Identification of basic residues in the heparin-binding exosite of factor Xa critical for heparin and factor Va binding

Exosites in the substrate specificity of blood coagulation reactions

The specificity of blood coagulation proteinases for substrate, inhibitor, and effector recognition is mediated by exosites on the surfaces of the catalytic domains, physically separated from the catalytic site. Some thrombin ligands bind specifically to either exosite I or II, while others engage both exosites. The involvement of different, overlapping constellations of exosite residues enables binding of structurally diverse ligands. The flexibility of the thrombin structure is central to the mechanism of complex formation and the specificity of exosite interactions. Encounter complex formation is driven by electrostatic ligand-exosite interactions, followed by conformational rearrangement to a stable complex. Exosites on some zymogens are in low affinity proexosite states and are expressed concomitant with catalytic site activation. The requirement for exosite expression controls the specificity of assembly of catalytic complexes on the coagulation pathway, such as the membrane-bound factor Xa*factor Va (prothrombinase) complex, and prevents premature assembly. Substrate recognition by prothrombinase involves a two-step mechanism with initial docking of prothrombin to exosites, followed by a conformational change to engage the FXa catalytic site. Prothrombin and its activation intermediates bind prothrombinase in two alternative conformations determined by the zymogen to proteinase transition that are hypothesized to involve prothrombin (pro)exosite I interactions with FVa, which underpin the sequential activation pathway. The role of exosites as the major source of substrate specificity has stimulated development of exosite-targeted anticoagulants for treatment of thrombosis.

Identification of a specific exosite on activated protein C for interaction with protease-activated receptor 1

Activated protein C (APC) is a vitamin K-dependent plasma serine protease which down-regulates the clotting cascade by inactivating procoagulant factors Va and VIIIa by limited proteolysis. In addition to its anticoagulant effect, APC also exhibits cytoprotective and antiinflammatory activity through the endothelial protein C receptor-dependent cleavage of protease activated receptor 1 (PAR-1) on endothelial cells. Recent mutagenesis data have indicated that the basic residues of two surface loops including those on 39 and the Ca2+-binding 70-80 loops constitute interactive sites for both factors Va and VIIIa, thereby mediating the interaction of APC specifically with these procoagulant cofactors. The basic residues of both loops have been discovered to be dispensable for the interaction of APC with PAR-1. It is not known if a similar exosite-dependent interaction contributes to the specificity of APC recognition of PAR-1 on endothelial cells. In this study, we have identified two acidic residues on helix-162 (Glu-167 and Glu-170) on the protease domain of APC which are required for the protease interaction with PAR-1, but not for its interaction with the procoagulant cofactors. Thus, the substitution of either Glu-167 or Glu-170 with Ala eliminated the cytoprotective signaling properties of APC without affecting its anticoagulant activity. These mutants provide useful tools for initiating in vivo studies to understand the extent to which the anticoagulant versus antiinflammatory activity of APC contributes to its beneficial effect in treating severe sepsis.

In the presence of phospholipids, glycosaminoglycans potentiate factor Xa-mediated protein C activation by modulating factor Xa activity

Although the thrombin/thrombomodulin complex is considered the physiological activator of protein C, factor Xa (f.Xa) can also activate protein C in a reaction that is potentiated by glycosaminoglycans. To explore this phenomenon, we first examined the effect of glycosaminoglycans of varying degrees of sulfation on the kinetics of protein C activation by f.Xa in the presence of Ca2+ and phosphatidylcholine-phosphatidylserine vesicles (PCPS). Heparin increased the rate of protein C activation by f.Xa by 4-fold. In contrast, N-desulfated heparin had no effect on activation, whereas dextran sulfate, which is more sulfated than heparin, increased catalytic efficiency 21-fold. These data suggest that the capacity of glycosaminoglycans to catalyze protein C activation by f.Xa depends on their degree of sulfation. The affinities of individual glycosaminoglycans for protein C and f.Xa were measured in the absence or presence of PCPS by monitoring changes in extrinsic fluorescence when fluorescein-labeled f.Xa or protein C was titrated with the various glycosaminoglycans. Heparin binds protein C with low affinity in the absence or presence of PCPS. In contrast, the affinity of heparin for f.Xa is 86-fold higher in the presence of PCPS compared to that in the absence of PCPS. Similar results were obtained using surface plasmon resonance. These findings suggest that a high affinity glycosaminoglycan binding site is exposed when f.Xa binds to PCPS. The observation that heparin promotes f.Xa-mediated activation of prethrombin 1 only in the presence of phospholipid suggests that glycosaminoglycan binding modulates the active site of f.Xa. This study reveals that when f.Xa interacts with anionic phospholipids, glycosaminoglycans bind f.Xa more tightly, allosterically modulate its active site, and enhance its capacity to activate protein C.

Serase-1B, a new splice variant of polyserase-1/TMPRSS9, activates urokinase-type plasminogen activator and the proteolytic activation is negatively regulated by glycosaminoglycans

Polyserase-1 (polyserine protease-1)/TMPRSS9 (transmembrane serine protease 9) is a type II transmembrane serine protease (TTSP) that possesses unique three tandem serine protease domains. However, the physiological function of each protease domain remains poorly understood. We discovered a new splice variant of polyserase-1, termed Serase-1B, which contains 34 extra amino acids consisting a SEA module (a domain found in sea urchin sperm protein, enterokinase and agrin) adjacent to the transmembrane domain and the first protease domain with a mucin-like box at the C-terminus. The tissue distribution of this enzyme by RT (reverse transcription)-PCR analysis revealed high expression in the liver, small intestine, pancreas, testis and peripheral blood CD14+ and CD8+ cells. To investigate the role of Serase-1B, a full-length form recombinant protein was produced. Interestingly, recombinant Serase-1B was partly secreted as a soluble inactive precursor and it was also activated by trypsin. This activated enzyme selectively cleaved synthetic peptides for trypsin and activated protein C, and it was inhibited by several natural serine protease inhibitors, such as aprotinin, alpha2-antiplasmin and plasminogen activator inhibitor 1. In addition, Serase-1B efficiently converted pro-uPA (urokinase-type plasminogen activator) into active uPA and this activation was strongly inhibited by these natural inhibitors. Furthermore, this activation was also negatively regulated by glycosaminoglycans. Our results indicate that Serase-1B is a novel member of TTSPs that might be involved in uPA/plasmin-mediated proteolysis and possibly implicated in biological events such as fibrinolysis and tumour progression.

Antithrombotic properties of Ixolaris, a potent inhibitor of the extrinsic pathway of the coagulation cascade

Ixolaris is a two-Kunitz tick salivary gland protein identified in Ixodes scapularis that presents extensive sequence homology to TFPI. It binds to FXa or FX as scaffolds and inhibits tissue factor/FVIIa complex (extrinsic Xnase). Differently from TFPI, ixolaris does not bind to the active site cleft of FXa. Instead, complex formation is mediated by the FXa heparin-binding exosite, which may also results in decreased FXa activity into the prothrombinase complex. In this report, we show that recombinant (125)I-ixolaris interacts with rat and human FX in plasma and prolongs the prothrombin time (PT) and activated partial thromboplastin time (aPTT) in vitro. We have also investigated the effects of ixolaris in vivo, using a venous thrombosis model. Subcutaneous (s.c.) or intravenous (i.v.) administration of ixolaris in rats caused a dose-dependent reduction in thrombus formation, with complete inhibition attained at 20 microg/kg and 10 microg/kg, respectively. Antithrombotic effects were observed 3 h after s.c. administration of ixolaris and lasted for 24 h thereafter. Ex vivo experiments showed that ixolaris (up to 100 microg/kg) did not affect the aPTT, while the PT was increased by approximately 0.4-fold at the highest ixolaris concentration. Remarkably, effective antithrombotic doses of ixolaris (20 microg/kg) was not associated with bleeding which was significant only at higher doses of the anticoagulant (40 microg/kg). Our experiments demonstrate that ixolaris is an effective and possibly safe antithrombotic agent in vivo.

Proposed structural models of the prothrombinase (FXa-FVa) complex

Activated coagulation factor V (FVa) functions as a cofactor to factor Xa (FXa) in the conversion of prothrombin (PT) to thrombin. This essential procoagulant reaction, despite being the subject of extensive investigation, is not fully understood structurally and functionally. To elucidate the structure of the FXa-FVa complex, we have performed protein:protein (Pr:Pr) docking simulation with the pseudo-Brownian Pr:Pr docking ICM package and with the shape-complementarity Pr:Pr docking program PPD. The docking runs were carried out using a new model of full-length human FVa and the X-ray structure of human FXa. Five representative models of the FXa-FVa complex were in overall agreement with some of the available experimental data, but only one model was found to be consistent with almost all of the reported experimental results. The use of hybrid docking approach (theoretical plus experimental) is definitively important to study such large macromolecular complexes. The FXa-FVa model we have created will be instrumental for further investigation of this macromolecular system and will guide future site directed mutagenesis experiments.

Pentasaccharide enhances the inactivation of factor Xa by antithrombin by promoting the assembly of a Michaelis-type intermediate complex. Demonstration by rapid kinetic, surface plasmon resonance, and competitive binding studies

It has been demonstrated that a unique pentasaccharide fragment of heparin (H5) activates AT by exposing an exosite on the serpin that is a recognition site for interaction with the basic autolysis loop (residues 143-154) of fXa. In support of this, the substitution of Arg-150 of fXa with Ala (R150A) impaired the reactivity of the mutant with AT by 1 order of magnitude specifically in the presence H5. To understand the mechanism by which heparin activation of AT improves the reactivity of the serpin with fXa, the H5-catalyzed reaction of AT with fXa, fXa R150A, and fXa S195A was studied using rapid kinetic, surface plasmon resonance, and competitive binding methods. The pseudo-first-order rate constants for the H5-catalyzed AT inhibition of both fXa and fXa R150A exhibited a linear dependence on the serpin concentration, thereby yielding second-order rate constants of 1.0 x 10(6) and 1.5 x 10(5) M(-)(1) s(-)(1), respectively. On the other hand, an approximately 70-saccharide, high-affinity heparin-catalyzed AT inhibition of both fXa derivatives showed a saturable dependence on the inhibitor concentration, yielding an identical rate constant of approximately 20 s(-)(1), but different ternary fXa-heparin-AT dissociation constants (K(E,ATH)) of approximately 130 and approximately 1780 nM for wild-type and R150A fXa, respectively. Competitive kinetic and surface plasmon resonance binding studies using the catalytically inactive S195A mutant of fXa yielded dissociation constants of 255 and 610 nM, respectively, for the mutant protease interaction with the AT-H5 complex. These results suggest that H5 enhances the reactivity of AT with fXa primarily by lowering the K(E,ATH) for the formation of a Michaelis-type serpin-protease encounter complex.

Antithrombin-S195A factor Xa-heparin structure reveals the allosteric mechanism of antithrombin activation

Regulation of blood coagulation is critical for maintaining blood flow, while preventing excessive bleeding or thrombosis. One of the principal regulatory mechanisms involves heparin activation of the serpin antithrombin (AT). Inhibition of several coagulation proteases is accelerated by up to 10,000-fold by heparin, either through bridging AT and the protease or by inducing allosteric changes in the properties of AT. The anticoagulant effect of short heparin chains, including the minimal AT-specific pentasaccharide, is mediated exclusively through the allosteric activation of AT towards efficient inhibition of coagulation factors (f) IXa and Xa. Here we present the crystallographic structure of the recognition (Michaelis) complex between heparin-activated AT and S195A fXa, revealing the extensive exosite contacts that confer specificity. The heparin-induced conformational change in AT is required to allow simultaneous contacts within the active site and two distinct exosites of fXa (36-loop and the autolysis loop). This structure explains the molecular basis of protease recognition by AT, and the mechanism of action of the important therapeutic low-molecular-weight heparins.

Ixolaris: a factor Xa heparin-binding exosite inhibitor

Ixolaris is a two-Kunitz TFPI (tissue factor pathway inhibitor) from the tick salivary gland. In contrast with human TFPI, Ixolaris binds tightly to the zymogen FX (Factor X) and to dansyl-Glu-Gly-Arg-chloromethyl ketone-treated FXa (DEGR-FXa; active-site-blocked FXa), indicating that exosites are involved in the FX(a)-Ixolaris interaction. Here we provide evidence that Ixolaris binds specifically to the FXa HBE (heparin-binding exosite), since (i) it markedly decreases the inhibition of FXa by the antithrombin-heparin but not the antithrombin-pentasaccharide complex, (ii) it impairs FXa binding to Sepharose-immobilized heparin, and (iii) it allosterically modulates the catalytic activity of FXa for small chromogenic substrates (S-2765). By using a series of recombinant FXa mutants in which the HBE is mutated, we have identified the importance of amino acids involved in the enzyme-inhibitor interaction as being in the following order: Arg-93>>Arg-165> or =Lys-169>Lys-236>Lys-96>Arg-240>Arg-125. Ixolaris at appropriate concentrations also inhibits thrombin formation in vitro by the assembled prothrombinase complex, a process that is critically dependent on the FXa HBE. Ixolaris is the first inhibitor characterized to date that binds specifically to the FXa HBE.

Heparin chain-length dependence of factor Xa inhibition by antithrombin in plasma

Heparin anticoagulants function by enhancing the inhibition of coagulation proteases by the serpin antithrombin (AT). A direct evaluation of the specific anti-factor Xa (fXa) activity of therapeutic heparins in the physiologically relevant plasma-based clotting assays has not been feasible since thrombin, the final protease of the cascade, is the primary target for inhibition by AT in the presence of heparin. To circumvent this problem, we developed an assay in which the native AT in plasma was replaced with an AT mutant which exhibits identical affinity for heparin and near normal reactivity for fXa, but does not react with thrombin and other coagulation proteases in either the absence or presence of heparin. This assay was used to distinguish the anti-fXa activity of different molecular weight heparins from their anti-thrombin activity in clotting assays which were initiated by the triggers of either the extrinsic or intrinsic coagulation pathway. The results suggest that the acceleration of fXa inhibition by AT exhibits a marked heparin chain-length dependence, with fondaparinux (a pentasaccharide) having the lowest and unfractionated heparin having the highest effect. Interestingly, comparative studies revealed that the fondaparinux-catalyzed acceleration of thrombin inhibition by AT also contributes to the prolongation of the clotting time, possibly suggesting that the anticoagulant function of the therapeutic pentasaccharide is mediated though the inhibition of both fXa and thrombin.

Functional mapping of charged residues of the 82-116 sequence in factor Xa: evidence that lysine 96 is a factor Va independent recognition site for prothrombin in the prothrombinase complex

It has been hypothesized that two antiparallel structures comprised of residues 82-91 and 102-116 in factor Xa (fXa) may harbor a factor Va- (fVa-) dependent prothrombin recognition site in the prothrombinase complex. There are 11 charged residues in the 82-116 loop of human fXa (Glu-84, Glu-86, Lys-90, Arg-93, Lys-96, Glu-97, Asp-100, Asp-102, Arg-107, Lys-109, and Arg-115). With the exception of Glu-84, which did not express, and Asp-102, which is a catalytic residue, we expressed the Ala substitution mutants of all other residues and evaluated their proteolytic and amidolytic activities in both the absence and presence of fVa. K96A and K109A activated prothrombin with 5-10-fold impaired catalytic efficiency in the absence of fVa. All mutants, however, exhibited normal activity toward the substrate in the presence of fVa. K109A also exhibited impaired amidolytic activity and affinity for Na(+); however, both fVa and higher Na(+) restored the catalytic defect caused by the mutation. Analysis of the X-ray crystal structure of fXa indicated that Glu-84 may interact by a salt bridge with Lys-109, explaining the lack of expression of E84A and the lower activity of K109A in the absence of fVa. These results suggest that none of the residues under study is a fVa-dependent recognition site for prothrombin in the prothrombinase complex; however, Lys-96 is a recognition site for the substrate independent of the cofactor. Moreover, the 82-116 loop is energetically linked to fVa and Na(+) binding sites of the protease.

Identification of factor Xa residues critical for interaction with protein Z-dependent protease inhibitor: both active site and exosite interactions are required for inhibition

Protein Z-dependent protease inhibitor (ZPI) is a plasma serpin, which can rapidly inactivate factor Xa (fXa) in the presence of protein Z (PZ), negatively charged phospholipids, and Ca2+. To investigate the mechanism by which ZPI inactivates fXa, we expressed the serpin in mammalian cells and characterized its reactivity with both wild-type and selected mutants of fXa that 1) contained substitutions in the autolysis loop and the heparin binding exosite, 2) lacked the first EGF-like domain (fXa-des-EGF-1), or 3) contained the Gla domain of protein C (fXa/PC-Gla). Inhibition studies in both the presence and absence of PZ revealed that Arg-143, Lys-147, and Arg-154 of the autolysis loop and Lys-96, Lys-169, and Lys-236 of the heparin binding exosite are required for recognition of ZPI, with Arg-143 being essential for the interaction. Similar studies with fXa-des-EGF-1 and fXa/PC-Gla suggested that protein-protein interaction with either the Gla or the EGF-1 domain may not play a dominant role in the PZ-dependent recognition of fXa by the serpin on phospholipid vesicles. Further studies showed that an inactive Ser-195 to Ala mutant of fXa effectively competes with wild-type fXa for binding to the non-serpin inhibitors tissue factor pathway inhibitor and recombinant tick anticoagulant peptide, but does not compete for binding to ZPI. This suggests that the catalytic residue of fXa is required for interaction with ZPI.

Targeting exosites on blood coagulation proteases

The high specificity of blood coagulation proteases has been attributed not only to residues surrounding the active site but also to other surface domains that are involved in recognizing and interacting with macromolecular substrates and inhibitors. Specific blood coagulation inhibitors obtained from exogenous sources such as blood sucking salivary glands and snake venoms have been identified. Some of these inhibitors interact with exosites on coagulation enzymes. Two examples are discussed in this short revision. Bothrojaracin is a snake venom-derived protein that binds to thrombin exosites 1 and 2. Complex formation impairs several exosite-dependent activities of thrombin including fibrinogen cleavage and platelet activation. Bothrojaracin also interacts with proexosite 1 on prothrombin thus decreasing the zymogen activation by the prothrombinase complex (FXa/FVa). Ixolaris is a two Kunitz tick salivary gland inhibitor, that is homologous to tissue factor pathway inhibitor. Recently it was demonstrated that ixolaris binds to heparin-binding exosite of FXa, thus impairing the recognition of prothrombin by the enzyme. In addition, ixolaris interacts with FX possibly through the heparin-binding proexosite. Differently from FX, the ixolaris-FX complex is not recognized as substrate by the intrinsic tenase complex (FIXa/FVIIIa). We conclude that these inhibitors may serve as tools for the study of coagulation exosites as well as prototypes for new anticoagulant drugs.

The Factor IXa Heparin-Binding Exosite Is a Cofactor Interactive Site: Mechanism for Antithrombin-Independent Inhibition of Intrinsic Tenase by Heparin

Therapeutic heparin concentrations selectively inhibit the intrinsic tenase complex in an antithrombin-independent manner. To define the molecular target and mechanism for this inhibition, recombinant human factor IXa with alanine substituted for solvent-exposed basic residues (H92, R170, R233, K241) in the protease domain was characterized with regard to enzymatic activity, heparin affinity, and inhibition by low molecular weight heparin (LMWH). These mutations only had modest effects on chromogenic substrate hydrolysis and the kinetics of factor X activation by factor IXa. Likewise, factor IXa H92A and K241A showed factor IXa-factor VIIIa affinity similar to factor IXa wild type (WT). In contrast, factor IXa R170A demonstrated a 4-fold increase in apparent factor IXa-factor VIIIa affinity and dramatically increased coagulant activity relative to factor IXa WT. Factor IXa R233A demonstrated a 2.5-fold decrease in cofactor affinity and reduced ability to stabilize cofactor half-life relative to wild type, suggesting that interaction with the factor VIIIa A2 domain was disrupted. Markedly (R233A) or moderately (H92A, R170A, K241A) reduced binding to immobilized LMWH was observed for the mutant proteases. Solution competition demonstrated that the EC(50) for LMWH was increased less than 2-fold for factor IXa H92A and K241A but over 3.5-fold for factor IXa R170A, indicating that relative heparin affinity was WT > H92A/K241A > R170A >> R233A. Kinetic analysis of intrinsic tenase inhibition demonstrated that relative affinity for LMWH was WT > K241A > H92A > R170A >> R233A, correlating with heparin affinity. Thus, LMWH inhibits intrinsic tenase by interacting with the heparin-binding exosite in the factor IXa protease domain, which disrupts interaction with the factor VIIIa A2 domain.

Antithrombin Activation by Nonsulfated, Non-Polysaccharide Organic Polymer

Accelerated antithrombin inhibition of procoagulant enzymes has been exclusively achieved with polysulfated polysaccharides. We reasoned that antithrombin activation should be possible with nonsulfated activators based only on carboxylic acid groups. As a proof of the principle, linear poly(acrylic acid)s were found to bind to antithrombin and accelerate inhibition of factor Xa and thrombin. Our work demonstrates that molecules completely devoid of sulfate groups can activate antithrombin effectively and, more importantly, suggests that it may be possible to develop orally bioavailable, carboxylate-based antithrombin activators.

Activation of factor VIII and mechanisms of cofactor action

The factor VIII procofactor circulates as a metal ion-dependent heterodimer of a heavy chain and light chain. Activation of factor VIII results from limited proteolysis catalyzed by thrombin or factor Xa, which binds the factor VIII substrate over extended interactive surfaces. The proteases efficiently cleave factor VIII at three sites, two within the heavy and one within the light chain resulting in alteration of its covalent structure and conformation and yielding the active cofactor, factor VIIIa. The role of factor VIIIa is to markedly increase the catalytic efficiency of factor IXa in the activation of factor X. This effect is manifested in a dramatic increase in the catalytic rate constant, k(cat), by mechanisms that remain poorly understood.

Zymogenic and enzymatic properties of the 70-80 loop mutants of factor X/Xa

The Ca(2+) binding 70-80 loop of factor X (fX) contains one basic (Arg(71)) and three acidic (Glu(74), Glu(76), and Glu(77)) residues whose contributions to the zymogenic and enzymatic properties of the protein have not been evaluated. We prepared four Ala substitution mutants of fX (R71A, E74A, E76A, and E77A) and characterized their activation kinetics by the factor VIIa and factor IXa in both the absence and presence of cofactors. Factor VIIa exhibited normal activity toward E74A and E76A and less than a twofold impaired activity toward R71A and E77A in both the absence and presence of tissue factor. Similarly, factor IXa in the absence of factor VIIIa exhibited normal activity toward both E74A and E76A; however, its activity toward R71A and E77A was impaired approximately two- to threefold. In the presence of factor VIIIa, factor IX activated all mutants with approximately two- to fivefold impaired catalytic efficiency. In contrast to changes in their zymogenic properties, all mutant enzymes exhibited normal affinities for factor Va, and catalyzed the conversion of prothrombin to thrombin with normal catalytic efficiencies. However, further studies revealed that the affinity of mutant enzymes for interaction with metal ions Na(+) and Ca(2+) was impaired. These results suggest that although charged residues of the 70-80 loop play an insignificant role in fX recognition by the factor VIIa-tissue factor complex, they are critical for the substrate recognition by factor IXa in the intrinsic Xase complex. The results further suggest that mutant residues do not play a specific role in the catalytic function of fXa in the prothrombinase complex.

The critical role of the 185-189-loop in the factor Xa interaction with Na+ and factor Va in the prothrombinase complex

The S1 site (Asp(189)) of factor Xa (fXa) is located on a loop (residues 185-189) that contains three solvent-exposed charged residues (Asp(185), Lys(186), and Glu(188)) below the active-site pocket of the protease. To investigate the role of these residues in the catalytic function of fXa, we expressed three mutants of the protease in which the charges of these residues were neutralized by their substitutions with Ala (D185A, K186A, and E188A). Kinetic studies revealed that E188A has a normal catalytic activity toward small synthetic and natural substrates and inhibitors of fXa; however, the same activities were slightly ( approximately 2-fold) and dramatically ( approximately 20-50-fold) impaired for the D185A and K186A mutants, respectively. Further studies revealed that the affinity of D185A and K186A for interaction with Na(+) has also been altered, with a modest impairment ( approximately 2-fold) for the former and a dramatic impairment for the latter mutant. Both prothrombinase and direct binding studies indicated that K186A also has an approximately 6-fold impaired affinity for factor Va. Interestingly, a saturating concentration of factor Va restored the catalytic defect of K186A in reactions with prothrombin and the recombinant tick anticoagulant peptide that is known to interact with the Na(+) loop of fXa, but not with other substrates. These results suggest that factor Va interacts with 185-189-loop for fXa, which is energetically linked to the Na(+)-binding site of the protease.

Mechanisms of Interactions of Factor X and Factor Xa with the Acidic Region in the Factor VIII A1 Domain

The 337-372 sequence of the factor VIIIa A1 subunit contains interactive sites for both zymogen factor X and the active enzyme, factor Xa. Solid phase binding studies indicated that factor Xa possessed a >20-fold higher affinity for the isolated A1 subunit of factor VIIIa compared with factor X. Heparin completely inhibited zero-length cross-linking of the 337-372 peptide to factor Xa but not to factor X. In the presence of calcium, factor Xa showed greater affinity for heparin than factor X. Studies using factor Xa mutants in which heparin-binding exosite residues were individually replaced by Ala showed that the R240A mutant was defective in recognition of the Lys36 cleavage site, generating the A137-372 intermediate with approximately 20% the catalytic efficiency of wild type. This defect likely resulted from an approximately 4-fold increase in Km for the A1 substrate because kcat values for the wild type and mutant were equivalent. Cleavage of the A1-A2 domain junction by factor Xa R240A was not blocked by the 337-372 peptide. Studies using mutant factor VIII where clustered acidic residues in the 337-372 segment were replaced by Ala showed that a factor VIIIa D361A/D362A/D363A mutant possessed a approximately 1.6-fold increase in Km for factor X compared with wild type. However, similar Km values were observed for recombinant factor X and R240A substrates. These results indicate that the binding regions of factor X and factor Xa for A1 domain overlap and that both utilize acidic residues 361-363. Furthermore, factor Xa but not factor X interacts with high affinity at this site via residues contained within the heparin-binding exosite of the proteinase.

Heparin-binding domains in vascular biology

Heparin is a major anticoagulant with activity mediated primarily through its interaction with antithrombin (AT). Heparan sulfate (HS), structurally related to heparin, binds a wide range of proteins of different functionality, taking part in various physiological and pathological processes. The heparin-AT complex, the most well understood facet of anticoagulation, serves as a prototypical example of the important role of heparin/HS in vascular biology. Extensive studies have identified common structural features in heparin/HS-binding sites of proteins. These include the elucidation of consensus sequences in proteins, patterns of clusters of basic and nonbasic residues, and common spatial arrangements of basic amino acids in the heparin-binding sites. Although these studies have provided valuable information, heparin/HS-binding proteins differ widely in structure. The prediction of heparin/HS-binding proteins from sequence information is not currently possible, and elucidation of protein-binding sites requires the individual study of each glycosaminoglycan-protein complex. Thus, x-ray crystallography and site-directed mutagenesis experiments are among the most powerful tools, providing accurate structural information, facilitating the characterization of heparin-protein complexes. Heparin and structurally related heparan sulfate bind a large number of proteins, taking part in a wide range of biological processes, particularly ones involved in vascular biology. Heparin-binding domains share certain common structural features, but there is no absolute dependency on specific sequences or protein folds.

Role of the gamma-carboxyglutamic acid domain of activated factor X in the presence of calcium during inhibition by antithrombin-heparin

BACKGROUND

Factor (F)Xa has 11 gamma-carboxylated glutamic acid (Gla) residues that are involved in calcium-dependent membrane binding. The serpin antithrombin (AT) is an important physiological regulator of FXa activity in an inhibition reaction that is enhanced by heparin. Recently, Rezaie showed that calcium further enhanced the heparin-catalyzed AT inhibition of FXa by promoting 'ternary complex' formation, and these results showed a role for the gamma-carboxyl-glutamate (Gla)-domain of FXa.

OBJECTIVES

In this study, we used recombinant FXa mutants to assess the role of individual Gla residues in augmenting or antagonizing the AT-heparin inhibition reaction in the presence of calcium.

RESULTS AND CONCLUSIONS

In the absence of heparin, AT inhibition of plasma and the recombinant FXas were essentially equivalent. Similar to plasma-derived FXa, calcium increased about 3-fold the inhibition rate of wild-type recombinant FXa by AT-heparin over that in the presence of EDTA. Interestingly, three different effects were found with the recombinant FXa Gla-mutants for AT-heparin inhibition: (i) Gla-->Asp 14 and 29 were enhanced without calcium; (ii) Gla-->Asp 16 and 26 were not enhanced by calcium; and (iii) Gla-->Asp 19 was essentially the same as wild-type recombinant FXa. These results support a theory that mutating individual Gla residues in FXa alters the calcium-induced conformational changes in the Gla region and affects the antithrombin-heparin inhibition reaction.

Role of the N-terminal Epidermal Growth Factor-like Domain of Factor X/Xa

The functional importance of the N-terminal epidermal growth factor-like domain (EGF-N) of factor X/Xa (FX/Xa) was investigated by constructing an FX mutant in which the exon coding for EGF-N was deleted from FX cDNA. Following expression and purification to homogeneity, the mutant was characterized with respect to its ability to function as a zymogen for either the factor VIIa-tissue factor complex or the factor IXa-factor VIIIa complex and then to function as an enzyme in the prothrombinase complex to catalyze the conversion of prothrombin to thrombin. It was discovered that EGF-N is essential for the recognition and efficient activation of FX by both activators in the presence of the cofactors. On the other hand, the FXa mutant interacted with factor Va with a normal apparent dissociation constant and activated prothrombin with approximately 3-fold lower catalytic efficiency in the prothrombinase complex. Surprisingly, the mutant activated prothrombin with approximately 12-fold better catalytic efficiency than wild-type FXa in the absence of factor Va. The mutant was inactive in both prothrombin time and activated partial thromboplastin time assays; however, it exhibited a similar specific activity in a one-stage FXa clotting assay. These results suggest that EGF-N of FX is required for the cofactor-dependent zymogen activation by both physiological activators, but it plays no apparent role in FXa recognition of the cofactor in the prothrombinase complex.

Identification of a factor Xa-interactive site within residues 337-372 of the factor VIII heavy chain

We recently demonstrated that the residues 337-372, comprising the acidic C-terminal region in A1 subunit, interact with factor Xa during the proteolytic inactivation of factor VIIIa (Nogami, K., Wakabayashi, H., and Fay, P. J. (2003) J. Biol. Chem. 278, 16502-16509). We now show this sequence is important for factor Xa-catalyzed activation of factor VIII. Peptide 337-372 markedly inhibited cofactor activation, consistent with a delay in the rate of cleavage at the A1-A2 junction. Studies using the isolated factor VIII heavy chain indicated that the peptide completely blocked cleavage at the A1-A2 junction (IC50 = 11 microm) and partially blocked cleavage at the A2-B junction (IC50 = 100 microm). Covalent cross-linking was observed between the 337-372 peptide and factor Xa following reaction with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide, and the peptide quenched the fluorescence of dansyl-Glu-Gly-Arg active site-modified factor Xa, suggesting that residues 337-372 directly interact with factor Xa. Studies using a monoclonal antibody recognizing residues 351-365 as well as the peptide to this sequence further restricted the interactive region. Mutant factor VIII molecules in which clustered acidic residues in the 337-372 segment were converted to alanine were evaluated for activation by factor Xa. Of the mutants tested, only factor Xa-catalyzed activation of the D361A/D362A/D363A mutant was inhibited with peak activity of approximately 50% and an activation rate constant of approximately 30% of the wild type values. These results indicate that the 337-372 acidic region separating A1 and A2 domains and, in particular, a cluster of acidic residues at position 361-363 contribute to a unique factor Xa-interactive site within the factor VIII heavy chain that promotes factor Xa docking during cofactor activation.

The Elusive Role of the Potential Factor X Cation-binding Exosite-1 in Substrate and Inhibitor Interactions

A number of studies suggest that blood-clotting factor X (FX) uses secondary site(s) to interact (as a substrate) with its activators. Numerous pieces of evidence also imply that, within prothrombinase (as an enzyme), activated FX (FXa) uses exosite(s) for cofactor Va and/or prothrombin recognition. Similarly, FXa exosite(s) seem to govern interaction with inhibitors. An obvious difference between FXa and thrombin resides within a region called exosite-1: positively charged in thrombin and clearly of opposite polarity in FXa. To investigate the role of this potential cation-binding exosite, we prepared a series of mutants within loops 34-40 and 70-80 of FX. Overall, the mutations induced relatively subtle, non-synergistic modulation. The potential exosite was dispensable for FX activation and is unlikely to constitute a critical region for factor Va binding, albeit it is clearly important for prothrombin activation. Our data also implicate loop 34-40 of FXa in the interaction with the tissue factor pathway inhibitor, in prevention of plasminogen activator inhibitor-1 binding, and in tempering inhibition by heparin-activated antithrombin. Compared with FX, mutants with reduced electrostatic potential potentiated thrombin production in FX-depleted plasma, whereas mutants with inverted electrostatic potential impeded clotting. Despite the definite consequences observed, disruption of the potential cation-binding exosite of FX had rather weak effects, far from what would be expected if this region was as crucial as in thrombin.

Localization of an Antithrombin Exosite That Promotes Rapid Inhibition of Factors Xa and IXa Dependent on Heparin Activation of the Serpin

We have previously shown that exosites in antithrombin outside the P6-P3' reactive loop region become available upon heparin activation to promote rapid inhibition of the target proteases, factor Xa and factor IXa. To identify these exosites, we prepared six antithrombin-alpha 1-proteinase inhibitor chimeras in which antithrombin residues 224-286 and 310-322 that circumscribe a region surrounding the reactive loop on the inhibitor surface were replaced in 10-16-residue segments with the homologous segments of alpha1-proteinase inhibitor. All chimeras bound heparin with a high affinity similar to wild-type, underwent heparin-induced fluorescence changes indicative of normal conformational activation, and were able to form SDS-stable complexes with thrombin, factor Xa, and factor IXa and inhibit these proteases with stoichiometries minimally altered from those of wild-type antithrombin. With only one exception, conformational activation of the chimeras with a heparin pentasaccharide resulted in normal approximately 100-300-fold enhancements in reactivity with factor Xa and factor IXa. The exception was the chimera in which residues 246-258 were replaced, corresponding to strand 3 of beta-sheet C, which showed little or no enhancement of its reactivity with these proteases following pentasaccharide activation. By contrast, all chimeras including the strand 3C chimera showed essentially wild-type reactivities with thrombin after pentasaccharide activation as well as normal full-length heparin enhancements in reactivity with all proteases due to heparin bridging. These findings suggest that antithrombin exosites responsible for enhancing the rates of factor Xa and factor IXa inhibition in the conformationally activated inhibitor lie in strand 3 of beta-sheet C of the serpin.

Influence of peptide conformation on oligosaccharide binding characteristics--a study using apamin-based chimeric peptide

Interactions between proteins and heparin play a crucial role in most of the cellular process. Unraveling the forces that govern the formation of these complexes is vital for understanding the specificities involved in these biomolecular events. In the present study, a detailed analysis has been undertaken to evaluate the effect(s) of peptide conformation on heparin-binding, using a chimeric peptide, apaK6--a chimera of a highly stable neurotoxic peptide from honey-bee venom and a de novo designed lysine-rich peptide. The dissociation constants of these peptide-heparin complexes were found to be in the submicromolar range. Comparison of the results obtained from the titration of the disulfide-reduced and disulfide-intact chimeric peptide with various sulfated oligosaccharides, derived from heparin, suggest that the initial structure of the peptide has pronounced effect on the binding affinity, binding modes and also on binding preferences. The results of this study indicate that the heparin-binding specificity of an isolated peptide and that exhibited by the same peptide when present in a globular protein could be significantly different, especially if the isolated peptide undergoes conformational change(s) upon binding to the sulfated oligosaccharides. In addition, such dependency of the binding specificity on the preformed structures could be utilized for the design of high-affinity and sequence-specific heparin-binding polypeptides.

Platelet factor 4 neutralizes heparan sulfate-enhanced antithrombin inactivation of factor Xa by preventing interaction(s) of enzyme with polysaccharide

Platelet factor 4 (PF4) is a heparin-binding protein which exhibits anti-heparin activities through the inhibition of antithrombin (AT)-dependent reactions with the serine proteases thrombin and factor Xa. PF4 also neutralizes heparan sulfate (HS), a glycosaminoglycan (GAG) present on the surface of endothelial cells, thereby possibly modulating an anticoagulant response. Previous models of PF4 mechanism did not distinguish whether PF4 causes steric hindrance of AT binding to fXa or of AT binding to the surface of the GAG chain. To shed light on the mechanism of PF4, studies of HS/heparin-catalyzed fXa inactivation by AT were undertaken. The results were consistent with PF4 directly interfering with AT binding to fXa rather than AT binding to the GAG chain, since PF4 did not prevent the heparin-dependent increase in AT intrinsic fluorescence. In fact, PF4 mechanism was competitive with respect to AT and non-competitive with respect to fXa, suggesting inhibition of important regulatory/catalytic interactions of fXa with the polysaccharide. Altogether, the results suggested a model by which PF4 bound to proximal (but distinct) sites to AT, resulting in steric interference of fXa binding to both polysaccharide and AT. It is proposed that PF4 inhibited the sequence of events recapitulated in the template mechanism describing heparin-dependent inhibition of fXa.

Glycosaminoglycans Bind Factor Xa in a Ca2+-Dependent Fashion and Modulate Its Catalytic Activity

Recent studies have demonstrated the existence of a Ca(2+)-dependent heparin-binding site on factor Xa. To characterize this heparin-binding site, the extrinsic fluorescence of fluorescein-labeled, active site-blocked factor Xa was monitored as it was titrated with glycosaminoglycans of various sulfate content and chain length. The binding of glycosaminoglycans to factor Xa appears to be charge-dependent because affinity is correlated with degree of glycosaminoglycan sulfation. All glycosaminoglycans bind factor Xa with higher affinity in the presence of Ca(2+) than in its absence. In contrast, when Gla-domainless factor Xa was substituted for factor Xa, glycosaminoglycans bound with similar affinities in the absence and presence of Ca(2+). These results support the hypothesis that the anionic Gla domain impairs glycosaminoglycan binding in the absence of Ca(2+). The changes in fluorescence intensity of factor Xa when titrated with glycosaminoglycans suggest that glycosaminoglycans induce conformational changes in the active site environment of factor Xa. To explore the consequences of these conformational changes, the effect of glycosaminoglycans on the catalytic activity of factor Xa was examined. Glycosaminoglycans influenced the ability of factor Xa to cleave chromogenic substrates and attenuated the capacity of factor Xa to activate factor VII. The potency of glycosaminoglycans in these assays reflected their affinity for factor Xa. These studies suggest that glycosaminoglycan binding perturbs exosites on the surface of factor Xa, potentially modifying interactions with cofactors or substrates.

Mechanism of catalysis of inhibition of factor IXa by antithrombin in the presence of heparin or pentasaccharide

Because of the homology between factor IXa and factor Xa (f.IXa and f.Xa, respectively), and the critical upstream position of f.IXa in the coagulation cascade, the contribution of the heparin-derived pentasaccharide to antithrombin-mediated inhibition of f.IXa was investigated. Pentasaccharide promotes inhibition of both f.IXa and f.Xa generated in recalcified plasma. This result demonstrates that antithrombin is the predominant inhibitor of f.IXa in plasma, and that the activity of antithrombin is promoted by pentasaccharide. Kinetic experiments reveal that pentasaccharide increases the rates of antithrombin-mediated inhibition of both f.IXa and f.Xa by 2 orders of magnitude. These findings indicate that pentasaccharide-induced conformational changes in antithrombin enhance its capacity to inhibit both f.IXa and f.Xa. In the presence of Ca2+, full-length heparin produces an additional approximately 10-fold increase in the rates of inhibition of both enzymes, consistent with a template role of heparin. Heparin binding to f.Xa was previously shown to be promoted in the presence of Ca2+. Binding studies with f.IXa reveal a 10-fold higher affinity for heparin in the presence of Ca2+ compared with its absence. Thus, Ca2+ promotes heparin-catalyzed inhibition of f.IXa and f.Xa by antithrombin by augmenting the template mechanism. These results indicate that heparin-mediated catalysis of f.IXa inhibition by antithrombin reflects both pentasaccharide-induced conformational changes and heparin-mediated bridging of antithrombin to f.IXa. Furthermore, our data suggest that the efficacy of pentasaccharide for prevention and treatment of thrombotic disorders may reflect its action at two sites in the coagulation system.

Heparin Inhibits the Intrinsic Tenase Complex by Interacting with an Exosite on Factor IXa

The specific molecular target for direct heparin inhibition of factor X activation by intrinsic tenase (factor IXa-factor VIIIa) was investigated. Comparison of size-fractionated oligosaccharides demonstrated that an octasaccharide was sufficient to inhibit intrinsic tenase. Substitution of soluble dihexanoic phosphatidylserine (C6PS) for phospholipid (PL) vesicles demonstrated that inhibition by low-molecular weight heparin (LMWH) was independent of factor IXa-factor VIIIa membrane assembly. LMWH also inhibited factor X activation by the factor IXa-PL complex via a distinct mechanism that required longer oligosaccharides and was independent of substrate concentrations. The apparent affinity of LMWH for the factor IXa-PL complex was higher in the absence of factor VIIIa, suggesting that the cofactor adversely affected the interaction of heparin with factor IXa-phospholipid. LMWH did not interact directly with the active site, as it failed to inhibit chromogenic substrate cleavage by the factor IXa-PL complex. LMWH induced a modest decrease in factor IXa-factor VIIIa affinity [K(D(app))] on PL vesicles that did not account for the inhibition. In contrast, LMWH caused a substantial reduction in factor IXa-factor VIIIa affinity in the presence of C6PS that fully accounted for the inhibition. Factor IXa bound LMWH with significantly higher affinity than factor X by competition solution affinity analysis, and the K(D(app)) for the factor IXa-LMWH complex agreed with the K(I) for inhibition of the factor IXa-PL complex by LMWH. Thus, LMWH binds to an exosite on factor IXa that antagonizes cofactor activity without disrupting factor IXa-factor VIIIa assembly on the PL surface. This exosite may contribute to the clinical efficacy of heparin and represents a novel target for antithrombotic therapy.

Identification of distinct sequences in human blood coagulation factor Xa and prothrombin essential for substrate and cofactor recognition in the prothrombinase complex

To identify amino acid sequences in factor Xa (fXa) and prothrombin (fII) that may be involved in prothrombinase complex (fXa.factor Va.fII.phospholipids) assembly, synthetic peptides based on fXa and fII sequences were prepared and screened for their ability to inhibit fXa-induced clotting of normal plasma. One fII peptide (PT557-571 homologous to chymotrypsin (CHT) residues 225-239) and two fXa peptides (X404-418, CHT231-244, and X415-429, CHT241-252C) potently inhibited plasma clotting and prothrombinase activity with 50% inhibition between 41 and 115 microM peptide. Inhibition of prothrombinase by PT557-571 and X415-429 was fVa-independent, whereas the inhibition by X404-418 was fVa-dependent. X404-418 inhibited the binding of fVa to fluorescein-labeled, inhibited fXai in the presence of phosphatidylcholine/phosphatidylserine vesicles, whereas X415-429 inhibited binding of fII to phospholipid-bound fluorescein-labeled, inhibited fXai. PT557-571 altered the fluorescence emission of fluorescein-labeled fXai, showing that PT557-571 binds to fXai. These data suggest that residues 404-418 in fXa provide fVa binding sites, whereas residues 557-571 in fII and 415-429 in fXa mediate interactions between fXa and fII in the prothrombinase complex.

Contribution of basic residues of the autolysis loop to the substrate and inhibitor specificity of factor IXa

The autolysis loop (residues 143-154 in chymotrypsinogen numbering) plays a pivotal role in determining the macromolecular substrate and inhibitor specificity of coagulation proteases. This loop in factor IXa (FIXa) has 3 basic residues (Arg143, Lys147, and Arg150) whose contribution to the protease specificity of factor IXa has not been studied. Here, we substituted these residues individually with Ala in Gla-domainless forms of recombinant factor IX expressed in mammalian cells. All mutants exhibited normal amidolytic activities toward a FIXa-specific chromogenic substrate. However, Arg143 and Lys147 mutants showed a approximately 3- to 6-fold impairment in FX activation, whereas the Arg150 mutant activated factor X normally both in the absence and presence of factor VIIIa. By contrast, Arg143 and Lys147 mutants reacted normally with antithrombin (AT) in both the absence and presence of the cofactor, heparin. However, the reactivity of the Arg150 mutant with AT was impaired 6.6-fold in the absence of heparin and 33- to 70-fold in the presence of pentasaccharide and full-length heparins. These results suggest that Arg143 and Lys147 of the autolysis loop are recognition sites for FX independent of factor VIIIa, and Arg150 is a specific recognition site for AT that can effectively interact with AT only if the serpin is in the heparin-activated conformation.

Mechanisms of glycosaminoglycan activation of the serpins in hemostasis

Serpins are the predominant protease inhibitors in the higher organisms and are responsible, in humans, for the control of many highly regulated processes including blood coagulation and fibrinolysis. The serpin inhibitory mechanism has recently been revealed by the solution of a crystallographic structure of the final serpin-protease complex. The serpin mechanism, in contrast to the classical lock-and-key mechanism, involves dramatic conformational change in both the inhibitor and the inhibited protein. The final result is a stable covalent complex in which the properties of each component are altered so as to allow clearance from the circulation. Several serpins are involved in hemostasis: antithrombin (AT) inhibits many coagulation proteases, most importantly factor Xa and thrombin; heparin cofactor II (HCII) inhibits thrombin; protein C inhibitor (PCI) inhibits activated protein C and thrombin bound to thrombomodulin; plasminogen activator inhibitor 1 inhibits tissue plasminogen activator; and alpha2-antiplasmin inhibits plasmin. Nearly all of these reactions are accelerated through interactions with glycosaminoglycans (GAGs) such as heparin or heparan sulfate. Recent structures of AT, HCII and PCI have revealed how in each case the serpin mechanism has been fine-tuned by evolution to bring about high levels of regulatory control, and how seemingly disparate mechanisms of GAG binding and activation can share critical elements. By considering the serpins involved in hemostasis together it is possible to develop a deeper understanding of their complex individual roles.

Mechanisms of factor Xa-catalyzed cleavage of the factor VIIIa A1 subunit resulting in cofactor inactivation

Activation of factor VIII by factor Xa is followed by proteolytic inactivation resulting from cleavage within the A1 subunit (residues 1-372) of factor VIIIa. Factor Xa attacks two sites in A1, Arg(336), which precedes the highly acidic C-terminal region, and a recently identified site at Lys(36). By using isolated A1 subunit as substrate for proteolysis, production of the terminal fragment, A1(37-336), was shown to proceed via two pathways identified by the intermediates A1(1-336) and A1(37-372) and generated by initial cleavage at Arg(336) and Lys(36), respectively. Appearance of the terminal product by the former pathway was 7-8-fold slower than the product obtained by the latter pathway. The isolated A1 subunit was cleaved slowly, independent of the presence of phospholipid. The A1/A3-C1-C2 dimer demonstrated an approximately 3-fold increased cleavage rate constant, and inclusion of phospholipid further enhanced this value by approximately 2-fold. Although association of A1 or A1(37-372) with A3-C1-C2 enhanced the rate of cleavage at Arg(336), inclusion of A3-C1-C2 did not affect the cleavage at Lys(36) in A1(1-336). A synthetic peptide 337-372 blocked the cleavage at Lys(36) (IC(50) = 230 microm) while showing little if any effect on cleavage at Arg(336). Proteolysis at Lys(36), and to a lesser extent Arg(336), was inhibited in a dose-dependent manner by heparin. These results suggest that inactivating cleavages catalyzed by factor Xa at Lys(36) and Arg(336) are regulated in part by the A3-C1-C2 subunit. Furthermore, cleavage at Lys(36) appears to be selectively modulated by the C-terminal acidic region of A1, a region that may interact with factor Xa via its heparin-binding exosite.

Residues Phe342-Asn346 of activated coagulation factor IX contribute to the interaction with low density lipoprotein receptor-related protein

When blood coagulation factor IX is converted to activated factor IX (factor IXa), it develops enzymatic activity and exposes the binding sites for both activated factor VIII and the endocytic receptor low density lipoprotein receptor-related protein (LRP). In the present study we investigated the interaction between factor IXa and LRP in more detail, using an affinity-purified soluble form of LRP (sLRP). Purified sLRP and full-length LRP displayed similar binding to factor IXa. An anti-factor IX monoclonal antibody CLB-FIX 13 inhibited factor IXa.sLRP complex formation. Both the antibody and a soluble recombinant fragment of LRP (i.e. cluster IV) interfered with factor IXa amidolytic activity, suggesting that the antibody and LRP share similar binding regions near the active site of factor IXa. Next, a panel of recombinant factor IXa variants with amino acid replacements in the surface loops bordering the active site was tested for binding to antibody CLB-FIX 13 and sLRP in a solid phase binding assay. Factor IXa variants with mutations in the region Phe(342)-Asn(346), located between the active site of factor IXa and factor VIII binding helix, showed reduced binding to both antibody CLB-FIX 13 and sLRP. Surface plasmon resonance analysis revealed that the variant with Asn(346) replaced by Asp displayed slower association to sLRP, whereas the variant with residues Phe(342)-Tyr(345) replaced by the corresponding residues of thrombin showed faster dissociation. Recombinant soluble LRP fragment cluster IV inhibited factor IXa-mediated activation of factor X with IC(50) values of 5 and 40 nm in the presence and absence of factor VIII, respectively. This inhibition thus seems to occur via two mechanisms: by interference with factor IXa.factor VIIIa complex assembly and by direct inhibition of factor IXa enzymatic activity. Accordingly, we propose that LRP may function as a regulator of blood coagulation.

Localization of the heparin binding exosite of factor IXa

Factor IXa (FIXa) is known to have a binding site for heparin that has not been mapped by a mutagenesis study. By homology modeling based on structural data, we identified eight basic residues in the catalytic domain of FIXa that can potentially bind to heparin. These residues, Lys(98), Lys(126), Arg(165), Arg(170), Lys(173), Lys(230), Arg(233), and Lys(239) (chymotrypsin numbering) were substituted with Ala in separate constructs in Gla-domainless forms. Following activation, it was found that all FIXa derivatives cleaved the chromogenic substrate CBS 31.39 with near normal catalytic efficiencies. Similarly, antithrombin inactivated FIXa derivatives with a similar second-order association rate constant (k(2)) in both the absence and presence of pentasaccharide. In the presence of a full-length heparin, however, k(2) values were dramatically impaired with certain mutants. Direct binding studies revealed that the same mutants lost their affinities for binding to heparin-Sepharose. Both kinetic and direct binding data indicated that five basic residues of FIXa in the following order of importance, Arg(233) > Arg(165) > Lys(230) > Lys(126) > Arg(170) are critical for binding to heparin. Consistent with these results, examination of the crystal structure of the catalytic domain of FIXa indicated that all five basic residues are spatially aligned in a manner optimal for interaction with heparin.

Nematode anticoagulant protein c2 reveals a site on factor Xa that is important for macromolecular substrate binding to human prothrombinase

The binding of recombinant nematode anticoagulant protein c2 (NAPc2) to either factor X or Xa is a requisite step in the pathway for the potent inhibition of VIIa tissue factor. We have used NAPc2 as a tight binding probe of human Xa to investigate protein substrate recognition by the human prothrombinase complex. NAPc2 binds with high affinity (K(d) approximately 1 nm) to both X and Xa in a way that does not require or occlude the active site of the enzyme. In contrast, NAPc2 is a tight binding, competitive inhibitor of protein substrate cleavage by human Xa incorporated into prothrombinase with saturating concentrations of membranes and Va. By fluorescence binding studies we show that NAPc2 does not interfere with the assembly of human prothrombinase. These are properties expected of an inhibitor that blocks protein substrate recognition by targeting extended macromolecular recognition sites (exosites) on the enzyme complex. A weaker interaction (K(d) = 260-500 nm) observed between NAPc2 and bovine X was restored to a high affinity one in a recombinant chimeric bovine X derivative containing 25 residues from the COOH terminus of the proteinase domain of human X. This region implicated in binding NAPc2 is spatially adjacent to a site previously identified as a potential exosite. Despite the weaker interaction with bovine Xa, NAPc2 was a tight binding competitive inhibitor of protein substrate cleavage by bovine prothrombinase as well. Extended enzymic surfaces elucidated with exosite-directed probes, such as NAPc2, may define a unique region of factor Xa that is modulated following its assembly into prothrombinase and in turn determines the binding specificity of the enzyme complex for its protein substrate.

Role of basic residues of the autolysis loop in the catalytic function of factor Xa

The autolysis loop of factor Xa (fXa) has four basic residues (Arg(143), Lys(147), Arg(150), and Arg(154)) whose contribution to protease specificity of fXa has not been examined. Here, we substituted these basic residues individually with Ala in the fX cDNA and expressed them in mammalian cells using a novel expression/purification vector system. Following purification to homogeneity and activation by the factor X activator from Russell viper venom, the mutants were characterized with respect to their ability to assemble into the prothrombinase complex to activate prothrombin and interact with target plasma fXa inhibitors, tissue factor pathway inhibitor (TFPI) and antithrombin. We show that all mutants interacted with factor Va with normal affinities and exhibited wild-type-like prothrombinase activities toward prothrombin. Lys(147) and Arg(154) mutants were inhibited by TFPI approximately 2-fold slower than wild type; however, both Arg(143) and Arg(150) mutants were inhibited normally by the inhibitor. The reactivities of Arg(143) and Lys(147) mutants were improved approximately 2-fold with antithrombin in the absence but not in the presence of heparin cofactors. On the other hand, the pentasaccharide-catalyzed reactivity of antithrombin with the Arg(150) mutant was impaired by an order of magnitude. These results suggest that Arg(150) of the autolysis loop may specifically interact with the activated conformation of antithrombin.

Ixolaris, a novel recombinant tissue factor pathway inhibitor (TFPI) from the salivary gland of the tick, Ixodes scapularis: identification of factor X and factor Xa as scaffolds for the inhibition of factor VIIa/tissue factor complex

Saliva of the hard tick and Lyme disease vector, Ixodes scapularis, has a repertoire of compounds that counteract host defenses. Following sequencing of an I scapularis salivary gland complementary DNA (cDNA) library, a clone with sequence homology to tissue factor pathway inhibitor (TFPI) was identified. This cDNA codes for a mature protein, herein called Ixolaris, with 140 amino acids containing 10 cysteines and 2 Kunitz-like domains. Recombinant Ixolaris was expressed in insect cells and shown to inhibit factor VIIa (FVIIa)/tissue factor (TF)-induced factor X (FX) activation with an inhibitory concentration of 50% (IC(50)) in the picomolar range. In nondenaturing gel, Ixolaris interacted stoichiometrically with FX and FXa but not FVIIa. Ixolaris behaves as a fast-and-tight ligand of the exosites of FXa and gamma-carboxyglutamic acid domainless FXa (des-Gla-FXa), increasing its amidolytic activity. At high concentration, Ixolaris attenuates the amidolytic activity of FVIIa/TF; however, in the presence of DEGR-FX or DEGR-FXa (but not des-Gla-DEGR-FXa), Ixolaris becomes a tight inhibitor of FVIIa/TF as assessed by recombinant factor IX (BeneFIX) activation assays. This indicates that FX and FXa are scaffolds for Ixolaris in the inhibition of FVIIa/TF and implies that the Gla domain is necessary for FVIIa/TF/Ixolaris/FX(a) complex formation. Additionally, we show that Ixolaris blocks FXa generation by endothelial cells expressing TF. Ixolaris may be a useful tool to study the structural features of FVIIa, FX, and FXa, and an alternative anticoagulant in cardiovascular diseases.

Contribution of basic residues of the 70-80-loop to heparin binding and anticoagulant function of activated protein C

The role of basic residues of the 70-80-loop, Arg(74), Arg(75), and Lys(78) (chymotrypsin numbering) in the catalytic function of activated protein C (APC) was investigated by expressing mutants of protein C in which these residues were replaced with Ala in three separate constructs. Following purification to homogeneity and activation by thrombin, the catalytic properties of the mutants were characterized with respect to their ability to cleave the chromogenic substrate Spectrozyme PCa, react with protein C inhibitor (PCI), and inactivate factor Va. Relative to wild-type APC, the mutants cleaved Spectrozyme PCa with identical or improved catalytic efficiencies. Similarly, PCI inhibited mutants with identical or improved second-order rate constants (k(2)) in the absence of heparin. However, the heparin-catalyzed inhibition of mutants by PCI was impaired approximately 10-fold. Analysis of k(2) values by a ternary complex model revealed that the affinities of mutants for heparin were impaired to a similar extent. Moreover, analysis of the NaCl gradient elution profiles of APC derivatives from Heparin-Sepharose supported this conclusion. An oligosaccharide containing 14 residues efficiently catalyzed the PCI inhibition of APC by a template mechanism. Further studies revealed that the ability of Arg(74) and Arg(75) mutants to inactivate factor Va was markedly impaired. We conclude that basic residues of the 70-80-loop are critical for the catalytic function of APC.

Partial activation of antithrombin without heparin through deletion of a unique sequence on the reactive site loop of the serpin

Native antithrombin (AT) has an inactive reactive site loop conformation unless it is activated by a unique pentasaccharide fragment of heparin (H(5)). Structural data suggests that this may be due to preinsertion of two N-terminal residues of the reactive site loop of the serpin into the A-beta-sheet of the molecule. Relative to alpha(1)-antitrypsin, the reactive site loop of AT has three additional residues, Arg(399), Val(400), and Thr(401), at the C-terminal P' end of the loop. To determine whether a longer reactive site loop of AT is responsible for loop preinsertion in the native conformation, mutants of the serpin were expressed in which these residues were individually or in combination deleted. Kinetic analysis suggested that deletion of two residues, Val(400) and Thr(401), changed the solution equilibrium of the serpin in favor of the active conformation, thereby enhancing the inhibition of factor Xa by an order of magnitude independent of H(5). Interestingly, the reactivity of this mutant with thrombin was impaired by the same order of magnitude in the absence, but not in the presence of H(5). These results suggest that a longer reactive site loop in AT is responsible for its inactive native conformation toward factor Xa, while at same time AT requires this feature to regulate the activity of thrombin.

Probing the molecular basis of factor Xa specificity by mutagenesis of the serpin, antithrombin

The molecular basis of the substrate and inhibitor specificity of factor Xa, the serine proteinase of the prothrombinase complex, was investigated by constructing two mutants of human antithrombin (HAT) in which the reactive site loop of the serpin from the P4-P4' site was replaced with the corresponding residues of the two factor Xa cleavage sites in prothrombin (HAT/Proth-1 and HAT/Proth-2). These mutants together with prethrombin-2, the smallest zymogen form of thrombin containing only the second factor Xa cleavage site, were expressed in mammalian cells, purified to homogeneity and characterized in kinetic reactions with factor Xa in both the absence and presence of cofactors; factor Va, high affinity heparin and pentasaccharide fragment of heparin. HAT/Proth-1 inactivated factor Xa approximately 3-4-fold better than HAT/Proth-2 in either the absence or presence of heparin cofactors. In the absence of a cofactor, factor Xa reacted with the HAT/Proth-2 and prethrombin-2 with similar second-order rate constants (approximately 2-3x10(2) M(-1)s(-1)). Pentasaccharide catalyzed the inactivation rate of factor Xa by the HAT mutants 300-500-fold. A similar 10(4)-10(5)-fold enhancement in the reactivity of factor Xa with prethrombin-2 and the HAT mutants was observed in the presence of the cofactors Va and heparin, respectively. Factor Va did not influence the reactivity of factor Xa with either one of the HAT mutants. These results suggest that (1) in the absence of a cofactor, the P4-P4' residues of HAT and prethrombin-2 primarily determine the specificity reactions with factor Xa, (2) factor Va binding to factor Xa is not associated with allosteric changes in the catalytic pocket of enzyme that would involve interactions with the P4-P4' binding sites, and (3) similar to allosteric activation of HAT by heparin, a role for factor Va in the prothrombinase complex may involve rearrangement of the residues surrounding the scissile bond of the substrate to facilitate its optimal docking into the catalytic pocket of factor Xa.

Localization of a heparin binding site in the catalytic domain of factor XIa

Inhibition of factor XIa by protease nexin II (K(i) approximately 450 pM) is potentiated by heparin (K(I) approximately 30 pM). The inhibition of the isolated catalytic domain of factor XIa demonstrates a similar potentiation by heparin (K(i) decreasing from 436 +/- 62 to 88 +/- 10 pM) and also binds to heparin on surface plasmon resonance (K(d) 11.2 +/- 3.2 nM vs K(d) 8.63 +/- 1.06 nM for factor XIa). The factor XIa catalytic domain contains a cysteine-constrained alpha-helix-containing loop: (527)CQKRYRGHKITHKMIC(542), identified as a heparin-binding region in other coagulation proteins. Heparin-binding studies of coagulation proteases allowed a grouping of these proteins into three categories: group A (binding within a cysteine-constrained loop or a C-terminal heparin-binding region), factors XIa, IXa, Xa, and thrombin; group B (binding by a different mechanism), factor XIIa and activated protein C; and group C (no binding), factor VIIa and kallikrein. Synthesized peptides representative of the factor XIa catalytic domain loop were used as competitors in factor XIa binding and inhibition studies. A native sequence peptide binds to heparin with a K(d) = 86 +/- 15 nM and competes with factor XIa in binding to heparin, K(i) = 241 +/- 37 nM. A peptide with alanine substitutions at (534)H, (535)K, (538)H, and (539)K binds and competes with factor XIa for heparin-binding in a manner nearly identical to that of the native peptide, whereas a scrambled peptide is approximately 10-fold less effective, and alanine substitutions at residues (529)K, (530)R, and (532)R result in loss of virtually all activity. We conclude that residues (529)K, (530)R, and (532)R comprise a high-affinity heparin-binding site in the factor XIa catalytic domain.

The antithrombin P1 residue is important for target proteinase specificity but not for heparin activation of the serpin. Characterization of P1 antithrombin variants with altered proteinase specificity but normal heparin activation

Heparin has been proposed to conformationally activate the serpin, antithrombin, by making the reactive center loop P1 arginine residue accessible to proteinases. To evaluate this proposal, we determined the effect of mutating the P1 arginine on antithrombin's specificity for target and nontarget proteinases in both native and heparin-activated states of the serpin. As expected, mutation of the P1 arginine to tryptophan, histidine, leucine, and methionine converted the specificity of antithrombin from a trypsin inhibitor (k(assoc) = 2 x 10(5) M(-1) s(-1)) to a chymotrypsin inhibitor (k(assoc) = 10(3)-10(5) M(-1) s(-1)). However, heparin pentasaccharide activation increased the reactivity of the P1 variants with chymotrypsin or of the wild-type inhibitor with trypsin only 2-6-fold, implying that the P1 residue had similar accessibilities to these proteinases in native and activated states. Mutation of the P1 arginine greatly reduced k(assoc) for antithrombin inhibition of thrombin and factor Xa from 40- to 5000-fold, but heparin normally accelerated the reactions of the variant antithrombins with these enzymes to make them reasonably efficient inhibitors (k(assoc) = 10(3)-10(4) M(-1) s(-1)). Fluorescence difference spectra of wild-type and P1 tryptophan variant antithrombins showed that the P1 tryptophan exhibited fluorescence properties characteristic of a solvent-exposed residue which were insignificantly affected by heparin activation. Moreover, all P1 variant antithrombins bound heparin with approximately 2-3-fold higher affinities than the wild type. These findings are consistent with the P1 mutations disrupting a P1 arginine-serpin body interaction which stabilizes the native low-heparin affinity conformation, but suggest that this interaction is of low energy and unlikely to limit the accessibility of the P1 residue. Together, these findings suggest that the P1 arginine residue is similarly accessible to proteinases in both native and heparin-activated states of the serpin and contributes similarly to the specificity of antithrombin for thrombin and factor Xa in the two serpin conformational states. Consequently, determinants other than the P1 residue are responsible for enhancing the specificity of antithrombin for the two proteinases when activated by heparin.

Phosphorothioate oligonucleotides inhibit the intrinsic tenase complex by an allosteric mechanism

Phosphorothioate oligonucleotides (PS ODNs) prolong the activated partial thromboplastin time in human plasma by inhibition of intrinsic tenase (factor IXa-factor VIIIa) activity. This inhibition was characterized using ISIS 2302, a 20-mer antisense PS ODN. ISIS 2302 demonstrated hyperbolic, mixed-type inhibition of factor X activation by the intrinsic tenase complex. The decrease in V(max(app)) was analyzed by examining complex assembly, cofactor stability, and protease catalysis. ISIS 2302 did not inhibit factor X activation by the factor IXa-phospholipid complex, or significantly affect factor VIII-phospholipid affinity. Inhibitory concentrations of ISIS 2302 modestly decreased the affinity of factor IXa-factor VIIIa binding in the presence of phospholipid (K(D) = 11.5 vs 4.8 nM). This effect was insufficient to explain the reduction in V(max(app)). ISIS 2302 did not affect the in vitro half-life of factor VIIIa, suggesting it did not destabilize cofactor activity. In the presence of 30% ethylene glycol, the level of factor X activation by the factor IXa-phospholipid complex increased 3-fold, and the level of chromogenic substrate cleavage by factor IXa increased more than 50-fold. ISIS 2302 demonstrated partial inhibition of factor X activation by the factor IXa-phospholipid complex, and chromogenic substrate cleavage by factor IXa, only in the presence of ethylene glycol. Like the intact enzyme complex, ISIS 2302 demonstrated hyperbolic, mixed-type inhibition of chromogenic substrate cleavage by factor IXa (K(I) = 88 nM). Equilibrium binding studies with fluorescein-labeled ISIS 2302 demonstrated a similar affinity (K(D) = 92 nM) for the PS ODN-factor IX interaction. These results suggest that PS ODNs bind to an exosite on factor IXa, modulating catalytic activity of the intrinsic tenase complex.

Prothrombin protects factor Xa in the prothrombinase complex from inhibition by the heparin-antithrombin complex

Heparin is a commonly used anticoagulant drug. It functions primarily by accelerating the antithrombin inhibition of coagulation proteinases, among which factor Xa and thrombin are believed to be the most important targets. There are conflicting results as to whether anticoagulant heparins can catalyze the antithrombin inhibition of factor Xa in the prothrombinase complex (factor Va, negatively charged membrane surfaces, and calcium ion), which is the physiologically relevant form of the proteinase responsible for the activation of prothrombin to thrombin during the blood coagulation process. In this study, a novel assay system was developed to compare the catalytic effect of different molecular-weight heparins in the antithrombin inhibition of factor Xa, either in free form or assembled into the prothrombinase complex during the process of prothrombin activation. This assay takes advantage of the unique property of a recombinant mutant antithrombin, which, similar to the wild-type antithrombin, rapidly inhibits factor Xa, but not thrombin, in the presence of heparin. A direct prothrombinase inhibition assay, monitoring thrombin generation under near physiological concentrations of prothrombin and antithrombin in the presence of therapeutic doses of low- and high-molecular-weight heparins, indicates that factor Xa in the prothrombinase complex is protected from inhibition by antithrombin more than 1000 times, independent of the molecular size of heparin.

Hypersulfated low molecular weight heparin with reduced affinity for antithrombin acts as an anticoagulant by inhibiting intrinsic tenase and prothrombinase

In buffer systems, heparin and low molecular weight heparin (LMWH) directly inhibit the intrinsic factor X-activating complex (intrinsic tenase) but have no effect on the prothrombin-activating complex (prothrombinase). Although chemical modification of LMWH, to lower its affinity for antithrombin (LA-LMWH) has no effect on its ability to inhibit intrinsic tenase, N-desulfation of LMWH reduces its activity 12-fold. To further explore the role of sulfation, hypersulfated LA-LMWH was synthesized (sLA-LMWH). sLA-LMWH is not only a 32-fold more potent inhibitor of intrinsic tenase than LA-LMWH; it also acquires prothrombinase inhibitory activity. A direct correlation between the extent of sulfation of LA-LMWH and its inhibitory activity against intrinsic tenase and prothrombinase is observed. In plasma-based assays of tenase and prothrombinase, sLA-LMWH produces similar prolongation of clotting times in plasma depleted of antithrombin and/or heparin cofactor II as it does in control plasma. In contrast, heparin has no effect in antithrombin-depleted plasma. When the effect of sLA-LMWH on various components of tenase and prothrombinase was examined, its inhibitory activity was found to be cofactor-dependent (factors Va and VIIIa) and phospholipid-independent. These studies reveal that sLA-LMWH acts as a potent antithrombin-independent inhibitor of coagulation by attenuating intrinsic tenase and prothrombinase.

Calcium enhances heparin catalysis of the antithrombin-factor Xa reaction by promoting the assembly of an intermediate heparin-antithrombin-factor Xa bridging complex. Demonstration by rapid kinetics studies

Heparin catalyzes the inhibition of factor Xa by antithrombin mainly through an allosteric activation of the serpin inhibitor, but an alternative heparin bridging mechanism has been suggested to enhance the catalysis in the presence of physiologic calcium levels due to calcium interactions with the Gla domain exposing a heparin binding exosite in factor Xa. To provide direct evidence for this bridging mechanism, we studied the heparin-catalyzed reaction of antithrombin with factor Xa, Gla-domainless factor Xa (GDFXa), and a heparin binding exosite mutant of GDFXa in the absence and presence of calcium using rapid kinetic methods. The pseudo-first-order rate constant for factor Xa inhibition by antithrombin complexed with a long-chain approximately 70-saccharide heparin showed a saturable dependence on inhibitor concentration in the presence but not in the absence of 2.5 mM Ca(2+), indicating the formation of an intermediate heparin-serpin-proteinase encounter complex with a dissociation constant of approximately 90 nM prior to formation of the stable serpin-proteinase complex with a rate constant of approximately 20 s(-1). Similar saturation kinetics were observed for the inhibition of GDFXa by the antithrombin-heparin complex, except that Ca(2+) was not required for the effect. By contrast, no Ca(2+)-dependent saturation of the inhibition rate constant was detectable over the same range of inhibitor concentrations for reactions of either a short-chain approximately 26-saccharide high-affinity heparin-antithrombin complex with factor Xa or the long-chain heparin-antithrombin complex with the heparin binding exosite mutant, GDFXa R240A. These findings suggest that binding of full-length heparin chains to an exosite of factor Xa in the presence of Ca(2+) produces a chain-length-dependent lowering of the dissociation constant for assembly of the intermediate heparin-antithrombin-factor Xa encounter complex, resulting in a several 100-fold rate enhancement by a heparin bridging mechanism.