Cofactor residues lysine 165 and 166 are critical for protein substrate recognition by the tissue factor-factor VIIa protease complex.

High affinity binding of factor VIIa (VIIa) to its cellular receptor tissue factor (TF), as well as association of factor X with phospholipid are required for optimal assembly of the extrinsic activation complex. In addition to the interactions of substrate with phospholipid and enzyme, we here provide evidence that cofactor residues Lys-165 and Lys-166 specifically contribute to the recognition of macromolecular substrate. Ala for Lys replacement in TFA165A166 was compatible with high affinity binding of VIIa when analyzed on cell surfaces as well as in the absence of phospholipid. Dissociation of TFA165A166.VIIa did not occur with a faster rate compared to TF.VIIa, further supporting unaltered VIIa binding function of TFA165A166. Cleavage of chromogenic peptidyl substrate by TFA165A166.VIIa complexes was not diminished, demonstrating that TFA165A166 supported enhancement of catalytic function of the VIIa protease domain. In contrast, factor X activation was reduced in the presence and absence of phospholipid. Further, TFA165A166 effectively competed with wild-type TF in the cleavage of factor X at limited VIIa concentrations. Selective reduction in macromolecular substrate hydrolysis combined with normal VIIa binding by TFA165A166 indicates that the cofactor TF does contribute, either directly or indirectly via specific interactions with VIIa, to factor X recognition.     

Importance of factor VIIa Gla-domain residue Arg-36 for recognition of the macromolecular substrate factor X Gla-domain

Macromolecular substrate docking with coagulation enzyme-cofactor complexes involves multiple contacts distant from the enzyme's catalytic cleft. Here we characterize the binding of the Gla-domain of macromolecular substrate coagulation factor X to the complex of tissue factor (TF) and VIIa. Site-directed mutagenesis of charged residue side chains in the VIIa Gla-domain identified Arg-36 as being important for macromolecular substrate docking. Ala substitution for Arg-36 resulted in an increased KM and a decreased rate of X activation. X with a truncated Gla-domain was activated by mutant and wild-type VIIa at indistinguishable rates, demonstrating that Arg-36 interactions require a properly folded Gla-domain of the macromolecular substrate. VIIa Arg-36 was also required for effective docking of the X Gla-domain in the absence of phospholipid, demonstrating that the Gla-domain of VIIa participates in protein-protein interactions with X. In the absence of TF, the mutant VIIa had essentially normal function, indicating that the cofactor positions VIIa's Gla-domain for optimal macromolecular substrate docking. Computational docking suggests multiple charge complementary contacts of the X Gla-domain with TF.VIIa. A prominent interaction is made by the functionally important X residue Gla-14 with the center of the extended docking site created by residues in the carboxyl module of TF and the contiguous VIIa Gla-domain. These data demonstrate the functional importance of interactions of the Gla-domains of enzyme and substrate, and begin to elucidate the molecular details of the ternary TF.VIIa.X complex.     

Macromolecular substrate affinity for the tissue factor-factor VIIa complex is independent of scissile bond docking.

The upstream coagulation enzymes are homologous trypsin-like serine proteases that typically function in enzyme-cofactor complexes, exemplified by coagulation factor VIIa (VIIa), which is allosterically activated upon binding to its cell surface receptor tissue factor (TF). TF cooperates with VIIa to create a bimolecular recognition surface that serves as an exosite for factor X binding. This study analyzes to what extent scissile bond docking to the catalytic cleft contributes to macromolecular substrate affinity. Mutation of the P1 Arg residue in factor X to Gln prevented activation by the TF.VIIa complex but did not reduce macromolecular substrate affinity for TF.VIIa. Similarly, mutations of the S and S' subsites in the catalytic cleft of the enzyme VIIa failed to reduce affinity for factor X, although the affinity for small chromogenic substrates and the efficiency of factor X scissile bond cleavage were reduced. Thus, docking of the activation peptide bond to the catalytic cleft of this enzyme-cofactor complex does not significantly contribute to affinity for macromolecular substrate. Rather, it appears that the creation of an extended macromolecular substrate recognition surface involving enzyme and cofactor is utilized to generate substrate specificity between the highly homologous, regulatory proteases of the coagulation cascade.     

Exosite interactions determine the affinity of factor X for the extrinsic Xase complex

The initiation of coagulation results from the activation of factor X by an enzyme complex (Xase) composed of the trypsin-like serine proteinase, factor VIIa, bound to tissue factor (TF) on phospholipid membranes. We have investigated the basis for the protein substrate specificity of Xase using TF reconstituted into vesicles of phosphatidylcholine, phosphatidylserine, or pure phosphatidylcholine. We show that occupation of the active site of VIIa within Xase by a reversible inhibitor or an alternate peptidyl substrate is sufficient to exclude substrate interactions at the active site but does not alter the affinity of Xase for factor X. This is evident as classical competitive inhibition of peptidyl substrate cleavage but as classical noncompetitive inhibition of factor X activation by active site-directed ligands. This implies that the productive recognition of factor X by Xase arises from a multistep reaction requiring an initial interaction at sites on the enzyme complex distinct from the active site (exosites), followed by active site interactions and bond cleavage. Exosite interactions determine protein substrate affinity, whereas the second binding step influences the maximum catalytic rate for the reaction. We also show that competitive inhibition can be achieved by interfering with exosite binding using factor X derivatives that are expected to have limited or abrogated interactions with the active site of VIIa within Xase. Thus, substrate interactions at exosites, sites removed from the active site of VIIa within the enzyme complex, determine affinity and binding specificity in the productive recognition of factor X by the VIIa-TF complex. This may represent a prevalent strategy through which distinctive protein substrate specificities are achieved by the homologous enzymes of coagulation.     

Characterization of factor VII association with tissue factor in solution. High and low affinity calcium binding sites in factor VII contribute to functionally distinct interactions

Protein-phospholipid as well as protein-protein interactions may be critical for tight binding of the serine protease factor VIIa (VIIa) to its receptor cofactor tissue factor (TF). To elucidate the role of protein-protein interactions, we analyzed the interaction of VII/VIIa with TF in the absence of phospholipid. Binding of VII occurred with similar affinity to solubilized and phospholipid-reconstituted TF. Lack of the gamma-carboxyglutamic acid (Gla)-domain (des-(1-38)-VIIa) resulted in a 10- to 30-fold increase of the Kd for the interaction, as did blocking the Gla-domain by Fab fragments of a specific monoclonal antibody. These results suggest that the VII Gla-domain can participate in protein-protein interaction with the TF molecule per se rather than only in interactions with the charged phospholipid surface. Gla-domain-independent, low affinity binding of VII to TF required micromolar Ca2+, indicating involvement of high affinity calcium ion binding sites suggested to be localized in VII rather than TF. Interference with Gla-domain-dependent interactions with TF did not alter the TF. VIIa-dependent cleavage of a small peptidyl substrate, whereas the proteolytic activation of the protein substrate factor X was markedly decreased, suggesting that the VIIa Gla-domain not only participates in the formation of a more stable TF. VIIa complex but contributes to extended substrate recognition.     

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.     

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.     

Selective attenuation of the extrinsic limb of the tissue factor-driven coagulation protease cascade by occupancy of a novel peptidyl docking site on tissue factor

Tissue factor (TF), the receptor and cofactor for factor VIIa (VIIa) for cellular initiation of the coagulation protease cascade, drives thrombogenesis, inflammation, tumor cell metastasis, and the lethality of severe sepsis. To identify TF surface loci that can selectively inhibit substrate zymogen association and activation, TF(1-218), the extracellular domain, was used as the target for the phage display search. This resulted in selection of 59 clones from a phage gpVIII surface protein-expressed library of constrained combinatorial peptides. Of these, one encoding the peptide Glu-Cys-Leu-Arg-Ser-Val-Val-Thr-Cys on gpVIII most avidly bound TF(1-218), as did the synthetic peptide. Inhibition of binding was selective with an IC(50) of 30 nM for proteolytic activation of factor X by the TF(1-218)-VIIa complex. In contrast, there was no inhibition of factor IX activation. The selective inhibition of only factor X association with TF(1-218) will spare the intrinsic hemostatic pathway while attenuating the extrinsic thrombogenic pathway. This and related peptidyl structures provide the potential for the more precise identification of TF surface loci that mediate selective functional properties of the protein as well as a structural basis for the design of novel molecules for selectively attenuating initiation of the extrinsic limb of the coagulation protease cascade and other functions of TF.     

Use of an oriented transmembrane protein to probe the assembly of a supported phospholipid bilayer.

Planar-supported phospholipid bilayers formed by the adsorption of vesicles are increasingly used in the investigation of lipid-dependent reactions. We have studied the way in which these bilayers are formed with phospholipid vesicles containing the transmembrane protein Tissue Factor (TF). TF complexed with the serine protease, factor VIIa, is the primary initiator of blood coagulation by way of activation of the zymogen factor X. TF has been shown to orient randomly on the inner and outer leaflets of vesicles. We used proteolytic digestion to produce vesicles in which the extracellular domain of TF is located on the inner leaflet. These vesicles show no cofactor activity for factor VIIa as a result of the inability of the extracellular domain of TF to bind VIIa. After freeze/thawing, 50% of the cofactor activity was regained, indicating reorientation of the sequestered, inner leaflet TF. Adsorption of these vesicles to the inner surface of glass microcapillaries results in a continuous phospholipid bilayer. The microcapillaries were perfused with a solution of factors VIIa and X, and the effluent was monitored for factor Xa production, a sensitive measure of the activity of the TF-VIIa complex. For coatings produced with the digested vesicles, minimal TF-VIIa activity was observed, showing that the supported bilayer preserves the orientation of the leaflets in the vesicles, i.e., the outer leaflet of the vesicles forms the outer leaflet of the supported bilayer.     

The interaction of human factor VIIa with tissue factor.

The interaction of factor VIIa with tissue factor (TF) results in an increase in the catalytic efficiency for the hydrolysis of several synthetic peptidyl p-nitroanilide substrates by factor VIIa. The binding of human recombinant factor VIIa to recombinant human TF incorporated into vesicles containing phosphatidylcholine (TF/PC) or phosphatidylcholine/phosphatidylserine (TF/PCPS) was studied using the increased rate of H-D-phenylalanyl L-pipecoyl L-arginine p-nitroanilide (S2238) hydrolysis as a signal for the interaction. The saturable dependence of rate on increasing concentrations of factor VIIa or TF/PCPS yielded no obvious evidence for cooperativity and could be analyzed according to the interaction of factor VIIa with independent noninteracting sites (Kd = 259 +/- 60 pM, n = 1.05 +/- 0.12 mol of factor VIIa/mol of TF at saturation). Identical titration curves and equilibrium parameters were derived from titrations using TF/PC or TF in the absence of phospholipids, indicating that possible protein-membrane interactions do not further stabilize the extrinsic Xase complex. The dissociation constant for the interaction of factor VIIa with TF/PCPS inferred from measurements of factor X activation (Kd = 197 +/- 38 pM) was comparable with the values obtained from measurements of S2238 hydrolysis. In contrast to the membrane-independent nature of the enzyme-cofactor interaction, the rate of factor X activation was reduced by approximately 50-fold when the enzyme complex was assembled using solution-phase TF. Collectively, the result indicate that the membrane dependence of extrinsic Xase function primarily results from an influence of the membrane surface on factor X utilization.     

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.     

Ligand-induced protease receptor translocation into caveolae: a mechanism for regulating cell surface proteolysis of the tissue factor- dependent coagulation pathway

The ability to regulate proteolytic functions is critical to cell biology. We describe events that regulate the initiation of the coagulation cascade on endothelial cell surfaces. The transmembrane protease receptor tissue factor (TF) triggers coagulation by forming an enzymatic complex with the serine protease factor VIIa (VIIa) that activates substrate factor X to the protease factor Xa (Xa). Feedback inhibition of the TF-VIIa enzymatic complex is achieved by the formation of a quaternary complex of TF-VIIa, Xa, and the Kunitz-type inhibitor tissue factor pathway inhibitor (TFPI). Concomitant with the downregulation of TF-VIIa function on endothelial cells, we demonstrate by immunogold EM that TF redistributes to caveolae. Consistently, TF translocates from the Triton X-100-soluble membrane fractions to low- density, detergent-insoluble microdomains that inefficiently support TF- VIIa proteolytic function. Downregulation of TF-VIIa function is dependent on quaternary complex formation with TFPI that is detected predominantly in detergent-insoluble microdomains. Partitioning of TFPI into low-density fractions results from the association of the inhibitor with glycosyl phosphatidylinositol anchored binding sites on external membranes. Free Xa is not efficiently bound by cell-associated TFPI; hence, we propose that the transient ternary complex of TF-VIIa with Xa supports translocation and assembly with TFPI in glycosphingolipid-rich microdomains. The redistribution of TF provides evidence for an assembly-dependent translocation of the inhibited TF initiation complex into caveolae, thus implicating caveolae in the regulation of cell surface proteolytic activity.     

Cooperative activation of human factor IX by the human extrinsic pathway of blood coagulation

The activation of human coagulation factor IX by human tissue factor.factor VIIa.PCPS.Ca2+ (TF.VIIa.PCPS.Ca2+) and factor Xa.PCPS.Ca2+ enzyme complexes was investigated. Reactions were performed in a highly purified system consisting of isolated human plasma proteins and recombinant human tissue factor with synthetic phospholipid vesicles (PCPS: 75% phosphatidylcholine (PC), 25% phosphatidylserine (PS)). Factor IX activation was evaluated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, [3H]factor IX activation peptide assay, colorimetric substrate thiobenzyl benzyloxycarbonyl-L-lysinate (Z-Lys-SBzl) hydrolysis, and specific incorporation of a fluorescent peptidyl chloromethyl ketone. Factor IX activation by the TF.VIIa.PCPS.Ca2+ enzyme complex was observed to proceed through the obligate non-enzymatic intermediate species factor IX alpha. The simultaneous activation of human coagulation factors IX and X by the TF.VIIa.PCPS.Ca2+ enzyme complex were investigated. When factors IX and X were presented to the TF.VIIa complex, at equal concentrations, it was observed that the rate of factor IX activation remained unchanged while the rate of factor X activation slowed by 45%. When the proteolytic cleavage products of this reaction were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, it was observed that the intermediate species factor IX alpha was generated more rapidly when factor X was present in the reaction mixture. When factor IX was treated with factor Xa.PCPS in the presence of Ca2+, it was observed that factor IX was rapidly converted to factor IX alpha. The activation of factor IX alpha by the TF.VIIa.PCPS.Ca2+ complex was evaluated, and it was observed that factor IX alpha was activated more rapidly by the TF.VIIa.PCPS.Ca2+ complex than was factor IX itself. These data suggest that factors IX and X, when presented to the TF.VIIa.PCPS.Ca2+ enzyme complex, are both rapidly activated and that factor Xa, which is generated in the initial stages of the extrinsic pathway, participates in the first proteolytic step in the activation of factor IX, the generation of factor IX alpha.     

The tissue factor region that interacts with factor Xa in the activation of factor VII

Tissue factor is the cell membrane-anchored cofactor for factor VIIa and triggers the coagulation reactions. The initial step is the conversion of factor VII to factor VIIa which, in vitro, is efficiently catalyzed by low concentrations of factor Xa. To identify the tissue factor region that interacts with the activator factor Xa during this process, we evaluated a panel of soluble tissue factor (1-219) mutants for their ability to support factor Xa-mediated activation of factor VII. The tissue factor residues identified as most important for this interaction (Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, and Tyr185) were identical to those found to be important for the interaction of substrate factor X with the tissue factor.factor VIIa complex. The residues form a continuous surface-exposed patch with an area of about 500 A(2), which appears to be located outside the tissue factor-factor VII contact zone. In agreement, the two monoclonal antibodies 5G6 and D3H44-F(ab')(2), whose epitopes overlap with this identified region, inhibited the rates of factor VII activation by 86% and 95%, respectively. These antibodies also strongly inhibited the conversion of (125)I-labeled factor VII when cell membrane-expressed, full-length tissue factor (1-263) was employed. Together the results suggest the usage of a common surface region of tissue factor in its dual role-as a cofactor for factor Xa-mediated factor VII activation and as a cofactor for factor VIIa-mediated factor X activation. The finding that factor Xa and factor X may engage in similar, if not identical, molecular interactions with tissue factor further indicates that factor Xa and factor X are similarly oriented toward their respective interaction partners in the ternary catalytic complexes.     

Factor VIIa/tissue factor generates a form of factor V with unchanged specific activity, resistance to activation by thrombin, and increased sensitivity to activated protein C

Factor VIIa, in complex with tissue factor (TF), is the serine protease responsible for initiating the clotting cascade. This enzyme complex (TF/VIIa) has extremely restricted substrate specificity, recognizing only three previously known macromolecular substrates (serine protease zymogens, factors VII, IX, and X). In this study, we found that TF/VIIa was able to cleave multiple peptide bonds in the coagulation cofactor, factor V. SDS-PAGE analysis and sequencing indicated the factor V was cleaved at Arg679, Arg709, Arg1018, and Arg1192, resulting in a molecule with a truncated heavy chain and an extended light chain. This product (FVTF/VIIa) had essentially unchanged activity in clotting assays when compared to the starting material. TF reconstituted into phosphatidylcholine vesicles was ineffective as a cofactor for the factor VIIa cleavage of factor V. However, incorporation of phosphatidylethanolamine in the vesicles had little effect over the presence of 20% phosphatidylserine. FVTF/VIIa was as sensitive to inactivation by activated protein C (APC) as thrombin activated factor V as measured in clotting assays or by the appearance of the expected heavy chain cleavage products. The FVTF/VIIa could be further cleaved by thrombin to release the normal light chain, albeit at a significantly slower rate than native factor V, to yield a fully functional product. These studies thus reveal an additional substrate for the TF/VIIa complex. They also indicate a new potential regulatory pathway of the coagulation cascade, i.e., the production of a form of factor V that can be destroyed by APC without the requirement for full activation of the cofactor precursor.     

Surface-mediated enzymatic reactions: simulations of tissue factor activation of factor X on a lipid surface.

Blood coagulation proceeds via reactions in which zymogen coagulation factors are activated to proteases. An essential step is the activation of factor X by a complex of tissue factor and factor VIIa. This complex usually is studied using phospholipid vesicles into which tissue factor is inserted. Because factor X exists free in solution and bound to the lipid-surface, it is difficult to establish experimentally the kinetic contribution of surfaces. We therefore developed a stochastic model to simulate such reactions and generate initial velocity data from which Michaelis-Menten parameters are estimated. Simulated Km values decrease slightly when substrate binding to lipid is increased and by a factor of four when the rates of surface diffusion are increased to that of fluid phase-diffusion. Simulations with various size planar surfaces established an enzyme capture radius of 32-64 nm. Simulations with different modes of enzyme-substrate complex assembly show that if the true substrate is lipid-bound, under certain conditions, the true Kcat is not measured; rather, the product "leaving rate" from the complex is the rate-limiting step that is measured as substrate is taken to infinity. This model is applicable to any surface-bound enzyme reaction.     

Structural modulation of factor VIIa by full-length tissue factor (TF1-263): implication of novel interactions between EGF2 domain and TF

Tissue factor (TF)-mediated factor VII (FVII) activation and a subsequent proteolytic TF-FVIIa binary complex formation is the key step initiating the coagulation cascade, with implications in various homeostatic and pathologic scenarios. TF binding allosterically modifies zymogen-like free FVIIa to its highly catalytically active form. As a result of unresolved crystal structure of the full-length TF_1-263-FVIIa binary complex and free FVIIa, allosteric alterations in FVIIa following its binding to full-length TF and the consequences of these on function are not entirely clear. The present study aims to map and identify structural alterations in FVIIa and TF resulting from full-length TF binding to FVIIa and the key events responsible for enhanced FVIIa activity in coagulation. We constructed the full-length TF_1-263-FVIIa membrane bound complex using computational modeling and subjected it to molecular dynamics (MD) simulations. MD simulations showed that TF alters the structure of each domain of FVIIa and these combined alterations contribute to enhanced TF-FVIIa activity. Detailed, domain-wise investigation revealed several new non-covalent interactions between TF and FVIIa that were not found in the truncated soluble TF-FVIIa crystal structure. The structural modulation of each FVIIa domain imparted by TF indicated that both inter and intra-domain communication is crucial for allosteric modulation of FVIIa. Our results suggest that these newly formed interactions can provide additional stability to the protease domain and regulate its activity profile by governing catalytic triad (CT) orientation and localization. The unexplored newly formed interactions between EGF2 and TF provides a possible explanation for TF-induced allosteric activation of FVIIa.     

Identification of a basic region on tissue factor that interacts with the first epidermal growth factor-like domain of factor X

Tissue factor (TF) facilitates the recognition and rapid activation of factor X (fX) by factor VIIa (fVIIa) in the extrinsic Xase pathway. TF makes extensive interactions with both light and heavy chains of fVIIa; however, with the exception of a basic recognition site for the Gla domain of fX, no other interactive site on TF for the substrate has been identified. Structural and modeling data have predicted that a basic region of TF comprised of residues Asn-199, Arg-200, and Lys-201 is located at a proper height on the membrane surface to interact with either the C-terminus of the Gla domain or the EGF-1 domain of fX. To investigate this possibility, we prepared the Ala substitution mutants of these residues and evaluated their ability to function as cofactors for fVIIa in the activation of wild-type fX and its two mutants which lack either the Gla domain (GD-fX) or both the Gla and EGF-1 domains (E2-fX). All three TF mutants exhibited normal cofactor activity in the amidolytic activity assays, but the cofactor activity of Arg-200 and Lys-201 mutants in fVIIa activation of both fX and GD-fX, but not E2-fX, was impaired approximately 3-fold. Further kinetic analysis revealed that kcat values with both TF mutants are impaired with no change in Km. These results suggest that both Arg-200 and Lys-201 of TF interact with EGF-1 of fX to facilitate the optimal docking of the substrate into the catalytic groove of the protease in the activation complex.     

The local phospholipid environment modulates the activation of blood clotting

Examples abound of membrane-bound enzymes for which the local membrane environment plays an important role, including the ectoenzyme that triggers blood clotting, the plasma serine protease, factor VIIa, bound to the integral membrane protein, tissue factor. The activity of this enzyme complex is markedly influenced by lipid bilayer composition and further by tissue factor partitioning into membrane microdomains on some cell surfaces. Unfortunately, little is known about how membrane microdomain composition controls factor VIIa-tissue factor activity, as reactions catalyzed by membrane-tethered enzymes are typically studied under conditions in which the experimenter cannot control the composition of the membrane in the immediate vicinity of the enzyme. To overcome this problem, we used a nanoscale approach that afforded complete control over the membrane environment surrounding tissue factor by assembling the factor VIIa.tissue factor complex on stable bilayers containing 67 +/- 1 phospholipid molecules/leaflet (Nanodiscs). We investigated how local changes in phospholipid bilayer composition modulate the activity of the factor VIIa.tissue factor complex. We also addressed whether this enzyme requires a pool of membrane-bound protein substrate (factor X) for efficient catalysis, or alternatively if it could efficiently activate factor X, which binds directly to the membrane nanodomain adjacent to tissue factor. We have shown that full proteolytic activity of the factor VIIa.tissue factor complex requires extremely high local concentrations of anionic phospholipids and further that a large pool of membrane-bound factor X is not required to support sustained catalysis.