A thrombin receptor function for platelet glycoprotein Ib-IX unmasked by cleavage of glycoprotein V

Glycoprotein (GP) V is a major substrate cleaved by the protease thrombin during thrombin-induced platelet activation. Previous analysis of platelets from GP V-null mice suggested a role for GP V as a negative modulator of platelet activation by thrombin. We now report the mechanism by which thrombin activates GP V -/- platelets. We show that proteolytically inactive forms of thrombin induce robust stimulatory responses in GP V null mouse platelets, via the platelet GP Ib--IX--V complex. Because proteolytically inactive thrombin can activate wild-type mouse and human platelets after treatment with thrombin to cleave GP V, this mechanism is involved in thrombin-induced platelet aggregation. Platelet activation through GP Ib-IX depends on ADP secretion, and specific inhibitors demonstrate that the recently cloned P2Y(12) ADP receptor (G(i)-coupled ADP receptor) is involved in this pathway, and that the P2Y(1) receptor (G(q)-coupled ADP receptor) may play a less significant role. Thrombosis was generated in GP V null mice only in response to catalytically inactive thrombin, whereas thrombosis occurred in both genotypes (wild type and GP V null) in response to active thrombin. These data support a thrombin receptor function for the platelet membrane GP Ib--IX--V complex, and describe a novel thrombin signaling mechanism involving an initiating proteolytic event followed by stimulation of the GP Ib--IX via thrombin acting as a ligand, resulting in platelet activation.     

Effects of platelet glycoprotein IIb-IIIa number and glycoprotein IIIa Leu33Pro polymorphism on platelet aggregation and sensitivity to glycoprotein IIb-IIIa antagonists

We investigated the influence of glycoprotein (GP) IIIa Leu33Pro polymorphism, platelet GP IIb-IIIa number, and plasma fibrinogen concentration on platelet aggregation and antiaggregatory action of GP IIb-IIIa antagonists. Healthy volunteers with GP IIIa Pro33(-) (Leu33Leu33, n = 20) and Pro33(+) (Leu33Pro33, n = 13, and Pro33Pro33, n = 2) genotypes were included into the study. GP IIIa Leu33Pro substitution was associated with the increase of the level and rate of platelet microaggregate formation induced by GP IIb-IIIa activating antibody CRC54 (100, 200, 400 microg/ml) against the epitope within 1-100 residues of GP IIIa N-terminal part (p from 0.001 to 0.047). No significant differences were detected between parameters of platelet aggregation induced by ADP (1.25, 2.5, 5.0, 20 microM) in GP IIIa Pro33(+) and Pro33(-) donors. GP IIb-IIIa antagonist Monafram (F(ab')(2) fragment of GP-IIb-IIIa blocking antibody CRC64) (1, 2, 3 microg/ml), but not eptifibatide (50, 100, 150 ng/ml) inhibited ADP-induced aggregation slightly less efficiently in GP IIIa Pro33(+) group (p < 0.05 at 1 and 2 microg/ml Monafram). GP IIb-IIIa number (evaluated as maximal binding of (125)I-labelled antibody CRC64) varied from 40.5 to 80.8 x 10(3) per platelet with no significant influence of GP IIIa genotype. Consistent correlations were revealed between GP IIb-IIIa quantity and the level and rate of ADP-induced aggregation (r from 0.353 to 0.583, p from <0.001 to 0.037) as well as resistance (level of residual aggregation) to both GP IIb-IIIa antagonists (r from 0.345 to 0.602, p from <0.001 to 0.042). ADP-induced aggregation was considerably increased and efficiency of GP IIb-IIIa antagonists decreased in donors with high in comparison with low GP IIb-IIIa quantity (>60 and 40-50 x 10(3) per platelet respectively, p < 0.01 for most tests). No correlations were observed between all tested parameters and plasma fibrinogen concentration. Our results indicate that inter-individual variability of platelet GP IIb-IIIa number significantly affects platelet aggregation and antiaggregatory effects of GP IIb-IIIa antagonists. Contribution of this factor is higher than that of GP IIIa Leu33Pro polymorphism and variations of fibrinogen concentration.     

Effects of platelet glycoprotein IIb-IIIa number and glycoprotein IIIa Leu33Pro polymorphism on platelet aggregation and sensitivity to glycoprotein IIb-IIIa antagonists

We investigated the influence of glycoprotein (GP) IIIa Leu33Pro polymorphism, platelet GP IIb-IIIa number, and plasma fibrinogen concentration on platelet aggregation and antiaggregatory action of GP IIb-IIIa antagonists. Healthy volunteers with GP IIIa Pro33(?) (Leu33Leu33, n?=?20) and Pro33(+) (Leu33Pro33, n?=?13, and Pro33Pro33, n?=?2) genotypes were included into the study. GP IIIa Leu33Pro substitution was associated with the increase of the level and rate of platelet microaggregate formation induced by GP IIb-IIIa activating antibody CRC54 (100,?200,?400?µg/ml) against the epitope within 1–100 residues of GP IIIa N-terminal part (p from 0.001 to 0.047). No significant differences were detected between parameters of platelet aggregation induced by ADP (1.25,?2.5,?5.0,?20?µM) in GP IIIa Pro33(+) and Pro33(?) donors. GP IIb-IIIa antagonist Monafram (F(ab’)₂ fragment of GP-IIb-IIIa blocking antibody CRC64) (1,?2,?3?µg/ml), but not eptifibatide (50,?100,?150?ng/ml) inhibited ADP-induced aggregation slightly less efficiently in GP IIIa Pro33(+) group (p?<?0.05 at 1 and 2?µg/ml Monafram). GP IIb-IIIa number (evaluated as maximal binding of ¹²⁵I-labelled antibody CRC64) varied from 40.5 to 80.8?×?10³ per platelet with no significant influence of GP IIIa genotype. Consistent correlations were revealed between GP IIb-IIIa quantity and the level and rate of ADP-induced aggregation (r from 0.353 to 0.583, p from <0.001 to 0.037) as well as resistance (level of residual aggregation) to both GP IIb-IIIa antagonists (r from 0.345 to 0.602, p from <0.001 to 0.042). ADP-induced aggregation was considerably increased and efficiency of GP IIb-IIIa antagonists decreased in donors with high in comparison with low GP IIb-IIIa quantity (>60 and 40–50?×?10³ per platelet respectively, p?<?0.01 for most tests). No correlations were observed between all tested parameters and plasma fibrinogen concentration. Our results indicate that inter-individual variability of platelet GP IIb-IIIa number significantly affects platelet aggregation and antiaggregatory effects of GP IIb-IIIa antagonists. Contribution of this factor is higher than that of GP IIIa Leu33Pro polymorphism and variations of fibrinogen concentration.     

Biochemical and functional consequences of dissociation of the platelet membrane glycoprotein IIb-IIIa complex

The platelet membrane glycoproteins, IIb and IIIa, form a Ca2+- dependent heterodimer complex that functions as the fibrinogen receptor in activated platelets to mediate platelet aggregation. Little is known about factors that affect the IIb-IIIa complex within the platelet membrane. It has been observed that platelets incubated with ethylene glycol tetra-acetic acid (EGTA) at 37 degrees C are unable to aggregate or to bind monoclonal antibodies specific for the IIb-IIIa complex. To determine whether this is due to a dissociation of IIb from IIIa, we developed a method for quantitating the complex on nondenaturing, polyacrylamide gradient gels. Platelets were surface-labeled with 125I and then solubilized and electrophoresed in 0.2% Triton and 10 mmol/L CHAPS. Under these conditions and in the presence of 1 mmol/L Ca2+, glycoproteins IIb and IIIa migrated on the gels as a discrete band at Rf = 0.33. Protein that was eluted from this band bound to an immunoaffinity column specific for the IIb-IIIa complex. In contrast, when the IIb-IIIa complex was solubilized and then dissociated with EGTA, the discrete band at Rf = 0.33 was no longer present, and IIb and IIIa were now found in a broad band at Rf = 0.45 to 0.50. To study IIb and IIIa within the surface membrane, the 125I-labeled platelets were first incubated with 0.5 mmol/L EGTA (1 nmol/L free Ca2+) at 22 degrees C and then solubilized in the absence of EGTA. The IIb and IIIa from these platelets migrated at Rf = 0.33, indicating the presence of the intact IIb-IIIa complex. In contrast, when the platelets were incubated at 37 degrees C for one hour with the EGTA, the discrete band at Rf = 0.33 representing the IIb-IIIa complex gradually disappeared. This phenomenon could not be reversed by adding Ca2+ back to the platelets before solubilization and electrophoresis. This loss of the IIb-IIIa complex from intact platelets was accompanied by (a) a progressive and irreversible decrease in adenosine diphosphate (ADP)-induced platelet aggregation and (b) decreased binding of a complex-dependent monoclonal antibody to the platelets. These studies demonstrate that when platelets are exposed to low Ca2+ at 37 degrees C, the IIb-IIIa heterodimer complexes in their surface membranes are irreversibly disrupted. Because intact IIb-IIIa complexes are required for platelet aggregation, the loss of these complexes may account for the failure of these platelets to aggregate in response to ADP.     

Thrombin induces a rapid redistribution of glycoprotein Ib-IX complexes within the membrane systems of activated human platelets

Previous studies have shown a decreased binding of monoclonal antibodies (MoAbs) to glycoprotein (GP) Ib-IX complexes on thrombin-stimulated platelets, but the reason for this is poorly understood. We have used (1) immunofluorescence procedures and flow cytometry, and (2) immunogold staining and electron microscopy to investigate this phenomenon. Washed platelets were incubated with alpha-thrombin, adenosine diphosphate, or ionophore A23187 for increasing lengths of time. For alpha-thrombin, but not the other agonists, flow cytometry confirmed a dose- and time-dependent decrease in the binding of MoAbs specific for GP Ib alpha (AP-1, Bx-1), GP IX (FMC 25), or to the complex itself (SZ 1). Immunoglold staining performed using standard transmission or scanning electron microscopy high-lighted surface areas devoid of bound antibody. However, a quantitatively normal immunofluorescence was restored if paraformaldehyde-fixed, thrombin-stimulated platelets were permeabilized with Triton X-100 (Sigma Chemical Co, St Louis, MO) before MoAb addition, while immunogold staining was now seen to be concentrated within the interior of the platelet. Glutaraldehyde-fixed samples were then embedded in the resin Lowicryl K4M (Taab Laboratories Equipment Ltd, Aldermaston, England) and immunogold staining performed on thin sections using a polyclonal antibody to glycocalicin. An increased presence of GP Ib-IX complexes within surface-connected membrane systems of the thrombin-stimulated platelets was confirmed. Interestingly, GP Ib-IX movement was opposite to the thrombin-induced externalization of internal pools of GP IIb-IIIa complexes and of the alpha-granule membrane GP, GMP-140.     

A defect of platelet aggregation associated with an abnormal distribution of glycoprotein IIb-IIIa complexes within the platelet: the cause of a lifelong bleeding disorder.

A young Italian man (A.P.) has a lifelong history of bleeding from gums and mucocutaneous tissue. Electron microscopy showed a wide diversity of platelet size including giant forms. In citrated platelet-rich plasma (PRP), platelet aggregation induced by adenosine diphosphate (ADP) and other agonists was much reduced. Both secretion and clot retraction were normal. The aggregation of washed platelets with ADP was improved but remained subnormal, as was aggregation with collagen and thrombin. Fibrinogen-binding was analyzed by flow cytometry using platelets in whole blood or PRP and was markedly decreased. Crossed immunoelectrophoresis of Triton X-100 extracts of (A.P.) platelets showed that GP IIb-IIIa levels were 40% to 50% of normal. Glycoprotein (GP) IIb and GP IIIa were of usual migration in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but their labeling was much reduced during lactoperoxidase-catalyzed iodination. Binding to (A.P.) platelets of four different 125I-labeled monoclonal antibodies to GP IIb-IIIa complexes was reduced to 12% to 20% of normal levels. However, when the patient's platelets were stimulated with alpha-thrombin, monoclonal antibody binding showed the same increase (approximately 20,000 sites) as normal platelets. Both flow cytometry and immunocytochemical studies showed that the distribution of residual surface GP IIb-IIIa within the total (A.P.) platelet population was heterogeneous and not related to platelet size. Staining of ultrathin sections confirmed the presence of an internal pool of GP IIb-IIIa. Monoclonal antibodies to other membrane glycoproteins bound normally to (A.P.) platelets. The patient has a selective deficiency of the surface pool of GP IIb-IIIa complexes that is manifested clinically by a mild Glanzmann's thrombasthenia-like syndrome.     

The human platelet membrane glycoprotein complex GP IIb-IIIa expresses antigenic sites not exposed on the dissociated glycoproteins

A number of recent reports have described murine monoclonal antibodies that react specifically with the complex formed by human platelet membrane glycoproteins (GP) IIb and IIIa. We show that the IgG L, a previously described human alloantibody isolated from a polytransfused thrombasthenia patient, has similar properties. When used in non-precipitating amounts in crossed immunoelectrophoresis (CIE), 125I-IgG L bound strongly to the IIb-IIIa complex. However, after dissociation of the complex with EDTA, only a weak binding to GP IIb and no binding to GP IIIa was detected. In further studies, increased amounts of IgG L were interacted with 125I-labeled membrane glycoproteins in (a) CIE and (b) classical indirect immunoprecipitation experiments. Although the antibody was able to quantitatively precipitate the IIb-IIIa complex from Triton X-100-soluble extracts of platelet membranes, no precipitation of GP IIb or GP IIIa was observed after divalent cation chelation. Addition of EDTA to immunoprecipitates containing GP IIb-IIIa resulted in dissociation and partial release of both glycoproteins. The interaction of the IgG L with electrophoretically separated GP IIb and GP IIIa was studied using a Western blot procedure in the presence of Ca2+, Mg2+, or EDTA. The presence of divalent cations did not increase the reactivity of the antibody with the individual glycoproteins. Overall, our results show that acquired antibodies to IIb-IIIa, such as the IgG L, may predominantly react with complex-dependent determinants.     

Platelet membrane topography: colocalization of thrombospondin and fibrinogen with the glycoprotein IIb-IIIa complex

The distribution of platelet thrombospondin (TSP), fibrinogen, and glycoproteins IIb-IIIa (GPIIb-IIIa) and GPIb were studied in resting and activated human platelets using frozen thin-section immunoelectron microscopy. In resting platelets, TSP and fibrinogen were found within alpha granules and not on the platelet surface. In unstimulated platelets, GPIIb-IIIa and GPIb were distributed diffusely over the platelet membrane as well as within the body of the platelets. Upon thrombin or A23187 stimulation, TSP, fibrinogen, and GPIIb-IIIa colocalized on the platelet membrane and the canalicular system as well as on pseudopodia and between adherent platelets. GPIb distribution was unchanged by platelet activation. The findings support the hypothesis that a macromolecular complex of TSP-fibrinogen and GPIIb-IIIa forms on the activated platelet membrane.     

Severe platelet dysfunction in a patient with autoantibodies against membrane glycoproteins IIb-IIIa

A young women affected by Hodgkin's disease developed chronic autoimmune thrombocytopenic purpura. Splenectomy induced normalization of her platelet count, but hemorrhagic symptoms did not disappear. The patient's platelets did not aggregate in response to collagen and ADP and the IgG fraction of the patient's plasma induced the same defect in normal platelets. The women's IgG recognized glycoproteins IIb and IIIa of normal platelet membranes. Prednisone therapy induced the disappearance of bleeding symptoms and the normalization of platelet aggregation.     

Synthesis of analogs of human platelet membrane glycoprotein IIb-IIIa complex by chicken peripheral blood thrombocytes.

Human platelets and their phylogenetic counterparts, avian thrombocytes, play a key role in primary hemostasis. Based upon extensive studies in mammals, platelet cohesion resulting in the formation of the "hemostatic plug" is known to be mediated by the mammalian platelet glycoprotein IIb-IIIa complex in concert with fibrinogen and calcium. The immunological and biochemical technology already developed for the analyses of mammalian platelet glycoproteins has never been applied to avian thrombocytes. By indirect immunofluorescence, we now show that a polyclonal rabbit antibody specific for human glycoproteins IIb plus IIIa and the well-characterized murine monoclonal anti-IIb-IIIa complex antibody, AP2, both crossreact with IIb and IIIa analogs on intact chicken thrombocytes. By two-dimensional polyacrylamide gel electrophoresis, we also demonstrate that chicken thrombocytes will incorporate [35S]methionine into several proteins, including the glycoprotein IIb and IIIa analogs during short-term (4 hr) incubation in vitro. This finding indicates that peripheral blood nucleated thrombocytes of the chicken, unlike their mammalian counterparts, retain the capacity to synthesize protein. The significance of these findings is 2-fold. First, we provide biochemical and immunological evidence that those proteins responsible for platelet cohesion in humans are structurally conserved in cells of analogous function in chickens despite the fact that these species have diverged from a common ancestor more than 200-250 million years ago. Second, we identify chicken thrombocytes as a readily available source of messenger RNA encoding numerous proteins analogous to those already characterized in human platelets, including glycoproteins IIb and IIIa.     

Artificial microvascular graft thrombosis: the consequences of platelet membrane glycoprotein Ib inhibition and thrombin inhibition

Early thrombosis of artificial microvascular grafts (AMG, grafts < or = 2 mm internal diameter) prevents their reliable clinical use. The present studies were undertaken to examine the effect of hirudin, a thrombin-specific inhibitor, and of the F(ab')2 fragment of PG-1, a monoclonal antibody (MoAb) directed against guinea pig platelet membrane glycoprotein Ib (GPIb), on AMG patency in an animal model. One- centimeter long segments of expanded polytetrafluoroethylene (ePTFE), 0.88 mm internal diameter, were serially implanted as interposition grafts in the guinea pig femoral arterial systems bilaterally. A control group was treated with 0.5 mL saline intravenously (IV) 30 minutes before limb 1 and limb 2 graft implantation. Three experimental groups were treated with 0.5 mL saline IV before limb 1 graft implantation as an animal control and with either 0.5 mL saline containing 1.25 mg/kg IV PG-1 F(ab')2, (which inhibits ristocetin- induced platelet agglutination and von Willebrand factor binding), hirudin 1 mg/kg IV, or a combination of both agents before limb 2 graft implantation. GPIb inhibition, thrombin inhibition, and the combination resulted in a significant prolongation of AMG patency (P < .005). Whereas thrombin inhibition with hirudin prolonged AMG patency similar to that observed with GPIb inhibition, the combination of GPIb and thrombin inhibition provided the overall longest prolongation of AMG patency. These results indicate that both platelet membrane GPIb and thrombin play a role in AMG thrombosis.     

Effect of phosphopyridoxylation on thrombin interaction with platelet glycoprotein Ib.

The purpose of this study was to determine the effect of chemical modification of lysyl residues on thrombin interaction with platelet membrane proteins. Modification of lysyl residues by pyridoxal-5'-phosphate affected two different sites on thrombin and resulted in a greatly decreased binding to platelets. Using a crosslinking bifunctional reagent [bis(sulphosuccinimidyl) suberate (BS3)], we show that modified thrombin retained the ability to form high molecular mass (greater than or equal to 400 kDa) complexes with yet unidentified platelet proteins and to bind to platelet protease nexin I, but had lost the ability to bind to platelet glycoprotein Ib (GPIb). As previously reported by others, heparin protected one of the two sites from phosphopyridoxylation. In contrast modified thrombin, heparin-protected modified thrombin retained the ability to bind to GPIb, indicating that the lysyl residue(s) protected by heparin from the modification are essential for GPIb binding. While unprotected modified thrombin failed to bind hirudin, heparin-protected modified thrombin retained its ability to bind the carboxy-terminal hirudin peptide H54-65. Tritium-labelling of the modified lysyl residues and degradation of modified thrombins by CNBr or trypsin confirmed that the lysyl residue(s) protected by heparin and essential for GPIb binding are located in the thrombin binding domain for the carboxyl-terminal tail of hirudin, within the sequence 18-73 of the thrombin B chain.     

Thrombin interaction with platelet glycoprotein Ib: effect of glycocalicin on thrombin specificity.

We describe here the alteration of thrombin specificity induced by its interaction with glycocalicin. Glycocalicin is the external part of platelet glycoprotein Ib alpha (GPIb alpha) and contains binding sites for von Willebrand factor and thrombin. Taking advantage of its solubility, we have used glycocalicin in competition assays on various thrombin activities. Glycocalicin did not inhibit chromogenic substrate hydrolysis nor diisopropylfluorophosphate iPr2 (PF) incorporation, indicating that thrombin binding to GPIb does not alter access to or the conformation of the thrombin catalytic site. Glycocalicin competitively inhibited thrombin binding to fibrin (Ki = 0.1 mumol/L) and blocked fibrinogen clotting activity of thrombin. Glycocalicin also inhibited thrombin binding to thrombomodulin in a competitive manner (Ki = 3 to 5 mumol/L), but failed to prevent thrombin interaction with protein C in the absence of thrombomodulin. Previous results have indicated that GPIb binds to thrombin within the anion binding exosite masked by the carboxy-terminal hirudin peptide 54-65. The present results confirm the implication of the anion binding exosite in GPIb recognition, and further indicate that the thrombin binding site for GPIb overlaps with the thrombin binding sites for fibrin and thrombomodulin, whereas it is distinct from the thrombin binding site for protein C. Some of the structural requirements for thrombin binding to GPIb appear to be very similar to those reported for binding to its platelet receptor. However, thrombin-GPIb interaction does not appear to compete with receptor hydrolysis but rather increases the sensitivity and the rate of platelet responses elicited by the receptor.     

Role of the glycoprotein IIb-IIIa complex in plasma membrane Ca2+ transport: a comparison of results obtained with platelets and human erythroleukemia cells

Several studies have suggested that the glycoprotein (GP) IIb-IIIa complex, which serves as the platelet fibrinogen receptor, also plays a role in the regulation of Ca2+ influx across the platelet plasma membrane. To examine this possibility further, we have compared Ca2+ transport in platelets and human erythroleukemia (HEL) cells, a megakaryoblastic cell line which synthesizes GP IIb-IIIa complexes that appear to be identical to those found on platelets. As with platelets, the results show the presence in unstimulated HEL cells of a rapidly exchangeable cytosolic Ca2+ pool that is in equilibrium with an intracellular sequestered Ca2+ pool and with extracellular Ca2+. Allowing for differences in cell size, the rate constants for Ca2+ exchange in HEL cells were similar to those in platelets. As in platelets, thrombin caused an increase in cytosolic Ca2+ that was due partly to enhanced Ca2+ influx and partly to the mobilization of internal Ca2+ stores. Incubation of the HEL cells with EDTA at 37 degrees C irreversibly altered the GP IIb-IIIa complex as evidenced by decreased binding of a complex-specific monoclonal antibody. In platelets this was accompanied by a 40% decrease in the rate of Ca2+ influx. However, in HEL cells there was neither a diminution in Ca2+ influx nor a reduction in the magnitude of the increase in cytosolic Ca2+ caused by thrombin. These results show that the parameters of Ca2+ distribution and movement are similar in HEL cells and platelets and that in HEL cells, as in platelets, the GP IIb-IIIa complex can be altered by removing Ca2+. However, unlike platelets, dissociation of the HEL cell IIb-IIIa complex has no discernible effect on plasma membrane Ca2+ transport. This suggests that earlier observations in platelets correlating changes in the rate of Ca2+ influx with changes in the number of intact IIb-IIIa complexes reflect an indirect, rather than a direct, role of these proteins in Ca2+ transport.     

Deficiency of platelet membrane glycoprotein Ia associated with a decreased platelet adhesion to subendothelium: a defect in platelet spreading

A bleeding disorder with absent collagen-induced platelet aggregation and adhesion has been described in a patient whose platelets failed to express surface glycoprotein Ia. We studied the interaction of her platelets with subendothelium in an annular perfusion chamber and the interaction with purified human collagen type III in a rectangular perfusion system under flow conditions. Platelet adherence was almost completely absent both at low and high shear rates. The few platelets which adhered remained in the contact stage without subsequent spreading and aggregate formation. Addition of a monoclonal antibody, which was directed against the von Willebrand moiety of FVIII-VWF, to the blood, completely abolished platelet adherence at high shear rates and had a partial effect at low shear rates. These data indicate that von Willebrand factor plays a role in the initial attachment (contact stage) of platelets to subendothelium. We conclude that the bleeding disorder and excessively prolonged bleeding time in our patient are caused by a new specific defect of the platelet-vessel wall interaction.     

Cell-lineage antigens of the stem cell-megakaryocyte-platelet lineage are associated with the platelet IIb-IIIa glycoprotein complex

The stem cell-platelet lineage is uniquely defined by platelet cell- lineage antigens. These antigens are present on all stem cells measured by the spleen colony assay and become restricted to the platelet cell lineage as differentiation proceeds. In this study, anti-platelet serum (APS) has been used to identify cells in the bone marrow that express platelet cell-lineage antigens and to identify platelet cell surface molecules expressing these antigens. Anti-platelet IgG extensively absorbed with brain, thymus, and peritoneal cells bound selectively to stem cells, megakaryocyte progenitor cells (Mk-CFC), and megakaryocytes in CBA mouse bone marrow and to blood platelets. No other hemopoietic cell type, tissue, cell line, or tumor cell bound significant amounts of antibody against platelet cell-lineage antigens as determined by ability to absorb the anti-stem cell activity in APS. Studies with lactoperoxidase-labeled platelets showed that two major iodinated proteins of Mr = 114,000 and 138,000 were immunoprecipitated with APS and with antiserum that had been extensively absorbed. These proteins correspond to the platelet IIb-IIIa glycoprotein complex, which is known to express receptors for collagen and fibrinogen, molecules known to influence hemopoietic cell proliferation and tumor cell growth. A panel of six monoclonal antibodies against human IIb-IIIa inhibited spleen colony formation by 17% to 100%, J15 and A5.15 also being cytotoxic for granulocyte-macrophage progenitor cells and Mk-CFC. Other platelet monoclonal antibodies did not inhibit spleen colony formation. Although APS inhibited fibrinogen binding to platelets and platelet aggregation, these activities were greatly reduced with absorbed antiserum. Furthermore, fibrinogen treatment of bone marrow did not block the anti-stem cell activity in APS. Thus the evidence is consistent with expression of platelet cell-lineage antigens on the platelet IIb-IIIa glycoprotein complex at a site removed from the fibrinogen binding site.     

Detection of an epitope specific for the dissociated form of glycoprotein IIIa of platelet membrane glycoprotein IIb-IIIa complex and its expression on the surface of adherent platelets

Summary Glycoproteins (GPs) IIb and IIIa form a Ca²⁺-dependent complex in platelet membrane and change their conformation upon platelet activation and dissociation of the complex. A new anti-GPIIIa monoclonal antibody (mAb). CRC54, is described which could distinguish different conformational states of GPIIIa. This antibody (i) precipitated GPIIb-IIIa from platelet Triton X-100-lysate. (ii) recognized the GPIIIa band in Western blotting of platelet SDS-lysate, and (iii) did not react with platelets from a Glanzmann's thrombasthenia patient lacking GPIIb-IIIa. Immunoblotting of chymotryptic digestion products of purified GPIIb-IIIa has shown that CRC54 epitope is located within residues 1–100 at the N-terminus of GPIIIa. CRC54 bound weakly to platelets in the presence of Ca²⁺ and Mg²⁺, 2.34 ± 0.28 ± 10³ molecules per platelet at saturation. The same level of binding was observed without any divalent cations in the medium. However, binding of CRC54 was increased by several times after treatment of platelets with EDTA, 10.04 ± 0.28 ± 10³ molecules per platelet. Increase of CRC54 binding correlated with the dissociation of GPIIb-IIIa complex which was followed by the decrease of the binding of another mAb, CRC64, directed against complex-specific epitope of GPIIb-IIIa. Binding of CRC54 to platelets was changed neither by platelet activation in suspension with thrombin or ADP nor by the occupancy of GPIIb-IIIa ligand binding site with GRGDSR peptide. However. binding was significantly stimulated by platelet adhesion to polystyrene plastic. As measured using ⁵¹Cr-labelled platelets, binding of ^l25I-CRC54 to adherent platelets in the presence of divalent cations was about 4 times higher than to platelets in suspension, 8.68 ± 0.48 ± 10³ per platelet. This increase was not due to the dissociation of GPIIb-IIIa since complex-specific antibody CRC64 still bound effectively to the surface of adherent platelets. The data obtained indicated that: (1) CRC54 recognized an epitope specific for the dissociated form of GPIIIa: (2) the CRC54-reactive epitope of GPIIIa is also expressed on the surface of adherent platelets.     

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

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)