Distinct roles for protein kinase C isoforms in regulating platelet purinergic receptor function

ADP is a critical regulator of platelet activation, mediating its actions through two G protein-coupled receptors (GPCRs), P2Y1 and P2Y12. We have shown previously that the receptors are functionally desensitized, in a homologous manner, by distinct kinase-dependent mechanisms in which P2Y1 is regulated by protein kinase C (PKC) and P2Y12 by G protein-coupled receptor kinases. In this study, we addressed whether different PKC isoforms play different roles in regulating the trafficking and activity of these two GPCRs. Expression of PKCalpha and PKCdelta dominant-negative mutants in 1321N1 cells revealed that both isoforms regulated P2Y1 receptor signaling and trafficking, although only PKCdelta was capable of regulating P2Y12, in experiments in which PKC was directly activated by the phorbol ester phorbol 12-myristate 13-acetate (PMA). These results were paralleled in human platelets, in which PMA reduced subsequent ADP-induced P2Y1 and P2Y12 receptor signaling. PKC isoform-selective inhibitors revealed that novel, but not conventional, isoforms of PKC regulate P2Y12 function, whereas both novel and classic isoforms regulate P2Y1 activity. It is also noteworthy that we studied receptor internalization in platelets by a radioligand binding approach showing that both receptors internalize rapidly in these cells. ADP-induced P2Y1 receptor internalization is attenuated by PKC inhibitors, whereas that of the P2Y12 receptor is unaffected. Both P2Y1 and P2Y12 receptors can also undergo PMA-stimulated internalization, and here again, novel but not classic PKCs regulate P2Y12, whereas both novel and classic isoforms regulate P2Y1 internalization. This study therefore is the first to reveal distinct roles for PKC isoforms in the regulation of platelet P2Y receptor function and trafficking.     

Biology and pharmacology of the platelet P2Y12 receptor

Platelets possess two receptors for ADP, P2Y(1) and P2Y(12). ADP is released from platelet dense granules upon platelet activation by numerous agonists and thereby amplifies platelet responses regardless of the initial stimulus. The P2Y(1) receptor is one of many platelet receptors coupled to Gq and initiates ADP-induced activation. The P2Y(12) receptor on the other hand is linked to Gi and plays a special role in the amplification of platelet activation initiated by numerous other pathways. Platelet activation leads to a range of responses that play a critical role in arterial thrombosis and the inflammatory responses associated with this, including platelet aggregation, dense and alpha granule secretion and procoagulant activity. P2Y(12) receptor activation yields powerful amplification of these processes such that P2Y(12) receptor antagonists may have dramatic inhibitory effects on platelet function regardless of the activating stimuli. This phenomenon, coupled with the restricted distribution of the P2Y(12) receptor in humans, makes the receptor an ideal target for pharmaceutical therapy. This has already been established by the therapeutic success of clopidogrel, which acts, via an active metabolite, on this receptor. However, current therapeutic regimens of clopidogrel yield variable and incomplete P2Y(12) receptor blockade and more effective strategies to block P2Y(12) receptor activation offer the potential of greater clinical efficacy.     

Identification of a potent inverse agonist at a constitutively active mutant of human P2Y12 receptor

Human platelets express two P2Y receptors: G(q)-coupled P2Y(1), and G(i)-coupled P2Y(12). Both P2Y(1) and P2Y(12) are ADP receptors on human platelets and are essential for ADP-induced platelet aggregation that plays pivotal roles in thrombosis and hemostasis. Numerous constitutively active G protein-coupled receptors have been described in natural or recombinant systems, but in the P2Y receptors, to date, no constitutive activity has been reported. In our effort to identify G protein coupling domains of the human platelet ADP receptor, we constructed a chimeric hemagglutinin-tagged human P2Y(12) receptor with its C terminus replaced by the corresponding part of human P2Y(1) receptor and stably expressed it in Chinese hamster ovary-K1 cells. It is interesting that the chimeric P2Y(12) mutant exhibited a high level of constitutive activity, as evidenced by decreased cAMP levels in the absence of agonists. The constitutive activation of the chimeric P2Y(12) mutant was dramatically inhibited by pertussis toxin, a G(i) inhibitor. The constitutively active P2Y(12) mutant retained normal responses to 2-methylthio-ADP, with an EC(50) of 0.15 +/- 0.04 nM. The constitutively active P2Y(12) mutant caused Akt phosphorylation that was abolished by the addition of pertussis toxin. Pharmacological evaluation of several P2Y(12) antagonists revealed (E)-N-[1-[7-(hexylamino)-5-(propylthio)-3H-1,2,3-triazolo-[4,5-d]-pyrimidin-3-yl]-1,5,6-trideoxy-beta-d-ribo-hept-5-enofuranuronoyl]-l-aspartic acid (AR-C78511) as a potent P2Y(12) inverse agonist and 5'-adenylic acid, N-[2-(methylthio)ethyl]-2-[(3,3,3-trifluoropropyl)thio]-, monoanhydride with (dichloromethylene)bis[phosphonic acid] (AR-C69931MX) as a neutral antagonist. In conclusion, this is the first report of a cell line stably expressing a constitutively active mutant of human platelet P2Y(12) receptor and the identification of potent inverse agonist.     

ADP receptors--targets for developing antithrombotic agents

Platelet P2 receptors--P2Y1, P2Y12, and P2X1--constitute the means by which adenine nucleotides can activate platelets. Coactivation of the Galphaq-coupled P2Y1 and Galphai2-coupled P2Y12 receptors is necessary for ADP-mediated platelet activation, which forms the basis of using P2 antagonists as antithrombotic drugs. P2Y1 receptor antagonists inhibit platelet activation, while P2Y1 knockout mice show longer bleeding times than normal mice but few other problems; however, its ubiquitous expression in other tissues renders P2Y1 questionable as an antithrombotic target. The P2Y12 receptor is expressed nearly exclusively in platelets and brain, making it an attractive antithrombotic target. Antagonists for the P2Y12 receptor have been developed that either require metabolic activation to covalently inhibit P2Y12 and are irreversible, or simply are competitive in nature and thus reversible. Ticlopidine and clopidogrel are irreversible P2Y12 antagonists and have been repeatedly proven as clinical antithrombotic agents. In addition, a recently reported P2Y12 antagonist, CS-747, shows promise as a future antithrombotic drug. The AR-C series of compounds represent reversible P2Y12 antagonists and have been used extensively to characterize the function of P2Y12 in platelets. Clinical studies show that AR-C69931MX is as effective as clopidogrel; furthermore, the combination of AR-C69931MX (cangrelor) and clopidogrel confers greater antagonism of P2Y12 than either antagonist alone. The P2X1 receptor is a calcium channel that functions to potentiate agonist-induced platelet shape change, and its inhibition or loss has little if any effect on hemostasis. A combination of P2Y1 and P2Y12 antagonists may represent an additional course of antithrombotic treatment.     

ADP receptor antagonists as antiplatelet therapeutics

With the cloning of the P2Y12 receptor, the molecular basis for ADP-induced platelet aggregation is seemingly complete. Two platelet-bound ADP receptors, P2Y1 and P2Y12, operate through unique pathways to induce and sustain platelet aggregation via the glycoprotein (GP)IIb-IIIa integrin. P2Y1 operates via a glycoprotein q (Gq) pathway, activates phospholipase C, induces platelet shape change and is responsible for intracellular calcium mobilisation. P2Y12 inhibits adenylyl cyclase through a glycoprotein i (Gi)-dependent pathway, and is the target of the clinically used thienopyridines, ticlopidine (Ticlid, F. Hoffman-La Roche) and clopidogrel (Plavix, Bristol-Myers Squibb/Sanofi-Synthelabo). In addition, the receptor is targeted by the ADP analogue AR-C66096, which is currently in Phase IIb clinical trials, as well as other non-nucleoside-based preclinical leads.     

The platelet ATP and ADP receptors

Adenine nucleotides, ADP and ATP, are coreleased from dense granules during platelet activation, as well as from endothelial cells and damaged red blood cells following vascular injury. Through autocrine and paracrine mechanisms, these extracellular signaling molecules interact with the platelet P2 receptors to amplify ongoing platelet activation. Two receptors for ADP, the G(q)-protein-coupled P2Y1 and G(i)-protein-coupled P2Y12 and one receptor for ATP, the P2X1 ion channel, have been identified on platelets. Due to distinct pharmacological properties and differential regulation, the P2Y and P2X receptors essentially operate on different scales of time and distance and trigger selective intracellular signaling cascades. Recent advances in the understanding of the P2Y receptor physiology have reinforced the concept of these receptors as useful targets for antithrombotic therapy. The function of P2X1 in platelet activation only recently started to be unraveled. This review focuses on recent findings on the physiology of these platelet ADP and ATP receptors, their distinct downstream intracellular signaling pathways as well as on the available agonists, antagonists and inhibitors that allow their pharmacological discrimination.     

Validation of a VerifyNow-P2Y12 cartridge for monitoring platelet inhibition with clopidogrel

Despite common use of clopidogrel in patients with vascular disease, monitoring of platelet inhibition is still not conventional in clinical practice. Considering substantial response variability, when some patients may experience inadequate protection, and/or increased risk of bleeding, simple and reliable methods to control adequate antiplatelet regimen is mandatory. We validated a new VerifyNow-P2Y12 assay to measure inhibition of the P2Y12 platelet receptors by clopidogrel by evaluating its receptor specificity, precision, and potential interference with platelet count, hematocrit, age, cholesterol, triglycerides, and other antiplatelet agents. Platelet aggregation induced by ADP or ADP + prostaglandin E1 (ADP + PGE1) in the presence of specific P2Y12 inhibitor 2-methylthio-AMP (2MeSAMP) for the assessment of assay specificity was performed in 10 volunteers. Seventeen medications were used for the VerifyNow-P2Y12 interference testing, and assay interplay with blood constituents was evaluated in a clinical setting in 131 patients with coronary artery disease. In the presence of 2MeSAMP, the average residual aggregation level across the 10 donors was 27% for ADP and 5% for ADP + PGE1. There also was a strong agreement between ADP + PGE1 aggregometry and VerifyNow-P2Y12 assay (93% vs. 95% average inhibition across all donors). The coefficient of variation for the test precision was less than 8%. The VerifyNow-P2Y12 readings were not influenced by age, platelet count, hematocrit, fibrinogen, cholesterol, or triglycerides level. There was an interference with abciximab before P2Y12 inhibition; however, after platelet suppression with cilostazol, the interference with all tested substances was minimal. VerifyNow-P2Y12 is a reliable, simple, and sensitive device suitable for monitoring of P2Y12 platelet receptor inhibitors in the clinical arena.     

2-Alkylthio-substituted platelet P2Y12 receptor antagonists reveal pharmacological identity between the rat brain Gi-linked ADP receptors and P2Y12

The Gi-linked platelet ADP receptor, now designated as P2Y12, accounts for ADP-induced inhibition of adenylyl cyclase in platelets and certain clonal rat cell lines. The pharmacology of this receptor is well characterized. Based on the functional approach of [35S]GTPgammaS autoradiography, we recently disclosed the widespread presence of Gi-linked ADP receptors in the rat nervous system. Based on initial pharmacological analysis, these receptors were strikingly similar with P2Y12. Here, we extend this analysis by comparing the potencies of six 2-alkylthio-substituted ATP analogues, including the adenosine-aspartate conjugate 2-hexylthio-AdoOC(O)Asp2 and five AR-C compounds (AR-C67085, AR-C69931, AR-C78511, AR-C69581, AR-C70300) with wide range of affinities towards P2Y12, in reversing 2-methylthio-ADP stimulated G protein activity in rat brain sections and human platelet membranes. Closely matching pIC50 values (r2=0.99) revealed pharmacological similarity between the two receptors with one exception: AR-C67085 more avidly recognized the platelet P2Y12. Further analysis of the rat brain pIC50 data against those available for three of the AR-C compounds in reversing P2Y12-mediated adenylyl cyclase inhibition in rat platelets (r2=0.96) and rat C6 glioma cells (r2=1.00) demonstrated that the three P2Y receptors are pharmacologically indistinguishable. We conclude that the rat brain Gi-linked ADP receptors, as revealed using [35S]GTPgammaS autoradiography, correspond to P2Y12.     

Pharmacokinetic, pharmacodynamic and pharmacogenetic profile of the oral antiplatelet agent ticagrelor

Acute coronary syndromes (ACS) remain life-threatening disorders associated with high morbidity and mortality, despite advances in treatment over the last decade. Adenosine diphosphate-induced platelet activation via P2Y(12) receptors plays a pivotal role in the pathophysiology of ACS. The current standard of treatment involves dual antiplatelet therapy with aspirin (acetylsalicylic acid) and the thienopyridine clopidogrel. Numerous studies and wide use in clinical practice have established the value of this approach in the treatment of ACS. However, clopidogrel treatment has a number of limitations, including a delayed onset of action due to the need for metabolic activation, variable and reduced antiplatelet effects in patients with certain genotypes, and prolonged recovery of platelet function due to irreversible P2Y(12) receptor binding. Prasugrel, a new thienopyridine, has demonstrated more consistent inhibition of platelet aggregation (IPA) than clopidogrel, although this thienopyridine also requires metabolic activation and treatment is associated with a significantly increased risk of life-threatening and fatal bleeding. The recently approved oral antiplatelet agent ticagrelor has the potential to overcome some of the limitations of current therapy due to its unique pharmacokinetic and pharmacodynamic profiles. It is a member of a new chemical class, the cyclopentyltriazolopyrimidines, and is a potent P2Y(12) receptor antagonist. Ticagrelor is rapidly absorbed, with a median time to maximum concentration of 1.3-2.0 hours. Ticagrelor does not require metabolic activation to an active form and binds rapidly and reversibly to the P2Y(12) receptor. As well as exerting effects via platelet P2Y(12) receptors, ticagrelor may confer additional benefits via inhibition of non-platelet P2Y(12) receptors. The pharmacokinetic profile of ticagrelor is not significantly affected by age, gender or administration with food, nor by prior treatment with, or responsiveness to, clopidogrel. Ticagrelor is primarily metabolized via the cytochrome P450 (CYP) 3A4 enzyme, rapidly produces plasma concentration-dependent IPA that is greater and more consistent than that observed with clopidogrel, and can also enhance platelet inhibition and overcome non-responsiveness in patients previously treated with clopidogrel. Importantly, the pharmacodynamic characteristics of ticagrelor are not influenced by CYP2C19 and ABCB1 genotypes. This article summarizes our current knowledge regarding the pharmacokinetic, pharmacodynamic and pharmacogenetic profile of ticagrelor.     

ADP receptors: inhibitory strategies for antiplatelet therapy

The interaction of adenosine-5'-diphosphate (ADP) with its platelet receptors (P2Y(1) and P2Y(12)) plays a very important role in thrombogenesis. The thienopyridine ticlopidine was the first specific antagonist of the platelet P2Y(12) ADP receptor to be tested in randomized clinical trials for the prevention of arterial thrombotic events. Although ticlopidine reduces the incidence of vascular events in patients at risk, it also unfortunately has some significant drawbacks: a relatively high incidence of toxic effects, which may be fatal in some cases; delayed onset of action; and a high interindividual variability in response. A second thienopyridine, clopidogrel, has superseded ticlopidine, because it is also an efficacious antithrombotic drug and is less toxic than ticlopidine. However, clopidogrel is not completely free from faults: severe toxic effects, albeit occurring much less frequently than with ticlopidine, may still complicate its administration to patients; the onset of pharmacologic action can be accelerated by the use of large loading doses, but may still not be optimal; the high interpatient variability in response remains an important issue. These concerns justify the continued search for agents that can further improve the clinical outcome of patients with atherosclerosis through greater efficacy and/or safety. A new thienopyridyl compound, prasugrel, which is characterized by higher potency and faster onset of action compared with clopidogrel, is currently under clinical evaluation. Two direct and reversible P2Y(12) antagonists, cangrelor and AZD6140, feature very rapid onset and reversal of platelet inhibition, which make them attractive alternatives to thienopyridines, especially when rapid inhibition of platelet aggregation or its quick reversal are required. Along with new the P2Y(12) antagonists, inhibitors of the other platelet receptor for ADP, the antagonists P2Y(1), are under development and may prove to be effective antithrombotic agents.     

ADP Receptor Antagonism

ADP is one of the most important mediators of both physiologic hemostasis and thrombosis. Development and utilization of agents that block ADP receptors on the platelet membrane, namely thienopyridines, has represented a major advancement for treatment of patients undergoing percutaneous coronary interventions and those with acute coronary syndromes. Currently, clopidogrel, a second-generation thienopyridine that inhibits the ADP P2Y(12) receptor, represents the treatment of choice, in addition to aspirin, for the prevention of stent thrombosis. Further, long-term adjunctive use of this ADP P2Y(12) receptor antagonist is also associated with improved clinical outcomes in high-risk patients, and represents the standard of care for these patients. Despite the unambiguous clinical benefit associated with clopidogrel, accumulating experience with this drug has also led to identification of some of its drawbacks, which are related to inadequate platelet inhibition with standard dosage regimens as well as to its irreversible antiplatelet effects. This has led to the questioning of currently recommended clopidogrel dosage regimens as well as to the development of novel and more potent ADP P2Y(12) receptor antagonists, some of which are also reversible agents. Numerous studies are currently ongoing with the objective of demonstrating how more potent platelet inhibition using higher loading and maintenance dose regimens of clopidogrel or novel ADP P2Y(12) receptor antagonists - such as prasugrel, ticagrelor (AZD 6140) and cangrelor - will affect clinical outcomes. This article reviews the current knowledge of platelet ADP P2Y(12) receptor antagonism and the projected developments in this field.     

Selective blockade of P2Y12 receptors by prasugrel inhibits myocardial infarction induced by thrombotic coronary artery occlusion in rats

We evaluated the effects of prasugrel, a third-generation thienopyridyl prodrug, on P2Y12 receptors, adenosine 5'-diphosphate (ADP)-induced platelet aggregation, and myocardial infarction (MI) in rats. Oral administration of prasugrel (0.3-3 mg/kg) resulted in the dose-related inhibition of washed platelet aggregation induced by ADP (1-10 μM). Ex vivo [H]-2-MeS-ADP binding to platelet P2Y12 receptors was also inhibited by prasugrel in a similar dose range. The antiaggregatory effects of prasugrel correlated strongly with P2Y12 blockade with correlation coefficients of 0.85-0.92, suggesting that the antiaggregatory activity of prasugrel largely reflected P2Y12 blockade achieved in vivo. We further examined the effects of the in vivo P2Y12 inhibition by prasugrel (1-10 mg/kg, po) on MI induced by thrombotic coronary artery occlusion in rats. In surviving rats, infarct size at 24 hours after photoirradiation was evaluated. In the vehicle group, necrosis area/total left ventricular area was 37.9% ± 6.8% (mean ± SE, n = 7). At all prasugrel doses tested (n = 7 for each dose), necrosis area/total left ventricular area was significantly smaller than that in the vehicle group: 14.4% ± 4.0% for 1 mg/kg (P < 0.01), 19.8% ± 4.5% for 3 mg/kg (P < 0.05), and 14.8% ± 3.6% for 10 mg/kg (P < 0.01). At the highest administered dose of prasugrel (10 mg/kg), blood pressure and heart rate were unchanged. Arrhythmia was observed in 5 of 7 animals in the vehicle group at 24 hours after irradiation; in contrast, no arrhythmia was found in the group treated with prasugrel (10 mg/kg). Taken together, these results demonstrate that prasugrel is a selective P2Y12 inhibitor in vivo, providing effective inhibition of platelet aggregation and MI in rats.     

The influence of P2Y12 receptor deficiency on the platelet inhibitory activities of prasugrel in a mouse model: evidence for specific inhibition of P2Y12 receptors by prasugrel

Prasugrel is a novel orally active thienopyridine with faster, higher and more reliable inhibition of platelet aggregation than clopidogrel reflecting its metabolism in vivo to an active metabolite with selective P2Y(12) antagonistic activity. Several lines of evidence support the contention that prasugrel provides selective P2Y(12) receptor antagonistic activity. To date, however, direct evidence of P2Y(12) specific action by prasugrel in vivo is limited. In the present study, effects of prasugrel on ex vivo platelet aggregation were examined in wild type (WT) and P2Y(12)(-/-) mice. In WT mice, prasugrel showed platelet inhibition that was 8.2 times more potent than clopidogrel. In P2Y(12)(-/-) mice, ADP induced platelet aggregation was minimal, and its extent was similar to that in prasugrel-treated WT mice. In addition, no further inhibition of platelet aggregation was observed after administration of prasugrel to P2Y(12)(-/-) mice. Furthermore, prasugrel-treated WT mice showed similar aggregation patterns using collagen- and murine PAR-4 agonist peptide to those of P2Y(12)(-/-) mice treated with vehicle or prasugrel. Overall, these results clearly provide additional in vivo evidence that prasugrel has selective P2Y(12) antagonistic activity.     

Characterization of a new peptide agonist of the protease-activated receptor-1

A new peptide (TFRRRLSRATR), derived from the c-terminal of human platelet P2Y(1) receptor, was synthesized and its biological function was evaluated. This peptide activated platelets in a concentration-dependent manner, causing shape change, aggregation, secretion and calcium mobilization. Of the several receptor antagonists tested, only BMS200261, a protease activated receptor 1 (PAR-1) specific antagonist, totally abolished the peptide-induced platelet aggregation, secretion and calcium mobilization. The TFRRR-peptide-pretreated washed platelets failed to aggregate in response to SFLLRN (10 microM) but not to AYPGKF (500 microM). In addition, in mouse platelets, peptide concentrations up to 600 microM failed to cause platelet activation, indicating that the TFRRR-peptide activated platelets through the PAR-1 receptor, rather than through the PAR-4 receptor. The shape change induced by 10 microM peptide was totally abolished by Y-27632, an inhibitor of p160(ROCK) which is a downstream mediator of G12/13 pathways. The TFRRR-peptide, YFLLRNP, and the physiological agonist thrombin selectively activated G12/13 pathways at low concentrations and began to activate both Gq and G12/13 pathways with increasing concentrations. Similar to SFLLRN, the TFRRR-peptide caused phosphorylation of Akt and Erk in a P2Y(12) receptor-dependent manner, and p-38 MAP kinase activation in a P2Y(12)-independent manner. The effects of this peptide are elicited by the first six amino acids (TFRRRL) whereas the remaining peptide (LSRATR), TFERRN, or TFEERN had no effects on platelets. We conclude that TFRRRL activates human platelets through PAR-1 receptors.     

Acyclic analogues of adenosine bisphosphates as P2Y receptor antagonists: phosphate substitution leads to multiple pathways of inhibition of platelet aggregation

Activation by ADP of both P2Y(1) and P2Y(12) receptors in platelets contributes to platelet aggregation, and antagonists at these receptor subtypes have antithrombotic properties. In an earlier publication, we have characterized the SAR as P2Y(1) receptor antagonists of acyclic analogues of adenine nucleotides, containing two phosphate groups on a symmetrically branched aliphatic chain, attached at the 9-position of adenine. In this study, we have focused on antiaggregatory effects of P2Y antagonists related to a 2-chloro-N(6)-methyladenine-9-(2-methylpropyl) scaffold, containing uncharged substitutions of the phosphate groups. For the known nucleotide (cyclic and acyclic) bisphosphate antagonists of P2Y(1) receptors, there was a significant correlation between inhibition of aggregation induced by 3.3 microM ADP in rat platelets and inhibition of P2Y(1) receptor-induced phospholipase C (PLC) activity previously determined in turkey erythrocytes. Substitution of the phosphate groups with nonhydrolyzable phosphonate groups preserved platelet antiaggregatory activity. Substitution of one of the phosphate groups with O-acyl greatly reduced the inhibitory potency, which tended to increase upon replacement of both phosphate moieties of the acyclic derivatives with uncharged (e.g., ester) groups. In the series of nonsymmetrically substituted monophosphates, the optimal antagonist potency occurred with the phenylcarbamate group. Among symmetrical diester derivatives, the optimal antagonist potency occurred with the di(phenylacetyl) group. A dipivaloyl derivative, a representative uncharged diester, inhibited ADP-induced aggregation in both rat (K(I) 3.6 microM) and human platelets. It antagonized the ADP-induced inhibition of the cyclic AMP pathway in rat platelets (IC(50) 7 microM) but did not affect hP2Y(1) receptor-induced PLC activity measured in transfected astrocytoma cells. We propose that the uncharged derivatives are acting as antagonists of a parallel pro-aggregatory receptor present on platelets, that is, the P2Y(12) receptor. Thus, different substitution of the same nucleoside scaffold can target either of two P2Y receptors in platelets.     

Differential regulation and relocalization of the platelet P2Y receptors after activation: a way to avoid loss of hemostatic properties?

In the present study, we investigated the desensitization and trafficking of the P2Y1 and P2Y12 receptors after agonist-induced stimulation of platelets or astrocytoma cells transfected with the P2Y1 or P2Y12 receptors fused to green fluorescent protein. In platelets and in transfected cells, exposure to 10 microM ADP caused desensitization of the P2Y1 receptor-driven calcium signal, whereas the P2Y12 receptor-mediated inhibition of cAMP formation was not affected. Plasma membranes from ADP-stimulated platelets also retained P2Y12 activity. Agonist-induced P2Y1 receptor desensitization was accompanied by its internalization in platelets and transfected cells. In contrast, although a substantial fraction of P2Y12 receptors was rapidly and transiently internalized, most of the P2Y12 receptors remained at the plasma membrane. Activated P2Y1 receptors were internalized through a clathrin-dependent pathway in cells and platelets, whereas the P2Y12 receptors seemed to use a distinct, clathrin-independent pathway. Together, these data indicate that the P2Y1 and P2Y12 receptors are differentially regulated upon activation. The absence of desensitization of the Gi protein-coupled P2Y12 receptor-dependent responses could represent a mechanism to preserve the hemostatic properties of otherwise unresponsive platelets.     

P2Y receptor antagonists in thrombosis

The dual role of P2Y1 and P2Y12 receptors in platelet aggregation by ADP has been firmly established, based on the action of selective inhibitors, gene targeting in mice and human genetic evidence. Both of these receptor subtypes constitute targets for antithrombotic agents, and compounds with a dual action might also be of interest. However, the agents currently on the market (ticlopidine and clopidogrel), or known to be in development (cangrelor, AZD-6140 and prasugrel), all target the P2Y12 receptor. The thienopyridines (ticlopidine, clopidogrel and prasugrel) irreversibly inactivate the P2Y12 receptor via the covalent binding of an active metabolite generated in the liver, while the other compounds are competitive antagonists. Cangrelor, an ATP derivative, is suitable for intravenous perfusion, whereas AZD-6140 is in clinical development as an orally active agent.     

The Role of P2Y Receptors in the Control of Blood Pressure

Extracellular nucleotides have been implicated in a number of physiological functions. Nucleotides act on cell-surface receptors known as P2 receptors, of which several subtypes have been cloned. P2X receptors are ligand-gated ion channels, whereas P2Y receptors belong to the superfamily of G-protein-coupled receptors. The human P2Y-receptor family is composed of seven subtypes (P2Y(1), P2Y(2), P2Y(4), P2Y(6), P2Y(11), P2Y(12), P2Y(13)). The principal physiological agonists of the human P2Y receptors are ADP (P2Y(1), P2Y(12), P2Y(13)), UTP/ATP (P2Y(2)), UTP (P2Y(4)), UDP (P2Y(6)) and ATP (P2Y(11)). P2Y receptors are widely expressed in human tissues, and many subtypes are found in vascular smooth muscle cells and endothelial cells in blood vessels. The intracellular signaling of P2Y receptors is very complex. Activation of P2Y receptors in blood vessels induces vasodilation or vasoconstriction, prolifera- tion of vascular smooth muscle cells and Ca(2+)-sensitization. All mechanisms play an important role in blood pressure control and cardiovascular disease. (c) 2002 Prous Science. All rights reserved.     

New perspectives in antiplatelet therapy

Platelet activation is a complex mechanism of response to vascular injury and atherothrombotic disease, leading to thrombus formation. A wide variety of surface receptors -integrins, leucine-rich family receptors, G protein coupled receptors, tyrosine kinase receptors- and intraplatelet molecules support and regulate platelet activation. They are potential targets of antiplatelet therapy for the prevention and treatment of arterial thrombosis. Despite the overall clinical benefit of established antiplatelet drugs targeting cyclooxigenase-1 (COX-1), glycoprotein integrin αIIbβ3, and the purinergic P2Y(12) receptor of adenosine diphosphate, a significant proportion of treated patients continue to experience recurrent ischaemic events. This may be in partly attributed to insufficient inhibition of platelet activation. In addition, it should not be underestimated that these drugs are not immune from bleeding complications. The substantial progress in understating the regulation of platelet activation has played a key role in the development of novel antiplatelet agents. Current examples of drug under development and evaluation include: novel P2Y(12) receptor inhibitors (prasugrel, ticagrelor, cangrelor, and elinogrel), thrombin receptor PAR-1 antagonists (vorapaxar, atopaxar), new integrin glycoprotein IIb/IIIa inhibitors, and inhibitors targeting the thromboxane receptor (TP), phosphodiesterases, the collagen receptor glycoprotein VI, and intraplatelet signalling molecules. This review summarizes the mechanisms of action and current clinical evaluation of these novel antiplatelet agents.