A new hypoglycemic agent, midaglizole, blunts diabetic platelet aggregation: a possible role of alpha 2 blockade

A newly developed alpha 2 blocker, midaglizole (DG-5128, 2-[2-(4,5-dihydro-1H-imidazol-2-yl)-1-phenylethyl] pyridine dihydrochloride sesquihydrate) has been shown to have a hypoglycemic action in healthy controls as well as in diabetics. Since human platelets are rich in alpha 2 receptors, the effects of midaglizole on platelet aggregation were investigated. In normal controls, ADP- or epinephrine-induced platelet aggregation was significantly inhibited 2 h after oral administration of 300 mg midaglizole. Midaglizole also suppressed diabetic platelet aggregation stimulated by 10 or 100 microM epinephrine and delayed the initiation of collagen-induced aggregation at 30 micrograms/ml. In vitro addition of midaglizole at 9 or 90 microM significantly inhibited epinephrine-induced platelet aggregation. Furthermore, long-term administration of midaglizole suppressed diabetic platelet aggregation induced by 0.5-1 microM ADP or 1 microM epinephrine. These results suggest that alpha 2 blockade not only blunts diabetic epinephrine-induced platelet aggregation but also affects ADP- or collagen-stimulated platelet aggregation, indicating that this alpha 2 blocker may offer a new approach to the treatment of diabetic microangiopathy.     

Effect of epinephrine on fibrinogen receptor exposure by aspirin-treated platelets and platelets from concentrates in response to ADP and thrombin

Synergistic effects between agonists on platelet aggregation have long been appreciated. Recently epinephrine was reported to induce maximal aggregation of aspirin-treated platelets when combined with ADP or thrombin, and to increase fibrinogen binding of non-aspirin treated platelets stimulated with low doses of ADP. The present study extends these observations to correlate fibrinogen binding in response to various combinations of ADP, epinephrine, and thrombin with platelet aggregation and 14C-serotonin release using aspirin-treated platelets as well as platelets from stored concentrates. When fresh platelets were stimulated with epinephrine (5 microM) together with either ADP (10 microM) or thrombin (150 mU/ml), fibrinogen binding increased by 180% compared to binding observed in response to ADP or thrombin alone. This was accompanied by enhanced platelet aggregation, but no increase in 14C-serotonin release. While both ADP and epinephrine potentiated the aggregation and fibrinogen binding of stored platelets in response to high doses of thrombin (150 mU/ml), maximal aggregation was achieved only with thrombin (150 mU/ml) and epinephrine (5 microM) in combination. The data thus suggest that 1) epinephrine induces maximal aggregation of aspirin-treated platelets stimulated with thrombin or ADP by significantly enhancing fibrinogen receptor exposure independently of the cyclooxygenase-mediated release reaction; 2) epinephrine stimulates platelets by a mechanism different from that of thrombin or ADP; and 3) as demonstrated by others, the ability of platelets from stored concentrates to aggregate and to bind fibrinogen in response to ADP can be enhanced by epinephrine, and, in addition, these platelets can aggregate and bind fibrinogen maximally when stimulated with combinations of epinephrine and thrombin.     

Platelet aggregation by fibrinogen polymers crosslinked across the E domain

There is evidence that platelet interactions with artificial surfaces are mediated by plasma proteins, especially fibrinogen, adsorbed on the surfaces. Multiple site interactions between fibrinogen molecules adsorbed in high concentration and receptors in the unactivated platelet may be sufficient for platelet adhesion and subsequent activation. To examine this hypothesis, we prepared soluble polymers of fibrinogen. Polymers produced by interaction of fibrinogen with Fab'2 fragments of antibodies against fibrinogen's E (central) domain (Fg- Fab'2(E] induced, in gel-filtered platelets, aggregation and serotonin release, which were blocked by monoclonal antibodies against the GPIIb/IIIa complex, by Fab fragments against the D domain, and by metabolic inhibitors; aggregation was attenuated but not abolished by enzymatic removal of ADP (with CP/CPK) or by blockage of ADP binding sites (with FSBA), and when secretion was inhibited by aspirin. Fg- Fab'2(E) also induced a dose-dependent elevation in cytoplasmic Ca2+ (measured by Aequorin luminescence) which was attenuated by CP/CPK and by FSBA, and was eliminated by metabolic inhibitors and by anti- IIb/IIIa antibody. Fibrinogen complexes crosslinked with dimethylsuberimidate or Factor XIII neither aggregated gel-filtered platelets nor inhibited platelet aggregation by ADP and fibrinogen, probably because of inaccessibility of lysine residues in the D (terminal) domain of fibrinogen, which are thought to be required for platelet binding. Thus, soluble complexes of fibrinogen having multiple available platelet receptor recognition sites activate gel-filtered platelets and may provide a useful model for platelet-surface interactions mediated by adsorbed fibrinogen.     

Studies on the mechanism of the inhibition of platelet aggregation and release induced by high levels of arachidonate

We have previously reported that arachidonic acid induced a biphasic pattern of platelet aggregation and the release of both dense and alpha- granule components. Low levels of arachidonate (0.025--0.1 mM) specifically induced aggregation and release, while high concentrations (0.15--0.35 mM) caused a progressive inhibition of these platelet responses in human gel-filtered platelets (GFP). We now report studies of the mechanism(s) responsible for this arachidonate-induced turn-off of platelet function. Electron micrographic studies demonstrated that there was no gross damage to the platelets during the turn-off. Active synthesis of malondialdehyde and thromboxane A2 was seen at the high arachidonate levels, despite the inhibition of aggregation. Furthermore, GFP inhibited by 0.25 mM arachidonate were capable of undergoing aggregation and serotonin release in response to other stimuli, such as collagen or thrombin. Thus, GFP appeared to be metabolically intact and functional during the inhibiton by high arachidonate levels. Thin-layer chromatographic studies revealed that prostaglandin metabolism was not changed at the high arachidonate levels. In addition, indomethacin (20 microM) did not abolish the arachidonate-induced inhibition of platelet function. Therefore, the inhibitory effect of high arachidonate did not depend on its conversion to other prostaglandin products. Platelet cyclic AMP levels increased twofold at the high arachidonate concentrations (1.3 +/- 0.3 pmole/10(8) platelets at peak aggregation, compared with 2.9 +/- 0.4 pmole/10(8) platelets at inhibition by 0.25 mM arachidonate, p less than 0.001). Prostaglandin-D2, a platelet inhibitor known to increase cyclic AMP, generated a similar rise (to 2.4 +/- 0.2 pmole/10(8) platelets). Thus, the magnitude of the arachidonate-induced increase in platelet cyclic AMP levels can account for the inhibition of aggregation and release.     

Inhibition of platelet aggregation by protease inhibitors. Possible involvement of proteases in platelet aggregation

The possible participation of proteases in human platelet aggregation was explored using various protease inhibitors and substrates. Protease inhibitors used included naturally occurring inhibitors of serine proteases and synthetic inhibitors that modify the active site of protease. Substrates used were synthetic substrates for the trypsin type as well as for the chymotrypsin type of protease. All these inhibitors and substrates inhibited platelet aggregation and serotonin release induced by ADP, collagen, epinephrine, or thrombin. In ADP- and epinephrine-induced platelet aggregation the second phase of aggregation was most efficiently inhibited. The inhibitors suppressed the formation of malondialdehyde during platelet aggregation. Release by aggregating agents of arachidonate and its metabolites from indomethacin-treated platelets as well as nontreated platelets was also inhibited. The inhibitors apperar to interact with stimulated platelets but not with unstimulated platelets. These observations suggest that the interaction of an aggregating agent with its platelet receptor activates a unique precursor serine protease that in turn activates platelet phospholipase to liberate arachidonic acid (the precursor of the potent platelet aggregating agent thromboxane A2) from platelet phospholipids.     

Correlation between fibrinogen binding to human platelets and platelet aggregability

Fibrinogen is essential for aggregating platelets with adenosine diphosphate (ADP) and was recently shown to bind to platelets stimulated with ADP. The present work confirms the specific and saturable nature of the platelet-fibrinogen interaction. Binding of 125iodine-labeled fibrinogen to human gel-filtered platelts was maximal at 1 min, and the receptors were saturated when the fibrinogen concentration in the suspending medium approached 0.8 mg/ml. Assuming that one fibrinogen molecule interacts with a single receptor, experiments with 9 normal donors revealed the presence of 12,896 +/- 2456 receptors per platelet. Much of the bound material dissociated from platelets after incubation with apyrase or EDTA. Binding was markedly inhibited at pH 6.5, in the presence of EDTA, and with platelets from 3 thrombasthenic patients but not with those from a patient with the Bernard-Soulier syndrome. Fibrinogen binding was also virtually absent with platelets that had been incubated with EDTA for 8 min at 37 degrees C and pH 7.8. These platelets could not aggregate when mixed with ADP and adequate CaCl2 and fibrinogen, although they could still change their shape. Thus, ADP-induced binding of fibrinogen correlates with platelet aggregability.     

Induction of human platelet fibrinogen receptors by epinephrine in the absence of released ADP

The ability of epinephrine to expose platelet fibrinogen receptors independent of released ADP was assessed using aspirin-treated, gel- filtered platelets. Similar to ADP-induced aggregation, platelet aggregation in response to epinephrine was accompanied by fibrinogen binding. Ten micromolar epinephrine induced a maximum number of platelet fibrinogen receptors in the absence of significant 14C- serotonin release. As indicated by Scatchard analysis, receptors exposed by both epinephrine and ADP had similar affinities for fibrinogen, but epinephrine induced approximately 30% fewer receptors than did ADP. This appears to correlate with the lesser degree of primary aggregation observed with this agent. Studies using phentolamine, a specific alpha-adrenergic antagonist, apyrase, or creatine phosphate/creatine kinase indicate that the exposure of platelet fibrinogen receptors by epinephrine was specific for platelet alpha-adrenergic receptor stimulation and was not the result of released ADP.     

A murine monoclonal antibody that blocks fibrinogen binding to normal platelets also inhibits fibrinogen interactions with chymotrypsin- treated platelets

We recently described a monoclonal antibody, 10E5 , that completely blocks adenosine diphosphate (ADP) induced fibrinogen binding to platelets and aggregation induced by ADP, epinephrine, and thrombin. Multiple lines of evidence indicate that 10E5 binds to platelet membrane glycoproteins IIb and/or IIIa. Because it has been reported that platelets treated with chymotrypsin aggregate when fibrinogen is added, we tested the effect of 10E5 antibody on chymotrypsin-induced fibrinogen binding and platelet aggregation. Aspirin-treated human platelets were washed in modified Tyrode's buffer (pH 7.5), incubated for 5 minutes at 22 degrees C with 300 micrograms/mL chymotrypsin, and washed again. The amount of 10E5 antibody bound to these platelets (37,232 +/- 2,928 molecules/platelet; mean +/- SEM, N=9) was similar to that bound to unstimulated control platelets (36,910 +/- 2,669) and did not differ significantly from the amount of antibody bound to ADP- treated platelets (P less than .01, N = 5). The amount of 10E5 bound to chymotrypsin-treated platelets correlated directly with the amount of fibrinogen bound to separate aliquots of the same platelet samples (r = .876, P less than .001). The 10E5 antibody caused virtually complete inhibition of both the binding of fibrinogen to chymotrypsin-treated platelets and the aggregation induced by exogenous fibrinogen. Immunoprecipitation studies of 125I-labeled chymotrypsin-treated platelets revealed that the 10E5 antibody bound proteins with molecular weights characteristic of glycoproteins IIb and IIIa. These data suggest that the fibrinogen receptor on chymotrypsin-treated platelets is identical to that on ADP-treated platelets and that this receptor is either near to, or on, the glycoprotein IIb/IIIa complex.     

Aggregation of Human Platelets by Bovine Platelet Fibrinogen

Aggregation of human platelets by addition of purified bovine platelet fibrinogen is described. Bovine plasma fibrinogen showed the same but much weaker effect. Human fibrinogen produced no aggregation. No absolute requirement for divalent cations or plasma proteins could be demonstrated. The aggregation of washed platelets appeared monophasic whereas in platelet-rich plasma it was usually biphasic. The use of inhibitors of ADP-induced platelet aggregation, inhibition of intracellular ATP-production, enzyme-catalyzed removal of ADP, and direct determinations of ADP in the medium showed the second phase to be mediated by ADP released from the platelets whereas the first phase was nearly independant of ADP. While the ability of platelet fibrinogen to aggregate platelets and to clot with thrombin were otherwise intimately interconnected, some aggregation activity remained after heat-denaturation of the platelet fibrinogen.     

Effect of fibrinogen concentration on the velocity of platelet aggregation

The relationship between fibrinogen binding to its receptor and platelet aggregation has been investigated by comparing 125I-fibrinogen binding and aggregation velocities of gel-filtered platelets in the presence of adenosine diphosphate (ADP). Aggregometric responses at various fibrinogen concentrations are found to be bell-shaped and show a maximum at fibrinogen concentrations (Fmax) similar to the 125I-fibrinogen hemisaturating doses. At higher and lower fibrinogen concentrations, platelet aggregation velocities decrease in a parallel manner. Lowering ADP concentration increases Fmax, in agreement with the modulatory effect of ADP on fibrinogen binding to platelets. Variations of fibrinogen in the range of physiopathologic plasma concentrations affect platelet aggregation induced by any ADP dose. These results clarify the relationship between the fibrinogen binding process and aggregation and demonstrate that plasma fibrinogen concentration has a major influence on the velocity of platelet aggregation.     

Release of platelet-derived growth factor from human platelets by arachidonic acid

Platelet alpha-granules contain a factor that stimulates the proliferation of arterial smooth muscle cells and may play a role in atherogenesis. We have studied the role of arachidonic acid in mediating the release of the platelet-derived growth factor (PDGF) from human platelets. PDGF was assayed by stimulating of [(3)H]thymidine incorporation into DNA of mouse 3T3 cells. Platelet aggregation and the release of platelet factor 4,beta-thromboglobulin, and serotonin were also studied. A biphasic response pattern was observed when gel-filtered platelets were incubated with arachidonate over the concentration range 0.01-0.4 mM. At low arachidonate levels (approximately 0.025-0.1 mM), specific concentration-dependent aggregation and release of PDGF and of the other components were observed. This effect was not seen with any of five other fatty acids tested and was suppressed by indomethacin (25 muM). At higher arachidonate concentrations (approximately 0.15-0.35 mM), a concentration-dependent turn-off of both aggregation and release occurred. At these concentrations the platelets remained functional, and no release of lactate dehydrogenase was observed. A similar biphasic pattern of arachidonate-induced aggregation and release was observed with platelet-rich plasma, over a similar range of arachidonate to albumin mole ratios. These studies demonstrate that PDGF and other alpha-granule constituents can be released from platelets specifically by arachidonate via an indomethacin-sensitive pathway, most probably involving the platelet cyclooxygenase and conversion of arachidonate to prostaglandin metabolities. The mechanisms responsible for the turn-off of the specific arachidonate-mediated responses at higher arachidonate concentrations remain to be defined.     

Epinephrine induces platelet fibrinogen receptor expression, fibrinogen binding, and aggregation in whole blood in the absence of other excitatory agonists

The exposure of fibrinogen receptors is an early event in agonist-induced platelet activation. Previous measurements of fibrinogen binding or aggregation in platelet-rich plasma or washed platelets have failed to define whether the initial response to epinephrine results solely from a direct effect of this agonist. To address this problem, we have measured fibrinogen receptor exposure on platelets in whole blood by using flow cytometry and a fluorescein isothiocyanate-labeled monoclonal antibody specific for the activated fibrinogen receptor (FITC-PAC1). We also measured platelet-bound fibrinogen with an antifibrinogen monoclonal antibody (FITC-9F9) as well as platelet aggregation in whole blood. In blood anticoagulated with citrate and in the presence of a cyclooxygenase inhibitor, epinephrine (0.1 to 100 mumol/L) caused significant FITC-PAC1 binding (P less than .001) that was maximal at 10 mumol/L epinephrine. The maximal epinephrine response was one third of that observed with 10 mumol/L adenosine diphosphate (ADP) and was eliminated by yohimbine, an alpha 2-adrenergic antagonist. Incubation of the blood with apyrase or phosphoenolpyruvate plus pyruvate kinase to remove extracellular ADP resulted in a 40% to 50% reduction in the epinephrine response. Despite this, FITC-PAC1 binding was still significant at epinephrine greater than or equal to 1 mumol/L (P less than .05). No reduction in epinephrine-induced FITC-PAC1 binding was observed in the presence of ATP alpha S, an ADP receptor antagonist; cinanserin, a serotonin antagonist; or WEB-2086, a platelet activating factor antagonist. Furthermore, addition of the thrombin inhibitors hirudin or leupeptin to citrated blood had no effect on the extent of the epinephrine response. Blood anticoagulated with hirudin also demonstrated an epinephrine response, even in the presence of apyrase. Similar results were obtained when FITC-9F9 was used to detect fibrinogen binding or when aggregation was assessed by a decrease in the number of single platelets. We conclude that epinephrine itself can induce fibrinogen receptor exposure, fibrinogen binding, and aggregation. This primary response is independent of synergistic interaction of epinephrine with traces of ADP, serotonin, platelet activating factor, or thrombin. However, such synergistic interaction with ADP present in whole blood may enhance the responses induced by epinephrine.     

The mechanism of heparin-induced platelet aggregation

When heparin was added to platelet-rich plasma, mild but irreversible platelet aggregation was demonstrated. This platelet response was not accompanied by release of alpha-granules and dense body constituents, nor by prostaglandin biosynthesis. It did, however, require metabolic energy and divalent cations as metabolic inhibitors (anti-mycin A and 6-deoxyglucose) and EDTA blocked the reaction. Bernard-Soulier syndrome platelets, which lack glycoprotein (GP) Ib, but not Glanzmann's Thrombasthenia platelets, which lack GP IIb/IIIa, were aggregated by heparin. Monoclonal antibody (mAb) against GP IIb/IIIa, but not mAb against GP Ib, strongly inhibited the reaction. These combined results suggest the participation of GP IIb/IIIa but not GP Ib in heparin-induced platelet aggregation. Fibrinogen was a cofactor in the reaction as gel-filtered platelets were unreactive to heparin but addition of fibrinogen restored their reactivity. Antithrombin III and fibronectin inhibited platelet response to heparin, suggesting that these proteins may protect platelets from aggregation by heparin.     

Identification of a new congenital defect of platelet function characterized by severe impairment of platelet responses to adenosine diphosphate.

This study characterizes a congenital hemorrhagic disorder caused by a platelet function defect with the following features: (1) severely impaired platelet aggregation and fibrinogen or von Willebrand factor (vWF) binding induced by adenosine diphosphate (ADP); (2) defective aggregation, release reaction, and fibrinogen or vWF binding induced by other agonists; (3) normal aggregation and release reaction induced by high concentrations of thrombin or collagen; (4) no further inhibition by ADP scavengers of aggregation, release reaction, and fibrinogen or vWF binding, comparable with those observed for normal platelets in the presence of ADP scavengers; (5) normal membrane glycoprotein (GP) composition and normal binding of the anti-GP IIb/IIIa monoclonal antibody 10E5; (6) no acceleration by ADP of binding of the anti-GP IIb/IIIa monoclonal antibody 7E3; (7) normal platelet-fibrin clot retraction if induced by thrombin or reptilase plus epinephrine, absent if induced by reptilase plus ADP; (8) no inhibition by ADP of the prostaglandin E1-induced increase in platelet cyclic adenosine monophosphate, but normal inhibition by epinephrine; (9) defective mobilization of cytoplasmic Ca2+ by ADP; (10) normal binding of 14C-ADP to fresh platelets, but defective binding of [2-3H]-ADP to formalin-fixed platelets. This congenital platelet function defect is characterized by selective impairment of platelet responses to ADP, caused by either decreased number of platelet ADP receptors or abnormalities of the signal-transduction pathway of platelet activation by ADP.     

The effect of blood constituents on platelet function: role of blood cells and plasma lipoproteins

Platelet aggregation as well as [14C] serotonin release were increased in platelet-rich plasma in comparison to gel-filtered platelet preparation. The addition of red blood cells to platelet-rich plasma enhanced thrombin-induced [14C] serotonin release by 7%, whereas in a gel-filtered platelet preparation free of any plasma constituents a 47% increment was noted. In the presence of white blood cells, no effect could be shown. Purified lipoproteins were incubated (in their normal plasma concentration) with gel-filtered platelets for 30 minutes at 37 degrees C, and the effect on in vitro platelet function was studied. Very low density lipoprotein and low density lipoprotein increased thrombin-induced platelet aggregation and [14C] serotonin release induced by epinephrine, ADP, and thrombin. In contrast, high density lipoprotein inhibited these platelet functions. Lipoprotein-deficient plasma increased platelet aggregation and release reaction. It appears that plasma lipoproteins have a profound effect on in vitro platelet function. Since both platelets and lipoproteins are of importance in atherosclerosis, the platelet-lipoprotein interaction might be of major significance in this process.     

Inhibition of fibrinogen binding to stimulated human platelets by a monoclonal antibody.

Fibrinogen binding to receptors on stimulated platelets is a prerequisite for platelet aggregation. To gain further insight into the role of fibrinogen in platelet aggregation and to identify the platelet fibrinogen receptor, we developed a monoclonal anti-platelet antibody that inhibited platelet aggregation. The purified antibody, designated A2A9, inhibited platelet aggregation stimulated by 10 microM ADP, 10 microM epinephrine, and thrombin at 1 unit/ml without inhibiting platelet shape change or platelet secretion. A2A9 was also a competitive inhibitor of fibrinogen binding to ADP-stimulated platelets. Fifty percent inhibition of fibrinogen binding occurred at 65 nM A2A9. Direct binding studies using radiolabeled A2A9 demonstrated 47,000 A2A9 binding sites on unstimulated platelets, with a dissociation constant of 60 nM. Platelets from two individuals with Glanzmann thrombasthenia bound essentially no A2A9. Therefore, these data support the hypothesis that receptor-bound fibrinogen mediates platelet aggregation. In order to identify the platelet fibrinogen receptor, A2A9 immobilized on agarose was used for affinity chromatography. Two platelet polypeptides with Mr = 140,000 and 93,000 were recovered from the immobilized A2A9. After disulfide reduction, these Mr values were altered to 125,000 and 116,000. The smaller polypeptide was also found to contain the PlA1 antigen. These data localize the epitope recognized by A2A9 to the platelet membrane glycoprotein IIb-IIIa complex and suggest that this complex forms the physiologic platelet fibrinogen receptor.     

Platelet sialic acid and platelet survival after aggregation by ADP

Some investigators have reported recently that platelet surface sialic acid is decreased during ADP-induced aggregation, whereas others have reported an increase. Since removal of sialic acid from the platelet surface shortens platelet survival, we have determined the survival of platelets that have been aggregatad by ADP. We have also measured the amount of sialic acid in the suspending fluid of platelets after ADP- induced aggregation. ADP-induced aggregation did not cause the loss of sialic acid from rabbit platelets (which do not undergo a release reaction in response to ADP) nor from washed human platelets in a medium containing physiologic concentrations of calcium in which granule contents are not released. In a medium without added calcium, ADP caused the release of 14C-serotonin (42.5% +/- 3%) from human platelets, but less than 4% of the sialic-acid-containing material was released. It seems likely that little of the releasable sialic acid of platelets is in the dense granules or the alpha-granules. Thrombin (5 U/ml) released 90.0% +/- 3.4% of the serotonin from human platelets but only 20.6% +/- 7.4% of the total sialic-acid-containing material. Neuraminidase removed 42.3% of the total sialic acid, presumably from the platelet surface. Rabbit platelets that had been aggregated by ADP and deaggregated survived normally when returned to the circulation. This observation also provides evidence that they had not lost membrane sialic acid during aggregation and deaggregation.     

Increased binding to ADP-stimulated platelets and aggregation effect of the dysfibrinogen Oslo I as compared with normal fibrinogen

Interactions of the dysfibrinogen Oslo I with platelets were investigated. This fibrinogen is a B beta-chain variant with faster than normal fibrin monomer polymerization. Fibrinogen Oslo I acted more efficiently in ADP-induced platelet aggregation, and bound to gel-filtered platelets with a higher affinity constant than did normal fibrinogen. At all concentrations more fibrinogen molecules became bound per platelet with the dysfibrinogen than with normal fibrinogen, both when the fibrinogens were tested separately or as a mixture using 125I or 131I to label the two types. At high concentrations this was probably due to ligand polymerization of the dysfibrinogen. These observations indicate that the increased cofactor function in platelet aggregation may be related to the increased affinity of the dysfibrinogen for the platelets.     

The effect of thrombin,Reptilase, and a fibrinopeptide B-releasing enzyme from the venom of the Southern Copperhead snake on rabbit platelets

The action of thrombin, Reptilase, and a fibrinopeptide B-releasing enzyme from the Southern Copperhead snake venom on gel-filtered rabbit platelets has been studied. Of these enzymes, only thrombin aggregated the platelets. A mixture of Reptilase and the Southern Copperhead enzyme, which closely mimicked the enzymatic activity of thrombin on fibrinogen, failed to induce aggregation. These results indicate that thrombin does not aggregate platelets by its action on fibrinogen on the platelet surface. Incubation of the gel-filtered platelets with the snake venom enzymes modified the platelet aggregation response to ADP. The rates of both aggregation and disaggregation were moderately decreased after incubation with Reptilase, and the rate of disaggregation was decreased after incubation with the Southern Copperhead enzyme.     

Aspirin does not inhibit adenosine diphosphate-induced platelet alpha- granule release

The involvement of metabolites of arachidonic acid in platelet-dense granule secretion and secondary platelet-platelet interactions is well characterized. However, their role in heterotypic interactions dependent on alpha-granule secretion is less well understood. Using platelet-surface expression of P-selectin as a marker of alpha-granule secretion, we have shown that: (1) aspirin treatment of platelets at doses that block dense granule secretion does not inhibit alpha-granule secretion to adenosine diphosphate (ADP); (2) synergism between epinephrine and ADP in the induction of P-selectin expression is similarly unaffected by aspirin; and (3) the ability of P-selectin to mediate adhesion of activated platelets to monocytes and polymorphonuclear lymphocytes in whole blood is also unchanged by aspirin treatment. To further explore the mechanisms responsible for platelet alpha-granule secretion, we have shown that inhibition of Na+/H+ exchange by either acidification of the extracellular medium or amiloride treatment blocked ADP-induced P-selectin expression. In contrast, incubation with the platelet lipoxygenase inhibitor 5,8,11- eicosatrynoic acid, by itself and with aspirin, did not decrease ADP- induced P-selectin expression. We conclude that platelet alpha-granule secretion in response to ADP is dependent on intact Na+/H+ exchange but is independent of the lipoxygenase- and cyclooxygenase-dependent metabolites of arachidonic acid.