. Both factor IXa beta and Xa beta cleaved the peptide substrates at similar rates to their natural substrates under comparable conditions. However the rates were substantially lower than optimum activation rates observed in the presence of Ca2+, phospholipids, and protein cofactors. In the future, it may be useful to investigate synthetic substrates that can bind to phospholipid vesicles in the same manner as the natural substrates for factors IXa beta and Xa beta.     

Characterization of the functional defect in factor IX Alabama. Evidence for a conformational change due to high affinity calcium binding in the first epidermal growth factor domain

Factor IX Alabama is a factor IX variant in which a glycine has been substituted for Asp47 in the first epidermal growth factor (EGF) domain. The structural defect in factor IX Alabama results in a molecule with 10% of normal coagulant activity. The interactions of immunoaffinity-purified factor IX Alabama with its activator, cofactors, and substrate have been investigated to determine the functional defect in the variant. Factor IX Alabama is activated by factor XIa/calcium at near normal rates. Calcium fluorescence-quenching experiments indicate that high affinity calcium binding in the first EGF domain is not altered in factor IX Alabama. The active site of factor IXa Alabama is fully competent to activate factor X in the absence of calcium when using polylysine as a surface to catalyze the reaction. Factor IXa Alabama has only 64% of normal factor IXa activity in the presence of 300 microM CaCl2 in the polylysine-catalyzed system although apparent high affinity calcium binding constants are similar. Factor IXa Alabama has 52-60% of normal activity in a calcium/phospholipid vesicle system. The addition of factor VIIIa to the phospholipid vesicle system decreases the relative rate of factor IXa Alabama to 18-19% of normal. Three-dimensional computer-aided models of the first EGF domain of normal factor IX and factor IX Alabama indicate no major structural alterations resulting from the glycine substitution for Asp47. The model of the first EGF domain of normal factor IX predicts a calcium-binding site involving Asp47, Asp49, Asp64, and Asp65. Our binding data, however, indicate that Asp47 is not necessary to form the high affinity binding site. We conclude that Asp47 in normal factor IX coordinates to the bound calcium, inducing a conformational change in the molecule essential for proper interaction with factor X and factor VIIIa.     

Comparison of lipid binding and kinetic properties of normal, variant, and gamma-carboxyglutamic acid modified human factor IX and factor IXa

The abilities of normal and three abnormal factor IXa molecules to activate factor X and to bind to phospholipid membranes have been compared to define the contributions of protein-lipid interactions and factor IXa light chain-heavy chain interactions to the functioning of this protein. The abnormal proteins studied had altered amino acid residues in their light chains. The heavy-chain regions, containing the active site serine and histidine residues, were normal in the abnormal proteins on the basis of titration by antithrombin III. The binding constants (Kd) for normal (N), variant [Chapel Hill (CH) and Alabama (AL)], and gamma-carboxyglutamic acid (Gla) modified (MOD) factors IX and IXa to phosphatidylserine (PS)/phosphatidylcholine (PC) small, unilamellar vesicles (SUV) were measured by 90 degrees light scattering. The Kd values for factor IXN binding were quite sensitive to the PS content of the membrane but less sensitive to Ca2+ concentrations between 0.5 and 10 mM. The zymogen and activated forms of both normal and abnormal factor IX bound with similar affinities to PS/PC (30/70) SUV. In the cases of factor IXaN and factor IXaAL, but not factor IXaCH or factor IXaMOD, irreversible changes in scattering intensity suggested protein-induced vesicle fusion. Since the activation peptide is not released from factor IXaCH, the normal interaction of factor IXa with a membrane must require the release of the activation peptide and the presence of intact Gla residues. The rate of factor X activation by normal and abnormal factor IXa was obtained by using a chromogenic substrate for factor Xa in the presence of PS/PC (30/70) SUV and 5 mM Ca2+.     

Role of phosphatidylethanolamine in assembly and function of the factor IXa-factor VIIIa complex on membrane surfaces

Phospholipid membranes play a significant role during the proteolytic activation of blood coagulation proteins. This investigation identifies a role for phosphatidylethanolamine (PE) during the activation of factor X by the tenase complex, an enzymatic complex composed of the serine protease, factor IXa, a protein cofactor, factor VIIIa, a phospholipid membrane, and Ca(2+). Phospholipid vesicles composed of PE, phosphatidylserine (PS), and phosphatidylcholine support factor Xa generation. The K(m) and k(cat) for factor X activation by the tenase complex are independent of PE in the presence of 20% PS. At lower PS concentrations, the presence of 20 or 35% PE lowers the K(m) and increases the k(cat) as compared to those in vesicles without PE. The effect of PE on the k(cat) of the tenase complex is mediated through factor VIIIa. PE also enhances factor Xa generation by facilitating tenase complex formation; PE lowers the K(d(app)) of factor IXa for both phospholipid/Ca(2+) and phospholipid/Ca(2+)/factor VIIIa complexes in the presence of suboptimal PS. In addition, the K(d)s of factor IXa and factor X were lower for phospholipid vesicles containing PE. N-Methyl-PE increased the k(cat) and decreased the K(d(app)), whereas N,N-dimethyl-PE had no effect on either parameter, indicating the importance of headgroup size. Lyso-PE had no effect on kinetic parameters, indicating the sn-2 acyl chain dependence of the PE effect. Together, these results demonstrate a role for PE in the assembly and activity of the tenase complex and further extend the understanding of the importance of PE-containing membranes in hemostasis.     

The connecting segment between both epidermal growth factor-like domains in blood coagulation factor IX contributes to stimulation by factor VIIIa and its isolated A2 domain

The light chain of activated factor IX comprises multiple interactions between both epidermal growth factor-like domains that contribute to enzymatic activity and binding of factor IXa to its cofactor factor VIIIa. To investigate the association between factor IXa-specific properties and surface-exposed structure elements, chimeras were constructed in which the interconnection between the modules Leu(84)-Thr(87) and the factor IX-specific loop Asn(89)-Lys(91) were exchanged for corresponding regions of factor X and factor VII. In absence of factor VIIIa, all chimeras displayed normal enzymatic activity. In the presence of factor VIIIa, replacement of loop Asn(89)-Lys(91) resulted in a minor reduction in factor IXa activity. However, chimeras with substitutions or insertions in the spacer between the epidermal growth factor-like domains showed a major defect in response to factor VIIIa. Of these chimeras, some displayed a normal response to isolated factor VIII A2 domain as a cofactor in factor X activation. Surprisingly, chimeras containing elongated inter-domain spacers from factor X or VII displayed reduced response to both complete factor VIIIa and the isolated A2 domain. Moreover, these chimeras still displayed effective association with immobilized A2 domain as assessed by surface plasmon resonance. We conclude that both sequence and length of the junction Leu(84)-Thr(87) between both epidermal growth factor-like domains contribute to the enhancement of factor IXa enzymatic activity that occurs upon assembly with factor VIIIa.     

Experimental and theoretical evidence supporting the role of Gly363 in blood coagulation factor IXa (Gly193 in chymotrypsin) for proper activation of the proenzyme

Factor IX is the zymogen of the serine protease factor IXa involved in blood coagulation. In addition to a catalytic domain homologous to the chymotrypsin family, it has Ca2+, phospholipid, and factor VIIIa binding regions needed for full biologic activity. We isolated a nonfunctional factor IX protein designated factor IXEagle Rock (IXER) from a patient with hemophilia B. The variant protein is indistinguishable from normal factor IX (IXN) in its migration on sodium dodecyl sulfate-gel electrophoresis, isoelectric point in urea, carbohydrate content and distribution, number of gamma-carboxyglutamic acid residues, and beta-OH aspartic acid content, and in its binding to an anti-IXN monoclonal antibody which has been shown previously to inhibit the interaction of factor VIIIa with factor IXaN. Further, IXER is cleaved to yield a factor IXa-like molecule by factor XIa/Ca2+ at a rate similar to that observed for IXN. However, in contrast to IXaN, IXaER does not bind to antithrombin-III (specific inhibitor of IXaN) and does not catalyze the activation of factor X (substrate) to factor Xa. To identify the mutation in IXER, all eight exons of IXN and IXER gene were amplified by the polymerase chain reaction technique and cloned. A single point mutation (G----T) which results in the replacement of Val for Gly363 in the catalytic domain of IXER was identified. Gly363 in factor IXa corresponds to the universally conserved Gly193 in the active site sequence of the chymotrypsin serine protease family. X-ray crystallographic data in the literature demonstrate a critical role of this Gly in stabilizing the active conformation of chymotrypsin/trypsin in two major ways: 1) in the formation of the substrate binding site; and 2) in the development of the oxyanion hole. Our computer structural data support a concept that the Gly363----Val change prevents the development of the active site conformation in factor IXa such that the substrate binding site and the oxyanion hole are not formed in the mutated enzyme.     

A novel blood coagulation factor IX/factor X-binding protein with anticoagulant activity from the venom of Trimeresurus flavoviridis (Habu snake): isolation and characterization

Using affinity chromatography on a column of factor X-Cellulofine, we have isolated a novel blood coagulation factor X-binding protein with anticoagulant activity from the venom of Trimeresurus flavoviridis (Habu snake). This anticoagulant protein was also purified by chromatography on Sephadex G-75 and S-Sepharose Fast Flow. The yield of the purified protein was approximately 16 mg from 400 mg of crude venom. The purified protein gave a single band on both analytical alkaline disc-gel electrophoresis and SDS-PAGE. This protein had a relative molecular weight (Mr) after SDS-PAGE of 27,000 before reduction of disulfide bonds and 14,000 after reduction of disulfide bonds. The protein prolonged the clotting time induced by kaolin or factor Xa. In the presence of Ca2+, it formed a complex with factor X, the molar ratio being 1 to 1. Similar complex formation was observed with factor Xa and factor IX/factor IXa, but not with other vitamin K-dependent coagulation factors, i.e., prothrombin, factor VII, protein C, protein S, and protein Z. The interaction of this anticoagulant protein with factor IX/factor X was dependent on gamma-carboxyglutamic acid (Gla) domains, since Gla-domainless derivatives of factor X and factor IXa beta' did not interact with this anticoagulant protein.     

Hydrophobic contact between the two epidermal growth factor-like domains of blood coagulation factor IX contributes to enzymatic activity

The three-dimensional structure of activated factor IX comprises multiple contacts between the two epidermal growth factor (EGF)-like domains. One of these is a salt bridge between Glu(78) and Arg(94), which is essential for binding of factor IXa to its cofactor factor VIII and for factor VIII-dependent factor X activation (Christophe, O. D., Lenting, P. J., Kolkman, J. A., Brownlee, G. G., and Mertens, K. (1998) J. Biol. Chem. 273, 222-227). We now addressed the putative hydrophobic contact at the interface between the EGF-like domains. Recombinant factor IX chimeras were constructed in which hydrophobic regions Phe(75)-Phe(77) and Lys(106)-Val(108) were replaced by the corresponding sites of factor X and factor VII. Activated factor IX/factor X chimeras were indistinguishable from normal factor IXa with respect to factor IXa enzymatic activity. In contrast, factor IXa(75-77)/factor VII displayed approximately 2-fold increased factor X activation in the presence of factor VIII, suggesting that residues 75-77 contribute to cofactor-dependent factor X activation. Activation of factor X by factor IX(106-108)/factor VII was strongly decreased, both in the absence and presence of factor VIII. Activity could be restored by simultaneous substitution of the hydrophobic sites in both EGF-like domains for factor VII residues. These data suggest that factor IXa enzymatic activity requires hydrophobic contact between the two EGF-like domains.