Effect of cellular and receptor activation on the extent of integrin alphaIIbbeta3 internalization

Previous studies by our laboratory demonstrated that internalization of fibrinogen-bound alphaIIbbeta3 correlated with both a loss of aggregation and a loss of bound fibrinogen from the platelet surface. However, these studies do not address whether cellular activation, receptor activation and/or receptor occupancy are responsible for the observed internalization of alphaIIbbeta3. The present studies were designed to evaluate the roles of cellular and receptor activation states on the alphaIIbbeta3 internalization process. In these studies, washed platelets were allowed to bind FITC-D57, an antialphaIIb monoclonal antibody, and were subsequently treated with ADP, thrombin receptor activation peptide (TRAP) or antiLIBS6 monoclonal antibody. Following flow cytometric analyses for log green fluorescence, rabbit antifluorescein was added, and the samples were re-analyzed for residual/unquenched fluorescence. Because access of the quenching antibody is limited to extracellular/surface-associated fluorescein, protection from quenching by antifluorescein is taken as evidence of internalization. Stimulation of platelets with ADP or TRAP resulted in a significant increase in the percent internalization of alphaIIbbeta3 compared to control (8.7% and 12.8% vs. 2.9%). Addition of cytochalasin E prior to stimulation resulted in a greater than 90% inhibition of both TRAP and ADP-induced internalization, suggesting that activation-dependent internalization is mediated by the actin cytoskeleton. To investigate whether receptor activation increases the extent of alphaIIbbeta3 internalization, platelets were treated with anti-LIBS6, which directly activates alphaIIbbeta3. Stimulation with anti-LIBS6 caused an approximate 8-fold increase in the extent of alphaIIbbeta3 internalization. To evaluate whether the activated pool of alphaIIbbeta3 is preferentially internalized, platelets were incubated with PAC-1, an antibody specific for activated alphaIIbbeta3. Platelets stimulated with TRAP, demonstrated a dose-dependent internalization of PAC-1. However, approximately 29% of total PAC-1 binding was internalized, irrespective of TRAP concentration, suggesting that a constant proportion of activated alphaIIbbeta3 is selectively internalized in platelets. Collectively, these data suggest that alphaIIbbeta3 is internalized to a greater extent in activated platelets in a cytoskeleton-dependent manner. Furthermore, the active conformer of alphaIIbbeta3 is preferentially internalized which may act as a mechanism for downregulating adhesiveness of activated platelets in the circulation.

Identification of a talin-binding site in the integrin beta(3) subunit distinct from the NPLY regulatory motif of post-ligand binding functions. The talin n-terminal head domain interacts with the membrane-proximal region of the beta(3) cytoplasmic tail

Following platelet aggregation, integrin alpha(IIb)beta(3) becomes associated with the platelet cytoskeleton. The conserved NPLY sequence represents a potential beta-turn motif in the beta(3) cytoplasmic tail and has been suggested to mediate the interaction of beta(3) integrins with talin. In the present study, we performed a double mutation (N744Q/P745A) in the integrin beta(3) subunit to test the functional significance of this beta-turn motif. Chinese hamster ovary cells were co-transfected with cDNA constructs encoding mutant beta(3) and wild type alpha(IIb). Cells expressing either wild type (A5) or mutant (D4) alpha(IIb)beta(3) adhered to fibrinogen; however, as opposed to control A5 cells, adherent D4 cells failed to spread, form focal adhesions, or initiate protein tyrosine phosphorylation. To investigate the role of the NPLY motif in talin binding, we examined the ability of the mutant alpha(IIb)beta(3) to interact with talin in a solid phase binding assay. Both wild type and mutant alpha(IIb)beta(3), purified by RGD affinity chromatography, bound to a similar extent to immobilized talin. Additionally, purified talin failed to interact with peptides containing the AKWDTANNPLYK sequence indicating that the talin binding domain in the integrin beta(3) subunit does not reside in the NPLY motif. In contrast, specific binding of talin to peptides containing the membrane-proximal HDRKEFAKFEEERARAK sequence of the beta(3) cytoplasmic tail was observed, and this interaction was blocked by a recombinant protein fragment corresponding to the 47-kDa N-terminal head domain of talin (rTalin-N). In addition, RGD affinity purified platelet alpha(IIb)beta(3) bound dose-dependently to immobilized rTalin-N, indicating that an integrin-binding site is present in the talin N-terminal head domain. Collectively, these studies demonstrate that the NPLY beta-turn motif regulates post-ligand binding functions of alpha(IIb)beta(3) in a manner independent of talin interaction. Moreover, talin was shown to bind through its N-terminal head domain to the membrane-proximal sequence of the beta(3) cytoplasmic tail.

Bidirectional transmembrane modulation of integrin alphaIIbbeta3 conformations

Activation of blood platelets by physiological stimuli (e.g. thrombin, ADP) at sites of vascular injury induces inside-out signaling, resulting in a conformational change of the prototype integrin alphaIIbbeta3 from an inactive to an active state competent to bind soluble fibrinogen. Furthermore, ligand occupancy of alphaIIbbeta3 initiates outside-in signaling and additional conformational changes of the receptor, leading to the exposure of extracellular neoepitopes termed ligand-induced binding sites (LIBS), which are recognized by anti-LIBS monoclonal antibodies. To date, the mechanism of bidirectional transmembrane signaling of alphaIIbbeta3 has not been established. In this study, using our newly developed anti-LIBScyt1 monoclonal antibody, we showed that extracellular ligand binding to alphaIIbbeta3 on blood platelets induces a transmembrane conformational change in alphaIIbbeta3, thereby exposing the LIBScyt1 epitope in the alphaIIb cytoplasmic sequence between Lys994 and Asp1003. In addition, a point mutation at this site (P998A/P999A) renders alphaIIbbeta3 constitutively active to bind extracellular ligands, resulting in fibrinogen-dependent cell-cell aggregation. Taken collectively, these results demonstrated that the extracellular ligand-binding site and a cytoplasmic LIBS epitope in integrin alphaIIbbeta3 are conformationally and functionally coupled. Such bidirectional modulation of alphaIIbbeta3 conformation across the cell membrane may play a key role in inside-out and outside-in signaling via this integrin.

Ras activation in platelets after stimulation of the thrombin receptor, thromboxane A2 receptor or protein kinase C

Several reports have indicated that the small G-protein Ras is not present immunologically in platelets. However, here we report the identification of Ras in platelets by immunoprecipitation with the Ras-specific monoclonal antibodies Y13-259 or Y13-238, followed by Western blotting. The presence of Ras was not due to contamination of samples with erythrocytes or leucocytes. Immunofluorescence studies indicated that Ras was present in a peripheral rim pattern in fixed, permeabilized platelets, suggesting an intracellular, plasma membrane location. Activation of platelets with the thrombin receptor peptide42-50, the prostaglandin H2/thromboxane A2 mimetic U46619 or phorbol 12-myristate 13-acetate induced a rapid increase in GTP-bound, activated Ras. In each case, this increase was inhibited by the protein kinase C (PKC) inhibitor bisindolylmaleimide GF 109203X, suggesting that Ras is activated downstream of PKC in platelets. Thus the activation of Ras in platelets by agonists will now allow consideration of multiple potential Ras-dependent signal transduction pathways in platelet activation processes.

Labeling of human platelet plasma membrane thromboxane A2/prostaglandin H2 receptors using SQB, a novel biotinylated receptor probe

This study reports the synthesis, biological evaluation, and application of a new biotinylated derivative 1-[[1S-[1 alpha, 2 alpha (Z),3 alpha, 4 alpha]]-7-[3-[[[[(1-oxocyclohexylpropyl)amino]acetyl]amino] methyl]-7-oxabicyclo [2.2.1]hept-2-yl]-5-heptenoyl]-2-[hexahydro-2'-oxo-1H-thieno[3',4' d] imidazole-4'-pentanoyl]hydrazine (SQB) of the thromboxane A2/prostaglandin H2 (TXA2/PGH2) receptor antagonist [1S-[1 alpha,2 alpha(Z),3 alpha,4 alpha]]-7-[3-[[[[(1-oxocyclohexylpropyl)amino]acetyl] amino]methyl]-7-oxabicyclo[2.2.1]hept-2-yl]-5-heptenoic acid (SQ31,491). SQB was synthesized by reacting SQ31,491 with biotin hydrazide, and the product was purified by flash chromatography. It was found that SQB specifically inhibited platelet aggregation in response to U46619 with an IC50 of 275 nM. On the other hand, SQB did not inhibit adenosine diphosphate or A23187-induced aggregation. Competition binding studies revealed that SQB produced a concentration-dependent inhibition of [3H]-[1S-[1 alpha, 2 beta (5Z),3 beta, 4 alpha]]-7-[3-[[2[(phenylamino) carbonyl]hydrazino]methyl]-7-oxabicyclo[2.2.1]hept-2-yl]-5-heptenoic acid ([3H]SQ29,548) specific binding in 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate (CHAPS)-solubilized platelet membranes, with a Ki of 220 nM. The shape of the SQB inhibition binding curve was indistinguishable from that produced by the TXA2/PGH2 receptor antagonist BM13.177. Finally, incubation of gel-filtered platelets or platelet-rich plasma with SQB and fluorescein isothiocyanate (FITC)-avidin demonstrated fluorescent labeling of platelet plasma membrane TXA2/PGH2 receptors. Furthermore, this SQB-FITC fluorescent labeling was reduced significantly by co-incubation of the platelets with the TXA2/PGH2 antagonist SQ29,548. Based on the ability of SQB-FITC-avidin to label intact platelets, it can be concluded: (1) that a pool of platelet TXA2/PGH2 receptors resides in the plasma membrane; and (2) that the binding domains for these receptors are oriented at or near the external membrane surface. Collectively, these data demonstrate that SQB is a highly specific probe for TXA2/PGH2 receptors, which should be of significant value for receptor localization studies in platelets and other tissues.

Internalization of bound fibrinogen modulates platelet aggregation

In agonist-stimulated platelets, the integrin alpha IIb beta 3 (glycoprotein IIb-IIIa) is converted from an inactive to an active fibrinogen receptor, thereby mediating platelet aggregation. With time after agonist addition, at least two events occur: fibrinogen becomes irreversibly bound to the platelet and, when stirring is delayed, platelets lose the ability to aggregate despite the presence of maximally bound fibrinogen. Because we previously identified an actively internalized pool of alpha IIb, beta 3 in platelets, we explored the possibility that both of these events might result from the internalization of fibrinogen bound to active alpha IIb beta 3. Under conditions of irreversible fibrinogen binding, fluorescence microscopy showed that biotinylated fibrinogen is rapidly internalized by activated platelets to a surface-inaccessible, intracellular pool. Flow cytometric analysis showed that the observed loss in accessibility to extracellular probes immediately precedes a loss in ability to the platelets to aggregate. Moreover, prevention of irreversible fibrinogen binding results in a prevention of internalization and a retention of aggregation capacity. Thus, the internalization of fibrinogen from the activated platelet surface appears to contribute not only to the irreversible phase of fibrinogen binding, but also to the downregulation of platelet adhesiveness. Fibrinogen internalization is therefore likely to represent a fundamental regulatory mechanism that modulates platelet function.

Platelet activation results in a redistribution of glycoprotein IV (CD36)

To investigate the possibility that thrombin and/or other platelet activators change the platelet surface expression of glycoprotein IV (GPIV, CD36), we used a panel of five GPIV-specific monoclonal antibodies (OKM5, 5F1, FA6-152, 8A6, and F13) directed against different epitopes. All these antibodies bound to resting platelets in a concentration-dependent and saturable manner, as determined by flow cytometry of washed platelets. Thrombin (1 U/mL) induced an approximately twofold increase in the platelet surface binding of each of these monoclonal antibodies. Immunofluorescence microscopy demonstrated an internal pool of GPIV that, after thrombin stimulation, redistributed to the platelet surface. In a whole-blood flow-cytometric assay, alpha-thrombin and the thromboxane A2 analogue U46619 each resulted in an approximately twofold increase in the platelet surface binding of OKM5, whereas ADP had a more modest effect, and collagen and epinephrine had little effect. The activation-induced up-regulation of the platelet OKM5 epitope occurred in vivo as demonstrated by flow cytometric analysis of whole blood emerging from a standardized skin puncture site. In summary, both in vitro and in vivo platelet activation results in increased platelet surface expression of GPIV, as a result of a redistribution of GPIV from an internal pool.

Immunolocalization of beta 1 integrins in platelets and platelet-derived microvesicles

Human platelets contain several adhesion receptors belonging to the integrin superfamily. At least three beta 1 integrins are present on platelets and have been shown to mediate platelet adhesion to collagen, fibronectin, and laminin. To study the cellular localization of the beta 1 integrins in platelets, we produced a polyclonal antibody by immunization of goat 172 with purified beta 1 subunit from HPB-ALL cells. Antibody 172 (Ab172) specifically immunoblotted a 135-Kd protein in a lysate of whole platelets. The reactivity of Ab172 with platelet membrane proteins was further determined by immunoprecipitation of lysates of surface-radioiodinated platelets. Ab172 immunoprecipitates, resolved by nonreducing/reducing two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis consisted of three labeled proteins with migrational properties of platelet glycoprotein (GP)Ia, GPIc and GPIIa. Neither GPIIb/IIIa nor the vitronectin receptor were immunoprecipitated by Ab172, confirming a lack of cross-reactivity with the beta 3 integrins in platelets. Immunofluorescence studies using Ab172 were performed to investigate the cellular distribution of beta 1 integrins in platelets. Fluorescent labeling of intact cells demonstrated the presence of beta 1 antigen on the surface of resting cells. Permeabilization of platelets with Triton X-100 showed the presence of an intracellular pool of beta 1 antigen. Double-label experiments using Ab172 and AP-2 (anti-GPIIb/IIIa) showed identical labeling patterns, suggesting a similar subcellular distribution for these integrins. Following thrombin stimulation, permeabilized cells showed a centralized clearing of both beta 1 antigen and GPIIb/IIIa as well as an intensification of surface labeling for beta 1 antigen. These findings suggest the translocation of intracellular beta 1 antigen to the platelet surface as a result of thrombin stimulation. Because platelet-derived microvesicles have been reported to contain GPIIb/IIIa, we investigated the possible distribution of beta 1 integrins in these structures. Microvesicles, produced as a result of platelet activation, were labeled with Ab172, suggesting the distribution of beta 1 integrins in these structures as well as in intact cells.

Arg-Gly-Asp-dependent occupancy of GPIIb/IIIa by applaggin: evidence for internalization and cycling of a platelet integrin

Using indirect immunofluorescence microscopy we examined the distribution and cycling of GPIIb/IIIa after binding to applaggin, a high-affinity Arg-Gly-Asp (RGD)--containing ligand. Resting, unfixed platelets were incubated with applaggin for 30 minutes at 37 degrees C, and bound applaggin was detected by an affinity-purified rabbit anti-applaggin antibody. Examination of intact cells showed a rim pattern for applaggin, consistent with its binding to the platelet surface. Staining of Triton X-100--permeabilized cells showed an intracellular pool of applaggin. Competition of applaggin binding by either AP-2, an anti-GPIIb/IIIa monoclonal antibody (MoAb) that blocks fibrinogen binding, or the synthetic peptide RGDW eliminated both surface and intracellular staining, indicating that applaggin is binding to GPIIb/IIIa in an RGD-dependent manner. Inhibition of platelet activation by PGE1 and theophylline had no effect on the observed staining patterns, indicating that cellular activation is not required for surface binding and subsequent internalization. To evaluate whether occupancy of functional binding sites on GPIIb/IIIa is required for internalization, we used mAb15, an anti-GPIIIa antibody that neither blocks fibrinogen binding nor induces the expression of ligand-induced binding sites on GPIIb/IIIa. In these studies mAb15 was internalized in a manner analogous to both AP-2 and applaggin, showing that occupancy of the RGD binding site is not required to initiate receptor internalization. To estimate the size of the newly internalized pool of applaggin, 125I-applaggin--binding studies were performed. Displacement of bound 125I-applaggin by excess unlabeled applaggin or EDTA showed that at least 17% of bound applaggin was nondisplaceable when binding was performed under conditions permitting membrane flow and internalization. These data indicate that GPIIb/IIIa is internalized in unstimulated platelets independent of cellular activation or occupancy of the functional binding site(s) of GPIIb/IIIa by RGD-containing ligands. Thus, internalization of GPIIb/IIIa may represent a mechanism by which the surface expression of this adhesion receptor is regulated.

Activation of calpain I and hydrolysis of calpain substrates (actin-binding protein, glycoprotein Ib, and talin) are not a function of thrombin-induced platelet aggregation

Calcium-activated neutral proteinase (calpain) has been shown to cleave proteins involved in the maintenance of cell structure. In human platelets, substrates of calpain include glycoprotein Ib (GPIb), actin-binding protein (ABP), and talin. GPIb-ABP complexes can be isolated in detergent extracts and are thought to represent membrane-cytoskeleton attachment sites. It has been hypothesized that the hydrolysis of GPIb-ABP by calpain is regulated by the extent of binding of this proteinase to the plasma membrane-cytoskeleton interface with platelet activation. Recently, another calpain substrate (talin) has been shown to redistribute from the cytoplasm to the plasma membrane-cytoskeleton interface as the result of thrombin stimulation. To investigate the intracellular distribution of calpain I, we employed the monoclonal antibody B27D8, specific for the heavy chain (catalytic subunit) of calpain I. Indirect immunofluorescent staining of resting human platelets revealed undetectable surface antigen. Permeabilization with Triton X-100, however, revealed a diffuse intracellular antigen consistent with a cytosolic distribution. To determine whether this antigen distribution reflected the proenzyme or the activated form of calpain I and to assess the degree of hydrolysis of ABP, GPIb, and talin, we employed B27D8 and murine monoclonal antibodies against ABP (1B3 and 3D1), GPIb (LJIb10), and rabbit polyclonal antibodies against talin (A2 and B11) in a quantitative immunotransblot assay. Examination of resting platelets revealed that calpain I existed as the 85-kd proenzyme form and that ABP, GPIb, and talin existed in their native intact forms. When platelets were aggregated with thrombin, autoproteolysis of calpain I occurred within the 30 seconds required to completely solubilize platelet aggregates in sodium dodecyl sulfate-containing buffer and not as a direct result of thrombin-induced activation.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of internal pools of membrane glycoproteins involved in platelet adhesive responses

To investigate the existence of intracellular pools of membrane glycoproteins involved in platelet adhesive reactions, the authors have studied the distribution of glycoprotein (GP) Ib and IIb/IIIa by immunofluorescence and immunoelectron microscopy. Studies on whole cells and frozen thick sections revealed a rim pattern of fluorescence for GPIb and GPIIb/IIIa consistent with a surface distribution. In addition, extensive staining occupying the entire cell interior was observed for anti-GPIIb/IIIa, whereas anti-GPIb revealed staining of large intracellular structures that contained no stainable fibrinogen. On the ultrastructural level, the extracellular face of the plasma membrane and the intraluminal face of vacuolar structures were stained with both anti-GPIb and anti-GPIIb/IIIa. Additionally, GPIIb/IIIa antigen was localized to alpha-granule membranes. To determine whether alpha-granule GPIIb/IIIa could be transported to the cell surface, the authors employed a calcium-dependent monoclonal anti-GPIIb/IIIa antibody. Incubation of platelets with EGTA at 37 C abolished staining of plasma membrane and vacuolar but not alpha-granule GPIIb/IIIa. Recalcification of these cells failed to restore the epitope; however, thrombin treatment of recalcified cells reconstituted surface staining with a concurrent loss of internal staining. These data suggest that GPIIb/IIIa is present in alpha-granule membranes and may be transported to the cell surface in response to thrombin treatment. In addition, both GPIb and GPIIb/IIIa antigens are present in intracellular membrane-bounded vacuolar structures which are closed to antibody probes in fixed cells. Redistribution of these internal pools of adhesive protein "receptors" may participate in the regulation of platelet adhesive properties.

Ultrastructural localization of coagulation factor V in human platelets

The distribution and transport in platelets of human coagulation Factor V was investigated by immunofluorescent and immunoelectron microscopy. In resting intact platelets, little surface staining was observed by immunofluorescence. In permeable resting cells, punctate staining similar to that reported for fibrinogen (Fbg), thrombospondin (TSP), fibronectin (Fn), von Willebrand factor (VWF), B-thromboglobulin (BTG), and platelet Factor 4 (PF4) was observed. Double label immunofluorescent staining for Fbg and Factor V demonstrated colocalization, suggesting their presence in the same intracellular structure. Thrombin stimulation induced the appearance of larger (approximately 0.5 mu) immunofluorescent masses of these proteins which exactly colocalized. Thus, at the light level, Factor V and Fbg are localized in the same structure in resting and thrombin-stimulated cells. On the ultrastructural level, an alpha granule localization for Fbg has previously been established. We have extended our immunofluorescent observations regarding the localization of Factor V in human platelets by use of transmission electron microscopy of antibody-stained ultrathin frozen sections. In resting cells, staining of virtually all alpha granules was observed for Factor V. In contrast, consistent staining was absent from other organelles including plasma membranes, mitochondria, and vacuolar structures which may represent the open canalicular system. These data thus establish at the ultrastructural level an alpha granule localization of human coagulation Factor V.

A platelet alpha granule membrane protein that is associated with the plasma membrane after activation. Characterization and subcellular localization of platelet activation-dependent granule-external membrane protein

We have identified and purified a platelet integral membrane protein (140,000 mol wt), using the KC4 monoclonal antibody specific for activated platelets, that is internal in resting platelets but exposed on activated platelets (Hsu-Lin S.-C., C.L. Berman, B.C. Furie, D. August, and B. Furie, 1984, J. Biol. Chem. 259: 9121-9126.). The expression of the protein on the platelet surface is secretion-dependent. This protein has been named platelet activation-dependent granule-external membrane (PADGEM) protein. PADGEM protein is distinct from the surface glycoproteins of resting platelets, but identical to the S12 antigen, GMP-140. Using immunofluorescent staining, resting platelets failed to stain for PADGEM protein with the KC4 antibody, but after permeabilization showed a punctate staining of the cell interior. Thrombin-stimulated intact platelets stained with a peripheral rim pattern thus demonstrating the translocation of PADGEM protein from an internal location to the cell surface. PADGEM protein expression on the platelet surface at varying thrombin concentrations correlated with alpha granule release, as measured by the secretion of platelet factor 4. Further evidence for an alpha granule localization of PADGEM protein was provided by nitrogen cavitation of resting platelets followed by metrizamide density gradient centrifugation; PADGEM protein codistributed with platelet factor 4. Using immunoelectron microscopy, the protein was localized to the alpha granule in frozen ultrathin sections of resting platelets labeled using rabbit anti-PADGEM protein antibodies, whereas in thrombin-activated platelets, the plasma membrane was labeled. These studies indicate that PADGEM protein is a component of the alpha granule membrane of resting platelets and is incorporated into the plasma membrane upon activation and secretion.

Identification and quantitation of protein S in human platelets

Gel filtered human platelets contaminated with less than 0.02% of plasma protein S contained 490 ng of protein S antigen per 3 X 10(8) platelets, equivalent to 2.5% of protein S in whole blood. Three patients with heterozygous plasma protein S deficiency, a congenital disorder associated with venous thrombotic disease, had platelet protein S antigen levels that were 40% of the mean platelet level in ten normal volunteers. In immunoblotting analysis, platelet protein S was indistinguishable from plasma protein S. Thrombin stimulation of platelets caused release of 63% of total protein S antigen and this release was abolished when platelets were preincubated with metabolic inhibitors. Thrombin effected limited proteolysis of platelet protein S and this reaction was inhibited by calcium ions. Immunofluorescent staining of platelets using protein S antibodies demonstrated that protein S colocalized with fibrinogen, an established alpha-granule protein. Thus, human platelets contain protein S in alpha granules that can be released by thrombin stimulation. The released protein S may bind to stimulated platelets and thereby promote and localize the anticoagulant activity of activated protein C on the platelet surface.

Ultrastructural localization of human platelet thrombospondin, fibrinogen, fibronectin, and von Willebrand factor in frozen thin section

We have investigated the localization of thrombospondin (TSP), fibrinogen, fibronectin, and von Willebrand factor in human platelets by transmission electron microscopy of antibody-stained ultrathin frozen sections. In negatively stained thin sections, alpha granules were identified on the basis of their smooth, roughly spherical shape, size, single limiting electron-lucent 100 A membrane, and frequent presence of electron-dense nucleoid. In contrast, mitochondria exhibited characteristic double membranes and cristae. Sections were separately stained with affinity-purified polyclonal antibodies to these proteins as well as with three monoclonal anti-TSP antibodies. Antibody specificity was documented in radioimmunoassays, by immunofluorescent cross-blocking, and by staining of bands of appropriate mobility in Western blots of whole platelets. Bound antibody was visualized using a 5-nm colloidal gold-avidin conjugate. In resting cells, staining of virtually all alpha granules was observed for all four proteins. In contrast, consistent staining was absent from other organelles, including plasma membranes, mitochondria, and vacuolar structures that may represent the open canalicular system.

ADP induced depolarization of human platelet membrane potential

The transmembrane potential of human blood platelets suspended in plasma was investigated by studying the distribution of a radiolabeled permeant ion [14C] thiocyanate. The membrane potential of resting platelets was found to be -54.50 mV +/- 9.23 S.D. with a range of -39 to -76 mV (n = 27). The possibility that platelet activation alters membrane potential or that changes in membrane potential serve as an activation trigger was investigated. Stimulation by ADP (10 microM) resulted in a significant (p less than 0.05) depolarization of the membrane potential. Preincubation with 6 mM EGTA failed to inhibit ADP-induced depolarization even though EGTA effectively prevented primary and secondary aggregation but not shape change. Preincubation with PGE1 inhibited shape change, aggregation, and the ADP-induced depolarization. No significant change in membrane potential was observed following stimulation by epinephrine (50 microM). These results suggest that the initial interaction of ADP and its receptor may involve an inward positive current which can be determined by thiocyanate distribution.

Immunofluorescent localization of adhesive glycoproteins in resting and thrombin-stimulated platelets

The distribution and transport of thrombospondin (TSP), fibrinogen (Fbg), fibronectin (Fn), and Factor VIII-related antigen (VIII:RAg) in resting and thrombin-stimulated platelets was investigated by immunofluorescence microscopy. In resting intact cells, little surface staining was seen for these proteins. In permeable resting cells, punctate staining similar to that reported for platelet factor 4 was observed. Double-label immunofluorescence staining for Fbg and either beta-thromboglobulin (beta TG), TSP, or Fn demonstrated co-localization, indicating their presence in the same intracellular structures. VIII:RAg showed general co-localization; however, the staining was finer, suggesting a possible differential intragranular localization. Thrombin stimulation induced the appearance of larger (approximately 0.5 mu) immunofluorescent masses of these proteins. In thrombin-stimulated cells, co-localization of all proteins in these masses was observed by double label immunofluorescence. Thus, TSP, Fbg, Fn, and beta TG are localized in the same structure in resting cells. Thrombin stimulates formation of common larger masses of these proteins prior to their release, suggesting that they reach the cell surface through a common intermediate.