Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

A directed-search strategy for point mutations in the factor VIII gene causing hemophilia A was used to screen eight potentially hypermutable CpG dinucleotides occurring at sites deemed to be of functional importance. Polymerase chain reaction-amplified DNA samples from 793 unrelated individuals with hemophilia A were screened by discriminant oligonucleotide hybridization. Point mutations were identified in 16 patients that were consistent with a model of 5-methylcytosine (5mC) deamination. Four new examples of recurrent mutation were demonstrated at the following codons: 336 (CGA----TGA), 372 (CGC----TGC), 372 (CGC----CAC), and 1689 (CGC----TGC). These are functionally important cleavage sites for either activated protein C or thrombin. Further novel C----T transitions were identified in the remaining arginine codons screened (-5, 427, 583, 795, and 1696), resulting in the creation of TGA termination codons. Differences in mutation frequency were found both within and between the CpG sites and between ethnic groups. These differences are assumed to be due to differences in the level of cytosine methylation at these sites, although direct evidence for this inference is lacking.
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PMID:The molecular genetic analysis of hemophilia A: a directed search strategy for the detection of point mutations in the human factor VIII gene. 197 2

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

Several recent studies have reported conflicting results on the effectiveness of danazol, an attenuated androgen, in raising plasma levels of clotting factors VIII and IX in patients with hemophilia. We undertook a randomized, double-blind cross-over trial using 8 weeks' administration of danazol (D), 600 mg/d, and 8 weeks' administration of placebo (P) separated by 2 weeks of rest in 12 patients with hemophilia A and four patients with hemophilia B. Plasma factor VIII and IX levels, frequency and type of bleeding episodes, amount of factor concentrate infused, fibrinogen, fibrinolysis assays, antithrombin III, liver function, and immune parameters were followed. During the danazol phase a minimal increase was noted in the average clotting factor levels, an increase that, although statistically significant, was of hemostatically marginal magnitude. Significant increases in protein C and plasminogen levels, however, were observed during the danazol period, suggestive of danazol-mediated enhanced fibrinolysis. Clinically, bleeding frequency was significantly increased, and more clotting factor was consumed during the danazol period. Furthermore, eight episodes of hematuria and oral mucosal bleeding was reported during the danazol phase in contrast to only one episode of hematuria during the placebo phase, consistent with an enhancement of fibrinolytic activity with danazol. We conclude that danazol does not have a hemostatically significant effect on plasma levels of factor VIII and IX but may be associated with enhancement of fibrinolytic activity, resulting in increased bleeding frequency and requiring more clotting factor infusions. Therefore, danazol is not a viable alternative in the treatment of hemophilia.
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PMID:Effect of danazol on clotting factor levels, bleeding incidence, factor infusion requirements, and immune parameters in hemophilia. 374 49

Factor VIII (antihemophilic factor) is the protein that is deficient or defective in patients with classical hemophilia and Von Willebrand syndrome. Factor VIII in plasma is thought to be associated in a complex with the highest molecular weight multimers of another glycoprotein, Von Willebrand protein. Highly purified human factor VIII appears to have an Mr of between 200,000 and 300,000 and to consist of several polypeptide chains. The concentration of factor VIII in plasma is around 100-200 ng/ml, equivalent to around 1 nM. The purified proteins retain one or more of the known properties of factor VIII, including the acceleration of factor IXa-mediated activation of factor X, ability to be activated by thrombin and factor Xa, inactivation by activated protein C, and by human antibodies to factor VIII. Among the known clotting factors, factors VIII and V are exceptional in not possessing enzymatic activity. Factors IXa and VIII and X appear to form a functional complex, all of which need to be present and active simultaneously for optimal activation of factor X. The mechanism by which factor VIII promotes activation of factor X by factor IXa is not known, but the major effect is to increase the rate of the reaction. Following treatment of factor VIII with thrombin, a new and smaller polypeptide Mr around 70,000 +/- 5,000 is produced. Factors IXa and Xa also have been reported to activate factor VIII. It is not known whether limited proteolytic cleavage is required absolutely for the expression of factor VIII activity or if it only increases an activity already expressed by the uncleaved protein. Factor VIII is inactivated by thrombin and by activated protein C. Thus, factor VIII can be modulated by at least four of the serine proteases in the clotting system. A major goal for future research is to increase our understanding of the role in blood clotting played by factor VIII, and to apply this information to clinical problems which result from inherited abnormalities of factor VIII.
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PMID:Factor VIII: structure and function in blood clotting. 642 37

Antihemophilic factor concentrates were surveyed for amidolytic activity on the chromogenic substrates S2238, S2302, S2222, and S2251, which are sensitive to thrombin, kallikrein, factor Xa, and plasmin, respectively. For antihemophilic factor concentrates from two manufacturers, the rates of amidolysis of S2238 and S2302 were approximately an order of magnitude greater than the rates of amidolysis of S2222 and S2251. The S2238 and S2302 activities were characterized by quantitating their interactions with specific substrates or inhibitors. The Km for amidolysis of S2238 was 558 mumol/L, which is 80 times higher than for thrombin but in close agreement to the reported value for activated protein C. The S2238 activity was not inhibited by the thrombin-specific inhibitor dansylarginine N-(3-ethyl-1,5-pentanediyl)amide, nor by soybean trypsin inhibitor or micromolar concentrations of antithrombin III in the presence of heparin. The S2238 activity was inhibited by D-Phe-Pro-Arg-CH2Cl, but with an estimated second-order rate constant of 3 X 10(5) mol/L-1 minute-1, approximately 1000 times less than for thrombin. These data are consistent with the identity of the S2238 activity as activated protein C. On the other hand, the S2302 activity in antihemophilic factor concentrates was most likely attributable to kallikrein. This was based on the agreement with authentic kallikrein of the Km for S2302 of 154 mumol/L as well as by the rapid inactivation by nanomolar concentrations of the kallikrein-specific inhibitor D-Phe-Phe-Arg-CH2Cl. However, the relative resistance of the S2302 activity to inhibition by soybean trypsin inhibitor or antithrombin III and the partial inhibition by aprotinin suggested that a large proportion of the kallikrein was bound to alpha 2-macroglobulin. This was confirmed by immunoprecipitation using specific anti alpha 2-macroglobulin IgG. The potential for proteolysis of factor VIII:von Willebrand protein during its purification from antihemophilic factor concentrates was demonstrated, and the proteolyzed factor VIII coagulant species was characterized. High-pressure gel permeation chromatography of purified factor VIII:von Willebrand protein at high ionic strength resulted in two sharp peaks of factor VIII procoagulant activity. The earlier eluting peak corresponded with the void volume, and the later peak eluted with an apparent molecular weight of 53,000 daltons. Immediately after separation, the 53,000-dalton factor VIII coagulant had at least a 100-fold higher specific activity than the factor VIII coagulant present in the void volume. However, the 53,000-dalton factor VIII coagulant was labile, with a half-life of 80 minutes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Characterization of proteases in AHF concentrates: effect on factor VIII:von Willebrand protein as assessed by high-pressure gel permeation chromatography. 643 16

Our understanding of thrombosis remains anchored to Virchow's view that the evolution of a thrombus is fostered by vascular damage, by retarded blood flow, and by alterations in the blood itself that increases its likelihood to clot. The last of these forces, the so-called hypercoagulable state, has been defined in many ways. For example, some evidence exists that increased titers of clotting factors or increased numbers of circulating platelets may be correlated with a thrombotic tendency. A more exciting way that clotting factors might contribute to thrombosis is that under certain conditions the titer of their activated forms might reach critical levels in the circulation. Another possibility is that a thrombotic tendency may be caused by qualitative alterations in clotting factors or platelets. The firmest evidence that alterations in blood clotting may be related to thrombosis is the undoubted high incidence of recurrent thromboembolism in patients with familial deficiencies of antithrombin III or protein C, an inhibitor of antihemophilic factor (factor VIII) and proaccelerin (factor V). Impaired fibrinolytic mechanisms may also predispose to thrombosis. Not yet explained is the fact that patients with lifelong hemostatic alterations in peripheral blood sustain only a handful of thrombotic episodes.
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PMID:Thrombosis and the hypercoagulable state. 648 6

In the last few years, plasma fractionation has been subjected to major technological changes which have contributed to improve the viral safety and overall purity of plasma derivatives. New viral inactivation treatments, primarily solvent-detergent and pasteurization, have been introduced in the manufacturing processes of plasma derivatives to ensure the inactivation of major plasma-borne viruses, including HIV and hepatitis B and C viruses. Concurrently, new highly purified products obtained by chromatographic methods (mainly ion exchange and/or immunopurification) have been developed in the last five years and have replaced former preparations, providing a significantly higher safety level in terms of purity and viral risks. For an example, the new generation of Factor VIII and Factor IX concentrates (to treat hemophilia A and hemophilia B, respectively), which have been introduced in the last five years, are purified over 10,000- to 20,000-fold from plasma, as compared to only 50- to 100-fold for the former products. Similarly, new, standardized, clotting factor or protease inhibitor concentrates have been made available, thus permitting to carry out selective hemotherapy of specific diseases. Examples include the development of von Willebrand factor, factor XI, protein C, or alpha 1-antitrypsin concentrates for the substitutive therapy of congenital or acquired deficiencies. In addition, the concept of good manufacturing practices has been implemented, whereas carefully controlled, validated processes are contributing to the consistency in the quality of those products. Current major problems in plasma fractionation relate to the potential occurrence of new pathogenic agents that could resist present viral inactivation treatments and to the potential effect of given purification technologies on the development of immunogenic properties of proteins. Current trends indicate that significant progress in viral safety of plasma derivatives (for example through the introduction of new concept such as viral filtration) are to be expected very soon. Further research in this very important field is mandatory as plasma should remain the starting material of important therapeutic products in the coming years.
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PMID:[Plasma fractionation. Progress, problems and perspectives]. 799 59

Patients with hemophilia A and B and factor levels than 1 percent of normal bleed frequently with an average number of spontaneous bleeding episodes of 20-30 or more. However there are patients with equally low levels of factor VIII or factor IX who bleed once or twice per year or not at all. To examine whether the presence of a hereditary defect predisposing to hypercoagulability might play a role in ameliorating the hemorrhagic tendency in these so-called "mild severe" hemophiliacs, we determined the prevalence of prothrombotic defects in 17 patients with hemophilia A and four patients with hemophilia B selected from 295 and 76 individuals with these disorders, respectively, followed at a large Italian hemophilia center. We tested for the presence of the Factor V Leiden mutation by PCR-amplifying a fragment of the factor V gene which contains the mutation site and then digesting the product with the restriction enzyme MnlI. None of the patients with hemophilia A and only one patient with hemophilia B was heterozygous for Factor V Leiden. None of the 21 patients had hereditary deficiencies of antithrombin III, protein C, or protein S. Our results indicate that the milder bleeding diathesis that is occasionally seen among Italian hemophiliacs with factor levels that are less than 1 percent cannot be explained by the concomitant expression of a known prothrombotic defect.
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PMID:Low prevalence of the factor V Leiden mutation among "severe" hemophiliacs with a "milder" bleeding diathesis. 860 5

Although many examples of unrelated hemophilia A patients carrying identical point mutations in the factor VIII (FVIII) gene have been reported, the clinical phenotype is not always the same among patients sharing the same molecular defect. Possible explanations for this discrepancy include undetected additional mutations in the FVIII gene or coinheritance of mutations at other genetic loci that modulate FVIII function. We report molecular genetic analysis of potential modifying genes in two sets of unrelated patients carrying common FVIII missense mutations but exhibiting different levels of clinical severity. Both mutations (FVIII R1689C and R2209Q) are associated with severe hemophilia A in some patients and mild/moderate disease in others. The common von Willebrand disease type 2N mutation (R91Q) was excluded as a modifying factor in these groups of patients. However, analysis of the recently described factor V (FV) R506Q mutation (leading to activated protein C resistance) identified a correlation of inheritance of this defect with reduced hemophilia A severity. Two moderately affected hemophilia A patients, each with either of two FVIII gene mutations, were heterozygous for FV R506Q, whereas two severely affected patients and two moderately affected patients were homozygous normal at the FV locus. Our results suggest that coinheritance of the FV R506Q mutation may be an important determinant of clinical phenotype in hemophilia A and that modification of the protein C pathway may offer a new strategy for the treatment of FVIII deficiency.
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PMID:Moderation of hemophilia A phenotype by the factor V R506Q mutation. 869 35

The hemophilia A mutation database lists more than 160 missense mutations: each represents a molecular defect in the FVIII molecule, resulting in the X-linked bleeding disorder hemophilia A with a clinical presentation varying from mild to severe. Without a three-dimensional FVIII structure it is in most cases impossible to explain biological dysfunction in terms of the underlying molecular pathology. However, recently the crystal structure of the homologous human plasma copper-binding protein ceruloplasmin (hCp) has been solved, and the A domains of FVIII share approximately 34% sequence identity with hCp. This advance has enabled the building of a molecular model of the A domains of FVIII based on the sequence identity between the two proteins. The model allows exploration of predictions regarding the general features of the FVIII molecule, such as the binding-sites for factor IXa and activated protein C; it has also allowed the mapping of more than 30 selected mutations with known phenotype from the database, and the prediction of hypothetical links to dysfunction in all but a few cases. A computer-generated molecular model such as that reported here cannot substitute for a crystal structure. However, until such a structure for FVIII becomes available, the model represents a significant advance in modeling FVIII; it should prove a useful tool for exploiting the increasing amount of information in the hemophilia A mutation database, and for selecting appropriate targets for investigation of the structure-function relationships via mutagenesis and expression in vitro.
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PMID:A molecular model for the triplicated A domains of human factor VIII based on the crystal structure of human ceruloplasmin. 911 85


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