Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.21.5 (thrombin)
 33,306 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In washed platelet systems, thrombin has been demonstrated to downregulate the platelet surface expression of glycoprotein (GP) Ib and GPIX. In the present study, we addressed the question as to whether, in the more physiologic milieu of whole blood, downregulation of platelet surface GPIb and GPIX can be induced by thrombin, adenosine diphosphate (ADP), and/or by an in vivo wound. Thrombin-induced downregulation of GPIb and GPIX on the surface of individual platelets in whole blood was demonstrated by the use of flow cytometry, a panel of monoclonal antibodies (MoAbs) and, to inhibit fibrin polymerization, the peptide glycyl-L-prolyl-L-arginyl-L-proline. Platelets were identified in whole blood by a GPIV-specific MoAb and exclusion of monocytes by light scattering properties. Flow cytometric analysis of whole blood emerging from a standardized bleeding-time wound established that downregulation of platelet surface GPIb and GPIX can occur in vivo. A GPIb-IX complex-specific antibody indicated that the GPIb and GPIX remaining on the surface of platelets activated in vivo or in vitro were fully complexed. Simultaneous analysis of individual platelets by two fluorophores demonstrated that thrombin-induced platelet surface exposure of GMP-140 (degranulation) was nearly complete at the time that downregulation of platelet surface GPIb-IX was initiated. However, degranulation was not a prerequisite because ADP downregulated platelet surface GPIb-IX without exposing GMP-140 on the platelet surface. Inhibitory effects of cytochalasins demonstrated that the activation-induced downregulation of both GPIX and GPIb are dependent on actin polymerization. In summary, downregulation of the platelet surface GPIb-IX complex occurs in whole blood stimulated by thrombin, ADP, or an in vivo wound, and is independent of alpha granule secretion.
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PMID:Downregulation of the platelet surface glycoprotein Ib-IX complex in whole blood stimulated by thrombin, adenosine diphosphate, or an in vivo wound. 844 98

Platelet glycoprotein (GP) V is a Mr 82,000 plasma membrane protein of unknown function that is cleaved by the potent platelet agonist, thrombin, to yield a Mr 69,500 fragment (GPVf1). Platelet GPIb, a disulfide-linked alpha beta heterodimer (Mr 160,000) that forms a noncovalent complex with GPIX (Mr 22,000), functions as the platelet adhesion receptor for surface-bound von Willebrand factor. Association between GPV and GPIb-IX has been suggested by the finding that both proteins are deficient in the Bernard-Soulier syndrome, a bleeding disorder characterized by giant platelets and defective interaction with von Willebrand factor. Here we report that GPV and GPIb-IX are coprecipitated by monoclonal antibodies (mAbs) against GPV, GPIb, or GPIX when platelets are solubilized in the mild detergent, digitonin. Treatment of digitonin immunopreciptates with the nonionic detergent, Nonidet P-40, released GPV from anti-GPIb and anti-GPIX mAb precipitates and GPIb-IX from the anti-GPV mAb precipitate. Removal of the Mr 45,000 amino-terminal part of GPIb alpha by treatment with elastase did not abrogate association of GPV with GPIb-IX, showing that the leucine-rich repeat sequences in GPIb alpha are not required for complex formation. Binding studies with 125I-labeled mAbs showed the presence of 24,370 GPIb-IX complexes and 11,170 molecules of GPV/platelet (n = 5). These data show that the leucine-rich glycoproteins GPV and GPIb-IX form a noncovalent complex in the platelet membrane. GPV may play a role in the interaction of platelets with von Willebrand factor.
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PMID:Glycoproteins V and Ib-IX form a noncovalent complex in the platelet membrane. 173 Jun 2

In this study, the question of whether glycoprotein Ib (GPIb) mediates both high and moderate affinity pathways of alpha-thrombin-induced platelet activation was examined. Flow cytometric studies, using a panel of monoclonal antibodies (MoAbs), showed that Serratia marcescens protease treatment removed greater than 97% of the glycocalicin portion of GPIb but did not affect the changes in the expression of GPIX or GMP-140 that were induced by high concentrations of alpha-thrombin (10 nmol/L). However, Serratia treatment almost completely abolished the increase in platelet surface GMP-140 induced by low concentrations of alpha-thrombin (0.5 nmol/L) and diminished the downregulation of platelet surface GPIX by 60.9% +/- 5.6% (mean +/- SEM, n = 3). When present in 20-fold molar excess, an MoAb directed against the alpha-thrombin/von Willebrand factor (vWf) binding domains of GPIb completely blocked the ristocetin-dependent binding of vWf to platelets but inhibited only to about 50% the binding of alpha-thrombin and the activation-dependent binding of vWf. In platelets treated with Serratia marcescens protease to remove GPIb, a concentration of this MoAb 16,000-fold in excess of the maximum possible remaining copies of GPIb failed to inhibit platelet activation by alpha-thrombin. These studies demonstrate that activation of intact platelets by alpha-thrombin proceeds by both GPIb-dependent and GPIb-independent mechanisms.
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PMID:Glycoprotein Ib (GPIb)-dependent and GPIb-independent pathways of thrombin-induced platelet activation. 201

Platelet membrane glycoprotein Ib (GPIb) and the GPIIb-IIIa complex have central roles in the interaction of platelets with the plasma coagulation system, damaged vessel walls, and other platelets. We investigated the effects of thrombin on these glycoproteins. Monoclonal antibodies were used to assess platelet surface glycoproteins by flow cytometry, total platelet glycoprotein content by immunoassay, and glycoproteins released from platelets, also by immunoassay. Five new observations were made with regard to thrombin-induced changes in platelet membrane glycoproteins: (a) The marked decrease in platelet surface binding of antibodies directed at GPIb was not confined to antibodies directed at the von Willebrand factor binding site. (b) There was a marked decrease in platelet surface binding of an antibody directed at GPIX, with maintenance of the 1:1 ratio of platelet surface binding of antibodies directed at GPIb and GPIX. (c) Changes in platelet surface binding of antibodies were not restricted to a distinct subpopulation of platelets. (d) There was no associated platelet release of glycocalicin (a proteolytic fragment of GPIb). (e) There was no associated platelet release of the GPIIb-IIIa complex. These thrombin-induced changes may be important in modulating the reactivity of platelets with the damaged vessel wall and with each other.
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PMID:Thrombin-induced changes in platelet membrane glycoproteins Ib, IX, and IIb-IIIa complex. 366 49

The effects of neutrophil cathepsin G on the glycoprotein (GP) Ib-IX complex of washed platelets were examined. Cathepsin G resulted in a concentration- and time-dependent decrease in the platelet surface GPIb-IX complex, as determined by flow cytometry, binding of exogenous von Willebrand factor (vWF) in the presence of ristocetin, and ristocetin-induced platelet agglutination. Cathepsin G resulted in proteolysis of the vWF binding site on GPIb alpha (defined by monoclonal antibody [MoAb] 6D1), as determined by increased supernatant glycocalicin fragment (a proteolytic product of GPIb alpha); decreased total platelet content of GPIb; and lack of effect of either cytochalasin B (an inhibitor of actin polymerization), prostaglandin I2 (an inhibitor of platelet activation), or prior fixation of the platelets. However, cathepsin G resulted in minimal decreases in the binding to fixed platelets of MoAbs TM60 (directed against the thrombin binding site on GPIb alpha) and WM23 (directed against the macroglycopeptide portion of GPIb alpha). In contrast to its proteolytic effect on GPIb alpha, the cathepsin G-induced decrease in platelet surface GPIX and the remnant of the GPIb-IX complex (defined by MoAbs FMC25 and AK1) was via a cytoskeletal-mediated redistribution, as determined by lack of change in the total platelet content of GPIX and the GPIb-IX complex; complete inhibition by cytochalasin B, prostaglandin I2, and prior fixation of platelets. Experiments with Serratia protease-treated and Bernard-Soulier platelets showed that neither platelet surface GPIb nor cathepsin G-induced proteolysis of GPIb were required for the cathepsin G-induced redistribution of the remnant of the GPIb-IX complex or the cathepsin G-induced increase in platelet surface P-selectin. In summary, neutrophil cathepsin G modulates the platelet surface expression of the GPIb-IX complex both by proteolysis of the vWF binding site on GPIb alpha and by a cytoskeletal-mediated redistribution of the remainder of the complex. Prior studies show that, although thrombospondin 1, antiserine proteases, and plasma are all inhibitors of cathepsin G, the effects of cathepsin G on platelets, including an increase in surface GPIIb-IIIa, occur during close contact between neutrophils and platelets in a protective microenvironment (eg, thrombosis and local inflammation).(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Neutrophil cathepsin G modulates the platelet surface expression of the glycoprotein (GP) Ib-IX complex by proteolysis of the von Willebrand factor binding site on GPIb alpha and by a cytoskeletal-mediated redistribution of the remainder of the complex. 751 6

In the early phase of primary hemostasis, platelets adhere to damaged vessel wall by binding via the platelet glycoprotein (GP) Ib-V-IX complex to von Willebrand factor (vWf) exposed on the subendothelium. The complex is composed of four glycoprotein subunits, GPIb alpha, GPIb beta, GPIX and GPV, each with a variable number of leucine-rich repeats. GPIb alpha and GPIb beta are linked by a disulphide bridge while GPIX and GPV associate noncovalently with the complex. The study of defects in the expression of the GPIb-V-IX complex at the platelet surface leading to pathological disorders, like Bernard-Soulier syndrome (BSS), or in the affinity of platelets for vWf, like pseudo-von Willebrand disease, has helped to delineate the binding site for vWf on GPIb alpha. However, the mechanism by which the complex binds to vWf has not yet been elucidated but it must involve changes in the conformation of the molecules as no interaction between platelets and vWf occurs in the plasma. The GPIb-V-IX complex has a binding site for thrombin on GPIb alpha which participates in the platelet activation by that agonist. GPV is also cleaved by thrombin but the function of this proteolysis is not clear. The platelet response to thrombin is slower and weaker when the thrombin binding site on GPIb alpha is blocked or cleaved or when the GPIb-V-IX complex is not expressed on the platelet surface as in classic BSS. At low doses of thrombin, the rapid activation of the platelets via the seven-transmembrane thrombin receptor is dependent on the presence of the GPIb-V-IX complex.
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PMID:Platelet GPIb-V-IX complex. Structure, function, physiology, and pathology. 766 Jan 35

We have recently shown that several components from the platelet plasma membrane were also present at different rates in the alpha-granule membrane. This is the case for the glycoprotein (GP) IIb-IIIa (CD41), CD36, CD9, PECAM1, and Rap1b, while the GPIB-IX-V complex was considered to escape the rule. In this investigation, we studied the subcellular localization of GPIb, GPIX, and GPV in the resting platelets of normal subjects, patients with Bernard-Soulier syndrome, patients with Gray platelet syndrome, and human cultured megakaryocytes. Ultra-thin sections of the cells were labeled with antibodies directed against glycocalicin, GPIb, GPIX, and GPV. We have shown that a significant and reproducible labeling for the three GPs was associated with the alpha-granule membrane, accounting for approximately 10% of the total labeling. Furthermore, GPIb labeling appears Willebrand factor (vWF). After thrombin activation, vWF remained close to the limiting membrane of the open canalicular system (OCS), suggesting an early association of both receptor and ligand. Plasma membrane and alpha-granule labeling was virtually absent from the Bernard-Soulier platelets (characterized by a GPIb deficiency), thus proving the specificity of the reaction. In Gray platelets (storage granule deficiency syndrome), the small residual alpha-granules were also occasionally labeled for GPIb, GPIX, and GPIX. Cultured megakaryocytes that displayed the classical GPIb distribution, eg, demarcation and plasma membranes, exhibited also a discrete labeling associated to the alpha-granules. In conclusion, this study shows that, evenly for these three GPs, the alpha-granule membrane mirrors the plasma membrane composition. This might occur through an endocytotic process affecting each plasma membrane protein to a different extent and could have a physiologic relevance in further presentation of a receptor bound to its alpha-granule ligand to the platelet surface.
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PMID:Alpha-granule membrane mirrors the platelet plasma membrane and contains the glycoproteins Ib, IX, and V. 860 28

In this study, we show that the platelet surface expression of glycoprotein (GP) V is regulated by two independent mechanisms. While confirming that both thrombin and neutrophil elastase proteolyse GPV, we show that neutrophil cathepsin G, thrombin receptor activating peptide (TRAP), and a combination of ADP and epinephrine can each result in a decrease in the platelet surface expression of GPV by a nonproteolytic mechanism: a cytoskeletal-mediated redistribution of platelet surface GPV to the surface-connected canalicular system (SCCS). Four independent lines of evidence documented the nonproteolytic nature of this decrease in the platelet surface expression of GPV. First, flow cytometric studies showed that cathepsin G, TRAP, and ADP/epinephrine decreased the platelet surface expression of GPV without changing the total platelet content of GPV. Second, immunoelectron microscopy directly demonstrated translocation of GPV from the platelet surface to the SCCS. Third, the cathepsin G-, TRAP-, and ADP/epinephrine-induced decreases in platelet surface GPV were fully reversible. Fourth, cytochalasin B, an inhibitor of actin polymerization, completely inhibited the cathepsin G-, TRAP-, and ADP/epinephrine-induced decreases in platelet surface GPV. The cytoskeletal-mediated redistribution of GPV occurred in a whole blood milieu and at physiologic temperatures (37 degrees C) and extracellular calcium concentrations (2 mmol/L). This study also defines the diverse effects on GPV, GPIb, and GPIX of multiple important platelet agonists. Cathepsin G proteolysed platelet surface GPIb alpha, but redistributed platelet surface GPIX and GPV to the SCCS. Thrombin proteolysed platelet surface GPV, but redistributed platelet surface GPIb and GPIX to the SCCS. Both TRAP and ADP/epinephrine redistributed platelet surface GPIb, GPIX, and GPV to the SCCS. Elastase proteolysed platelet surface GPIb alpha and GPV, but, unlike the other agonists tested, neither proteolysed nor redistributed platelet surface GPIX. The experiments with TRAP showed that activation of the seven-transmembrane domain thrombin receptor can result in translocation of GPIb, GPIX, and GPV to the SCCS independently of the GPIb-mediated pathway of thrombin-induced platelet activation. This study also provides two additional lines of support for the recent report that GPV is noncovalently complexed with GPIb and GPIX in the platelet surface membrane. First, although only the GPIb alpha subunit of this putative complex is known to be directly linked to the platelet cytoskeleton via actin-binding protein, cytochalasin B inhibited the ADP/epinephrine-, cathepsin G-, and TRAP-induced decrease in platelet surface GPV. Second, triple labeling flow cytometric experiments showed that, on each individual platelet, the ADP/epinephrine-induced decrease and subsequent return of the platelet surface expression of GPV occurred simultaneously with the decrease and subsequent return of the platelet surface expression of GPIb. In summary, the platelet surface expression of GPV is regulated by two independent mechanisms: proteolysis and a reversible, cytoskeletal-mediated redistribution to the SCCS.
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PMID:The platelet surface expression of glycoprotein V is regulated by two independent mechanisms: proteolysis and a reversible cytoskeletal-mediated redistribution to the surface-connected canalicular system. 860 29

Genetic defects of the blood platelet membrane glycoproteins, GPIIb-IIIa (alpha IIb/beta 3; CD41/CD61) and GPIb-V-IX (CD42) are the origin of several rare bleeding disorders, the best known of which are Glanzmann's thrombasthenia, Bernard-Soulier syndrome, and platelet-type von Willebrand's disease. In Glanzmann's thrombasthenia, GPIIb-IIIa are missing or defective and platelet aggregation is lacking or reduced. Either gene can be affected and mutations leading to lack of expression or to expression of poorly functional forms have been described. In Bernard-Soulier syndrome, GPIb-V-IX are missing or defective, leading to poor platelet adhesion at high-shear stress to damaged vessel wall and reduced platelet response to thrombin. Mutations in both GPIb alpha (CD42b) and GPIX (CD42a) have been described. Mutations in GPIb alpha can also lead to platelet-type von Willebrand's disease in which GPIb-V-IX are expressed normally but bind von Willebrand's factor spontaneously, which leads to platelet aggregation and thrombocytopenia.
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PMID:Molecular abnormalities in Glanzmann's thrombasthenia, Bernard-Soulier syndrome, and platelet-type von Willebrand's disease. 937 10

We have studied down-regulation and redistribution of glycoprotein V (GPV) and its fragment GPVf2, a subunit of a receptor for von Willebrand factor (VWF), on the surface membrane of thrombin and thrombin receptor activating peptide (TRAP) stimulated platelets by using a newly developed GPVf2-specific monoclonal antibody (1D9). Immunoelectron-microscopical studies revealed that about 50% each of total GPV and GPIX were expressed on the surface membrane of the resting human platelets, and about 83% of GPlbalpha was expressed on the surface. In thrombin-stimulated platelets, the surface GPIbalpha, GPIX and GPV, after hydrolysis by thrombin, was converted to GPVf2, translocated from the surface to the intraplatelet pool and then again redistributed to the surface. In TRAP-stimulated platelets, GPIbalpha, GPIX and GPV, without conversion to GPVf2, were translocated from the surface to the intraplatelet pool and then returned to the surface. Ristocetin-induced agglutinations of both the thrombin- and TRAP-stimulated platelets were lowered during the decreased surface expressions of GPIbalpha, GPIX and GPV/GPVf2 and then normalized when these GPs were again redistributed onto the surface, indicating that the redistributed GPIb/IX/Vf2 complex on the surface can act as a VWF receptor as efficiently as an intact GPIb/IX/V.
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PMID:Down-regulation and redistribution of GPV/GPVf2, a subunit of von Willebrand factor receptor (GPIb/IX/V complex), on the surface membrane of thrombin-stimulated human platelets. 1002 12


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