Biochemical and functional characterization of a new murine monoclonal antibody against human platelet glycoprotein IIIa.

A new murine monoclonal antibody, MDP-1, specific for human platelet glycoprotein IIIa has been produced and characterized. Following SDS-polyacrylamide gel electrophoresis, MDP-1 reacted with a 94kDa protein immobilized on a nitrocellulose membrane. Upon reduction, MDP-1 no longer bound to the 94kDa protein indicating an epitope requiring at least one disulfide bond. On crossed immunoelectrophoresis MDP-1 reacted to the same peak as the GP IIb-IIIa complex-specific antibody AP-2. After dissociation of the GP IIb-IIIa complex with EDTA, AP-2 showed no reactivity while MDP-1 bound to a new peak that was broader and anodal to the original GP IIb-IIIa peak, consistent with GP IIIa. MDP-1 inhibited ADP and thrombin induced aggregation. In addition, MDP-1 inhibited ADP induced release of ATP, but did not inhibit thrombin stimulated ATP release. Following chymotrypsin digestion, MDP-1 bound to a cleaved GP IIIa protein (nonreduced M, = 122 kDa) consistent with opening of the major disulfide loop. A second cleavage resulted in a 63 kDa species that reacted with MDP-1. Scatchard analysis revealed 22 000 molecules of MDP-1 bound per platelet, and indicated a type of binding consistent with positive cooperativity. The antibody bound equally well to stimulated and unstimulated platelets. MDP-1 binding was inhibited by a polyclonal anti-PI(A1) antibody, but bound to platelets from a PI(A1) negative individual indicating a binding site close to but not identical to the PI(A1) epitope. In addition, MDP-1 binding was not inhibited by Arg-Gly-Asp-Ser (RGDS) suggesting that it is not directed to the RGD binding site on GP IIIa.

A comparison of the fibrinogen receptor distribution on adherent platelets using both soluble fibrinogen and fibrinogen immobilized on gold beads.

The distribution of fibrinogen receptors was determined on the surface of adherent platelets using both direct labeling with the ligand fibrinogen which was immobilized on gold particles (Fg-Au) and indirect immunogold (Ig-Au) labeling of bound soluble fibrinogen identified with a rabbit polyclonal anti-fibrinogen antibody. Two distinctly different patterns of labeling were obtained and appeared to depend on whether solid phase fibrinogen (Fg-Au) or soluble phase released fibrinogen were bound to the membrane receptor. The membrane-bound Fg-Au reorganized in patterns that closely mimicked the organization of the underlying cytoskeleton. In approximately 18% of the adherent platelets, Fg-Au was seen in channels or vesicle-like structures lying deep to the platelet surface suggesting internalization into the open canalicular system and/or endocytosis. The labeling pattern obtained when identifying the location of membrane-bound soluble released fibrinogen by Ig-Au was diffuse and lacked the organizational patterns characteristic of Fg-Au. Unlike the Fg-Au probe, early dendritic platelets were heavily labeled by the soluble phase fibrinogen using the Ig-Au technique. Although the label covered the entire exposed platelet membrane in fully spread platelets, labeling over the peripheral web was more dense than that over the intermediate or granulomere zone. The diffuse organization and heavier peripheral distributional pattern of the glycoprotein IIb-IIIa (GP IIb-IIIa) receptor in fixed, adherent platelets, was also seen with the GP IIb-IIIa receptor-specific antibody AP-2. The binding of both the Fg-Au and Ig-Au were inhibited using the tetrapeptide Arg-Gly-Asp-Ser (RGDS) (93% and 98% inhibition, respectively), AP-2 (98% and 97%, respectively) and platelets from patients with Glanzmann's thrombasthenia (GT) (99% and 98%, respectively). The data presented provides the first report that receptor reorganization, following binding of fibrinogen, appears to be related to the state of the ligand. Substrate bound fibrinogen (i.e., Fg-Au or fibrinogen bound to another platelet) induces receptor translocation toward the platelet granulomere in a capping-like phenomenon. On the other hand, the binding of soluble released fibrinogen results in formation of microclusters and short linear arrays in a diffuse distribution but does not induce central movement of receptors. Furthermore, double labeling studies clarify that Fg-Au does not identify all available fibrinogen receptors as many are occupied by soluble released fibrinogen. The data presented provides an interesting new perspective on what constitutes an appropriate ligand-receptor stimulus sufficient to induce receptor reorganization.

Absent platelet aggregation with normal fibrinogen binding in basset hound hereditary thrombopathy.

Platelets from dogs with Basset Hound Hereditary Thrombopathy (BHT) initially displayed a thrombasthenia-like aggregation defect but have been shown to have normal amounts of platelet membrane glycoproteins IIb and IIIa (GPIIb-IIIa), and therefore are more accurately described as thrombopathic. The presence of normal quantities of GPIIb-IIIa, however, did not rule out the possibility of a functionally abnormal glycoprotein complex which would be unable to bind radio-labeled fibrinogen. Therefore, fibrinogen binding in BHT platelets was evaluated. Platelets from BHT and normal dogs were activated with 1 x 10(-5) M ADP in the presence of 125I-fibrinogen and the surface-bound radioactivity was quantitated. The amount of fibrinogen bound by BHT dog platelets was not significantly different than that bound by normal dog platelets. Platelets from dogs with BHT bound 30,282 +/- 3,133 and normal dog platelets bound 31,664 +/- 2,772 molecules of fibrinogen per platelet. The quantitatively normal GPIIb-IIIa complex binds fibrinogen in normal amounts and does not seem to represent the abnormality responsible for the aggregation defect in BHT platelets. Therefore, other factors central to normal platelet function and related to platelet aggregation must be considered.

Defective contact activation of platelets from dogs with basset hound hereditary thrombopathy.

Basset Hound Hereditary Thrombopathy (BHT) is an autosomally inherited disorder of platelet function characterized by a thrombasthenia-like defect in aggregation but normal clot retraction. Glycoprotein IIb-IIIa (GP IIb-IIIa) is detectable in BHT platelets but may be functionally defective. In order to further characterize this potential model for human Glanzmann's thrombasthenia, contact reactivity of BHT platelets was studied by whole mount electron microscopy. Gel filtered BHT platelets, after 30 minutes of contact activation, attached poorly to a formvar substrate. There was an 8 fold difference in the number of adherent BHT platelets and normal platelets. In addition, contact induced shape change was inhibited when compared to control dogs. Almost 95% of control platelets reached fully dendritic or spread forms after 30 minutes of contact; in contrast only 63.7% of BHT platelets reached this degree of activation. The addition of 8.2 uM ADP to BHT platelets induced nearly a 4 fold increase in the number of spread forms and a 5 fold increase in the number of adherent BHT platelets, but did not cause aggregate formation. Both the defect in adhesion and shape change and the ability of ADP to stimulate both adhesion and contact-induced shape change in BHT platelets are similar to recent observations in our laboratory in patient's with type II Glanzmann's thrombasthenia.

Apparent intrinsic prothrombinase activity of human Factor X zymogen: identification with Factor VIII inhibitor bypassing activity (FEIBA).

Steady state kinetic studies have provided evidence for intrinsic prothrombinase activity of human factor X zymogen in a chromogenic assay system. Using a prothrombin substrate, kinetic parameters have been obtained for the action of factors X and Xa. The Km for prothrombin is of a different order of magnitude for the zymogen as compared with the active enzyme. Using a kinetic approach, we have obtained evidence for the binding of factor Xa zymogen to cofactors essential for the coagulant activity of factor Xa. Zymogen enzymatic activity is not inhibited by a specific serine proteinase inhibitor, (p-amidino-phenyl)methanesulfonyl fluoride (p-APMSF), a potent inhibitor of factor Xa. The apparent slow rate of zymogen inhibition by antithrombin III (AT III) as compared with the active enzyme suggests a different kind of zymogen-antithrombin interaction. Blood clotting studies paralleled the kinetic data. Factor X zymogen evidences factor VIII inhibitor bypassing activity (FEIBA) in an in vitro direct clotting system employing factor VIII deficient inhibitor plasma as substrate in both activated or nonactivated partial thromboplastin assay. Most significantly, zymogen coagulant is refractory to inhibition by p-APMSF or AT III. We conclude that a system consisting of factor X zymogen-phospholipid-factor Va can physiologically initiate blood clotting in the presence of inhibitors and may have a major role in the bypass mechanism of therapeutic prothrombin complex concentrate (PCC).