Diversity of signaling underlying responses mediated by selective activation of the platelet thromboxane A2 (TXA2) receptor; pharmacological and kinetic studies in vitro.

Selective activation of the platelet TXA2 receptor is sufficient to mediate concurrent aggregation, deaggregation and shape change (SC) responses without activation of known Gi-coupled receptors (Platelets 2003; 14: 89). However, Gi-coupled receptor activation strongly influences the hemostasis response in vivo. This study investigated the modulatory effects of two signaling pathways related to Gi-coupled receptor activation, stimulation of phosphoinositide 3-kinases (PI3Ks) and inhibition of adenylyl cyclase (AC), on the aggregation, deaggregation and SC components of the platelet activation response. A novel turbidimetric approach was applied to separate these responses and to characterize their pharmacology and kinetics. The SC response was more sensitive to TXA2 receptor activation (lower EC50 value) but less sensitive to a TXA2 receptor antagonist (higher Kd value) than the net aggregation response. Epinephrine and sulprostone, agonists of the Gi-coupled alpha2A-adrenoceptor and EP3 receptor, respectively, amplified the SC, decelerated deaggregation and enhanced net aggregation responses. SQ22536 and 2',5'-dideoxyadenosine, inhibitors of AC activity, elicited smaller but qualitatively similar effects. The PI3K inhibitor wortmannin did not affect the SC response but accelerated deaggregation and inhibited net aggregation. These data are consistent with a differential modulation of the platelet SC response by each pathway associated with Gi-coupled receptor activation, while both pathways cooperatively enhance the net aggregation response by decelerating deaggregation. We propose that the TXA2 receptor mediated concurrent platelet aggregation and SC responses, that are differentially modulated by different signaling pathways, provide a model for studying the underlying cellular pharmacology of platelet physiology.

Concurrent responses elicited by isolated activation of platelet Gq-coupled receptors, in vitro: a novel approach for their separation and analysis.

This study tested the hypothesis that aggregation mediated by activation of a single G(q)-coupled receptor can be studied quantitatively if four concurrent but distinct components of the observed platelet response, autocrine stimulation, shape change (SC), aggregation and deaggregation, are separately measured. Responses mediated by two G(q)-coupled receptors, the TXA(2) and the P2Y(1), were assayed by a novel, kinetics-based turbidimetric approach. Blocking the autocrine stimulation with a cocktail of receptor antagonists revealed rapid and sustained SC that largely masked the aggregation. Mathematical removal of the SC contribution from the changes in optical density indicated that selective activation of either the TXA(2) or the P2Y(1) receptor was sufficient to induce a small aggregation (DeltaOD = 0.1-0.2) that was reversed rapidly by a concurrent deaggregation. Model-derived rate constants of SC, aggregation and deaggregation described the observed complex time course of their concurrency well. Laser light scattering aggregometry confirmed the rapid deaggregation of platelet aggregates following TXA(2) or P2Y(1) receptor-mediated formation. Saturable concentration response curves of net aggregation were elicited at EC(50) values 6-15 higher than those of SC. The utility of this approach was further demonstrated by the separation of the four components of the response mediated by concurrent 5-HT(2A) and alpha(2A)-adrenoceptor activation, as well as the P2Y(1) and alpha(2A)-adrenoceptor, and the autocrine stimulation and SC mediated by the 5-HT(2A) receptor. We propose that the novel approach described here is necessary to study the receptor pharmacology and the kinetics of concurrent platelet responses in vitro as demonstrated by platelet aggregation elicited by selective activation of the TXA(2) or the P2Y(1) receptors.

Molecular and biochemical evidence for the presence of type III adenylyl cyclase in human platelets.

The isoform(s) of adenylyl cyclase (AC) present in human platelets has not been identified, and evidence supporting a role for AC in platelet aggregation is equivocal. We recently characterized deaggregation as an active component of the platelet aggregation response that may be an important determinant of the extent and duration of aggregation. G(i)-coupled receptors are linked to the inhibition of AC and are targets of antiplatelet drugs. They also affect platelet aggregation by modulating deaggregation, suggesting a role for AC in modulating this response. The purpose of this study was to identify the AC isoform(s) present in human platelets and to identify its physiological modulators. RT-PCR screening of platelet, buffy coat layer cell and bone marrow megakaryocyte cDNA, and Western blot analysis with AC type III (AC-III) antibodies identified AC-III in platelets and in megakaryocytes. Human platelet AC-III was cloned and expressed in HEK293 cells and its characteristics compared to native platelet AC. Both platelet AC and cloned AC-III required Mg(2+) for activity, were insensitive to Ca(2+) and were G(s)- and G(i)-coupled. Zn(2+) and SQ22536 inhibited platelet AC activity. The affinity of SQ22536 was increased with Mg(2+)-related stimulation of AC, while that of Zn(2+) was unchanged, which is consistent with a non-competitive interaction between the two metal ions on AC. The Zn(2+) chelator TPEN reversed the inhibitory effects of Zn(2+). This study identified AC-III as the predominant AC isoform in human platelets, the activity of which may affect the extent and duration of the net aggregation response by modulating deaggregation.

Agonist concentration-dependent differential responsivity of a human platelet purinergic receptor: pharmacological and kinetic studies of aggregation, deaggregation and shape change responses mediated by the purinergic P2Y1 receptor in vitro.

Platelet shape change (SC), aggregation and deaggregation responses are integral components of hemostasis that are elicited and modulated in vivo by the simultaneous activation of several membrane receptors. Selective activation of the purinergic P2Y1 receptor in vivo elicits a sustained SC and a small, transient aggregation response that is reversed rapidly by a robust deaggregation response (Platelets 2003; 14: 89). Using a kinetics-based turbidimetric approach to study the modulation of these concurrent components of human platelet responses, we demonstrate that these P2Y1 receptor-related responses and a number of their kinetic and steady-state characteristics are differentially elicited and modulated. P2Y1 receptor agonist concentrations that elicited aggregation (pEC50 for ADP, 2-MeSADP; 5.88, 6.69) were 10-fold greater than those that elicited SC (7.33, 7.67). The magnitude of the aggregation response was agonist concentration-dependent, saturable and was associated with an agonist concentration-dependent deceleration of the deaggregation response. Gi-coupled receptor (alpha 2A-adrenoceptor, EP3 and P2Y12 receptors) agonists also enhanced aggregation through deceleration of the deaggregation response, and an inhibitor of PI3K activity (wortmannin) inhibited aggregation through acceleration of the deaggregation response. Neither treatment affected the extent or the kinetics of the SC response. The aggregation but not the SC response was rapidly desensitized by P2Y1 receptor activation by ADP. The affinity of the presence of a single P2Y1 receptor subtype. The differential characteristics and modulation of the SC and aggregation responses by a single receptor support the idea that different signaling pathways activated at different occupancy states of the same receptor underlie the two responses. P2Y1 receptor-mediated platelet aggregation and SC responses provide a convenient model for studying the phenomenon of agonist-directed signaling by differential occupancy of the same membrane receptor.