Characteristics of quinine- and quinidine-induced antibodies specific for platelet glycoproteins IIb and IIIa.

Recent studies have shown that antibodies characteristic of quinine- and quinidine-induced thrombocytopenia sometimes recognize the platelet membrane glycoprotein (GP) complex IIb/IIIa in addition to their well known target, GPIb/IX. We have investigated the frequency with which drug-induced antibodies bind to GPIIb/IIIa and the nature of their target epitopes. In studies of sera from 13 patients sensitive to quinidine or quinine, we found that 10 contained IgG antibodies specific for both GPIb/IX and GPIIb/IIIa, two reacted with GPIb/IX alone, and one reacted with GPIIb/IIIa alone. In all cases, the presence of drug was required for binding of IgG to target GPs. By immunoabsorption, we found that each of five polyspecific sera contained at least two different antibodies, one reactive with GPb/IX and the other with GPIIb/IIIa. Further studies with eight drug-dependent antibodies (DDAb) specific for GPIIb/IIIa showed that three recognized the GPIIb/IIIa complex only, one recognized GPIIb alone, and three recognized GPIIIa alone. The eighth serum appeared to bind to both GPIIIa alone and to an epitope determined by the GPIIb/IIIa complex. The three antibodies specific for GPIIIa alone also reacted with GPIIIa deglycosylated with endo-H, and with the major (61 Kd) fragment obtained by chymotryptic digestion of GPIIIa but failed to react with reduced GPIIIa. These findings demonstrate that, in drug-induced, immunologic thrombocytopenia, the anti-platelet immune response is typically directed against epitopes on both GPIb/IX and GPIIb/IIIa. The three DDAb we studied that were specific for GPIIIa alone recognize epitopes resistant to chymotrypsin and endo-H treatment that are dependent on intrachain disulfide bonding.     

Downregulation of the platelet surface glycoprotein Ib-IX complex in whole blood stimulated by thrombin, adenosine diphosphate, or an in vivo wound [see comments]

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.     

Quinine- and quinidine platelet antibodies can react with GPIIb/IIIa

Quinine- and quinidine-dependent antiplatelet antibodies are generally believed to bind to the membrane glycoprotein complex, GPIb/IX. However, we and others have found that some drug-dependent antibodies bind to platelets from patients with the Bernard-Soulier syndrome which lack these glycoproteins. We therefore studied the reactions of a group of these antibodies with normal and Bernard-Soulier platelets and their membrane proteins. As indicated by rosette formation of the sensitized platelets around protein A-Sepharose beads, two quinine- and two quinidine-dependent antibodies reacted with both normal and Bernard-Soulier syndrome platelets at a high (300 microM) concentration of drug. At a pharmacologic drug concentration (10 microM), all four antibodies reacted with normal platelets but only the two quinine-induced antibodies reacted with Bernard-Soulier platelets. Immunoprecipitation studies with solubilized, tritium-labelled normal platelets, at both high and low drug concentrations, showed that each of the four antibodies precipitated proteins corresponding to GPIb and GPIX. Fainter bands corresponding to glycoproteins IIb and IIIa, which do not label well with tritium, were also detected. With radioiodinated normal platelets, it was found that each of the four antibodies was capable of precipitating GPIIb/IIIa, but only in the presence of drug. The four antibodies also promoted drug-dependent precipitation of GPIIb and GPIIIa from lysates of radioiodinated Bernard-Soulier platelets. The two quinine-dependent antibodies precipitated these glycoproteins at both high and low drug concentrations, while the quinidine-dependent antibodies reacted much more strongly at the higher drug concentration. Precipitation of GPIb/IX was not observed with BSS platelets. Absorption of a quinine-induced antibody with Bernard-Soulier platelets in the presence of drug eliminated its ability to precipitate GPIIb and GPIIIa. However, the absorbed antibody retained the ability to precipitate GPIb from solubilized normal platelets. Thus, at least two drug-dependent antibodies were present, one specific for GPIb/IX and the other for GPIIb/IIIa. These findings indicate that glycoproteins IIb and/or IIIa, in addition to the GPIb/IX complex, can serve as targets for drug-dependent antibodies in both intact and detergent-solubilized platelet preparations.     

Rifampicin-dependent antibodies bind a similar or identical epitope to glycoprotein IX-specific quinine-dependent antibodies

The drug-dependent antibody of a patient with rifampicin-induced thrombocytopenia was characterized using the antigen-capture enzyme-linked immunosorbent assay (MAIPA assay), flow cytometry, and immunoprecipitation. The antibody was found to bind glycoprotein (GP) Ib-IX but not GPIIb-IIIa because (1) it immunoprecipitated drug-dependently the former but not the latter glycoprotein complex and (2) the MAIPA assay showed strong rifampicin-dependent antibody binding when anti-GPIb-IX monoclonal antibodies (mAbs) (AK2 and FMC25) but not anti-GPIIb-IIIa mAbs (AP2, SZ21, and SZ22) were used to capture the antigen. The antibody binding site was further localized to the GPIX subunit of the GPIb-IX complex because flow cytometric analysis revealed drug-dependent antibody binding to L cells transfected with human GPIbbeta and GPIX complementary DNA (L betaIX cells) but not with human GPIbalpha and GPIbbeta complementary DNA (L alphabeta cells). Finally, in the MAIPA assay, the rifampicin-dependent antibody almost completely cross-blocked the binding of the anti-GPIX mAb (SZ1) to platelets. Similar cross-blocking of SZ1binding to platelets by the quinine-dependent antibodies was also observed. This finding not only confirms that the epitope of the rifampicin-dependent antibody is on GPIX but it is also identical to or located in close proximity to that of the quinine-dependent antibody and SZ1. Further characterization of the epitopes of these antibodies may have important implications for a general understanding of the mechanism of drug-induced thrombocytopenia. (Blood. 2000;95:1988-1992)     

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)     

Immunoglobulins targeting both GPIIb/IIIa and GPIb/IX in chronic idiopathic thrombocytopenic purpura (ITP): evidence for at least two different IgG antibodies

Antiplatelet antibodies in chronic idiopathic thrombocytopenic purpura (ITP) mainly target glycoprotein (GP) IIb/IIIa and GPIb/IX. Previous studies, employing modern antigen-specific assays, indicate that serum reactive with both GPIIb/IIIa and GPIb/IX is not an uncommon finding in chronic ITP. However, the mechanism behind this dual reactivity remains unclear. We studied sera from 72 patients with chronic ITP using modified GPIIb/IIIa- and GPIb/IX-specific MAIPA assays. Among the 34 positive sera, seven showed strong reactivity against both GPIIb/IIIa and GPIb/IX. These seven dual reactive ITP sera were further analysed by absorption studies. It was found that sera absorbed with immobilized GPIb/IX lost nearly all serum IgG specific for GPIb/IX but fully retained the IgG specific for GPIIb/IIIa. Conversely, sera absorbed with immobilized GPIIb/IIIa retained their reactivity only with GPIb/IX. These findings demonstrate that ITP sera, reactive with both GPIIb/IIIa and GPIb/IX, contain at least two different IgG antibody populations, each reactive with only one of the GP complexes.     

Quinine-induced thrombocytopenia: drug-dependent GPIb/IX antibodies inhibit megakaryocyte and proplatelet production in vitro

The development of immune cytopenias is a well-recognized side effect of many drugs. Quinine- and quinidine-dependent antibodies are classic examples of drug-induced effects that cause severe, life-threatening thrombocytopenia. Whereas the effects of drug-dependent antibodies on platelets have been well documented, their effects on megakaryocyte (Mk) biology are still unclear. We analyzed sera from several quinine-induced thrombocytopenia (QITP) patients on highly pure Mks (98% glycoprotein IIb-positive [GPIIb(+)]; 92% GPIX(+)) derived from human CD34(+) cells cultured with human thrombopoietin. We demonstrate by flow cytometry and confocal microscopy that QITP IgGs bind Mks efficiently in the presence of quinine. Incubation of day-4 Mks with QITP sera or purified IgG resulted in induction of apoptosis, a significant decrease in cell viability, and an increase in cell death. Furthermore, QITP sera preferentially reduced the number of late GPIX(+)/GPIbα(+) Mks and the number of receptors per cell in the surviving population. Ploidy distribution, lobularity, and average cell size of Mks remained unchanged after treatment. In addition, treated Mks showed a marked decrease in their proplatelet production capacity, suggesting that drug-dependent antibodies hinder platelet production. Therefore, QITP antibodies considerably reduce the proplatelet production capabilities of Mks despite undetectable effects on DNA content, morphology, and cell size.     

Receptor patching and capping of platelet membranes induced by monoclonal antibodies

Redistribution of glycoproteins (GP) Ib, glycocalicin, IIb, and IIIa on the surface of human platelets in response to stimulation with corresponding monoclonal antibodies (MoAb) and a polyclonal antiglycocalicin antibody was studied by immunofluorescence, immunoelectron microscopy, and a quantitative radioimmune assay. Immobilization of the antigens by prefixation with formaldehyde showed a uniform distribution over the surface of the platelet. Incubation of unfixed platelets with specific MoAb against various epitopes on GPIIb and/or IIIa resulted in a time-dependent patching, subsequent capping, and after prolonged exposure to the antibody/label complex, internalization of the complex, possibly by endocytosis. In contrast, GPIb could not be shown to cap. From these results we conclude that platelet GPIIb and/or IIIa undergo spatial rearrangement in a manner analogous to that observed in lymphocytes, whereas GPIb does not. Since both GPIb and GPIIb and/or IIIa seem to be transmembraneous GP associated with the cytoskeleton, a special, though unidentified, role of GPIIb/IIIa in the induction of lateral membrane mobility is postulated.     

Glycoprotein Ib/IX complex is the target in rifampicin-induced immune thrombocytopenia

Thrombocytopenia is a major adverse effect of several drug treatments. Rifampicin has been recognized as a cause of immune thrombocytopenia during intermittent high-dose therapy. We characterized the antibody of a patient who presented with purpura and thrombocytopenia during treatment of tuberculosis with rifampicin. Drug-dependent binding of the antibody to platelets was demonstrated by flow cytometry. In a glycoprotein-specific immunoassay, the binding epitope of the IgG antibody was found in the glycoprotein Ib/IX complex, using four different monoclonal antibodies (mAbs) against various epitopes on the GPIb/IX complex, as well as mAbs against GPIIb/IIIa, GPIa/IIa and GPIV. By immunoprecipitation of biotin-labelled platelets, reactivity of the antibody with GPIb/IX was found only in the presence of the drug. These findings clearly demonstrate that rifampicin induces the formation of drug-dependent antibodies capable of causing thrombocytopenia. The binding site of the rifampicin-dependent antibody, located in the GPIb/IX complex, seems to be a favoured target for antibodies induced by different drugs.     

Surface expression of glycoprotein ib alpha is dependent on glycoprotein ib beta: evidence from a novel mutation causing Bernard-Soulier syndrome

Bernard-Soulier syndrome is a rare bleeding disorder caused by a quantitative or qualitative defect in the platelet glycoprotein (GP) Ib-IX-V complex. The complex, which serves as a platelet receptor for von Willebrand factor, is composed of 4 subunits: GPIb alpha, GPIb beta, GPIX, and GPV. We here describe the molecular basis of a novel form of Bernard-Soulier syndrome in a patient in whom the components of the GPIb-IX-V complex were undetectable on the platelet surface. Although confocal imaging confirmed that GPIb alpha was not present on the platelet surface, GPIb alpha was readily detectable in the patient's platelets. Moreover, immunoprecipitation of plasma with specific monoclonal antibodies identified circulating, soluble GPIb alpha. DNA-sequence analysis revealed normal sequences for GPIb alpha and GPIX. There was a G to A substitution at position 159 of the gene encoding GPIb beta, resulting in a premature termination of translation at amino acid 21. Studies of transient coexpression of this mutant, W21stop-GPIb beta, together with wild-type GPIbalpha and GPIX, demonstrated a failure of GPIX expression on the surface of HEK 293T cells. Similar results were obtained with Chinese hamster ovary alpha IX cells, a stable cell line expressing GPIbalpha that retains the capacity to re-express GPIX. Thus, we found that GPIbbeta affects the surface expression of the GPIb-IX complex by failing to support the insertion of GPIb alpha and GPIX into the platelet membrane. (Blood. 2000;96:532-539)     

Platelet endothelial cell adhesion molecule-1 (PECAM-1) is a target glycoprotein in drug-induced thrombocytopenia

Drug-induced immune thrombocytopenia (DITP) is a serious complication of drug treatment. Previous studies demonstrated that most drug-dependent antibodies (DDAbs) react with the platelet membrane glycoprotein (GP) complexes IIb/IIIa and Ib/IX/V. We analyzed the sera from 5 patients who presented with DITP after intake of carbimazole. Notably, thrombocytopenia induced by carbimazole was relatively mild in comparison to patients with DITP induced by quinidine. The sera reacted with platelets in an immunoassay on addition of the drug. In immunoprecipitation experiments with biotin-labeled platelets and endothelial cells, reactivity with the platelet endothelial cell adhesion molecule-1 (PECAM-1, CD31) could be demonstrated, whereas neither GPIIb/IIIa nor GPIb/IX was precipitated in the presence of the drug. These results could be confirmed by GP-specific immunoassay (MAIPA) using monoclonal antibodies (mabs) against PECAM-1. In addition, the binding of DDAbs could be abolished by preincubation with soluble recombinant PECAM-1. Carbimazole-dependent antibodies showed similar reactivity with platelets carrying the Leu(125) and Val(125) PECAM-1 isoforms, indicating that this polymorphic structure, which is located in the first extracellular domain, is not responsible for the epitope formation. Binding studies with biotin-labeled mutants of PECAM-1 and analysis of sera with mabs against different epitopes on PECAM-1 in MAIPA assay suggested that carbimazole-dependent antibodies prominently bound to the second immunoglobulin homology domain of the molecule. Analysis of 20 sera from patients with quinidine-induced thrombocytopenia by MAIPA assay revealed evidence that DDAbs against PECAM-1 are involved in addition to anti-GPIb/IX and anti-GPIIb/IIIa. We conclude that PECAM-1 is an important target GP in DITP. (Blood. 2000;96:1409-1414)     

Patients with quinine-induced immune thrombocytopenia have both "drug-dependent" and "drug-specific" antibodies

Immune thrombocytopenia induced by quinine and many other drugs is caused by antibodies that bind to platelet membrane glycoproteins (GPs) only when the sensitizing drug is present in soluble form. In this disorder, drug promotes antibody binding to its target without linking covalently to either of the reacting macro-molecules by a mechanism that has not yet been defined. How drug provides the stimulus for production of such antibodies is also unknown. We studied 7 patients who experienced severe thrombocytopenia after ingestion of quinine. As expected, drug-dependent, platelet-reactive antibodies specific for GPIIb/IIIa or GPIb/IX were identified in each case. Unexpectedly, each of 6 patients with GPIIb/IIIa-specific antibodies was found to have a second antibody specific for drug alone that was not platelet reactive. Despite recognizing different targets, the 2 types of antibody were identical in requiring quinine or desmethoxy-quinine (cinchonidine) for reactivity and in failing to react with other structural analogues of quinine. On the basis of these findings and previous observations, a model is proposed to explain drug-dependent binding of antibodies to cellular targets. In addition to having implications for pathogenesis, drug-specific antibodies may provide a surrogate measure of drug sensitivity in patients with drug-induced immune cytopenia.     

Increased platelet sensitivity to ristocetin is predicted by the binding characteristics of a GPIb/IX determinant

Platelets from patients with platelet-type von Willebrand disease (vWD) were used as immunogens for the production of murine monoclonal antibodies (MoAbs). One such MoAb, C-34, inhibited ristocetin-induced aggregation of patient or normal platelets, but not aggregation induced by other aggregating agents. As demonstrated by crossed-immunoelectrophoresis, C-34 recognized an epitope within the GPIb/IX complex. In indirect immunofluorescence studies on fresh platelets, the ratio of any of four different anti-GPIb MoAbs to one another was near unity (0.88-1.14) both for normals and for patients. In contrast, the ratio of the binding of C-34 to such a MoAb (AP-1) was 0.31 +/- 0.02 (means +/- SE) for normal platelets and significantly increased to 0.54 +/- 0.01 for patient platelets (P less than 0.001). In NP-40 lysates of 3H-labelled platelets, saturating concentrations of C-34 produced much fainter bands than did AS-2 or other anti-GPIb MoAbs in the GPIb and GPIX regions. In contrast to the other anti-GPIb MoAbs, C-34 did not bind to the purified 125I-labelled glycocalicin fragment of GPIb, to the glycocalicin derivative identified by crossed-immunoelectrophoresis, or to the amino-terminal approximately 40 kDa portion of GPIb alpha cleaved from 3H-labelled platelets by trypsin. C-34 appears to be the first MoAb that is quantitatively informative in identifying the abnormal platelets in platelet-type vWD. The observed differences between the patient and normal platelets may reflect an abnormality in the primary structure of the GPIb/IX complex. Alternatively, patient platelets may have an abnormality of other structures near this region that impose less of a steric hindrance upon binding of antibody to the C-34 epitope.     

Drug-induced immune thrombocytopenia: Mapping of the drug binding site to the membrane-proximal region of platelet GPIX

Drug-induced Immune thrombocytopenia (DIT) is a common complication of several medications, including commonly used antibiotics. The most widely studied DIT is caused by quinine. In DIT, antibodies predominantly bind to the platelet membrane glycoprotein (GP) IX in a drug-dependent fashion resulting in increased platelet clearance. Binding of the sensitizing drug, such as quinine, to GPIX has been proposed but is yet to be established. This work demonstrates that quinine is retained specifically by human GPIX. Quinine binding was first analyzed in wild-type mouse platelets and in transgenic mouse platelet expressing human GPIX using high performance liquid chromatography. Binding of quinine to GPIX was then measured in Chinese hamster ovary (CHO) cells expressing a combination of wild type, human or mouse, three human/mouse chimeric constructs and six mutant GPIX proteins. Quinine was retained by human GPIX. No detectable absorption was observed with mouse GPIX or human GPIbα. The quinine binding site was mapped to residues 110–115 of human GPIX suggesting that quinine interacts with specific residues of the GP. These findings provide further insights into the molecular mechanisms of DIT.     

Quaternary organization of GPIb-IX complex and insights into Bernard-Soulier syndrome revealed by the structures of GPIbβ and a GPIbβ/GPIX chimera

Platelet GPIb-IX receptor complex has 3 subunits GPIbα, GPIbβ, and GPIX, which assemble with a ratio of 1:2:1. Dysfunction in surface expression of the complex leads to Bernard-Soulier syndrome. We have crystallized the GPIbβ ectodomain (GPIbβ(E)) and determined the structure to show a single leucine-rich repeat with N- and C-terminal disulphide-bonded capping regions. The structure of a chimera of GPIbβ(E) and 3 loops (a,b,c) taken from the GPIX ectodomain sequence was also determined. The chimera (GPIbβ(Eabc)), but not GPIbβ(E), forms a tetramer in the crystal, showing a quaternary interface between GPIbβ and GPIX. Central to this interface is residue Tyr106 from GPIbβ, which inserts into a pocket generated by 2 loops (b,c) from GPIX. Mutagenesis studies confirmed this interface as a valid representation of interactions between GPIbβ and GPIX in the full-length complex. Eight GPIbβ missense mutations identified from patients with Bernard-Soulier syndrome were examined for changes to GPIb-IX complex surface expression. Two mutations, A108P and P74R, were found to maintain normal secretion/folding of GPIbβ(E) but were unable to support GPIX surface expression. The close structural proximity of these mutations to Tyr106 and the GPIbβ(E) interface with GPIX indicates they disrupt the quaternary organization of the GPIb-IX complex.     

The cysteine knot of platelet glycoprotein Ib beta (GPIb beta) is critical for the interaction of GPIb beta with GPIX

The glycoprotein Ib (GPIb) complex is composed of GPIb alpha covalently attached to GPIb beta and noncovalently complexed with GPIX and GPV. Patients with Bernard-Soulier syndrome demonstrate that mutations in either GPIb beta or GPIX result in an absence of platelet GPIb alpha. This occurs through the interaction of GPIX with GPIb beta. The precise sites of interaction of GPIb beta with GPIX are not known. To characterize the interaction of GPIb beta and GPIX, we developed an anti-GPIb beta monoclonal antibody MBC 257.4, whose epitope was in the N-terminal region of GPIb beta. N-terminal truncations of GPIb beta were expressed in mammalian cells. N-terminal truncations of GPIb beta, missing the first 14, 26, or 31 amino acids, were surface-expressed but did not enable coexpressed GPIX to be surface expressed, suggesting that the site of interaction with GPIX was modified by these deletions. GPIb beta and GPIX chimeras corresponding to predicted boundaries were used to define the sites of interaction of GPIb beta with GPIX. Replacing the N-terminal disulfide loops of GPIb beta (amino acids 1-14) with the corresponding disulfide loops of GPIX (amino acids 1-22) resulted in surface expression of coexpressed wildtype GPIX. However, when the N terminus of GPIb beta was replaced to residue 32 with the N terminus of GPIX (amino acids 1-36), GPIX did not surface express with this chimera. These results suggest that the cysteine knot region of GPIb beta in the N terminus is critical for the conformation of GPIb beta that interacts with GPIX and further suggests that a critical interaction of GPIb beta with GPIX involve residues 15 through 32 of GPIb beta     

Human anti-PlEl antibody recognizes epitopes associated with the alpha subunit of platelet glycoprotein Ib

Together, a platelet-reactive antibody in the serum of a polytransfused patient (proband) and a platelet-reactive antibody in the serum of a mother of an infant with neonatal thrombocytopenia have served to establish the diallelic, platelet-specific alloantigen system, PlE. We now provide evidence that the platelet-specific antibody in the serum of the proband, anti-PlE1, recognizes epitopes associated with the alpha subunit of glycoprotein (GP) Ib. By 51Cr release, platelets from two of three patients with the Bernard-Soulier syndrome (BSS) responded sub-normally to anti-PlE1, and the apparently normal response of platelets from the last BSS patient was attributable to anti-HLA-A2 antibodies in the proband serum. These results suggested that the PlE1 antigen is associated with the GPIb complex (glycoproteins Ib kX) known to be absent from BSS platelets. This possibility was confirmed by ELISA using the purified GPIb complex or glycocalicin, the N-terminal fragment of GPIb alpha produced by proteolysis with endogenous platelet calpain, as solid-phase antigen. Anti-PlE1 antibody bound specifically to both the GPIb complex and glycocalicin. 3H-labelled platelet membrane glycoproteins with apparent molecular weights of 130k, 25k, and 21k (under reduced conditions) corresponding to GPIb alpha, GPIb beta, and GPIX were immunoprecipitated by anti-PlE1 plasma. Finally, at a titre of 1:16, anti-PlEl completely inhibited ristocetin-induced platelet agglutination, a property of platelets mediated by GPIb.     

Identification of platelet glycoprotein IIb/IIIa as the major binding site for released platelet-von Willebrand factor [published erratum appears in Blood 1987 Jun;69(6):1789]

We studied the effects(s) of two monoclonal antibodies, 6D1 and 10E5 (directed against platelet glycoprotein Ib [GPIb] and the GPIIb/IIIa complex, respectively), and purified human plasma fibrinogen on the binding of released platelet-von Willebrand factor (vWf) to the platelet surface. Neither of the monoclonal antibodies nor fibrinogen had any effect on the amount of platelet-vWf expressed on unstimulated platelets or on the amount expressed on platelets stimulated in the absence of extracellular Ca++. However, the antibody directed against GPIIb/IIIa inhibited 72% of the thrombin-induced increase in the platelet-vWf bound to the platelet surface when platelets were stimulated in the presence of 5 mmol/L Ca++. The antibody against GPIb did not inhibit the surface expression of platelet-vWf on stimulated platelets in the presence of Ca++. Purified normal human fibrinogen inhibited the surface binding of platelet-vWf to thrombin-stimulated platelets to a degree similar to that observed with the monoclonal antibody directed against the GPIIb/IIIa complex. These data indicate that platelet-vWf released from platelets binds primarily to the GPIIb/IIIa complex at or near the plasma fibrinogen binding site.     

Antibodies against platelet GPIb/IX,GPIIb/IIIa,and other platelet antigens in chronic idiopathic thrombocytopenic purpura

Abstract: Antibodies involved in the pathogenesis of chronic idiopathic thrombocytopenic purpura (ITP) react most frequently with platelet glycoprotein (GP) Ib/IX and GPIIb/IIIa. However, uncertainty as to the specificity, frequency, and clinical significance of such antibodies still remains. By using a modified antigen-capture ELISA (MACE), an immunoprecipitation assay, and an immunoblot assay, sera from 60 patients with chronic ITP were analyzed. GP-specific antibodies were found in 50% (30/60) of the patients, with 14 patients having antibodies directed solely to GPIIb/IIIa, 8 holding antibodies specific only for GPIb/IX, and 8 possessing antibodies against both antigens. Serum antibodies were more frequently (p<0.01) detected in either active and/or non-splenectomized ITP patients. Moreover, in patients displaying antibodies against GPIb/IX, significantly (p<0.05) lower platelet counts were observed. Using the immunoblot assay, antibodies specific for a 30 kD platelet antigen were detected in 12 of 60 patients. This antigen could not be immunoprecipitated from surface labelled platelet membranes, indicating an intracellular location. We conclude that in chronic ITP, (1) the frequency of anti-GPIIb/IIIa antibodies is close to that of anti-GPIb/IX antibodies, (2) anti-GP antibodies are more likely to be detected in patients with an active disease status and, (3) a 30 kD internal platelet protein is another frequent antigen.     

Evidence for a light chain restriction of glycoprotein Ib/IX and Ilb/IIIa reactive antibodies in chronic idiopathic thrombocytopenic purpura (ITP)

To address the assumption of clonally restricted antibodies in immune thrombocytopenias we studied sera from 19 patients with chronic ITP known to possess antibodies reactive with glycoprotein (GP) Ib/IX and/or GPIIb/IIIa. These sera were re-analysed using the standard monoclonal antibody immobilization of platelet antigens (MAIPA) assay and 16 patients exhibited IgG antibodies reactive with GPIIb/IIIa; seven patients showed also a reactivity with GPIb/IX. Employing a light-chain-specific MAIPA assay, 75% (12/16) of these sera displayed GPHb/ Ilia-specific antibodies that were light chain restricted; only 13% (2/16) of the GPIIb/IHa reactive sera showed a mixed kappa and lambda phenotype. A light-chain-restricted phenotype was also seen for the GPIb/IX reactive antibodies. To further substantiate these findings, the MAIPA assay was modified in order to avoid interference from human anti-mouse antibodies. A high frequency of light-chain restricted platelet antibodies was also found using the modified MAIPA technique. These results support the hypothesis of a clonal B-cell expansion in immune thrombocytopenias, producing antibodies with a restricted idiotype repertoire and reacting with a limited number of epitopes.