EC:3.4.21.69 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.69 (APC)
16,337 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Factor VIII is represented as a series of heterodimers composed of an 83(81) kDa light chain noncovalently bound to a variable size (93 to 210 kDa) heavy chain. Activated protein C inactivates factor VIII causing several cleavages of the factor VIII heavy chain(s). When factor VIII subunits were dissociated and component heavy and light chains isolated, the heavy chains were no longer a substrate for proteolysis by activated protein C. However, when factor VIII heavy chains were recombined with light chain, the reconstituted factor VIII activity was inactivated by activated protein C. The rate of factor VIII inactivation catalyzed by activated protein C was reduced by the presence of free light chain. The extent of this inhibition was dependent upon the concentration of light chain. Control experiments indicated that this protective effect of free light chain was not the result of inhibition of the activated protein C - lipid interaction. Fluorescence analysis demonstrated binding between the factor VIII light chain, chemically modified with eosin maleimide, and activated protein C, modified at its active site by dansyl-Glu-Gly-Arg chloromethyl ketone. Similar to proteolysis of factor VIII by activated protein C, this binding was dependent upon a lipid surface. Based upon the degree of fluorescence quenching, a spatial distance of 26 A was calculated separating the two fluorophores. These results demonstrate direct binding of activated protein C to the factor VIII light chain and suggest that this binding is an obligate step for activated protein C-catalyzed inactivation of factor VIII.
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PMID:Inactivation of human factor VIII by activated protein C: evidence that the factor VIII light chain contains the activated protein C binding site. 252 Dec 91

Since a vitamin K dependent protein, protein C, can inactivate factor VIII, a study was undertaken to determine if the level and stability of factor VIII in plasma are influenced by such a protein. Factor VIII lability was determined by incubating citrated plasma, diluted 1:10 and 1:20 in pH 7 X 2 imidizole buffer, for 6 h at 37 degrees C. Normal plasma had a mean factor VIII of 98 +/- 61 U/100 ml. The amount of factor VIII remaining after 6 h of incubation was 68 +/- 14% of the original factor VIII level. In warfarinized patients, factor VIII (218 +/- 65 U/100 ml) and VWF:AGN (331 +/- 102 U/100 ml) were elevated (P less than 0.001). Following incubation, their residual activity was 103 +/- 20% of the original factor VIII level. In samples taken after warfarin was discontinued, normal factor VIII lability returned, while plasma levels of factor VIII and VWF:AGN remained elevated. Similarly, in the plasma of a vitamin K deficient patient, increased factor VIII stability was also evident; lability was restored following vitamin K replacement. We conclude that factor VIII stability is determined in part by a vitamin K dependent protein. In clinical states in which this protein is functionally absent, factor VIII is elevated and more stable.
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PMID:The destabilization of factor VIII by a vitamin K dependent protein. 258 May 48

Eighty patients undergoing total hip replacement (THR) were randomly allocated to three groups. Group I (n = 29) received general anaesthesia, Group II (n = 29) epidural anaesthesia and Group III (n = 22) the same epidural as Group II and the same general anaesthesia as Group I but with a lower isoflurane concentration. Prothrombin time (PT), activated thromboplastin time (APTT), fibrinogen (FG), plasminogen (PG), antithrombin III (AT III), protein C (Proc C), alpha-2-antiplasmin (alpha 2AP), Factor VIII coagulating activity (F VIII:C), von Willebrand factor antigen (vWF:Ag), von Willebrand ristocetin cofactor (vWF:Rcof), tissue plasminogen activator (tPA) as antigen and activity were measured before induction (A), at the end of surgery (B), on the first postoperative morning (C) and 7 days postoperatively (D). The most relevant finding was that AT III was equally depressed immediately after surgery in all groups, but returned to normal significantly faster in the epidural group (mean values at C: 96.2% in Group I, 104.1% in Group II, 92.7% in Group III). The faster return to normal of AT III after epidural anaesthesia could be one of the mechanisms responsible for the beneficial effect of this technique on the prevention of thromboembolic complications.
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PMID:Coagulation and fibrinolytic parameters in patients undergoing total hip replacement: influence of the anaesthesia technique. 268 46

The levels of protein C (PC) and other coagulation factors were monitored during endotoxin-induced disseminated intravascular coagulation (DIC) in the dog. Initial evaluation of the effectiveness of intradermal administration of bolus endotoxin quantities into the dog, demonstrated induction of DIC in the canine, without the severe side effects associated with bacterial sepsis. Quantitative determination of canine plasma protein C levels were performed using a multiple step amidolytic assay, that included a specific precipitation of the vitamin K-dependent proteins from citrated plasma, followed by thrombin activation (and neutralization) and subsequent measurement of the activated protein C (APC) by chromogen hydrolysis. This investigation demonstrated, that over a twenty-four hour interval, intradermal administration of endotoxin produces a gradual decrease in the PC activity levels, concomitant with a significant reduction in the Factor V, Factor VIII and fibrinogen levels and platelet count, and a prolongation of the Prothrombin Time and Partial Thromboplastin Time. During the first 6 hours, protein C levels fell below the pre-levels and remained significantly lower in the surviving dogs. Thus, this endotoxin-induced DIC animal model permits evaluation of various hemostatic parameters, yet diminishes the severe clinical findings associated with DIC.
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PMID:Protein C activity levels in endotoxin-induced disseminated intravascular coagulation in a dog model. 278 30

Factor VIII was inactivated by activated protein C in the presence of calcium and phospholipids. Analysis of the activated protein C-catalyzed cleavage products of factor VIII indicated that inactivation resulted from the cleavage of the heavy chains. The heavy chains appeared to be converted into 93- and 53-kDa peptides. Inactivation of factor VIII that was only composed of the 93-kDa heavy chain and 83-kDa light chain indicated that the 93-kDa polypeptide could be degraded into a 68-kDa peptide that could be subsequently cleaved into 48- and 23-kDa polypeptides. Thus, activated protein C catalyzed a minimum of four cleavages in the heavy chain. Activated protein C did not appear to alter the factor VIII light chain. The addition of protein S accelerated the rate of inactivation and the rate of all of the cleavages. The effect of protein S could be observed on the cleavage of the heavy chains and on secondary cleavages of the smaller products, including the 93-, 68-, and 53-kDa polypeptides. The addition of factor IX to the factor VIII-activated protein C reaction mixture resulted in the inhibition of factor VIII inactivation. The effect of factor IX was dose dependent. Factor VIII was observed to compete with factor Va for activated protein C. The concentration dependence of factor VIII inhibition of factor Va inactivation suggested that factor VIII and factor Va were equivalent substrates for activated protein C.
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PMID:Inactivation of factor VIII by activated protein C and protein S. 294 97

Activated protein C (APC) acts as a potent anticoagulant enzyme by inactivating Factor V and Factor VIII. In this study, protein S was shown to increase the inactivation of purified Factor VIII by APC ninefold. The reaction rate was saturated with respect to the concentration of protein S when protein S was present in a 10-fold molar excess over APC. The heavy chain of Factor VIII was cleaved by APC and protein S did not alter the degradation pattern. Factor VIII circulates in a complex with the adhesive protein von Willebrand factor. When purified Factor VIII was recombined with von Willebrand factor, the inactivation of Factor VIII by APC proceeded at a 10-20-fold slower rate as compared with Factor VIII in the absence of von Willebrand factor. Protein S had no effect on the inactivation of the Factor VIII-von Willebrand factor complex by APC. After treatment of this complex with thrombin, however, the actions of APC and protein S towards Factor VIII were completely restored. In hemophilia A plasma, purified Factor VIII associated with endogenous von Willebrand factor, resulting in a complete protection against APC (4 nM). By mixing hemophilic plasma with plasma from a patient with severe von Willebrand's disease, we could vary the amount of von Willebrand factor. 1 U of von Willebrand factor was needed to provide protection of 1 U Factor VIII. Also in plasma from patients with the IIA-type variant of von Willebrand's disease, Factor VIII was protected. In von Willebrand's disease plasma, which was depleted of protein S, APC did not inactivate Factor VIII. These results indicate that protein S serves as a cofactor in the inactivation of Factor VIII and Factor VIIIa by APC and that von Willebrand factor can regulate the action of these two anticoagulant proteins.
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PMID:Inactivation of human factor VIII by activated protein C. Cofactor activity of protein S and protective effect of von Willebrand factor. 297 73

Factor VIII functions in the intrinsic pathway of coagulation as the cofactor for factor IXa proteolytic activation of factor X. Proteolytic cleavage is required for activation and may be responsible for inactivation of cofactor activity. To identify which of the multiple cleavages are required for activation and inactivation of factor VIII, site-directed DNA-mediated mutagenesis of the factor VIII cDNA was performed and the altered forms of factor VIII were expressed in COS-1 monkey cells and characterized. Conversion of arginine residues to isoleucine residues at the aminoterminal side of the cleavage sites at positions 740, 1648, and 1721 resulted in cleavage resistance at the modified site with no alteration in the in vitro procoagulant activity and the susceptibility to thrombin activation. Similar modification of the thrombin cleavage sites at either position 372 or position 1689 resulted in molecules with residual factor VIII activity but resistant to thrombin cleavage at the modified site and not susceptible to thrombin activation. Modification of the arginine to either an isoleucine or a lysine at residue 336, the site postulated for proteolytic inactivation by activated protein C, resulted in a factor VIII molecule with increased procoagulant activity. This increased activity may result from greater resistance to proteolytic inactivation. A model for the activation and inactivation of factor VIII is proposed.
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PMID:Proteolytic requirements for thrombin activation of anti-hemophilic factor (factor VIII). 312 86

The effect of Norplant subdermal implants on 22 different hemostatic variables was determined in 100 women attending the Fertility Control Clinic of the Singapore National University Hospital before and after 6 and 12 months of use. The factors analyzed were: hematocrit, hemoglobin (Hb), prothrombin time (PT), activated partial thromboplastin time (APTT), platelet count, fibrinogen, coagulation factor II, Factor V,Factor VII, Factor VIII, Factor VIIIR:Ag, Factor X, plasminogen activator, FDP, plasminogen (imm), antithrombin III (functional), antithrombin (antigen), protein C, alpha2-antiplasmin, alpha2-macroglobulin, alpha2-antitrypsin, platelet count, platelet aggregation (ADP), and platelet aggregation (collagen). The factors that differed significantly after 12 months were: Hb,PT,APTT, Factors II,V,VII, and VIIIR:Ag, Plasminogen (imm), antithrombin III(antigen), alpha2-antiplasmin, platelet count, and platelet aggregation. Most of these differences, while significant, were still within the normal range, except for PT,APTT, and platelet count. The subjects were considered to be in an enhanced risk for hypercoagulation and thrombosis.
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PMID:The effects of Norplant-2 rods on clinical chemistry in Singaporean acceptors after 1 year of use: haemostatic changes. 314 69

Comprehensive coagulation studies were performed on members of a family with combined factor V/VIII deficiency. The purpose of these studies was to investigate the hypothesis that combined factor V/VIII deficiency is due to a lack of the inhibitor to activated protein C. The analyses performed included routine APTT and PT, factor V and VIII coagulant activity and antigen levels, von Willebrand factor levels, protein C antigen assay, and both protein C inhibitor activity and antigen levels. Three of the 19 family members studied were found to have a deficiency of both factors V and VIII. These three individuals showed prolonged APTTs and PTs and decreased levels of factor V and factor VIII coagulant activity and antigen. Factor VIII related antigen and ristocetin cofactor (von Willebrand factor) levels were normal. Protein C and both protein C inhibitor activity and antigen levels were also found to be normal. These findings confirm the results of other recent investigators and indicate that the autosomal, inherited combined factor V/VIII deficiency is not due to a protein C inhibitor deficiency. The real defect in this combined deficiency remains to be determined.
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PMID:Combined factor V/VIII deficiency: a case report including levels of factor V and factor VIII coagulant and antigen as well as protein C inhibitor. 393 61

Chronic renal failure causes elevations of factor VIII coagulant activity and Factor VIII-related antigen even before the patients enter chronic hemodialysis. The change from control of Factor VIII ristocetin cofactor does not reach significance. The elevations are not effected by entering onto hemodialysis. These parameters are the same for non-diabetic and diabetic patients. Protein C, plasminogen and total fibrinolytic capacity are normal in diabetic and non-diabetic patients, with or without hemodialysis for chronic renal failure. However, before entering onto hemodialysis some of these parameters had negative correlation coefficients with parts of the factor VIII complex among the diabetic and non-diabetic patients. These negative correlates turned positive after hemodialysis. Thus, there are differences in these catabolic mechanisms for factor VIII when hemodialysis is used for diabetic and non-diabetic patients with chronic renal failure.
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PMID:Factor VIII complex in chronic renal failure: influence of protein C, fibrinolysis and diabetes mellitus. 613 88

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