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Enzyme
Compound
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Enzyme
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Query: EC:3.4.21.5 (
thrombin
)
33,306
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Genomic DNA from 170 unrelated hemophilia A patients was examined for gene defects in the coding region of the
Factor VIII
gene. Exons 18, 22-24 and 26 contain a CGA codon for arginine within the recognition sequence for the restriction enzyme Taq I. These five sites were amplified by the polymerase chain reaction and tested for abnormal Taq I restriction patterns. In five cases, the enzyme Taq I failed to digest the amplified fragments. Direct sequencing of the amplified products demonstrated a C to T transition in the coding strand of exons 18, 22 and 24 in three severe hemophilia A patients resulting in TGA termination codons. Two patients showed G to A transition in exons 24 and 26 reflecting a C to T transition in the non-coding strand substituting a glutamine for an arginine. Three deletions involving exon 26 and one exons 23-26 were found in severe hemophiliac patients. In contrast, exons 23 and 24 failed to amplify in one patient with a moderate form of the disease suggesting an in-frame splicing of exons 22 and 25. Exon 8 and the 3' end of exon 14 were analyzed by denaturing gradient gel electrophoresis (DGGE). Two patients with a moderate form of the disease demonstrated an abnormal electrophoretic pattern in exon 8 and sequencing demonstrated missense mutations at codon 372 for arginine within a
thrombin
activation site. One missense mutation was a C to T transition substituting cysteine for arginine and the other was an infrequent G to C transversion at an adjacent nucleotide changing the same arginine to proline.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:A directed search for mutations in hemophilia A using restriction enzyme analysis and denaturing gradient gel electrophoresis. A study of seven exons in the factor VIII gene of 170 cases. 152 2
Factor VIII
(
FVIII
) is the nonproteolytic cofactor for FIXa in the tenase complex of blood coagulation.
FVIII
is proteolytically activated by
thrombin
and FXa in vitro to form a heterotrimer with full procoagulant activity. Activated protein C inactivates
thrombin
-activated
FVIII
through cleavage adjacent to position Arg 336 in the cofactor. We have investigated the interaction of FIXa and
FVIII
and subjected
FVIII
polypeptides to N-terminal amino acid sequence analysis. Contrary to previous reports, we were unable to demonstrate the activation of
FVIII
by FIXa. Incubation of these two proteins at equimolar or close to equimolar concentrations resulted in the inactivation of
FVIII
, coincident with cleavage of the
FVIII
heavy chain adjacent to Arg 336 and the light chain adjacent to Arg 1719. These cleavages were detected in the presence or absence of
thrombin
, indicating that FIXa does not stabilize
thrombin
-activated FVIIIa. APC cleaved
FVIII
at the same position in the heavy chain, and simultaneous incubation of
FVIII
, APC, and FIXa did not result in stabilization of the cofactor. We conclude that FIXa does not play a role in the stabilization or activation of
FVIII
.
...
PMID:Inactivation of factor VIII by factor IXa. 154 20
We have recently identified the molecular defect responsible for cross-reacting material-positive hemophilia A in two unrelated patients in which the substitution of cysteine for arginine-1689 (
Factor VIII
-East Hartford[FVIII-EH]) abolishes a critical
Factor VIII
light chain
thrombin
cleavage site. As other mutant proteins with a cysteine for arginine substitution have been modified in the presence of cysteamine, we have determined the effect of this and other reducing agents on FVIII-EH function. Cysteamine concentrations between 0.1 and 10 mM caused dose- and time-dependent increases in FVIII-EH VIII:C activity, as much as 14-fold (to 35 and 62 U/dl for the two patients tested). Comparable data were obtained in a standard one-stage VIII:C coagulation assay and in a chromogenic substrate assay measuring Factor Xa generation. Thrombin cleavage of the FVIII-EH light chain in the presence of cysteamine was documented by immunoadsorption and analysis. Cystamine and cysteamine-S-phosphate, similar compounds that do not possess a free thiol group, had no effect. Cysteamine augmentation of FVIII-EH VIII:C was abolished by the simultaneous addition of N-ethyl maleimide or iodoacetamide, but these sulfhydryl blocking agents did not prevent the VIII:C increase and light chain cleavage by
thrombin
if the plasma samples were dialyzed to remove the inhibitors before adding the cysteamine. However, incubation with DTT before iodoacetamide prevented the cysteamine effect after dialysis. These data suggest that when isolated from patient plasma, FVIII-EH cysteine-1689 is present in a disulfide bond. This bond is cleaved by cysteamine to form a new mixed disulfide, a pseudolysine that restores a
thrombin
cleavage site that is essential for procoagulant function.
...
PMID:Cysteamine enhances the procoagulant activity of Factor VIII-East Hartford, a dysfunctional protein due to a light chain thrombin cleavage site mutation (arginine-1689 to cysteine). 156 80
Factor VIII
East Hartford (FVIII-EH) procoagulant activity is reduced because the substitution of cysteine for arginine 1689 abolishes an essential
Factor VIII
light chain
thrombin
cleavage site. Incubation of FVIII-EH plasma with penicillamine or DTT causes a five- to sixfold increase in FVIII-EH VIII:C, at 80 and 1 mM, respectively. While there is no FVIII-EH light chain cleavage when
thrombin
is added in the presence of penicillamine or DTT, these reducing agents disrupt the FVIII-vWf complex. For example, the addition of 5 mM DTT to normal or FVIII-EH plasma causes a 50% reduction in
Factor VIII
binding to vWf. These observations suggested that DTT increases FVIII-EH VIII:C by partial dissociation of FVIII-EH from vWf. This was verified by showing that vWf-free FVIII-EH had VIII:C activity of 21 U/dl, while the starting plasma level was 2.5 U/dl. Removal of other FVIII-EH plasma proteins by agarose gel filtration had no effect on VIII:C activity. The demonstration that this mutant
Factor VIII
has cofactor function when separated from vWf indicates that the dissociation of
Factor VIII
from vWf is an essential effect of
Factor VIII
light chain cleavage at arginine-1689.
...
PMID:Factor VIII-East Hartford (arginine 1689 to cysteine) has procoagulant activity when separated from von Willebrand factor. 156 81
Generation of coagulation factor Xa by the intrinsic pathway protease complex is essential for normal activation of the coagulation cascade in vivo. Monocytes and platelets provide membrane sites for assembly of components of this protease complex, factors IXa and VIII. Under biologically relevant conditions, expression of functional activity by this complex is associated with activation of factor VIII to VIIIa. In the present studies, autocatalytic regulatory pathways operating on monocyte and platelet membranes were investigated by comparing the cofactor function of
thrombin
-activated factor VIII to that of factor Xa-activated factor VIII. Reciprocal functional titrations with purified human factor VIII and factor IXa were performed at fixed concentrations of human monocytes, CaCl2, factor X, and either factor IXa or factor VIII.
Factor VIII
was preactivated with either
thrombin
or factor Xa, and reactions were initiated by addition of factor X. Rates of factor X activation were measured using chromogenic substrate specific for factor Xa. The K1/2 values, i.e., concentration of factor VIIIa at which rates were half maximal, were 0.96 nM with
thrombin
-activated factor VIII and 1.1 nM with factor Xa-activated factor VIII. These values are close to factor VIII concentration in plasma. The Vsat, i.e., rates at saturating concentrations of factor VIII, were 33.3 and 13.6 nM factor Xa/min, respectively. The K1/2 and Vsat values obtained in titrations with factor IXa were not significantly different from those obtained with factor VIII. In titrations with factor X, the values of Michaelis-Menten coefficients (Km) were 31.7 nM with
thrombin
-activated factor VIII, and 14.2 nM with factor Xa-activated factor VIII. Maximal rates were 23.4 and 4.9 nM factor Xa/min, respectively. The apparent catalytic efficiency was similar with either form of factor VIIIa. Kinetic profiles obtained with platelets as a source of membrane were comparable to those obtained with monocytes. These kinetic profiles are consistent with a 1:1 stoichiometry for the functional interaction between cofactor and enzyme on the surface of monocytes and platelets. Taken together, these results indicate that autocatalytic pathways connecting the extrinsic, intrinsic, and common coagulation pathways can operate efficiently on the monocyte membrane.
...
PMID:Functional assembly of intrinsic coagulation proteases on monocytes and platelets. Comparison between cofactor activities induced by thrombin and factor Xa. 161 61
The effects of physical training on hemostatic parameters were evaluated in 56 postmyocardial infarction (MI) patients before and after one month of systematic physical training and in 30 control post-MI patients, who did not undergo such training. There were no significant changes in prothrombin time (PT) and alpha 1-antitrypsin (alpha 1AT) at the beginning and end of the study in either group. Levels of fibrinogen,
Factor VIII
: C (VIII:C) and von Wildebrand antigen (vWf:Ag), and activities of ATIII and plasminogen (Plg) were significantly decreased in the group with physical training (p less than 0.05), while values were unchanged in the control group. Hematocrit, platelet counts, and alpha 2-plasmin inhibitor (alpha 2PI) activities also decreased in the physical training group (p less than 0.05). In contrast, these variables increased in the control group (p less than 0.05). Activated partial thromboplastin time (aPTT) tended to be prolonged in the group with physical training, while it was shortened in the control group. In a subset of 20 patients with physical training, resting levels of plasmin-alpha 2PI complex (PIC),
thrombin
-antithrombin III complex (TAT), protein-C (P-C:Ag), plasminogen activator inhibitor-1 (PAI-1), VII:C, and P-C activities had significantly decreased after one month of physical training (p less than 0.05), although tissue plasminogen activator activities remained unchanged. Physical training appeared to suppress coagulability as indicated by the decrease in fibrinogen, VIII:C, vWf:Ag, VII:C, and TAT, and prolongation of aPTT. The decrease in plasminogen, t-PA:Ag, alpha 2PI, PAI-1, and PIC after physical training may result from the decreased coagulability. In conclusion, physical training appears to induce a suppression of the coagulation system in patients in the recovery phase of MI.
...
PMID:Blood coagulability and fibrinolytic activity before and after physical training during the recovery phase of acute myocardial infarction. 162 56
The decay of human coagulation factor VIIIa has been studied by kinetic methods that ensure no interference through proteolytic feedback. The rate of decay of factor VIIIa activity was found to vary with the activator used to activate factor VIII. Thrombin-activated factor VIII-von Willebrand factor complex (fVIII-vWf) decayed at a rate of 0.31 min-1, whereas factor Xa-activated fVIII-vWf decayed at 0.11 min-1 under the same conditions.
Factor VIII
free of von Willebrand factor (factor VIII: C), although decaying at a generally slower rate after activation, still showed a dependence of decay rate on activator:
thrombin
-activated factor VIII:C decaying at a rate of 0.06 min-1, and factor Xa-activated factor VIII: C at 0.01 min-1. Readdition of von Willebrand factor (18 micrograms/ml) to factor VIII:C did not alter the observed activity or decay rate. The decay of the two species of factor VIIIa was studied, using the fVIIIa-vWf complex, in the presence of varying levels of factor IXa. Plots of reciprocal decay rates vs factor IXa concentration were linear, and nearly parallel for the two factor VIIIa species, with a mean slope of 0.56 min.nM-1. In addition to these studies, we have confirmed previous studies showing that the two forms of factor VIIIa differ in cofactor activity, but they do so in the same ratio as in their decay rates. We suggest that this difference and that observed in decay rate have a common cause, and incorporate this into a potential kinetic model of factor VIII activation and decay.
...
PMID:Thrombin-activated and factor Xa-activated human factor VIII: differences in cofactor activity and decay rate. 163 34
Factor VIII
functions in an enzyme complex upon the activated platelet membrane where phosphatidylserine exposure correlates with expression of receptors for factor VIII. To evaluate the specificity of phosphatidylserine-containing membrane binding sites for factor VIII, we have developed a novel membrane model in which phospholipid bilayers are supported by glass microspheres (lipospheres). The binding of fluorescein-labeled factor VIII to lipospheres with membranes of 15% phosphatidylserine was equivalent to binding to phospholipid vesicles (KD = 4.8 nM). Purified von Willebrand factor (vWf), a carrier protein for factor VIII, decreased membrane binding of factor VIII with a Ki of 10 micrograms/ml. Likewise, normal plasma decreased bound factor VIII by more than 90% whereas plasma lacking vWf decreased the binding of factor VIII by only 20%. Proteolytic activation of factor VIII by
thrombin
, which releases factor VIII from vWf, increased liposphere binding in the presence of vWf and in the presence of normal plasma. Although factor V is homologous to factor VIII and binds to lipospheres with the same affinity, purified factor V was not an efficient competitor for the membrane binding sites of factor VIII. These results indicate that phosphatidylserine-containing membrane sites have sufficient specificity to select
thrombin
-activated factor VIII from the range of phospholipid-binding proteins in plasma.
...
PMID:Specificity of phosphatidylserine-containing membrane binding sites for factor VIII. Studies with model membranes supported by glass microspheres (lipospheres). 163 16
Factor VIII
is a cofactor in the tenase enzyme complex which assembles on the membrane of activated platelets. A critical step in tenase assembly is membrane binding of factor VIII. Platelet membrane factor VIII-binding sites were characterized by flow cytometry using either fluorescein maleimide-labeled recombinant factor VIII or a fluorescein-labeled monoclonal antibody against factor VIII. Following activation by
thrombin
, most platelets bound factor VIII within 90 s. In addition, over the course of several minutes, membranous vesicles (microparticles) were shed from the platelet plasma membrane and each microparticle bound as much factor VIII as a stimulated platelet. Over 30 min, stimulated platelets (but not microparticles) lost the capacity to bind factor VIII.
Factor VIII
bound saturably to microparticles from platelets stimulated with
thrombin
,
thrombin
plus collagen, or the complement proteins C5b-9. The binding of factor VIII was compared to factor V, a structurally homologous coagulation cofactor. Analysis of microparticle binding kinetics yielded similar on and off rates for factor VIII and factor Va and KD values of 2-10 nM. In the presence of 20 nM factor Va, the binding of factor VIII to microparticles was increased, and there was a comparable increase in platelet tenase activity. At higher factor Va concentrations, factor VIII binding and tenase activity were inhibited. Conversely, factor VIII had a similar dose-dependent effect on factor Va binding and platelet prothrombinase activity. Synthetic phospholipid vesicles containing phosphatidylserine competed with microparticles for binding of factor VIII and factor Va. These studies indicate that activated platelets express a transient increase in high affinity receptors for factor VIII, whereas platelet-derived microparticles express a sustained increase in receptors. The binding characteristics of platelet membrane receptors for factor VIII are similar to those for factor Va.
...
PMID:Platelet-derived microparticles express high affinity receptors for factor VIII. 165 28
Glomerular endothelial cells are located in extremely close proximity to glomerular mesangial cells, without intervening basement membrane. This close apposition of the two cell types suggest that interactions between the cells should readily occur. Given that endothelial cells are known to produce mediators which regulate the tone of underlying vascular smooth muscle cells, the hypothesis that glomerular endothelial cells can produce endothelium-derived relaxation factor and the potent vasoconstrictor endothelin-1 was examined. Pure cultures of glomerular endothelial cells were established in vitro. The cells expressed a number of characteristics that identified them as endothelial cells, namely
Factor VIII
related antigen, angiotensin I converting enzyme, and uptake of acetylated LDL. The glomerular endothelial cells responded to the calcium-mobilizing agonists bradykinin, ATP,
thrombin
and platelet activating factor with a significant rise in cytosolic calcium concentrations. Under basal conditions, the glomerular endothelial cells produced a mediator pharmacologically indistinguishable from EDRF, which raised cGMP levels in co-incubated mesangial cells approximately 4 to 5-fold. The calcium-mobilizing agonists further stimulated EDRF release by glomerular endothelial cells. Glomerular endothelial cells in culture were also found to express mRNA for endothelin-1, and to secrete this peptide into their supernatant. Furthermore, the calcium-mobilizing agonists markedly stimulated endothelin-1 release by activating endothelin-1 gene transcription. Glomerular mesangial cells respond to EDRF with a rise in cytosolic cGMP concentration and relaxation, and to endothelin-1 with a rise in cytosolic calcium concentration and contraction. It is therefore proposed that local release of EDRF and endothelin-1 by glomerular endothelial cells may participate in the regulation of glomerular hemodynamics through alterations in mesangial cell contractile tone.
...
PMID:Endothelium-derived vasoactive mediators and renal glomerular function. 179 4
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