Human Neutrophil Elastase Proteolytically Activates the Platelet Integrin alpha IIbbeta 3 through Cleavage of the Carboxyl Terminus of the alpha IIb Subunit Heavy Chain
INVOLVEMENT IN THE POTENTIATION OF PLATELET AGGREGATION*

(Received for publication, November 14, 1996, and in revised form, January 16, 1997)

Mustapha Si-Tahar Dagger §, Dominique Pidard Dagger , Viviane Balloy Dagger , Marc Moniatte par **, Nelly Kieffer Dagger Dagger §§, Alain Van Dorsselaer par ** and Michel Chignard Dagger

From the Dagger  Unité de Pharmacologie Cellulaire, Unité Associée IP/INSERM 285, Institut Pasteur, Paris, the par  Laboratoire de Spectrométrie de Masse Bioorganique, Institut de Chimie, Strasbourg, France, and the Dagger Dagger  Laboratoire Franco-Luxembourgeois de Recherche Biomédicale, Centre Universitaire, Grand-Duchy, Luxembourg

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Neutrophil elastase (NE) and cathepsin G are two serine proteinases released concomitantly by stimulated polymorphonuclear neutrophils. We previously demonstrated that while NE by itself does not activate human platelets, it strongly enhances the weak aggregation induced by a threshold concentration of cathepsin G (threshold of cathepsin G) (Renesto, P., and Chignard, M. (1993) Blood 82, 139-144). The aim of this study was to delineate the molecular mechanisms involved in this potentiation process. Two main pieces of data prompted us to focus on the activation of the platelet fibrinogen receptor, the alpha IIbbeta 3 integrin. First, previous studies have shown this integrin to be particularly prone to proteolytic regulation of its function. Second, we found that the potentiating activity of NE on the threshold of cathepsin G-induced platelet aggregation was strictly dependent on the presence of exogenous fibrinogen. Using flow cytometry analysis, NE was shown to trigger a time-dependent binding of PAC-1 and AP-5, two monoclonal antibodies specific for the activated and ligand-occupied conformers of alpha IIbbeta 3. Furthermore, the potentiated aggregation was shown to result from an increased capacity of platelets to bind fibrinogen. Indeed, the combination of NE and threshold of cathepsin G increased the binding of PAC-1 approx 5.5-fold over basal values measured on nontreated platelets, whereas this binding raised only by approx 3-fold in threshold of cathepsin G-stimulated platelets (p < 0.05). By contrast, phosphatidic acid accumulation, pleckstrin phosphorylation, and calcium mobilization produced by the combination of NE and threshold of cathepsin G were not significantly different from those measured with threshold of cathepsin G alone (p > 0.05), indicating that the phospholipase C/protein kinase C pathway is not involved in the potentiation of aggregation. The foregoing data, as well as the requirement of catalytically active NE to trigger alpha IIbbeta 3 activation and potentiate threshold of cathepsin G-initiated platelet aggregation, led us to examine whether the structure of this integrin was affected by NE. Immunoblot and flow cytometry analysis revealed a limited proteolysis of the carboxyl terminus of the alpha IIb subunit heavy chain (alpha IIbH), as judged by the disappearance of the epitope for the monoclonal antibody PMI-1. Mass spectrometry studies performed on a synthetic peptide mapping over the cleavage domain of alpha IIbH predicted the site of proteolysis as located between Val837 and Asp838. Treatment by NE of ATP-depleted platelets or Chinese hamster ovary cells expressing human recombinant alpha IIbbeta 3 clearly established that activation of the integrin was independent of signal transduction events and was concomitant with the proteolysis of alpha IIbH. In support of this latter observation, a close correlation was observed between the kinetics of proteolysis of alpha IIbH on platelets and that of expression of the ligand binding activity of alpha IIbbeta 3 (r2 = 0.902, p <=  0.005). However, only a subpopulation (approx 25%) of the proteolyzed alpha IIbbeta 3 appeared to fully express the ligand binding capacity. Altogether, these results demonstrate that NE up-regulates the fibrinogen binding activity of alpha IIbbeta 3 through a restricted proteolysis of the alpha IIb subunit, and that this process is relevant for the potentiation of platelet aggregation.


INTRODUCTION

Thrombosis and inflammation are processes which result from complex relationships between various vascular cell types, i.e. endothelial cells, leukocytes, and platelets (1, 2). As part of such a cell cooperation network, polymorphonuclear neutrophils contribute to vessel injury not only by their own, but also through interactions with platelets. Thus, neutrophils are found admixed with platelets in the core of vascular occlusions in several experimental models (1, 3), and more importantly, a neutrophil-dependent platelet deposition has been described in arterial injuries (4-6). Neutrophil-mediated platelet activation can be demonstrated in vitro by adding specific neutrophil agonists such as the formyl-Met-Leu-Phe (fMLP) peptide, tumor necrosis factor-alpha , or interleukin-8 to autologous neutrophil-platelet mixed suspensions (7-10). Cathepsin G, a serine proteinase stored in the azurophilic granules of neutrophils and released upon their stimulation, has been established as the major mediator of this cell-to-cell interaction (11-13). Acting similarly to alpha -thrombin, another serine proteinase agonist of platelets, cathepsin G-induced platelet activation results in massive exocytosis and aggregation reactions. The potent signal transduction triggered by this neutrophil proteinase includes the activation of an as yet unidentified proteinase-activated membrane receptor, and the subsequent stimulation of the phospholipase C (PLC)1/protein kinase C (PKC) and Ca2+ pathways (14-16). Another important serine proteinase released from the azurophilic granules concomitantly with cathepsin G is neutrophil elastase (NE). While NE fails to trigger platelet aggregation and exocytosis (17-19), it has been demonstrated that when cathepsin G and NE are added together at concentrations comparable to those released by fMLP-activated neutrophils, NE potentiates the capacity of platelets to aggregate in response to cathepsin G (18, 19). However, the molecular mechanism underlying this synergism remains unknown.

Platelet aggregation is primarily mediated by the binding of the bifunctional adhesive protein fibrinogen to the surface of adjacent activated platelets, and considerable evidence has established the integrin alpha IIbbeta 3 (glycoprotein IIb-IIIa) as the membrane receptor for fibrinogen, thus supporting platelet aggregation (for review, see Refs. 20-22). As all other integrin receptors (23), alpha IIbbeta 3 is made of two non-covalently associated subunits. The alpha IIb subunit is made of two disulfide-linked glycosylated polypeptide chains originating from a single precursor. The heavy chain (alpha IIbH, relative molecular mass, Mr approx  126,000) is entirely extracellular, whereas the light chain (alpha IIbL, Mr approx  23,000) contains a single transmembrane domain. The beta 3 subunit (Mr approx  110,000) is made of one glycosylated polypeptide chain with a single transmembrane domain, and presents a complex pattern of intramolecular disulfide bonds within its large extracellular domain (20). Although alpha IIbbeta 3 is constitutively expressed on the platelet plasma membrane, the receptor normally acquires its capacity to bind fibrinogen only upon platelet activation. An inside-out signaling process is likely responsible for converting this integrin from a low-affinity to a high-affinity membrane receptor for fibrinogen, through conformational modifications of its extracellular domains (21, 22). During platelet exocytosis, translocation to the plasma membrane of the fraction of alpha IIbbeta 3 complexes associated with the internal alpha -granules (24) is another mean for increasing the capacity of activated platelets to bind fibrinogen (25). Finally, an alternative pathway for activation of alpha IIbbeta 3 at the surface of platelets could be a proteolytic modification of the extracellular regions of this receptor. Thus, exposure of platelets to pancreatic or leukocyte elastases (26, 27) or to alpha -chymotrypsin (28-30) has been reported to induce the irreversible expression of fibrinogen-binding sites in the absence of intracellular activation.

In view of these data, and considering the potential physiopathological importance of the process, the aim of the present study was to delineate the molecular mechanism(s) involved in the potentiation exerted by NE on cathepsin G-induced platelet aggregation. For this purpose, we considered both the possible involvement of intracellular signaling pathways, and the changes in the structure and biological activity of the alpha IIbbeta 3 integrin brought about by NE alone or in combination with cathepsin G.


MATERIALS AND METHODS

Antibodies and Reagents

Except for the monoclonal antibody PAC-1, which was provided by the University Cell Center of Pennsylvania (Philadelphia, PA), the murine monoclonal and rabbit polyclonal domain-specific anti-alpha IIbbeta 3 antibodies used in this study and listed in Table I were obtained from the Scripps Research Institute (La Jolla, CA): PMI-1 and the polyclonal antiserum raised against the peptide V41 (designated anti-V41) were kindly supplied by Dr. M. H. Ginsberg, AP-2 and AP-5 were generous gifts from Dr. T. J. Kunicki, and the polyclonal antiserum IIb-10 was kindly provided by Dr. S. E. D'Souza. Rabbit polyclonal antisera against purified SDS-denaturated whole alpha IIb or beta 3 (designated as anti-alpha IIb and anti-beta 3) have been previously described and characterized (30). Negative control IgG or IgM isotype antibodies were from Sigma and DAKO (Glostrup, Denmark), respectively. Fluorescein isothiocyanate-conjugated anti-IgG or anti-IgM were obtained from DAKO and Sigma, respectively. Reagents for SDS-PAGE were from Bio-Rad. Nitrocellulose membranes (0.45 µm pores) were from Schleicher and Schuell (Dassel, Germany). Affinity-purified staphylococcal 125I-Protein A and carrier-free sodium [125I]iodide were from Amersham International plc (Little Chalfont, United Kingdom). The PKC inhibitor GF 109203X was a kind gift from Dr. J. Kirilovsky (Laboratoire Glaxo-Wellcome, Les Ulis, France). This compound was dissolved in Me2SO (which final concentration in platelets was less than 0.5%, v/v). Eglin C was generously provided by Dr. H. P. Schnebli (Ciba-Geigy Research, Basel, Switzerland). Blood was obtained from the Centre National de Transfusion Sanguine (Paris, France). Fibrinogen (Grade L) was purchased from Kabi (Stockolm, Sweden) and treated with diisopropyl fluorophosphate to inactivate coagulant contaminants and subsequently dialyzed to remove the free inhibitor. N-Succinyl-(Ala)2-Pro-Phe-p-nitroanilide (a cathepsin G substrate), N-succinyl-(Ala)3-p-nitroanilide (a NE substrate), 2-deoxy-D-glucose, sodium azide (NaN3), glucono-delta -lactone, the proteinase inhibitors phenylmethylsulfonyl fluoride (PMSF), benzamidine, leupeptin, soybean trypsin inhibitor and aprotinin were from Sigma. Iscove's buffer was from BioWhittaker (Belgium). The peptide FPQPPVNPLKVDWGL (using the single-letter code for amino acids), corresponding to the sequence 827-841 of the alpha IIb subunit heavy chain, was synthesized by Neosystem Laboratoire (Strasbourg, France). All other reagents were obtained as indicated in Si-Tahar et al. (16).

Table I.

Domain-specific alpha IIbbeta 3 antibodies used in this study


Name Mono/polyclonal Isotype Specificity on alpha IIbbeta 3 Refs.

PAC-1 Monoclonal IgM RGDa-binding site 31
AP-2 Monoclonal IgG1 Complexed form of alpha IIb and beta 3 32
AP-5 Monoclonal IgG1 LIBSb on the amino terminus of beta 3 33
PMI-1 Monoclonal IgG1 LIBS on the carboxyl terminus of alpha IIbHc 34
IIb-10 Polyclonal Amino terminus of alpha IIbH 30
Anti-V41 Polyclonal Amino terminus of alpha IIbLc 34

a RGD, Arg-Gly-Asp adhesion motif present in fibrinogen (20).
b LIBS, ligand-induced binding site.
c alpha IIbH, alpha IIbL, extracellular heavy chain and transmembrane light chain, respectively, of the alpha IIb subunit.

Purification of Neutrophil Cathepsin G and NE

Cathepsin G and NE were purified as described previously (16), using a two-step chromatographic procedure (aprotinin-Sepharose affinity and CM-Trisacryl ion-exchange). The purity of the neutrophil proteinases was assessed by SDS-PAGE. Moreover, it was verified that cathepsin G and NE preparations were devoid of each others proteinase by monitoring spectrophotometrically the hydrolysis of N-succinyl-(Ala)2-Pro-Phe-p-nitroanilide and N-succinyl-(Ala)3-p-nitroanilide induced by purified NE and cathepsin G, respectively. For the determination of their active site concentrations, a constant amount of the enzymes were reacted in the presence of increasing amounts of titrated alpha 1-antitrypsin and extrapolation of the concentrations were performed using linear regression analysis.

To block the catalytic site of NE, the purified proteinase (70 µM) was incubated for 60 min at 25 °C with PMSF (1.25 mM), and the mixture was subsequently dialyzed to remove the free inhibitor. PMSF-treated NE was shown to be proteolytically inactive by testing the lack of hydrolysis of its specific synthetic substrate.

Preparation and Labeling of Platelets

Blood was obtained from healthy adult volunteers without any medication. The platelet-rich plasma was isolated by centrifugation of blood at 180 × g for 20 min and incubated with 5-[14C]HT (0.05 mCi/ml) for 30 min at 37 °C. For protein phosphorylation and phospholipid metabolism studies, platelets were labeled with [32P]phosphoric acid as described previously (16). Then, labeled platelets were washed by two successive centrifugations (1,600 × g, 10 min) and resuspended in Tyrode's buffer (composition, mM: NaCl, 137.0; KCl, 2.68; NaHCO3, 11.9; NaH2PO4, 0.42; CaCl2, 2.0; MgCl2, 1.0; glucose, 5.5; Hepes, 5.0; and bovine serum albumin, 0.35%, pH 7.4) supplemented with PGI2 (0.25 µM) and heparin (50 units/ml). Before the last centrifugation, the platelet pellet was resuspended in the same buffer without heparin. The final pellet was resuspended in Tyrode's buffer such that the final platelet concentration was 4 × 108/ml. The entire procedure was performed at 37 °C and isolated platelets were maintained at this temperature until use.

Generation of Stable CHO Cells Expressing Human alpha IIbbeta 3 (CHO/alpha IIbbeta 3)

The full-length cDNA encoding wild type human alpha IIb (35) or human beta 3 (36) were inserted into the pBJ1 expression vector and cotransfected into CHO dhfr(neg) cells as described previously (37). Briefly, 20 µg of each alpha IIb and beta 3 cDNA and 2 µg of dihydrofolate reductase plasmid (pMDR901) were mixed with 40 µg of LipofectAMINE in a final volume of 200 µl and added to the cells. After a 48-h incubation of the cells in Iscove's medium supplemented with 10% heat-inactivated fetal calf serum, the cells were grown in nucleoside-free alpha -minimal essential medium supplemented with 10% dialyzed fetal calf serum, used as selective medium. Positive transfectants were selected for cell surface expression of recombinant alpha IIbbeta 3 using the complex specific anti-alpha IIbbeta 3 monoclonal antibody AP-2 (32) and goat anti-mouse IgG-coated immunomagnetic beads. Cells were further grown to confluence in T75 or T25 flasks in Iscove's buffer supplemented with glutamine, penicillin, streptomycin, and 10% fetal calf serum, and routinely passaged after detachment using EDTA buffer (composition, mM: NaCl, 126; KCl, 5; EDTA, 10; HEPES, 50, pH 7.4).

Aggregation and Secretion Measurements

Platelet aggregation in 0.5-ml aliquots (4 × 108 platelets/ml) was recorded at 37 °C using a Dual Aggro-Meter (Chrono-Log Corp., Havertown, PA) under constant stirring (1,100 rpm). Samples were preincubated with imipramine (1 µM) to prevent the re-uptake of released 5-[14C]HT and with fibrinogen (0.7 mg/ml) for 2 min before stimulation. Activation was initiated by addition of cathepsin G, NE, or a threshold concentration of cathepsin G (threshold of cathepsin G) preceded by NE for 10 s, and the variations in light transmission were continuously recorded. The 5-[14C]HT- or 32P-labeled platelets were transferred to tubes containing 125 µl of a stopping solution made of 77 mM EDTA, 155 mM NaCl, 33% formaldehyde (1:9:8, v/v), or 1.8 ml of ice-cold chloroform, methanol, 12 M HCl, 0.1 M EDTA (20:40:1:2, v/v), respectively, to terminate the reaction. Supernatants containing released 5-[14C]HT were mixed with scintillation fluid for measuring radioactivity. Aggregation was expressed as the percent of changes in light transmission and the 5-[14C]HT release was expressed as the percent of total 5-[14C]HT platelet content.

Protein Phosphorylation and Polyphosphoinositide Metabolism

Chloroform/distillated water (0.5 volume of each) was added to 32P-labeled platelets diluted in the stopping organic solution (see above). This suspension was vigorously shaken and centrifuged for 10 min at 10 °C. The upper aqueous phase was discarded. Proteins, concentrated at the interface, were solubilized according to the procedure of Laemmli (38). Radiolabeled proteins were then subjected to SDS-PAGE using a 12.5% resolving gel and a 5% stacking gel. After staining, dried gels were exposed to a Molecular Dynamics (MD; Evry, France) PhosphorImaging screen. Concurrently, the lower chloroformic phase was evaporated, washed according to Jolles et al. (39), and resuspended in chloroform. Phosphoinositides and phosphatidic acid (PtdOH) were separated by thin layer chromatography using chloroform/acetone/methanol/acetic acid/water (40:15:13:12:7, v/v) as the migration solvent. Upon drying, the chromatography plates were also exposed to a PhosphorImaging screen. PLC and PKC activities were evaluated by quantifying the radioactive signals associated to PtdOH and pleckstrin, respectively, using an MD PhosphorImager coupled to the ImageQuant software (version 3.3).

Calcium Flux Measurements

Platelets were prepared as described above with slight modifications. Following the resuspension in Tyrode's buffer supplemented with prostacyclin and heparin, platelets were incubated for 30 min at 37 °C with 3 µM Fura 2-acetoxymethylester, washed, and the final platelet concentration was adjusted to 4 × 108/ml in Tyrode's buffer. The basal fluorescence of a 1-ml aliquot of cell suspensions was monitored under stirring with a spectrofluorimeter Jobin Yvon JY 3D (Paris, France) thermostatted at 37 °C. Fluorescence excitation and emission wavelengths were 340 and 510 nm, respectively. Platelets preincubated for 2 min were challenged with cathepsin G, NE, or combinations of both proteinases, and the changes in fluorescence were recorded for 2 min.

Flow Cytometry Analysis

Analysis of Washed Platelets

Cell samples were treated as for platelet aggregation analysis, except for those used to analyze the binding of PAC-1, for which exogenous fibrinogen was omitted as this natural ligand of the activated alpha IIbbeta 3 may competitively inhibit the binding of PAC-1 (31). In any case, once the agonist has been added, the stirring was allowed for only 5 s to homogenize the milieu, then samples were incubated undisturbed for different periods of time at 37 °C to prevent platelet aggregate formation, which would interfere with the flow cytometry analysis. The reaction was stopped by the addition of 5 µM eglin C, an inhibitor of cathepsin G and NE (40) and 2 mM PMSF. Platelets were then immediately fixed with 1% (v/v) formaldehyde for 30 min at room temperature. Following the fixation, all samples were diluted 10-fold in Tyrode's buffer and then incubated for 30 min at 4 °C with saturating concentrations of purified PAC-1 (2 µg/ml), AP-2 (1 µg/ml), PMI-1 (5 µg/ml), AP-5 ascitic fluid (diluted 1/1000), or with nonimmune IgG or IgM as control isotypes. Incubations were done in conical bottom 96-well plastic plates with 4 × 106 cells/well. After centrifugation of the plates at 80 × g for 10 min at 4 °C, platelets were washed twice in Tyrode's buffer and incubated for 30 min at 4 °C with the corresponding second fluorescein isothiocyanate-labeled antibody at optimal concentration. Finally, platelets were centrifuged as above, resuspended in the same buffer, and stored at 4 °C in the dark until flow cytometric assays were performed within the next 24 h. It is of note that when platelets were to be tested for the expression of the PMI-1 epitope, they were first incubated with the proteinase, then with 5 mM EDTA for 15 min at room temperature to maximally expose the PMI-1 epitope (41), before to be fixed and processed as described above.

Analysis of CHO/alpha IIbbeta 3 Cells

Cells were harvested from culture flasks using EDTA buffer and washed once in Iscove's buffer without fetal calf serum and then in Tyrode's buffer. The final pellet was resuspended in this latter buffer such that the final concentration was 107 cells/ml. Then, cells were incubated for 3 min at 37 °C with 400 nM NE or 550 nM cathepsin G under gentle shaking. The reaction was stopped and part of the cells further fixed with 1% (v/v) formaldehyde, whereas nonfixed cells were used for immunoblot analysis (see below). Next, 106 fixed CHO/alpha IIbbeta 3 cells were processed for PAC-1 or AP-2 or control isotype antibodies binding as described for platelets.

In all cases, samples were analyzed using a FACScan flow cytometer (Becton Dickinson Immunocytometry System, Mountain View, CA). Binding of the different domain-specific anti-alpha IIbbeta 3 antibodies to their epitopes is expressed as the fold increase in median fluorescence intensity over basal values measured on nontreated cells, following subtraction of the background binding measured with the control isotypes.

Binding of 125I-Labeled Monoclonal Antibodies

The monoclonal antibodies PMI-1 and AP-5 were purified to homogeneity from ascitic fluids by conventional Protein A- or Protein G-Sepharose chromatography, and labeled with 125I to a specific activity of approx 4.5 × 104 becquerels/µg of IgG using the chloramine T procedure (32, 41). Platelets were exposed to NE (400 nM) in an aggregometer cuvette for increasing periods of time (up to 3 min), and the proteinase was blocked by addition of eglin C and PMSF as for flow cytometry analysis. Control platelet suspensions were treated similarly except that NE was absent. Platelets were immediately distributed (final concentration, 2 × 108/ml) in a Tyrode's medium containing either divalent cations or EDTA (final concentration, 3 mM), and either one of the 125I-labeled antibodies. Incubations were performed at room temperature for 45 min, and platelet-bound antibodies were separated from unbound by layering triplicate 50-µl aliquots of the cell suspensions on 0.5 ml of 20% sucrose made in Tyrode's medium, and centrifugation for 5 min at 14,000 × g. The supernatant and sucrose were aspirated, and the platelet pellets at the bottom of the tube cut and counted for 125I in a 1282 Compugamma CS counter (LKB Wallac, Turku, Finland). Binding of 125I-AP-5 on NE-treated platelets, which reflected fibrinogen binding to the activated alpha IIbbeta 3 integrin (33), was performed in the presence of divalent cations. Under similar conditions, binding to control nontreated platelets was negligible, as previously reported (33), and increased linearly as a constant fraction (0.7%) of the antibody input. This was taken as nonspecific binding. Maximal binding of 125I-AP-5 was measured in the presence of EDTA (33) and found to saturate at 25 µg/ml IgG; this concentration was used throughout all subsequent experiments. Binding of 125I-PMI-1 on NE-treated platelets, which measured the proteolysis of the alpha IIbbeta 3 integrin (see "Results"), was performed in the presence of EDTA, to maximize the exposure of the PMI-1 epitope on the platelet surface (41). In preliminary experiments, the nonspecific binding was measured in the presence of a 50-fold excess of unlabeled antibody, and found to represent a constant fraction (0.25%) of the antibody input. Maximal binding of 125I-PMI-1 was measured on control platelets in the presence of EDTA and found to saturate at 250 µg/ml IgG; this concentration was used throughout all subsequent experiments. Isotherm binding of increasing amounts of 125I-labeled antibodies to nontreated or NE-treated platelets for 1 min showed that the KD of each antibody for its epitope was unchanged following proteolysis of alpha IIbbeta 3 (data not shown). All data are reported as specific binding, i.e. total binding corrected for the nonspecific as defined above.

SDS-PAGE and Immunoblot Analysis

At the end of the exposure of platelets to proteinases in the aggregometer cuvettes, and after addition of eglin C and PMSF to block the enzymatic activity of cathepsin G and/or NE, 200 µl of platelet suspensions were rapidly centrifuged at 12,000 × g for 4 min. The supernatant was carefully removed and the platelet pellets were resuspended in the initial volume with 10 mM Tris/HCl, 150 mM NaCl, 3 mM EDTA, pH 6.8, and cells were solubilized by addition of a one-fifth volume of 12% (w/v) SDS and 30 mM N-ethylmaleimide in 10 mM Tris/HCl, pH 6.8, and heated at 100 °C for 5 min. SDS-PAGE was performed according to the procedure of Laemmli (38). When needed, disulfide bonds were reduced prior to electrophoresis by adding 5% (v/v) 2-mercaptoethanol to the samples. For CHO/alpha IIbbeta 3 cells solubilization, 1-3 × 106 nonfixed cells pretreated or not with NE or cathepsin G as described above were centrifuged for 4 min at 12,000 × g. After discarding the supernatant, the cell pellets were resuspended at 107 cells/ml in a lysis medium (final concentrations, mM: Tris, 10; NaCl, 150; EDTA, 3; N-ethylmaleimide, 5; PMSF, 1; benzamidine, 5; leupeptin, 0.1; soybean trypsin inhibitor, 0.0014, pH 7.4) to which 10% (v/v) Triton X-100 was added for a final concentration of 1%. Protein extraction was performed at 4 °C for 30 min with occasional vortexing, then the extract cleared from cells debris and nucleus by a 15-min centrifugation at 12,000 × g at 4 °C. The supernatant was then solubilized with SDS-N-ethylmaleimide, and the extract processed for SDS-PAGE.

Electrophoresis was performed after loading each well on gels with 10 or 20 µg of total platelet or CHO/alpha IIbbeta 3 cell proteins, respectively; then proteins were transferred to nitrocellulose membranes and probed by immunoblotting using specific antibodies exactly as described previously (30), and as specified in the figure legends. Bound antibodies were detected following incubation of the membranes with 125I-Protein A (diluted 1/1000) and autoradiography on Kodak X-Omat MA or AR films (Kodak-Pathé, Paris, France) for various periods of time (0.25 to 4 days). For Mr determinations, polyacrylamide gels were calibrated using standard proteins with Mr in the range 200,000 to 14,400.

Matrix-assisted Laser Desorption/Ionization-Time of Flight (MALDI-TOF) Analysis

The site of cleavage by NE was searched by MALDI-TOF mass spectrometry on a 15-mer peptide, designated peptide 827-841, corresponding to the amino acid sequence Phe827-Leu841 of the alpha IIbH subunit (35). Enzymatic digestion assay was performed at 37 °C with NE at a final concentration of 400 nM and the peptide 827-841 at 525 µM in 200 mM Tris acetate, pH 7.4. Following different incubation periods, a 1-µl aliquot was withdrawn from the reaction medium and diluted in 0.1% aqueous trifluoroacetic acid, a solution that quenches the enzyme reaction by lowering the pH to approx 3. The stability of the substrate in the absence of NE was assessed under the same conditions. The diluted medium was then submitted to MALDI-TOF measurement. Samples were prepared as follows: 1 µl of a 4-alpha -cyano-4-hydroxy-trans-cinnamic acid was deposited on a stainless steel probe and allowed to evaporate quickly. About 0.5 µl of the dilute digest solution was then deposited on the matrix surface and allowed to air dry. At last, the sample was washed according to Vorm et al. (42) with 0.5% aqueous trifluoroacetic acid. Mass spectra were obtained using a Bruker Biflex MALDI-TOF mass spectrometer (Bremen, Germany). The average error on the MALDI-TOF derived mass is theoretically 0.1%, i.e. 1.7 Da in our mass range. However, the difference between the experimental mass and the calculated average isotopic mass of our peptide was usually less than 0.5 Da. Hence, the sequence of the peptide(s) resulting from cleavage by NE could be unambiguously derived from their masses. The instrument was calibrated prior to each measurement with the monoprotonated molecular ions from a standard mixture of angiotensin II, ACTH 18-39, and bovine insulin. The sequences of the proteolytic fragments were predicted using the MacProMass 1.2 software (Beckman Research Institute, Duarte, CA) on the basis of the known sequence of the initial peptide and the determined molecular masses of the fragment(s).

Statistics

Results are expressed as mean ± S.E. for the indicated number of independently performed experiments. Statistical significance between the different values was analyzed by Student's t-test for unpaired data with a threshold of p <=  0.05. The standard linear regression analysis was applied to correlate the different parameters using the Statview 512+ software (BrainPower Inc., Calabasas, CA).


RESULTS

Characteristics of the Potentiation by NE of Cathepsin G-induced Platelet Activation

As previously established (11, 16), cathepsin G alone added to platelet suspensions at the optimal concentration of 550 nM acts as a strong platelet agonist inducing extensive platelet aggregation (83.5 ± 5.6%, n = 5), accompanied by a marked exocytosis of intracellular granules as judged by the release of 5-[14C]HT from dense granules (76.2 ± 1.6%, n = 5; Fig. 1, panels A and B). For each tested platelet suspension, we determined the threshold of cathepsin G as that resulted in platelet shape change followed by 5-10% of increase in light transmission within 3 min of stirring (Fig. 1, panels A and B). This concentration was always within the range 150 to 180 nM. Under these conditions, exocytosis remained minimal at 3 min, with 3.1 ± 0.8% of 5-[14C]HT release (n = 5; Fig. 1, panel B).


Fig. 1. Characteristics of the potentiation by NE of platelet activation induced by cathepsin G. Washed human 5-[14C]HT-labeled platelets (0.5 ml, 4 × 108 cells/ml) stirred at 37 °C were preincubated for 2 min with 1 µM imipramine. Reaction with proteinases were then followed for 3 min. Panel A, tracings of platelet aggregation in the presence of exogenous fibrinogen (0.7 mg/ml) after challenge with 550 nM cathepsin G, an optimal concentration of NE (400 nM), a threshold concentration of cathepsin G (thCat G, 150-180 nM), or threshold of cathepsin G preceded by 400 nM NE for 10 s. Panel B, platelet aggregation and 5-[14C]HT secretion performed under identical conditions, except that the potentiation was evaluated with increasing concentrations of NE. Results are expressed as the percentage of maximal light transmission and as the percentage of the total 5-[14C]HT granule content, respectively, and are means ± S.E. of five experiments conducted with cells from different donors. Panel C, a representative tracing of three distinct experiments of aggregation initiated by the combination of NE and threshold of cathepsin G in the absence of exogenous fibrinogen.
[View Larger Version of this Image (45K GIF file)]


Platelet suspensions stirred for 3 min with 400 nM NE (and up to 800 nM) showed no evidence for aggregate formation (Fig. 1, panel A) and exocytosis of internal granules was barely detectable (0.8 ± 0.3% release of 5-[14C]HT, n = 5), in agreement with previous reports (17-19). By contrast, addition of 400 nM NE 10 s before stimulation of platelets with threshold of cathepsin G resulted in an extensive aggregation, similar to that induced by the optimal concentration of cathepsin G (Fig. 1, panels A and B). The potentiation exerted by NE on threshold of cathepsin G-induced platelet aggregation was already detectable with 100 nM NE, and was maximal in the range 200-800 nM NE (Fig. 1, panel B). Increasing the period of exposure of platelets to NE to 180 s before threshold of cathepsin G had no further effect on the extent of potentiation (not shown and Ref. 18).

Major observations in these experiments were that (i) whereas aggregation induced by 550 nM cathepsin G was associated with an extensive granule exocytosis, the aggregation induced by the combination of 100-800 nM NE with threshold of cathepsin G was accompanied by a limited release of granule contents, varying from 4.7 ± 1.4% to a maximum of 25.9 ± 0.9% secretion of 5-[14C]HT (n = 5; Fig. 1, panel B); and (ii) the potentiating activity of NE on threshold of cathepsin G-induced platelet aggregation was strictly dependent on the presence of exogenous fibrinogen (Fig. 1, panels A and C).

Activation of the Platelet Fibrinogen Receptor by NE and Cathepsin G

Previous reports have shown that platelet exposure to various serine proteinases, including elastases, induces expression of fibrinogen binding sites (26, 27). This, together with the requirement for exogenous fibrinogen for the potentiation of platelet aggregation (the present work) led us to consider that the synergism resulting from the combination of NE and threshold of cathepsin G could be exerted at the level of the alpha IIbbeta 3 integrin, the platelet fibrinogen receptor. We first evaluated whether NE could modify by itself the surface expression and the biological activity of alpha IIbbeta 3 on platelets by using flow cytometry analysis with a panel of monoclonal antibodies specific for distinct conformations of this integrin (see Table I). These included AP-2, an alpha IIbbeta 3 complex-specific antibody reacting with both the resting and active forms of the receptor (32), PAC-1, which binds at one fibrinogen-binding site on alpha IIbbeta 3 and only recognizes the active conformation of the receptor (31), and AP-5, an anti-ligand-induced binding site (LIBS) which specifically reveals the active and fibrinogen-occupied integrin (33). As mentioned under "Materials and Methods," when platelets were to be tested with PAC-1, prior incubation with NE was without exogenous fibrinogen, while analysis of the binding of AP-5 was necessarily performed on platelets incubated in the presence of fibrinogen.

As illustrated in Fig. 2, exposure of platelet suspensions to 400 nM NE at 37 °C, a concentration which triggers a maximal potentiation of threshold of cathepsin G-induced platelet aggregation, resulted in a rapid transition of the alpha IIbbeta 3 conformation reflecting activation of the receptor and binding of its ligand. Indeed, a time-dependent increase in binding of PAC-1 occurred within 10 s of exposure to NE, and reached a plateau after 1 min (panel A). A similar increase in the binding of AP-5 was observed, with a plateau after 2 min of exposure to NE (panel B). At 3 min, binding of PAC-1 and AP-5 on NE-treated platelets was increased about 2.3-fold (n = 8, p < 0.001) and 3.4-fold (n = 4, p < 0.05), respectively, compared with nontreated platelets. However, binding of these antibodies on NE-treated platelets was approximately 3.5-fold lower than that measured on platelets optimally stimulated with 550 nM cathepsin G (compare panels A and C, and B and D). Such a difference can be largely explained by the ability of a high concentration of cathepsin G to induce platelet shape change and extensive exocytosis of alpha -granules (43), thus allowing the translocation of the internal fraction of alpha IIbbeta 3 complexes to the plasma membrane (25). Indeed, binding of AP-2 to platelets activated with 550 nM cathepsin G for 3 min was increased by 92.7 ± 16.8% when compared with nontreated platelets (n = 7, p < 0.001; see Fig. 3, panel B), an increase similar to that measured on platelets activated with 0.5 IU/ml thrombin (98.9 ± 9.2%, n = 8, p < 0.001). By contrast, the increase in AP-2 binding to platelets exposed to 400 nM NE was only 9.6 ± 5.0% and remained nonsignificant (n = 8, p > 0.05; see Fig. 3, panel B).


Fig. 2. Activation of the platelet fibrinogen receptor by NE and cathepsin G. Unstirred platelets were preincubated in the absence (panels A and C) or presence (panels B and D) of exogenous fibrinogen (0.7 mg/ml) to analyze PAC-1 or AP-5 antibodies binding, respectively. Reactions were initiated by adding 400 nM NE (panels A and B) or 550 nM cathepsin G (panels C and D) and stopped at different times with 5 µM eglin C and 2 mM PMSF. Binding of PAC-1 and AP-5 to platelets were then measured by flow cytometry and are expressed as the fold-increase in median fluorescence intensity over basal values measured on nontreated platelets. Results are means ± S.E. of four to eight experiments conducted with cells from different donors.
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Fig. 3. Involvement of the activation of alpha IIbbeta 3 by NE in the potentiation of threshold of cathepsin G-induced platelet activation. Unstirred platelets were incubated in the absence of exogenous fibrinogen. Reactions were initiated by adding 400 nM NE, threshold of cathepsin G (150-180 nM) alone or in combination with NE, or 550 nM cathepsin G. Reactions were followed for 3 min and stopped with eglin C and PMSF. Bindings of PAC-1 (panel A) and AP-2 (panel B) measured by flow cytometry are expressed as the fold increase in median fluorescence intensity over basal values measured on nontreated platelets. Results are means ± S.E. of three experiments conducted with cells from different donors. thCat.G, threshold of concentration of cathepsin G.
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Involvement of the Activation of alpha IIbbeta 3 by NE in the Potentiation of Threshold of Cathepsin G-induced Platelet Aggregation

Considering that NE is able to up-regulate the biological activity of the plasma membrane alpha IIbbeta 3 integrin, we assumed that the potentiation by NE of platelet aggregation induced by threshold of cathepsin G resulted from an increased capacity of the platelet surface to bind fibrinogen. To examine this hypothesis, platelet suspensions were challenged for 3 min with 400 nM NE, threshold of cathepsin G, or a combination of both proteinases, before being processed for analysis of AP-2 and PAC-1 binding by flow cytometry, the latter antibody being taken as a fibrinogen-like probe. Thus, combination of the two proteinases increased the binding of PAC-1 approx 5.5-fold, while activation of platelets with 550 nM cathepsin G increased PAC-1 binding approx 7.5-fold, these values being not statistically different (p > 0.05, n = 3). By contrast, the increase in PAC-1 binding induced at 3 min by threshold of cathepsin G alone was approx 3-fold above the background binding measured for nontreated platelets, a value similar to that measured for NE-treated platelets in this series of experiments (p > 0.05; Fig. 3, panel A). Of note is that PAC-1 binding to platelets activated with either threshold of cathepsin G alone or with the combination of NE and threshold of cathepsin G was significantly different (p < 0.05, n = 3). When platelet suspensions were similarly treated in the presence of exogenous fibrinogen, then evaluated for the binding of AP-5 as a marker of ligand-occupied alpha IIbbeta 3, similar profiles were obtained (not illustrated). Strikingly, the strong potentiating effect of NE on threshold of cathepsin G-induced platelet aggregation occurred despite a limited expression of the internal alpha IIbbeta 3 fraction at the plasma membrane, as measured by the binding of AP-2 which was identical to that initiated by threshold of cathepsin G alone (approx 1.3-fold increase over basal value under both conditions, p > 0.05; Fig. 3, panel B).

Role of the Platelet Intracellular Signaling in the Potentiation Induced by the Combination of NE and Cathepsin G

The enhanced exposure of fibrinogen-binding sites induced by NE could be potentially explained by the ability of this proteinase to enhance intracellular signals by which cathepsin G normally initiates platelet activation and thus up-regulates the activity of alpha IIbbeta 3. It has been demonstrated (14-16) that the interrelated elements of the PLC-Ca2+-PKC pathway act in concert to mediate such a cell response. Thus, as indicated in Fig. 4, an optimal concentration of cathepsin G (550 nM) triggered extensive activation of the PLC and PKC pathways, as measured through PtdOH accumulation (panel A) and phosphorylation of pleckstrin, a 47-kDa protein (P47) which is the main substrate for PKC in platelets (44) (panel B). As expected, activation of PLC and PKC was accompanied by a massive increase in cytosolic Ca2+ (panel C). By contrast, activation of platelets with threshold of cathepsin G resulted in a detectable but limited metabolic activation compared with 550 nM cathepsin G. On the other hand, exposure of platelets to NE alone at concentrations up to 800 nM failed to initiate PLC or PKC activities or intracellular Ca2+ movements. Finally, and more importantly, stimulation of platelets with the combination of 400 nM NE and threshold of cathepsin G resulted in an activation which was not different with that produced by threshold of cathepsin G alone (values of fold-increase over basal signals were 2.25 ± 0.25 and 2.63 ± 0.14 (n = 4) for PtdOH accumulation, respectively, and 1.26 ± 0.05 and 1.24 ± 0.02 (n = 4) for P47 phosphorylation, respectively). Furthermore, we determined that the activation of alpha IIbbeta 3 by NE was not blocked by substances known to prevent platelet activation. Table II shows that pretreatment of platelets with GF 109203X, a specific PKC inhibitor (45), or with PGI2, a potent activator of platelet adenylate cyclase and inhibitor of alpha IIbbeta 3 metabolic activation (46), had no inhibitory effect on the capacity of 400 nM NE to activate alpha IIbbeta 3, as evaluated by the binding of PAC-1. By contrast, and as expected, both GF 109203X and PGI2 were potent inhibitors of the expression of activated alpha IIbbeta 3 on the surface of platelets stimulated with 0.5 IU/ml thrombin (45, 46). Altogether, these data clearly indicate that the potentiating effect of NE on threshold of cathepsin G-induced platelet aggregation is not related to an increased intracellular signaling involving the PLC, PKC, and Ca2+ components.


Fig. 4. Lack of involvement of the platelet intracellular signaling in the potentiation induced by NE. Platelets labeled with 32P (0.5 ml, 4 × 108 cells/ml) or loaded with Fura 2 (1 ml, 4 × 108 cells/ml) were preincubated in the presence of exogenous fibrinogen and stimulated for 3 min as indicated in the legend to Fig. 1. Results are expressed as the fold increase of the radioactivity associated with PtdOH (Panel A) or P47 (Panel B) in treated platelets over basal values measured on nontreated cells. Data are means ± S.E. of four experiments conducted with platelets from different donors. The variations in fluorescence reflecting changes of intracellular Ca2+ concentrations were monitored for 2 min (panel C). Tracings are representative of two distinct experiments performed in duplicate. thCat. G, threshold of concentration of cathepsin G.
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Table II.

Effect of drugs on NE- and thrombin-induced expression of the activated alpha IIbbeta 3 conformer

GF 109203X and PGI2 were preincubated with platelets at 37 °C for 30 s and for 2 min, respectively, before stimulation with the proteinases for 3 min. PAC-1 binding analysis was performed as described in the legend to Fig. 2 and is expressed as the percentage of the control median fluorescence intensity measured in NE- or thrombin-stimulated platelets in the absence of drugs. Results are mean ± S.E. of the indicated number of experiments conducted with cells from different donors.


Drug NE (400 nM) Thrombin (0.5 IU/ml)

GF 109203X (7.5 µM) 114.9  ± 11.0% (n = 3) 28.7  ± 5.5% (n = 3)
PGI2 (10 µM) 124.6  ± 8.7% (n = 4) 23.8  ± 1.9% (n = 5)

Effects of NE on the Structure of alpha IIbbeta 3

A major feature in our study was that PMSF-inactivated NE was totally unable to either up-regulate the activity of alpha IIbbeta 3 as measured by the binding of PAC-1 (2.3 ± 0.2- versus 1.1 ± 0.1-fold increase (n = 3) over basal values with intact and PMSF-treated NE, respectively), or to potentiate cathepsin G-induced platelet aggregation (not shown and Ref. 19), indicating that the proteolytic activity of NE is required for both processes. This, together with the known susceptibility of alpha IIbbeta 3 to proteolysis by serine proteinases (26-30) and the absence of intracellular metabolic activation by NE (see above), prompted us to examine whether the integrin structure was affected by this proteinase under our experimental conditions.

Panel A in Fig. 5 illustrates the analysis of the beta 3 and alpha IIb subunits separated on 7-12% gradient acrylamide gels following reduction of intra- or interchain disulfide bonds, and probed with polyclonal rabbit antisera raised against each of the whole subunit. When compared with nontreated control platelets (lane 1), platelets exposed to 400 nM NE for 3 min (lane 2) showed no proteolytic modification of the beta 3 subunit (Mr approx  118,000), whose mobility and intensity remained unchanged. Only longer exposure (15 min) to 400 nM NE, or to higher concentrations of proteinase (1.2 µM) resulted in the appearance of a minor membrane-associated fragment of beta 3 with Mr approx  66,000 (not shown and Ref. 27). Under the conditions of electrophoresis used in this experiment, the alpha IIb subunit could be clearly resolved into its two heavy and light polypeptide chains (alpha IIbH, Mr approx  126,000, and alpha IIbL, Mr approx 25,000). alpha IIbL appeared to be unchanged for both its mobility and intensity in NE-treated platelets. By contrast, the alpha IIbH subunit migrated as a broader band in platelets exposed to NE (lane 2), as compared with nontreated platelets (lane 1), with a component (indicated by the open arrowhead in Fig. 5, panel A) running slightly ahead of the intact alpha IIbH.


Fig. 5. Immunoblot analysis of alpha IIb and beta 3 subunits in platelets treated by NE alone or in combination with threshold of cathepsin G. Platelet samples were incubated in the presence of exogenous fibrinogen, as indicated in the legend to Fig. 1, and untreated (lanes 1) or treated with 400 nM NE alone (lanes 2) or in combination with threshold of cathepsin G (lanes 3). Reactions were followed for 3 min and then stopped with eglin C and PMSF, and platelets were immediately sedimented and solubilized with SDS. Disulfides bonds were either unreduced (panel C) or reduced (panels A and B) with 2-mercaptoethanol prior to electrophoresis. After SDS-PAGE on 7-12% (panel A) or 5% (panel B and C) acrylamide gels and transfer to nitrocellulose membranes, platelet proteins were probed with polyclonal antisera against the alpha IIb or beta 3 subunit (diluted 1/1000), the polyclonal antiserum IIb-10 (diluted 1/100), the monoclonal PMI-1 (10 µg/ml) followed by a polyclonal rabbit anti-mouse IgG (10 µg/ml), or the polyclonal anti-V41 antiserum (diluted 1/200). Bound antibodies were revealed by incubation with 125I-Protein A (diluted 1/1000) followed by autoradiography. Molecular masses were calculated with respect to calibration standard proteins included in each gel. alpha IIbHf and alpha IIbf represent the membrane-associated proteolytic fragments of alpha IIbH and alpha IIb, respectively.
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More detailed immunoblot analysis of the alpha IIbH subunit was performed following reduced SDS-PAGE on highly resolutive 5% acrylamide gels, using a panel of domain-specific alpha IIb antibodies (see Table I). As illustrated in panel B of Fig. 5, the anti-alpha IIb polyclonal antiserum clearly identified two molecular species in NE-treated platelets (lane 2), showing approximately equal intensity, one corresponding to the intact alpha IIbH (Mr approx  128,000) as seen in control untreated platelets (lane 1), and the second to a membrane-bound proteolytic fragment with Mr approx  123,000, designated alpha IIbHf. On several platelet samples exposed to NE under identical conditions, the mean Mr difference between alpha IIbH and alpha IIbHf was 6,470 ± 290 (n = 15). Considering that alpha IIbH is entirely extracellular, such a limited proteolysis must have occurred at one or both extremities of the polypeptide chain. The polyclonal rabbit antiserum IIb-10, recognizing the alpha IIbH amino-terminal Leu1-Pro14 sequence (30), reacted equally with the intact alpha IIbH and the alpha IIbHf fragment. By contrast, the murine monoclonal antibody PMI-1, which recognizes the alpha IIbH carboxyl-terminal Pro844-Arg856 sequence (34), was reactive with the residual intact alpha IIbH in NE-treated platelets, but totally unreactive with alpha IIbHf (Fig. 5, panel B). To ascertain that proteolysis was limited to alpha IIbH, similar experiments were performed on unreduced samples (Fig. 5, panel C). Here, the anti-alpha IIb antiserum identified the native alpha IIb subunit (i.e. disulfide-linked alpha IIbH and alpha IIbL) in nontreated samples with Mr approx  143,000 (lane 1). With NE-treated platelets (lane 2), a second component could be distinguished slightly ahead of intact alpha IIb. This component, designated alpha IIbf, had Mr approx  137,000. The alpha IIb light chain within the alpha IIbf membrane-bound proteolytic species was shown to have an intact amino terminus by the normal reactivity of alpha IIbf with the anti-V41 polyclonal antiserum, which recognizes the amino-terminal Gln860-Arg871 sequence of alpha IIbL (34).

Similar immunoblot analysis was further performed on SDS lysates of platelets treated for 3 min with the combination of 400 nM NE and threshold of cathepsin G (lanes 3 in Fig. 5). Results were strictly identical to those obtained with platelets treated with 400 nM NE alone. In addition, we previously demonstrated that high concentrations of cathepsin G alone have no proteolytic effect on the alpha IIbbeta 3 integrin (47). Taken together, these data indicate that under optimal conditions of potentiation by NE of threshold of cathepsin G-initiated aggregation, NE specifically proteolyzes a short domain located at the carboxyl terminus of the alpha IIbH polypeptide chain.

Since the above data pointed to the existence of a specific and previously unreported modification of alpha IIbbeta 3 by NE, we sought to confirm that it occurred to a significant extent at the surface of platelets. Platelet suspensions were thus exposed to 400 nM NE for increasing periods of time (up to 3 min) and analyzed by flow cytometry to quantitate the binding of the monoclonal antibody PMI-1 (this being taken as a marker of proteolysis at the alpha IIbH carboxyl terminus) since the PMI-1 epitope should be lost upon exposure to NE. Results indicated a near complete disappearance of the PMI-1 epitope on NE-treated platelets, with a binding after 3 min of proteolysis decreased by 93 ± 4% (n = 5) compared with the initial value measured on untreated platelets (data not illustrated).

Localization of the Cleavage Site(s) for NE within the alpha IIbH Carboxyl Terminus

Considering the domain of alpha IIb proteolyzed by NE (see above), the relative Mr difference measured between alpha IIbH and alpha IIbHf (approx 6,500), and the fact that in resting platelets, the epitope recognized by PMI-1 is largely cryptic (41), the site(s) of cleavage by NE were searched by MALDI-TOF mass spectrometry on a peptide corresponding to the sequence Phe827-Leu841 of alpha IIbH. Indeed, this sequence maps from the carboxyl-terminal side of Cys826, which is involved in the linkage of alpha IIbH to alpha IIbL (20), to the amino-terminal side of the PMI-1 epitope (34) (Fig. 6, panel B). The lower tracing in panel A of Fig. 6 shows a mass spectrum which corresponds to the initial undigested peptide 827-841, with a mass of 1708.0 Da. Upon a 5-min incubation of this peptide with 400 nM NE (upper tracing in panel A of Fig. 6), a single new peptide was generated with a mass of 1236.8 Da, corresponding to the sequence Phe827-Val837. This indicates a proteolysis of the initial peptide at a unique bond, between Val837 and Asp838. Of note is that the cleavage was detectable as soon as 30 s and was complete at 10 min, without detection of other proteolytic products (not shown). The shorter tetrapeptide fragment Asp838-Leu841 could not be detected under our experimental conditions.


Fig. 6. Localization of the cleavage site for NE within the carboxyl terminus of the alpha IIb subunit heavy chain. Panel A, MALDI-TOF mass spectra of the peptide 827-841, corresponding to the amino acid sequence Phe827 to Leu841 of the alpha IIbH subunit. Lower and upper tracings are mass spectra of the untreated peptide and of peptides obtained after a 5-min digestion by NE at 37 °C, pH 7.4, respectively (m/z, observed mass/charge). Tracings are representative of two distinct experiments performed in duplicate. Panel B, location of the deduced cleavage site by NE (indicated by a vertical arrow) in the alpha IIbH carboxyl terminus. Epitopes of the PMI-1 and anti-V41 antibodies within the alpha IIb subunit are also indicated. The shaded circle at Ser847 represents an O-linked oligosaccharide (20).
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Relationship between Cleavage of the alpha IIb Subunit Heavy Chain by NE and Activation of alpha IIbbeta 3

When bindings of both PMI-1 and AP-5 were examined by flow cytometry on the same platelet samples treated by NE, a relationship was observed between the time course of proteolysis of the alpha IIbH subunit (i.e. the decreasing binding of PMI-1) and that of the ligand binding capacity of alpha IIbbeta 3 (i.e. the increasing binding of AP-5) (data not shown). To further support this inference and to exclude an activation of the integrin resulting from NE acting on another membrane structure inducing signaling which may feed-back to alpha IIbbeta 3, two series of experiments were carried out. First, platelets were depleted in cytosolic ATP by incubation for 15 min with 50 mM 2-deoxy-D-glucose, 0.05% NaN3, and 10 mM glucono-delta -lactone to inhibit glycolysis, oxidative phosphorylations, and glycogen phosphorylase, respectively (48). These platelets were treated or not with 400 nM NE or 550 nM cathepsin G for 3 min, and PAC-1 binding was examined by flow cytometry as an index of alpha IIbbeta 3 activation. Results showed that while NE-induced activation of the fibrinogen receptor remained unchanged (p > 0.05, n = 3), that produced through intracellular pathways by cathepsin G (see Fig. 4) was inhibited by 73.8 ± 1.0% (p < 0.001, n = 3). Second, CHO cells expressing human alpha IIbbeta 3 were used as it is known that these cells do not support agonist-induced metabolic activation of this integrin (49). Fig. 7 indicates that treatment of CHO/alpha IIbbeta 3 cells with NE resulted in a 4.2 ± 0.7-fold increase over basal value for PAC-1 binding (n = 2). This was specific to NE since incubation of these cells with 550 nM cathepsin G did not trigger any increase in PAC-1 binding. Moreover, this process did not result from an increase of alpha IIbbeta 3 molecules expression at the surface of CHO/alpha IIbbeta 3 cells as values for AP-2 binding were unchanged compared with nontreated cells. Importantly, in both cases (i.e. platelets pretreated with metabolic inhibitors and CHO/alpha IIbbeta 3 cells), activation of alpha IIbbeta 3 by NE was accompanied by an extensive proteolysis of alpha IIbH (Fig. 7).


Fig. 7. Specific proteolytic activation by NE of alpha IIbbeta 3 integrin expressed in CHO transfected cells. CHO/alpha IIbbeta 3 cells were incubated under gentle shaking with 400 nM NE, 550 nM cathepsin G (Cat. G), or without proteinases (resting) for 3 min. Reactions were stopped by addition of eglin C and PMSF. From aliquots of a single cell sample, both PAC-1 and AP-2 antibodies binding (lower panel) and structure of the alpha IIbH subunit (upper panel) were analyzed by flow cytometry and SDS-PAGE coupled to immunoblot, respectively. Of note is that pro-alpha IIb represents the intracellular immature alpha IIb subunit (35). As in Fig. 5, alpha IIbHf corresponds to the NE proteolytic fragment of alpha IIbH.
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We thus further examined whether cleavage of the alpha IIbH subunit by NE quantitatively correlates with the activation of alpha IIbbeta 3. Direct binding of 125I-AP-5 and 125I-PMI-1 antibodies allowed quantitative measurements of the number of NE-activated and occupied alpha IIbbeta 3 molecules in relation to the number of proteolyzed molecules, respectively. Panel A in Fig. 8 shows that the maximal number of binding sites for 125I-PMI-1 on control nontreated platelets (27,270 ± 5,360 molecules/platelet, n = 3) progressively decreased upon exposure of cells to NE, to be reduced at 3 min by 96 ± 3%. Panel B demonstrates that, on a time course basis, the proteolysis of the carboxyl-terminal domain of alpha IIbH correlates linearly with the increased capacity of alpha IIbbeta 3 to bind exogenous fibrinogen (r2 = 0.902, p <=  0.005). In this series of experiments, the maximal binding of 125I-AP-5 (measured in the presence of EDTA) on nontreated as well as NE-treated platelets amounted to 18,250 ± 770 molecules/platelet (n = 3), whereas the specific binding measured in the presence of divalent cations and fibrinogen on platelets treated with NE for 3 min amounted to 4,270 ± 760 molecules/platelet, i.e. 23 ± 3.6% of the maximal AP-5 binding capacity of platelets. These data suggest that not all proteolyzed alpha IIbbeta 3 molecules acquire the capacity to bind a ligand, and that the stoichiometry is about one active integrin over four proteolyzed.


Fig. 8. Relationship between cleavage by NE of the alpha IIb subunit heavy chain and activation of the alpha IIbbeta 3 integrin. Platelets were incubated with exogenous fibrinogen as described in the legend to Fig. 2. Reactions were initiated by adding 400 nM NE for increasing periods of time and stopped with eglin C and PMSF. From aliquots of a single platelet sample, specific bindings of 125I-PMI-1 and 125I-AP-5 were measured as described under "Materials and Methods," and are expressed as the number of IgG molecules bound per platelet. Binding of 125I-PMI-1 was measured in the presence of EDTA to maximize epitope expression, while binding of 125I-AP-5 was measured in the presence of divalent cations. Panel A depicts the time-dependent disappearance of the PMI-1 epitope and panel B represents the same data plotted versus the exposure of the AP-5 epitope. Results are means ± S.E. of three experiments conducted with cells from different donors.
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DISCUSSION

The aim of the present investigation was to characterize the molecular mechanism underlying the synergistic activation of platelets by the neutrophil-derived proteinases elastase and cathepsin G. The major findings are as follows: (i) NE does not activate the platelet intracellular signaling but specifically cleaves the alpha IIb subunit heavy chain of the alpha IIbbeta 3 integrin, likely between Val837 and Asp838; (ii) this proteolysis correlates with an up-regulation of the fibrinogen receptor function of this integrin; and (iii) this particular activation of alpha IIbbeta 3 by NE is relevant for the potentiation of platelet aggregation initiated by low concentrations of cathepsin G.

The alpha IIbbeta 3 integrin has been shown to undergo variations in affinity for fibrinogen that reflect conformational changes within the alpha IIb and beta 3 subunits (20-22). Since cathepsin G stimulates platelets as potently as does thrombin and through a common signaling pathway (14-16, 50), it may be speculated that the mechanism which regulates the fibrinogen-binding function is similar for both proteinases. In thrombin-activated platelets, an intracellular signal transduction pathway, including heterotrimeric GTP-binding proteins, PLC, PKC, PI 3-kinase, low molecular weight GTP-binding proteins and the cytoskeleton, affects the cytoplasmic domains of alpha IIbbeta 3 and influence the conformation of the extracellular domains (inside-out signaling) (22, 51). Hence, cathepsin G-induced activation of the alpha IIbbeta 3 integrin (the present study and Ref. 43 and 50) is likely controlled by this complex network of intracellular signaling reactions. In addition to that exposed on the cell surface, alpha IIbbeta 3 has been identified in an internal membrane compartment made of the surface-connected canalicular system and the alpha -granules (24). Compared with resting platelets, the density of alpha IIbbeta 3 on the platelet plasma membrane increases after strong stimulation, due to the mobilization of these intracellular stores (25). This is confirmed in the present work for a maximal concentration of cathepsin G (550 nM) using AP-2, a monoclonal antibody that recognizes a complex-dependent determinant on alpha IIbbeta 3, whose binding doubles under these conditions, in agreement with previous findings (50).

Other serine proteinases have been shown to induce the activation of alpha IIbbeta 3, but through a nonmetabolic pathway. Thus, treatment of platelets with chymotrypsin (28-30) or elastases (26, 27) results in a proteolytic-dependent exposure of fibrinogen-binding sites at the platelet surface. In accordance with these studies, measurements of the binding of PAC-1 and AP-5 antibodies allowed us to demonstrate that NE rapidly induces the high affinity and ligand-occupied conformers of native alpha IIbbeta 3. Unlike cathepsin G or thrombin, this was not accompanied by an increase of the number of alpha IIbbeta 3 expressed on the platelet surface. Another difference with cathepsin G or thrombin is that the up-regulation of alpha IIbbeta 3 by NE occurs even in the presence of the potent inhibitor of platelet activation PGI2 or after the metabolic pool of ATP has been depleted. A similar stimulation of fibrinogen binding at the platelet surface, independent of PGI2-inhibitable pathways, has been observed following incubation of platelets with Fab fragments of certain anti-LIBS antibodies (52). It was hypothesized that these activating antibodies shift a conformational balance to favor or stabililize the high affinity of alpha IIbbeta 3 for fibrinogen. With regard to NE, its potential binding to the integrin might also displace a structural equilibrium as do anti-LIBS antibodies. However, our data rather indicate that the conformational shift which uncovers binding site(s) for fibrinogen is associated with a proteolytic processing. Indeed, the blockade of NE catalytic site by PMSF suppressed the activation of alpha IIbbeta 3. Actually, immunoblot analysis as well as the measurement of the binding capacity of platelets for PMI-1 antibody, revealed a limited proteolysis by NE of the alpha IIb subunit heavy chain carboxyl terminus. Furthermore, kinetics of this cleavage closely correlated with that of the expression of the ligand binding activity. It is of note, however, that these two events occur in a stoichiometry of about four alpha IIbbeta 3 molecules proteolyzed for one molecule activated. Taken together, these data mean that NE cleaves almost all the alpha IIbbeta 3 complexes expressed at the platelet plasma membrane, but only a fraction (approx 25%) of them shift from an inactive to an active conformer. This observation is actually consistent with studies which have brought evidence for the existence of distinct subpopulations of alpha IIbbeta 3 at the platelet surface, showing distinct conformations and/or susceptibility to acquire an activated state (52-54). Interestingly, this functional heterogeneity appears intrinsic to the alpha IIbbeta 3 molecules. Thus, after purification of the total platelet integrin, at least two conformers can be identified, one inactive but still activable, and one "naturally" active following solubilization (approx 20% of the total, based on data reported in Ref. 54). The mechanism through which a fraction of the platelet alpha IIbbeta 3 molecules resists the activation shift remains to be determined. Finally, that NE activates alpha IIbbeta 3 directly through proteolysis was confirmed using CHO cells transfected with human alpha IIbbeta 3, knowing that the integrin expressed in these cells is unable to respond to metabolic activation (49). All these data concur to exlude that NE acts on another membrane protein which may secondary stimulate alpha IIbbeta 3.

MALDI-TOF mass spectrometry performed on the synthetic peptide corresponding to the sequence Phe827-Leu841 of alpha IIbH gave an insight into the site of NE-induced proteolysis by indicating a cleavage located between Val837 and Asp838. This finding is in agreement with the primary specificity of NE for valine residues (55). As a result of this cleavage by NE within the alpha IIbH carboxyl terminus, a peptide of 19 amino acids, i.e. Asp838-Arg856, including an O-glycosylated serine residue at position 847 (20) (see Fig. 6), is expected to be released. The difference in Mr found in SDS-PAGE between alpha IIbH and its membrane-bound proteolytic derivative (approx 6,500) is in fair agreement with the presumed mass of such a glycopeptide. A mechanism by which this restricted cleavage can modulate global conformational changes within the whole alpha IIbbeta 3 integrin can be hypothesized on the basis of different structural models of this integrin (see Fig. 9). From the model proposed by Honda et al. (33), it can be suggested that the alpha IIb domain proteolyzed by NE is located in a structurally constrained cluster of cryptic LIBS epitopes including PMI-1 (alpha IIbH 842-856), AP-5 (beta 3 1-6), LIBS-2 (beta 3 602-690), and an undefined region in beta 3 interacting with the PMI-2 antibody. On the other hand, studies aimed to localize the alpha IIb sequences involved in the intrasubunit contacts have suggested that alpha IIbH would be folded on itself, notably through interactions between its amino-terminal and carboxyl-terminal domains (56). Therefore, it may be speculated that through limited proteolysis of the carboxyl-terminal end of the alpha IIbH subunit, NE removes a constraint in a confined but particularly sensitive region. The generated conformational change may then propagate over the whole alpha IIbbeta 3 complex (57), converting a subpopulation of the integrin molecules from a resting to an active fibrinogen receptor.


Fig. 9. Schematic model of the activation by NE of the alpha IIbbeta 3 integrin through proteolysis of the alpha IIb subunit. In the resting conformer, the ligand-binding pocket of alpha IIbbeta 3 is not accessible to ligands such as fibrinogen or the PAC-1 antibody (represented by a hatched box). Based on previous structural models (33, 54), the carboxyl terminus domain of the alpha IIb subunit heavy chain proteolyzed by NE could be located in a cluster of cryptic LIBS epitopes (indicated by bold lines) including PMI-1 below the cleavage site. The cleavage induced by NE would remove a constraint in this region, converting the integrin from a resting to an active conformer and releasing the 19-mer glycopeptide Asp838-Arg856. Following occupancy of the activated alpha IIbbeta 3, further conformational change(s) on the integrin would expose the LIBS epitopes.
[View Larger Version of this Image (35K GIF file)]


While the PLC/PKC pathway controls the synergism resulting from combination of low concentrations of platelet agonists such as thrombin and epinephrine (58), it does not account for the enhanced activation of alpha IIbbeta 3 and platelet aggregation induced by the combination of NE and cathepsin G (see Fig. 4). As one consequence, it can be ruled out that this process occurs through an increase by NE of the catalytic activity of cathepsin G, or an increase of cathepsin G receptor expression and/or affinity, which would have resulted in an increase of intracellular signaling messengers. In fact, on the basis of the foregoing data, and notably those showing the activation by NE of surface-expressed alpha IIbbeta 3, a hypothetical mechanism may be proposed to construe how NE enhances the platelet aggregation initiated by low concentrations of cathepsin G. During this process, cathepsin G would initiate different intracellular transduction signals, including the PLC-Ca2+-PKC pathway, with as one result, a basal metabolic activation of alpha IIbbeta 3, however, insufficient to promote stable aggregate formation. In parallel, NE would trigger a proteolysis of the carboxyl terminus of the alpha IIb subunit heavy chain with the subsequent spatial reorientation of the extracellular domains within the alpha IIb and beta 3 subunits allowing increased binding of fibrinogen. As more fibrinogen binds and cross-links adjacent platelets, post-occupancy outside-in signaling events through alpha IIbbeta 3 may amplify cell activation (51), and finally maximize the recruitment of platelets into aggregates similar to those produced by high concentrations of strong platelet agonists acting through a solely intracellular signaling pathway. Consistent with this proposal, it is of interest to note that the potentiating effect of NE is not restricted to cathepsin G, as NE can also enhance platelet aggregation initiated by low concentrations of collagen or the thromboxane A2 stable analog U46619 (not shown and Ref. 19).

Numerous studies suggest that platelet activation in vivo could be attributed to the combined action of pairs (or more) of agonists (58, 59). The potentiation by NE of cathepsin G-induced platelet activation reported in the present work might be relevant in physiopathological situations in which both platelets and neutrophils can locally accumulate and physically interact such at sites of inflammatory or thrombotic lesions (4-6). In connection with these studies, it is tempting to speculate that proteinase-induced enhancement of adhesive receptor function could be a wide and physiologically relevant process. Indeed, like the proteolysis-dependent activation of alpha IIbbeta 3 by NE described here, a recent study provided evidence that serine proteinases proteolytically enhance cell adhesion mediated by the integrin alpha Vbeta 3 (60).


FOOTNOTES

*   The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§   Supported by grants from the Ministère de la Recherche et de l'Enseignement Supérieur and the Association pour la Recherche sur le Cancer (ARC), France. To whom correspondence should be addressed: Unité de Pharmacologie Cellulaire, Unité associée IP/INSERM 285, Institut Pasteur, 25, rue du Dr Roux, F-75015, Paris, France. Tel.: 33-1-45-68-86-88; Fax: 33-1-45-68-87-03; E-mail: msitahar{at}pasteur.fr.
   Supported by the Centre National de la Recherche Scientifique.
**   Supported by BioAvenir (Rhône-Poulenc Santé), France.
§§   Supported by the Centre de Recherche Public-Santé, Luxembourg, by the Centre National de la Recherche Scientifique, France, and by the EC Biomed Grant CT 931685.
1   The abbreviations used are: PLC, phospholipase C; NE, neutrophil elastase; threshold of cathepsin G, threshold concentration of cathepsin G; PKC, protein kinase C; P47, pleckstrin; MALDI-TOF, matrix-assisted laser desorption/ionization-time of flight; LIBS, ligand-induced binding site; CHO, Chinese hamster ovary; PAGE, polyacrylamide gel electrophoresis; PMSF, phenylmethylsulfonyl fluoride; PGI2, prostaglandin I2; PtdOH, phosphatidic acid; 5-HT, 5-hydroxytryptamine.

ACKNOWLEDGEMENTS

We thank Dr. Mark H. Ginsberg, Dr. Thomas J. Kunicki, and Dr. Stanley E. D'Souza, from the Scripps Research Institute (La Jolla, CA), for kindly providing antibodies essential for this project. We are indebted to Jean-Charles Théodet for his participation in the early steps of this study. We also thank Dr. Juan J. Calvete (Institut für Reproduktionsmedizin, Hannover, Germany) for helpful comments during these investigations.


REFERENCES

  1. Cerletti, C., Evangelista, V., Molino, M., and de Gaetano, G. (1995) Thromb. Haemostasis 74, 218-223 [Medline] [Order article via Infotrieve]
  2. Marcus, A. J., Safier, L. B., Broekman, M. J., Islam, N., Fliessbach, J. H., Hajjar, K. A., Kaminski, W. E., Jendraschak, E., Silverstein, R. L., and von Schacky, C. (1995) Thromb. Haemostasis 74, 213-217 [Medline] [Order article via Infotrieve]
  3. Del Maschio, A., Dejana, E., and Bazzoni, G. (1993) Ann. Hematol. 67, 23-31 [Medline] [Order article via Infotrieve]
  4. Issekutz, A. C., Ripley, M., and Jackson, J. R. (1983) Lab. Invest. 49, 716-724 [Medline] [Order article via Infotrieve]
  5. Bednar, M., Smith, B., Pinto, A., and Mullane, K. M. (1985) J. Cardiovasc. Pharmacol. 5, 906-912
  6. Mehri, Y., Lacoste, L.-L., and Lam, Y. T. (1994) Circulation 90, 997-1002 [Abstract]
  7. Chignard, M., Selak, M. A., and Smith, J. B. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 8609-8613 [Abstract]
  8. Del Maschio, A., Evangelista, V., Rajtar, G., Min Chen, Z., Cerletti, C., and de Gaetano, G. (1990) Am. J. Physiol. 258, H870-H879 [Abstract/Free Full Text]
  9. Renesto, P., and Chignard, M. (1991) J. Immunol. 7, 2305-2309
  10. Si-Tahar, M., Renesto, P., Balloy, V., and Chignard, M. (1994) Eur. Cytokine Netw. 5, 455-460 [Medline] [Order article via Infotrieve]
  11. Selak, M. A., Chignard, M., and Smith, J. B. (1988) Biochem. J. 251, 293-299 [Medline] [Order article via Infotrieve]
  12. Ferrer-Lopez, P., Renesto, P., Shattner, M., Bassot, S., Laurent, P., and Chignard, M. (1990) Am. J. Physiol. 258, C1100-C1107 [Abstract/Free Full Text]
  13. Evangelista, V., Piccardoni, P., White, J. G., de Gaetano, G., and Cerletti, C. (1993) Blood 81, 2947-2957 [Abstract]
  14. Molino, M., Di Lallo, M., de Gaetano, G., and Cerletti, C. (1992) Biochem. J. 288, 741-745 [Medline] [Order article via Infotrieve]
  15. Selak, M. A. (1993) Platelets 4, 85-89
  16. Si-Tahar, M., Renesto, P., Falet, H., Rendu, F., and Chignard, M. (1996) Biochem. J. 313, 401-408 [Medline] [Order article via Infotrieve]
  17. Bykowska, K., Kaczanowska, J., Karpowicz, M., Stachurska, J., and Kopec, M. (1983) Thromb. Haemostasis 50, 768-772 [Medline] [Order article via Infotrieve]
  18. Selak, M. A. (1992) Thromb. Haemostasis 68, 570-576 [Medline] [Order article via Infotrieve]
  19. Renesto, P., and Chignard, M. (1993) Blood 82, 139-144 [Abstract]
  20. Calvete, J. J. (1994) Thromb. Haemostasis 72, 1-15 [Medline] [Order article via Infotrieve]
  21. Ginsberg, M. H., Du, X., O'Toole, T. E., and Loftus, J. C. (1995) Thromb. Haemostasis 74, 352-359 [Medline] [Order article via Infotrieve]
  22. Stuiver, I., and O'Toole, T. E. (1995) Stem Cells 13, 250-262 [Abstract]
  23. Hynes, R. O. (1992) Cell 69, 11-25 [Medline] [Order article via Infotrieve]
  24. Wencel-Drake, J. D., Plow, E. F., Kunicki, T. J., Woods, V. L., Keller, D. M., and Ginsberg, M. H. (1986) Am. J. Pathol. 124, 324-334 [Abstract]
  25. Niiya, K., Hodson, E., Bader, R., Byers-Ward, V., Koziol, J. A., Plow, E. F., and Ruggeri, Z. M. (1987) Blood 70, 475-483 [Abstract]
  26. Kornecki, E., Ehrlich, Y. H., De Mars, D. D., and Lenox, R. H. (1986) J. Clin. Invest. 77, 750-756 [Medline] [Order article via Infotrieve]
  27. Kornecki, E., Ehrlich, Y. H., Egbring, R., Gramse, M., Seitz, R., Eckardt, A., Lukasiewicz, H., and Niewiarowski, S. (1988) Am. J. Physiol. 255, H651-H658 [Abstract/Free Full Text]
  28. Kornecki, E., Tuszynski, G. P., and Niewiarowski, S. (1983) J. Biol. Chem. 258, 9349-9356 [Abstract/Free Full Text]
  29. Peerschke, E., and Coller, B. S. (1984) Blood 64, 59-63 [Abstract]
  30. Pidard, D., Frelinger, A. L., Bouillot, C., and Nurden, A. T. (1991) Eur. J. Biochem. 200, 437-447 [Abstract]
  31. Taub, R., Gould, R. J., Garsky, V. M., Ciccarone, T. M., Hoxie, J., Friedman, P. A., and Shattil, S. J. (1989) J. Biol. Chem. 264, 259-265 [Abstract/Free Full Text]
  32. Pidard, D., Montgomery, R. R., Bennett, J. S., and Kunicki, T. J. (1983) J. Biol. Chem. 258, 12582-12586 [Abstract/Free Full Text]
  33. Honda, S., Tomiyama, Y., Pelletier, A. J., Annis, D., Honda, Y., Orchelowski, R., Ruggeri, Z., and Kunicki, T. J. (1995) J. Biol. Chem. 270, 11947-11954 [Abstract/Free Full Text]
  34. Loftus, J. C., Plow, E. F., Frelinger, A. L., III, D'Souza, S. E., Dixon, D., Lacy, J., Sorge, J., and Ginsberg, M. H. (1987) Proc. Natl. Acad. Sci. U. S. A. 840, 7114-7118
  35. Poncz, M., Eisman, R., Heidenreich, R., Silver, S. M., Vilaire, G., Surrey, S., Schwartz, E., and Bennett, J. S. (1987) J. Biol. Chem. 262, 8476-8482 [Abstract/Free Full Text]
  36. Fitzgerald, L. A., Steiner, B., Rall, S. C., Jr., Lo, S., and Phillips, D. R. (1987) J. Biol. Chem. 262, 3936-3939 [Abstract/Free Full Text]
  37. Kieffer, N., Melchior, C., Guinet, J. M., Michels, S., Gouon, V., and Bron, N. (1996) Cell Adhes. Comm. 4, 25-39 [Medline] [Order article via Infotrieve]
  38. Laemmli, U. K. (1970) Nature 227, 680-685 [Medline] [Order article via Infotrieve]
  39. Jolles, J., Zwiers, H., Dekker, A., Wirtz, K. W. A., and Gispen, W. H. (1981) Biochem. J. 194, 283-291 [Medline] [Order article via Infotrieve]
  40. Renesto, P., Ferrer-Lopez, P., and Chignard, M. (1990) Lab. Invest. 62, 409-416 [Medline] [Order article via Infotrieve]
  41. Frelinger, A. L., III, Lam, S. C.-T., Plow, E. F., Smith, M. A., Loftus, J. C., and Ginsberg, M. H. (1988) J. Biol. Chem. 263, 12397-12402 [Abstract/Free Full Text]
  42. Vorm, O., and Roepstorff, P. (1994) Biol. Mass Spectrom. 23, 734-740 [Medline] [Order article via Infotrieve]
  43. LaRosa, C. A., Rohrer, M. J., Benoit, S. E., Rodino, L. J., Barnard, M. R., and Michelson, A. D. (1994) J. Vasc. Surg. 19, 306-319 [Medline] [Order article via Infotrieve]
  44. Nishizuka, Y. (1984) Nature 308, 693-698 [Medline] [Order article via Infotrieve]
  45. Toullec, D., Pianetti, P., Coste, H., Bellevergue, P., Grand-Perret, T., Ajakane, M., Baudet, V., Boissin, P., Boursier, E., Loriolle, F., Duhamel, L., Charon, D., and Kirilovsky, J. (1991) J. Biol. Chem. 266, 15771-15781 [Abstract/Free Full Text]
  46. Graber, S. E., and Hawiger, J. (1982) J. Biol. Chem. 257, 14606-14609 [Abstract/Free Full Text]
  47. Pidard, D., Renesto, P., Berndt, M. C., Rabhi, S., Clemetson, K. J., and Chignard, M. (1994) Biochem. J. 303, 489-498 [Medline] [Order article via Infotrieve]
  48. Verhoeven, A. J. M., Mommersteeg, M. E., and Akkerman, J. W. N. (1985) J. Biol. Chem. 260, 2621-2624 [Abstract]
  49. O'Toole, T. E., Loftus, J. C., Du, X., Glass, A. A., Ruggeri, Z. M., Shattil, S. J., Plow, E. F., and Ginsberg, M. H. (1990) Cell Regul. 1, 883-893 [Medline] [Order article via Infotrieve]
  50. Molino, M., Di Lallo, M., Martelli, N., de Gaetano, G., and Cerletti, C. (1993) Blood 82, 2442-2451 [Abstract]
  51. Shattil, S. J. (1995) Thromb. Haemostasis 74, 149-155 [Medline] [Order article via Infotrieve]
  52. Frelinger, A. L., III, Du, X., Plow, E. F., and Ginsberg, M. H. (1991) J. Biol. Chem. 266, 17106-17111 [Abstract/Free Full Text]
  53. Kouns, W. C., Hadvary, P., Haering, P., and Steiner, B. (1992) J. Biol. Chem. 267, 18844-18851 [Abstract/Free Full Text]
  54. Kunicki, T. J., Annis, D. S., Deng, Y.-J., Loftus, J. C., and Shattil, S. J. (1996) J. Biol. Chem. 271, 20315-20321 [Abstract/Free Full Text]
  55. Nakajima, K., Powers, J. C., Ashe, B. M., and Zimmerman, M. (1979) J. Biol. Chem. 254, 4027-4032 [Medline] [Order article via Infotrieve]
  56. Calvete, J. J., Mann, K., Alvarez, M. V., Lopez, M. M., and GonzalezRodriguez, J. (1992) Biochem. J. 282, 523-532 [Medline] [Order article via Infotrieve]
  57. Du, X., Gu, M., Nagaswami, C., Bennett, J. S., and Ginsberg, M. H. (1993) J. Biol. Chem. 268, 23087-23092 [Abstract/Free Full Text]
  58. Siess, W. (1991) News Physiol. Sci. 6, 51-56 [Abstract/Free Full Text]
  59. Huang, E. M., and Detwiler, T. C. (1981) Blood 57, 685-691 [Abstract]
  60. Fujii, K., and Imamura, S. (1995) Exp. Cell Res. 220, 201-211 [CrossRef][Medline] [Order article via Infotrieve]

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