A Computer Assisted Method to Obtain the Prothrombin Activation Velocity in Whole Plasma Independent of Thrombin Decay Processes

A method is described that, on the basis of the time course of amidolytic activity after the triggering of thrombin generation in normal plasma, allows the calculation of the velocity of prothrombin conversion independent of thrombin inactivating processes.

It is shown how the reaction constants for the α2M-dependent and the α2M-independent thrombin inactivation processes can be obtained in a sample of whole plasma.

The method is verified by demonstrating that the experimentally observed time courses of residual prothrombin and of α2M-thrombin complex coincide with those calculated from the time course of amidolytic activity, and by showing that the course of prothrombin conversion in plasma without α2-macroglobulin or AT III is adequately described if the α2M or AT Ill-dependent breakdown constants are taken zero in the calculations.

It appears that the inactivation of thrombin, endogenously generated in whole plasma, is about half as fast as that of exogenous thrombin added to the plasma.

A computer program is presented that carries out the relevant calculations.

Kinetic Aspects of the Interaction of Blood Clotting Enzymes

It is shown that in a system where thrombin acts on fibrinogen, the clotting time can be used to assess coagulation velocity because clotting time and clotting velocity are inversely proportional.

Ragged spiking of free calcium in ADP-stimulated human platelets: regulation of puff-like calcium signals in vitro and ex vivo

1. Human platelets respond to agonists of G protein (G(q))-coupled receptors by generating an irregular pattern of spiking changes in cytosolic Ca2+ ([Ca2+]i). We have investigated the ADP-induced Ca2+ responses of single, Fluo-3-loaded platelets in the presence or absence of autologous plasma or whole blood under flow conditions. 2. In plasma-free platelets, incubated in buffer medium, baseline separated [Ca2+]i peaks always consisted of a rapid rising phase (median time 0.8 s) which was abruptly followed by a slower, mono-exponential decay phase. The decay constant differed from platelet to platelet, ranging from 0.23 +/- 0.02 to 0.63 +/- 0.03 s(-1) (mean +/- S.E.M., n = 3-5), and was used to identify individual Ca2+ release events and to determine the Ca2+ fluxes of the events. 3. Confocal, high-frequency measurements of adherent, spread platelets (diameter 3-5 microm) indicated that different optical regions had simultaneous patterns of both low- and high-amplitude Ca2+ release events. 4. With or without plasma or flowing blood, the ADP-induced Ca2+ signals in platelets had the characteristics of irregular Ca2+ puffs as well as more regular Ca2+ oscillations. Individual [Ca2+]i peaks varied in amplitude and peak-to-peak interval, as observed for separated Ca2+ puffs within larger cells. On the other hand, the peaks appeared to group into periods of ragged, shorter-interval Ca2+ release events with little integration, which were alternated with longer-interval events. 5. We conclude that the spiking Ca2+ signal generated in these small cells has the characteristics of a 'poor' oscillator with an irregular frequency being reactivated from period to period. This platelet signal appears to be similar in an environment of non-physiological buffer medium and in flowing, whole blood.

Purified protein S contains multimeric forms with increased APC-independent anticoagulant activity

Protein S, the cofactor of activated protein C (APC), also expresses anticoagulant activity independent of APC by directly inhibiting prothrombin activation via interactions with factor Xa, factor Va, and phospholipids. In different studies, however, large variations in APC-independent anticoagulant activities have been reported for protein S. The investigation presented here shows that within purified protein S preparations different forms of protein S are present, of which a hitherto unrecognized form (<5% of total protein S) binds with high affinity to phospholipid bilayers (K(d) < 1 nM). The remaining protein S (>95%) has a low affinity (K(d) = 250 nM) for phospholipids. Using their different affinities for phospholipids, separation of the forms of protein S was achieved. Native polyacrylamide gel electrophoresis demonstrated that the form of protein S that binds to phospholipids with low affinity migrated as a single band, whereas the high-affinity protein S exhibited several bands that migrated with reduced mobility. Size-exclusion chromatography revealed that the slower-migrating bands represented multimeric forms of protein S. Multimeric protein S (<5% of total protein S) appeared to have a 100-fold higher APC-independent anticoagulant activity than the abundant form of protein S. Comparison of purified protein S preparations that exhibited a 4-fold difference in APC-independent anticoagulant activity showed that the ability to inhibit prothrombin activation correlated with the content of multimeric protein S. Multimeric protein S could not be identified in normal human plasma, and it is therefore unlikely that this form of protein S contributes to the APC-independent anticoagulant activity of protein S that is observed in plasma.

Binding of annexin V to membrane products of lipid peroxidation

There is increasing evidence that endogenously generated aldehydes formed as a result of lipid peroxidation are involved in the pathophysiological effects associated with oxidative stress in cells and tissues. Malondialdehyde (MDA), a major product of lipid peroxidation, can modify amines present on the cell surface and thereby introduce negative charges that can affect the interfacial ionic layer. We show that lipid peroxidation of RBC generates MDA adducts that, similar to phosphatidylserine (PS), bind annexin V in a Ca(2+)-dependent manner. Like PS, these adducts also promote the "PS-dependent" prothrombinase assays, albeit to lower levels. These results indicate that annexin V binding cannot be used as an exclusive indicator of cell surface PS and raise the possibility that some phenomenon attributed to PS may, in fact, also involve aldehyde-lipid adducts.

Complexes of anti-prothrombin antibodies and prothrombin cause lupus anticoagulant activity by competing with the binding of clotting factors for catalytic phospholipid surfaces

We investigated the mechanism by which anti-prothrombin antibodies cause lupus anticoagulant (LAC) activity. Addition of affinity-purified anti-prothrombin antibodies from LAC-positive plasma samples (alpha-FII-LAC+) to normal plasma induced LAC activity. Upon increasing the phospholipid concentration, LAC activity was neutralized. Addition of purified alpha-FII-LAC+ to normal plasma strongly inhibited factor Xa formation. No inhibition was measured when alpha-FII-LAC+ were added to prothrombin-deficient plasma or when purified anti-prothrombin antibodies from LAC-negative plasma samples (alpha-FII-LAC-) were added. When a combination of prothrombin and alpha-FII-LAC+ was added to the purified clotting complex, a strong inhibition of factor Xa and IIa formation was seen. The alpha-FII-LAC+ alone or a combination of prothrombin and alpha-FII-LAC- did not show inhibition. Ellipsometry studies showed that, in the presence of alpha-FII-LAC+, the affinity of prothrombin for a phospholipid surface increased dramatically, whereas a much lower increase was observed with alpha-FII-LAC-. Our results show that complexes of prothrombin and anti-prothrombin antibodies with LAC activity inhibit both prothrombinase and tenase. The antibodies increase the affinity of prothrombin for the phospholipid surface, thereby competing with clotting factors for the available catalytic phospholipid surface, a mechanism similar to that of anti-beta2-glycoprotein I antibodies.

Regulation of platelet factor Va-dependent thrombin generation by activated protein C at the surface of collagen-adherent platelets

Recent studies have indicated that factor Va bound to activated platelets is partially protected from inactivation by activated protein C (APC). To explore whether this sustained factor Va activity could maintain ongoing thrombin generation, the kinetics of platelet factor Va-dependent prothrombinase activity and its inhibition by APC were studied. In an attempt to mimic physiologically relevant conditions, platelets were adhered to collagen type I-coated discs. These discs were then spun in solutions containing prothrombin and factor Xa either in the absence or presence of APC. The experiments were performed in the absence of platelet-derived microparticles, with thrombin generation and inhibition confined to the surface of the adherent platelets. APC completely inactivated platelet-associated prothrombinase activity with an overall second order rate constant of 3.3 x 10(6) m(-)1 s(-)1, which was independent of the prothrombin concentration over a wide range around the apparent K(m) for prothrombin. Kinetic studies on prothrombinase assembled at a planar phospholipid membrane composed of 25 mol % phosphatidylserine and 75 mol % phosphatidylcholine revealed a similar second order rate constant of inhibition (2.5 x 10(6) m(-1) s(-1)). Collectively, these data demonstrate that ongoing platelet factor Va-dependent thrombin generation at the surface of collagen-adherent platelets is effectively inhibited by APC. No differences were observed between the kinetics of APC inactivation of plasma-derived factor Va or platelet factor Va as part of the prothrombinase associated with, respectively, a planar membrane of synthetic phospholipids or collagen-adherent platelets.

Antibodies to beta2-glycoprotein I associated with antiphospholipid syndrome suppress the inhibitory activity of tissue factor pathway inhibitor

Anionic phospholipid membranes have a dual role in blood coagulation: they are essential for the initiation and propagation as well as for the limitation and termination of the blood coagulation process. Patients with the anti-phospholipid syndrome (APS) carrying antibodies against complexes of anionic phospholipids and plasma proteins, show in vitro inhibited phospholipid dependent coagulation reactions, whereas in vivo the presence of these antibodies is associated with an increased risk of thrombosis. In this study we focussed on the effects of these anti-phospholipid antibodies on the regulation of TF-mediated factor Xa (FXa) generation in plasma. We hypothesized that anti-phospholipid antibodies interfere with the phospholipid-dependent inhibition by tissue factor pathway inhibitor (TFPI) of TF-induced coagulation. Indeed, total-IgG, anti-cardiolipin-IgG (aCL) and anti-beta2GPI-IgG, isolated from patient plasmas, all stimulated TF-induced FXa generation in normal plasma. This enhanced FXa generation was not observed when the patient's IgG was depleted of anti-beta2GPI-IgG or when normal plasma was depleted of beta2PGPI or TFPI. Taken together, these data indicate that antibodies to beta2GPI, circulating in patients with APS, suppress TFPI-dependent inhibition of TF-induced coagulation, which results in an increased FXa generation.

Competition of annexin V and anticardiolipin antibodies for binding to phosphatidylserine containing membranes

Annexin V, an intracellular protein with a calcium-dependent high affinity for anionic phospholipid membranes, acts as an inhibitor of lipid-dependent reactions of the blood coagulation. Antiphospholipid antibodies found in the plasma of patients with antiphospholipid syndrome generally do not interact with phospholipid membranes directly, but recognize (plasma) proteins associated with lipid membranes, mostly prothrombin or beta(2)-glycoprotein I (beta(2)GPI). Previously, it has been proposed that antiphospholipid antibodies may cause thrombosis by displacing annexin V from procoagulant cell surfaces. We used ellipsometry to study the binding of annexin V and of complexes of beta(2)GPI with patient-derived IgG antibodies to beta(2)GPI, commonly referred to as anticardiolipin antibodies (ACA), to phospholipid bilayers composed of phosphatidylcholine (PC) and 20% phosphatidylserine (PS). More specifically, we investigated the competition of these proteins for the binding sites at these bilayers. We show that ACA-beta(2)GPI complexes, adsorbed to PSPC bilayers, are displaced for more than 70% by annexin V and that annexin V binding is unaffected by the presence of ACA-beta(2)GPI complexes. Conversely, annexin V preadsorbed to these bilayers completely prevents adsorption of ACA-beta(2)GPI complexes, and none of the preadsorbed annexin V is displaced by ACA-beta(2)GPI complexes. Using ellipsometry, we also studied the effect of ACA-beta(2)GPI complexes on the interaction of annexin V with the membranes of ionophore-activated blood platelets as a more physiological relevant model of cell membranes. The experiments with blood platelets confirm the high-affinity binding of annexin V to these membranes and unequivocally show that annexin V binding is unaffected by the presence of ACA-beta(2)GPI. In conclusion, our data unambiguously show that ACA-beta(2)GPI complexes are unable to displace annexin V from procoagulant membranes to any significant extent, whereas annexin V does displace the majority of preadsorbed ACA-beta(2)GPI complexes from these membranes.

Inhibition of Tissue Factor-Factor VIIa-catalyzed Factor X Activation by Factor Xa-Tissue Factor Pathway Inhibitor

The physiological inhibitor of tissue factor (TF).factor VIIa (FVIIa), full-length tissue factor pathway inhibitor (TFPI(FL)) in complex with factor Xa (FXa), has a high affinity for anionic phospholipid membranes. The role of anionic phospholipids in the inhibition of TF.FVIIa-catalyzed FX activation was investigated. FXa generation at a rotating disc coated with TF embedded in a membrane composed of pure phosphatidylcholine (TF.PC) or 25% phosphatidylserine and 75% phosphatidylcholine (TF.PSPC) was measured in the presence of preformed complexes of FXa.TFPI(FL) or FXa.TFPI(1-161) (TFPI lacking the third Kunitz domain and C terminus). At TF.PC, FXa.TFPI(FL) and FXa.TFPI(1-161) showed similar rate constants of inhibition (0.07 x 10(8) M(-1) s(-1) and 0.1 x 10(8) M(-1) s(-1), respectively). With phosphatidylserine present, the rate constant of inhibition for FXa.TFPI(FL) increased 3-fold compared with a 9-fold increase in the rate constant for FXa. TFPI(1-161). Incubation of TF.PSPC with FXa.TFPI(FL) in the absence of FVIIa followed by depletion of solution FXa.TFPI(FL) showed that FXa.TFPI(FL) remained bound at the membrane and pursued its inhibitory activity. This was not observed with FXa.TFPI(1-161) or at TF.PC membranes. These data suggest that the membrane-bound pool of FXa.TFPI(FL) may be of physiological importance in an on-site regulation of TF.FVIIa activity.

Factor Xa cleavage of tissue factor pathway inhibitor is associated with loss of anticoagulant activity

Tissue factor:factor VIIa induced activation of blood coagulation is inhibited by the complex between factor Xa and tissue factor pathway inhibitor (factor Xa:TFPI). We recently reported that phospholipid-bound factor Xa reduces the high binding affinity of factor Xa:TFPI for negatively charged phospholipids by a partial degradation of TFPI (17). The present study was undertaken to elucidate the factor Xa cleavage sites in TFPI and to delineate the consequences of this proteolysis with respect to the inhibitory activity of factor Xa:TFPI. We found that phospholipid-bound factor Xa cleaves in TFPI the peptide bonds between Lys86-Thr87 and Argl99-Ala200. Interestingly, Arg199 is the P1 residue of the third Kunitz-type protease inhibitor domain. The fast cleavage of the Arg199-Ala200 bond results in a 50-70% reduction of the anticoagulant activity of factor Xa:TFPI, as determined with a dilute tissue factor assay, but is not associated with a diminished inhibitory activity of factor Xa:TFPI towards TF:factor VIIa catalyzed activation of factor X. On the other hand, the slower cleavage of the Lys86-Thr87 peptide bond was associated with both a diminished anticoagulant and anti-TF:factor VIIa activity. Dissociation of factor Xa from the cleaved TFPI was not observed. These data provide evidence for a dual role of factor Xa since it is the essential cofactor in the TFPI-controlled regulation of TF-dependent coagulation as well as a catalyst of the inactivation of TFPI.

Adsorption of proteins onto poly(ether urethane) with a phosphorylcholine moiety and influence of preadsorbed phospholipid

In a previous report we demonstrated that the blood compatibility of poly(ether urethane) (PEU) was improved by grafting phosphorylcholine (PC) groups on the surface. The improved blood compatibility was indicated by decreased platelet adsorption/activation and reduced thrombin formation at the polymer surface in experiments in which the surfaces were contacted with platelet-rich plasma in vitro. In the present study, we investigated the effect of grafted PC groups at a PEU surface on protein and phospholipid adsorption. Adsorption of human fibrinogen (Fg), human serum albumin (Alb), human high-molecular-weight kininogen (HMWK), and dioleoyl phosphatidylcholine (DOPC) vesicles was measured by ellipsometry. For this purpose, thin PEU films were cast on silicon wafers. The polymer film was photochemically modified with a PC-containing aryl azide. The presence of PC groups on the polymer surface was demonstrated by ESCA (Electron Spectroscopy for Chemical Analysis). The hydrophilicity of the polymer surface increased by the surface modification, as indicated by a decrease of the contact angle from 59 degrees before to 43 degrees after modification. Our data show that the presence of PC groups has little effect on the adsorption of proteins to a PEU surface. The highest adsorption was observed for Fg (0.49 microgram/cm2 on PC-modified PEU and 0.50 microgram/cm2 on PEU), followed by HMWK (0.28 microgram/cm2 on both PC-modified PEU and PEU), and Alb (0.16 microgram/cm2 on PC-modified PEU and 0.18 microgram/cm2 on PEU). Protein adsorption was further studied on a "biomembrane-like" DOPC bilayer formed on hydrophilic silicon. We found no protein adsorption on this DOPC bilayer. The adsorption of small unilamellar DOPC vesicles on the polymer surfaces amounted to about 0.06 microgram/cm2 (corresponding to circa 30% of monolayer coverage) and was similar for PC-modified PEU and PEU. Despite this partial surface coverage, preadsorbed DOPC on the polymer surface diminished the subsequent adsorption of proteins considerably. These results show that the mere presence of phosphorylcholine groups on a PEU surface is insufficient to suppress protein adsorption. The highly ordered structure of natural phospholipid bilayers seems to be required to suppress protein adsorption effectively.

Transient high affinity binding of tissue factor pathway inhibitor-factor Xa complexes to negatively charged phospholipid membranes

The interaction of tissue factor pathway inhibitor (TFPI), factor Xa, and TFPI-factor Xa complexes with negatively charged phospholipid membranes composed of 25 mol % phosphatidylserine and 75 mol % phosphatidylcholine was studied by ellipsometry. The binding of TFPI alone was negligible; factor Xa bound with moderate affinity, with a dissociation constant Kd = 42 nM. Formation of the TFPI-factor Xa complex drastically enhanced the affinity for phospholipid membranes, Kd = 5 nM, compared to that of either protein alone. TFPI1-161, a TFPI variant lacking the third Kunitz domain and the positively charged C-terminus did not enhance binding affinity of the factor Xa. Analysis of the kinetics of adsorption and desorption confirmed the equilibrium binding data, although upon longer residence at the lipid membrane the desorption rate of TFPI-factor Xa complexes became slower, indicating an increase in affinity with longer residence of the TFPI-factor Xa complexes at the membrane. In contrast, binding of TFPI-factor Xa complexes in the presence of an excess factor Xa was transient; maximal binding is followed by a slow desorption of the complex. Immunoblot analysis revealed that this desorption was accompanied with cleavage of TFPI by membrane-bound factor Xa. Collectively, our results show that phosphatidylserine containing membranes will accumulate tightly bound TFPI-factor Xa complexes, and that uncomplexed, phospholipid-bound, factor Xa, will cause limited proteolysis of TFPI accompanied by simultaneous release of these complexes from the phospholipid membrane.

Initiation and propagation of blood coagulation at artificial surfaces studied in a capillary flow reactor

We have made use of a novel flow reactor to study the initiation and propagation of the ex vivo blood coagulation processes at artificial surfaces. The flow reactor consisted of a primary glass or polymer capillary that is connected to a secondary glass capillary, which inner wall was coated with a phospholipid bilayer of 25 mol% dioleoylphosphatidylserine/75 mol% dioleoylphosphatidylcholine (DOPS/DOPC). Citrated platelet free plasma and a CaCl2 solution were delivered by syringe pumps and mixed just before the entrance of the flow reactor. The outflowing plasma was assayed for factor XIa, factor IXa, factor Xa and thrombin activity. Perfusion of recalcified plasma through a bare glass capillary resulted in a transient generation of fluid phase factor XIa. In contrast, factor IXa production increased slowly to attain a stable steady-state level. We established that surface-bound factor XIa was responsible for a continuous production of factor IXa. Factor IXa-induced generation of factor Xa and thrombin was only observed when contact activated plasma was subsequently perfused through a DOPS/DOPC-coated capillary, showing that propagation of the factor IXa trigger requires a procoagulant, phosphatidylserine-containing, phospholipid membrane. The negatively charged inner surface of a heparin-coated polyurethane capillary, generated like the glass capillary significant amounts of factor XIa and factor IXa when perfused with recalcified plasma. No differences were found between unfractionated heparin and heparin devoid of anticoagulant activity. Thus, it is concluded that contact activation and factor IXa generation in flowing plasma is not inhibited by immobilised anticoagulant active heparin. Consequently, factor IXa-dependent thrombin generation at a downstream located phospholipid membrane was similar, regardless the specific anticoagulant activity of immobilised heparin.

Activation of blood coagulation at heparin-coated surfaces

It is hypothesized that immobilized heparin exerts a dual role in blood coagulation. On the one hand, the heparinized surface is because of its dense negative charge, thought to initiate the intrinsic pathway of blood coagulation. On the other hand, heparin is known as a potent anticoagulant drug. However, it remains to be seen how much contact-phase activation of factor XI contributes to thrombin formation and how this process is counterbalanced by which of the anti-protease activities of immobilized heparin. In the present study we examined the generation of factors XIa, IXa, and Xa, and thrombin in recalcified normal and antithrombin-depleted plasma exposed to polyacrylamide-graft polyurethane (PU) sheets modified by multipoint attachment of two different heparin species. One of them, HAH, contained the specific antithrombin binding sequence and the other one, NAH, had a low affinity for antithrombin and had no anticoagulant activity. Our data demonstrate that in contrast to PU, PU-NAH and PU-HAH are strong mediators of factor XIa and factor IXa formation in normal and antithrombin-deficient plasma. Interestingly, compared to PU-HAH and PU-NAH, thrombin formation was only slightly diminished in antithrombin-deficient plasma exposed to PU. In contrast, thrombin formation was dramatically delayed and diminished in normal plasma exposed to PU-HAH. These findings indicate that very low amounts of factor XIa apparently suffice to induce significant amounts of thrombin. In this sense, heparinized surfaces are highly thrombogenic, but our data also indicate that this activity is effectively counterbalanced by the anti-thrombin activity of the immobilized anti-coagulant species of heparin.

Prothrombinase is protected from inactivation by tissue factor pathway inhibitor: competition between prothrombin and inhibitor

The inhibition of prothrombinase by tissue factor pathway inhibitor (TFPI) has been studied in the presence and absence of prothrombin. The rate constant of association of prothrombinase with full-length TFPI was 2.1x10(7) M-1.s-1 and 0.05x10(7) M-1.s-1 for the reaction with C-terminus truncated TFPI (TFPI1-161). The rate constant of dissociation was 0.65x10(-4) s-1 in both cases. The rate constant of inhibition of prothrombinase by TFPI1-161 was similar to that of solution-phase factor Xa. In contrast, phospholipids and factor Va enhanced the association rate of the reaction between factor Xa and full-length TFPI by approx. 20-fold. Although TFPI, and in particular the full-length variant of the molecule, is a potent inhibitor of prothrombinase (overall inhibition constant of 3 pM), we also found that prothrombin competed very effectively with TFPI for the active site of factor Xa in the prothrombinase complex. A 50% reduction of the rate constant of inhibition was measured in the presence of 4 nM prothrombin, i.e. 0.2% of the plasma concentration of prothrombin. The physiological significance of TFPI as an inhibitor of prothrombinase activity is thus questionable.

Role of divalency in the high-affinity binding of anticardiolipin antibody-beta 2-glycoprotein I complexes to lipid membranes

beta 2-Glycoprotein I (beta 2GPI) is an essential cofactor for the binding to lipids of anticardiolipin antibodies (ACA), isolated from patients with anti-phospholipid syndrome. We used ellipsometry to study the binding of beta 2GPI and the beta 2GPI-mediated binding of ACA to planar membranes composed of phosphatidylcholine (PC) and 5-20 mol % phosphatidylserine (PS). No binding of beta 2GPI was observed to neutral (PC) membranes. Maximal binding of beta 2GPI was 3.2-3.6 pmol.cm-2. Affinity decreased strongly with decreasing PS content; increasing the NaCl and CaCl2 concentrations also led to a decrease in affinity. At physiologic conditions (10 mol % PS, 120 mM NaCl, and 3 mM CaCl2), a Kd of 14 microM was observed. Binding constants were insensitive to the chemical composition of the negatively charged phospholipid headgroup. ACA (1.25-10 micrograms.mL-1) caused a 30-40-fold enhancement of beta 2GPI binding to PS/PC membranes (20 mol % PS), resulting in the binding of about 2 pmol.cm-2 divalent ACA-(beta 2GPI)2 complexes at 100 nM beta 2GPI. In the absence of beta 2GPI, binding of ACA was negligible. Ad- and desorption kinetics of ACA-beta 2GPI complexes indicate that the initial monovalent association of ACA to membrane-bound beta 2GPI is rapidly followed by formation of divalent ACA-(beta 2GPI)2 complexes. Experiments with monovalent Fab1 fragments of ACA showed no appreciable effect on the beta 2GPI binding to lipid, substantiating the notion that divalent interactions are essential for the high-affinity binding of ACA-beta 2GPI. The anticoagulant effect of ACA is rationalized by the observation that binding of ACA-beta 2GPI complexes to the PSPC membrane severely restricts the adsorption of blood coagulation factor Xa.

Tissue factor pathway inhibitor: regulation of its inhibitory activity by phospholipid surfaces

The basic C-terminus of Tissue Factor Pathway Inhibitor (TFPI) appears to be essential for its anticoagulant activity when tested in a diluted thromboplastin prothrombin time assay. Although the data reported so far have increased our knowledge about the C-terminus as a major binding site for heparin, lipoproteins and phospholipids, it is still unclear how this region of TFPI plays a role in its anticoagulant mode of action. We earlier reported that in the presence of phospholipid the rate of association of factor Xa with full length TFPI (FL-TFPI) is about 10-fold faster than with C-terminus truncated TFPI. This in turn makes that, in vitro, full length TFPI is a more potent inhibitor of tissue factor-factor VIIa catalyzed factor X activation than truncated TFPI. Binding studies, utilizing an ellipsometer, revealed that in contrast to the complex of C-terminus truncated TFPI (TFPI1-161) and factor Xa, the FL-TFPI.factor Xa complex has a high affinity for negatively charged phospholipids. However, when examined in a tubular flow reactor containing tissue factor embedded in a phospholipid bilayer composed of 25 mol% phosphatidyl-serine/75 mol% phosphatidylcholine, no differences in the potency of FL-TFPI and TFPI1-161 to inhibit factor X activation were found. The two variants of TFPI did show an interesting difference though. We found that the quaternary complex of TF.factor VIIa.FL-TFPI.factor Xa was much more stable than the complex containing TFPI1-161. This difference could not be attributed to their different phospholipid-binding properties since the same difference in stability was found on membranes that contained only DOPC.

Kinetics of factor VIII-von Willebrand factor association

The binding of factor VIII to von Willebrand factor (vWF) is essential for the protection of factor VIII against proteolytic degradation in plasma. We have characterized the binding kinetics of human factor VIII with vWF using a centrifugation binding assay. Purified or plasma vWF was immobilized with a monoclonal antibody (MoAb RU1) covalently linked to Sepharose (Pharmacia LKB Biotechnology, Uppsala, Sweden). Factor VIII was incubated with vWF-RU1-Sepharose and unbound factor VIII was separated from bound factor VIII by centrifugation. The amount of bound factor VIII was determined from the decrease of factor VIII activity in the supernatant. Factor VIII binding to vWF-RU1-Sepharose conformed to the Langmuir model for independent binding sites with a Kd of 0.46 +/- 0.12 nmol/L, and a stoichiometry of 1.3 factor VIII molecules per vWF monomer at saturation, suggesting that each vWF subunit contains a binding site for factor VIII. Competition experiments were performed with a recombinant vWF (deltaA2-rvWF), lacking residues 730 to 910 which contain the epitope for MoAB RU1. DeltaA2-rvWF effectively displaced previously bound factor VIII, confirming that factor VIII binding to vWF-RU1-Sepharose was reversible. To determine the association rate constant (k(on)) and the dissociation rate constant (k(off)), factor VIII was incubated with vWF-RU1-Sepharose for various time intervals. The observed association kinetics conformed to a simple bimolecular association reaction with k(on) = 5.9 +/- 1.9 x 10(6) M(-1) s(-1) and k(off) = 1.6 +/- 1.2 x 10(-3) s(-1) (mean +/- SD). Similar values were obtained from the dissociation kinetics measured after dilution of preformed factor VIII-vWF-RU1-Sepharose complexes. Identical rate constants were obtained for factor VIII binding to vWF from normal pooled plasma and to vWF from plasma of patients with hemophilia A. The kinetic parameters in this report allow estimation of the time needed for complex formation in vivo in healthy individuals and in patients with hemophilia A, in which monoclonally purified or recombinant factor VIII associates with endogenous vWF. Using the plasma concentration of vWF (50 nmol/L in monomers) and the obtained values for K(on) and K(off), the time needed to bind 50% of factor VIII is approximately 2 seconds.

Prothrombin contributes to the assembly of the factor Va-factor Xa complex at phosphatidylserine-containing phospholipid membranes

The activation of prothrombin is catalyzed by prothrombinase, a complex of factor Xa and factor Va assembled on a negatively charged phospholipid membrane. We used a tubular flow reactor to identify the relative contributions of factor Va, prothrombin, and the negatively charged phosphatidylserine to the assembly of prothrombinase. Perfusion of phospholipid-coated capillaries with a mixture of factor Xa, factor Va, and prothrombin resulted in a steady-state rate of thrombin production that increased with (i) the phosphatidylserine content of the phospholipid bilayer, (ii) the factor Va concentration, and, most interestingly, (iii) the prothrombin concentration of the perfusion solution. Incorporation of 20 mol % phosphoatidylethanolamine, a phospholipid with poor ability to promote prothrombinase activity, into a 5 mol % phosphatidylserine membrane also increased the steady-state rate of thrombin production. Direct measurements of the amount of prothrombinase in the flow reactor demonstrated that increased catalytic activities were the result of an increased steady-state amount of membrane-associated prothrombinase. Thus, similar turnover numbers of prothrombin activation (3100 min-1) were calculated, irrespective of the phosphatidylserine content of the membrane. We established for membranes with low phosphatidylserine content (< 10 mol%) a linear relationship between the prothrombinase activity and the arithematical product of the factor Va concentration in the perfusion solution and the prothrombin concentration near the catalytic surface. Our results indicate that, in addition to factor Va, prothrombin also is essential to the assembly of prothrombinase at macroscopic surfaces with low phosphatidylserine content. The data further suggest that the prothrombin concentration near the surface, controlled by the prothrombinase activity and mass transfer, is an important regulator of the prothrombinase surface density.

Inhibition of prothrombinase at macroscopic lipid membranes: competition between antithrombin and prothrombin

The kinetics of inhibition of prothrombinase during prothrombin conversion by antithrombin and antithrombin-heparin complexes was studied in a tubular flow reactor. Prothrombinase was assembled at a macroscopic phospholipid membrane, composed of 25 mol % phosphatidylserine and 75 mol % phosphatidylcholine, deposited on the inner wall of a glass capillary, by perfusion with a factor Xa-factor Va mixture. Measurement of thrombin production allowed estimation of the amount of prothrombinase present at the capillary wall. Perfusion with a mixture of prothrombin and antithrombin or antithrombin-heparin complexes caused a progressive decline of the prothrombinase activity. The rate of inactivation steeply decreased with increasing prothrombin concentrations, indicating competitive inhibition. Analysis of competitive inhibition data requires estimation of the time-dependent substrate concentration, Co, near the prothrombin converting surface using earlier developed transport theory [Billy, D., et al. (1995) J. Biol. Chem. 270, 1029-1034]. It appears that the inhibition rate is proportional to the fraction of enzyme, Km/(Km+Co), not occupied by substrate. The value of Km of prothrombinase estimated from the dependence of the inhibition rate on the prothrombin concentration (Km = 2-3 nM) is in excellent agreement with the value estimated from the substrate conversion rate (Km = 3 nM). Therefore inhibition of prothrombinase by antithrombin and antithrombin-heparin complexes is fully competitive with the substrate: prothrombin. Our results show that prothrombinase assembled on macroscopic lipid surfaces by virtue of its low Km value is protected for inhibition due to highly effective competition of prothrombin with antithrombin for the active site of factor Xa.

Antithrombin activity of surface-bound heparin studied under flow conditions

Polyacrylamide-grafted polyetherurethane sheets were modified by end-point and multipoint attachment of heparin. The surface-bound heparin was firmly attached. No release of heparin activity could be detected when the surface was rinsed at a wall shear rate of 2000 s-1. Uptake of antithrombin and thrombin inactivation were investigated under well-defined flow conditions by the use of a spinning device with an attached disk-shaped heparinized surface. It is demonstrated that the rate of thrombin inactivation at the antithrombin-heparin surface equals the maximal rate of transport of thrombin toward the surface when the surface coverage of antithrombin exceeds 10 pmol/cm2. This result indicates that a higher intrinsic catalytic efficiency of a surface does not necessarily result in a higher antithrombin activity. We varied the heparin content of the surfaces between 0 and 35 micrograms/cm2 by increasing the number of functional groups to which heparin could be covalently attached. The uptake of antithrombin increased with the heparin content of the surface, but the stoichiometry decreased from 2 to 0.5 pmol antithrombin/micrograms heparin. Apparently, antithrombin could not bind to heparins buried in the poly(acrylamide) layer. The rate of thrombin inactivation at surfaces with low heparin content (2 micrograms/cm2) fells below the transport limit of thrombin and became proportional with the heparin content of the surface. Although the contribution of surface-bound heparin to the neutralization of fluid-phase thrombin was found to be negligible compared with the effect of fluid-phase antithrombin at physiologic relevant concentrations, these heparinized surfaces markedly delayed the onset of thrombin generation in platelet-rich plasma.(ABSTRACT TRUNCATED AT 250 WORDS)

Binding of blood coagulation factor VIII and its light chain to phosphatidylserine/phosphatidylcholine bilayers as measured by ellipsometry

Factor VIII is a plasma protein which plays an essential role in the coagulation system. When assembled with the enzyme Factor IXa on a phospholipid membrane, it functions as a cofactor in the enzyme complex that cleaves the zymogen Factor X to Factor Xa. We studied the binding of both Factor VIII and the Factor VIII light chain to planar phospholipid bilayers consisting of 25% dioleoylphosphatidylserine and 75% dioleoylphosphatidylcholine (PSPC) by ellipsometry. Equilibrium-binding studies revealed that both Factor VIII and its light chain bind with high affinity to PSPC bilayers. The binding affinity of Factor VIII, with a dissociation constant Kd of 0.24 nM, was comparable with that of the Factor VIII light chain (Kd 0.49 nM). Maximal binding was 2.3 mmol of protein per mol of PSPC for Factor VIII and 7.1 mmol of protein per mol of PSPC for the Factor VIII light chain. Adsorption kinetics of both Factor VIII and its light chain conformed to the classical Langmuir adsorption model yielding dissociation constants calculated from the rates of adsorption that were similar to those obtained by equilibrium-binding studies. In contrast, measurements of rates of desorption revealed a deviation from those expected for a single class of binding sites. The desorption rate of Factor VIII increased with increasing residence time on the lipid membrane. This indicates transition of Factor VIII to a configuration with a lower binding affinity. As this time-dependent change in affinity could affect the validity of the measurement of binding parameters, in particular equilibrium-binding determinations carried out on a long timescale, binding affinity was also estimated from adsorption kinetics at half-maximal surface coverage, a relatively rapid procedure for the determination of the affinity. A Kd of 0.087 nM was obtained under these conditions. Measurement of equilibrium binding to small PSPC vesicles, a system in which equilibrium is rapidly attained, resulted in similar binding parameters (Kd = 0.13 nM and a maximal binding of 2.8 mmol of protein per mol of PSPC). These data confirm the results of equilibrium binding to planar bilayers. Taken together, our results indicate that Factor VIII, by means of its 80 kDa light chain, binds to PSPC bilayers with a dissociation constant below the concentration of Factor VIII in plasma and therefore may readily bind to exposed phospholipid membranes under physiological conditions.

Assembly of the prothrombinase complex on lipid vesicles depends on the stereochemical configuration of the polar headgroup of phosphatidylserine

The conversion of prothrombin into thrombin is an imperative step in the sequence of reactions leading to the formation of a hemostatic plug. This reaction is catalyzed by the prothrombinase complex, composed of factors Xa and Va, which is assembled on a phospholipid surface through Ca-mediated interactions with the lipid polar headgroups. In this paper we describe experiments indicative for a major role of the stereochemical configuration of phosphatidylserine in the binding of the prothrombinase complex to a phospholipid surface. Using two stereoisomers of phosphatidylserine, i.e., L-alpha-glycerophosphoryl-L-serine (PLS) and L-alpha-glycerophosphoryl-D-serine (PDS), we demonstrate that membranes containing PLS are appreciably more favorable than membranes containing PDS in promoting assembly of the prothrombinase complex and catalysis of prothrombin conversion. Ellipsometric analysis of the binding of factor Va and factor Xa to a surface composed of phosphatidylcholine and 10 mol % of either PLS or PDS reveals that the apparent Kd for factor Va increases about 25-fold when substituting PDS for PLS. For factor Xa a 5-fold increase in Kd was observed on replacing PDS for PLS. When PLS is replaced by phosphatidyl-beta-lactate (PLac), a phospholipid resembling PS but lacking the amino group, a similar decrease in prothrombinase activity is found as observed with PDS, implicating the importance of both the amino group and the stereoconfiguration of the serine moiety for the assembly of the prothrombinase complex.(ABSTRACT TRUNCATED AT 250 WORDS)

Short-term effects of early intravenous treatment with a beta-adrenergic blocking agent or a specific bradycardiac agent in patients with acute myocardial infarction receiving thrombolytic therapy

OBJECTIVES

This study was conducted to explore mechanisms that could explain the possible clinical benefit of early administration of a beta 1-selective adrenoreceptor blocking agent or a bradycardiac drug as adjunct to thrombolysis in acute myocardial infarction.

BACKGROUND

The effects of beta-blockers given concomitantly with thrombolytic therapy in patients with acute myocardial infarction have not been fully examined. The potential role of specific bradycardiac agents lacking negative inotropism as an alternative to beta-blockers in this setting has never been studied in humans.

METHODS

In a double-blind study, we examined the effects of early intravenous and continued oral administration of a beta-blocker (atenolol), a specific bradycardiac agent (alinidine) or placebo on left ventricular function, late coronary artery patency, infarct size, exercise capacity and incidence of arrhythmias.

RESULTS

A total of 292 patients with acute myocardial infarction of < or = 5 h duration and without contraindications to thrombolytic or beta-blocker therapy were studied. Of these, 100 were allocated to treatment with atenolol (5 to 10 mg intravenously followed by 25 to 50 mg orally every 12 h), 98 to alinidine (20 to 40 mg intravenously followed by 20 to 40 mg orally every 8 h) and 94 to placebo. All patients received 100 mg of alteplase over 3 h and full intravenous heparinization. No significant differences in coronary artery patency, global ejection fraction or regional wall motion were observed at 10 to 14 days among the three groups. Likewise, enzymatic and scintigraphic infarct size were also very similar. Neither atenolol nor alinidine was associated with a significant reduction in the incidence of arrhythmias during the 1st 24 h. No significant differences in clinical events were observed, with the exception of a greater incidence of nonfatal pulmonary edema in the atenolol group (6% vs. 1% in the alinidine group and 0% in the placebo group, p = 0.021).

CONCLUSIONS

In the absence of contraindications, the administration of a beta-blocker or a specific bradycardiac agent together with thrombolytic therapy was safe. In this limited number of patients, these agents did not appear to enhance myocardial salvage or preservation of left ventricular function or to reduce the incidence of major arrhythmias in the early phase of infarction.

Adsorption and conversion of prothrombin on a rotating disc

In most flow systems, the rate of protein transfer from bulk solution to a macroscopic surface is site-dependent. In studies on surface-mediated protein conversion, this hampers the comparison of a proposed expression for the conversion process, such as the Michaelis-Menten equation, which actually measured overall conversion rates. However, the rotating disc is a classical example of a uniformly accessible surface and therefore was used for a quantitative analysis of prothrombin conversion by the phospholipid-bound factor Xa/factor Va complex (prothrombinase complex). A simple design of a rotating disc, adapted for ellipsometric measurement of protein adsorption, is presented. Agreement between experiment and theory was obtained for the influence of rotation velocity on the initial, transport-limited, adsorption rates of lysozyme, prothrombin, and fibrinogen. After coverage of the disc with a 20% phosphatidylserine/80% phosphatidylcholine bilayer and preadsorption of factor Va, addition of excess factor Xa and prothrombin resulted in effective conversion of prothrombin. For high (10 fmol.cm-2) surface coverage of prothrombinase, the rate of conversion equals the transport limited adsorption rate of prothrombin. For low (0.1 to 0.5 fmol.cm-2) surface concentrations of prothrombinase, the conversion rate dropped below the transport limit and the intrinsic kinetic parameters could be estimated at Km = 7.1 +/- 1.2 nM and kcat = 25 +/- 1.0 s-1 (20 degrees C). At these low surface activities of prothrombinase, the effect of the rotation rate (6 to 225 rad.s-1) on prothrombin conversion could be explained by the rotation-rate dependent prothrombin transport. This indicates that the fluid shear rate has no drastic influence on the intrinsic kinetics of prothrombin conversion.

Aggregation of phospholipid vesicles by a chimeric protein with the N-terminus of annexin I and the core of annexin V

A chimeric protein was produced with the N-terminal domain (amino acids 1-45) of annexin I and the core of annexin V (amino acids 19-320). This protein, annexin IN-VC, has a similar Ca2+ requirement for binding to phospholipid bilayers of 20% phosphatidylserine (PS)/80% phosphatidylcholine (PC) as annexin V. In contrast to annexin V, this protein has a strong potency to aggregate phospholipid vesicles as is shown by turbidimetric measurements and cryo-electron microscopy. Ellipsometry was employed to study quantitatively the phenomenon of phospholipid vesicle adhesion to annexin IN-VC bound to a planar phospholipid bilayer. The amount of phospholipid vesicles bound by annexin IN-VC on the planar bilayer is proportional to its surface coverage and can be inhibited by coadsorption of annexin V on the planar bilayer or by shielding the phospholipid surface of the vesicles with blood coagulation factor Va. Annexin IN-VC, like annexin V, does not bind to pure PC bilayers, but its adsorption on anionic phospholipid bilayers brings about the capacity to bind pure PC vesicles. This suggests that annexin IN-VC generates or exposes after binding to anionic phospholipids another phospholipid binding site, that differs from the annexin V phospholipid binding site. Collectively, the data suggest that two-dimensional cluster formation of annexin IN-VC on a bilayer with anionic phospholipids is involved in vesicle adherence.

Monitoring of unbound protein in vesicle suspensions with off-null ellipsometry

In studies on the binding of proteins to small unilamellar phospholipid vesicles (SUV), the concentration of unbound protein usually remains unknown, because the vesicles cannot be separated from the bulk solution. In the present study, this limitation was overcome by addition of a supported planar phospholipid bilayer to the cuvette containing a vesicle suspension. Ellipsometric measurement of the protein adsorption velocities on this bilayer allowed determination of the concentrations of unbound protein. At high protein concentrations the adsorption is rapidly completed and the usual null-ellipsometry is too slow to obtain well-defined initial adsorption rates. Therefore, an off-null technique was developed, allowing measurement of the adsorbed protein mass at time intervals of 20 ms. Binding of prothrombin and coagulation factor Xa was measured in SUV suspensions prepared from a 20% dioleoylphosphatidylserine (DOPS) and 80% dioleoylphosphatidylcholine (DOPC) phospholipid mixture. For prothrombin, a dissociation constant Kd = 140 +/- 27 nM (mean +/- S.E.) and maximal surface concentration gamma max = (8.9 +/- 0.8) x 10(-3) mole of protein per mole of lipid, were obtained. For factor Xa, these values were Kd = 49.6 +/- 6.3 nM and gamma max = (23.0 +/- 1.4) x 10(-3) mole of protein per mole of lipid. These binding parameters are similar to those obtained earlier for planar bilayers. Apparently, the binding of factor Xa and prothrombin is not dependent on surface curvature.

Circulatory models in assessment of cardiac enzyme release in dogs

Cardiac ischemia causes interstitial leakage of cellular enzymes followed by release of these enzymes into plasma. Quantitative interpretation of these data requires a specific circulatory model, and the performance of such models was investigated. Plasma activities of cardiac enzymes were measured for increasingly abrupt forms of ischemic heart injury in the dog: 1) permanent ligation of the left anterior descending coronary artery (LAD); 2) reperfusion after 2 h of ligation of the LAD; and 3) calcium-free perfusion of the LAD during 10 min (calcium-paradox injury). Release into plasma of a rapidly (41%/h) and a slowly (2.2%/h) catabolized enzyme was calculated from the plasma activities, using a detailed circulatory model with compartments for heart, plasma, muscle, skin, and viscera. The time course of cellular enzyme leakage into interstitial space in the heart was calculated from release into plasma and a range of reported values for transendothelial permeability. Simplification to one- and two-compartment models introduced, respectively, 10 and 2% error in calculated cumulative release. Considering the other sources of error, this implies adequate performance of the two-compartment model. Protein washout from the heart is strongly influenced by expansion of interstitial protein space with dead myocyte volume and depends on the microheterogeneity of necrotic tissue areas. Accelerated release of enzymes into plasma after reperfusion reflects accelerated cellular leakage rather than enhanced washout.

Clustering of lipid-bound annexin V may explain its anticoagulant effect

In 1985 we isolated a new vascular anticoagulant protein VAC alpha, now called annexin V, with a high binding affinity (Kd less than 10(-10) M) for phospholipids. Its anticoagulant effect was attributed to displacement of coagulation factors from the phospholipid membrane. The present study demonstrates that the inhibition of prothrombinase activity by annexin V strongly depends on the curvature of the membrane surface and on the calcium concentration. Half-maximal inhibition of prothrombinase on and binding of annexin V to small vesicles, composed of 20% phosphatidylserine and 80% phosphatidylcholine, requires 2-3 mM calcium. With large vesicles and planar bilayers considerably less calcium is required for inhibition of prothrombinase and for lipid binding. Half-maximal binding of annexin V to large vesicles and to planar bilayers occurs at 0.7 and 0.2 mM calcium, respectively. This seemingly confirms the displacement model. The displacement of coagulation factors, however, proved to be incomplete, with residual surface concentrations of factors Xa, Va, and prothrombin sufficient for effective production of thrombin. Cryoelectron microscopy revealed that annexin V binding to large vesicles caused planar facets, indicating the formation of large sheets of clustered annexin V. Apparently, the formation of these two-dimensional arrays is promoted by calcium and hampered by high surface curvature. It is speculated that the complete inhibition (greater than 99%) of prothrombinase activity by annexin V is caused by the reduced lateral mobility of prothrombin and factor Xa in rigid sheets of annexin V covering the membrane.

Membrane-mediated assembly of the prothrombinase complex

Prothrombinase assembly was studied on macroscopic planar bilayers consisting of 20% dioleoyl-phosphatidylserine (DOPS) and 80% dioleoyl-phosphatidylcholine (DOPC). The dissociation constant for the binding of factor Xa to the bilayer, measured by ellipsometry, was Kd = 47 +/- 8 nM (mean +/- S.D.) and this value was lowered to Kd = 2.2 +/- 0.3 pM by preadsorption of factor Va. This latter value was determined from direct measurement of steady-state thrombin production. A comparable value of Kd = 1.0 +/- 0.1 pM was found by repeating these experiments in suspensions of phospholipid vesicles, and it was verified that prothrombinase assembly was not influenced by the addition of prothrombin. Using a minute amount (0.094 fmol cm-2) of preadsorbed factor Va, it was found that the rate of prothrombinase assembly exceeds the rate of collisions between Xa molecules from the buffer and the sparse Va molecules on the bilayer. Apparently, factor Xa adsorbs first to the membrane and then associates rapidly with factor Va by lateral diffusion. The data indicate almost instantaneous equilibrium of this complex formation on the surface with a lower limit for the bimolecular rate constant of kon = 2.8 x 10(13) (mol/cm2)-1 s-1. In suspensions of small phospholipid vesicles, prothrombinase assembly is collisionally limited and the value of kon should be proportional to vesicle diameter. This was verified with a method for estimation of kon values from thrombin generation curves. Values of 0.36 x 10(9) and 1.6 x 10(9) M-1 s-1 were found for vesicles of 20-30- and 60-80-nm diameter, respectively.

Production of thrombin by the prothrombinase complex is regulated by membrane-mediated transport of prothrombin

Production of thrombin by phospholipid-bound prothrombinase complexes has been described as being regulated by the prothrombin concentration in the buffer (free-substrate model) as well as by the concentration of prothrombin adsorbed to the phospholipid surface (bound-substrate model). We studied simultaneous adsorption and conversion of prothrombin on planar bilayers consisting of 20% dioleoylphosphatidylserine and 80% dioleoylphosphatidylcholine. A transport limitation in the conversion of prothrombin was prevented by using a very low (0.3 fmol cm-2) amount of prothrombinase on the bilayer. The Michaelis and catalytic constants thus found were Km = 5.8 +/- 0.7 nM and kcat = 33 +/- 1 s-1 (mean +/- S.D.). The apparent bimolecular rate constant Kcat/Km = 5.7 x 10(9) M-1 s-1 exceeds the theoretically maximal value for the free-substrate model. In contrast, kcat/Km is within the range expected for a diffusion-controlled bound-substrate model. A similar mechanism for prothrombin conversion in suspensions of phospholipid vesicles would imply increasing kcat/Km values for increasing vesicle diameter. This prediction was tested and a 3-fold increase in kcat/Km values was indeed found for vesicles 60-80 nm in diameter compared to vesicles of 20-30 nm diameter. It is concluded that thrombin production is dependent on protein fluxes rather than on protein concentrations.

Linearized model for the initiation of factor Va, and thrombin generation

A simple model of the initiation of thrombin formation in plasma as a response to factor Xa generation was constructed. In this model factor Xa is considered as an input with a constant concentration. Substrate depletion and inactivation by activated protein C are neglected. The resulting linear model allows a closed form solution by standard methods. With values of the reaction rate constants, as determined in purified systems, this model predicts a highly explosive and complete activation of factor V and prothrombin as a response to any given (steady state) factor Xa concentration even in situations where prothrombinase and(/or) thrombin are rapidly inactivated. However, the time delay to rapid thrombin production becomes longer at lower factor Xa concentrations. Analysis of this time delay as a function of the factor Xa concentration indicates that the gain of the feedback loop of factor V activation by thrombin is so high that the contribution of factor V activation by factor Xa is relatively unimportant for factor Xa concentrations in the nanomolar range. It appears that the time lag is mainly determined by the gain of this feedback loop: similar proportional reductions of each of these reaction rates causes a similar effect. The effects of moderately enhanced inhibition rates of thrombin and prothrombinase on the time delay depend strongly on factor Xa concentration. Only a minor prolongation of the delay is predicted for factor Xa concentrations in the nanomolar range, but for factor Xa concentrations in the 1-10 pM range, the enhanced decay will cause considerable delays. Simultaneous reduction of the turnover rate of prothrombinase results in much larger delays for the entire range of factor Xa concentrations.

Simulation model for thrombin generation in plasma

A simulation model for the production of thrombin in plasma is presented. Values of the reaction rate constants as determined in purified systems are used and the model is tested by comparison of simulations of factor Xa, factor Va and thrombin generation curves with experimental data obtained in thromboplastin-activated plasma. Simulations of the effect of hirudin indicate that factor V is predominantly activated by thrombin and not by factor Xa. The model predicts a threshold value for the factor Xa production which, if exceeded, results in explosive and complete activation of prothrombinase. The dependence of this threshold value on different negative feedback reactions, e.g. the inactivation of thrombin and factor Xa by antithrombin III (+ heparin), is investigated. The threshold value, for control plasma in the range of 1-10 pM total factor Xa production, can be raised two orders of magnitude by accelerated inactivation of factor Xa and prothrombinase but is hardly affected by a tenfold increase in the rate of thrombin inactivation or by increased production of activated protein C. This latter effect, however, results in a more gradual input-response relation between factor Xa input and the extent of prothrombinase activation.

Surface exclusion and molecular mobility may explain Vroman effects in protein adsorption

Data on protein adsorption usually show that for increasing surface coverage the adsorption velocity decreases much faster than linearly. This contrasts to the classical Langmuir model with an adsorption velocity proportional to the number of unoccupied binding sites. It has been shown that this non-linearity may explain phenomena like transient adsorption of different proteins from a protein mixture or dilution-dependent changes in binding properties, collectively called Vroman effects. However, the molecular mechanisms explaining this non-linear behavior remain to be established. A Monte Carlo simulation model is presented that incorporates steric hindrance, lateral mobility and mutual interactions of adsorbed molecules. Experimental data on the adsorption kinetics of prothrombin and annexin V, a recently discovered anticoagulant protein, at phospholipid bilayers are analyzed with this model. A major conclusion is that the steep decline in adsorption rates for increasing surface coverage can be explained, without assuming repulsive forces between adsorbed molecules, as a surface exclusion effect combined with lateral mobility of adsorbed molecules. The fact that annexin V shows this effect to a much lesser degree than prothrombin is tentatively explained by clustering of adsorbed annexin V molecules. A qualitative effect of lateral mobility on the adsorption characteristics, predicted by the model, is confirmed in experiments in which the fluidity of the bilayers was manipulated.

Time course of cellular enzyme release in dog heart injury

The transport time of enzyme from heart to plasma was studied in two experimental models. First, the enzyme alanine aminotransferase was slowly infused into the left ventricular wall in open-chest dogs. The half-life for the washout of alanine aminotransferase activity into plasma was 20 +/- 4 minutes (mean +/- SEM, n = 8) and was not different in ischemic and normally perfused tissue. From measurements of arteriovenous differences in alanine aminotransferase activity and left ventricular blood flow, it was concluded that 77 +/- 14% of total enzyme washout from ischemic tissue occurred by direct entry into the bloodstream. The corresponding value for the vascular permeability-surface area product was 264 +/- 55 ml.kg-1.hr-1. For a second model, we studied myocardial enzyme release into plasma after abrupt heart injury induced by 10 minutes of calcium-free coronary perfusion followed by reintroduction of calcium (calcium-paradox mechanism). The half-life for the release into plasma was 1.9 +/- 0.2 hours (mean +/- SEM, n = 6) and was again not influenced by sustained ischemia. Slower washout, as observed for this second model, is consistent with increased interstitial protein space and corresponds to a permeability--surface area product between 135 and 285 ml.kg-1.hr-1. These results were used to calculate the time course of cellular enzyme leakage from the rate of enzyme release into plasma in various forms of heart injury. Significant shifts between the time curves of evolving cellular injury and enzyme release into plasma are observed after 2 hours of ischemia followed by coronary reperfusion, but not after permanent ischemia.

Significance of initial ST segment elevation and depression for the management of thrombolytic therapy in acute myocardial infarction. European Cooperative Study Group for Recombinant Tissue-Type Plasminogen Activator

To determine the ability of initial ST segment elevation and depression to predict infarct size limitation by thrombolytic therapy, data were analyzed in 721 patients with acute myocardial infarction who were admitted to a randomized, placebo-controlled study of intravenous recombinant tissue-type plasminogen activator. Patients with QRS duration of 120 msec or more or with previous history of myocardial infarction were excluded, leaving 322 in the treatment and 333 in the placebo group. Cumulative 72-hour release of alpha-hydroxybutyrate dehydrogenase and global ejection fraction as well as left ventricular wall motion derived from angiography were used as independent measures of infarct size. Electrocardiograms obtained at admission, 6 hours after start of therapy, and before discharge were analyzed. All ST measurements were made by hand at the J point and 60 msec after the J point. Patients with high ST segment elevation at admission (i.e., sum of ST elevation at 60 msec after the J point was 20 mm or more) had significantly larger infarction and higher hospital mortality when compared with those with lower (less than 20 mm) ST elevation. Reciprocal ST segment depression also showed a linear relation with infarct size and mortality, independent from ST elevation, both in anterior and inferior myocardial infarction. The sum of deviations measured at the J point and 60 msec after the J point differed significantly, especially in anterior myocardial infarction at admission (mean, 16 +/- 9 versus 23 +/- 11 mm). The prognostic value of one measurement was not, however, superior over the other. Treatment with recombinant tissue-type plasminogen activator was most effective in those with large ST deviations at admission, but patients with anterior infarction and smaller ST shifts also appeared to benefit from therapy. Results in individual patients were variable, and the overall correlation of initial ST shifts with enzymatic infarct size was rather low. In conclusion, the present study shows that the magnitude of initial ST elevation and also of reciprocal ST depression in the admission electrocardiogram is valuable for the management and assessment of thrombolytic therapy in patients with acute myocardial infarction.

Binding of vascular anticoagulant alpha (VAC alpha) to planar phospholipid bilayers

Vascular anticoagulant alpha (VAC alpha, annexin V) is a member of the family of calcium and phospholipid binding proteins, the annexins. The binding properties of VAC alpha to phospholipid bilayers were studied by ellipsometry. Adsorption was calcium-dependent and completely reversible upon calcium depletion. Half-maximal adsorptions to phospholipid bilayers consisting of 100, 20, 5, and 1% dioleoyl-phosphatidylserine (DOPS) supplemented with dioleoyl-phosphatidylcholine (DOPC) were reached at Ca2+ concentrations of 0.04, 0.22, 1.5, and 8.6 mM. These surfaces all showed the same maximal adsorption of 0.22 +/- 0.01 micrograms of VAC alpha/cm2 (mean +/- S.D.). The adsorption to bilayers containing more than 10% DOPS was independent of VAC alpha concentrations in the range of 0.5-100 nM. Dissociation constants for VAC alpha binding to these surfaces were estimated to be below 2 x 10(-10) M. No adsorption was observed on pure DOPC bilayers at a Ca2+ concentration of 3 mM. The ability to mediate VAC alpha binding to 20% DOPS/80% DOPC bilayers was highly specific for Ca2+. The use of other divalent cations resulted in decreased binding in the order Cd2+ greater than Zn2+ greater than Mn2+ greater than Co2+ greater than Ba2+ greater than Mg2+. Zinc ions had a synergistic effect on Ca2(+)-dependent VAC alpha binding. The Ca2+ concentration needed for half-maximal binding to cardiolipin, dioleoyl-phosphatidylglycerol, DOPS, phosphatidylinositol, phosphatidic acid, dioleoyl-phosphatidylethanolamine, and sphingomyelin increased in that order. Adsorption was independent of the overall surface charge of the phospholipid membrane.

Complete recovery in plasma of enzymes lost from the heart after permanent coronary artery occlusion in the dog

Plasma activities of creatine kinase (CK) and alpha-hydroxybutyrate dehydrogenase (HBD) were measured after permanent coronary artery occlusion in the dog. Cumulative release of enzymes in plasma was calculated from these data by using a previously validated two-compartment model for circulating enzymes. Regional myocardial ischemia was measured by injection of radiolabeled microspheres. After 48 hours, the dogs were killed, and a detailed map of left ventricular enzyme activity was obtained from 108 tissue samples. Cumulative release into plasma of CK and HBD was 96 +/- 20% and 112 +/- 26%, respectively, of the total activities depleted from the heart (mean +/- SD, n = 11). The scatter in these values is inherent to the calculations, and it is concluded that both enzymes are recovered completely in plasma and, thus, can be used as quantitative markers of injury. Discrepancies between this result and earlier reports on the recovery of CK are only partly apparent and can be explained partly by underestimation of the elimination rate of CK from plasma, irregardless of tissue edema and incomplete extraction of enzyme activity from tissue.

Estimation of the fractional catabolic rate constants for the elimination of cytosolic liver enzymes from plasma

Pathological elevations of the plasma activities of liver enzymes are not simply related to the quantitative release of such enzymes from the liver. Several enzymatic indices, such as the well-known de Ritis quotient, may be determined by differences in the time course of hepatic enzyme release, rather than reflecting true differences in the released quantities of various enzymes. A more quantitative use of enzymatic data is hampered by the fact that the fractional catabolic rate constants for the elimination of enzyme activities from plasma are unknown. In the present study, three of these constants are estimated by comparison of the time-activity curves in plasma with the corresponding curve of a simultaneously released, more slowly eliminated reference enzyme. This method can be applied in patients with an acute short period of hepatic enzyme release. Values obtained for the cytosolic isoforms of lactate dehydrogenase, AST and ALT are: fractional catabolic rate constant (lactate dehydrogenase isoenzyme 5) = 0.13 +/- 0.01 hr-1, fractional catabolic rate constant (cytosolic AST) = 0.088 +/- 0.016 hr-1 and fractional catabolic rate constant (cytosolic ALT) = 0.034 +/- 0.004 hr-1 (mean +/- S.E., n = 10). These values are much higher than the apparent disappearance rate constants, because of extravascular return of activity and tailing release of enzymes during the major part of the elimination phase. It is shown that these results are consistent with earlier published data on the disappearance rates from plasma of lactate dehydrogenase, AST and ALT after acute liver injury. Cumulative release of various cytosolic enzymes occurred in proportion to the corresponding activities in human control livers.

Plasma activity of muscle enzymes: quantification of skeletal muscle damage and relationship with metabolic variables

One hundred fourteen sedentary volunteers (34 +/- 8 years) took part in an endurance training study to be completed after 18-20 months with a marathon. Ultimately, 60 males and 18 females achieved that goal. The training program, carefully supervised, was divided into three periods with a maximum of 45-, 70-, and 110-km week training volume and concluded with a performance race of 15, 25, and 42.2 km, respectively. Three days before and 3 and 5 days after each race, 35 subjects were selected to perform a progressive treadmill test and the remaining subjects participated in field tests of 400 and 1000 m. A significant decrease in half-life time of CK enzyme plasma activity after running long distances in the course of the study from 20 h to 13 h was observed. Based on plasma enzyme activity and supposing that the total enzyme content left the muscle fiber, the estimated amount of muscle damage was found to be small. A gender difference in plasma enzyme activity increase (females demonstrated a lower increase) occurred only after the marathon.

Myocardial enzyme depletion in infarcted human hearts: infarct size and equivalent tissue mass

Myocardial activities of several enzymes were measured in infarcted and non-infarcted areas of heart sections obtained from eight patients who died after acute myocardial infarction. Similar data were obtained from four patients with cardiovascular disorders who died from causes other than myocardial infarction and from six patients without previously known heart disease. It was found that both non-infarcted and infarcted tissue samples contained considerably altered enzyme activities. This finding explains the low correlations between enzymatic and histological estimates of infarct size previously reported. However, when the residual myocardial activities of different enzymes were compared with each other, a close correlation was found between creatine kinase, alpha-hydroxybutyrate dehydrogenase, and aspartate aminotransferase. It appears that the pathological changes in the myocardial activities of these enzymes may be explained by the phenomenon of diluted myocardium. This indicates that myocardial injury, as estimated from plasma enzyme activities, may still be expressed meaningfully in gram equivalents of healthy myocardium.

Minimal myocardial injury after uncomplicated coronary bypass surgery. Various sources of overestimation

Myocardial injury after aorto-coronary bypass surgery was estimated in 72 patients from total release into plasma of cardiac creatine kinase (CK-MB) and alpha-hydroxybutyrate dehydrogenase (HBD). Activities of CK-MB were determined both by immuno-inhibition of CK-M units and by ion-exchange chromatography. After correction for per-operative hemolysis, the estimates based on HBD were in agreement with the estimates based on CK-MB as determined by the ion-exchange method. Both enzymes indicated a mean loss of only about 2 gram-equivalents of myocardium. Such minimal injury was also found in metabolic and ultrastructural studies of myocardial biopsies in the same patients, as reported earlier. However, approximately two-fold larger estimates of injury were obtained from plasma CK-MB activities determined by immuno-inhibition. This apparent extra release of CK-MB runs parallel with massive release of CK-activity from skeletal muscle damaged by surgery. Taking also into account the various calculation methods used by different authors, overestimates as large as 10-20 gram-equivalents of lost myocardium after uncomplicated bypass surgery, as published in the literature, can be explained.

Rapid enzyme release from acutely infarcted myocardium after early thrombolytic therapy: washout or reperfusion damage?

In a randomized study on early intracoronary thrombolytic therapy in patients with acute myocardial infarction (AMI), serial plasma enzyme activities were measured to analyze the rate of enzyme appearance in plasma with reference to treatment allocation, area at risk, and infarct size. Cumulative activities of alpha-hydroxybutyrate dehydrogenase (HBDH) appearing in plasma in the first 24 hours (Q24), 48 hours (Q48), and 72 hours (Q72) were calculated to obtain infarct size (= Q72) and rate of HBDH appearance in plasma (= Q24/Q72). Analyzed on the basis of "intention to treat" in 448 patients with AMI, the mean Q24/Q72 value (+/- SEM) was 0.653 +/- 0.011 in 230 patients receiving thrombolytic therapy; this value was significantly (p less than 0.001) higher than that observed in 218 patients receiving conventional therapy (0.504 +/- 0.012). In the thrombolysis group Q24/Q72 was independent of infarct size, whereas in the control group Q24/Q72 was negatively correlated with infarct size (r = -0.26; p less than 0.001). Plotted against the sum of ST segment elevations at admission (sigma ST) mean Q24 values were similar in both treatment groups, but mean Q48 and especially Q72 values were larger in the control group than in the thrombolysis group. We conclude that: (1) in reperfused infarctions the time course for development of infarct is accelerated in comparison to unreperfused infarcts; (2) this accelerated process of necrosis lasts about 40 to 50 hours, a duration that is hardly influenced by infarct size; and (3) the reperfusion-induced acceleration of enzyme release resembles the reoxygenation-induced enzyme release from anoxic hearts.(ABSTRACT TRUNCATED AT 250 WORDS)

Enzyme tests in the evaluation of thrombolysis in acute myocardial infarction

The activity of alpha-hydroxybutyrate dehydrogenase, creatine kinase, creatine kinase MB and aspartate aminotransferase was measured on serial plasma samples from patients with acute myocardial infarction. The study was part of a multicentre randomised trial of the effect of thrombolytic treatment in the acute phase of acute myocardial infarction. The applicability and comparability of enzyme tests for the estimation of myocardial injury were studied in 76 control patients and 74 patients treated with streptokinase. Treatment with streptokinase caused a considerable acceleration of enzyme release after acute myocardial infarction, both in patients with persistent coronary occlusion and in those with successful reperfusion. But this changed pattern of enzyme release did not affect the rate of enzyme elimination from plasma or the released proportions of different enzymes. Thus the assessment of infarct size by measurement of these enzyme activities can also be applied to patients treated with streptokinase. Moreover, the enzymes measured in the present study are all equally valid markers of myocardial injury.