Deposition of fibronectin on material surfaces exposed to plasma: quantitative and biological studies

Experiments were carried out to characterize plasma fibronectin deposition onto material surfaces exposed to plasma solutions. Under nonclotting conditions, the amount of fibronectin adsorption on the surfaces, determined by an indirect radioactive antibody assay, was maximal at low plasma concentrations (0.1%). At higher concentrations of plasma, other plasma proteins appeared to compete with and inhibit adsorption of fibronectin. Biological activity (fibronectin-promoted cell spreading) was also greatest at low plasma concentrations and decreased as the plasma concentration was raised. When surfaces were exposed to plasma under clotting conditions (i.e., addition of Ca2+ and thrombin), fibronectin deposition on the surfaces and biological activity remained constant or increased as the plasma concentration was raised. Based on indirect immunofluorescent antibody assays, the fibronectin deposited from clotting plasma appeared to be in a punctate distribution over the entire material surface and occasionally was associated with discrete fibrillar structures. The increased deposition of fibronectin from clotting plasma compared to nonclotting plasma (approximately a 10-fold difference with 10% plasma) was partially a result of covalent crosslinking of fibronectin to fibrin based upon studies with putrescine added to inhibit crosslinking during clotting. On the other hand, the increase in biological activity that occurred if the surfaces were exposed to clotting plasma was completely inhibited by putrescine, indicating that fibronectin had to be crosslinked to fibrin to have biological activity under these conditions. Finally, fibronectin deposition also occurred on surfaces exposed to whole blood and was markedly enhanced when clotting occurred.     

Activation of Coagulase Clotting by Trypsin Inhibitor

Egg white trypsin inhibitor activated coagulase clotting when added to a final concentration between 2 and 60 mg/ml. The greatest increase in clotting rate was observed in reaction mixtures containing the lowest concentrations of serum and plasma. Maximal activation was reached with 40 mg of trypsin inhibitor per ml when either serum or plasma was used as the source of coagulase-reacting factor (CRF). The increased rate of clotting is partly due to inhibition of plasmin. Freezing and thawing reduced plasma clotting inhibition. Soybean trypsin inhibitor also activated the coagulase reaction. The increased rate of clotting was observed with a coagulase preparation from organisms which produced plasminogen activators and with the culture supernatant fraction from organisms which did not activate plasminogen to plasmin. The tube test for coagulase could be made more sensitive for some strains of staphylococci by increasing the concentration of CRF (added as plasma or serum) by adding trypsin inhibitor, or both.     

Anticoagulant activities of a monoclonal antibody that binds to exosite II of thrombin.

A monoclonal IgG isolated from a patient with multiple myeloma has been shown to bind to exosite II of thrombin, prolong both the thrombin time and the activated partial thromboplastin time (aPTT) when added to normal plasma, and alter the kinetics of hydrolysis of synthetic peptide substrates. Although the IgG does not affect cleavage of fibrinogen by thrombin, it increases the rate of inhibition of thrombin by purified antithrombin approximately 3-fold. Experiments with plasma immunodepleted of antithrombin or heparin cofactor II confirm that prolongation of the thrombin time requires antithrombin. By contrast, prolongation of the aPTT requires neither antithrombin nor heparin cofactor II. The IgG delays clotting of plasma initiated by purified factor IXa but has much less of an effect on clotting initiated by factor Xa. In a purified system, the IgG decreases the rate of activation of factor VIII by thrombin. These studies indicate that binding of a monoclonal IgG to exosite II prolongs the thrombin time indirectly by accelerating the thrombin-antithrombin reaction and may prolong the aPTT by interfering with activation of factor VIII, thereby diminishing the catalytic activity of the factor IXa/VIIIa complex.     

Ligands which effect human protein C activation by thrombin

This report documents attempts to mimic the rate enhancement effect of thrombomodulin on human alpha-thrombin-catalyzed activation of human protein C in the absence of exogenous calcium. Specifically the following tryptamine analogs at 1 mM concentration were shown to enhance the protein C activation rate relative to a control with no added effector at pH 8.3 (50 mM Tris-HCl, 0.1 M NaCl, 37 degrees C): serotonin, 1.2; tryptamine, 2.9; 5-fluorotryptamine, 4.4; 6-fluorotryptamine, 7.2. At much higher levels, e.g. 10 mM, all of the above effectors, as well as indole, showed a moderate inhibition of human protein C activation. ATP, a platelet release product, showed a sigmoidal inhibition pattern similar to that found previously for thrombin amidase, clotting, and esterase activity (Conery, B.G., and Berliner, L.J. (1983) Biochemistry 22, 369-375). Overall, the enhancement factors for human alpha-thrombin activation of protein C with the tryptamine analogs described above were remarkable when considering the effect of a simple ligand versus the natural activator, thrombomodulin.     

Characterization of the threshold response of initiation of blood clotting to stimulus patch size

This article demonstrates that the threshold response of initiation of blood clotting to the size of a patch of stimulus is a robust phenomenon under a wide range of conditions and follows a simple scaling relationship based on the Damk?hler number. Human blood and plasma were exposed to surfaces patterned with patches presenting clotting stimuli using microfluidics. Perturbations of the complex network of hemostasis, including temperature, variations in the concentration of stimulus (tissue factor), and the absence or inhibition of individual components of the network (factor IIa, factor V, factor VIII, and thrombomodulin), did not affect the existence of this response. A scaling relationship between the threshold patch size and the timescale of reaction for clotting was supported in numerical simulations, a simple chemical model system, and experiments with human blood plasma. These results may be useful for understanding the spatiotemporal dynamics of other autocatalytic systems and emphasize the relevance of clustering of proteins and lipids in the regulation of signaling processes.     

Mechanism of Coagulation in Gecarcinus lateralis

Agglutination of cells, degranulation, and loss of cellularmembranes compose the major form of coagulation in the hemolymphof Gecarcinus lateralis. It is only after agglutination of theformed elements of the hemolymph that fibrin-like strands appear.Sodium citrate, in a concentration of 10% or more to preventcoagulation, is always inadequate to prevent cell agglutination. Multiple studies by protein electrophoresis failed to revealany differences between plasma and serum, nor did they allowus to identify a soluble protein in plasma that did not appearin serum. Crab hemolymph changes in its capacity for clottingduring the molt cycle, with the most rapid clotting occurringin the premolt period. A new protein appears in the premoltperiod, but its relation to the whole clotting mechanism isunknown. In contradistinction to vertebrate systems, citrated hemolymphdoes not clot when calcium is added. There is no relationshipthat can be demonstrated between activating systems in vertebrateplasma and clotting in the crab. It would seem that, ratherthan the vertebrate coagulating system evolving from the crustaceantype of clotting system, the development of these clotting systemshas run in parallel. The crustacean cell, in addition, appearsto be more potent than vertebrate cells in clotting systems.The comparison of human lymph to crustacean hemolymph wouldindicate that, for a given amount of cells, crustacean hemolymphclots 2 to 20 times faster than human lymph. On the other hand,agglutination of cells is a fundamental initiating step in coagulationof both human blood and crustacean hemolymph.     

Activation of human blood coagulation factor XI independent of factor XII. Factor XI is activated by thrombin and factor XIa in the presence of negatively charged surfaces

Human blood coagulation factor XI was activated by either autoactivation or thrombin. These reactions occurred only in the presence of negatively charged materials, such as dextran sulfate (approximately Mr 500,000), sulfatide, and heparin. During the activation, factor XI was cleaved at a single Arg-Ile bond by thrombin or factor XIa to produce an amino-terminal 50-kDa heavy chain and a carboxyl-terminal 35-kDa light chain. This activation pattern is identical to that produced by factor XIIa. The addition of a small amount of thrombin and sulfatide to factor XII-deficient plasma produced shorter clotting times than when these agents were added to factor XI/factor XII combined-deficient plasma. These results suggest that the activation of factor XI by thrombin and possibly the autoactivation of factor XI proceed in plasma to lead fibrin clot formation. These reactions may have a role on an appropriate negatively charged surface in normal hemostasis.     

Regulation of the activities of thrombin and plasmin by cholesterol sulfate as a physiological inhibitor in human plasma

Thrombin and plasmin, both of which are serine proteases in the plasma of vertebrates, play essential roles in blood clotting and fibrinolysis, respectively, and regulation of their activities is important to suppress the excessive reactions within the vascular network and to prevent tissue injury. Along with the peptidic inhibitors belonging to the serpin family, we found that cholesterol sulfate (CS), which is present at the concentration of 2.0+/-1.2 nmol/ml in human plasma, was a potent inhibitor of both plasma thrombin and plasmin. Thrombin, as determined both using a chromogenic substrate and the natural substrate, fibrinogen, was inactivated upon reaction with CS in a dose-dependent manner, but not in the presence of the structurally related steroid sulfates, I3SO3-GalCer and II3NAalpha-LacCer, suggesting that both the sulfate group and the hydrophobic side chain of CS are necessary for the inhibitory activity of CS. Preincubation of thrombin with CS at 37 degrees C for 10 min was required to achieve maximum inhibition, and virtually complete inhibition was achieved at a molar ratio of CS to thrombin of 18:1. CS-treated thrombin had the same Km and a lower Vmax than the original enzyme, and a higher molecular weight. The molecular weight and activity of the original enzyme were not observed on the attempted separation of the CS-treated enzyme by gel permeation chromatography and native PAGE, indicating that the inactivation of thrombin by CS is irreversible. In contrast, CS was readily liberated from the enzyme by SDS-PAGE, suggesting that hydrophobic interactions are involved in the CS-mediated inactivation of thrombin. When acidic lipids were reacted with thrombin after dissolving them in DMSO, I3SO3-GalCer, steroid sulfates and II3NAalpha-LacCer, as well as CS, but not SDS and sodium taurocholate, exhibited inhibitory activity, probably due to micellar formation facilitating interaction between thrombin and negatively charged lipids. On the other hand, plasmin, as determined using a chromogenic substrate, was more susceptible to acidic lipids than thrombin. CS, I3SO3-GalCer and II3NAalpha-LacCer, all of which are present in serum, inhibited the activity of plasmin in aqueous media, as well as in DMSO-mediated lipid solutions. Thus, acidic lipids in plasma were demonstrated to possess regulatory activity as endogenous detergents toward both enzymes for blood clotting and fibrinolysis.     

Systems Biology of Coagulation Initiation: Kinetics of Thrombin Generation in Resting and Activated Human Blood

Blood function defines bleeding and clotting risks and dictates approaches for clinical intervention. Independent of adding exogenous tissue factor (TF), human blood treated in vitro with corn trypsin inhibitor (CTI, to block Factor XIIa) will generate thrombin after an initiation time (T_i) of 1 to 2 hours (depending on donor), while activation of platelets with the GPVI-activator convulxin reduces T_i to ∼20 minutes. Since current kinetic models fail to generate thrombin in the absence of added TF, we implemented a Platelet-Plasma ODE model accounting for: the Hockin-Mann protease reaction network, thrombin-dependent display of platelet phosphatidylserine, VIIa function on activated platelets, XIIa and XIa generation and function, competitive thrombin substrates (fluorogenic detector and fibrinogen), and thrombin consumption during fibrin polymerization. The kinetic model consisting of 76 ordinary differential equations (76 species, 57 reactions, 105 kinetic parameters) predicted the clotting of resting and convulxin-activated human blood as well as predicted T_i of human blood under 50 different initial conditions that titrated increasing levels of TF, Xa, Va, XIa, IXa, and VIIa. Experiments with combined anti-XI and anti-XII antibodies prevented thrombin production, demonstrating that a leak of XIIa past saturating amounts of CTI (and not “blood-borne TF” alone) was responsible for in vitro initiation without added TF. Clotting was not blocked by antibodies used individually against TF, VII/VIIa, P-selectin, GPIb, protein disulfide isomerase, cathepsin G, nor blocked by the ribosome inhibitor puromycin, the Clk1 kinase inhibitor Tg003, or inhibited VIIa (VIIai). This is the first model to predict the observed behavior of CTI-treated human blood, either resting or stimulated with platelet activators. CTI-treated human blood will clot in vitro due to the combined activity of XIIa and XIa, a process enhanced by platelet activators and which proceeds in the absence of any evidence for kinetically significant blood borne tissue factor.     

蝮蛇毒蛋白C激活物对凝血系统的影响

目的研究蝮蛇毒纯化蛋白C激活物(PCA)的抗凝机制。方法测定PCA对正常人混浆KPTT、PT、TT的影响,对血液凝血活酶生成试验(BTGT)及PA二期法的影响以及对白兔的KPTT和Fgn的影响。结果PCA在最终浓度为0.025mg/L时对正常人混浆KPTT可明显延长,但PT和TT不受影响;当它的浓度增加到50mg/L,PT也可延长,但TT依然无明显变化;最终浓度为0.0125mg/L时,血液凝血活酶生成明显受抑制;当它的浓度增加到2.5mg/L,凝血酶生成显著减少,但抗凝血酶时间始终无明显变化;PCA可明显延长白兔的KPTT。结论PCA在低浓度时首先抑制凝血系统第一阶段内凝途径,在高浓度时也妨碍外凝途径或共同途径,BTGT和PA二期法比KPTT和PT敏感;PCA具有体内抗凝作用。     

Gel formation by fibrin oligomers without addition of monomers

Soluble fibrin oligomers were formed by reacting fibrinogen with thrombin under fine clotting conditions where the action of thrombin is the rate-determining step for polymerization, and by inhibiting the reaction shortly before gelation. Oligomeric fibrin was separated from unreacted fibrinogen and small oligomers by gel permeation chromatography. Electron microscopy revealed that the largest soluble fibrin oligomers resemble the protofibrils present in fine clots, but are somewhat shorter and entirely lack the twisted, trifunctional junctions that contribute to the elastic properties of fine clots. When thrombin was added to the soluble fibrin oligomers, polymerization resumed and clots were formed at a more rapid rate than from fibrinogen at the same concentration and resulted in a less-opaque clot under coarse clotting conditions. The results confirm a prediction of a theory for the polymerization of fibrin and provide additional evidence that the final state of a coarse fibrin clot depends on the mobility of protofibrils during its formation.     

Investigating thrombin-loaded fibrin in whole blood clot microfluidic assay via fluorogenic peptide

During clotting under flow, thrombin rapidly generates fibrin, whereas fibrin potently sequesters thrombin. This co-regulation was studied using microfluidic whole blood clotting on collagen/tissue factor, followed by buffer wash, and a start/stop cycling flow assay using the thrombin fluorogenic substrate, Boc-Val-Pro-Arg-AMC. After 3 min of clotting (100 s^?1) and 5 min of buffer wash, non-elutable thrombin activity was easily detected during cycles of flow cessation. Non-elutable thrombin was similarly detected in plasma clots or arterial whole blood clots (1000 s^?1). This thrombin activity was ablated by Phe-Pro-Arg-chloromethylketone (PPACK), apixaban, or Gly-Pro-Arg-Pro to inhibit fibrin. Reaction-diffusion simulations predicted 108 nM thrombin within the clot. Heparin addition to the start/stop assay had little effect on fibrin-bound thrombin, whereas addition of heparin-antithrombin (AT) required over 6 min to inhibit the thrombin, indicating a substantial diffusion limitation. In contrast, heparin-AT rapidly inhibited thrombin within microfluidic plasma clots, indicating marked differences in fibrin structure and functionality between plasma clots and whole blood clots. Addition of GPVI-Fab to blood before venous or arterial clotting (200 or 1000 s^?1) markedly reduced fibrin-bound thrombin, whereas GPVI-Fab addition after 90 s of clotting had no effect. Perfusion of AF647-fibrinogen over washed fluorescein isothiocyanate (FITC)-fibrin clots resulted in an intense red layer around, but not within, the original FITC-fibrin. Similarly, introduction of plasma/AF647-fibrinogen generated substantial red fibrin masses that did not penetrate the original green clots, demonstrating that fibrin cannot be re-clotted with fibrinogen. Overall, thrombin within fibrin is non-elutable, easily accessed by peptides, slowly accessed by average-sized proteins (heparin/AT), and not accessible to fresh fibrinogen.     

Purification and characterization of a prothrombin activator from the venom of the Australian brown snake, Pseudonaja textilis textilis

A simple procedure, involving chromatography on concanavalin A-Sepharose and gel filtration, has been developed for the purification of a prothrombin activator from the venom of the Australian brown snake Pseudonaja textilis textilis. The prothrombin activator, which is a major venom component, is a high molecular weight protein (Mr greater than or equal to 200,000) which yields a number of subunits when examined by SDS-PAGE. It is related antigenically to the venom prothrombin activator of the taipan Oxyuranus scutellatus. P. textilis prothrombin activator is able to coagulate citrated plasma, warfarin plasma, and Factor V- and Factor X-deficient plasmas; to convert purified human prothrombin to thrombin; and to hydrolyse the peptide p-nitroanilide substrate S-2222. Calcium ions and phospholipids had little if any effect on the rates of coagulation of citrated plasma or S-2222 hydrolysis catalysed by this enzyme.     

Prothrombin fragment 1 X 2 X 3, a major product of prothrombin activation in human plasma

The conversion of the blood coagulation zymogen prothrombin to thrombin is associated with the production of several cleavage intermediates and products. In contrast to earlier studies of prothrombin cleavage in chemically defined systems, the current investigation examines the fragmentation of human prothrombin in normal plasma. Radiolabeled prothrombin was added to platelet-poor relipidated normal human plasma, and clotting was initiated with the addition of Ca(II) and kaolin. Analysis of the radiolabeled prothrombin cleavage products by polyacrylamide gel electrophoresis in the presence of dodecyl sulfate and beta-mercaptoethanol identified a heretofore unobserved product of prothrombin activation with an apparent molecular weight of 45,000. This product was identified as fragment 1 X 2 X 3, the NH2-terminal 286 amino acids of prothrombin. The product was isolated from a prothrombin digest by immunoaffinity chromatography using anti-prothrombin:Ca(II) antibodies and by preparative gel electrophoresis. Its amino-terminal sequence is identical to that of prothrombin. Digestion of this product with either Factor Xa or thrombin yields, at a minimum, fragment 1 X 2 and fragment 1. Amino-terminal sequence analysis of the products obtained by digestion with Factor Xa of the unknown activation product indicated 3 amino acid residues at each cycle consistent with the presence of fragment 1, fragment 2, and fragment 3. To unambiguously identify the COOH-terminal amino acid sequence of the product, its factor Xa digestion products were separated by reverse-phase high performance liquid chromatography. Edman degradation of one peptide revealed the complete sequence of fragment 3. On this basis, we identify the Mr 45,000 polypeptide as fragment 1 X 2 X 3 and indicate that it is a prominent product of prothrombin conversion to thrombin when activation occurs in plasma.     

Physicochemical characterization of human S-protein and its function in the blood coagulation system.

S-protein, the main inhibitor of the assembly of the membrane attack complex of complement, was isolated from human plasma by a simple purification procedure, which includes barium citrate adsorption, ammonium sulphate precipitation, chromatography on DEAE-Sephacel and Blue Sepharose and gel filtration on Sephacryl S-200. The homogeneous protein (sedimentation coefficient 4.6 S) was obtained in approx. 5% yield relative to its concentration in plasma, which was found to be 0.3-0.5 mg/ml. The final product did not cross-react with antisera against complement proteins or other proteinase inhibitors of human plasma. On polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate, S-protein migrated as a single-chain band with an apparent Mr of 74000 under non-reducing conditions and as a doublet of Mr 78000 and 65000 upon reduction. In plasma or serum S-protein also existed in two forms of corresponding Mr values, as was evidenced by an immunoblot enzyme-linked immunosorbent assay technique. S-protein was found to be an acidic glycoprotein with 10% (W/W) carbohydrate content and several isoelectric points in the range pH 4.75-5.25, and it contained one free thiol group per molecule of protein. The functional properties of S-protein in the complement system were demonstrated by its ability to inhibit complement-dependent cell lysis in a concentration-dependent manner (Ki 0.6 microM) and by its incorporation into the nascent SC5b-7 complex. A new function for S-protein could be revealed in the blood coagulation system. The slow progressive inhibition of thrombin by antithrombin III was not affected by S-protein, whereas the purified protein interfered with the fast inactivation of thrombin clotting as well as amidolytic activity by antithrombin III-heparin complex. The acceleration of this inhibition reaction by heparin was counteracted by S-protein, indicating the ability of S-protein to neutralize heparin activity.     

Effects of calcium binding and of EDTA and CaEDTA on the clotting of bovine fibrinogen by thrombin

Studies were carried out at pH 7.0 and gamma/2 0.15 before addition of CaCl2 or EDTA. Clotting time, tau, at 3.03 microM fibrinogen and 0.91 u/ml thrombin was determined for equilibrium systems. With added Ca2+, tau decreases, from tau 0 at 0 added Ca2+ (mean, 29.7 +/- 3 s), by approximately 3 s at 5 mM added Ca2+. With added EDTA, tau increases sigmoidally from tau 0 at 0 EDTA to a maximum (mean tau m = 142 +/- 23 s) at approximately 200 microM EDTA. tau then decreases slightly to a minimum at approximately 1.3 mM and finally increases to infinity at approximately 10 mM EDTA. Between 0 and 1.3 mM EDTA, effects on clotting time are completely reversed by adding Ca2+ and, after equilibration at 400 microM EDTA, tau is independent of EDTA concentration. Thus, up to 400 microM EDTA, effects on clotting time are attributed to decreasing fibrinogen bound Ca2+. Between 5 mM Ca2+ and 200 microM EDTA it is assumed that an equilibrium distribution of fibrinogen species having 3, 2, 1, or 0 bound calcium ions is established and that a clotting time is determined by the sum of products of species fractional abundance and pure species clotting time. Analysis indicates that pure species clotting times increase proportionately with decreasing Ca2+ binding, binding sites are nearly independent, and the microscopic association constant for the first bound Ca2+ is approximately 4.9 X 10(6) M-1. Effects of adding Ca2+ at times t1 after thrombin addition to systems initially equilibrated at 200 microM EDTA were determined. Analysis of the relation between tau and t1 indicates that as Ca2+ binding decreases, rate constants for release of B peptides decrease less than those for release of A peptides. As EDTA concentration is increased above 1.3 mM, inhibitory effects of EDTA and CaEDTA progressively increase.     

Modulation of platelet activation by native DNA.

Native DNA (dsDNA) was found to induce the aggregation of isolated human platelets and the release of platelet 5HT; this activation was inhibited by both theophylline and TYA, suggesting a role for cAMP and metabolic products formed from arachidonate. By contrast, nonaggregating amounts of dsDNA inhibited platelet activation induced by collagen or thrombin. This inhibition, which could be overcome by use of greater amounts of the stimulatory agents, was not associated with the loss of platelet viability. Activation of platelets by dsDNA was not observed in plasma or in isolated platelet systems to which small amounts of cell-free plasma were added. However, dsDNA maintained in plasma its ability to inhibit platelet aggregation induced by collagen and thrombin. RNA and single-stranded DNA failed to induce platelet aggregation or release of 5HT and to block the platelet activation stimulated by dsDNA. Further, dsDNA did not significantly inhibit platelet aggregation in platelet-rich plasma stimulated by ADP or epinephrine. These data implicate dsDNA as a selective and potentially important activator and modulator of platelet responsiveness.     

Surface-governed molecular regulation of blood coagulation

Among extracellular biological processes the spatial control of blood clotting is a unique phenomenon. Localization in space has very important consequences in both normal and pathological conditions. Under physiological circumstances a clot is formed only in the vicinity of injury, albeit the prerequisites of coagulation are almost completely given in the whole circulation. The local character of blood clotting is secured by the following major conditions: The regulatory signal initiating coagulation-the damaged vascular wall-is itself a surface on which the majority of clotting reactions take place. The first enzyme, factor XII, of the intrinsic coagulation pathway is activated on the collagen fibers exposed in the damaged vascular wall, although the significance of this reaction in respect of the clotting process is ambiguous. On the membrane of platelets adhered to the damaged blood vessel is activated factor XI, too, which is a well-established participant of the intrinsic clotting process. The further consecutive reactions of coagulation are confined to the surface produced by injury, because the enzymes involved contain gamma-carboxyl-glutamyl side chains which are anchored through calcium bridges to the phospholipids of the platelet membrane. The last enzyme of the sequence is thrombin, which is released from the surface. The reactions taking place on the surface form an enzyme cascade, which amplifies the relatively weak triggering signal by several orders of magnitudes. Amplification is ensured not only by the enzyme-substrate relationship of the consecutive reaction partners, but also by spatial confinement, which endows the process with higher efficacy than could be expected on a statistical basis from reactions in solution. It contributes to the efficiency of enzyme cascade that the non-enzymatic regulatory proteins increase the activity of factors IXa and Xa, and thereby the overall process. While the partner of factor IXa, factor VIII, is captured from plasma, factor V, the partner of factor Xa, is derived from the platelets adhered to the damaged surface and orients the binding of factor Xa. The surface localization ensures the protection of the members of clotting system: In the activator complexes found on the surface, the spatial arrangement of clotting factors prevents the inactivation of factors by physiological inhibitors or by proteolytic enzymes and specific antibodies that appear in the circulation in pathological conditions. Platelet factor 4, derived from platelets, binds heparin and thereby markedly decreases the reactivity of antithrombin III, the physiological inhibitor of clotting factors. The above two circumstances are     

Meizothrombin formation during factor Xa-catalyzed prothrombin activation. Formation in a purified system and in plasma

Meizothrombin and thrombin formation were quantitated during factor Xa-catalyzed activation of human prothrombin in reaction systems containing purified proteins and in plasma. In the purified system considerable amounts of meizothrombin accumulated when prothrombin was activated by factor Xa (with or without accessory components) under initial steady state conditions. The ratio of the rates of meizothrombin and thrombin formation was not influenced by variation of the pH, temperature, or ionic strength of the reaction medium. When 2 microM prothrombin was activated by the complete prothrombinase complex (factor Xa, factor Va, Ca2+, and phospholipid) 80-90% of the initially formed reaction product was meizothrombin. Lowering the prothrombin concentration from 2 to 0.03 microM caused a gradual decrease in the ratio of meizothrombin/thrombin formation from 5 to 0.6. When the phosphatidylserine content of the phospholipid vesicles was varied between 20 and 1 mol % and prothrombin activation was analyzed at 2 microM prothrombin the relative amount of meizothrombin formed decreased from 85 to 55%. With platelets, cephalin, or thromboplastin as procoagulant lipid, thrombin was the major reaction product and only 30-40% of the activation product was meizothrombin. We also analyzed complete time courses of prothrombin activation both with purified proteins and in plasma. In reaction systems with purified proteins substantial amounts of meizothrombin accumulated under a wide variety of experimental conditions. However, little or no meizothrombin was detected in plasma in which coagulation was initiated via the extrinsic pathway with thromboplastin or via the intrinsic pathway with kaolin plus phospholipid (cephalin, platelets, or phosphatidylserine-containing vesicles). Thus, thrombin was the only active prothrombin activation product that accumulated during ex vivo coagulation experiments in plasma.     

Vitronectin is phosphorylated by a cAMP-dependent protein kinase released by activation of human platelets with thrombin

Activation of freshly isolated human platelets with a physiological stimulant (thrombin) causes them to release a cAMP-dependent protein kinase which specifically phosphorylates one plasma protein (Mr 75000). This protein is immunochemically and biochemically identified as vitronectin (also know as S protein), which was previously implicated in blood clotting, complement function and cell adhesion.