Characterization of Novel Forms of Coagulation Factor XIa: independence of factor XIa subunits in factor IX activation

Factor XI is the zymogen of a dimeric plasma protease, factor XIa, with two active sites. In solution, and during contact activation in plasma, conversion of factor XI to factor XIa proceeds through an intermediate with one active site (1/2-FXIa). Factor XIa and 1/2-FXIa activate the substrate factor IX, with similar kinetic parameters in purified and plasma systems. During hemostasis, factor IX is activated by factors XIa or VIIa, by cleavage of the peptide bonds after Arg145 and Arg180. Factor VIIa cleaves these bonds sequentially, with accumulation of factor IX alpha, an intermediate cleaved after Arg145. Factor XIa also cleaves factor IX preferentially after Arg145, but little intermediate is detected. It has been postulated that the two factor XIa active sites cleave both factor IX peptide bonds prior to releasing factor IX abeta. To test this, we examined cleavage of factor IX by four single active site factor XIa proteases. Little intermediate formation was detected with 1/2-FXIa, factor XIa with one inhibited active site, or a recombinant factor XIa monomer. However, factor IX alpha accumulated during activation by the factor XIa catalytic domain, demonstrating the importance of the factor XIa heavy chain. Fluorescence titration of active site-labeled factor XIa revealed a binding stoichiometry of 1.9 +/- 0.4 mol of factor IX/mol of factor XIa (Kd = 70 +/- 40 nm). The results indicate that two forms of activated factor XI are generated during coagulation, and that each half of a factor XIa dimer behaves as an independent enzyme with respect to factor IX.     

The factor IX gamma-carboxyglutamic acid (Gla) domain is involved in interactions between factor IX and factor XIa

During hemostasis, factor IX is activated to factor IXabeta by factor VIIa and factor XIa. The glutamic acid-rich gamma-carboxyglutamic acid (Gla) domain of factor IX is involved in phospholipid binding and is required for activation by factor VIIa. In contrast, activation by factor XIa is not phospholipid-dependent, raising questions about the importance of the Gla for this reaction. We examined binding of factors IX and IXabeta to factor XIa by surface plasmon resonance. Plasma factors IX and IXabeta bind to factor XIa with K(d) values of 120 +/- 11 nm and 110 +/- 8 nm, respectively. Recombinant factor IX bound to factor XIa with a K(d) of 107 nm, whereas factor IX with a factor VII Gla domain (rFIX/VII-Gla) and factor IX expressed in the presence of warfarin (rFIX-desgamma) did not bind. An anti-factor IX Gla monoclonal antibody was a potent inhibitor of factor IX binding to factor XIa (K(i) 34 nm) and activation by factor XIa (K(i) 33 nm). In activated partial thromboplastin time clotting assays, the specific activities of plasma and recombinant factor IX were comparable (200 and 150 units/mg), whereas rFIX/VII-Gla activity was low (<2 units/mg). In contrast, recombinant factor IXabeta and activated rFIX/VIIa-Gla had similar activities (80 and 60% of plasma factor IXabeta), indicating that both proteases activate factor X and that the poor activity of zymogen rFIX/VII-Gla was caused by a specific defect in activation by factor XIa. The data demonstrate that factor XIa binds with comparable affinity to factors IX and IXabeta and that the interactions are dependent on the factor IX Gla domain.     

Substrate-dependent modulation of the mechanism of factor XIa inhibition

Factor XIa is a serine protease which participates in both the extrinsic and intrinsic pathways of blood coagulation. In this work we used active site directed inhibitors to study the mechanism of factor IX activation by factor XIa. To this end, we developed a new sensitive method for the detection of factor IXa based on its affinity to antithrombin III. Using this assay, we found that the peptidic inhibitors, leupeptin and aprotinin, exhibited similar potencies in inhibiting factor IX activation and the cleavage of a tripeptidic chromogenic substrate by factor XIa. As expected, leupeptin and aprotinin were competitive with respect to the tripeptidic chromogenic substrate. However, the inhibition of factor IX activation was best described by mixed-type inhibition with the affinity of leupeptin and aprotinin to the factor XIa-factor IX complex only approximately 10-fold lower than their affinity toward factor XIa. These results, consistent with previous factor XI domain analyses, suggest that the active site of factor XIa does not contribute significantly to the affinity of factor XIa toward factor IX. The competitive component of the inhibition of factor IX activation suggests that binding of factor IX to factor XIa heavy chain affects the interactions of leupeptin and aprotinin with the active site.     

Intrinsic versus extrinsic coagulation. Kinetic considerations.

A study to compare the kinetics of activation of factor IX by Factor XIa/Ca2+ and by Factor VIIa/tissue factor/Ca2+ has been undertaken. When purified human proteins, detergent-extracted brain tissue factor and tritiated-activation-peptide-release assays were utilized, the kinetic constants obtained were: Km = 310 nM, kcat. = 25 min-1 for Factor XIa and Km = 210 nM, kcat. = 15 min-1 for Factor VIIa. The kinetic constants for the activation of Factor X by Factor VIIa/brain tissue factor were: Km = 205 nM, kcat. = 70 min-1. Predicted rates for the generation of Factor IXa and Factor Xa were obtained when human monocytic tumour U937 cells (source of tissue factor) and Factor VIIa were used to form the activator. In other experiments, inclusion of high-Mr kininogen did not increase the activation rates of Factor IX by Factor XIa in the presence or absence of platelets and/or denuded rabbit aorta. These kinetic data strongly indicate that both Factor XIa and Factor VIIa play physiologically significant roles in the activation of Factor IX.     

A low molecular weight platelet inhibitor of factor XIa: purification, characterization, and possible role in blood coagulation.

A low molecular weight platelet inhibitor of factor XIa (PIXI) has been purified 250-fold from releasates of washed and stimulated human platelets. Molecular weight estimates of 8400 and 8500 were determined by gel filtration and SDS-polyacrylamide gel electrophoresis, respectively, although a second band of Mr 5000 was present upon electrophoresis. The inhibitor does not appear to be one of the platelet-specific, heparin-binding proteins, since it neither bound to nor was affected by heparin. An amount of PIXI which inhibited by 50% factor XIa cleavage of the chromogenic substrate S2366 (Pyr-Glu-Pro-Arg-pNA-2H2O) only slightly inhibited (5-9%) factor XIIa, plasma kallikrein, plasmin, and activated protein C and did not inhibit factor Xa, thrombin, tPA, or trypsin, suggesting specificity for factor XIa. Kinetic analyses of the effect of PIXI on factor XIa activity demonstrated mixed-type, noncompetitive inhibition of S2366 cleavage and of factor IX activation with Ki's of 7 x 10(-8) and 3.8 x 10(-9) M, respectively. Immunoblot analysis showed that PIXI is not the inhibitory domain of protease nexin II, a potent inhibitor of factor XIa also secreted from platelets. Amino acid analysis showed that PIXI has no cysteine residues and, therefore, is not a Kunitz-type inhibitor. PIXI can prevent stable complex formation between alpha 1-protease inhibitor and factor XIa light chain as demonstrated by SDS-polyacrylamide gel electrophoresis. The inhibition by PIXI of factor XIa-catalyzed activation of factor IX and its capacity to prevent factor XIa inactivation by alpha 1-protease inhibitor, combined with the specificity of PIXI for factor XIa among serine proteases found in blood, suggest a role for PIXI in the regulation of intrinsic coagulation.     

Exosite-mediated substrate recognition of factor IX by factor XIa. The factor XIa heavy chain is required for initial recognition of factor IX

Studies of the mechanisms of blood coagulation zymogen activation demonstrate that exosites (sites on the activating complex distinct from the protease active site) play key roles in macromolecular substrate recognition. We investigated the importance of exosite interactions in recognition of factor IX by the protease factor XIa. Factor XIa cleavage of the tripeptide substrate S2366 was inhibited by the active site inhibitors p-aminobenzamidine (Ki 28 +/- 2 microM) and aprotinin (Ki 1.13 +/- 0.07 microM) in a classical competitive manner, indicating that substrate and inhibitor binding to the active site was mutually exclusive. In contrast, inhibition of factor XIa cleavage of S2366 by factor IX (Ki 224 +/- 32 nM) was characterized by hyperbolic mixed-type inhibition, indicating that factor IX binds to free and S2366-bound factor XIa at exosites. Consistent with this premise, inhibition of factor XIa activation of factor IX by aprotinin (Ki 0.89 +/- 0.52 microM) was non-competitive, whereas inhibition by active site-inhibited factor IXa beta was competitive (Ki 0.33 +/- 0.05 microM). S2366 cleavage by isolated factor XIa catalytic domain was competitively inhibited by p-aminobenzamidine (Ki 38 +/- 14 microM) but was not inhibited by factor IX, consistent with loss of factor IX-binding exosites on the non-catalytic factor XI heavy chain. The results support a model in which factor IX binds initially to exosites on the factor XIa heavy chain, followed by interaction at the active site with subsequent bond cleavage, and support a growing body of evidence that exosite interactions are critical determinants of substrate affinity and specificity in blood coagulation reactions.     

Blood clotting factor IX BM Nagoya. Substitution of arginine 180 by tryptophan and its activation by alpha-chymotrypsin and rat mast cell chymase

Factor IX BM Nagoya (IX Nagoya) is a natural mutant of factor IX responsible for severe hemophilia B. A patient with this mutant is characterized by a markedly prolonged ox brain prothrombin time. IX Nagoya was purified from the patient's plasma by immunoaffinity chromatography with an anti-factor IX monoclonal antibody column. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that treatment of IX Nagoya with factor XIa/Ca2+ resulted in cleavage only at the Arg145-Ala146 bond. Reversed-phase high performance liquid chromatography of a trypsin digest of IX Nagoya showed an aberrant peptide, which was further digested with proteinase Asp-N. Primary structure analysis of one of the Asp-N peptides revealed that Arg180 is replaced by Trp. An essentially complete (99%) amino acid sequence of IX Nagoya was obtained by sequencing fragments derived from a lysyl endopeptidase digest in which no other substitutions in the catalytic triad or substrate binding site were found. We also found that IX Nagoya is activated by alpha-chymotrypsin or rat mast cell chymase by monitoring the rate of factor X activation using a fluorogenic peptide substrate in the presence of factor VIII, phospholipids, and Ca2+. These results indicate that the substitution of Arg180 by Trp impairs the cleavage by factor XIa required for activation of this zymogen and that the substitution causes hemophilia BM.     

Functional characterization of human blood coagulation factor XIa using hybridoma antibodies

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.     

Identification and chemical synthesis of a substrate-binding site for factor IX on coagulation factor XIa.

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.     

Mutations in hemophilia Bm occur at the Arg180-Val activation site or in the catalytic domain of factor IX

Hemophilia Bm is characterized by a strikingly prolonged plasma ox brain prothrombin time. In an attempt to find an explanation for this phenomenon we have analyzed various aspects of the Bm variants factor IX Deventer, factor IX Milano, factor IX Novara, and factor IX Bergamo. Proteolytic cleavage by factor XIa was normal in two Bm variants, but absent at the Arg180-Val bond in the other two. In the latter variants Arg180 was replaced by either Trp or Gln, whereas Val181----Phe and Pro368----Thr replacements have occurred in the variants that were normally cleaved by factor XIa. In all four variants the Bm effect could be neutralized with a single monoclonal antibody against factor IX. Also, after treatment with factor XIa, none of the Bm variants reacted with antithrombin III (in contrast to normal factor IXa). Purified factor IX Deventer (one of the variants with a replacement of Arg181), either with or without pretreatment with factor XIa, was found to be a more effective competitive inhibitor of the factor VIIa-tissue factor-induced factor X activation than similarly treated normal factor IX. In addition, this inhibitory effect was much more pronounced when bovine tissue factor was used instead of human tissue factor. We propose that the normal activation of factor IX not only produces a conformational change around the active site serine that allows efficient substrate binding and catalysis, but that the same conformational change is instrumental in effectively dissociating factor IXa from the activating factor VIIa-tissue factor complex. Amino acid replacements that disrupt this conformational transition directly (e.g. Pro368----Thr near the catalytic center) or indirectly (mutations at the Arg180-Val activation site) therefore lead to a combination of 1) the loss of coagulant activity and 2) an inhibitory effect in the ox brain prothrombin time assay.     

Role of calcium ions and the heavy chain of factor XIa in the activation of human coagulation factor IX

Since optimal rates of factor IX activation by factor XIa require the presence of calcium ions and the heavy chain of the enzyme as well as the active-site-containing light chain, we have studied the effects of calcium ions and the heavy chain on the reaction kinetics. Whereas the amidolytic activities of factor XIa and of its active-site-containing light chain were almost indistinguishable, the two enzymes behaved quite differently when factor IX was the substrate. Factor XIa was 100-fold more potent in the presence of Ca2+ than in its absence. On the contrary, the presence or absence of Ca2+ made very little difference in the case of the isolated light chain of factor XIa. Moreover, the enzymatic activity of the light chain was almost identical with that of intact factor XIa when Ca2+ was absent. Using an optimal concentration of Ca2+, we studied the activation in the presence of various concentrations of two monoclonal antibodies, one (5F4) directed against the light chain of factor XIa and the other (3C1) against its heavy chain. Analysis of 1/V vs. 1/S plots showed that whereas inhibition by 5F4 was noncompetitive, 3C1 neutralized the enzyme in a classical competitive fashion. We conclude that in the calcium-dependent activation of factor IX by factor XIa the heavy chain of the enzyme is involved in the binding of the substrate and this is essential for optimal reaction rates.     

Role of charged groups in factor XI/XIa activity

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.     

Activation of normal and abnormal human factor IX with trypsin

Human factor IX is activated to factor IXa beta when factor XIa cleaves two peptide bonds, Arg 145-Ala 146 and Arg 180-Val 181, to release an activation peptide. In factor IX Chapel Hill (IXCH), isolated from a hemophilia B patient with a mild bleeding disorder, the arginine 145 residue has been replaced with a histidine. Thus factor IXCH is activated by factor XIa by cleaving only at the Arg 180-Val 181 bond, leaving the activation peptide attached, and resulting in an activated species, factor IXa alpha CH, that, like normal factor IXa alpha, is only 20% as active as factor IXa beta. It is reported that both factor IX and factor IXCH could be activated by trypsin to forms of factor IXa beta and factor IXa beta CH that had clotting activities identical to factor XIa-activated factor IX. Amino-terminal amino acid sequence analysis showed that trypsin cleaved factor IX at the same bonds as did factor XIa; factor IXCH was cleaved at the Arg 180-Val 181 bond, as normal, and was cleaved near the histidine 145, at the Lys 142-Leu 143 bond, releasing a slightly larger activation peptide than from normal factor IXa beta. Metal ions had no effect on the rate of activation of factor IX by trypsin; however, metal ions had a profound effect on the rate at which further incubation with trypsin inactivated factor IXa. Calcium and manganese protected factor IXa from inactivation by trypsin more effectively than magnesium, which was more effective than no metal ion. It is concluded that trypsin can activate normal factor IX and factor IXCH to fully active IXa beta forms.     

Degradation of coagulation proteins by an enzyme from Malayan pit viper (Akistrodon rhodostoma) venom

Three hydrolases from the crude venom of the Malayan pit viper (Akistrodon rhodostoma) can be differentiated. The first, which we designate ARH alpha, is the well-known fibrinogenolytic enzyme ancrod. The second, ARH beta, which has not been described previously, is identified by its electrophoretic mobility after sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), by its ability to hydrolyze H-D-phenylalanyl-L-piperyl-L-arginyl-rho-nitroanilide, and by inhibition of its activity by diisopropyl phosphorofluoridate. The third, ARH gamma, also previously not described, has been purified by using gel permeation and ion-exchange chromatography and preparative PAGE. Chemical, electrophoretic, and hydrodynamic data indicate that it is a single-chain, nonglobular glycoprotein with a molecular weight of 25,600. ARH gamma catalyzes the degradation of several plasma vitamin K dependent coagulation factors, including factor IX, factor X, prothrombin, and protein C. The products are electrophoretically similar to factor IXa beta, factor Xa, thrombin, and activated protein C, respectively. However, these products contain little or no enzymatic activity. ARH gamma-degraded factor IX, factor X, prothrombin, and protein C can be subsequently activated by factor XIa, Russell's viper venom X coagulant protein, crude taipan snake venom, and thrombin, respectively. The N-terminal sequence of the peptides resulting from the ARH gamma digest of porcine factor IX shows that at least three bonds are hydrolyzed: (1) at position 152, seven residues from the Arg145-Ala146 factor XIa cleavage site; (2) at position 167 within the factor IX activation peptide; and (3) at position 177, three residues from the Arg180-Val181 factor XIa cleavage site. The degradation of factor IX by ARH gamma is not affected by several serine protease inhibitors. ARH gamma catalyzes the degradation of both the heavy and light chains of porcine factor VIII which results in the inability of thrombin to activate factor VIII. ARH gamma also catalyzes the degradation of porcine antithrombin III which abolishes its ability to inhibit thrombin. These findings may have relevance to studies of hemostatic derangements following envenomation by this snake. Additionally, several novel coagulation factor derivatives have been generated for structure-function studies.     

Blood clotting factor IX Niigata: substitution of alanine-390 by valine in the catalytic domain

Factor IX Niigata is a mutant factor IX responsible for the moderately severe hemophilia B in a patient who has a normal level of factor IX antigen with reduced clotting activity (1-4% of normal). We reported previously that the purified mutant protein could be converted to the factor IXa beta form by factor XIa/Ca2+ at a rate similar to that in the case of normal factor IX, but the resulting mutant factor IXa beta could not activate factor X in the presence of factor VIII, Ca2+, and phospholipids (Yoshioka, A. et al. (1986) Thromb. Res. 42, 595-604). In the present study, we analyzed factor IX Niigata at the structural level to elucidate the molecular abnormality responsible for the loss of clotting activity. Amino acid sequence analysis of a peptide obtained on lysyl endopeptidase digestion, coupled with subsequent SP-V8 digestion, demonstrated that the alanine at position 390 was substituted by valine in the catalytic domain of the factor IX Niigata molecule.     

Isolation and functional characterization of the active light chain of activated human blood coagulation factor XI

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.     

Expression and characterization of human factor IX and factor IX-factor X chimeras in mouse C127 cells

Human blood clotting factor IX, and two chimeric molecules of factor IX, in which the first epidermal growth factor-like domain or both epidermal growth factor-like domains have been replaced by that of human factor X, have been expressed in mouse C127 cells. The recombinants have been purified using a metal ion-dependent monoclonal antibody specific for residues 1-42 of human factor IX. All recombinant molecules are activated normally by human factor XIa in the presence of calcium ion. Activation of the factor IX recombinants by factor VIIa-tissue factor appears to be normal for the epidermal growth factor-1 exchange but considerably reduced for the construction containing both epidermal growth factor-like domains of factor X. The analysis of gamma-carboxyglutamic acid residues reveals that all of the purified recombinants are almost fully carboxylated. The extent of aspartic acid hydroxylation at residue 64 is 60% for all recombinants. The chimeric molecule with both epidermal growth factor-like domains from factor X has about 4% normal activity in the activated partial thromboplastin time assay. In contrast, the construct containing the first epidermal growth factor-like domain of factor X shows essentially normal clotting activity. Thus, it is unlikely that this domain is involved in a unique interaction with factor VIII.     

Human factor XIa cleaves fibrinogen: effects on structure and function

Factor XIa, the enzymatic form of the factor XI zymogen, is generated as a result of factor XII-dependent surface activation in plasma. Factor XIa degrades high molecular weight kininogen, its cofactor for activation (which binds factor XIa to the surface), as well as cleaves and activates coagulation factor IX. In this report, we present evidence that factor XIa can also cleave fibrinogen and decrease the thrombin-catalyzed formation of the fibrin clot. Furthermore, the products of factor XIa-digested fibrinogen markedly inhibited the rate of polymerization of fibrin monomers. Factor XIa initially cleaved the A alpha-chain of fibrinogen and subsequently degraded the B beta-chain. However, the cleavage sites on both chains were distinct from those susceptible to thrombin. The gamma-chain was degraded only after prolonged incubation with factor XIa. Furthermore, the profile of fibrinogen proteolysis by factor XIa was distinctly different from that of plasmin-catalyzed fibrinogenolysis. Unlike plasmin, factor XIa was not able to cleave the NH2-terminus of the B beta-chain of fibrinogen. Moreover, factor XIa, unlike plasmin, failed to hydrolyze fibrin. Further study of the proteolytic digests of fibrinogen produced by factor XIa may give additional insight into the mechanism of polymerization of this protein.     

Identification of amino acids in the factor XI apple 3 domain required for activation of factor IX

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.     

Allosteric modification of factor XIa functional activity upon binding to polyanions

The effects of several polyanions on the hydrolysis of the chromogenic substrate L-pyroglutamyl-L-prolyl-L-arginyl-p-nitroaniline (S-2366) and on the activation of factor IX by factor XIa have been investigated. Two forms of dextran sulfate (M(r) approximately 500000 and M(r) approximately 10000, DX10) and two forms of heparin (64 disaccharide units, M(r) approximately 14000, and hypersulfated heparin, S-Hep, M(r) approximately 12000) inhibited both factor XIa amidolytic activity and factor IX activation in a concentration-dependent manner. The inhibitory effect was not due to binding of either substrate by the polyanions since only a decrease in V(max) without any effect on K(m) was observed in kinetic assays. Steric inhibition is unlikely since the concentrations of polyanions required for inhibition of small peptide hydrolysis were lower than those required for macromolecular substrate cleavage. In contrast, an allosteric inhibitory mechanism was supported by an enhancement of the dansyl fluorescence of 5-(dimethylamino)-1-(naphthalenesulfonyl)glutamylglycylarginyl- (DEGR-) factor XIa observed when the fluorophore was in complex with either DX10 or S-Hep. Moreover, in the presence of a polyanion the fluorophore was far more resistant to quenching by acrylamide. These results provide compelling evidence that factor XIa binding to the polyanions, dextran sulfate and heparin, results in inhibition of the enzyme by an allosteric mechanism.