Antibody-mediated platelet destruction by quinine, quinidine, and their metabolites

Metabolites of quinine and quinidine, along with the parent compounds, were investigated for their ability to promote complement-mediated platelet destruction when combined with drug-dependent platelet antibodies from five patients with quinine- and quinidine-induced thrombocytopenia. In all, eight metabolites and four closely related structural analogues were studied. These included the desmethyl, 2'-oxo, 10,11-dihydroxy, N-oxide, N'-oxide, and diN,N'-oxide derivatives. When we used the cytotoxic chromium 51 release assay, the parent compounds were typically from 10 to greater than 300 times more effective than the corresponding metabolites and structural analogues in promoting antibody-mediated platelet lysis. Reaction patterns varied significantly among all antibodies and compounds studied, strengthening previous evidence that drug-dependent platelet antibodies are extremely heterogeneous in their reactions with platelets. Although most of the metabolites were much less potent than the parent compounds in promoting antibody-mediated platelet lysis, one quinidine-induced antibody was significantly inhibited in its quinidine-mediated lytic activity by the addition of desmethylquinidine, an essentially nonreactive metabolite with this particular antibody. These findings support the hypothesis that the native structures of quinine and quinidine are sufficient to provoke drug-dependent antibody formation and subsequent platelet destruction independently of their metabolites. They also suggest a possible protective role for some of these metabolites in certain individuals who are susceptible to this allergic drug reaction.     

Heparin-induced thrombocytopenia: an autoimmune disorder regulated through dynamic autoantigen assembly/disassembly

Heparin‐induced thrombocytopenia (HIT) is the most common drug‐induced, antibody‐mediated cause of thrombocytopenia and thrombosis. HIT is caused by IgG antibodies that bind to epitopes on platelet factor 4 (PF4) released from activated platelets that develop when it forms complexes with heparin. Anti‐PF4/antibodies develop in over 50% of patients undergoing surgery involving cardiopulmonary bypass (CPB), an incidence 20‐fold higher than HIT. Why might this occur? Binding of HIT IgG occurs only over a narrow molar ratio of reactants, being optimal at 1 mol PF4 tetramer to 1 mol unfractionated heparin (UFH). At these ratios, PF4 and UFH form ultralarge (>670 kD) complexes that bind multiple IgG molecules/complex, are highly antigenic, and promote platelet activation. Low molecular weight heparin (LMWH), which is less antigenic, forms ultralarge complexes less efficiently and largely at supratherapeutic concentrations. In transgenic mice that vary in expression of human PF4 on their platelets, antigenic complexes form between PF4 and endogenous chondroitin sulfate. Binding of HIT IgG to platelets and induction of thrombocytopenia in vivo is proportional to PF4 expression. Heparin prolongs the duration and exacerbates the severity of the thrombocytopenia. High doses of heparin, as used in CPB, or protamine, which competes with PF4 for heparin, disrupts antigen formation and prevents thrombocytopenia induced by HIT antibody. These studies may help explain the disparity between the incidence of antibody formation and clinical disease and may help identify patients at risk for HIT (high platelet PF4). They also demonstrate that this autoimmune disease can be modulated at the level of autoantigen formation and point to rational means to intervene proximal to thrombin generation. J. Clin. Apheresis. 22:, 2007 © 2007 Wiley‐Liss, Inc.     

Fab-mediated binding of drug-dependent antibodies to platelets in quinidine- and quinine-induced thrombocytopenia

Platelets coated with quinine- or quinidine-induced antibodies form rosettes around protein A-Sepharose beads and normal platelets form rosettes about protein A-Sepharose beads coated with these antibodies. These reactions occurred only in the presence of sensitizing drug. Platelets also formed rosettes about protein A-Sepharose beads coated with an anti-PIA1 antibody, but drug was not required. Formation of rosettes between antibody-coated platelets and protein A-Sepharose was inhibited by F(ab')2 fragments of goat antibody specific for the Fc portion of human IgG, while rosette formation between antibody-coated protein A-Sepharose and platelets was inhibited by F(ab')2 fragments directed against the F(ab')2 portion of the IgG molecule. Since binding of IgG to protein A is known to occur via the Fc region, these findings suggest that binding of drug-induced antibodies to platelets occurs at the Fab domains of the IgG molecule.     

Antibodies from patients with heparin-induced thrombocytopenia/thrombosis are specific for platelet factor 4 complexed with heparin or bound to endothelial cells.

Heparin-induced thrombocytopenia/thrombosis (HITP) is thought to be mediated by immunoglobulins that activate platelets in the presence of pharmacologic concentrations of heparin, but the molecular basis for this relatively common and often serious complication of heparin therapy has not been established. We found that plasma from each of 12 patients with HITP contained high titer (> or = 1:200) antibodies that reacted with immobilized complexes of heparin and platelet factor 4 (PF4), a heparin-binding protein contained in platelet alpha-granules. Recombinant human PF4 behaved similarly to PF4 isolated from platelets in this assay system. Complexes formed at an apparent heparin/PF4 molecular ratio of approximately 1:2 (fresh heparin) and approximately 1:12 (outdated heparin) were most effective in binding antibody. Immune complexes consisting of PF4, heparin, and antibody reacted with resting platelets; this interaction was inhibited by a monoclonal antibody specific for the Fc gamma RII receptor and by excess heparin. Human umbilical vein endothelial cells, known to express heparin-like glycosaminoglycan molecules on their surface, were recognized by antibody in the presence of PF4 alone; this reaction was inhibited by excess heparin, but not by anti-Fc gamma RII. Antibodies reactive with heparin/PF4 were not found in normal plasma, but IgG and IgM antibodies were detected at dilutions of 1:10 (IgG) and 1:50 (IgM) in 3 of 50 patients (6%) with other types of immune thrombocytopenia. These findings indicate that antibodies associated with HITP react with PF4 complexed with heparin in solution or with glycosaminoglycan molecules on the surface of endothelial cells and provide the basis for a new hypothesis to explain the development of thrombocytopenia with thrombosis or disseminated intravascular coagulation in patients sensitive to heparin.     

Determinants of donor platelet variability when testing for heparin-induced thrombocytopenia.

Heparin-induced thrombocytopenia is a common immune-mediated drug reaction that can be complicated by life-threatening arterial thrombosis. The diagnosis can be confirmed by demonstrating heparin-dependent release of radiolabeled serotonin from washed normal platelets in the presence of patient serum. However, certain serum samples from these patients produce 14C-serotonin release from some but not other normal donor platelets. We investigated this problem of donor platelet variability by studying the reactivities of 10 serum samples from patients with heparin-induced thrombocytopenia with platelets from 10 normal donors (100 serum and platelet combinations). We observed a marked variability in reactivity for patient serum and platelets from normal donors; this initially appeared random. However, closer examination indicated that the reactivities varied hierarchically. Because heparin-induced thrombocytopenia is caused by binding of heparin-dependent IgG to platelet Fc receptors, we examined whether platelet Fc receptor number or function explained the variability in platelet reactivity. We observed that platelet Fc receptor function, as measured by platelet release associated with heat-aggregated IgG, was highly correlated with platelet reactivity to heparin-induced thrombocytopenia serum samples. No significant correlation, however, was found between Fc receptor number and platelet response. Reaction of murine monoclonal antibodies that activate human platelets by means of the platelet Fc receptors was not predictive of platelet reactivity to heparin-induced thrombocytopenia serum.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heparin-associated thrombocytopenia: observations on the mechanism of platelet aggregation

We investigated the mechanism of heparin-mediated platelet aggregation in 11 patients with heparin-associated thrombocytopenia. Severe thrombocytopenia (16,000 to 66,000 platelets/microliters) developed in each patient during heparin therapy, and platelet aggregation occurred in vitro when heparin was added to mixtures of patient plasma and normal platelet-rich plasma. In 10 patients, heparin-initiated platelet aggregation was inhibited by preincubation of mixtures of normal platelet-rich plasma and heparin-associated thrombocytopenia plasma with monoclonal antiglycoprotein Ib antibodies 6D1 or LJ-Ib1. Both antibodies are directed against the von Willebrand factor binding site on glycoprotein Ib and inhibit only ristocetin-induced platelet agglutination. Purified immunoglobulin G (IgG) from patients with heparin-associated thrombocytopenia also supported heparin-induced aggregation, but equivalent amounts of antigen-binding fragments [F(ab')2] did not. We also found that F(ab')2 of LJ-Lb1 did not inhibit heparin-induced platelet aggregation but retained inhibitory activity against ristocetin-induced platelet agglutination. The monoclonal antibody 3G6, directed against the alpha-chain of glycoprotein Ib but not inhibitory of ristocetin-induced platelet agglutination, had no effect on heparin-induced platelet aggregation. Antibodies to von Willebrand factor that inhibit ristocetin-induced platelet agglutination did not inhibit heparin-mediated platelet aggregation, but antibodies to glycoprotein IIb-IIIa blocked aggregation. These data suggest that platelet aggregation in heparin-associated thrombocytopenia may be initiated by an interaction between patient IgG, heparin, and the platelet surface. Platelet activation appears to be mediated by a platelet surface crystallizable fragment (Fc) receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of quinine- and quinidine-dependent drug antibodies to platelets is mediated by the Fab domain of the immunoglobulin G and is not Fc dependent.

The antibody domain controlling reactions between platelet membranes and drug-dependent (dd) antibodies from patients with thrombocytopenia induced by cinchona alkaloids was studied using F(ab')2, Fab, and Fc fragments made from purified dd-IgG. By direct binding radioimmunoassay (RIA) measurements, 20,000 to 50,000 antibody molecules bound per platelet equivalent of purified platelet membranes at apparent saturation with three different antibodies. F(ab')2 and Fab fragments bound to platelet membranes drug dependently but Fc fragments did not. The ability of dd-IgG fragments to compete with intact IgG was quantitatively measured by RIA and by complement fixation. F(ab')2 and Fab competed with intact IgG at an 8:1 and greater than 50:1 molar ratio, respectively, in RIA, and at a 1.6-3:1 and 44-75:1 ratio, respectively, by complement fixation assays. Fc did not compete with IgG in either assay. We conclude that the Fab domain supports attachment of dd antibody to the platelet surface.     

Immunoreactions involving platelets. III. Quantitative aspects of platelet agglutination,inhibition of clot retraction,and other reactions caused by the antibody of quinidine purpura

Quantitative aspects of platelet agglutination and inhibition of clot retraction by the antibody of quinidine purpura were described. The reactions appeared to depend on formation of types of antibody-quinidine-platelet complexes which could fix complement but complement was not necessary for these reactions. Complement fixation was at least 10 times more sensitive than platelet agglutination or inhibition of clot retraction for measurement and detection of antibody activity. Although it has been considered that antibodies of drug purpura act as platelet lysins in the presence of complement and that direct lysis of platelets accounts for development of thrombocytopenia in drug purpura, the present study suggests that attachment of antibody produces a change in platelets which is manifested in vitro only by increased susceptibility to non-specific factors which can alter the stability of platelets in the absence of antibody. The attachment of antibody to platelets in vivo may only indirectly affect platelet survival. In contrast to human platelets, dog, rabbit, and guinea pig platelets, and normal or trypsin-treated human red cells did not agglutinate, fix complement, or adsorb antibody; and intact human endothelial cells did not fix complement or adsorb antibody. Rhesus monkey platelets were not agglutinated by the antibody but did adsorb antibody and fix complement although their activity in these reactions differed quantitatively from that of human platelets. Cinchonine could be substituted for quinidine in agglutination and inhibition of clot retraction reactions but quinine and cinchonidine could not. Attempts to cause passive anaphylaxis in guinea pigs with the antibody of quinidine purpura were not successful.     

Platelet FcγRIIA HIS131ARG polymorphism and platelet function: antibodies to platelet-bound fibrinogen induce platelet activation

Summary.  The His131Arg polymorphism of platelet FcγRIIA affects the binding affinity of certain IgG subclasses. The Arg131 allele has been associated with (auto)immune thrombocytopenia and heparin-induced thrombocytopenia in some studies. Because FcγRIIA can transmit platelet activation signals, we studied platelet responsiveness from 73 healthy donors to determine if this polymorphism modulated platelet function. Platelet function was studied by agonist and shear-induced activation, and standard aggregation. FcγRIIA was genotyped by allele-specific PCR. Compared with His131, the Arg131 allele was associated with significantly greater binding of activation-dependent antibodies. This effect was most prominent for the receptor-induced binding site (RIBS) antibodies F26 ( P  < 0.0001) and RIBS1 ( P  = 0.0057), and the ligand-induced binding site antibody LIBS1 ( P  = 0.0367). Unexpectedly, Arg131-positive platelets did not show greater fibrinogen binding, platelet aggregation or shear-induced platelet activation. We considered whether enhanced Fc binding and FcγRIIA cross-linking were responsible for those discrepancies. The increased binding of the two RIBS antibodies to the Arg131 isoform was abolished by blocking FcγRIIA, and the FcγRIIA genotype effect on F26 IgG binding was lost when F26 F(ab')₂ fragments were used. Furthermore, intact F26 and RIBS1 IgG directly and specifically induced P-selectin expression, and this effect was greatest in Arg131-positive platelets. We concluded that (a) the His131Arg polymorphism of FcγRIIA does not affect intrinsic platelet reactivity; (b) RIBS antibodies are able to cross-link FcγRIIA and activate platelets, and this activation has a modest effect on Arg131 platelets; and (c) flow cytometric based platelet assays may need to compensate for this FcγRIIA His131Arg effect on platelet activation.     

Developing recombinant HPA-1a-specific antibodies with abrogated Fcgamma receptor binding for the treatment of fetomaternal alloimmune thrombocytopenia

Fetomaternal alloimmune thrombocytopenia (FMAIT) is caused by maternal generation of antibodies specific for paternal platelet antigens and can lead to fetal intracranial hemorrhage. A SNP in the gene encoding integrin beta3 causes a clinically important maternal-paternal antigenic difference; Leu33 generates the human platelet antigen 1a (HPA-1a), whereas Pro33 generates HPA-1b. As a potential treatment to prevent fetal intracranial hemorrhage in HPA-1a alloimmunized pregnancies, we generated an antibody that blocks the binding of maternal HPA-1a-specific antibodies to fetal HPA-1a1b platelets by combining a high-affinity human HPA-1a-specific scFv (B2) with an IgG1 constant region modified to minimize Fcgamma receptor-dependent platelet destruction (G1Deltanab). B2G1Deltanab saturated HPA-1a+ platelets and substantially inhibited binding of clinical HPA-1a-specific sera to HPA-1a+ platelets. The response of monocytes to B2G1Deltanab-sensitized platelets was substantially less than their response to unmodified B2G1, as measured by chemiluminescence. In addition, B2G1Deltanab inhibited chemiluminescence induced by B2G1 and HPA-1a-specific sera. In a chimeric mouse model, B2G1 and polyclonal Ig preparations from clinical HPA-1a-specific sera reduced circulating HPA-1a+ platelets, concomitant with transient thrombocytopenia. As the Deltanab constant region is uninformative in mice, F(ab')2 B2G1 was used as a proof of principle blocking antibody and prevented the in vivo platelet destruction seen with B2G1 and polyclonal HPA-1a-specific antibodies. These results provide rationale for human clinical studies.     

Flow cytometry analysis of platelet antibodies

We have devised assays to detect both circulating alloantibodies to platelets (indirect assay) and platelet-association IgG and IgM (direct assay) using a flow cytometric technique. A variety of patients with immune thrombocytopenia were studied. Employment of a confocal lens in the flow cytometer increased the discrimination power of the instrument. Patients with autoimmune thrombocytopenia (idiopathic thrombocytic purpura [ITP], systemic lupus erythematosus (SLE), lymphoma, leukemia, and drug-induced thrombocytopenia showed a significant increase in platelet-associated antibody. Circulating antibodies to platelets (alloantibodies) were demonstrated in cases of platelet refractoriness and neonatal isoimmune purpura. Day-today precision of the assays ranged from 3% to 6% (coefficient of variation). No interference was shown in the presence of hemoglobin (5 g/L), triglycerides (10 g/L), or polyclonal and monoclonal immunoglobulinemia (50 g/L: IgG, IgA, IgM). The sensitivity of the direct assay was 500 attograms of IgG or IgM platelet.     

The chemical and immunoglobulin structural features necessary for reactions of quinine-dependent antibodies to neutrophils

BACKGROUND: Previously described were three patients with quinine- dependent antibodies to neutrophils, platelets, and red cells who had episodic pancytopenia and renal failure. The nature of the antibody- drug-neutrophil interactions was investigated with sera from these patients. STUDY DESIGN AND METHODS: Sera from all three patients were tested against neutrophils in flow cytometry in the presence of several compounds related to quinine. IgG and Fab and F(ab')2 fragments were prepared from the serum of one patient and tested against neutrophils in flow cytometry and immunoprecipitation in the presence of quinine and related compounds. RESULTS: In flow cytometry, sera from all three patients plus quinidine reacted with neutrophils. Sera from Patients 1 and 3 reacted with neutrophils in the presence of cinchonidine (desmethoxy-quinine) and serum from Patient 3 also reacted with neutrophils in the presence of cinchonine (desmethoxy-quinidine). None of the sera reacted with neutrophils in the presence of chloroquine or primaquine. Serum from Patient 3 plus quinolinic acid, a tryptophan metabolite, reacted with neutrophils, but sera from the other two patients did not. Patient 3 serum plus tryptophan or another tryptophan metabolite, quinalidic acid, did not react with neutrophils. IgG from Patient 3 serum reacted with neutrophils in flow cytometry in the presence of quinine, quinidine, cinchonidine, cinchonine, and quinolinic acid. F(ab')2 fragments plus quinine or cinchonidine also reacted with neutrophils, but Fab fragments plus quinine did not. In the presence of quinine, Patient 3 IgG immunoprecipitated the 85- and 60-kDa molecules and F(ab')2 fragments immunoprecipitated the 85-kDa molecule. Patient 3 serum plus quinidine, cinchonidine, cinchonine, and quinolinic acid immunoprecipitated the 130- and 85-kDa molecules, but not the 60-kDa molecule. CONCLUSION: Quinine-dependent neutrophil antibodies often react with neutrophils in the presence of quinidine and related compounds. These reactions were mediated by the F(ab')2 domain of IgG.     

Platelet antibodies of the IgM class in immune thrombocytopenic purpura

The clinical course and response to therapy of patients with immune thrombocytopenic purpura (ITP) are not completely determined by the level of IgG present on the platelet surface. It is possible that antibodies of other immunoglobulin classes also play a role in platelet destruction in some of these patients. Therefore, we studied 175 patients with ITP for the presence of IgM anti-platelet antibodies using radiolabeled polyclonal or monoclonal anti-IgM. We observed that 57% of patients with clinical ITP had increased levels of IgM on their platelets, compared with normal controls and patients with thrombocytopenia who did not have ITP (less than 10%), (P less than 0.01). We obtained similar results using either radiolabeled polyclonal or monoclonal anti-IgM, reagents whose integrity was first characterized using erythrocytes coated with defined amounts of IgM antibody. Among patients with increased platelet-IgM there was a significant correlation both with the presence of increased platelet-C3 as well as the amount of platelet-C3 (P less than 0.01, r = 0.53). We demonstrated the presence of warm-reacting IgM anti-platelet antibodies in the plasma of two of these patients who were further studied. The isolated IgM fraction from these two plasmas was able to activate complement and place 3H-C3 on normal platelets. These studies demonstrate the presence of warm-reacting IgM anti-platelet antibodies in some patients with ITP. They suggest that the binding of complement to platelets by IgM antibodies may initiate platelet clearance as well as enhance the effect of IgG antibodies in ITP.     

Heterogeneity of antibody response to human platelet transfusion.

To study the antibody response to human platelet transfusions, nine thrombocytopenia patients with bone marrow failure were given 6 U (3X10(11)) of random platelet concentrates twice a week. Before transfusion, none of the patients had preexisting antibodies detectable with lymphocytotoxicity, platelet aggregation, or capillary leukoagglutination techniques. After receiving 18-78 U of platelets, they became refractory to further transfusions of random platelets and alloantibodies were detectable. Two patterns of antibody response could be identified. In three patients, the sera were not lymphocytotoxic with a panel of standard cells in which all the known HLA antigens in the first and second series were represented at least once. Yet, they caused platelet aggregation with 30, 24, and 60%, respectively, of a donor population studied. The aggregating activities were inhibited by antihuman IgG but not by antihuman IgA or antihuman IgM antiserum. The aggregating antibodies could be absorbed out with donor platelets but not lymphocytes or granulocytes. Antibodies from two of these patients aggregated platelets of their respective siblings matched for both HLA haplotypes. Transfusion of platelets from these two siblings did not increase the platelet count while platelets obtained from aggregation-negative donors did. The sera from the remaining six patients were lymphocytotoxic with 15-100% of the panel of standard cells. They also had aggregating antibodies, which could be absorbed out by both platelets and lymphocytes, suggesting that they were HLA antibodies. These data suggest that the development of platelet-specific antibodies may play an important role in the immunological rejection of isologous platelets, and should be considered in the selection of donors for patients who are refractory to platelets from random donors.     

Captopril-enhanced binding of PlA1 (HPA-1a) antibodies in posttransfusion purpura

A case of posttransfusion purpura is reported in a 90-year-old patient whose PlA1 antibody (anti-HPA-1a) was found to bind better to HPA-1a in the presence of captopril, a drug the patient had taken. Initially, IgG antibodies were found in the serum that reacted with normal platelets, but the binding of the antibody was increased in vitro by captopril, which suggested that captopril was responsible for the thrombocytopenia. However, in vitro studies demonstrated that the patient's platelets were negative for HPA-1a and that anti-HPA-1a was present in the serum, both of which findings were consistent with the diagnosis of posttransfusion purpura. The binding of this antibody was enhanced 50 percent by captopril in vitro, and increased binding in the presence of captopril did not occur when the anti-HPA-1a was removed. Similar results were obtained with serum containing anti-HPA-1a from another patient with posttransfusion purpura. Thus, captopril may increase the binding of anti-HPA-1a and confuse the determination of the cause of acute thrombocytopenia.     

Platelets do not adsorb HLA class I molecules during storage of pooled platelet concentrates

The origin of HLA class I molecules on platelets is still under discussion. Adsorption of HLA molecules on platelets using specific experimental conditions has been described. The study presented investigates whether there is a significant elution and adsorption of HLA class I molecules on platelets during storage of pooled random platelet concentrates (PRPC) under routine conditions. Platelet concentrates (PCs) from whole blood were prepared from HLA-A2-positive and HLA-A2-negative donors, pooled and stored under routine conditions. In addition, platelets from HLA-A2-negative donors were pelleted and resuspended in cell-free plasma from HLA-A2-positive donors. HLA-A2-positive PCs (positive control), HLA-A2-negative PCs (negative control) and HLA-A2-negative platelets in plasma from HLA-A2-negative donors were stored simultaneously. Binding of FITC-conjugated monoclonal murine antihuman HLA-A2 antibodies (anti-HLA-A2-mab) was measured during 5-day storage by flow cytometry. An increased binding of anti-HLA-A2-mab during storage was found on HLA-A2-negative platelets (P < 0.005) independently whether they were incubated with cell-free plasma or platelets from HLA-A2-positive donors or autologous HLA-A2-negative cell-free plasma. However, non-specific binding of IgG controls increased equally, whereas anti-HLA-A2-mab binding to platelets from HLA-A2-positive donors did not decrease during storage. This study suggests that there is no significant elution and adsorption of HLA class I antigens of platelets in pooled PCs during storage under the usual conditions for platelet storage. Increased anti-HLA-A2-mab signal was due to non-specific binding. Therefore, HLA class I compatible platelets should maintain their compatibility for an immunized patient when stored in a pool with HLA incompatible platelets and shortened survival after transfusion should not be expected.     

Variant Bernard-Soulier syndrome type bolzano. A congenital bleeding disorder due to a structural and functional abnormality of the platelet glycoprotein Ib-IX complex.

We have studied a patient with a congenital bleeding disorder and phenotypic manifestations typical of Bernard-Soulier syndrome, including giant platelets with absent ristocetin-induced von Willebrand factor binding. Two monoclonal antibodies reacting with distinct epitopes in the amino-terminal domain of the alpha-chain of glycoprotein (GP) Ib were used to estimate the number of GP Ib molecules on the platelet membrane. In the patient, binding of one antibody (LJ-Ib10) was approximately 50% of normal, while binding of the other (LJ-Ib1) was absent. Binding of both antibodies was reduced to approximately 50% of normal in the mother and one sister of the propositus, and their platelets exhibited approximately 70% of normal von Willebrand factor binding. Immunoblotting studies confirmed the presence of GP Ib alpha, as well as GP IX, in patient platelets. Antibody LJ-Ib10, but not LJ-Ib1, could immunoprecipitate the patient's GP Ib alpha from surface-labeled proteins. Thus, platelets from the propositus contained a structurally and functionally altered GP Ib-IX complex lacking a specific antibody epitope and the ability to bind von Willebrand factor. In contrast, the binding of human alpha-thrombin to the patient's platelets was normal, and three classes of binding sites with high, intermediate, and low affinity could be detected. These studies define a distinct variant form of Bernard-Soulier syndrome and provide evidence, based on a naturally occurring mutant molecule, that the amino-terminal region of GP Ib alpha contains a von Willebrand factor-binding domain distinct from the high affinity thrombin-binding site. Use of different monoclonal antibodies with distinct epitope specificities appears to be essential for a correct identification of variant Bernard-Soulier syndrome.     

Dose-dependent platelet stimulation and inhibition induced by anti-PIA1 IgG

The PIA1 antibody produces several clinically distinct and severe thrombocytopenias. Investigations have demonstrated divergent effects on platelet function; prior reports demonstrated inhibition, while a conflicting publication showed platelet activation. We have resolved this conflict using anti-PIA1 IgG produced by a patient with posttransfusion purpura. Relatively low concentrations stimulated platelet aggregation and release of adenosine triphosphate (ATP) whereas high concentrations inhibited platelet function, producing a thrombasthenia-like state. The number of molecules of platelet-associated IgG necessary to initiate aggregation and ATP release (2,086 +/- 556) or produce maximum aggregation (23,420 +/- 3,706) or complete inhibition (63,582 +/- 2654) were measured with a quantitative radiometric assay for bound anti-PIA1. Preincubation of platelets with high concentrations of PIA1 antibody inhibited platelet aggregation with 10 mumol/L adenosine diphosphate and blocked 125I-labeled fibrinogen platelet binding. Platelet activation with nonfibrinogen dependent agonist, 1 U/ml thrombin, was not inhibited by this high concentration of PIA1 IgG. In conclusion, anti-PIAI IgG produces (1) stimulation of platelet aggregation and ATP release that is initiated with 2000 molecules IgG per platelet and is associated with an increase of 125I-fibrinogen binding; (2) conversely, inhibition of platelet aggregation is observed with maximum antibody binding, 63,000 molecules IgG per platelet, and is mediated via a blockade of fibrinogen binding.     

Immune-mediated thrombocytopenia of malaria.

Thrombocytopenia frequently complicates malarial infections but the mechanism has not been elucidated. We studied 28 patients with malarial infections and noted that 16 of 17 thrombocytopenic patients had elevated levels of platelet-associated IgG (PAIgG). In all thrombocytopenic patients studied, the level of PAIgG returned to normal as the platelet count rose to normal levels. To study the mechanism of the elevated platelet-bound IgG, IgG and F(ab')2 from patients with recurrent Plasmodium falciparum infections was purified and radiolabeled. Labeled and unlabeled P. falciparum antigen was also prepared. IgG did not nonspecifically bind to malaria-damaged platelets. Binding studies with 3H-malarial antigen demonstrated platelets have saturable binding sites for malarial antigen. Increasing concentrations of malarial antigen displaced the 125I-IgG antimalarial antibody from the platelets. The binding of 125I-IgG and 125I-F(ab')2 was similar and this excluded significant immune complex binding. The thrombocytopenia that complicates at least some malarial infections is caused by immune mechanisms; specific IgG binds to platelet-bound malaria antigen through the Fab portion of the immunoglobulin molecule.     

Isolation and Quantitation of the Platelet Membrane Glycoprotein Deficient in Thrombasthenia Using a Monoclonal Hybridoma Antibody

We used the hybridoma technique to characterize further the platelet glycoprotein abnormality in Glanzmann's thrombasthenia. Spleen cells from Balb/c mice immunized with human platelets were fused to mouse myeloma cell line Sp2/0-Ag14. Hybridoma lines producing a variety of antiplatelet antibodies were isolated by hypoxanthine-aminopterin-thymidine selection and cloned, and purified monoclonal IgG from six lines was prepared. One of these lines, 8aB5-9, produced an antibody, Tab, that binds to a protein on normal but not thrombasthenic platelets. We isolated this protein from Triton X-100 solubilized normal platelet membranes by affinity chromatography on Tab-Sepharose. As determined by SDS polyacrylamide gel electrophoresis, the isolated protein is a complex of glycoproteins IIb and IIIa, because the two subunits comigrate with glycoproteins IIb and IIIa of whole platelets and show identical changes in mobility after disulfide bond reduction. We prepared (125)I-Tab to determine the number of glycoprotein IIb-IIIa complexes on normal and thrombasthenic platelets by a direct binding assay. Platelets from 17 normal donors bound 39,000+/-4,600 (SD) Tab molecules/platelet. Platelets from four patients with thrombasthenia lacked Tab binding sites (<5%). Five obligate and four presumed heterozygotes for thrombasthenia bound 24,500+/-5,800 Tab molecules/platelet. The platelet alloantigen, Pl(Al), is not that recognized by Tab, because platelets from three Pl(Al)-negative subjects bound Tab normally. Studies with the Tab antibody have (a) enabled quantitation of the number of glycoprotein IIb-IIIa complexes on normal platelet membranes, (b) demonstrated that thrombasthenic homozygotes lack and heterozygotes have a partial deficiency of this complex, and (c) made possible the isolation of this membrane protein which may be required for normal platelet aggregation and clot retraction.