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:3.4.21.5 (thrombin)
33,306 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Methods have been developed to isolate human platelet membrane fragments from plasma and serum. Rabbit antibody produced against the human platelet membrane glycoprotein complex, IIb/IIIa, was utilized in an immunoelectrophoretic assay to evaluate the amount of this antigen in various microparticle preparations. The serum concentration of platelet microparticles was more than tenfold greater than that observed for plasma (65 micrograms/ml versus 4.4 micrograms/ml, respectively). Ultrastructural evaluation of either plasma or serum-derived microparticles disclosed a variety of membrane fragments and membrane-bound vesicles with occasional fragments of red blood cells, white blood cells, and platelets. In contrast, microparticle preparations derived from isolated washed platelets after thrombin stimulation contained a heterogeneous array of membrane fragments, vesicles, and granules but no identifiable red cell, white cell, or platelet fragments. Thus, these studies demonstrate that normal human plasma and serum contain platelet membrane fragments that are produced during cell activation. If a similar loss of platelet membranes occurs in vivo following reversible platelet activation, it is possible that the resulting membrane modifications may be of importance in both the structural and functional changes that develop during platelet senescence.
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PMID:Isolation of human platelet membrane microparticles from plasma and serum. 711 53

The kinetics and hydrodynamic properties of factor V-membrane interaction were characterized. Factor V bound to membranes containing acidic phospholipids with a high collisional efficiency. For membranes of 20% phosphatidyl-serine-80% phosphatidylcholine, an association rate constant of (1.13 +/- 0.10) X 10(8) M-1 s-1 was obtained. These membranes contained about 20 factor V binding sites per vesicle of 3.6 X 10(6) daltons. This association rate represented about a 30% collisional efficiency. Dissociation of factor V was measured by a fluorescence energy transfer method with a dissociation rate constant of 0.0055 s-1 at 10 degrees C. The equilibrium dissociation constant for binding to these membranes at 10 degrees C and 0.14 M ionic strength was 5 X 10(-11) M. Ionic strength, pH, calcium, and charge density in the membrane had large effects on the rate of factor V-membrane dissociation, indicating a strongly ionic interaction between protein and membrane. In contrast, the association rate was nearly insensitive to ionic strength. The membrane-binding properties were relatively unchanged after thrombin digestion of factor V or after long-term protein storage which resulted in loss of procoagulant activity. Other proteins of the prothrombinase reaction greatly decreased the rate of factor Va-membrane dissociation. At protein saturation, factor V increased the hydrodynamic radius of phospholipid vesicles by 11.4 nm. In contrast, factor Va increased the hydrodynamic vesicle radius by only about 5 nm. The mass of membrane-bound protein was comparable for both proteins.
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PMID:Kinetic and hydrodynamic analysis of blood clotting factor V-membrane binding. 717 55

Present knowledge of the structure and function of platelet glycocalicin is reviewed. Glycocalicin (M 150,000) is a glycoprotein component of the outer surface of intact platelets which is released in soluble form following platelet homogenization. Glycocalicin has been purified and shown to inhibit platelet aggregation induced by thrombin or by ristocetin. Thrombin binding activity is associated with the peptide "tail" of the molecule (Mr 45,000), the macroglycopeptide portion (Mr 120,000) being without effect. Glycocalicin and membrane-bound glycoprotein I have been shown to be functionally and immunologically identical. Studies with platelets modified by chymotrypsin, and with platelets from patients with Bernard-Soulier disease and an ill-defined bleeding abnormality show that the amount of thrombin bound is proportional to the total amount of glycocalicin and glycoprotein I present. These results support the concept of a single class of binding site for thrombin in platelets.
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PMID:Structure and function of platelet glycocalicin. 736 63

Poliovirus protein 3B (also known as VPg) is covalently linked to the 5' ends of both genomic and antigenomic viral RNA. Genetic and biochemical studies have implicated protein 3AB, the membrane-bound precursor to VPg, in the initiation of genomic RNA synthesis. We have purified 3AB to near homogeneity following thrombin cleavage of purified glutathione S-transferase-3AB. When added to transcription reaction mixtures catalyzed by poliovirus RNA polymerase (3Dpol), 3AB stimulated RNA synthesis up to 75-fold with oligo(U)-primed virion RNA, globin mRNA, and unprimed synthetic, full-length minus-strand viral RNA as the templates. Synthetic VPg also stimulated RNA synthesis but was only 1 to 2% as effective as 3AB on a molar basis. The increased level of transcription was not the result of enhancing the elongation rate of the polymerase. No evidence was found for uridylylation of 3AB or for covalent linkage to RNA transcription products. 3AB sedimented as a multimer in glycerol gradients. In the presence of the polymerase, the sedimentation rate of both proteins increased, suggesting the formation of a complex. Detergent prevented both multimerization and complex formation. The polymerase also bound to immobilized glutathione S-transferase-3AB; this procedure was used to purify the polymerase to near homogeneity. These results suggest a mechanism for bringing together 3AB, 3Dpol (or its precursor 3CD), and viral RNA in host cell membranous vesicles in which all viral RNA synthesis occurs.
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PMID:Poliovirus protein 3AB forms a complex with and stimulates the activity of the viral RNA polymerase, 3Dpol. 747 38

Activated platelets have been shown previously to exhibit membrane-bound IL-1 bioactivity, which leads to the question of localization of the cytokine in platelets. Using immunocytological and flow cytometric techniques, we found IL-1 alpha and IL-1 beta in the cytoplasma of both resting and thrombin-activated platelets. Immunogold-silver staining of the cell surface of activated platelets as well as preembedding antibody treatment of platelets revealed the presence of IL-1 (alpha and beta) in low density on the surface of intact cells in contrast to distinct enrichment in the cytoplasma of damaged platelets. Fibrin fibres present between cells indicated adsorbance of IL-1. There was also weak binding of anti-IL-1 alpha to the surface of thrombin-activated platelets as shown by flow cytometry. Following activation there appears to be some transfer of IL-1 onto the cell surface of activated cells, the bulk of the cytokine, however, is probably not released prior to platelet disintegration. In summary, we present evidence for the presence of both IL-1 alpha and IL-1 beta in resting and activated platelets without being able to demonstrate localization of the cytokines to specific subcellular structures.
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PMID:Platelets contain interleukin-1 alpha and beta which are detectable on the cell surface after activation. 763 Nov 54

Neutral endopeptidase 24.11, a membrane-bound metallopeptidase, cleaves, and degrades vasoactive peptides such as atrial natriuretic peptide, endothelin, angiotensin I, substance P, and bradykinin. Therefore, the presence of this metallopeptidase may contribute to the regulation of vascular tone and local inflammatory responses in the vascular endothelium and elsewhere. We determined neutral endopeptidase in cultured human endothelial cells from different vascular beds and studied its regulation by protein kinase C. Neutral endopeptidase was detected in all cultured endothelial cell types. Lowest concentrations were measured in human endothelial cells from umbilical veins (360 +/- 14 pg/mg protein), followed by pulmonary and coronary arteries; higher concentrations were found in endothelial cells from the cardiac microcirculation (1099 +/- 73 pg/mg protein). Neutral endopeptidase content increased during cell growth but was not affected by endothelial cell growth factor or modifications of the growth medium. Stimulation of protein kinase C with 1-oleoyl-2-acetyl-rac-glycerol (0.1 to 1 mumol/L) and phorbol 12-myristate 13-acetate (0.01 to 0.1 mumol/L) induced a time- and concentration-dependent increase of endothelial cells that was inhibited by cycloheximide (5 mumol/L), an inhibitor of protein synthesis. Incubation with phospholipase C (1 mumol/L) and thrombin (10 IU/mL) induced upregulation of neutral endopeptidase, resulting in 158 +/- 26% and 150 +/- 22% increases, respectively, compared with controls. The thrombin effect was inhibited by calphostin C (1 mumol/L), an inhibitor of protein kinase C. Endothelial neutral endopeptidase is constitutively expressed in endothelial cells from different origins and is inducible by thrombin via activation of the protein kinase C pathway.
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PMID:Regulation and differential expression of neutral endopeptidase 24.11 in human endothelial cells. 763 30

Factor V was purified from the plasma of an activated protein C (APC)-resistant patient who is homozygous for the mutation Arg506-->Gln (factor VR506Q). Factor VR506Q was converted by thrombin into factor Va which was further purified yielding a factor Va preparation that had the same cofactor activity in prothrombin activation as normal factor Va. Inactivation of low concentrations of normal factor Va (< 5 nM) by 0.15 nM APC in the presence of phospholipid vesicles proceeded via a biphasic reaction that consisted of a rapid phase (k = 4.3 x 10(7) M-1s-1), yielding a reaction intermediate with reduced cofactor activity that was fully inactivated during the subsequent slow phase (k = 2.3 x 10(6) M-1s-1). Inactivation of factor VaR506Q proceeded via a monophasic reaction (k = 1.7 x 10(6) M-1s-1). Immunoblot analysis showed that APC-catalyzed inactivation of factor Va occurred via peptide bond cleavages in the heavy chain. The rapid phase of inactivation of normal factor Va was associated with cleavage at Arg506 and full inactivation of factor Va required subsequent cleavage at Arg306. The slow monophasic inactivation of factor VaR506Q correlated with cleavage at Arg306. Cleavage at Arg506 in normal factor Va resulted in accumulation of a reaction intermediate that exhibited 40% cofactor activity in prothrombin activation mixtures that contained a high factor Xa concentration (5 nM). Compared with native factor Va, the reaction intermediate retained virtually no cofactor activity at low factor Xa concentrations (0.3 nM). This demonstrates that factor Va that is cleaved at Arg506 is impaired in its ability to interact with factor Xa. Michaelis-Menten kinetic analysis showed that cleavage at Arg506 in membrane-bound factor Va was characterized by a low Km for factor Va (20 nM) and kcat = 0.96 s-1. For cleavage at Arg306 in factor VaR506Q the kinetic parameters were Km = 196 nM and kcat = 0.37 s-1. This means that differences between APC-catalyzed inactivation of factors Va and VaR506Q become much less pronounced at high factor Va concentrations. When factor VaR506Q was inactivated by APC in the absence of phospholipids, cleavage at Arg679 of the heavy chain also contributed to factor Va inactivation. Comparison of rate constants for APC-catalyzed cleavage at Arg306, Arg506, and Arg679 in the absence and presence of phospholipids indicated that phospholipids accelerated these cleavages to a different extent.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Peptide bond cleavages and loss of functional activity during inactivation of factor Va and factor VaR506Q by activated protein C. 767 48

Thrombomodulin (TM) is the anticoagulant endothelial cell membrane-bound protein cofactor in the thrombin-mediated activation of protein C (PC). It has been clearly demonstrated that the anticoagulant and profibrinolytic functions of the PC system are important for the prevention of a thromboembolic disease. Patients with PC, protein S, or PC "'cofactor"' deficiency and/or dysfunction develop thromboembolic diseases. However, the molecular abnormality in at least 20% to 30% of thrombophilic patients cannot be identified by hitherto recognized defects. A putative pathologic lesion in the TM gene could be one of several candidates for these prothrombotic mutations. A directed search strategy for deletions, insertions, or point mutations in the TM gene has not been performed. Therefore, in the present study, we have analyzed the entire TM gene, including the promoter region, by polymerase chain reaction-single-strand conformation polymorphism (PCR-SSCP) in normal healthy volunteers and in patients presenting with a thromboembolic disease. We have identified a patient with a thromboembolic disease and a TM point mutation. In a 45-year-old Hispanic man with a documented pulmonary embolism, PCR-SSCP showed an aberrant band pattern and subsequent DNA sequence analysis showed a heterozygous substitution for G1456 to T. This substitution predicts an Asp468 to a Tyr change in the amino acid sequence that is located between the transmembrane domain and the sixth epidermal growth factor-like domain. The Asp468 to Tyr change would probably lead to significant structural changes not allowing the expression of the TM protein or to a conformational change that is not functional.
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PMID:The first mutation identified in the thrombomodulin gene in a 45-year-old man presenting with thromboembolic disease. 781 89

The ability of intact peripheral blood monocytes to modulate factor V procoagulant activity was studied using electrophoretic and autoradiographic techniques coupled to functional assessment of cofactor activity. Incubation of plasma concentrations of factor V with monocytes (5 x 10(6)/ml) resulted in the time-dependent cleavage of the 330-kDa protein. Activation occurred via several high molecular mass intermediates (> or = 200 kDa) to yield peptides of 150, 140, 120, 94, 91, 82, and 80 kDa, which paralleled the expression of cofactor activity. The cleavage pattern observed differed from that obtained with either thrombin or factor Xa as an activator. The incubation time required to achieve full cofactor activity was dependent on the monocyte donor and ranged from 10 min to 1 h and was consistently slightly lower than that obtained with thrombin-activated factor Va. Cofactor activity was not diminished by additional incubation. The cofactor activity generated bound to the monocyte such that a competent prothrombinase complex was formed at the monocyte membrane surface. Furthermore, within 5 min of factor V addition to monocytes, near maximal cofactor activity (approximately 70%) was bound and expressed on the monocyte membrane. The proteolytic activity toward factor V was associated primarily with the monocyte membrane, as little proteolytic activity was released into the cell-free supernatant. Proteolytic activity was inhibited by diisopropyl fluorophosphate and phenylmethanesulfonyl fluoride. However, the inhibitor profile obtained with alpha 1-antiproteinase inhibitor, alpha 1-antichymotrypsin, and alpha 2-macroglobulin suggested membrane-bound forms of elastase and cathepsin G were mediating, in large part, the proteolysis observed. These data were confirmed using purified preparations of both proteases and a specific anti-human leukocyte elastase antibody. Thus, expression of these proteases at the monocyte surface may contribute to thrombin generation at extravascular tissue sites by catalyzing the activation of the essential cofactor, factor Va, which binds to the monocyte surface and supports the factor Xa-catalyzed activation of prothrombin.
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PMID:Human coagulation factor V is activated to the functional cofactor by elastase and cathepsin G expressed at the monocyte surface. 783 8

A poor anticoagulant response of plasma to activated protein C is correlated with a single mutation in the factor V molecule (Arg506-->Gln). Factor V was purified to homogeneity from plasma of two unrelated patients (patient I, factor VI, and patient II, factor VII), who are homozygous for this mutation. The factor V molecule from both patients has normal procoagulant activity when compared with factor V isolated from normal plasma in both a clotting time-based assay and in an assay measuring alpha-thrombin formation. The cleavage and subsequent inactivation by activated protein C (APC) of the alpha-thrombin-activated membrane-bound cofactor (factor Va) from both patients were analyzed and compared with the cleavage and inactivation of normal human factor Va. In normal factor Va, cleavage at Arg506 generates a M(r) = 75,000 fragment and a M(r) = 28,000/26,000 doublet and is necessary for the optimum exposure of the sites for subsequent cleavage at Arg306 and Arg679. Proteolysis at these sites leads to the appearance of M(r) - 45,000 and 30,000 fragments and a M(r) = 22,000/20,000 doublet. Cleavage at Arg306 is membrane-dependent and is required for complete inactivation. Following 5 min of incubation with APC (5.4 nM) membrane-bound normal factor Va (280 nM) has virtually no cofactor activity whereas under similar experimental conditions factor VaI and factor VaII retain approximately 50% of their initial activity. After 1 h of incubation with APC, factor VaI retains 20% of its initial cofactor activity whereas factor VaII has 10% remaining cofactor activity. The initial loss in cofactor activity (approximately 70%) of membrane-bound factor VaI and factor VaII during the first 10 min of the inactivation reaction is correlated with cleavage at Arg306 and appearance of a M(r) = 45,000 fragment and a M(r) = 62,000/60,000 doublet. Subsequently, the M(r) = 62,000/60,000 doublet is cleaved at Arg679 to generate a M(r) = 56,000/54,000 doublet resulting in complete loss of cofactor activity. Both procofactors, factor VI and factor VII, were inactivated following cleavage at Arg306 and Arg679, with APC inactivation rates equivalent to those observed for normal factor V. Our data demonstrate that: 1) cleavage at Arg506 is required for optimum exposure of the cleavage sites at Arg306 and Arg679 and rapid inactivation of membrane-bound factor Va; and 2) cleavage at Arg306 by APC on membrane-bound factor V occurs at the same rate in both normal and APC-resistant individuals. Thus cleavage at Arg306 and Arg679 and subsequent inactivation of the membrane-bound procofactor, factor V, does not require prior cleavage at Arg506 for optimum exposure.
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PMID:Characterization of the molecular defect in factor VR506Q. 787 54


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