Zymogen factor IX potentiates factor IXa-catalyzed factor X activation

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

Inactivation of factor VIII by factor IXa.

Factor VIII (FVIII) is the nonproteolytic cofactor for FIXa in the tenase complex of blood coagulation. FVIII is proteolytically activated by thrombin and FXa in vitro to form a heterotrimer with full procoagulant activity. Activated protein C inactivates thrombin-activated FVIII through cleavage adjacent to position Arg 336 in the cofactor. We have investigated the interaction of FIXa and FVIII and subjected FVIII polypeptides to N-terminal amino acid sequence analysis. Contrary to previous reports, we were unable to demonstrate the activation of FVIII by FIXa. Incubation of these two proteins at equimolar or close to equimolar concentrations resulted in the inactivation of FVIII, coincident with cleavage of the FVIII heavy chain adjacent to Arg 336 and the light chain adjacent to Arg 1719. These cleavages were detected in the presence or absence of thrombin, indicating that FIXa does not stabilize thrombin-activated FVIIIa. APC cleaved FVIII at the same position in the heavy chain, and simultaneous incubation of FVIII, APC, and FIXa did not result in stabilization of the cofactor. We conclude that FIXa does not play a role in the stabilization or activation of FVIII.     

Binding of factor VIIIa and factor VIII to factor IXa on phospholipid vesicles.

The activation of factor X by factor IXa (fIXa) in the presence of phosphatidylcholine-phosphatidylserine (PCPS) vesicles is markedly accelerated by thrombin-activated factor VIII (fVIIIa). The interaction between highly purified fVIIIa and fIXa in this complex was studied fluorometrically at 25 degrees C by using a derivative of D-phenylalanyl-prolyl-arginyl-fIXa which was modified at the active site with fluorescein-5-maleimide (Fl-M-FPR-fIXa). Titration of Fl-M-FPR-fIXa with fVIIIa at fixed PCPS resulted in a large, saturable increase in anisotropy (delta r = 0.09). The titration data were fit to a model assuming a reversible equilibrium between fVIIIa and fIXa, resulting in an apparent dissociation constant of 2 nM and a stoichiometry of 1 mol of fVIIIa/mol of Fl-M-FPR-fIXa. The initial velocity of factor X activation was measured under identical conditions except that active fIXa and factor X were included, which yielded binding parameters similar to those determined fluorometrically. Thus, the fluorescence method accurately reflects complex formation between fVIIIa and fIXa on the phospholipid surface, and the fVIIIa-fIXa interaction is not influenced by the presence of the substrate, factor X. Addition of fVIII to Fl-M-FPR-fIXa and PCPS produced a small, saturable increase in anisotropy (delta r = 0.03), followed by a larger increase (delta r = 0.07) upon addition of thrombin to activate fVIII. Thus, fVIII binds fIXa, but proteolytic modification of fVIII must occur before the complete fVIIIa-dependent structural change in the active site of fIXa, as reflected in the anisotropy change, occurs     

Proteolysis of blood coagulation factor VIII by the factor VIIa-tissue factor complex: generation of an inactive factor VIII cofactor.

Activation of factor VIII by thrombin occurs via limited proteolysis at R372, R740, and R1689. The resultant active factor VIIIa molecule consists of three noncovalently associated subunits: A1-a1, A2-a2, and A3-C1-C2 (50, 45, and 73 kDa respectively). Further proteolysis of factor VIIIa at R336 and R562 by activated protein C subsequently inactivates this cofactor. We now find that the factor VIIa-tissue factor complex (VIIa-TF/PL), the trigger of blood coagulation with restricted substrate specificity, can also catalyze limited proteolysis of factor VIII. Proteolysis of factor VIII was observed at 10 sites, producing 2 major fragments (47 and 45 kDa) recognized by an anti-factor VIII A2 domain antibody. Time courses indicated the slow conversion of the large fragment to 45 kDa, followed by further degradation into at least two smaller fragments. N-Terminal sequencing along with time courses of proteolysis indicated that VIIa-TF/PL cleaved factor VIII first at R740, followed by concomitant cleavage at R336 and R372. Although cleavage of the light chain at R1689 was observed, the majority remained uncleaved after 17 h. Consistent with this, only a transient 2-fold increase in factor VIII clotting activity was observed. Thus, heavy chain cleavage of factor VIII by VIIa-TF/PL produces an inactive factor VIII cofactor no longer capable of activation by thrombin. In addition, VIIa-TF/PL was found to inactivate thrombin-activated factor VIII. We hypothesize that these proteolyses may constitute an alternative pathway to regulate coagulation under certain conditions. In addition, the ability of VIIa-TF/PL to cleave factor VIII at 10 sites greatly expands the known protein substrate sequences recognized by this enzyme-cofactor complex.     

The association of coagulation factor Xa and factor Va

The binding of factor Xa to factor Va in the presence of Ca2+ ions and phospholipid is fundamental for the activation of prothrombin to thrombin. Nevertheless, the biochemistry of the intrinsic association between factors Xa and Va is poorly understood. In the present study we have measured the formation of the protein-protein complex in the absence of phospholipid by using analytical ultracentrifugation. Factor Xa or factor Va were respectively modified with a chromophore-peptidyl-chloromethyl ketone or a thiol-specific chromophore, which permitted selective evaluation of the sedimentation of either component by virtue of its unique absorbance properties. Regardless of which protein was labeled, a factor Xa-Va complex (s20,w = 9.8) was formed. The interaction is specific and reversible. In 2 mM Ca2+ and at 20 degrees C, the dissociation constant for the binding of factor Xa to factor Va is 0.8 microM with a 1:1 stoichiometry. The association has multiphasic Ca2+ dependence. At concentrations of Ca2+ below 1 mM or above 2 mM, a weaker protein-protein equilibrium is maintained.     

Autoactivatability of human Hageman factor (factor XII)

Purified Hageman factor was found to autodigest upon binding to a negatively charged surface such as kaolin. Assessment by incorporation of tritiated diisopropylfluorophosphate indicated that this cleavage was accompanied by activation and that the two known forms of activated Hageman factor result. Cleavage within a critical disulfide bridge generated activated Hageman factor, a two-chain enzyme of molecular weight 80,000 as well as the active Hageman factor fragment, a 28,000 molecular weight cleavage product. The autocleavage seen was dependent upon the percentage of activated Hageman factor in the starting material and was independent of HMW-kininogen. This result suggest that initiation of the intrinsic coagulation cascade may, in part, depend upon the autoactivatability of Hageman factor described herein. This observation may in turn, account for the ability of prekallikrein deficient plasma to gradually autoactivate as a function of the time of contact with initiating surfaces.     

Role of factor VIII C2 domain in factor VIII binding to factor Xa.

Factor VIII (FVIII) is activated by proteolytic cleavages with thrombin and factor Xa (FXa) in the intrinsic blood coagulation pathway. The anti-C2 monoclonal antibody ESH8, which recognizes residues 2248-2285 and does not inhibit FVIII binding to von Willebrand factor or phospholipid, inhibited FVIII activation by FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain dose-dependently bound to immobilized anhydro-FXa, a catalytically inactive derivative of FXa in which dehydroalanine replaces the active-site serine. The affinity (K(d)) values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did not bind to anhydro-FXa. Similarly, competitive assays using overlapping synthetic peptides corresponding to ESH8 epitopes (residues 2248-2285) demonstrated that a peptide designated EP-2 (residues 2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%, respectively. Our results provide the first evidence for a direct role of the C2 domain in the association between FVIII and FXa.     

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.     

Transforming growth factor activity of bovine brain-derived growth factor

Bovine brain-derived growth factor (BDGF), whose biochemical properties resemble those of endothelial cell growth factor (ECGF) and brain-derived acidic fibroblast growth factor (acidic FGF), is able to promote colony formation of normal rat kidney fibroblasts (NRK cells) in soft agar. As in the case of transforming growth factor beta (TGF beta), EGF potentiates the anchorage-independent growth promoting activity of BDGF. In the presence of EGF (5 ng/ml), the optimal concentration of BDGF for stimulation of anchorage-independent of NRK cells is approximately 0.5 ng/ml. At higher concentrations, BDGF becomes inhibitory. The anchorage-independent cell growth promoting activity of BDGF differs from that of TGF beta in acid and reducing agent stability.     

Plasmacytoma growth factor activity of murine granulocyte-macrophage colony-stimulating factor

Mouse plasmacytoma FLOPC21 was adapted to culture in the presence of a mouse Th cell supernatant. A stable factor-dependent cell line was derived from this culture and the factor responsible for its growth was identified as granulocyte-macrophage colony-stimulating factor.     

Meiosis-reinitiation-inducing factor of Tetrahymena functions upstream of M-phase-promoting factor.

Reinitiation of meiosis (maturation) of amphibian Bufo and Xenopus oocytes can be induced if Tetrahymena extract is injected into them. The activity differed from M-phase-promoting factor, because action of the former factor on the induction of maturation was inhibited by treatment of the oocytes with cycloheximide. Activity of M-phase-promoting factor was not detected in Tetrahymena extract regardless of the presence of cdc2 homologues in the extract. However, cycloheximide-resistant-maturation-inducing activity appeared in the recipients, when the maturation was induced by injection of Tetrahymena extract. Immunoblots using antibodies against cdc2 showed that injection of Tetrahymena extract induced fast mobility of the recipient cdc2 in the presence of the recipient protein synthesis. The same mobility shift of the cdc2 was also induced when M-phase-promoting factor containing Xenopus oocyte extract was injected into immature oocytes or when the immature oocyte extract was treated with alkaline phosphatase. These results indicate that meiosis-reinitiation-inducing factor of Tetrahymena functions upstream of M-phase-promoting factor to induce dephosphorylation of the recipient cdc2. Tetrahymena cdc2 homologues also showed fast mobility when the Tetrahymena extract was treated with alkaline phosphatase. Preliminary experiments showed that the meiosis-reinitiation-inducing factor of Tetrahymena was a soluble protein.     

Stoichiometry of the porcine factor VIII-von Willebrand factor association

Factor VIII and von Willebrand factor (vWF) are glycoproteins that form a tightly bound complex in plasma. The interaction of porcine factor VIII with porcine vWF was studied by analytical velocity sedimentation. A single approximately 240-kDa species of factor VIII was isolated for use in the analysis. In contrast, when analyzed by agarose/sodium dodecyl sulfate-polyacrylamide gel electrophoresis, vWF consisted of a population of greater than 10 multimers derived from a 270-kDa monomer. A single boundary (So20,w = 7.2 S) was observed during velocity sedimentation of factor VIII at 260,000 x g. A single boundary also was observed for vWF (weight-average So20,w = 21 S) at 42,000 x g. Under condition of excess factor VIII, the weight-average So20,w of the factor VIII-vWF complex was 40 S at 42,000 x g. At 260,000 x g, the factor VIII-vWF complex had sedimented completely, leaving only free factor VIII. The height of the plateau region of the factor VIII sedimentation velocity curve at 260,000 x g was studied as a function of several starting concentrations of vWF. The experiments were done under conditions in which the effect of radial dilution was negligible so that the plateau height was a measure of the concentration of free factor VIII. The plateau height decreased linearly as the concentration of vWF was increased, indicating that the association was essentially irreversible under the conditions used. A stoichiometry of 1.2 vWF monomers/factor VIII molecule was calculated from the slope of the line. Assuming one factor VIII-binding site/vWF monomer, these results indicate that all factor VIII-binding sites are accessible in the vWF multimer.     

Topography of the human factor VIII-von Willebrand factor complex

Factor VIII circulates in noncovalent complex with von Willebrand factor (vWf). The topography of this complex was evaluated by fluorescence energy transfer using factor VIII subunits modified with N-(1-pyrenyl)maleimide (NPM; fluorescence donor) and vWf-derived fragments modified with 7-diethylamino-3-[4'-maleimidylphenyl]-4-methyl coumarin (CPM; fluorescence acceptor). Results from a previous study indicated an interfactor VIII subunit distance of 20 A separating Cys528 and Cys1858 in the factor VIII heavy and light chains, respectively (Fay, P.J., and Smudzin, T. M. (1989) J. Biol. Chem. 264, 14005-14010). Fluorophore modification of the vWf SPIII homodimer (residues 1-1365) indicated multiple attachment sites at Cys126/135/1360 as determined from sequence analysis of fluorescent tryptic peptides derived from the modified protein. Based upon donor quenching data, an interfluorophore distance of approximately 28 A was calculated separating NPM-factor VIII light chain or factor VIII reconstituted from NPM-light chain plus unmodified heavy chain, from CPM-SPIII. A similar value (29 A) was obtained for NPM-light chain paired with CPM-SPIII-T4 (vWf residues 1-272), suggesting that donor quenching resulted primarily from modified residue(s) Cys126/135 in the acceptor. No energy transfer was observed for the NPM-heavy chain/CPM-SPIII pairing. However, when NPM-heavy chain was reassociated with unmodified light chain prior to reaction with CPM-SPIII or CPM-SPIII-T4, energy transfer was observed with calculated interfluorophore distances of approximately 31 and 34 A, respectively. Levels of acceptor resulting in maximal donor quenching suggested an equimolar stoichiometry of factor VIII (light chain)/vWf fragment in the reconstituted complexes. These results indicate a close spatial arrangement among the A3 domain of factor VIII light chain, the A2 domain of factor VIII heavy chain, and the NH2 terminus region of vWf in the factor VIII-vWf complex.     

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

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