Gene induction by coagulation factor Xa is mediated by activation of protease-activated receptor 1.

Cell signaling by coagulation factor Xa (Xa) contributes to pro-inflammatory responses in vivo. This study characterizes the signaling mechanism of Xa in a HeLa cell line that expresses protease-activated receptor 1 (PAR-1) but not PAR-2, -3, or -4. Xa induced NF-kappaB in HeLa cells efficiently but with delayed kinetics compared to thrombin. This delay caused no difference in gene expression patterns, as determined by high-density microarray analysis. Both proteases prominently induced the angiogenesis-promoting gene Cyr61 and connective tissue growth factor. Inhibition of PAR-1 cleavage abolished MAP kinase phosphorylation and gene induction by Xa, demonstrating that Xa signals through PAR-1 and not through a novel member of the PAR family. Activation of cell surface prothrombin with the snake venom enzyme Ecarin also produced PAR-1-dependent signaling. However, though the response to Ecarin was completely blocked by the thrombin inhibitor hirudin, the response to Xa was not. This suggests that the Xa response is not mediated by locally generated thrombin. The concentration dependence of Xa for PAR-1 activation is consistent with previously characterized Xa-mediated PAR-2 signaling, suggesting that local concentration of Xa on the cell surface, rather than sequence-specific recognition of the PAR scissile bond, determines receptor cleavage. This study demonstrates that PAR-1 cleavage by Xa can elicit the same cellular response as thrombin, but mechanistic differences in receptor recognition may be crucial for specific roles for Xa in signaling during spatial or temporal separation from thrombin generation.

Residue Met(156) contributes to the labile enzyme conformation of coagulation factor VIIa.

Serine protease activation is typically controlled by proteolytic cleavage of the scissile bond, resulting in spontaneous formation of the activating Ile(16)-Asp(194) salt bridge. The initiating coagulation protease factor VIIa (VIIa) differs by remaining in a zymogen-like conformation that confers the control of catalytic activity to the obligatory cofactor and receptor tissue factor (TF). This study demonstrates that the unusual hydrophobic Met(156) residue contributes to the propensity of the VIIa protease domain to remain in a zymogen-like conformation. Mutation of Met(156) to Gln, which is found in the same position of the highly homologous factor IX, had no influence on the amidolytic and proteolytic activity of TF-bound VIIa. Furthermore, the mutation did not appreciably stabilize the labile Ile(16)-Asp(194) salt bridge in the absence of cofactor. VIIa(Gln156) had increased affinity for TF, consistent with a long range conformational effect that stabilized the cofactor binding site in the VIIa protease domain. Notably, in the absence of cofactor, amidolytic and proteolytic function of VIIa(Gln156) were enhanced 3- and 9-fold, respectively, compared with wild-type VIIa. The mutation thus selectively influenced the catalytic activity of free VIIa, identifying the Met(156) residue position as a determinant for the zymogen-like properties of free VIIa.

Role of residue Phe225 in the cofactor-mediated, allosteric regulation of the serine protease coagulation factor VIIa.

Functional regulation by cofactors is fundamentally important for the highly ordered, consecutive activation of the coagulation cascade. The initiating protease of the coagulation system, factor VIIa (VIIa), retains zymogen-like features after proteolytic cleavage of the activating Arg(15)-Ile(16) peptide bond and requires the binding of the cofactor tissue factor (TF) to stabilize the protease domain in an active enzyme conformation. Structural comparison of TF-bound and free VIIa failed to provide a conclusive mechanism for this catalytic activation. This study provides novel insight into the cofactor-dependent regulation of VIIa by demonstrating that the side chain of Phe(225), an aromatic residue that is common to allosterically regulated serine proteases, is necessary for optimal TF-mediated activation of VIIa's catalytic function. However, mutation of Phe(225) did not abolish the cofactor-induced stabilization of the Ile(16)-Asp(194) salt bridge, previously considered the primary switch mechanism for activating VIIa. Moreover, mutation of other residue side chains in the VIIa protease domain resulted in a reduced level of or no stabilization of the amino-terminal insertion site upon TF binding, with little or no effect on the TF-mediated enhancement of catalysis. This study thus establishes a crucial role for the aromatic Phe(225) residue position in the allosteric network that transmits the activating switch from the cofactor interface to the catalytic cleft, providing insight into the highly specific conformational linkages that regulate serine protease function.

A novel clotting assay for quantitation of plasma prothrombin (factor II) using Echis multisquamatus venom.

Measuring plasma prothrombin activity seems useful for evaluating thrombotic risk and managing oral anticoagulant therapy as an adjunct to the international normalized ratio. Therefore, we designed a new plasma prothrombin assay based on the ability of Echis multisquamatus venom to activate prothrombin with only calcium as a cofactor. In this assay, 1 part of undiluted citrated plasma is added to 5 parts of a venom reagent and the clotting time is measured. The assay's advantages are that dilution of the test plasma is required only when prothrombin activity exceeds 100%, a single standard curve can be used over months for a given batch of stock reagent, and barium-adsorbed plasma is used for dilution of test plasma and construction of the standard curve, thus eliminating the need for prothrombin-deficient plasma. However, one should be aware of the following: (1) test samples must contain at least 200 mg/dL fibrinogen; and (2) when prothrombin concentrations were below 50%, the venom-based assay often gave values up to 10% higher than the thromboplastin-based assay. Values obtained in 262 plasma samples tested with the venom-based assay and with a thromboplastin-based prothrombin assay correlated well (r2 = 0.93).

A kinetic assay to determine prothrombin binding to membranes.

Activation of prothrombin by multisquamase, the prothrombin activator from the venom of Echis multisquamatus (Central Asian sand viper), is inhibited by membranes containing negatively charged anionic phospholipids. This inhibition appears to be due to the fact that the venom activator cannot activate membrane-bound prothrombin. Initial steady state rates of prothrombin activation by multisquamase in the presence of phospholipids appeared to depend on the fraction unbound prothrombin only and this phenomenon was used to quantitate binding of prothrombin to membranes of varying phospholipid composition. In this method, the initial rate of prothrombin activation by multisquamase is measured in the absence (total prothrombin) and in the presence of a procoagulant surface (rate depending only on free prothrombin) and from the difference in activation rates the amount of membrane-bound prothrombin is calculated. The validity of the method was established by determination of the binding parameters for prothrombin binding to 100 microM phospholipid vesicles composed of 20 mole% phosphatidylserine and 80 mole% phosphatidylcholine. The binding parameters obtained were Kd=0.84 microM and n=0.021 micromoles prothrombin bound per micromole phospholipid which is in agreement with literature. Due to the nature of the measurement the method is especially suitable to quantitate binding of prothrombin at concentrations as low as 5 nM prothrombin.

Autocatalytic peptide bond cleavages in prothrombin and meizothrombin.

During factor Xa-catalyzed prothrombin activation, several other reaction products accumulate as a result of proteolysis of prothrombin and its activation products by thrombin and meizothrombin. Gel electrophoretic analysis and N-terminal sequencing of reaction products showed that in the absence of Ca2+ ions thrombin cleaved the following peptide bonds: Arg51-Thr52/Arg54-Asp55 in the fragment 1 (F1) domain (k = 0.4 x 10(4) M-1 s-1), Arg155-Ser156 in prothrombin (k = 2 x 10(4) M-1 s-1), and Arg284-Thr285 in prethrombin 1 (k = 0.02 x 10(4) M-1 s-1). In the presence of 2.5 mM CaCl2, cleavage in fragment 1 (Arg51-Thr52/Arg54-Asp55) was not detectable, whereas cleavage at Arg155-Ser156 (i.e., removal of F1) was inhibited 25-fold. Cleavage at Arg284-Thr285 (formation of prethrombin 2 des-1-13) was not affected by the presence of Ca2+ ions. Meizothrombin rapidly converted itself into meizothrombin des-F1. The half-life (t1/2 = approximately 30 s) of this reaction was independent of the meizothrombin concentration (0.1-1 microM meizothrombin), which is indicative for intramolecular autocatalysis (k = 0.02 s-1 in the presence of 2.5 mM Ca2+ ions). Since the rapid removal of fragment 1 precludes investigations of the cleavage at Arg284-Thr285 in intact meizothrombin, we analyzed the cleavage of this peptide bond in R155A-meizothrombin, a recombinant product that is resistant to autocatalytic removal of the fragment 1 domain. In the absence of phospholipids, R155A-meizothrombin converted itself into thrombin des-1-13 by a combination of intramolecular (k = 0.8 x 10(-4) s-1) and intermolecular autocatalysis (k = 0.2 x 10(3) M-1 s-1). Intramolecular autocatalytic conversion of R155A-meizothrombin into thrombin was not affected by the presence of phospholipids (k = 0.8 x 10(-4) s-1), whereas intermolecular autocatalysis was accelerated 25-fold (k = 5.6 x 10(3) M-1 s-1) by phospholipid vesicles. Since factor Xa/Va-catalyzed conversion of meizothrombin into thrombin occurs with k = 5.5 x 10(8) M-1 s-1, we conclude that in reaction systems containing purified proteins autocatalysis of meizothrombin hardly contributes to thrombin formation during factor Xa-catalyzed prothrombin activation.

Purification and characterization of multisquamase, the prothrombin activator present in Echis multisquamatus venom.

The venom of Echis multisquamatus (Central Asian sand viper) contains a single prothrombin activator, designated multisquamase, which is structurally and functionally different from ecarin, the prothrombin activator from the venom of Echis carinatus (saw-scaled viper). Multisquamase is comprised of a 58000 Mr and a 23000 Mr subunit that consists of two disulfide-linked chains of 12000 Mr and 10000 Mr, respectively. In contrast to ecarin, which activates prothrombin and prethrombin 1 at comparable rates, and whose activity is hardly affected by Ca2+ or by changes in ionic strength, multisquamase hardly activates prethrombin 1; prothrombin activation requires Ca2+ and is strongly inhibited at high ionic strength. The most favourable kinetic parameters are observed at 1 mM Ca2+ and at low ionic strength (Km=0.085 microM and kcat=0.68 s(-1) at I approximately 0.04). An increase in ionic strength considerably reduces the rate of prothrombin activation, due to an increase of the Km (Km=0.8 microM and kcat=1.03 s(-1) at I approximately 0.2). Studies in plasmas from patients on oral anticoagulant therapy show that E. Multisquamatus venom only activates carboxylated prothrombin, whereas E. carinatus activates both prothrombin and descarboxyprothrombin. Thus, multisquamase-dependent prothrombin activation appears to require post-translational modification of the gla-domain. This venom prothrombin activator may, therefore, become a useful tool to quantitate prothrombin and descarboxyprothrombin in cases where vitamin K-dependent carboxylation of prothrombin is impaired.