Protein S negates the activated protein C inhibitory activity of plasma.

The inactivation of factor Va by the natural anticoagulant, activated protein C (APC) is subject to a number of regulatory mechanisms. This report examines the efficacy of APC in plasma and evaluates the role of the APC cofactor protein S in this milieu. The ability of protein S to enhance the anticoagulant effects of activated protein C was demonstrated using a factor Xa recalcification time of Al(OH)3 adsorbed plasma. At a set concentration of APC, increasing concentrations of protein S resulted in a linear and saturable potentiation of the activity of APC. This result was not reflected in a purified component assay, where the extent of factor Va inactivation by APC was only marginally augmented by protein S. The efficacy of the cofactor was not affected by variations in the concentration of factor Va. Similarly, increasing the protein S:APC molar ratio of 200:1 resulted in only a trivial enhancement of APC activity. To directly examine the proteolysis of factor Va by APC in plasma, a novel assay system containing Al(OH)3 adsorbed, factor V deficient plasma supplemented with purified human factor Va was developed. The addition of APC in varying concentrations to this system consistently yielded factor Va inactivation rates inferior to those seen in a purified component assay. This finding is consistent with the presence of APC inhibitory activity in plasma. When protein S was added to the plasma system, factor Va inactivation by APC was restored to a similar level to that observed in the purified system.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cardiolipin enhances protein C pathway anticoagulant activity

The anticoagulant activity of activated protein C (APC) was studied using factor Xa-1-stage assays of both the procoagulant and anticoagulant activities of phospholipid vesicles containing phosphatidylserine or cardiolipin as active phospholipids. In the absence of APC, phosphatidylserine vesicles showed higher procoagulant activity than cardiolipin vesicles whereas cardiolipin vesicles supported APC-dependent anticoagulant activity better than phosphatidylserine vesicles. Enhancement of APC anticoagulant activity in plasma by cardiolipin was markedly stimulated by the APC cofactor protein S. In purified reaction mixtures, cardiolipin in phospholipid vesicles dose-dependently enhanced APC anticoagulant activity. This effect of cardiolipin was partially dependent on protein S, and immunoblotting studies showed that cardiolipin enhanced the APC-mediated cleavage of the factor Va heavy chain at Arg506 and Arg306. In solid-phase binding assays, increasing amounts of cardiolipin in multicomponent phospholipid vesicles increased the affinity for protein S and to a lesser extent APC. These data are consistent with the hypothesis that cardiolipin stimulates the anticoagulant protein C pathway by increasing the affinity of phospholipid surfaces for protein S:APC and by enhancing inactivation of factor Va by APC due to cleavages at Arg506 and Arg306 in factor Va. Based on this, it is further hypothesized that anti-cardiolipin or anti-oxidized cardiolipin antibodies may be thrombogenic because they inhibit phospholipid-dependent expression of the anticoagulant protein C pathway.     

Isolation and characterization of an antifactor V antibody causing activated protein C resistance from a patient with severe thrombotic manifestations

A 44-year-old woman with a history of severe thrombotic manifestations presented with a markedly reduced activated protein C-sensitivity ratio (APC-SR). DNA sequencing of and around the regions encoding the APC cleavage sites in the factor Va molecule excluded the presence of the factor VLeiden mutation and of other known genetic mutations. No antiphospholipid antibodies were present in the patient's plasma and both prothrombin time and activated partial thromboplastin time were normal. The total immunoglobulin fraction was isolated from the patient's plasma and found to induce severe APC resistance when added to normal plasma and to factor V-deficient plasma supplemented with increasing concentrations of factor V. Immunoblotting and immunoprecipitation experiments with the total immunoglobulin fraction purified from the patient's plasma demonstrated that the antibody recognizes factor V, is polyclonal, and has conformational epitopes on the entire factor V molecule (heavy and light chains, and B region). Thus, the immunoglobulin fraction interferes with the anticoagulant pathway involving factor V. The inhibitor was isolated by sequential affinity chromatography on protein G-Sepharose and factor V-Sepharose. The isolated immunoglobulin fraction inhibited factor Va inactivation by APC because of impaired cleavage at Arg306 and Arg506 of the heavy chain of the cofactor. The isolated immunoglobulin fraction was also found to inhibit the cofactor effect of factor V for the inactivation of factor VIII by the APC/protein S complex. Our data provide for the first time the demonstration of an antifactor V antibody not related to the presence of antiphospholipid antibodies, which is responsible for thrombotic rather than hemorrhagic symptoms.     

Inhibition of activated protein C anticoagulant activity by prothrombin

In this study, we test the hypothesis that prothrombin levels may modulate activated protein C (APC) anticoagulant activity. Prothrombin in purified systems or plasma dramatically inhibited the ability of APC to inactivate factor Va and to anticoagulate plasma. This was not due solely to competition for binding to the membrane surface, as prothrombin also inhibited factor Va inactivation by APC in the absence of a membrane surface. Compared with normal factor Va, inactivation of factor Va Leiden by APC was much less sensitive to prothrombin inhibition. This may account for the observation that the Leiden mutation has less of an effect on plasma-based clotting assays than would be predicted from the purified system. Reduction of protein C levels to 20% of normal constitutes a significant risk of thrombosis, yet these levels are observed in neonates and patients on oral anticoagulant therapy. In both situations, the correspondingly low prothrombin levels would result in an increased effectiveness of the remaining functional APC of approximately 5-fold. Thus, while the protein C activation system is impaired by the reduction in protein C levels, the APC that is formed is a more effective anticoagulant, allowing protein C levels to be reduced without significant thrombotic risk. In situations where prothrombin is high and protein C levels are low, as in early stages of oral anticoagulant therapy, the reduction in protein C would result only in impaired function of the anticoagulant system, possibly explaining the tendency for warfarin-induced skin necrosis.     

Factor V antigen levels and venous thrombosis: risk profile, interaction with factor V leiden, and relation with factor VIII antigen levels

Clotting factor V has a dual function in coagulation: after activation, procoagulant factor V stimulates the formation of thrombin, whereas anticoagulant factor V acts as a cofactor for activated protein C (APC) in the degradation of factor VIII/VIIIa, thereby reducing thrombin formation. In the present study, we evaluated whether plasma factor V levels, either decreased or increased, are associated with venous thrombosis. High procoagulant factor V levels may enhance prothrombinase activity and increase the thrombosis risk. Low anticoagulant factor V levels could reduce APC-cofactor activity in the factor VIII inactivation (APC-resistant phenotype), which might also promote thrombosis. Low factor V levels in combination with factor V Leiden could lead to a more severe APC-resistant phenotype (pseudohomozygous APC resistance). To address these issues, we have measured factor V antigen (factor V:Ag) levels in 474 patients with thrombosis and 474 control subjects that were part of the Leiden Thrombophilia Study (LETS). Factor V:Ag levels increased by 7.6 U/dL for every successive 10 years of age. Mean factor V:Ag levels were 134 (range 41 to 305) U/dL in patients and 132 (range 47 to 302) U/dL in controls. Neither high nor low factor V:Ag levels were associated with venous thrombosis. We found that factor V:Ag and factor VIII antigen levels in plasma were correlated, but factor V did not modify the thrombotic risk of high factor VIII levels. The normalized APC ratio was not influenced by the factor V:Ag level in subjects with or without factor V Leiden. We conclude that neither low nor high factor V:Ag levels are associated with venous thrombosis and that factor V:Ag levels do not mediate the thrombotic risk associated with high factor VIII levels.     

Congenital and acquired activated protein C resistance

Resistance to the anticoagulant action of activated protein C, APC resistance, is a highly prevalent risk factor for venous thrombosis among individuals of Caucasian origin. In most cases, APC resistance is associated with a single missense mutation in the gene for coagulation factor V (FV (Leiden)), which predicts the replacement of Arg (506) with a Gln at one of the cleavage sites for APC in factor V. Factor V is a Janus-faced protein with dual functions, serving as an essential nonenzymatic cofactor in both pro- and anticoagulant pathways. Procoagulant factor Va, generated after proteolysis by thrombin or factor Xa, is a cofactor to factor Xa in the activation of prothrombin, whereas anticoagulant factor V, generated after proteolysis by APC, functions as a cofactor in the APC-mediated degradation of FVIIIa. The FV (Leiden) mutation affects the anticoagulant response to APC at two distinct levels of the coagulation pathway, as it impairs degradation of both activated factor V and activated factor VIII, the latter effect inasmuch as FVLeiden is a poor APC cofactor. Several other genetic traits, some of them quite common, are known to affect the anticoagulant response to APC, but none of them cause the same severe APC-resistance phenotype as FV (Leiden) and their importance as risk factors for thrombosis is unclear. A poor APC response may also result from acquired conditions, some of which are clearly involved in the pathogenesis of venous thrombosis. Venous thrombosis is a typical multifactorial disease, the pathogenesis of which involves multiple gene-gene and gene-environment interactions. In many patients with severe thrombophilia, APC resistance is found as a contributing risk factor.     

An update on clinical and basic aspects of the protein C anticoagulant pathway

The protein C anticoagulant pathway provides a mechanism for regulating the coagulation process through the selective inactivation of factors Va and VIIIa. Recent studies have suggested that factor V may facilitate this process and that a mutation at one of the inactivation sites can contribute to resistance to activated protein C (APC) inactivation of factor Va. This appears to be a common cause of familial thrombophilia. The control mechanisms involved in factor Va inactivation have also begun to become more clear. Membrane surfaces seem to be critical to complete factor Va inactivation, and the membrane composition requirements for optimal anticoagulant activity are distinct from those of procoagulant reactions. Specifically, the APC anticoagulant activity requires phosphatidylethanolamine, whereas the prothrombin activation complex does not. These observations may partially explain thrombotic complications with antiphospholipid antibodies in which the some antibodies have been shown to react preferentially with phosphatidylethanolamine and could, therefore, selectively block APC function. Clinically, more complete studies on partial protein C deficiency indicate that, at least within families, the deficiency is a significant risk factor for thrombosis. The impact of deficiencies on thrombotic risk suggests that protein C or other components of the pathway may be useful therapeutic agents. The limited clinical experience in treating meningococcemia, warfarin-induced skin necrosis, and homozygous protein C deficiency with protein C concentrates suggests that this approach is safe and effective.     

Proteolytic events that regulate factor V activity in whole plasma from normal and activated protein C (APC)-resistant individuals during clotting: an insight into the APC-resistance assay

Human factor V is activated to factor Va by alpha-thrombin after cleavages at Arg709, Arg1018, and Arg1545. Factor Va is inactivated by activated protein C (APC) in the presence of a membrane surface after three sequential cleavages of the heavy chain. Cleavage at Arg506 provides for efficient exposure of the inactivating cleavages at Arg306 and Arg679. Membrane-bound factor V is also inactivated by APC after cleavage at Arg306. Resistance to APC is associated with a single nucleotide change in the factor V gene (G1691-->A) corresponding to a single amino acid substitution in the factor V molecule: Arg506-->Gln (factor V Leiden). The consequence of this mutation is a delay in factor Va inactivation. Thus, the success of the APC-resistance assay is based on the fortuitous activation of factor V during the assay. Plasmas from normal individuals (1691 GG) and individuals homozygous for the factor V mutation (1691 AA) were diluted in a buffer containing 5 mmol/L CaCl2, phospholipid vesicles (10 micromol/L), and APC. APC, at concentrations < or = 5.5 nmol/L, prevented clot formation in normal plasma, whereas under similar conditions, a clot was observed in plasma from APC-resistant individuals. Gel electrophoresis analyses of factor V fragments showed that membrane-bound factor V is primarily cleaved at Arg306 in both plasmas. However, whereas in normal plasma production of factor Va heavy chain is counterbalanced by fast degradation after cleavage at Arg506/Arg306, in the APC-resistant individuals' plasma, early generation and accumulation of the heavy chain portion of factor Va occurs as a consequence of delayed cleavage at Arg306. At elevated APC concentrations (>5.5 nmol/L), no clot formation was observed in either plasma from normal or APC-resistant individuals. Our data show that resistance to APC in patients with the Arg506-->Gln mutation is due to the inefficient degradation (inactivation) of factor Va heavy chain by APC.     

Anticoagulant protein C pathway defective in majority of thrombophilic patients [see comments]

A defect involving poor anticoagulant response to activated protein C (APC), an anticoagulant serine protease known to inactivate factors Va and VIIIa in plasma, was recently reported and the existence of a novel APC cofactor was suggested. To define the frequency of this defect among 25 venous thrombophilic patients with no identifiable laboratory test abnormality and among 22 patients previously identified with heterozygous protein C or protein S deficiency, the APC-induced prolongation of the activated partial thromboplastin time assay for these patients was compared with results for 35 normal subjects. The results show that this new defect in anticoagulant response to APC is surprisingly present in 52% to 64% of the 25 patients, ie, in the majority of previously undiagnosed thrombophilia cases, but is not present in 20 of 22 heterozygous protein C or protein S deficient patients, suggesting that the new factor is a risk factor independent of protein C or protein S deficiency. The results demonstrate that abnormalities in the anticoagulant protein C pathway are present in the majority of thrombophilic patients.     

Plasma glucosylceramide deficiency as potential risk factor for venous thrombosis and modulator of anticoagulant protein C pathway

To assess the relationship between venous thrombosis and plasma glucosylceramide (GlcCer) or phosphatidylethanolamine (PE), plasma levels of GlcCer and PE were determined for 70 venous thrombosis patients referred for evaluation and 70 healthy blood donors. The mean GlcCer level, but not the PE level, was lower in patients versus controls (4.9 vs 6.5 microg/mL [P =.0007] and 66 vs 71 microg/mL [P =.48], respectively). As a measure of relative risk, the odds ratio for deep vein thrombosis in subjects with GlcCer levels below the 10th percentile of controls was 5.7 (95% CI, 2.3-14). To assess the influence of glycolipids on anticoagulant response to activated protein C (APC):protein S in modified prothrombin time assays, the effects of depleting endogenous plasma GlcCer by glucocerebrosidase treatment or of adding exogenous purified GlcCer or other neutral glycolipids to plasma were tested. Glucocerebrosidase treatment reduced plasma sensitivity to APC:protein S in parallel with GlcCer reduction. Exogenously added GlcCer and the homologous Glc-containing globotriaosylceramide (Gb3Cer), but not galactosylceramide, dose-dependently prolonged clotting times of normal plasma in the presence, but not absence, of APC:protein S, which suggests that GlcCer or Gb3Cer can enhance protein C pathway anticoagulant activity. In studies using purified proteins, inactivation of factor Va by APC:protein S was enhanced by GlcCer alone and by GlcCer in multicomponent vesicles containing phosphatidylserine and phosphatidylcholine. These results suggest that the neutral glycolipids GlcCer and Gb3Cer may directly contribute to the anticoagulant activity of the protein C pathway and that deficiency of plasma GlcCer may be a risk factor for venous thrombosis. (Blood. 2001;97:1907-1914)     

A comparison between two activated protein C resistance methods as routine diagnostic tests for factor V Leiden mutation

The most common commercially available test measuring activated protein C (APC) resistance relies on the the anticoagulant response to added APC in an activated partial thromboplastin time (APTT) based method. Another method is a Russell Viper venom time (RVVT) based system. To improve the specificity for factor V Leiden of the APTT based method, pre-dilution of test plasma in FV-deficient plasma has recently been recommended. In this study we tested the relative suitabilities of the APTT-based system, the RVVT-based system and their corresponding assays modified by pre-dilution in FV-deficient plasma, for screening asymptomatic subjects, a group of thrombophilic patients (in particular those with low APC ratios), patients on oral anticoagulants, and patients with lupus anticoagulant (LAC). We found the RVVT-based assay to be superior to the APTT-based method in the separation of normals from those with FV Leiden mutation both in asymptomatic subjects and in the thrombophilic patient group. Both modified assays demonstrated a sensitivity and specificity of 100% for FV Leiden, as verified by genotyping in asymptomatic subjects, thrombophilic patients and patients on oral anticoagulants, with the modified RVVT-based assay giving better separation between normals and FV Leiden. Inhibition of phospholipid-dependent coagulation by LAC antibodies rendered the APTT-based system less suitable than the phospholipid-rich RVVT-based one, and as nine of the 20 LAC-positive patients were on warfarin, we showed only the modified RVVT assay to be a reliable predictor of factor V Leiden in this patient group.     

Extensive venous and arterial thrombosis associated with an inhibitor to activated protein C.

Activated protein C resistance (APCR) in the absence of alterations in the factor V gene has been observed during pregnancy, in patients on oral contraceptives, in the presence of antiphospholipid antibodies, and in patients with ischemic stroke. We report a 49-year-old woman with recurrent major venous and arterial thromboses who displayed pronounced APCR, yet no changes in the activated protein C (APC) cleavage sites of factor V. The APCR values determined by four different assays were similar to those obtained in plasma from a homozygote for factor V Q506. Addition of IgG isolated from the patient's serum to normal plasma lowered the APCR ratio from 2.4 to 1.6. Incubation of patient's IgG with normal APC resulted in a profound change in the mobility of APC in crossed immunoelectrophoresis. APC was also shown to bind to patient's IgG immobilized on a protein A agarose column. Factor Va inactivation by APC was inhibited by patient's IgG, but not by control IgG in the presence or absence of either phospholipids or protein S. These results provide evidence for the existence of an acquired antibody against APC in the patient's plasma, which gave rise to the APCR phenotype and was probably responsible for the major thrombotic events. We suggest that acquired APCR due to anti-APC antibodies be considered a potential cause for severe venous and arterial thromboses.     

Use of a generally applicable tissue factor--dependent factor V assay to detect activated protein C-resistant factor Va in patients receiving warfarin and in patients with a lupus anticoagulant

The original activated partial thromboplastin time-based assay for activated protein C (APC)-resistant factor Va (FVa) requires carefully prepared fresh plasma and cannot be used in patients receiving warfarin or in patients with antiphospholipid antibodies. A new test is described here that circumvents these limitations and distinguishes without overlap heterozygotes for APC-resistant FVa from persons with normal FV. A diluted test plasma is incubated with an FV-deficient substrate plasma and tissue factor and then clotted with Ca2+ or Ca2+ plus APC. Test results are independent of the FV level or the dilution of the test plasma used. Of 39 controls, 37 gave normal results. Two controls (5%) gave results indicative of APC resistant FVa and on DNA analysis were found to be heterozygous for FV R506Q. Twenty of 21 randomly selected patients receiving warfarin gave normal results. In the single patient with abnormal results, heterozygous FV R506Q was confirmed by DNA analysis. Two of 15 patients with protein S deficiency and 5 of 29 patients with a lupus anticoagulant had abnormal results. APC resistance caused by FV R506Q was confirmed in the five of these seven patients available for DNA analysis. APC-resistant FVa was also detected in 10 of 21 (46%) stored plasma from unrelated patients with venous thrombosis and negative earlier evaluation for a lupus anticoagulant or a deficiency of protein C, protein S, or antithrombin, which confirms a high incidence of this defect among patients with venous thrombosis.     

Activated protein C resistance: molecular mechanisms based on studies using purified Gln506-factor V

Gln506-factor V (FV) was purified from plasma of an individual homozygous for an Arg506Gln mutation in FV that is associated with activated protein C (APC) resistance. Purified Gln506-FV, as well as Gln506-FVa generated by either thrombin or FXa, conveyed APC resistance to FV-deficient plasma in coagulation assays. Clotting assay studies also suggested that APC resistance does not involve any abnormality in FV-APC-cofactor activity. In purified reaction mixtures, Gln506-FVa in comparison to normal FVa showed reduced susceptibility to APC, because it was inactivated approximately 10-fold slower than normal Arg506-FVa. It was previously reported that inactivation of normal FVa by APC involves an initial cleavage at Arg506 followed by phospholipid- dependent cleavage at Arg306. Immunoblot and amino acid sequence analyses showed that the 102-kD heavy chain of Gln506-FVa was cleaved at Arg306 during inactivation by APC in a phospholipid-dependent reaction. This reduced but measurable susceptibility of Gln506-FVa to APC inactivation may help explain why APC resistance is a mild risk factor for thrombosis because APC can inactivate both normal FVa and variant Gln506-FVa. In summary, this study shows that purified Gln506- FV can account for APC resistance of plasma because Gln506-FVa, whether generated by thrombin or FXa, is relatively resistant to APC.     

Impaired APC cofactor activity of factor V plays a major role in the APC resistance associated with the factor V Leiden (R506Q) and R2 (H1299R) mutations

Activated protein C (APC) resistance is a major risk factor for venous thrombosis. Factor V (FV) gene mutations like FV(Leiden) (R506Q) and FV(R2) (H1299R) may cause APC resistance either by reducing the susceptibility of FVa to APC-mediated inactivation or by interfering with the cofactor activity of FV in APC-catalyzed FVIIIa inactivation. We quantified the APC cofactor activity expressed by FV(Leiden) and FV(R2) and determined the relative contributions of reduced susceptibility and impaired APC cofactor activity to the APC resistance associated with these mutations. Plasmas containing varying concentrations of normal FV, FV(Leiden), or FV(R2) were assayed with an APC resistance assay that specifically measures the APC cofactor activity of FV in FVIIIa inactivation, and with the activated partial thromboplastin time (aPTT)-based assay, which probes both the susceptibility and APC cofactor components. FV(R2) expressed 73% of the APC cofactor activity of normal FV, whereas FV(Leiden) exhibited no cofactor activity in FVIIIa inactivation. Poor susceptibility to APC and impaired APC cofactor activity contributed equally to FV(Leiden)-associated APC resistance, whereas FV(R2)-associated APC resistance was entirely due to the reduced APC cofactor activity of FV(R2). Thrombin generation assays confirmed the importance of the anticoagulant activity of FV and indicated that FV(Leiden) homozygotes are exposed to a higher thrombotic risk than heterozygotes because their plasma lacks normal FV acting as an anticoagulant protein.     

Resistance to activated protein C activity of an anti-/2 -glycoprotein I antibody in the presence of β-glycoprotein I

Some researchers claim that lupus anticoagulant-positive plasma may cause a false-positive reaction in the test for activated protein C (APC) resistance, a hereditary thrombophilic state characterized by abnormal factor V, which frequently causes venous thrombosis, We investigated whether anti-/3₂ -glycoprotein I antibody (aGPI), which has recently come to be regarded as an anti-cardiolipin antibody (aCL) itself, might have an effect on the APC resistance test.     

The impact of oral anticoagulant therapy, factor VIII level and quality of factor V-deficient plasma on three commercial methods for activated protein C resistance.

Several methods are now available for the laboratory assessment of activated protein C resistance (APCR). In this study, we evaluated two activated partial thromboplastin time-based assays [Coatest activated protein C (APC) and Diagen protein C activator (PCA)], with and without predilution of test plasma in factor V-deficient plasma (FVdp) and an amidolytic assay (Immuno Ltd, Vienna, Austria). Testing plasmas from normal volunteers who had received 1-deamino-8-D-arginine vasopressin (DDAVP) also assessed the effect of elevated factor VIII on APCR. In the unmodified clotting tests, the Coatest kit gave overlapping results for normal and heterozygous FV:Q506 samples; some FV:Q506 samples on oral anticoagulant therapy (OAT) were misclassified as normal, and some normal samples with high factor VIII levels would be classified as APC resistant. The unmodified Diagen kit correctly classified these three types of sample, but had the disadvantage that prolonged PCA clotting times gave serious problems with instrument end-point detection. Both kits modified by diluting the samples in FVdp correctly classified all the samples, as well as samples from patients with lupus anticoagulant (LA) and patients receiving heparin. The Immunochrom kit correctly classified the normal and FV:Q506 samples, but would have misclassified most normal persons on OAT as well as some patients with LA or receiving heparin therapy as APC resistant.     

Comparison of anticoagulant and procoagulant activities of stimulated platelets and platelet-derived microparticles

Activation of human platelets considerably enhanced their ability to accelerate factor Va inactivation by activated protein C (APC). The anticoagulant activity of platelet suspensions was markedly dependent on the kind of agonist used to activate platelets. APC-catalyzed factor Va inactivation in free solution was characterized by an apparent second-order rate constant of 2 x 10(5) (mol/L)-1 (seconds)-1. Nonstimulated platelets (2.4 x 10(8)/mL) and platelets stimulated with adenosine diphosphate or adrenalin accelerated factor Va inactivation fourfold. Rates of factor Va inactivation were increased 11-fold by thrombin-stimulated platelets, 29-fold after platelet stimulation with the Ca(2+)-ionophore A23187. At low platelet concentrations (3 x 10(7)/mL) only background levels of anticoagulant activity were observed in platelet suspensions that were nonstimulated or stimulated with thrombin or collagen. However, when such reaction mixtures were stirred during the activation procedure, platelet anticoagulant activity was increased more than 10-fold. Independent of platelet stimulation and stirring conditions, exogenously added purified plasma protein S increased platelet-dependent factor Va inactivation approximately twofold. Addition of a neutralizing antiprotein S antibody had little effect on the anticoagulant activity of platelets. This indicates that, under the reaction conditions tested, platelet-released protein S did not contribute to factor Va inactivation. Approximately 25% of the anticoagulant activity of stimulated platelet suspensions appeared to be associated with microparticles that were released on platelet activation. Such microparticles may provide an important source of anticoagulant activity. A similar distribution of procoagulant, ie, prothrombinase, activity between platelets and microparticles was observed for the same platelet suspensions. Because platelet stimulation and stirring also had the same overall effects on the ability of platelets and platelet microparticles to promote prothrombin activation and factor Va inactivation, it appears likely that the generation of potential platelet anticoagulant and procoagulant activities is coupled to the same platelet stimulation reactions.     

Determination of activated protein C resistance in anticoagulated and lupus positive patients.

Clotting-based activated protein C (APC) assays have limitations when testing patients on oral anticoagulant (OA) therapy or with a lupus anticoagulant (LA). Predilution in factor V (FV)-deficient plasma and testing with phospholipid-rich Russell Viper venom (RVV)-based methods have been shown to be the most suitable methods when testing these patient groups, respectively. We evaluated a modified RVV based clotting test (Gradileiden V test; Gradipore, Sydney, Australia) in a large patient cohort and determined its sensitivity to the FV Leiden mutation. We also examined whether normal plasma can be used to dilute plasma from warfarinized patients without compromising sensitivity to the FV Leiden mutation. A total of 1,956 plasmas were studied including congenital protein C (five plasmas), and protein S deficiency (five plasmas), LA (29 plasmas), FV Leiden heterozygote (102 plasmas), and homozygote (five plasmas), warfarin (54 plasmas), standard heparin therapy (37 plasmas) and normal healthy controls (21 plasmas). Molecular analysis was performed on all samples. The effect of FV Leiden concentration on the APC ratio was examined by determining the APC resistance of a homozygous plasma serially diluted in six sources of normal plasma (NP). The relationship was non-linear and dependent on the initial APC ratio of the chosen source of NP. APC resistance was demonstrated in the varying sources of NP in dilutions of 1/4 (25% FV Leiden) to 1/32 (3% FV Leiden). A 1/2 dilution in pooled NP is recommended for patients on OA therapy because the test remains sensitive at levels of 25% FV Leiden and this is the dilution routinely used for other applications in a coagulation laboratory. The effect of a LA on the APC ratio was similarly studied by determining the APC resistance of a homozygous plasma serially diluted in two sources of LA-positive plasma. This relationship was also non-linear and dependent on the initial APC ratio of the LA-positive plasma. APC resistance was demonstrated in dilutions of 1/16 (6% FV Leiden) to 1/64 (1.5% FV Leiden) demonstrating the sensitivity of the test to APC resistance in the presence of a LA. Our results show the modified RVV-based test clearly predicts the presence of factor V Leiden in a large cohort of patients. The method offers advantages when testing patients with a LA and patients receiving warfarin providing a 1/2 predilution step in pooled NP is performed. Pooled NP does not affect the sensitivity of the test to the mutation, is routinely used in coagulation laboratories, and is considerably less expensive than FV-deficient plasma.     

Inhibition of platelet prothrombinase activity by a lupus anticoagulant

Lupus anticoagulants are spontaneously occurring antibodies with specificity for negatively charged phospholipids. The plasma of a patient with such a polyclonal antibody of IgM type demonstrated low levels of factor VIII coagulant activity (VIII:C) and factors IX, XI and XII when analyzed by biologic clotting assays, whereas in immunochemical assays, normal levels of VIII coagulant antigen and factor IX were obtained. After immunoadsorption of patient plasma with anti-IgM Sepharose, normal biologic activities were demonstrated in clotting assays for VIII:C, factors IX, XI, and XII. The addition of the patient's isolated IgM to normal plasma resulted in grossly abnormal results in these coagulation assays, and a pattern similar to that of the patient's plasma was obtained. The inhibitory effect of the patient's lupus anticoagulant on blood coagulation was demonstrated also in platelet-rich plasma. The results of the clotting assays indicated that the anticoagulant inhibited several of the reactions in the blood coagulation cascade. The availability of purified components made it possible to demonstrate an inhibiting effect on the activation of prothrombin by factor Xa in the presence of isolated platelets, as well as in a system where purified factor V and well defined phospholipid vesicles were substituted for the platelets.