Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.6 (thromboplastin)
 13,278 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Protein S is a vitamin K-dependent non-enzymatic coagulation factor involved in the regulation of activated protein C (APC). In this paper we report an APC-independent anticoagulant function of protein S. We observed an inhibition of prothrombinase activity on endothelial cells and platelets which was half-maximal at physiological concentrations of free protein S in plasma. On endothelial cells, thrombin-cleaved protein S (PSt) as well as protein S in complex with C4b-binding protein (C4BP) inhibited prothrombinase activity to the same extent as protein S did. In solid-phase binding assays, direct binding of protein S and PSt to factor V and factor Va were observed. Protein S-C4BP complex did not bind to factor V or factor Va, implicating that the factor V(a) binding site on protein S is lost by the interaction with C4BP. A direct inhibition of factor Xa activity by protein S was also observed. Incubation of factor Xa with protein S revealed a noncompetitive inhibition of factor Xa by protein S with a Ki of (4.9 +/- 0.8) x 10(-7) M. Both protein S and protein S-C4BP complex were able to inhibit factor Xa to the same extent, whereas PSt had lost its inhibitory activity. This suggests that the conformational change induced by cleavage of the amino-terminal thrombin-sensitive loop results in a loss of a factor Xa binding site on protein S. The inhibitory effect of protein S involves interactions with both factor Va and factor Xa. The interaction of protein S with factor Xa is influenced by cleavage of the thrombin-sensitive loop, whereas C4BP blocks the interaction of protein S with factor Va. Inhibition of the prothrombinase complex by either forms of protein S might be an important mechanism in regulating thrombin generation in blood coagulation. The importance of the APC-independent anticoagulant action of protein S was emphasized by experiments in which the addition of protein S to normal plasma induced a prolongation of clotting time in a dilute activated partial thromboplastin time (dAPTT) assay. Furthermore, inhibition of endogenous protein S by the addition of monoclonal antibodies against protein S to normal plasma, induced a shortening of the clotting time in a dAPTT assay.
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PMID:Human protein S inhibits prothrombinase complex activity on endothelial cells and platelets via direct interactions with factors Va and Xa. 806 24

Although human protein S binds to human factor Va and inhibits prothrombinase activity, this inhibition is not totally dependent on factor Va. Hence, we investigated possible interaction of protein S with human factor Xa. Factor Xa, diisopropylphospho-factor Xa and their biotin derivatives ligand blotted specifically to protein S and protein S ligand blotted specifically to factor X and factor Xa. Biotinylated factors X and Xa bound to immobilized protein S and, reciprocally, protein S bound to immobilized factor Xa with a Kd of approximately 19 nM. In fluid phase, protein S bound to factor Xa with a Kd of approximately 18 nM. Protein S at 33 nM reversibly inhibited 50% of factor Xa amidolytic activity. Protein S inhibition of prothrombin conversion to thrombin by factor Xa was phospholipid-independent and was 1.6 times stimulated by Ca2+ ions. Inhibition of prothrombinase activity by protein S was 2.3-fold more potent in the presence of factor Va, with 50% inhibition at approximately 8 nM protein S. Protein S prolonged the factor Xa one-stage clotting time of protein S-depleted plasma in a dose-dependent manner. These data demonstrate mechanisms of anticoagulant action for protein S that are independent of activated protein C and that involve direct binding to factors Xa and Va and direct inhibition of factor Xa.
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PMID:Protein S binds to and inhibits factor Xa. 814 82

Since plasma protein S serves an anticoagulant function by mechanisms which are not completely understood, its possible interaction with Factor Va was investigated. Human protein S bound to immobilized human Factor Va in a calcium-dependent, saturable, and reversible manner and Factor Va bound similarly to immobilized protein S. Binding of protein S to immobilized Factor V was greatly enhanced by pretreatment of the surface-bound Factor V with increasing doses of thrombin up to 1 unit/ml. Binding of protein S to Factor Va was also demonstrated in fluid phase with a Kd of 33 +/- 9 nM. Biotin-labeled heavy chain of Factor Va bound to immobilized protein S, and this binding was reversed by a 17-fold molar excess of intact unlabeled Factor Va. Protein S competed efficiently with prothrombin for binding to immobilized Factor Va. The prothrombinase activity in a reaction mixture of purified clotting factors was inhibited by protein S and exhibited a pattern of mixed inhibition. The concentration of protein S needed for 50% inhibition of the prothrombinase activity of a mixture containing 1 nM Factor Xa, 20 pM Factor Va, and 50 microM phospholipids was about 16 nM. Since not all protein S preparations exhibited this degree of prothrombinase inhibitory activity, extensive control experiments were performed to verify that the inhibitory activity was associated with protein S during immunoaffinity chromatography and was not caused by traces of activated protein C in the protein S preparations. These data show that protein S has an anticoagulant function which is independent of activated protein C and, at least in part, that this is because of its competition with prothrombin for direct binding to Factor Va.
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PMID:Binding of protein S to factor Va associated with inhibition of prothrombinase that is independent of activated protein C. 842 62

Factor V and protein S are cofactors of activated protein C (APC) which accelerate APC-mediated factor VIII inactivation. The effects of factor V and protein S were quantitated in a reaction system in which plasma factor VIII was inactivated by APC and the loss of factor VIII activity was monitored in a factor X-activating system in which a chromogenic substrate was used to probe factor Xa formation. Factor V increased the rate of APC-mediated factor VIII inactivation in a dose-dependent manner in representative plasma samples with protein S or factor V deficiency, abnormal factor V (heterozygous or homozygous for factor VR506Q), or a combination of heterozygous protein S deficiency and heterozygous factor VR506Q. This effect was much less pronounced in the plasma samples with a decreased protein S level, but the impaired response in these plasmas was corrected by addition of protein S, indicating that both factor V and protein S are required for optimal inactivation of factor VIII by APC. The effects of factor V and protein S were also studied in a reaction system with purified proteins. APC-catalysed factor VIII inactivation was enhanced 3.7-fold in the presence of 1.1 nM factor V and 1.5-fold in the presence of 2.4 nM protein S. When both 1.1 nM factor V and 2.4 nM protein were present the rate enhancement was 11-fold. Factor V is a more potent cofactor than protein S, as can be concluded from the fact that 0.04 nM factor V gave the same stimulation as 2.4 nM protein S. Protein S lost its cofactor function after complexation with C4b binding protein, which indicates that it is free protein S that acts as a cofactor. To investigate the effect of the R506Q mutation in factor V on APC-mediated factor VIII inactivation, factor V was purified from the plasma of patients homozygous for factor VR506Q. In the absence of protein S, factor VR506Q did not enhance factor VIII inactivation by APC, but in the presence of 2.4 nM protein S a slight enhancement was observed. The APC cofactor activity of factor V was lost when factor V was activated with thrombin or with the factor V activator from Russell's viper venom. These data indicate that optimal inactivation of factor VIII by APC requires the presence of an intact factor V molecule and free protein S.
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PMID:Factor V enhances the cofactor function of protein S in the APC-mediated inactivation of factor VIII: influence of the factor VR506Q mutation. 886 33

Protein S is a vitamin-K dependent glycoprotein involved in the regulation of the anticoagulant activity of activated protein C (APC). Recent data showed a direct anticoagulant role of protein S independent of APC, as demonstrated by the inhibition of prothrombinase and tenase activity both in plasma and in purified systems. This anticoagulant effect of protein S can be explained either by a direct interaction of protein S with one of the components of the complexes and/or by the interference with the binding of these components to phospholipid surfaces. During our investigation we noted that protein S preparations purified in different ways and derived from different sources, expressed discrepant APC cofactor and direct anticoagulant activity. In order to elucidate these differences and to study the mechanism of the APC-independent activity of protein S, we compared the protein S preparations in phospholipid-binding properties and anticoagulant activity. The dissociation constant for the binding of protein S to immobilized phospholipids ranged from 7 to 74 nM for the different protein S preparations. APC-independent inhibition of both prothrombinase and tenase activity performed on phospholipid vesicles and in plasma showed a strong correlation with the affinity for phospholipids. The APC-independent activity could be abolished by monoclonal antibodies that were either calcium-dependent and/or directed against epitopes in the Gla-region of protein S, suggesting that the protein S-phospholipid interaction is crucial for the APC-independent anticoagulant function of protein S. Protein S preparations with a low APC-independent activity expressed a high APC-cofactor activity suggesting that the affinity of protein S for phospholipids is of less importance in the expression of APC-cofactor activity of protein S. We conclude that high affinity interactions of protein S with the membrane surface are essential for the direct anticoagulant activity of protein S and we suggest that inhibition of the prothrombinase and the tenase complex by protein S is a consequence of the occupation of the phospholipid surface by protein S molecules.
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PMID:The interaction of protein S with the phospholipid surface is essential for the activated protein C-independent activity of protein S. 888 77

Protein S is a vitamin K-dependent plasma protein that acts as a cofactor of activated protein C (APC) and as an inhibitor of the prothrombinase complex. We previously reported that protein S-Tokushima, found in a patient with heterozygous protein S deficiency and severe venous thrombotic disease, has a substitution of Glu for Lys-155 in the second epidermal growth factor (EGF)-like domain of protein S. In the present study, we characterized the role of protein S, which is required for the expression of the APC cofactor activity and for the inhibition of the prothrombinase complex activity, using recombinant normal protein S (rPS-N) and protein S-Tokushima (rPS-T), expressed in BHK cells. rPS-N as well as plasma protein S showed APC cofactor activity, but rPS-T did not. Both rPS-N and rPS-T equally bound to phospholipids (Cephalin) and C4b-binding protein fixed to microwells. APC bound to rPS-N and plasma protein S, but did not bind to rPS-T. Although rPS-N as well as plasma protein S inhibited the platelet prothrombinase complex activity, rPS-T did not. Factor Xa bound to rPS-N but not to rPST. Binding of rPS-N to biotinylated factor Va in solution phase did not differ significantly from that of rPS-T. The dysfunction of protein S-Tokushima is suggested to be mainly caused by a lack of interaction with APC required for the expression of the APC cofactor activity and by a lack of interaction with factor Xa required for the inhibition of the prothrombinase complex activity.
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PMID:Characterization of dysfunctional protein S-Tokushima (K155-->E) in relation to the molecular interactions required for the regulation of blood coagulation. 911 55

To determine the structural basis of phosphatidylethanolamine (PE)-dependent activated protein C (APC) activity, we prepared a chimeric molecule in which the Gla domain and hydrophobic stack of protein C were replaced with the corresponding region of prothrombin. APC inactivation of factor Va was enhanced 10-20-fold by PE. Protein S enhanced inactivation 2-fold and independently of PE. PE and protein S had little effect on the activity of the chimera. Factor Va inactivation by APC was approximately 5-fold less efficient than with the chimera on vesicles lacking PE and slightly more efficient on vesicles containing PE. The cleavage patterns of factor Va by APC and the chimera were similar, and PE enhanced the rate of Arg506 and Arg306 cleavage by APC but not the chimera. APC and the chimera bound to phosphatidylserine:phosphatidylcholine vesicles with similar affinity (Kd approximately 500 nM), and PE increased affinity 2-3-fold. Factor Va and protein S synergistically increased the affinity of APC on vesicles without PE to 140 nM and with PE to 14 nM, but they were less effective in enhancing chimera binding to either vesicle. In a factor Xa one-stage plasma clotting assay, the chimera had approximately 5 times more anticoagulant activity than APC on PE-containing vesicles. Unlike APC, which showed a 10 fold dependence on protein S, the chimera was insensitive to protein S. To map the site of the PE and protein S dependence further, we prepared a chimera in which residues 1-22 were derived from prothrombin and the remainder were derived from protein C. This protein exhibited PE and protein S dependence. Thus, these special properties of the protein C Gla domain are resident outside of the region normally hypothesized to be critical for membrane interaction. We conclude that the protein C Gla domain possesses unique properties allowing synergistic interaction with factor Va and protein S on PE-containing membranes.
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PMID:A chimeric protein C containing the prothrombin Gla domain exhibits increased anticoagulant activity and altered phospholipid specificity. 953 91

Coagulation factor V is composed of domains A1-A2-B-A3-C1-C2 and is activated by thrombin through proteolytic cleavage at Arg 709, Arg 1018 and Arg 1545. Upon thrombin activation, the B-domain is released and the active factor Va is formed by the heavy (A1-A2) and light chains (A3-C1-C2). Factor Va functions as an essential cofactor to factor Xa in the conversion of prothrombin to thrombin during coagulation. Recently it was shown that coagulation factor V, apart from being a precursor form to the procoagulant factor Va, also has anticoagulant properties, as it functions as a cofactor to activated protein C (APC). APC is a member of the anticoagulant pathway and downregulates the coagulation process through proteolytic inactivation of factors VIII/VIIIa and factors V/Va. In a factor VIIIa degradation assay, the APC-mediated inactivation of factor VIIIa is potentiated by the synergistic cofactors protein S and factor V. Protein S alone has little cofactor activity, whereas in the presence of factor V it is dramatically enhanced. This study provides insights into the molecular mechanisms that regulate the anticoagulant activity of factor V. Thrombin cleavage of factor V occurs in a sequential order. The thrombin cleavage site Arg 1545 is kinetically less favored than the other two sites, and cleavage at this site is the last to occur during thrombin activation of factor V As a consequence of this, different activation intermediates exist that express different levels of procoagulant activity. The anticoagulant activities of these intermediates have now been studied. It was found that factor V could be cleaved by thrombin at both Arg 709 and Arg 1018 and still work fully as a cofactor to APC, whereas cleavage at Arg 1545 completely abolished the anticoagulant activity of factor V. This suggests that the APC cofactor function of factor V depends on the B-domain remaining attached to the A3 domain. This study further shows that APC converts coagulation factor V into a member of the anticoagulant pathway by cleaving factor V in the A2 domain at Arg 506. By cleavage of factor V, APC not only produces an anticoagulant cofactor, but at the same time eliminates the pool of procoagulant factor V, since APC cleaved factor V will have no future as a cofactor in the coagulation. The unique way by which APC and thrombin, through proteolytic cleavage, can convert factor V into either an anticoagulant or a procoagulant adds to the intriguing mechanisms that balance the procoagulant and anticoagulant forces.
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PMID:Mechanisms that regulate the anticoagulant function of coagulation factor V. 1009 86

The independent effect of protein S as prothrombinase inhibitor has been proposed to depend on binding to both coagulation factors Va and factor Xa or on the binding to phospholipid thereby limiting the phospholipid available for prothrombinase activity. In this study we show that plasma concentrations of protein S (300 nM) equilibrated with the prothrombinase components (factor Va, factor Xa, phospholipid) cause a profound inhibition at low phospholipid concentrations (approximately 0.2 microM). This inhibition by protein S of prothrombinase activity is abrogated with increasing phospholipid concentrations. Modeling of the effect of protein S on prothrombinase based only on the reported affinity of protein S for phospholipids (Kd approximately 10(-8) M) in an equilibrium model (Clotspeed), predicted the experimentally obtained thrombin generation rates at low phospholipid in the presence of protein S based on the diminished available phospholipid binding sites for the prothrombinase components. Consistently, initial rates of prothrombinase activity are already maximally inhibited when protein S is preincubated with the phospholipid prior to the addition of factor Xa, factor Va and prothrombin. The results indicate that the order of addition of prothrombinase components and the availability of phospholipid may have a profound influence on observed effects of protein S on prothrombinase activity. All prothrombinase components (factor Xa, factor Va, phospholipid) become available during the course of the physiological thrombin generation. The effect of protein S was therefore studied on tissue factor-induced, platelet-dependent thrombin generation. Protein S delayed and inhibited the rate of thrombin generation of tissue factor-induced thrombin formation when surface is provided at physiologic concentrations using isolated platelets (2 x 10(8)/ml). In contrast, protein S hardly affected thrombin generation in this model when platelets were pre-activated with collagen. Furthermore, the observed effects of addition of protein C and thrombomodulin in the absence or presence of protein S on tissue factor-induced, platelet-dependent thrombin generation, indicate that protein S and protein C may cooperate in the regulation of prothrombinase activity through independent mechanisms.
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PMID:Regulation of prothrombinase activity by protein S. 1045 58

Protein S is anticoagulant in the absence of activated protein C because of direct interactions with coagulation Factors Xa and Va. Synthetic peptides corresponding to amino acid sequences of protein S were tested for their ability to inhibit prothrombinase activity. The peptide containing the C-terminal sequence of protein S, residues 621-635 (PSP14), reversibly inhibited prothrombinase activity in the presence but not in the absence of Factor Va (K(i) approximately 2 microM). PSP14 inhibition of prothrombinase was independent of phospholipids but could be competitively overcome by increasing Factor Xa concentrations, suggesting that the C-terminal region of protein S may compete for a Factor Xa binding site on Factor Va. Studies using peptides with amino acid substitutions suggested that lysines 630, 631, and 633 were critical residues. PSP14 inhibited Factor Va activity in Factor Xa-one-stage clotting assays. PSP14 inhibited protein S binding to immobilized Factor Va. When preincubated with protein S, antibodies raised against PSP14 inhibited binding of protein S to Factor Va and blocked inhibition of prothrombinase activity by protein S. These results show that the C-terminal region of protein S containing residues 621-635 is essential for binding of protein S to Factor Va and that this interaction contributes to anticoagulant action.
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PMID:C-terminal residues 621-635 of protein S are essential for binding to factor Va. 1059 4


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