The tissue factor/factor VIIa/factor Xa complex: a model built by docking and site-directed mutagenesis

Factor X is activated to factor Xa (fXa) in the extrinsic coagulation pathway by the tissue factor (TF)/factor VIIa (fVIIa) complex. Upon activation, the fXa molecule remains associated with the TF/fVIIa complex, and this ternary complex is known to activate protease-activated receptors (PARs) 1 and 2. Activation of fVII in the TF complex by fXa is also seen at physiologic concentrations. The ternary complexes TF/fVII/fXa, TF/fVIIa/fX, and TF/fVIIa/fXa are therefore all physiologically relevant and of interest as targets for inhibition of both coagulation and cell-signaling pathways that are important in cardiovascular disease and inflammation. We therefore present a model of the TF/fVIIa/fXa complex, built with the use of the available structures of the TF/fVIIa complex and fXa by protein-protein docking calculations with the program Surfdock. The fXa model has an extended conformation, similar to that of fVIIa in the TF/fVIIa complex, with extensive interactions with TF and the protease domain of fVIIa. All four domains of fXa are involved in the interaction. The gamma-carboxyglutamate (Gla) and epithelial growth factor (EGF1 and EGF2) domains of fVIIa are not significantly involved in the interaction. Docking of the Gla domain of fXa to TF/fVIIa has been reported previously. The docking results identify potential interface residues, allowing rational selection of target residues for site-directed mutagenesis. This combination of docking and mutagenesis confirms that residues Glu51 and Asn57 in the EGF1 domain, Asp92 and Asp95 in the EGF2 domain, and Asp 185a, Lys 186, and Lys134 in the protease domain of factor Xa are involved in the interaction with TF/fVIIa. Other fX protease domain residues predicted to be involved in the interaction come from the 160s loop and the N-terminus of the fX protease domain, which is oriented in such a way that activation of both fVII by fXa, and the reciprocal fX activation by fVIIa, is possible.     

The cofactor function of the N-terminal domain of tissue factor

Tissue factor (TF) is an integral membrane protein cofactor for factor VIIa (fVIIa) that initiates the blood coagulation cascade during vascular injury. TF has two fibrinonectin type III-like domains, both of which make extensive interactions with both the light and heavy chains of fVIIa. In addition to interaction with fVIIa, the membrane proximal C-terminal domain of TF is also known to bind the natural substrates factors IX and X, thereby facilitating their assembly and recognition by fVIIa in the activation complex. Both fVIIa and TF are elongated proteins, and their complex appears to be positioned nearly perpendicular to the membrane surface. It is possible that, similar to fVIIa, the N-terminal domain of TF also contacts the natural substrates. To investigate this possibility, we substituted all 23 basic and acidic residues of the N-terminal domain of TF with Ala or Asn and expressed the mutants as soluble TF(2-219) in a novel expression/purification vector system in the periplasmic space of bacteria. Following purification to homogeneity, the cofactor properties of mutants in promoting the amidolytic and proteolytic activity of fVIIa were analyzed in appropriate kinetic assays. The amidolytic activity assays indicated that several charged residues spatially clustered at the junction of the N- and C-terminal domains of TF are required for high affinity interaction with fVIIa. On the other hand, the proteolytic activity assays revealed that none of the residues under study may be an interactive site for either factor IX or factor X. However, it was discovered the Arg(74) mutant of TF was defective in enhancing both the amidolytic and proteolytic activity of fVIIa, suggesting that this residue may be required for the allosteric activation of the protease.     

Role of zymogen and activated factor X as scaffolds for the inhibition of the blood coagulation factor VIIa-tissue factor complex by recombinant nematode anticoagulant protein c2

Recombinant nematode anticoagulant protein c2 (rNAPc2) is a potent, factor Xa (fXa)-dependent small protein inhibitor of factor VIIa-tissue factor (fVIIa.TF), which binds to a site on fXa that is distinct from the catalytic center (exo-site). In the present study, the role of other fX derivatives in presenting rNAPc2 to fVIIa.TF is investigated. Catalytically active and active site blocked fXa, as well as a plasma-derived and an activation-resistant mutant of zymogen fX bound to rNAPc2 with comparable affinities (K(D) = 1-10 nm), and similarly supported the inhibition of fVIIa.TF (K(i)* = approximately 10 pm). The roles of phospholipid membrane composition in the inhibition of fVIIa.TF by rNAPc2 were investigated using TF that was either detergent-solubilized (TF(S)), or reconstituted into membranes, containing phosphatidylcholine (TF(PC)) or a mixture of phosphatidylcholine and phosphatidylserine (TF(PCPS)). In the absence of the fX derivative, inhibition of fVIIa.TF was similar for all three conditions (K(i) approximately 1 microm), whereas the addition of the fX derivative increased the respective inhibition by 35-, 150-, or 100,000-fold for TF(S), TF(PC), and TF(PCPS). The removal of the gamma-carboxyglutamic acid-containing domain from the fX derivative did not affect the binding to rNAPc2, but abolished the effect of factor Xa as a scaffold for the inhibition of fVIIa.TF by rNAPc2. The overall anticoagulant potency of rNAPc2, therefore, results from a coordinated recognition of an exo-site on fX/fXa and of the active site of fVIIa, both of which are properly positioned in the ternary fVIIa.TF.fX(a) complex assembled on an appropriate phospholipid surface.     

Structural changes in factor VIIa induced by Ca2+ and tissue factor studied using circular dichroism spectroscopy.

Factor VIIa (fVIIa) is composed of four discrete domains, a gamma-carboxyglutamic acid (Gla)-containing domain, two epidermal growth factor (EGF)-like domains, and a serine protease domain, all of which appear to be involved, to different extents, in an optimal interaction with tissue factor (TF). All except the second EGF-like domain contain at least one Ca2+ binding site and many properties of fVIIa, e.g., TF and phospholipid binding and amidolytic activity, are Ca(2+)-dependent. A CD study was performed to characterize and locate the conformational changes in fVIIa induced by Ca2+ and TF binding. In addition to intact fVIIa, derivatives lacking the Gla domain or the protease domain were used. Assignment of the Ca(2+)-induced changes in the far-UV region of the fVIIa spectrum to the Gla domain could be made by comparing the CD spectra obtained with these fVIIa derivatives. The changes primarily appeared to reflect a Ca(2+)-induced ordering of alpha-helices existing in the apo state of fVIIa. This was corroborated by models of the apo and Ca2+ forms of fVIIa, obtained as difference spectra between fVIIa derivatives, were very similar to those of isolated Gla peptides from other vitamin K-dependent plasma proteins. The near-UV CD spectrum of fVIIa was dominated by aromatic residues residing in the protease domain and specific bands affected by Ca2+ were indicative of tertiary structural alterations. The formation of a fVIIa:TF complex led to secondary structural changes that appeared to be restricted to the catalytic domain, possibly shedding light on the mechanism by which TF induces an enhancement of fVIIa catalytic activity.     

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.     

Definition of a factor Va binding site in factor Xa

We reported previously that residue 347 in activated fX (fXa) contributes to binding of the cofactor, factor Va (fVa) (Rudolph, A. E., Porche-Sorbet, R. and Miletich, J. P. (2000) Biochemistry 39, 2861-2867). Four additional residues that participate in fVa binding have now been identified by mutagenesis. All five resulting fX species, fX(R306A), fX(E310N), fX(R347N), fX(K351A), and fX(K414A), are activated and inhibited normally. However, the rate of inhibition by antithrombin III in the presence of submaximal concentrations of heparin is reduced for all the enzymes. In the absence of fVa, all of the enzymes bind and activate prothrombin similarly except fXa(E310N), which has a reduced apparent affinity ( approximately 3-fold) for prothrombin compared with wild type fXa (fXa(WT)). In the absence of phospholipid, fVa enhances the catalytic activity of fXa(WT) significantly, but the response of the variant enzymes was greatly diminished. On addition of 100 nm PC:PS (3:1) vesicles, fVa enhanced fXa(WT), fXa(R306A), and fXa(E310N) similarly, whereas fXa(R347N), fXa(K351A), and fXa(K414A) demonstrated near-normal catalytic activity but reduced apparent affinity for fVa under these conditions. All enzymes function similarly to fXa(WT) on activated platelets, which provide saturating fVa on an ideal surface. Loss of binding affinity for fVa as a result of the substitutions in residues Arg-347, Lys-351, and Lys-414 was verified by a competition binding assay. Thus, Arg-347, Lys-351, and Lys-414 are likely part of a core fVa binding site, whereas Arg-306 and Glu-310 serve a less critical role.     

The tissue factor region that interacts with substrates factor IX and Factor X

The enzymatic activity of coagulation factor VIIa is controlled by its cellular cofactor tissue factor (TF). TF binds factor VIIa with high affinity and, in addition, participates in substrate interaction through its C-terminal fibronectin type III domain. We analyzed surface-exposed residues in the C-terminal TF domain to more fully determine the area on TF important for substrate activation. Soluble TF (sTF) mutants were expressed in E. coli, and their ability to support factor VIIa-dependent substrate activation was measured in the presence of phospholipid vesicles or SW-13 cell membranes. The results showed that factor IX and factor X interacted with the same TF region located proximal to the putative phospholipid surface. According to the degree of activity loss of the sTF mutants, this TF region can be divided into a main region (residues Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, Tyr185) forming a solvent-exposed patch of 488 A(2) and an extended region which comprises an additional 7-8 residues, including the distally positioned Asn199, Arg200, and Asp204. Some of the identified TF residues, such as Trp158 and those within the loop Lys159-Lys165, are near the factor VIIa gamma-carboxyglutamic acid (Gla) domain, suggesting that the factor VIIa Gla-domain may also participate in substrate interaction. Moreover, the surface identified as important for substrate interaction carries a net positive charge, suggesting that charge interactions may significantly contribute to TF-substrate binding. The calculated surface-exposed area of this substrate interaction region is about 1100 A(2), which is approximately half the size of the TF area that is in contact with factor VIIa. Therefore, a substantial portion of the TF surface (3000 A(2)) is engaged in protein-protein interactions during substrate catalysis.     

Probing the interface between factor Xa and tissue factor in the quaternary complex tissue factor-factor VIIa-factor Xa-tissue factor pathway inhibitor.

Blood coagulation is triggered by the formation of a complex between factor VIIa (FVIIa) and its cofactor, tissue factor (TF). TF-FVIIa is inhibited by tissue factor pathway inhibitor (TFPI) in two steps: first TFPI is bound to the active site of factor Xa (FXa), and subsequently FXa-TFPI exerts feedback inhibition of TF-FVIIa. The FXa-dependent inhibition of TF-FVIIa activity by TFPI leads to formation of the quaternary complex TF-FVIIa-FXa-TFPI. We used site-directed fluorescence probing to map part of the region of soluble TF (sTF) that interacts with FXa in sTF-FVIIa-FXa-TFPI. We found that the C-terminal region of sTF, including positions 163, 166, 200 and 201, is involved in binding to FXa in the complex, and FXa, most likely via its Gla domain, is also in contact with the Gla domain of FVIIa in this part of the binding region. Furthermore, a region that includes the N-terminal part of the TF2 domain and the C-terminal part of the TF1 domain, i.e. the residues 104 and 197, participates in the interaction with FXa in the quaternary complex. Moreover, comparisons of the interaction areas between sTF and FX(a) in the quaternary complex sTF-FVIIa-FXa-TFPI and in the ternary complexes sTF-FVII-FXa or sTF-FVIIa-FX demonstrated large similarities.     

Substitution of the Gla domain in factor X with that of protein C impairs its interaction with factor VIIa/tissue factor: lack of comparable effect by similar substitution in factor IX

We previously reported that the first epidermal growth factor-like (EGF1) domain in factor X (FX) or factor IX (FIX) plays an important role in the factor VIIa/tissue factor (FVIIa/TF)-induced coagulation. To assess the role of gamma-carboxyglutamic acid (Gla) domains of FX and FIX in FVIIa/TF induced coagulation, we studied four new and two previously described replacement mutants: FX(PCGla) and FIX(PCGla) (Gla domain replaced with that of protein C), FX(PCEGF1) and FIX(PCEGF1) (EGF1 domain replaced with that of protein C), as well as FX(PCGla/EGF1) and FIX(PCGla/EGF1) (both Gla and EGF1 domains replaced with those of protein C). FVIIa/TF activation of each FX mutant and the corresponding reciprocal activation of FVII/TF by each FXa mutant were impaired. In contrast, FVIIa/TF activation of FIX(PCGla) was minimally affected, and the reciprocal activation of FVII/TF by FIXa(PCGla) was normal; however, both reactions were impaired for the FIX(PCEGF1) and FIX(PCGla/EGF1) mutants. Predictably, FXIa activation of FIX(PCEGF1) was normal, whereas it was impaired for the FIX(PCGla) and FIX(PCGla/EGF1) mutants. Molecular models reveal that alternate interactions exist for the Gla domain of protein C such that it is comparable with FIX but not FX in its binding to FVIIa/TF. Further, additional interactions exist for the EGF1 domain of FX, which are not possible for FIX. Importantly, a seven-residue insertion in the EGF1 domain of protein C prevents its interaction with FVIIa/TF. Cumulatively, our data provide a molecular framework demonstrating that the Gla and EGF1 domains of FX interact more strongly with FVIIa/TF than the corresponding domains in FIX.     

The length of the linker between the epidermal growth factor‐like domains in factor VIIa is critical for a productive interaction with tissue factor

Formation of the factor VIIa (FVIIa)‐tissue factor (TF) complex triggers the blood coagulation cascade. Using a structure‐based rationale, we investigated how the length of the linker region between the two epidermal growth factor (EGF)‐like domains in FVIIa influences TF binding and the allosteric activity enhancement, as well as the interplay between the γ‐carboxyglutamic acid (Gla)‐containing and protease domains. Removal of two residues from the native linker was compatible with normal cofactor binding and accompanying stimulation of the enzymatic activity, as was extension by two (Gly‐Ser) residues. In sharp contrast, truncation by three or four residues abolished the TF‐mediated stabilization of the active conformation of FVIIa and abrogated TF‐induced activity enhancement. In addition, FVIIa variants with short linkers associated 80‐fold slower with soluble TF (sTF) as compared with wild‐type FVIIa, resulting in a corresponding increase in the equilibrium dissociation constant. Molecular modeling suggested that the shortest FVIIa variants would have to be forced into a tense and energetically unfavorable conformation in order to be able to interact productively with TF, explaining our experimental observations. We also found a correlation between linker length and the residual intrinsic enzymatic activity of Ca²⁺‐free FVIIa; stepwise truncation resulting in gradually higher activity with des(83–86)‐FVIIa reaching the level of Gla‐domainless FVIIa. The linker appears to determine the average distance between the negatively charged Gla domain and a structural element in the protease domain, presumably of opposite charge, and proximity has a negative impact on apo‐FVIIa activity.     

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.     

Similar molecular interactions of factor VII and factor VIIa with the tissue factor region that allosterically regulates enzyme activity

Tissue factor (TF) binds the zymogen (VII) and activated (VIIa) forms of coagulation factor VII with high affinity. The structure determined for the sTF-VIIa complex [Banner, D. W., et al. (1996) Nature 380, 41-46] shows that all four domains of VIIa (Gla, EGF-1, EGF-2, and protease) are in contact with TF. Although a structure is not available for the TF-VII complex, the structure determined for free VII [Eigenbrot, C., et al. (2001) Structure 9, 675-682] suggests a significant conformational change for the zymogen to enzyme transition. In particular, the region of the protease domain that must contact TF has a conformation that is altered from that of VIIa, suggesting that the VII protease domain interacts with TF in a manner different from that of VIIa. To test this hypothesis, a panel of 12 single-site sTF mutants, having substitutions of residues observed to contact the proteolytic domain of VIIa, have been evaluated for binding to both zymogen VII and VIIa. Affinities were determined by surface plasmon resonance measurements using a noninterfering anti-TF monoclonal antibody to capture TF on the sensor chip surface. Dissociation constants (K(D)) measured for binding to wild-type sTF are 7.5 +/- 2.4 nM for VII and 5.1 +/- 2.3 nM for VIIa. All of the sTF mutants except S39A and E95A exhibited a significant decrease (>2-fold) in affinity for VIIa. The changes in affinity measured for VII or VIIa binding with substitution in sTF were comparable in magnitude. We conclude that the proteolytic domain of both VII and VIIa interacts with this region of sTF in a nearly identical fashion. Therefore, zymogen VII can readily adopt a VIIa-like conformation required for binding to TF.     

Ixolaris binding to factor X reveals a precursor state of factor Xa heparin-binding exosite

Ixolaris is a two-Kunitz tick salivary gland tissue factor pathway inhibitor (TFPI). In contrast to human TFPI, Ixolaris specifically binds to factor Xa (FXa) heparin-binding exosite (HBE). In addition, Ixolaris interacts with zymogen FX. In the present work we characterized the interaction of Ixolaris with human FX quantitatively, and identified a precursor state of the heparin-binding exosite (proexosite, HBPE) as the Ixolaris-binding site on the zymogen. Gel-filtration chromatography demonstrated 1:1 complex formation between fluorescein-labeled Ixolaris and FX. Isothermal titration calorimetry confirmed that the binding of Ixolaris to FX occurs at stoichiometric concentrations in a reaction which is characteristically exothermic, with a favorable enthalpy (DeltaH) of -10.78 kcal/mol. ELISA and plasmon resonance experiments also indicate that Ixolaris binds to plasma FX and FXa, or to recombinant Gla domain-containing FX/FXa with comparable affinities ( approximately 1 nM). Using a series of mutants on the HBPE, we identified the most important amino acids involved in zymogen/Ixolaris interaction-Arg-93 > Arg-165 > or = Lys-169 > Lys-236 > Arg-125-which was identical to that observed for FXa/Ixolaris interaction. Remarkably, Ixolaris strongly inhibited FX activation by factor IXa in the presence but not in the absence of factor VIIIa, suggesting a specific interference in the cofactor activity. Further, solid phase assays demonstrated that Ixolaris inhibits FX interaction with immobilized FVIIIa. Altogether, Ixolaris is the first inhibitor characterized to date that specifically binds to FX HBPE. Ixolaris may be a useful tool to study the physiological role of the FX HBPE and to evaluate this domain as a target for anticoagulant drugs.     

Sequential coagulation factor VIIa domain binding to tissue factor

Vessel wall tissue factor (TF) is exposed to blood upon vascular damage which enables association with factor VIIa (FVIIa). This leads to initiation of the blood coagulation cascade through localization and allosteric induction of FVIIa procoagulant activity. To examine the docking pathway of the FVIIa-TF complex, various residues in the extracellular part of TF (sTF) that are known to interact with FVIIa were replaced with cysteines labelled with a fluorescent probe. By using stopped-flow fluorescence kinetic measurements in combination with surface plasmon resonance analysis, we studied the association of the resulting sTF variants with FVIIa. We found the docking trajectory to be a sequence of events in which the protease domain of FVIIa initiates contact with sTF. Thereafter, the two proteins are tethered via the first epidermal growth factor-like and finally the γ-carboxyglutamic acid (Gla) domain. The two labelled sTF residues interacting with the protease domain of FVIIa bind or become eventually ordered at different rates, revealing kinetic details pertinent to the allosteric activation of FVIIa by sTF. Moreover, when the Gla domain of FVIIa is removed the difference in the rate of association for the remaining domains is much more pronounced.     

Role of the Gla and first epidermal growth factor-like domains of factor X in the prothrombinase and tissue factor-factor VIIa complexes

Factor X (FX) has high structure homology with other proteins of blood coagulation such as factor IX (FIX) and factor VII (FVII). These proteins present at their amino-terminal extremity a gamma-carboxyglutamic acid containing domain (Gla domain), followed by two epidermal growth factor-like (EGF1 and EGF2) domains, an activation peptide, and a serine protease domain. After vascular damage, the tissue factor-FVIIa (TF-FVIIa) complex activates both FX and FIX. FXa interacts stoichiometrically with tissue pathway inhibitor (TFPI), regulating TF-FVIIa activity by forming the TF-FVIIa-TFPI-FXa quaternary complex. Conversely, FXa boosts coagulation by its association with its cofactor, factor Va (FVa). To investigate the contribution of the Gla and EGF1 domains of FX in these complexes, FX chimeras were produced in which FIX Gla and EGF1 domains substituted the corresponding domains of FX. The affinity of the two chimeras, FX/FIX(Gla) and FX/FIX(EGF1), for the TF-FVIIa complex was markedly reduced compared with that of wild-type-FX (wt-FX) independently of the presence of phospholipids. Furthermore, the association rate constants of preformed FX/FIX(Gla)-TFPI and FX/FIX(EGF1)-TFPI complexes with TF-FVIIa were, respectively, 10- and 5-fold slower than that of wt-FXa-TFPI complex. Finally, the apparent affinity of FVa was 2-fold higher for the chimeras than for wt-FX in the presence of phospholipids and equal in their absence. These data demonstrate that FX Gla and EGF1 domains contain residues, which interact with TF-FVIIa exosites contributing to the formation of the TF-FVIIa-FX and TF-FVIIa-TFPI-FXa complexes. On the opposite, FXa Gla and EGF1 domains are not directly involved in FVa binding.     

Activation and active site occupation alter conformation in the region of the first epidermal growth factor-like domain of human factor VII

The first epidermal growth factor-like domain (EGF-1) of factor VII (FVII) provides the region of greatest contact during the interaction of FVIIa with tissue factor. To understand this interaction better, the conformation-sensitive FVII EGF-1-specific monoclonal antibody (mAb) 231-7 was used to investigate the conformational effects occurring in this region upon both FVII activation and active site occupation. The binding affinity of mAb 231-7 was approximately 3-fold greater for the zymogen state than for the active state; a result affected by the presence of both calcium and the adjacent Gla domain. Once activated, active site inhibition of FVIIa with a variety of chloromethyl ketone inhibitors resulted in a 10-fold range of affinities of FVIIai molecules to mAb 231-7. Gla domain removal eliminated this variation in affinity, suggesting the involvement of a Gla/EGF-1 interaction in this conformational effect. In addition, the binding of mAb 231-7 to FVIIa EGF-1 stimulated the amidolytic activity of free FVIIa. Taken together, these results imply an allosteric interaction between the FVIIa active site and the EGF-1 domain that is sensitive to variation in active site occupant structure. Thus, these present studies indicate that the conformational change associated with FVII activation and active site occupation involves the EGF-1 domain and suggest potential functional consequences of these changes.     

Identification of exosite residues of factor Xa involved in recognition of PAR-2 on endothelial cells

Recent results have indicated that factor Xa (FXa) cleaves protease-activated receptor 2 (PAR-2) to elicit protective intracellular signaling responses in endothelial cells. In this study, we investigated the molecular determinants of the specificity of FXa interaction with PAR-2 by monitoring the cleavage of PAR-2 by FXa in endothelial cells transiently transfected with a PAR-2 cleavage reporter construct in which the extracellular domain of the receptor was fused to cDNA encoding for alkaline phosphatase. Comparison of the cleavage efficiency of PAR-2 by a series of FXa mutants containing mutations in different surface loops indicated that the acidic residues of 39-loop (Glu-36, Glu-37, and Glu-39) and the basic residues of 60-loop (Lys-62 and Arg-63), 148-loop (Arg-143, Arg-150, and Arg-154), and 162-helix (Arg-165 and Lys-169) contribute to the specificity of receptor recognition by FXa on endothelial cells. This was evidenced by significantly reduced activity of mutants toward PAR-2 expressed on transfected cells. The extent of loss in the PAR-2 cleavage activity of FXa mutants correlated with the extent of loss in their PAR-2-dependent intracellular signaling activity. Further characterization of FXa mutants indicated that, with the exception of basic residues of 162-helix, which play a role in the recognition specificity of the prothrombinase complex, none of the surface loop residues under study makes a significant contribution to the activity of FXa in the prothrombinase complex. These results provide new insight into mechanisms through which FXa specifically interacts with its macromolecular substrates in the clotting and signaling pathways.     

Crystal Structure of Active Site-Inhibited Human Coagulation Factor VIIa (des-Gla)

Factor VIIa (FVIIa) is a crucial haemostatic protease consisting of four distinct domains termed the Gla, epidermal growth factor-1 (EGF-1), EGF-2, and protease domains (from N- to C-terminus). The crystal structure of human FVIIa inhibited at the active site with 1, 5-dansyl-Glu-Gly-Arg-chloromethyl ketone and lacking the Gla domain has been solved to a resolution of 2.28 A. The EGF-2 and protease domains were well resolved, whereas no electron density for the EGF-1 domain was observed, suggesting a flexible arrangement or disorder within the crystal. Superposition of the protease domain of the present structure with that previously resolved in the tissue factor (TF)/FVIIai complex revealed that although overall the domain structures are similar, the EGF-2 domain is rotated by 7.5 degrees relative to the protease domain on binding TF. A single cleavage in the protease domain was found, between Arg315 and Lys316 (chymotrypsin numbering 170C-170D) in a FVII-specific insertion loop: this cleavage appeared to be essential for crystallisation. Insertion of the heavy chain N-terminal Ile153 is essentially identical in the two structures, as is the geometry of the active site residues and the inhibitor C-terminal arginine residue. Some differences are seen in the cleaved loop, but changes in TF-contact residues are generally minor. This structure supports the hypothesis that TF binding enables spatial domain arrangements in the flexible FVIIa molecule necessary for procoagulant function and furthermore that active site occupancy induces FVIIa active conformation via N-terminal insertion.     

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.     

Tissue factor residues 157-167 are required for efficient proteolytic activation of factor X and factor VII.

The cell surface receptor tissue factor (TF) initiates coagulation by supporting the proteolytic activation of factors X and IX as well as VII to active serine proteases. Architectural similarity of TF to the cytokine receptor family suggests a strand-loop-strand structure for TF residues 151-174. Site-directed Ala exchanges in the predicted surface loop demonstrated that residues Tyr157, Lys159, Ser163, Gly164, Lys165, and Lys166 are important for function. Addition of side chain atoms at the Ser162 position decreased function, whereas the Ala exchange was tolerated. The dysfunctional mutants bound VII with high affinity and fully supported the catalysis of small peptidyl substrates by the mutant TF.VIIa complex. Lys159-->Ala substitution was compatible with efficient activation of factor X, whereas the Try157-->Ala exchange and mutations in the carboxyl aspect of the predicted loop resulted in diminished activation of factor X. The specific plasma procoagulant activity of all functionally deficient mutants increased 7- to 200-fold upon the supplementation of VIIa suggesting that TF residues 157-167 also provide important interactions that accelerate the activation of VII to VIIa. These data are consistent with assignment of the TF 157-167 region as contributing to protein substrate recognition and cleavage by the TF.VIIa complex.