Multiple pathways of thrombin-induced platelet activation differentiated by desensitization and a thrombin exosite inhibitor.

Recently a thrombin receptor with a unique mechanism of activation was cloned from a megakaryocyte-like cell line (Vu et al., Cell 64:1057-1068, 1991). Thrombin cleaves a portion of this receptor creating a new N-terminus that acts as a "tethered-ligand" to activate the receptor. A thrombin receptor activating peptide (SFLLRNPNDKYEPF) homologous to the new N-terminus was shown to activate platelets. We synthesized this peptide and demonstrated that it desensitized platelets to activation by low concentrations of alpha-thrombin but not gamma-thrombin. We also synthesized a thrombin exosite inhibitor (BMS 180742) that inhibited platelet aggregation induced by low, but not high, concentrations of alpha-thrombin. In contrast, a thrombin active site inhibitor, N alpha-(2-naphthylsulfonyl-glycyl)-D,L-amidinophenylalanylpiperi dide, competitively inhibited thrombin-induced platelet aggregation. We conclude that thrombin-induced platelet activation is mediated by at least two pathways: one activated by low concentrations of alpha-thrombin and blocked by a thrombin exosite inhibitor that appears to be coupled to the "tethered-ligand" thrombin receptor, and another that is stimulated by higher concentrations of alpha-thrombin and by gamma-thrombin and does not require the thrombin exosite for activation. Both pathways are blocked by a thrombin active site inhibitor.     

Protein kinase C phosphorylation of syntaxin 4 in thrombin-activated human platelets

We postulated that the syntaxins, because of their key role in SNARE complex formation and exocytosis, could be important targets for signaling by intracellular kinases involved in secretion. We found that syntaxin 4 was phosphorylated in human platelets treated with a physiologic agent that induces secretion (thrombin) but not when they were treated with an agent that prevents secretion (prostacyclin). Syntaxin 4 phosphorylation was blocked by inhibitors of activated protein kinase C (PKC), and, in parallel assays, PKC inhibitors also blocked secretion from thrombin-activated platelets. In platelets, cellular activation by thrombin or phorbol 12-myristate 13-acetate decreased the binding of syntaxin 4 with SNAP-23, another platelet t-SNARE. Phosphatase inhibitors increased syntaxin 4 phosphorylation and further decreased syntaxin 4-SNAP-23 binding induced by cell activation. Conversely, a PKC inhibitor blocked syntaxin 4 phosphorylation and returned binding of syntaxin 4-SNAP-23 to that seen in nonstimulated platelets. In vitro, PKC directly phosphorylated platelet syntaxin 4 and recombinant syntaxin 4. PKC phosphorylation in vitro inhibited (71 +/- 8%) the binding of syntaxin 4 to SNAP-23. These results provide evidence that extracellular activation can be coupled through intracellular PKC signaling so as to modulate SNARE protein interactions involved in platelet exocytosis.     

Correlation of thrombin-induced glycoprotein V hydrolysis and platelet activation

To assess the possibility that hydrolysis of the platelet surface thrombin substrate, glycoprotein V, is a necessary step in thrombin-induced platelet activation, thrombin-catalyzed hydrolysis of glycoprotein V was correlated with thrombin-induced platelet activation. Hydrolysis of tritium-labeled glycoprotein V on washed human platelets was measured by the appearance of a labeled supernatant fragment, and platelet activation was measured as secretion of ATP. Hydrolysis of glycoprotein V was linear with respect to both thrombin concentration and time of incubation. The extent of platelet activation was correlated with the rate of hydrolysis but not with the amount hydrolyzed. Maximum platelet activation could be obtained with thrombin treatments resulting in hydrolysis of as little as 4% of glycoprotein V per min. Glycoprotein V was partially removed from platelets by pretreatment with either platelet calcium-dependent protease or chymotrypsin. The rate of thrombin-catalyzed hydrolysis of the remaining glycoprotein V from these pretreated platelets was as little as 1.5% the rate from control platelets, but there was no impairment of the extent of platelet activation. Thus, these protease-pretreated platelets compared with control platelets showed a different correlation of glycoprotein V hydrolysis with platelet activation. Glycoprotein V was also partially removed by pretreatment of prostacyclin-inhibited platelets with thrombin. After removal of thrombin and prostacyclin, these platelets were desensitized to subsequent activation by thrombin. Incubation of desensitized platelets with nonsaturating levels of thrombin led to less than 25% of the activation seen with control platelets but to a slightly greater hydrolysis of glycoprotein V. Thus, the desensitization to thrombin was not due to loss of ability of the activating thrombin to hydrolyze glycoprotein V. These results do not exclude a role for glycoprotein V as a component of the platelet thrombin receptor, but they indicate that there is no simple relationship between thrombin-induced hydrolysis of glycoprotein V and platelet activation.     

A platelet secretion pathway mediated by cGMP-dependent protein kinase

Platelet secretion (exocytosis) is critical in amplifying platelet activation, in stabilizing thrombi, and in arteriosclerosis and vascular remodeling. The signaling mechanisms leading to secretion have not been well defined. We have shown previously that cGMP-dependent protein kinase (PKG) plays a stimulatory role in platelet activation via the glycoprotein Ib-IX pathway. Here we show that PKG also plays an important stimulatory role in mediating aggregation-dependent platelet secretion and secretion-dependent second wave platelet aggregation, particularly those induced via Gq-coupled agonist receptors, the thromboxane A2 (TXA2) receptor, and protease-activated receptors (PARs). PKG I knock-out mouse platelets and PKG inhibitor-treated human platelets showed diminished aggregation-dependent secretion and also showed a diminished secondary wave of platelet aggregation induced by a TXA2 analog and thrombin receptor-activating peptides that were rescued by the granule content ADP. Low dose collagen-induced platelet secretion and aggregation were also reduced by PKG inhibitors. Furthermore PKG I knockout and PKG inhibitors significantly attenuated activation of the Gi pathway that is mediated by secreted ADP. These data unveil a novel PKG-dependent platelet secretion pathway and a mechanism by which PKG promotes platelet activation.     

A role for phosphatidylinositol 3-kinase in platelet aggregation in response to low, but not high, concentrations of PAF or thrombin

In this study we show that platelet activating factor (PAF) activates PI 3-kinase over a rapid time course that correlates closely with the aggregation response. Tyrosine kinases are involved in this response, since there is increased PI 3-kinase activity associated with tyrosine-phosphorylated proteins. PI 3-kinase inhibitors were used to probe the dependence of PAF-induced aggregation on PI 3-kinase. Both wortmannin and LY-294002 inhibited PAF-induced aggregation that correlated with PI 3-kinase inhibition only when using lower concentrations of PAF giving reversible aggregation (primary phase). Similar results were obtained with human platelets using thrombin or thrombin receptor activating peptide. The same pattern of response was observed when activation of GPIIbIIIa was assessed by flow cytometry, i.e., PI 3-kinase inhibitors blocked integrin activation only when lower concentrations of agonist were used. We suggest that PI 3-kinase is important for reversible (primary) aggregation of platelets in response to PAF or thrombin, perhaps by contributing to the 'inside-out' activation of the platelet integrin GPIIbIIIa, only when submaximal concentrations of agonists are used. The lack of effect of PI 3-kinase inhibitors, when high concentrations of agonist are used, suggests that PI 3-kinase-independent pathways contribute to aggregation under these conditions.     

Molecular cloning of a functional thrombin receptor reveals a novel proteolytic mechanism of receptor activation.

We isolated a cDNA encoding a functional human thrombin receptor by direct expression cloning in Xenopus oocytes. mRNA encoding this receptor was detected in human platelets and vascular endothelial cells. The deduced amino acid sequence revealed a new member of the seven transmembrane domain receptor family with a large amino-terminal extracellular extension containing a remarkable feature. A putative thrombin cleavage site (LDPR/S) resembling the activation cleavage site in the zymogen protein C (LDPR/I) was noted 41 amino acids carboxyl to the receptor's start methionine. A peptide mimicking the new amino terminus created by cleavage at R41 was a potent agonist for both thrombin receptor activation and platelet activation. "Uncleavable" mutant thrombin receptors failed to respond to thrombin but were responsive to the new amino-terminal peptide. These data reveal a novel signaling mechanism in which thrombin cleaves its receptor's amino-terminal extension to create a new receptor amino terminus that functions as a tethered ligand and activates the receptor.     

The binding of 1,N6-etheno-NAD to bovine liver glutamate dehydrogenase

The interaction of thrombin and platelets was studied with a heterobifunctional photoactivable crosslinking agent. Radiolabeled thrombin that was modified with ethyl-N-5-azido-2-nitrobenzoylaminoacetimidate formed two types of complex with platelet proteins: platelet-associated complexes and supernatant complexes. The platelet-associated complexes formed within 20 s. Autoradiography after electrophoresis with sodium dodecyl sulfate indicated that these complexes had apparent masses of 210, 185, 155 and 125 kDa. Formation of the complexes was blocked by hirudin; this is consistent with crosslinking that was a direct consequence of the binding of thrombin to a specific receptor, since hirudin blocks thrombin-induced platelet activation and the saturable binding of thrombin to platelets. The labeled supernatant complex had an apparent mass of about 490 kDa. It also formed in the supernatant solution of platelets after activation with a divalent cation ionophore, suggesting a complex of thrombin with a secreted protein. The supernatant complex did not involve fibrinogen or alpha 2-macroglobulin, but a similar complex was formed with partially purified secreted glycoprotein G (thrombin-sensitive protein, thrombospondin). Formation of the complex was blocked by hirudin. A similar complex was formed after prolonged (1 h) incubation without photoactivation. It is concluded that thrombin forms high-affinity, hirudin-sensitive complexes with secreted glycoprotein G, as well as with platelet surface proteins.     

The perturbation of thrombin binding to human platelets by trypsin and neuraminidase

The initial step in the interaction of thrombin with human platelets in binding of the enzyme to the platelet surface. The effects of digestion of isolated platelets with trypsin and neuraminidase on aggregation, release of serotonin and binding of thrombin have been examined.Trypsin is a powerful inducer of platelet aggregation as well as the release reaction. The aggregation effect of trypsin may be blocked with disodium ehtylenediaminetatraacetate (EDTA). Further, in the presence of EDTA, trypsin-induced release of [¹⁴C]serotonin is 15–20% lower compared to controls and the initial lag period is prolonged. Conditions were developed under which trypsin did neither aggregate nor release serotonin from platelets. Even under these conditions, trypsin caused a profound loss in the thrombin binding capacity of platelets. Thus, the trypsin-induced fall in the thrombin binding capacity and the platelet response are dissociated. This loss in the thrombin binding by trypsin is due to a lower number of binding sites available on the platelet surface and is not due to an altered affinity.Neuraminidase did not induce platelet aggregation or the release reaction. The ability of platelets to bind thrombin was also unimpaired by prior digestion with neuraminidase. Thus, the sialic acid at the platelet surface is not essential in the function of thrombin recognition by the receptor. This moiety may nontheless be a constituent of a glycoprotein which might act as the thrombin receptor.     

Domain 3 of kininogens contains a cell-binding site and a site that modifies thrombin activation of platelets.

High and low molecular weight kininogens (HK and LK) are able to bind to platelets to inhibit thrombin binding to and activation of platelets. The heavy chain domain on the kininogens that contains these functions has been determined. Domain 3 (D3) but not domains 1 or 2, completely inhibited 125I-HK binding to platelets (Ki = 24 +/- 7 nM, n = 4). 125I-D3 specifically bound to unstimulated platelets and human umbilical vein endothelial cells. On platelets, it was blocked by unlabeled D3 and HK but not prekallikrein, factor XII, C1s, or C1 inhibitor. Further, one monoclonal antibody (HKH13) directed to kininogens' D3 blocked 125I-HK and 125I-D3 binding to platelets. The binding of 125I-D3 to platelets was fully reversible by addition of 35 molar excess of unlabeled D3. D3 binding to platelets was saturable with an apparent Kd of 39 +/- 8 nM (n = 4) and 1227 +/- 404 binding sites/platelet. D3, like HK and LK, inhibited thrombin-induced platelet activation by preventing thrombin binding to platelets. Another monoclonal antibody (HKH12), directed to D3, which did not block HK binding to platelets, reduced HK's ability to inhibit 125I-alpha-thrombin binding. This result suggests that the region on D3 that inhibits 125I-alpha-thrombin binding to platelets is different from that which directly binds to platelets. These studies indicate that D3 of the kininogens contains both a binding region for platelets and endothelial cells and another region that inhibits thrombin-induced platelet activation.     

Thyroid hormone stimulates expression of 6-phosphofructo-2-kinase in rat liver

Gel-filtrated human platelets were stimulated with thrombin in the absence and presence of adrenaline. Adrenaline markedly enhanced the thrombin-induced increase in cytoplasmic pH (pH_i) in BCECF-loaded platelets. This rise in pH_i was strongly inhibited by the Na⁺/H⁺ exchange blocker EIPA. The potentiation by adrenaline of thrombin-induced PLC activation measured as [³²P]PA formation and final platelet responses was, however, not blocked by EIPA, even at low concentrations of thrombin. These results indicate that the enhancement by adrenaline of thrombin-induced cytoplasmic alkalinization may be a secondary effect which is not essential for the potentiation by adrenaline of platelet activation by thrombin.     

A 14 amino acid peptide derived from the amino terminus of the cleaved thrombin receptor elevates intracellular calcium and stimulates prostacyclin production in human endothelial cells.

Cleavage by thrombin of the platelet thrombin receptor exposes a new N-terminal segment SFLLRNPNDKYEPF (SFLL) which acts as a tethered ligand. The free peptide activates platelets and induces platelet aggregation. We now show that SFLL can also activate human umbilical vein endothelial cells (HUVEC) and induce rises in both cytosolic free calcium ([Ca2+]i) and prostacyclin (PGI2) production. These responses were time- and concentration-dependent and were similar to those for native thrombin except that they were not blocked by hirudin. Initial activation of HUVEC with thrombin desensitized the subsequent response to SFLL for both rises in [Ca2+]i and PGI2 production. Thus, SFLL alone can activate HUVEC and elevate [Ca2+]i and induce PGI2 production suggesting that the thrombin receptors on platelet and endothelial cells are functionally and structurally similar.     

Cathepsin G activates protease-activated receptor-4 in human platelets

Of the four known protease-activated receptors (PARs), PAR1 and PAR4 are expressed by human platelets and mediate thrombin signaling. Whether these receptors are redundant, interact, or play at least partially distinct roles is unknown. It is possible that PAR1 and/or PAR4 might confer responsiveness to proteases other than thrombin. The neutrophil granule protease, cathepsin G, is known to cause platelet secretion and aggregation. We now report that this action of cathepsin G is mediated by PAR4. Cathepsin G triggered calcium mobilization in PAR4-transfected fibroblasts, PAR4-expressing Xenopus oocytes, and washed human platelets. An antibody raised against the PAR4 thrombin cleavage site blocked platelet activation by cathepsin G but not other agonists. Desensitization with a PAR4 activating peptide had a similar effect. By contrast, inhibition of PAR1 function had no effect on platelet responses to cathepsin G. When neutrophils were present, the neutrophil agonist fMet-Leu-Phe triggered calcium signaling in Fura-2-loaded platelets. Strikingly, this neutrophil-dependent platelet activation was blocked by the PAR4 antibody. These data show that PAR4 mediates platelet responses to cathepsin G and support the hypothesis that cathepsin G might mediate neutrophil-platelet interactions at sites of vascular injury or inflammation.     

Glycoprotein Ib-mediated platelet activation. A signalling pathway triggered by thrombin.

Platelet activation by thrombin plays a major role in the development of haemostasis and thrombosis. Thrombin activates human platelets by cleaving the N-terminal region of G-protein-coupled protease-activated receptors (PARs). On the other hand, the platelet membrane glycoprotein GPIb acts as a thrombin-binding site and promotes platelet activation by low thrombin concentrations. We present here new evidence in favour of a thrombin receptor function for GPIb. We have selected conditions in which thrombin-GPIb interactions were enhanced by thrombin immobilization. Activation was studied independently of PAR cleavage by using active-site-blocked thrombin. We show that immobilized, proteolytically inactive thrombin induces platelet adhesion and spreading, dense granule secretion and integrin alphaIIbbeta3-dependent platelet-platelet interactions. The pathway must be dependent on GPIb because it is deficient in platelets from a patient with Bernard Soulier syndrome and inhibited by a monoclonal antibody to GPIb (SZ2) or by an excess of glycocalicin. Secreted ADP plays a major role in GPIb-dependent thrombin-induced platelet activation which is, in addition, regulated by cAMP concentration. Thrombin-induced GPIb-dependent platelet activation leads to tyrosyl phosphorylation of several proteins. Inhibition of platelet-platelet interactions and protein tyrosine phosphorylations by inhibitors of phosphatidylinositol 3-kinases and protein kinase C implies that activation of the latter are important steps of the GPIb-coupled signalling pathway triggered by thrombin.     

Porphyromonas gingivalis-induced platelet aggregation in plasma depends on Hgp44 adhesin but not Rgp proteinase

Evidence from recent epidemiological studies suggests a link between periodontal infections and increased risk of atherosclerosis and related cardiovascular and cerebrovascular events in human subjects. One of the major pathogens of periodontitis, Porphyromonas gingivalis, has the ability to aggregate human platelets in platelet-rich plasma (PRP). Mechanism of P. gingivalis-induced platelet aggregation in PRP was investigated. Proteinase inhibitors toward Arg-gingipain (Rgp) and Lys-gingipain (Kgp) did not suppress P. gingivalis-induced platelet aggregation in PRP, whereas the Rgp inhibitor markedly inhibited P. gingivalis-induced platelet aggregation using washed platelets. Mutant analysis revealed that P. gingivalis-induced platelet aggregation in PRP depended on Rgp-, Kgp- and haemagglutinin A (HagA)-encoding genes that intragenically coded for adhesins such as Hgp44. Hgp44 adhesin on the bacterial cell surface, which was processed by Rgp and Kgp proteinases, was essential for P. gingivalis-induced platelet aggregation in PRP. P. gingivalis cell-reactive IgG in plasma, and FcgammaRIIa receptor and to a lesser extent GPIbalpha receptor on platelets were found to be a prerequisite for P. gingivalis-induced platelet aggregation in PRP. These results reveal a novel mechanism of platelet aggregation by P. gingivalis.     

Interaction of lectins with human platelets. Effects on platelet stimulation by thrombin and ristocetin.

Wheat germ agglutinin induced aggregation and secretion of fresh platelets. Aggregation, but not secretion of serotonin by platelets in plasma, by the lectin was inhibited by 5 mM EDTA. Further, the lectin-induced stimulation of fresh platelets was blocked by prostaglandin E1. Thus, this lectin stimulates platelets by a mechanism which closely mimics thrombin activation and is independent of intercellular crosslinking. Lentil lectin did not stimulate platelets. Each platelet contained about 6 . 10(-5) binding sites for the lectins with an apparent dissociation constant of 3.0 . 10(-7) M. Wheat germ agglutinin, which binds mainly to glycoprotein I (Mr 150 000), increased the subsequent binding of thrombin to fixed platelets while lentil lectin was without effect. It appears that thrombin and wheat germ agglutinin bind to independent but interacting sites. Wheat germ agglutinin, but neither thrombin nor lentil lectin, inhibited the agglutination of platelets by ristocetin. Further, rat platelets were not aggregated by either ristocetin or wheat germ agglutinin. It appears that the interaction sites of ristocetin and wheat germ agglutinin on platelets are overlapping.     

Photoaffinity labeling of platelet thrombin-binding proteins

The interaction of thrombin and platelets was studied with a heterobifunctional photoactivable crosslinking agent. Radiolabeled thrombin that was modified with ethyl-N-5-azido-2-nitrobenzoylaminoacetimidate formed two types of complex with platelet proteins; platelet-associated complexes and supernatant complexes. The platelet-associated complexes formed within 20 s. Autoradiography after electrophoresis with sodium dodecyl sulfate indicated that these complexes had apparent masses of 210, 185, 155 and 125 kDa. Formation of the complexes was blocked by hirudin; this is consistent with crosslinking that was a direct consequences of the binding of thrombin to a specific receptor, since hirudin blocks thrombin-induced platelet activation and the saturable binding of thrombin to platelets. The labeled supernatant complex had an apparent mass of about 490 kDa. It also formed in the supernatant solution of platelets after activation with a divalent cation ionophore, suggesting a complex of thrombin with a secreted protein. The supernatant complex did not involve fibrinogen or α₂-macroglobulin, but a similar complex was formed with partially purified secreted glycoprotein G (thrombin-sensitive protein, thrombospondin). Formation of the complex was blocked by hirudin. A similar complex was formed after prolonged (1 h) incubation without photoactivation. It is concluded that thrombin forms high-affinity, hirudin-sensitive complexes with secreted glycoprotein G, as well as with platelet surface proteins.     

Akt activation in platelets depends on Gi signaling pathways

The serine-threonine kinase Akt has been established as an important signaling intermediate in regulating cell survival, cell cycle progression, as well as agonist-induced platelet activation. Stimulation of platelets with various agonists including thrombin results in Akt activation. As thrombin can stimulate multiple G protein signaling pathways, we investigated the mechanism of thrombin-induced activation of Akt. Stimulation of platelets with a PAR1-activating peptide (SFLLRN), PAR4-activating peptide (AYPGKF), and thrombin resulted in Thr308 and Ser473 phosphorylation of Akt, which results in its activation. This phosphorylation and activation of Akt were dramatically inhibited in the presence of AR-C69931MX, a P2Y12 receptor-selective antagonist, or GF 109203X, a protein kinase C inhibitor, but Akt phosphorylation was restored by supplemental Gi or Gz signaling. Unlike wild-type mouse platelets, platelets from Galphaq-deficient mice failed to trigger Akt phosphorylation by thrombin and AYPGKF, whereas Akt phosphorylation was not affected by these agonists in platelets from mice that lack P2Y1 receptor. However, ADP caused Akt phosphorylation in Galphaq- and P2Y1-deficient platelets, which was completely blocked by AR-C69931MX. In contrast, ADP failed to cause Akt phosphorylation in platelets from mice treated with clopidogrel, and thrombin and AYPGKF induced minimal phosphorylation of Akt, which was not affected by AR-C69931MX in these platelets. These data demonstrate that Gi, but not Gq or G12/13, signaling pathways are required for activation of Akt in platelets, and Gi signaling pathways, stimulated by secreted ADP, play an essential role in the activation of Akt in platelets.     

A new role for FcgammaRIIA in the potentiation of human platelet activation induced by weak stimulation

The low affinity receptor for immunoglobulin G, FcgammaRIIA, is expressed in human platelets, mediates heparin-induced thrombocytopenia and participates to platelet activation induced by von Willebrand factor. In this work, we found that stimulation of platelets with agonists acting on G-protein-coupled receptors resulted in the tyrosine phosphorylation of FcgammaRIIA, through a mechanism involving a Src kinase. Treatment of platelets with the blocking monoclonal antibody IV.3 against FcgammaRIIA, but not with control IgG, inhibited platelet aggregation induced by TRAP1, TRAP4, the thromboxane analogue U46619, and low concentrations of thrombin. By contrast, platelet aggregation induced by high doses of thrombin was unaffected by blockade of FcgammaRIIA. We also found that the anti-FcgammaRIIA monoclonal antibody IV.3 inhibited pleckstrin phosphorylation and calcium mobilization induced by low, but not high, concentrations of thrombin. In addition, thrombin- or U46619-induced tyrosine phosphorylation of several substrates typically involved in FcgammaRIIA-mediated signalling, such as Syk and PLCgamma2, was clearly reduced by incubation with anti-FcgammaRIIA antibody IV.3. Upon stimulation with thrombin, FcgammaRIIA relocated in lipid rafts, and thrombin-induced tyrosine phosphorylation of FcgammaRIIA occurred within these membrane domains. Controlled disruption of lipid rafts by depleting membrane cholesterol prevented tyrosine phosphorylation of FcgammaRIIA and impaired platelet aggregation induced by U46619 or by low, but not high, concentrations of thrombin. These results indicate that FcgammaRIIA can be activated in human platelets downstream G-protein-coupled receptors and suggest a novel general mechanism for the reinforcement of platelet activation induced by low concentrations of agonists.     

Acetylated prothrombin as a substrate in the measurement of the procoagulant activity of platelets: elimination of the feedback activation of platelets by thrombin.

Human prothrombin was acetylated to produce a modified prothrombin that upon activation by platelet-bound prothrombinase generates a form of thrombin that does not activate platelets but retains its amidolytic activity on a chromogenic peptide substrate. If normal prothrombin is used in such an assay, the thrombin that is generated activates the platelets in a feedback manner, accelerating the rate of thrombin generation and thereby preventing accurate measurement of the initial platelet procoagulant activity. Acetylation of prothrombin was carried out over a range of concentrations of sulfo-N-succinimidyl acetate (SNSA). Acetylation by 3 mM SNSA at room temperature for 30 min at pH 8.2 in the absence of metal ions produced a modified prothrombin that has <0.1% clotting activity (by specific prothrombin clotting assay), but it is activated by factor Xa (in the presence of either activated platelets or factor Va + anionic phospholipid) to produce thrombin activity that is measurable with a chromogenic substrate. Because the feedback action on the platelets is blocked, thrombin generation is linear, allowing quantitative measurement of the initial platelet activation state.     

Activation of human platelet phospholipase C by ionophore A23187 is totally dependent upon cyclo-oxygenase products and ADP.

Human platelets exposed to the Ca2+ ionophore A23187 form cyclo-oxygenase metabolites from liberated arachidonic acid and secrete dense granule substituents such as ADP. I have shown previously that A23187 causes activation of phospholipase A2 and some stimulation of phospholipase C. I now report that, in contrast to the case for thrombin, the activation of phospholipase C in response to ionophore is completely dependent upon the formation of cyclo-oxygenase products and the presence of ADP. The addition of A23187 to human platelets induces a transient drop in the amount of phosphatidylinositol 4,5-bisphosphate, a decrease in the amount of phosphatidylinositol, and the formation of diacylglycerol and phosphatidic acid. In addition, lysophosphatidylinositol and free arachidonic acid are produced. The presence of cyclo-oxygenase inhibitors or agents which remove ADP partially impairs these changes. When both types of inhibitor are present, the changes in phosphatidylinositol 4,5-bisphosphate and the formation of diacylglycerol and phosphatidic acid are blocked entirely, whereas formation of lysophosphatidylinositol and free arachidonic acid are relatively unaffected. The prostaglandin H2 analogue U46619 activates phospholipase C. This stimulation is inhibited partially by competitors for ADP. I conclude that phospholipase C is not activated by Ca2+ in the platelet, and suggest that stimulation is totally dependent upon a receptor coupled event.