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).     

Effect of rabbit thrombomodulin on thrombin inhibition by antithrombin in the presence of heparin

Thrombomodulin acts as a cofactor for protein C activation by thrombin (PC activation cofactor activity) and inhibits thrombin-induced fibrinogen clotting (direct anticoagulant activity). In addition, rabbit thrombomodulin has been shown to promote thrombin inactivation by antithrombin (AT-dependent anticoagulant activity). However, a non-acidic form (i.e. non-retarded on ion-exchange chromatography) of thrombomodulin generated by limited proteolysis retained only the PC activation cofactor activity. The acidic form (retarded on ion-exchange chromatography) of thrombomodulin is now shown to prevent the rapid inactivation of thrombin by antithrombin in the presence of heparin, presumably by preventing the formation of the ternary thrombin-AT-heparin complex. This effect was not observed with non-acidic thrombomodulin. When submitted to chondroitinase digestion, thrombomodulin was converted into an essentially non-acidic form that lacked both the AT-dependent and the direct anticoagulant activities but showed a PC activation cofactor function indistinguishable from that of native thrombomodulin. This chondroitinase-digested form did not prevent the catalytic effect of heparin on the inhibition of thrombin by AT. It is concluded that the acidic domain of rabbit thrombomodulin, a chondroitin (dermatan) sulfate glycosaminoglycan, interacts with a site of the thrombin molecule that is not involved in the protein C activation cofactor function, but is essential to the cleavage of fibrinogen or binding of heparin.     

Thrombin generation in patients after acute deep-vein thrombosis

Thrombin generation measurement may be of value for assessing the risk of venous thromboembolism, but its long term profile has not been assessed in patients. We evaluated thrombin generation by Calibrated Automated Thrombogram (CAT) in plasma during follow up of 104 consecutive patients after an acute episode of deep venous thrombosis. Blood was drawn three times over the course of 24 months. Thrombin generation was measured in absence and presence of thrombomodulin and compared to a reference range derived from thrombin generation curves in 137 healthy volunteers. Thrombin generation of patients showed significantly higher endogenous thrombin potential (ETP) and peak height compared to the reference population. Differences were more pronounced in assays triggered with 1 pM TF. Inhibition by thrombomodulin was attenuated in patients off anticoagulants as compared to the reference population (21% vs. 42.2%, p < 0.0001); inhibition in patients on anticoagulant treatment was less pronounced (9.7%, p < 0.0001). Protein C activity, protein S antigen as well as free protein S showed highly negative correlation with ETP in all patients. A significant negative relation was found between FVIII levels and thrombomodulin induced reduction of ETP and peak height. In conclusion, thrombin generation by CAT reflects changes in coagulation status in patients following a thromboembolic event and is most sensitive at CAT analysis triggered with 1 pM TF. A role for factor VIII as an important attributable cause of hypercoagulability is reflected by the reduced inhibitory effect of thrombomodulin at high factor VIII levels.     

Regulation of bovine activated protein C by protein S: the role of the cofactor protein in species specificity

The anticoagulant activity of bovine activated Protein C was observed to exhibit species specificity when tested in the plasmas from cow, dog, rabbit, and human. The relative effectiveness in descending order was cow, dog, human, and rabbit. When bovine Protein S was added to each of these plasmas, the species specificity of bovine activated Protein C was lost. No activated Protein C cofactor activity could be detected in either rabbit or human plasma. Bovine activated Protein C enhanced the rate of inactivation of both rabbit and human Factor Va in serum. The rate of activated Protein C catalyzed inactivation of rabbit and human Factor Va could be enhanced by the addition of bovine Protein S. These results indicated that the species specificity of the anticoagulant activity of bovine activated Protein C is mediated by a cofactorenzyme interaction rather than an enzyme-substrate interaction. These results further demonstrated that the anticoagulant activity of activated Protein C is due, in part, to the inactivation of Factor Va.     

Plasma protein oxidation is associated with an increase of procoagulant markers causing an imbalance between pro- and anticoagulant pathways in healthy subjects

The aim of the present study was to investigate whether the overall oxidation state of plasma proteins is associated with changes of circulating pro- and anticoagulant markers in healthy subjects (n = 99, 49 males, 50 females, aged from 6 to 91 yrs.). The carbonyl content of plasma proteins was measured and validated as an ex vivo index of the overall protein oxidation state due to its correlation with the plasma level of o-tyrosine (r = 0.87, P <0.0001), which is a well known oxidized product of L-phenylalanine. Using a multivariate analysis the carbonyl content of plasma protein was positively associated with procoagulant markers such as prothrombin F1 + 2 (r = 0.28, P = 0.0019) and fibrinopeptide A, (FpA) (r = 0.278, P = 0.003), as well as with the soluble derivative of the endothelial protein thrombomodulin (TM) (r = 0.469, P <0.0001). The procoagulant marker of thrombin activity, FpA, was significantly and positively correlated with the anticoagulant product of thrombin, namely the Protein C activation peptide (PCP), only in the tertile with low protein carbonyl content. At higher tertiles this correlation was no longer observed, thus suggesting a detrimental effect of oxidative stress on the TM/Protein C anticoagulant pathway. In 15 subjects with high carbonyl content of plasma protein, treatment for 18 days with 600 mg/d of vitamin E did not substantially modify the protein carbonyl content, the anticoagulant markers APC/PCP, and all procoagulant markers except F1+2, whose value significantly decreased by 25%. In conclusion, the present study shows that a high plasma protein oxidation ex vivo is associated with an overall hemostatic imbalance, which favors procoagulant markers. Vitamin E treatment in vivo restores only in part the equilibrium between pro- and anticoagulant pathways. This may open the way to further studies aimed at elucidating the mechanisms by which the oxidative stress is linked to activation of the coagulation system in atherothrombotic disorders.     

The endothelial cell protein C receptor: its role in thrombosis

The protein C anticoagulant pathway plays a crucial role as a regulator of the blood clotting cascade. Protein C is activated on the vascular endothelial cell membrane by the thrombin-thrombomodulin complex. The endothelial protein C receptor binds protein C and further enhances protein C activation. Once formed, activated protein C down-regulates thrombin formation by inactivating factors Va and VIIIa and exerts cytoprotective effects through endothelial protein C receptor binding. An adequate generation of activated protein C depends on the precise assembly, on the surface of the endothelial cells, of thrombin, thrombomodulin, protein C, and endothelial protein C receptor. Therefore, any change in the efficiency of this assembly may cause a reduction or increase in activated protein C generation and modulate the risk of thrombosis. This review highlights the role of the endothelial protein C receptor in disease and discusses the association of its mutations with the risk of thrombosis.     

Thrombomodulin activity in commercial thromboplastin preparations

Recently, it was reported that endothelial cells contain a membrane protein which serves as a cofactor for the activation of protein C by thrombin (thrombomodulin). Because many commercial thromboplastins are prepared from vessel-rich tissues/organs (lung, brain, placenta), it was hypothesized that some preparations may contain significant amounts of thrombomodulin; theoretically, thrombomodulin contaminations may enhance the prothrombin time. Among 8 different commercial thromboplastins tested two thromboplastins were found to contain significant amounts of thrombomodulin activity: Simplastin (64 U/ml) and Ortho (12.8 U/ml). However, we were unable to demonstrate that the presence of the thrombomodulin activity in these thromboplastins could affect the prothrombin time either by delaying fibrin formation (formation of thrombin-thrombomodulin complexes) or by inhibiting activated factor V (formation of activated protein C).     

Polymorphisms in the endothelial protein C receptor gene and thrombophilia

The protein C anticoagulant pathway plays a crucial role as a regulator of the blood clotting cascade. Protein C is activated on the vascular endothelial cell membrane by the thrombin-thrombomodulin complex. Once formed, activated protein C (APC) down-regulates thrombin formation by inactivating factors (F)Va and FVIIIa. Endothelial protein C receptor (EPCR) is able to bind protein C and increase the rate of protein C activation. Normal APC generation depends on the precise assemblage, on the surface of endothelial cells, of thrombin, thrombomodulin, protein C and EPCR. Therefore, any change in the efficiency of this assemblage may cause reduced/increased APC generation and modify the risk of thrombosis. This review highlights the different mutations/polymorphisms reported in the EPCR gene and their association with the risk of thrombosis.     

The inhibitory effect of recombinant human soluble thrombomodulin on initiation and extension of coagulation--a comparison with other anticoagulants

Recombinant human soluble thrombomodulin (rhsTM) was compared with various anticoagulants for in vitro anticoagulant effects on thrombin generation, clotting time, and thromboelastography. rhsTM as well as APC reduced the level of the peak of the thrombin generation curve, but we did not observe any time-delay to reach the peak. This effect of rhsTM was diminished in PC-deficient plasma and was closely associated with the inhibitory effect on prothrombinase and factor Va. On the other hand, hirudin and argatroban delayed the time to reach the level of the peak, without reducing it. rhsTM and other anticoagulants except for activated protein C (APC) were found to have concentration-dependent anticoagulant activity by conventional clotting tests. However, the concentration of rhsTM for clotting time was slightly affected by anti-protein C antibody. Moreover, the concentration of rhsTM required to inhibit thrombin activity directly was 50 times higher than that needed to inhibit thrombin generation. The effect of rhsTM on clot development was compared with that of other anticoagulants by thromboelastography; rhsTM reduced the growth of the clot but had little effect on the time to activate clotting, while the other anticoagulants had the opposite effect. This effect of rhsTM was completely abolished by the addition of anti-protein C or anti-protein S antibody. These findings suggest that rhsTM attenuates blood clotting by reducing the level of generated thrombin through protein C activation and subsequent factor Va inactivation and prothrombinase inhibition.     

Alpha 2-macroglobulin enhances prothrombin activation and thrombin potential by inhibiting the anticoagulant protein C/protein S system in cord and adult plasma

Protein S (PS) is a vitamin K-dependent plasma protein and serves as a cofactor for the anticoagulant activities of activated protein C (APC). We investigated the effects of different PS concentrations on prothrombin activation and thrombin generation in cord and adult plasma containing APC and different amounts of alpha 2-macroglobulin (a2-M). Prothrombin activation was assessed by monitoring the time-course of prothrombin fragment 1+2 (F1+2) generation. Thrombin generation curves were determined by means of a subsampling technique using the chromogenic substrate S-2238. We demonstrate a dose-dependent inhibition of the anticoagulant action of PS by a2-M: suppression of F1+2 and thrombin generation due to addition of PS was stronger in plasma containing low amounts of a2-M than in plasma with elevated a2-M levels. Since no complex formation between a2-M and PS was observed by means of SDS-PAGE, we attribute decreased anticoagulant action of PS at high a2-M levels to enhanced complex formation between APC and a2-M. Thereby, APC is subtracted from its cofactor PS, resulting in suppressed formation of the anticoagulant APC/PS complex. Thus, our data suggest that a2-M, besides its well-known anticoagulant effects, also acts as a procoagulant by suppressing the formation of the anticoagulant APC/PS complex. Our findings have implications particularly on thrombin generation and inhibition in cord plasma, since a2-M levels in newborns are elevated over adult values and the antithrombotic APC/PS pathway is up-regulated at birth. Therefore, elevated levels of a2-M might restrict the up-regulation of the APC/PS pathway.     

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.     

Modification of human thrombin: effect on thrombomodulin binding

Thrombomodulin, an endothelial cell protein, binds thrombin with high affinity and alters thrombin from a procoagulant to an anticoagulant molecule. In this study, chemical and/or proteolytic modification of thrombin was carried out to identify the essential components required for its interaction with thrombomodulin. Modification of thrombin at the catalytic site serine and histidine residues, with Diisopropylfluorophosphate and Tosyl-L-lysine chloromethyl ketone, resulted in loss of clotting and amidolytic activity. Both Diisopropyl phosphoryl-thrombin and Tosyl-L-chloromethyl ketone-thrombin inhibited native-thrombin: thrombomodulin catalyzed protein C activation with Ki values of 5 nM and 6 nM respectively indicating no loss of affinity for thrombomodulin. Oxidation of tryptophan residues with N-bromosuccinimide or iodination of tyrosine residues of thrombin led to reduced clotting and amidolytic activity as well as a reduced ability to interact with thrombomodulin. Modification of arginine residues with Phenylglyoxal and 2,3,Butanedione led to loss of thrombomodulin binding affinity. Limited proteolysis of thrombin by trypsin yielded the derivative beta-thrombin which had also lost its ability to interact with thrombomodulin. Deglycosylation of thrombin did not alter its binding affinity for thrombomodulin. These results indicate that one or more tryptophan, arginine and tyrosine residues are essential for the recognition of thrombin by thrombomodulin whilst the carbohydrate side chain and the active site residues of the thrombin molecule are not involved in thrombomodulin binding.     

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 structure-function relationship of activated protein C. Lessons from natural and engineered mutations

Protein C is the central enzyme of the natural anticoagulant pathway and its activated form APC (activated protein C) is able to proteolyse non-active as well as active coagulation factors V and VIII. Proteolysis renders these cofactors inactive, resulting in an attenuation of thrombin formation and overall down-regulation of coagulation. Presences of the APC cofactor, protein S, thrombomodulin, endothelial protein C receptor and a phospholipid surface are important for the expression of anticoagulant APC activity. Notably, APC also has direct cytoprotective effects on cells: APC is able to protect the endothelial barrier function and expresses anti-inflammatory and anti-apoptotic activities. Exact molecular mechanisms have thus far not been completely described but it has been shown that both the protease activated receptor 1 and EPCR are essential for the cytoprotective activity of APC. Recently it was shown that also other receptors like sphingosine 1 phosphate receptor 1, Cd11b/CD18 and tyrosine kinase with immunoglobulin-like and EGF-like domains 2 are likewise important for APC signalling. Mutagenesis studies are being performed to map the various APC functions and interactions onto its 3D structure and to dissect anticoagulant and cytoprotective properties. The results of these studies have provided a wealth of structure-function information. With this review we describe the state-of-the-art of the intricate structure-function relationships of APC, a protein that harbours several important functions for the maintenance of both humoral and tissue homeostasis.     

Influence of coagulation factors and tissue factor concentration on the thrombin generation test in plasma

The thrombin generation test is used to study coagulation in patients with haemorrhagic diseases or with high thrombotic risk. To our knowledge, this is the first study investigating the relative influence of coagulation factors on thrombin generation in plasma. The aim was to investigate the influence of coagulant factors, anticoagulant factors, and tissue factor (TF) on three parameters: endogenous thrombin potential (ETP), peak thrombin concentration, and lag time for the appearance of thrombin. At a low TF concentration, all factors except factor XI influenced thrombin generation. At a high TF concentration, only the factors of the extrinsic pathway exerted an influence. ETP and peak thrombin were linearly correlated to factor II concentration. Factor V and factor VII effects increased hyperbolically with factor concentration. The influence of factor X on thrombin generation depended on TF concentration. In the absence of factor VIII and factor IX, ETP fell to 60-70% of the normal when peak thrombin fell to 25-30% of the normal. Fibrinogen concentration influenced ETP and peak thrombin and decreasing fibrinogen levels shortened the lag time. As expected, decreasing antithrombin concentration caused dramatic increases in thrombin generation. Protein S prolonged the lag time, especially at a low TF concentration. No effect of protein C was observed, likely due to the absence of thrombomodulin. The thrombin generation test was more sensitive to factor deficiencies at low than at high TF concentration. ETP was not the most critical parameter for studying coagulation factor deficiencies. Instead, peak thrombin was the most sensitive parameter.     

Endogenous heparinase-sensitive anticoagulant activity in human plasma.

In this paper we show that an anticoagulant activity, which we measure by thrombin time, appears in human plasma after its exhaustive proteolytic digestion. This activity is extremely heat stable, it is resistant to chondroitin ABC lyase (E.C.4.2.2.4) and heparan sulfate lyase (E.C.4.2.2.8), it is sensitive to heparin lyase (E.C.4.2.2.7) and to nitrous acid treatment: we suggest that it can be identified as authentic heparin. The amount present in 1 ml of plasma of healthy subjects corresponds to 0.1-0.2 I.U. of standard heparin (150 I.U./mg). Proteolytically digested human plasma was submitted to ion-exchange chromatography on DEAE-Sephacel and the anticoagulant activity in the fractions eluted at the different molarities of NaCl was measured by thrombin time. This analysis shows that the anticoagulant activity elutes at very low ionic strength. The possibility that interactions of the endogenous heparin with proteins or protein fragments are responsible for the difficulty in isolating heparin from human plasma is discussed.     

Preparation of succinylthrombin and its effects in vivo on the coagulation system

An innovative chemically modified thrombin, succinylthrombin, was prepared by the treatment of thrombin with succinic anhydride. Succinylthrombin showed a remarkable reduction of fibrinogen clotting activity with a reduction of the potency for protein C (PC) activation. However, the degree of the remaining potency for PC activation was greater than the degree of the remaining clotting activity. The potency for PC activation was enhanced by the addition of thrombomodulin and calcium ion. The degree of the enhancement was approximately 6-times greater than that of acetylthrombin, which we previously suggested as an effective anticoagulant. The infusion of succinylthrombin into rabbits induced a prolongation of the activated partial thromboplastin time (APTT). The fibrinogen level was not affected even by the infusion of succinylthrombin of a dose which cause the prolongation of the APTT to the same extent as that following an infusion of thrombin. The factor Xa clotting time was also prolonged by the succinylthrombin without any significant drop in the number of the circulating platelet.     

Control of thrombin mediated cleavage of protein S

Thrombin has been shown to cleave the vitamin K dependent cofactor protein S with subsequent loss of its cofactor activity. This study examines the control mechanisms for thrombin cleavage of protein S. The anticoagulant activity of activated protein C (APC) is enhanced fourteen fold by the addition of protein S. Thrombin cleaved protein S is seven fold less efficient than the native protein, and this loss of activity is due to reduced affinity of cleaved protein S for APC or the lipid surface compared to the intact protein. In the absence of Ca++, protein S is very sensitive to minimal concentrations of thrombin. As little as 1.5 nM thrombin results in complete cleavage of 20 nM protein S in 10 min and loss of cofactor activity. Ca++, in concentrations greater than 0.5 mM, will inhibit this cleavage and in the presence of physiological Ca++ concentrations, no cleavage of protein S could be demonstrated in spite of high concentrations of thrombin (up to 1 microM) and prolonged incubations (up to two hours). The endothelial surface protein thrombomodulin is very efficient in inhibiting the cleavage of protein S by thrombin suggesting that any thrombin formed on the endothelial cell surface is unlikely to cleave protein S, thus allowing the intact protein to act as a cofactor to APC. We conclude that the inhibitory effects of Ca++ and thrombomodulin on thrombin mediated cleavage of protein S imply that this event, by itself, is unlikely to represent a physiological control of the activity of protein S.     

Low levels of the anticoagulant activity of protein C in patients with chronic renal insufficiency: an inhibitor of protein C is present in uremic plasma.

Twenty-nine of 54 uremic patients had low levels of protein C measured as anticoagulant activity, contrasting with normal levels measured as amidolytic activity or antigenic concentration. We demonstrate that this discrepancy is due to the presence of a soluble plasma inhibitor that interferes specifically with the anticoagulant activity of activated protein C. The inhibitor does not interfere with other coagulation assays. It is resistant to diisopropylfluorophosphate, high temperatures and repeated freezing and thawing. It can be dissociated from protein C by anti-protein C antibodies or by dialysis in vitro and in vivo. It binds to positively charged resins and can be eluted with high salt concentrations without losing its inhibitory capacity. The inhibitory effect is correlated with plasma creatinine levels and fluctuates with time.     

Protein C inhibitor: Purification and proteinase reactivity

Protein C inhibitor was purified from human plasma by a modification of a published procedure (Suzuki, K., Nishioka, J., and Hashimoto, S. J. Biol. Chem. 258, 163–168, 1983). Approximately 1 mg of pure protein was obtained from 1 L plasma, a yield of about 17%. The protein C inhibitor preparation did not lose activity over 4 weeks at 4°C. Second order rate constants were measured for the inhibition of activated protein C, thrombin, and urokinase, and bimolecular complexes of protein C inhibitor with activated protein C and thrombin were visualized by denaturing polyacrylamide gel electrophoresis. Heparin accelerated the inhibition of the three proteinases in a manner consistent with a template mechanism. Plasma or pure protein C inhibitor (at the same concentration) showed the same effect of heparin on activated protein C inhibition, indicating that protein C inhibitor accounts for all the heparin-dependent inhibition of activated protein C in vivo.