Impairment of the protein C anticoagulant pathway in a patient with systemic lupus erythematosus, anticardiolipin antibodies and thrombosis

We have identified an inhibitor of the protein C anticoagulant pathway in the plasma of a patient with systemic lupus erythematosus and a history of recurrent deep vein thrombosis, fetal wastage, and seizures. The patient's plasma contained anticardiolipin antibodies as well as a weak lupus anticoagulant. Examination of this patient's plasma revealed normal levels of protein C and protein S antigen, normal levels of functional protein C, as well as essentially normal levels of every blood coagulation factor. In a modified prothrombin time assay, the activated protein C-mediated prolongation of the clotting time observed in normal plasma was not observed in this patient's plasma. Gel permeation chromatography of the patient's plasma revealed that the inhibitory material was a high molecular weight protein that coeluted with the IgM peak. The inhibitor did not appear to circulate as a complex with protein C, since the inhibitor could easily be separated from protein C during fractionation procedures, and did not interfere with the activation of protein C in plasma as assessed by a functional amidolytic assay. Our findings suggest that the recurrent thrombotic episodes observed in this patient may have occurred as a result of the patient's antiphospholipid antibody neutralizing specific phospholipids essential for the full expression of the anticoagulant activity of activated protein C.     

Species specificity of the fibrinolytic effects of activated protein C.

Activated protein C (APC) has been shown to stimulate fibrinolysis in both in vitro and in vivo experimental systems. In order to test the importance of protein S in the fibrinolytic activity of APC we have compared the activity of APC, prepared from rabbit, bovine and human plasma, in the stimulation of whole blood clot lysis, the inactivation of plasminogen activator inhibitors and anticoagulant activity. When whole blood clot lysis was performed using tissue plasminogen activator in either human or rabbit blood, APC was found to enhance clot lysis in a species specific manner that paralleled the pattern observed for its anticoagulant activity. Bovine APC, was the poorest stimulator of fibrinolysis in human plasma. However, if bovine protein S was also added to human plasma, bovine APC was as effective in promoting fibrinolysis as human APC. In contrast, no species specific effects on the inactivation of plasminogen activator inhibitor activity was observed. Though substantial effects of APC on plasminogen activator inhibitor levels were made by rabbit, human and bovine activated protein C in human plasma, there was no effect of activated protein C on the rate of clot lysis of human plasma. These results suggest that protein S is important for the expression of the fibrinolytic activity of activated protein C and that the effect of protein S may be useful for the differentiation of fibrinolytic effects of activated protein C that may be related to the inactivation of plasminogen activator inhibitors and those that are not.     

A simplified PTT-based protein C activity assay using the thrombin-thrombomodulin complex

A simplified assay for protein C activity in plasma is described which uses the ability of rabbit lung thrombomodulin to inhibit the procoagulant activity of thrombin while stimulating protein C activation. Barium eluates of plasma are activated for one hour at 37 degrees C by a mixture of human thrombin and rabbit lung thrombomodulin at concentrations which neutralize each other's effect on the kaolin-cephalin activated partial thromboplastin time (PTT). Protein C anticoagulant activity in the activated eluates is then measured directly in the PTT. The method is independent of protein S levels in the test samples, and is suitable for warfarinized and heparinized plasma. Protein C levels obtained with this method correlate closely with functional levels of vitamin K-dependent procoagulants as measured by the prothrombin and proconvertin time (P&P) in normal subjects and in patients receiving warfarin, indicating specificity for gamma-carboxylated protein C. The method has the potential to detect molecular variants defective in any of the interactions required for generation of anticoagulant activity in vivo.     

Effect of protein C and activated protein C on coagulation and fibrinolysis in normal human subjects

Although protein C (PC) and activated protein C (APC) have been postulated to be useful for treating patients with thrombosis, their critical effect remains to be studied in human subjects. To examine whether purified PC or APC are useful for treating patients with thrombosis without showing any adverse effect, we studied effects on coagulation and fibrinolysis in normal human subjects. When highly purified human PC was administered intravenously to healthy subjects, plasma levels of immunoreactive PC decreased with a half-life of 10.9 h. Intravenously administered APC decreased with a half-life of 23 min as measured by prolongation of activated partial thromboplastin time (APTT). However, 1.7 h was obtained for the plasma half-life of APC when it was measured immunologically. These findings suggested that a significant fraction of the administered APC was rapidly inhibited by plasma inhibitor. Upon administration of APC, APTT was prolonged and plasma levels of clotting factor VIII (F-VIII) decreased transiently as measured by clotting assay. However, when determined by a chromogenic assay method in which 120-fold diluted plasma samples were used, plasma levels of F-VIII remained unchanged. Plasma levels of F-V did not decrease after APC administration. These findings suggested that prolongation of APTT and apparent decrease in plasma F-VIII clotting activity might be due to the in vitro-effect of APC present in plasma samples used. Diurnal fluctuation of plasminogen activator inhibitor in normal subject was not affected by administration of APC. Thus, PC or APC seems to function selectively at the site of thrombin-formation without lowering plasma levels of coagulation factors.     

A functional assay of protein C in human plasma

A functional assay for protein C in plasma is described in which barium eluates of plasma are incubated with bovine thrombin and rabbit thrombomodulin to activate protein C. The activated protein C solution is added to an activated partial thromboplastin time (APTT) system containing normal plasma and an APTT reagent (Dade ActinR). The prolongation of coagulation time after recalcification in this system is taken as a measure of the anticoagulant activity of protein C. When expressed as per cent of the value in pooled normal plasma, the results obtained by this method in 34 normal controls and in 3 untreated patients with protein C deficiency were very similar to those obtained by radioimmunoassay of protein C. In 2 patients with protein C deficiency and 23 patients without, all on dicoumarol or warfarin treatment, the anticoagulant activity of protein C was less than its antigen concentration. The day to day analytical coefficient of variation (SD/mean) was 12% at the 100% level (n = 12), and 10% at the 25% level (n = 12).     

Variations of protein C in uremic hemodialysed patients

Protein C has been measured by three different assays (antigenic, amidolytic and chronometric) in 27 end-stage renal insufficient patients before and after hemodialysis. Protein C levels have been compared with other coagulation inhibitors (antithrombin III, protein S) and fibrinolytic parameters. Baseline anticoagulant activity of protein C has been found impaired in eight cases whereas other inhibitors were normal. In four cases, both anticoagulant and antigenic levels were low. In one case, amidolytic method could also found a low activity. Hemodialysis leads to an increase of protein C activity and antigen level. Heparinemia after hemodialysis does not interfere with the chronometric measurement of protein C anticoagulant activity. Total protein level, hematocrit, protein S and antithrombin III are also elevated after hemodialysis. Baseline fibrinolytic parameters are normal and remain unchanged after hemodialysis. The clinical relevance of such modifications is discussed.     

Studies on human protein C inhibitor in normal and factor V/VIII deficient plasmas

Activated protein C is a potent anticoagulant which inactivates Factors V and VIII in plasma. Normal plasma contains an inhibitor of activated protein C. A previous report from our laboratory hypothesized that the absence of this inhibitor in plasmas from patients with combined Factor V/VIII deficiency could be the molecular basis for this disease. This report demonstrates the presence of protein C inhibitor in those Factor V/VIII deficient plasmas originally studied. Freezing and thawing significantly reduced the ability of normal and Factor V/VIII deficient plasmas to inhibit activated protein C. It is suggested that this explains the conflicting literature reports describing functional assays of protein C inhibitor in Factor V/VIII deficient plasma. This observation also emphasizes that extreme care must be used in handling and storing plasma samples that are to be assayed for protein C inhibitor.     

Protein C: Rouen, a new hereditary protein C abnormality with low anticoagulant but normal amidolytic activities

A family is described in which venous thrombo-embolic disease is associated with reduced plasma protein C anticoagulant activity but normal levels of protein C amidolytic activity and antigen. The partial characterization of the heterozygous defect is described using crossed immunoelectrophoresis (CIE) with or without calcium and seven functional assays which differ by activators (thrombin-thrombomodulin complex, bovine thrombin and Protac snake venom) and by an eventual preliminary adsorption on insoluble salts. PC activity was thereafter determined either by chronometric or amidolytic assays. The results indicate that this abnormal protein C (PC) is normally activated and at least partially carboxylated. Three hypothesis are proposed to explain the discrepancy between normal amidolytic and low anticoagulant activities.     

The Ser460Pro mutation in recombinant protein S Heerlen does not affect its APC-cofactor and APC-independent anticoagulant activities

Protein S is a vitamin K-dependent plasma protein that functions as an APC-cofactor, but also exhibits anticoagulant activity in the absence of APC. The Heerlen polymorphism of protein S is characterized by a Ser460Pro substitution and lacks glycosylation at Asn458. It is associated with decreased protein S levels due to selective deficiency of free protein S Heerlen. To understand the lack of thrombotic complications associated with the protein S Heerlen mutation, we compared recombinant protein S Heerlen, wild type (wt) protein S and plasma-derived protein S. wt-Protein S and protein S Heerlen each bound 1:1 to C4BP with dissociation constants of 0.27 and 0.33 nM, respectively. Both wt-protein S and protein S Heerlen, either free or in complex with C4BP, were equally active as prothrombinase inhibitors in the absence of APC. All three protein S preparations stimulated APC-catalyzed inactivation of normal FVa, FVa Leiden and FVIIIa to the same extent. If extrapolated to plasma, it is not likely that the decreased free protein S levels in carriers of the protein S Heerlen mutation are compensated by an increased anticoagulant activity of protein S Heerlen-C4BP complexes. It is possible that an unrecognized plasma factor selectively enhances the anticoagulant activity of protein S Heerlen. If not, the reduction of free protein S levels in heterozygous protein S Heerlen-carriers combined with (low) normal total protein S levels apparently minimally affects the total anticoagulant activity of protein S (APC-cofactor and APC-independent activity) and hence is not associated with increased risk of venous thrombosis.     

Role of each Asn-linked glycan in the anticoagulant activity of human protein C inhibitor

The N-glycosylation site mutants of human protein C inhibitor (PCI; N230S, N243Q, N319Q, N230S/N243Q, and N230S/N319Q) were prepared by amino acid replacement of the asparagine residue with a serine or glutamine residue using site-directed mutagenesis and expressed in the baculovirus/insect cell expression system. To examine the importance of each Asn-linked glycan in the activity of PCI, we compared wtPCI with the mutants of N-glycosylation site(s) in terms of the procoagulant protease-inhibitory and anticoagulant activities. The inhibitory activities of N230S, N319Q, and N230S/N319Q toward human thrombin and plasma kallikrein were significantly increased compared with wtPCI, but those of N243Q and N230S/N243Q were reduced. The inhibitory activity of N230S toward human plasma coagulation was significantly increased compared with wtPCI, and that of N230S/N319Q was also significantly increased compared with N319Q. Furthermore, the procoagulant protease-inhibitory and anticoagulant activities of N230S/N319Q (glycosylated on Asn243 only) compared favorably with those of N230S, and both of the mutants possessed highest activities in the purified mutants. These results suggest that the Asn243-linked glycan in PCI molecule possesses critical roles for its anticoagulant activity in the circulation, and the Asn230-linked glycan down-regulates the activity of PCI.     

Antithrombotic activity of protein S infused without activated protein C in a baboon thrombosis model

Protein S (ProS) is an essential plasma protein that enhances the anticoagulant activity of activated protein C (APC). In vitro , purified native human Zn2+-containing ProS also exerts direct anticoagulant activity by inhibiting prothrombinase and extrinsic FXase activities independently of APC. We investigated antithrombotic effects of ProS infused without APC in a baboon shunt model of thrombogenesis that employs a device consisting of arterial and venous shear flow segments. In in vitro experiments, the Zn2+-containing human ProS used for the studies displayed >10-fold higher prothrombinase inhibitory activity and anticoagulant activity in tissue factor-stimulated plasma, and four-fold higher inhibition of the intrinsic pathway than the Zn2+-deficient ProS used. In the thrombosis model, ProS (33 μg/minute for 1 hour) or saline was infused locally; platelet and fibrin deposition in the shunt were measured over 2 hours. During experiments performed at 50 ml/minute blood flow, Zn2+-containing ProS inhibited platelet deposition 73-96% in arterial-type flow segments and 90-99% in venous-type flow segments; Zn2+-deficient ProS inhibited platelet deposition 52% in arterial-type flow segments and 65-73% in venous-type flow segments. At 100 ml/min blood flow rate, Zn2+-containing ProS inhibited platelet deposition by 39% and 73% in the respective segments; Zn2+-deficient ProS inhibited platelet deposition by 5% and 0% in the respective segments. Zn2+-containing ProS suppressed fibrin deposition by 67-90%. Systemic APC-independent ProS activity was significantly increased and thrombin-antithrombin complex levels were significantly decreased after infusion of ProS. Thus, infused human Zn2+-containing ProS is antithrombotic in primates, and may have therapeutic potential even in protein C-deficient human patients.     

Functional assays for protein C activity and protein C inhibitor activity in plasma

An assay system for protein C (PC) activity and PC-inhibitor in plasma was developed. The assay was based on: (1) binding of PC to wells of a microtiter plate coated with a murine monoclonal anti-PC antibody (C3) that did not interfere with the activity or activation of PC; (2) activation of immobilized PC with Protac C; (3) incubation with or without a source of activated PC inhibitor; and (4) measurement of amidolytic activity using the substrate S-2366. The activity assay was specific for PC and sensitive to less than 1 microliter of plasma or 4 ng PC. Inhibition of activated PC by plasma followed pseudo first order kinetics. Heparin caused a dose dependent increase in the inhibition rate with half maximal stimulation at approximately 3 U/ml and maximal stimulation at heparin concentrations greater than or equal to 10 U/ml. This assay is suitable not only for determination of functional plasma levels of PC and PC inhibitor activities but also for kinetic studies of inhibition of activated PC in complex systems, such as plasma. Studies showed that urokinase interfered with the inhibition of APC by plasma inhibitor(s).     

Inhibition of human factor VIIa-tissue factor activity by placental anticoagulant protein

Previous studies indicated that human placental anticoagulant protein, a member of the lipocortin family, prolonged the clotting time of normal plasma when clotting was induced by brain thromboplastin or by kaolin in the presence of cephalin and calcium. Using a two-stage amidolytic assay to assess factor X activation and a tritiated peptide release assay to assess factor IX activation, we have examined the ability of purified preparations of placental anticoagulant protein (Mr = 36.5 kDa) to inhibit the activation of either factor X or factor IX by a complex of human factor VIIa-tissue factor. Placental anticoagulant protein markedly inhibits factor X and factor IX activation by factor VIIa-tissue factor in a non-competitive manner with Ki values of 40 nM and 70 nM, respectively. Placental anticoagulant protein had no effect on factor Xa amidolytic activity, and its inhibitory activity was not diminished by prior incubation with antibody raised against partially purified plasma extrinsic pathway inhibitor. Binding of placental anticoagulant protein to phospholipid vesicles, crude tissue factor and purified, relipidated human brain tissue factor apoprotein was observed only in the presence of calcium ions. These results indicate that placental anticoagulant protein is a potent factor VIIa-tissue factor inhibitor and suggests that its mechanism of action involves binding to the phospholipid portion of the tissue factor lipoprotein.     

Interspecies loop grafting in the protease domain of human protein C yielding enhanced catalytic and anticoagulant activity.

Human anticoagulant activated protein C (hAPC) is less potent than the bovine APC (bAPC) molecule and our aims were to elucidate the molecular background for this difference and to create an APC with enhanced anticoagulant activity. In the protease domain of human protein C (hPC), the loop 148 (GWGYHSSREKEAKRN) is four residues longer than the corresponding loop in bovine APC (GWGY RDETKRN). To investigate whether this caused the species difference, the loop in hPC was replaced by the shorter bovine loop, whereas the longer human loop was introduced in bovine protein C. The mutation in hAPC yielded enhanced catalytic activity against chromogenic (4-fold) as well as natural (factors Va and VIIIa) substrates and 2-3-fold increased anticoagulant activity. The opposite effects were obtained with the bovine mutant. As compared to wild-type hAPC, the mutant hAPC was inhibited slightly faster by the protein C inhibitor, whereas the inhibition by alpha1-antitrypsin was unaffected by the mutation. A computer model of bAPC was developed in order to analyse further our data. Collectively, our results demonstrate enhanced catalytic efficiency to result from mutagenesis in the loop 148 and show that APC mutant with increased anticoagulant activity can be created.     

Enhancement of protein S anticoagulant function by beta2-glycoprotein I, a major target antigen of antiphospholipid antibodies: beta2-glycoprotein I interferes with binding of protein S to its plasma inhibitor, C4b-binding protein.

Thrombosis in the antiphospholipid syndrome has been associated with acquired deficiency of the anticoagulant protein S. We sought evidence that beta2-glycoprotein I, a major target antigen for antiphospholipid antibodies, is involved in regulation of protein S activity. Incubation of purified protein S or plasma with beta2-glycoprotein I reversed functional modulation of protein S by its plasma inhibitor, the C4b-binding protein. In a plasma-free ELISA, beta2-glycoprotein I prevented the binding of protein S and C4b-binding protein when preincubated with immobilized protein S but not when similarly preincubated with C4b-binding protein. beta2-glycoprotein I in fluid phase interfered with precipitation of protein S by sepharose-bound C4b-binding protein. Effects of beta2-glycoprotein I on protein S function were inhibited by one of four monoclonal anti-beta2-glycoprotein 1 antibodies. These data suggest that beta2-glycoprotein I helps maintain adequate plasma levels of circulating free, active protein S. Antiphospholipid (anti-beta2-glycoprotein I) antibodies might cause sporadic thrombosis, at least in part, by impairing this novel regulatory mechanism.     

The anticoagulant properties of a modified form of protein S

Protein S (PS) is a vitamin K-dependent anticoagulant that acts as a cofactor to activated protein C (APC). To date PS has not been shown to possess anticoagulant activity in the absence of APC. In this study, we have developed monoclonal antibody to protein S and used to purify the protein to homogeneity from plasma. Affinity purified protein S (PSM), although identical to the conventionally purified protein as judged by SDS-PAGE, had significant anticoagulant activity in the absence of APC when measured in a factor Xa recalcification time. Using SDS-PAGE we have demonstrated that prothrombin cleavage by factor Xa was inhibited in the presence of PSM. Kinetic analysis of the reaction revealed that PSM competitively inhibited factor Xa mediated cleavage of prothrombin. PS preincubated with the monoclonal antibody, acquired similar anticoagulant properties. These results suggest that the interaction of the monoclonal antibody with PS results in an alteration in the protein exposing sites that mediate the observed anticoagulant effect. Support that the protein was altered was derived from the observation that PSM was eight fold more sensitive to cleavage by thrombin and human neutrophil elastase than conventionally purified protein S. These observations suggest that PS can be modified in vitro to a protein with APC-independent anticoagulant activity and raise the possibility that a similar alteration could occur in vivo through the binding protein S to a cellular or plasma protein.     

Treatment of hereditary protein C deficiency with stanozolol

Five type I protein C deficient male patients received 5 mg stanozolol b.i.d. during 4 weeks. After four weeks of treatment plasma protein C activity increased from 0.42 to 0.74 U/ml and protein C antigen from 0.49 to 0.75 U/ml. This approximately 1.6 fold increase in plasma protein C was accompanied by an increase in factor II antigen (1.5 fold), factor V activity (1.6 fold), factor X antigen (1.1 fold), antithrombin III antigen (1.3 fold) and heparin cofactor II antigen (1.5 fold), while the concentration of factor VII, factor VIII, and factor IX activity, and of protein S antigen remained unchanged. Prothrombin fragment F1+2, measured in two patients, increased 1.3 fold. In addition to its effect on procoagulant and anticoagulant factors stanozolol had profibrinolytic effects, reflected in an increase in tPA activity and in the concentration of plasminogen. These data indicate that in type I protein C deficient patients stanozolol increases the concentrations of both procoagulant and anticoagulant factors and favours fibrinolysis. The efficacy of stanozolol in preventing thrombotic disease in type I protein C deficient patients, however, remains to be established. During the four weeks of stanozolol treatment no thrombotic manifestations were observed in the protein C deficient patients.     

Behavior of protein S during long-term oral anticoagulant therapy

It has recently been reported that a natural anticoagulant, protein S (PS), is depressed during oral anticoagulation. Since more detailed information is required from the clinical standpoint, we measured plasma levels of PS [both total and free (not complexed) PS antigen], C4b-binding protein (C4bp) and other vitamin K-dependent proteins (factors II, VII, IX, X and protein C) in 60 plasma samples from patients on long-term oral anticoagulant therapy with warfarin. Together with the reduction of other vitamin K-dependent plasma proteins, PS decreased during warfarin treatment, being dependent on the intensity of the therapy. A considerable variation in plasma PS levels was also observed among individuals with a similar intensity of anticoagulation. Plasma concentration of C4bp was closely correlated with total PS level, and free PS/total PS ratio was independent of thrombotest values. These findings indicate that long-term oral anticoagulant therapy results in the suppression of the synthesis of PS, and that its reduction is on the whole balanced with C4bp and vitamin K-dependent coagulation factors. It was suggested that the metabolism of C4bp might be regulated by the plasma PS level, although this hypothesis needs further exploration.     

TFPI-dependent activities of protein S

Protein S is an essential anticoagulant protein that acts as a cofactor for full length tissue factor pathway inhibitor (TFPI) and activated protein C (APC) in the down regulation of coagulation. Protein S enhances APC-mediated inactivation of the coagulation factors Va and VIIIa, and it stimulates inhibition of factor (F)Xa by TFPI. Because TFPI is a tight binding, but slow inhibitor of FXa, the TFPI/protein S system fails to regulate FXa generation at high tissue factor/FVIIa concentrations. In this review, we explain how TFPI/protein S can regain its activity at high tissue factor concentrations in the presence of APC, resulting in an intertwinement of TFPI- and APC-cofactor activities of protein S, and making TFPI a major determinant of APC-anticoagulant activity in plasma.     

Effect of oral contraceptives on the anticoagulant activity of protein S in plasma

We determined anticoagulant parameters that depend on protein S function in plasma, i.e. the APC-independent anticoagulant activity of protein S (expressed as pSR) and APC resistance determined with thrombin generation-based tests (expressed as APCsr) as well as plasma levels of total and free protein S and prothrombin in men, women not using oral contraceptives (OC), and in women using second or third generation OC. Thrombin generation in the APC resistance assays was initiated either with factor Xa (Xa-APCsr) or tissue factor (TF-APCsr). The APC-independent anticoagulant activity of protein S was highest in men (pSR=1.69) and gradually decreased from women not using OC (pSR=1.49) via women using second generation (pSR=1.35) to women using third generation OC (pSR=1.27). The pSR correlated inversely with nAPCsr determined with the tissue factor-based APC resistance test (TF-APCsr) but not with nAPCsr determined with the factor Xa-based assay (Xa-APCsr). Multiple linear regression analysis in which sex, OC use, and protein S and prothrombin levels were included as independent variables and the pSR, TF-APCsr or Xa-APCsr as dependent variables indicated that plasma protein S levels poorly predict the pSR and the TF-APCsr, but are the main determinant of the Xa-APCsr. This indicates that OC use alters the expression of protein S activity. This phenomenon can be caused by differences in modulation of the activity of protein S by other plasma proteins that change during OC use or by OC-induced changes in the protein S molecule that impair its anticoagulant activity. Functional impairment of protein S as a result of hormonal influence may, at least in part, contribute to the thrombotic risk of OC users.