Paradoxical Platelet Activation Was not Observed on Dissociation of Abciximab from GPIIb-IIIa Complexes

The ability of abciximab to bind and dissociate from platelets raises the question of the conformational state of GPIIb-IIIa complexes losing abciximab and the risk of paradoxical drug-induced platelet activation. Platelets incubated with abciximab and mixed in vitro with c7E3 Fab-free platelets lost the drug to the new platelets giving a single platelet population with a unimodal abciximab distribution within 17 h. Prelabeling the receiving platelets with phycoerythrin-labeled anti-GPIb monoclonal antibody (MoAb), permitted their identification by flow cytometry. Binding of PAC-1 and AP6, two MoAbs specific for activated GPIIb-IIIa, was then assessed to both losing and receiving platelet populations during transfer of abciximab. The subpopulation losing c7E3 Fab failed to show increased binding of these MoAbs. However, PAC-1 binding increased in both subpopulations after addition of ADP. Thus GPIIb-IIIa complexes are not in an activated state after dissociation of abciximab unless there is an additional source of activation.

Analysis of the Amino Acid Requirement for a Normal αIIbβ3 Maturation at αIIbGlu324 Commonly Mutated in Glanzmann Thrombasthenia

Glanzmann thrombasthenia is an inherited bleeding disorder arising from quantitative or qualitative defects of the αIIbβ3 integrin of platelets. Here, we report that PCR-SSCP analysis and DNA sequencing revealed a homozygous single base pair substitution in exon 12 of the αIIb gene leading to a Glu324 (E) to Lys (K) substitution in the αIIb subunit in a patient with Type I disease. As this mutation is found on at least 3 continents, the codon for Glu324 may be a mutational hotspot of the disease. To better understand this mutation, we analyzed the effect of substituting E324 with A324, L324, D324, Q324, N324, S324, as well as K324, looking at both αIIbβ3 maturation and cell surface expression in transiently transfected Cos-7 cells. The maturation state of the receptor clearly correlated with the level of cell membrane expression. Maturation efficiency was dependent on the electric charge as well as the size of the side chain of the amino acid present in what is a highly conserved N-terminal position in the third β-strand of blade 5 of the αIIbβ-propeller.

A Novel Hemizygous Bernard-Soulier Syndrome (BSS) Mutation in the Amino Terminal Domain of Glycoprotein (GP)Ibβ- Platelet Characterization and Transfection Studies

Glycoprotein (GP) Ib-V-IX is a unique adhesion receptor complex on platelets. Mutations in GPIbα, Ibβ, and IX can lead to the rare bleeding disorder, Bernard-Soulier Syndrome (BSS). Here, we report a novel hemizygous variant of BSS in which Pro29 in one GPIbβ allele is substituted by a Leu (GPIbβ:P29L). Fluoresence in situ hybridisation revealed that the 22q11 locus was deleted from the homologous chromosome. The pedigree was determined and revealed inheritance of the GPIbβ:P29L allele from the father. Flow cytometry with a range of antibodies detected no expression of GPIb-V-IX on the surface of the patient’s platelets. Western blotting revealed an absence of GPIbα and GPIbβ from platelet lysates. Co-expression of GPIbβ:P29L with normal GPIbα and GPIX in a heterologous cell system confirmed that the mutant subunit did not support surface expression of the complex. Interestingly, residual expression of GPIbβ:P29L anchored in the plasma membrane alone was now seen. This novel BSS mutation expressed in heterologous cells is in agreement with recent in vitro evidence that the correct conformation of the amino terminal region of GPIbβ is required for normal expression of the intact receptor complex.

Two Different β3 Cysteine Substitutions Alter αIIbβ3 Maturation and Result in Glanzmann Thrombasthenia

We report the defects responsible for Glanzmann thrombasthenia in two patients showing traces of abnormally migrating platelet β3 in immunoblotting. Using PCR-SSCP and direct sequencing, we identified a novel homozygous mutation in exon 10 of the β3 gene of patient 1 which gave a C457 to Y amino acid substitution. A C542 to R substitution in β3 of patient 2 was previously reported by us. These cysteines are present in EGF-domains 1 and 3 respectively of β3. We therefore constructed mutants carrying substitutions on cysteine residues in each of the first three EGF domains of β3, C457, C495 and C542 respectively. Transient expression of these mutants in COS-7 cells, including the C542 and C547 double mutant, proved that disulfide disruption directly affects cell surface expression of the integrin. We then showed by metabolic (35S) labeling and Endo-H glycosidase treatment that these substitutions strongly affected complex maturation within the cell.

Mutations in the β3 gene giving rise to type I Glanzmann thrombasthenia in two families in Portugal

Glazzmann thrombasthenia is an inherited bleeding syndrome in which an absence of platelet aggregation is associated with quantitative or qualitative deficiencies of the alphaIIbbeta3 integrin. We now describe biochemical and molecular studies on two Portuguese families where platelets lack both surface and intracellular pools of alphaIIbbeta3. DNA extraction was followed by PCR-SSCP analysis of all exons and intronic boundaries in the alphaIIb and beta3 genes. Migration abnormalities were found for PCR fragments encompassing exon 12 (family 1) and exon 10 (family 2). For patient 1, there was a homozygous G to T transition at position 1846 which resulted in a stop codon at codon 616 in the beta3 gene. For patient 2, direct sequencing revealed a homozygous 1347C insert which led to a stop codon at codon 444 in the beta3 gene. For both patients a single mutated allele was inherited from each parent. Evidence is accumulating that nonsense mutations leading to a truncated beta3 may be a frequent cause of type I Glanzmann thrombasthenia in the Iberian peninsula.

Phenotypic heterogeneity in the Gray platelet syndrome extends to the expression of TREM family member, TLT-1

The Gray platelet syndrome (GPS) is a rare inherited disorder linked to undefined molecular abnormalities that prevent the formation and maturation of alpha-granules. Here, we report studies on two patients from unrelated families that confirm phenotypic heterogeneity in the disease. First we used immunoelectron microscopy (I-EM) to confirm that TREM-like transcript-1 (TLT-1) is mostly localized to alpha-granule membranes of normal platelets. Then we performed Western blotting (WB) and flow cytometry with permeabilized platelets to show that TLT-1 is selectively reduced in the platelets of patient 1, previously noted to be deficient in glycoprotein (GP)VI (Nurden et al., Blood 2004; 104: 107-114). Yet both TLT-1 and GPVI were normally expressed in platelets of patient 2. Usual levels of JAM-C and claudin-5, also members of the immunoglobulin receptor family, were detected in platelets of both patients. In contrast, P-selectin was markedly decreased for patient 1 but not patient 2. Two metalloproteases, MMP-2 and MMP-9 were normally present. As predicted, platelets of patient 1 showed little labelling for TLT-1 in I-EM, whereas residual Fg was seen in small vesicular structures and P-selectin lining vacuoles or channels of what may be elements of the surface-connected canalicular system. Our results identify TLT-1 as a glycoprotein potentially targeted in platelets of GPS patients, while decreases in at least three membrane glycoproteins suggest that an unidentified proteolytic activity may contribute to the phenotype in some patients with this rare disease.

Family screening for a Glanzmann's thrombasthenia mutation using PCR-SSCP

Genetic counselling is often requested in Glanzmann's thrombasthenia, but measurements of GPIIb-IIIa density on platelets are often too inconclusive to allow a precise assessment of whether prospective parents are obligate heterozygotes for this disease by this measure alone. The recent application of PCR technology to Glanzmann's thrombasthenia has resulted in the identification of a large number of mutations, i.e. insertions/ deletions, splicing defects, in the genes for both GPIIb and GPIIIa. Among the reported abnormalities is an intronic G-->A substitution at the splice donor site of intron 15 in the GPIIb gene of a European gypsy tribe. This gives rise to an abnormal splicing, of an 8-bp deletion located at the 3' end of exon 15, a reading-frame shift and a premature stop codon in the mRNA for GPIIb. In applying PCR-SSCP to the elucidation of the genetic defects of a series of Glanzmann's patients, we have found the above-cited abnormality in three more gypsy families in France. The presence of the mutation was initially established by sequencing the amplified fragment, and its presence in family members was confirmed by both PCR-SSCP and HphI restriction analysis. Evaluation of the intronic G-->A mutation enabled genetic counselling to prospective parents within these families.

Triple heterozygosity in the integrin alphaIIb subunit in a patient with Glanzmann's thrombasthenia

We report triple heterozygosity in the integrin alpha(IIb) subunit in a 5-year-old Canadian girl with Glanzmann's thrombasthenia. The patient has a severe bleeding history possibly aggravated by low VWF suggestive of associated type 1 von Willebrand's disease. Platelet aggregation was absent or severely reduced for all physiologic agonists. Flow cytometry showed an approximately 4% residual surface expression of alpha(IIb)beta(3). Western blotting confirmed a low platelet expression of both subunits. PCR-SSCP and direct sequencing showed no abnormalities in the beta(3) gene, but revealed a G-->A transition at a splice site [IVS 19 (+1)] of exon 19 in the alpha(IIb) gene. Of maternal inheritance, the splice site mutation was associated with intermediate levels of alpha(IIb)beta(3) in carriers. Unexpectedly, two G-->A transitions were detected in exon 29 of the alpha(IIb) gene and led to V(951)-->M and A(958)-->T amino acid substitutions. Family studies using restriction enzymes showed that both exon 29 mutations were paternal in origin and cosegregated across three generations. Transient expression in which mutated alpha(IIb) was cotransfected with wild-type beta(3) in COS-7 cells showed that V(951)-->M gave a much reduced surface expression of alpha(IIb)beta(3) and a block in the maturation of pro-alpha(IIb). In contrast, the A(958) substitution appeared to be a novel polymorphism. Our studies highlight an unusual mixture of defects giving rise to severe bleeding in a child and describe the first pathological missense mutation affecting a C-terminal residue of the calf-2 domain of alpha(IIb).

Severe deficiency of glycoprotein VI in a patient with gray platelet syndrome

We report a novel case of gray platelet syndrome (GPS) where a severe deficiency of the platelet collagen receptor, glycoprotein (GP) VI, accompanies classical symptoms of a low platelet count and platelets lacking alpha-granules. Dense granules were normally present. Platelet aggregation with collagen was severely decreased, as was the response to convulxin (Cvx), a GPVI agonist. Quantitative analysis of GPVI using fluorescein isothiocyanate (FITC)-Cvx in flow cytometry showed its virtual absence on the patient's platelets. The GPVI deficiency was confirmed using monoclonal antibodies in Western blotting and in immunogold labeling on frozen thin sections where internal pools of GPVI were confirmed for normal platelets. The Fc receptor gamma-chain, constitutively associated with GPVI in normal platelets, was present in subnormal amounts, and the phospholipase C gamma 2-dependent activation pathway appeared to function normally. No autoantibodies to GPVI were found in the patient's serum using monoclonal antibody immobilization of platelet antigen (MAIPA). Sequencing of coding regions of the GPVI gene failed to show abnormalities, and mRNA for GPVI was present in the patient's platelets, pointing to a probable acquired defect in GPVI expression. Our results may provide a molecular explanation for the subgroup of patients with severely deficient collagen-induced platelet aggregation as previously described for GPS in the literature.

Redistribution of glycoprotein Ib within platelets in response to protease-activated receptors 1 and 4: roles of cytoskeleton and calcium

Thrombin activates human platelets by hydrolyzing the protease-activated receptors PAR-1 and PAR-4, exposing new N-terminal sequences which act as tethered ligands, and binding to glycoprotein (GP) Ib, whose surface accessibility transiently decreases when platelets are stimulated by the enzyme. In an attempt to better understand this latter process, we used the peptides SFLLRNPNDKYEPF (PAR-1-AP or TRAP) and AYPGKF (PAR-4-AP) to study whether hydrolysis of both PAR receptors leads to GPIb redistribution. Both peptides induced surface clearance of GPIb with a maximum at 2 min and 5 min for PAR-1-AP and PAR-4-AP, respectively, followed by a slow return to the surface with levels normalizing between 30 and 60 min. Translocation was associated with the formation of clusters of GPIb as revealed by fluorescence microscopy. This transient redistribution of GPIb was blocked by cytochalasin D and in large part by the membrane permeable Ca2+ chelator, BAPTA. The inhibitor of phosphatidylinositol 3-kinase and myosin light chain kinase, wortmannin, did not significantly modify internalization of GPIb, although its return to the surface was delayed for PAR-1-AP. PAR receptor-mediated association of GPIb to the insoluble cytoskeleton was blocked by cytochalasin D, while BAPTA alone increased and stabilized the presence of GPIb. Globally, immunoprecipitation experiments and analysis of the cytoskeleton confirmed that GPIb translocation is powered by a contractile mechanism involving Ca2+ mobilization, actin polymerization, and myosin incorporation into the cytoskeleton and that both PAR-1 and PAR-4 can activate this process.

A novel missense mutation shows that GPIbbeta has a dual role in controlling the processing and stability of the platelet GPIb-IX adhesion receptor

Glycoprotein (GP) Ibalpha is a major adhesive receptor of platelets, surface expressed as part of the GPIb-IX-V complex. However, important questions about how the four gene products (Ibalpha, Ibbeta, IX, and V) composing this complex are processed remain. A deficiency of or nonfunctioning GPIb-IX-V is characteristic of the Bernard-Soulier syndrome (BSS), an inherited bleeding disease. We now report a BSS variant whose platelets have little or no GIbbeta or GPIX, but where residual GPIbalpha was selectively located in flow cytometry by monoclonal antibodies (WM23 and Bx-1) recognizing denatured epitopes. Whereas WM23 immunoprecipitated GPIbalpha (130 kDa), GPIX, and GPIbbeta from control platelets, a single surface protein of approximately 66 kDa was obtained for the patient. DNA sequencing revealed a homozygous Asn(64) --> Thr substitution in the GPIbbeta from the patient. This substitution modified a conserved residue in the COOH-terminal region flanking the single-copy leucine-rich domain of GPIbbeta. When GPIbbeta64Thr was coexpressed in a stable CHO cell line with wild-type GPIbalpha and GPIX, flow cytometry and confocal microscopy failed to show GPIb-IX complexes at the cell surface. Intracellular GPIbalpha and GPIbbeta were detected and largely confined to the endoplasmic reticulum, and little GPIX was seen. GPIbalpha was immunoprecipitated as a 66-70 kDa protein in (35)S metabolic studies and lacked O-glycosidic side chains. Also, it was not disulfide bound to the mutated GPIbbeta. Thus, a single amino acid substitution in the extracellular domain of GPIbbeta can affect both the maturation of GPIbalpha and GPIX stability. GPIbbeta has a pivotal role in regulating GPIb-IX-V biosynthesis.

Immunolocalization of P2Y1 and TPalpha receptors in platelets showed a major pool associated with the membranes of alpha -granules and the open canalicular system

P2Y(1) and thromboxane-prostanoid-alpha (TPalpha) receptors on platelets belong to the G-protein-coupled 7-transmembrane domain family. They transmit signals for shape change, mobilization of calcium, and platelet aggregation. Immunogold labeling with a monoclonal antibody (MoAb) to the amino-terminal domain of P2Y(1) and a polyclonal antibody to the C-terminal domain of TPalpha revealed that while present at the platelet surface, both receptors were abundantly represented inside the platelet. Specifically, receptors were found in membranes of alpha-granules and elements of the open-canalicular system. A similar organization was found in mature megakaryocytes. Activation of platelets by adenosine diphosphate (ADP) and the thromboxane A(2) (TXA(2)) analog, I-BOP [1S-(1 alpha,2 beta(5Z),3 alpha-(1E,3S)4 alpha)-7-(3-(3- hydroxy-4-(p-iodophenoxy)-1-butenyl)-7-oxabicyclo(2.2.1)hept-2-yl)-5-heptenoic acid], increased the labeling of both P2Y(1) and TPalpha at the surface and in intracellular pools, suggesting that activation resulted in greater antibody accessibility to the receptor. A return to a platelet discoid shape and to basal values of labeling accompanied receptor desensitization. Platelets lacking the P2Y(12) ADP receptor normally expressed P2Y(1) and TPalpha, both before and after activation. Studies with the anti-ligand-induced binding site (anti-LIBS) MoAb, AP-6, confirmed that stored fibrinogen associated with internal pools of alpha(IIb)beta(3) at the start of secretion in a microenvironment containing agonist receptors. Pharmacologic antagonism of ADP or TXA(2) receptors in antithrombotic therapy may need to take into account blockade of internal receptor pools.

A novel hemizygous Bernard-Soulier Syndrome (BSS) mutation in the amino terminal domain of glycoprotein (GP)Ibbeta--platelet characterization and transfection studies

Glycoprotein (GP) Ib-V-IX is a unique adhesion receptor complex on platelets. Mutations in GPIbalpha, Ibbeta, and IX can lead to the rare bleeding disorder, Bernard-Soulier Syndrome (BSS). Here, we report a novel hemizygous variant of BSS in which Pro29 in one GPIbbeta allele is substituted by a Leu (GPIbbeta:P29L). Fluoresence in situ hybridisation revealed that the 22q11 locus was deleted from the homologous chromosome. The pedigree was determined and revealed inheritance of the GPIbbeta:P29L allele from the father. Flow cytometry with a range of antibodies detected no expression of GPIb-V-IX on the surface of the patient's platelets. Western blotting revealed an absence of GPIbalpha and GPIbbeta from platelet lysates. Co-expression of GPIbbeta:P29L with normal GPIbalpha and GPIX in a heterologous cell system confirmed that the mutant subunit did not support surface expression of the complex. Interestingly, residual expression of GPIbbeta:P29L anchored in the plasma membrane alone was now seen. This novel BSS mutation expressed in heterologous cells is in agreement with recent in vitro evidence that the correct conformation of the amino terminal region of GPIbbeta is required for normal expression of the intact receptor complex.

Analysis of the amino acid requirement for a normal alphaIIbbeta3 maturation at alphaIIbGlu324 commonly mutated in Glanzmann thrombasthenia

Glanzmann thrombasthenia is an inherited bleeding disorder arising from quantitative or qualitative defects of the alphaIIbbeta3 integrin of platelets. Here, we report that PCR-SSCP analysis and DNA sequencing revealed a homozygous single base pair substitution in exon 12 of the IIb gene leading to a Glu(324) (E) to Lys (K) substitution in the alphaIIb subunit in a patient with Type I disease. As this mutation is found on at least 3 continents, the codon for Glu(324) may be a mutational hotspot of the disease. To better understand this mutation, we analyzed the effect of substituting E(324) with A(324), L(324), D(324), Q(324), N(324), S(324), as well as K(324), looking at both alphaIIbbeta3 maturation and cell surface expression in transiently transfected Cos-7 cells. The maturation state of the receptor clearly correlated with the level of cell membrane expression. Maturation efficiency was dependent on the electric charge as well as the size of the side chain of the amino acid present in what is a highly conserved N-terminal position in the third beta-strand of blade 5 of the alphaIIbeta beta-propeller.

A Ser752-->Pro substitution in the cytoplasmic domain of beta3 in a Glanzmann thrombasthenia variant fails to prevent interactions between the alphaIIbbeta3 integrin and the platelet granule pool of fibrinogen

A Glanzmann thrombasthenia variant with a beta3 Ser752-->Pro cytoplasmic domain substitution has platelets that fail to aggregate or bind soluble fibrinogen (Fg) after activation. Despite this, Fg is normally present in the alpha-granules. We have used immunoelectron microscopy to examine the reactivity of Fg with the different pools of alphaIIbbeta3 in the patient's platelets. Immunogold labelling was performed on cryosections using an anti-ligand-induced binding site (LIBS) monoclonal antibody (mAb), which binds to alphaIIbbeta3 only when Fg is bound, or a mixture of two anti-receptor-induced binding site (RIBS) mAbs that specifically recognize receptor-bound Fg. Labelling of the alpha-granule membrane and channels of the surface-connected canalicular system in unstimulated platelets confirmed that the mutated alphaIIbbeta3 retains the capacity to transport Fg. When the patient's platelets were stimulated with ADP in the presence of Fg, as expected there was a much-decreased activation of surface-exposed alphaIIbbeta3. However, thrombin-induced activation was associated with both secretion and a rapid increase in the labelling of internal membrane systems by anti-RIBS and anti-LIBS mAbs, with mobilization of the internal Fg pool. Yet labelling on the surface of the patient's platelets was transient. Our studies implied that alphaIIbbeta3 in platelets may bind fibrinogen in different activation states and that this patient specifically lacked high-affinity binding.

Two different beta3 cysteine substitutions alter alphaIIb beta3 maturation and result in Glanzmann thrombasthenia

We report the defects responsible for Glanzmann thrombasthenia in two patients showing traces of abnormally migrating platelet beta3 in immunoblotting. Using PCR-SSCP and direct sequencing, we identified a novel homozygous mutation in exon 10 of the beta3 gene of patient 1 which gave a C457 to Y amino acid substitution. A C542 to R substitution in beta3 of patient 2 was previously reported by us. These cysteines are present in EGF-domains 1 and 3 respectively of beta3. We therefore constructed mutants carrying substitutions on cysteine residues in each of the first three EGF domains of beta3, C457, C495 and C542 respectively. Transient expression of these mutants in COS-7 cells, including the C542 and C547 double mutant, proved that disulfide disruption directly affects cell surface expression of the integrin. We then showed by metabolic (35S) labeling and Endo-H glycosidase treatment that these substitutions strongly affected complex maturation within the cell.

A novel 196Leu to Pro substitution in the beta3 subunit of the alphaIIbbeta3 integrin in a patient with a variant form of Glanzmann thrombasthenia

Glanzmann thrombasthenia (GT) is an inherited disorder where an absence of platelet aggregation is associated with quantitative or qualitative abnormalities of the alphaIIbbeta3 integrin. In rare patients, amino acid substitutions have provided information on the functional significance of specific domains within alphaIIb or beta3. We now report an elderly male GT patient (R.M.) from the south west of France whose platelets possess a small residual expression of alphaIIbbeta3. Furthermore, the integrin failed to undergo the necessary conformational changes following platelet activation to permit the binding of fibrinogen or activation-dependent monoclonal antibodies despite the presence of an RGD-binding site. Screening of the alphaIIb and beta3 genes by PCR-SSCP revealed a heterozygous mutation at position 685 in exon 5 of the beta3 gene leading to a 196Leu to Pro substitution. 196Leu is a highly conserved amino acid of beta3. The other beta3 allele appeared to be silent. This mutation, inherited from his mother and present in other family members with intermediate levels of alphaIIbbeta3, was close to the MIDAS-like domain of beta3, a fact that appears to explain its effect on alphaIIbbeta3 activation and fibrinogen binding.

Paradoxical platelet activation was not observed on dissociation of abciximab from GpIIb-IIIa complexes

The ability of abciximab to bind and dissociate from platelets raises the question of the conformational state of GPIIb-IIIa complexes losing abciximab and the risk of paradoxical drug-induced platelet activation. Platelets incubated with abciximab and mixed in vitro with c7E3 Fab-free platelets lost the drug to the new platelets giving a single platelet population with a unimodal abciximab distribution within 17 h. Prelabeling the receiving platelets with phycoerythrin-labeled anti-GPIb monoclonal antibody (MoAb), permitted their identification by flow cytometry. Binding of PAC-1 and AP6, two MoAbs specific for activated GPIIb-IIIa, was then assessed to both losing and receiving platelet populations during transfer of abciximab. The subpopulation losing c7E3 Fab failed to show increased binding of these MoAbs. However, PAC-1 binding increased in both subpopulations after addition of ADP. Thus GPIIb-IIIa complexes are not in an activated state after dissociation of abciximab unless there is an additional source of activation.

Labeling of the internal pool of GP IIb-IIIa in platelets by c7E3 Fab fragments (abciximab): flow and endocytic mechanisms contribute to the transport

Abciximab is a new antiplatelet therapeutic in ischemic cardiovascular disease. The drug, chimeric Fab fragments of a murine monoclonal antibody (MoAb) (c7E3), blocks GP IIb-IIIa function. However, its capacity to reach all receptor pools in platelets is unknown. Electron microscopy and immunogold labeling were used to localize abciximab in platelets of patients receiving the drug for up to 24 hours. Studies on frozen-thin sections showed that c7E3 Fab, in addition to the surface pool, also labeled the surface-connected canalicular system (SCCS) and alpha-granules. Analysis of gold particle distribution showed that intraplatelet labeling was not accumulative and in equilibrium with the surface pool. After short-term incubations of platelets with c7E3 Fab in vitro, gold particles were often seen in lines within thin elements of the SCCS, some of which appeared in contact with alpha-granules. Little labeling was associated with Glanzmann's thrombasthenia platelets, confirming that the channels contained bound and not free c7E3 Fab. Endocytosis of abciximab in clathrin-containing vesicles was visualized by double staining and constitutes an alternative mechanism of transport. The remaining free pool of GP IIb-IIIa was evaluated with the MoAb AP-2; flow cytometry showed it to be about 9% on the surface of nonstimulated platelets but 33% on thrombin-activated platelets. The ability of drugs to block all pools of GP IIb-IIIa and then to be associated with secretion-dependent residual aggregation must be considered when evaluating their efficiency in a clinical context.

Autoimmune thrombocytopenic purpura (AITP) and acquired thrombasthenia due to autoantibodies to GP IIb-IIIa in a patient with an unusual platelet membrane glycoprotein composition

The subject (E.B.) is a 63-year-old woman with autoimmune thrombocytopenic purpura (AITP) who was first examined some 6 years ago with symptoms of epistaxis and gum bleeding, severe thrombocytopenia, and large platelets. Her serum tested positively with control platelets in the MAIPA assay performed using monoclonal antibodies (MoAb) to glycoprotein (GP) IIIa (XIIF9, Y2/51), yet was negative in the presence of MoAbs to GP IIb (SZ 22) or to the GP IIb-IIIa complex (AP2, P2). The patient's platelets failed to aggregate with all agonists tested except for ristocetin. IgG isolated from the patient's serum inhibited ADP-induced aggregation of control platelets. Unexpectedly, flow cytometry showed an altered expression of membrane glycoproteins on the patient's platelets. Levels of GP Ib-IX were much higher than previously located by us in platelets. In contrast, the expression of GP IIb-IIIa was about half that seen with control subjects. When Western blotting was performed, a striking finding was a strong band of 250 kDa recognized by a series of MoAbs to GP Ib alpha in addition to the band in the normal position of GP Ib alpha. Finally, ADP-stimulated (E.B.) platelets failed to express activation-dependent epitopes on GP IIb-IIIa as recognized by PAC-1, AP6, or F26 and additionally gave a reduced P-selectin expression after thrombin addition. In conclusion, we present a novel patient with a severely perturbed platelet function where an altered membrane GP profile is associated with the presence of an autoantibody recognizing a complex-dependent determinant on GP IIb-IIIa and inhibitory of platelet aggregation.

Confirmation that GP Ib-IX complexes have a reduced surface distribution on platelets activated by thrombin and TRAP-14-mer peptide

In 1990 we reported that GP Ib-IX complexes accumulated within the surface-connected canalicular system (SCCS) of thrombin-stimulated platelets. This conclusion was reached following investigations using monoclonal antibodies (MAbs) in flow cytometry and a polyclonal antibody to GP Ib alpha in electron microscopy with immunogold staining performed on ultrathin sections of resin-embedded platelets. Recent controversy concerning these results has prompted us to perform further studies using 14 anti-GP Ib-IX MAbs obtained from the 1993 Boston Workshop on Leukocyte Antigens. Features were the use of the MAbs in mixtures and the fact that immunogold staining was performed on frozen thin sections. Platelets were stimulated with either alpha-thrombin or TRAP-14-mer peptide. In all cases a decreased density of GP Ib-IX complexes on exposed areas of the activated platelet surface was accompanied by an increased expression within the SCCS. At the same time we noted that when platelets were stimulated with TRAP-14-mer they progressively exhibited a different internal morphology in comparison to that seen with thrombin. In particular, the dense central mass disappeared and large vacuoles were present throughout the cytoplasm. Overall, these studies confirm that changes in the distribution of GP Ib-IX complexes which follow thrombin-induced platelet activation (i) are indeed observed when antibody mixtures are used to detect them, and (ii) are mediated through the receptor recognized by the TRAP-14-mer peptide.

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.