Characterization of a selective and potent antagonist of human P2X(7) receptors, AZ11645373.

BACKGROUND AND PURPOSE: The ATP-gated P2X(7) receptor has been shown to play a role in several inflammatory processes, making it an attractive target for anti-inflammatory drug discovery. We have recently identified a novel set of cyclic imide compounds that inhibited P2X(7) receptor-mediated dye uptake in human macrophage THP-1 cells. In this study the actions and selectivity of one of these compounds, AZ11645373, were characterized. EXPERIMENTAL APPROACH: We measured membrane currents, calcium influx, and YOPRO-1 uptake from HEK cells expressing individual P2X receptors, and YOPRO1 uptake and interleukin-1beta release from THP-1 cells in response to ATP and the ATP analogue benzoylbenzoyl ATP (BzATP). KEY RESULTS: AZ11645373 up to 10 microM, had no agonist or antagonist actions on membrane currents due to P2X receptor activation at human P2X(1), rat P2X(2), human P2X(3), rat P2X(2/3), human P2X(4), or human P2X(5) receptors expressed in HEK cells. AZ11645373 inhibited human P2X(7) receptor responses in HEK cells in a non-surmountable manner with K (B) values ranging from 5 - 20 nM, with mean values not significantly different between assays. K (B) values were not altered by removing extracellular calcium and magnesium. ATP-evoked IL-1beta release from lipopolysaccharide-activated THP-1 cells was inhibited by AZ11645373, IC(50) = 90 nM. AZ11645373 was > 500-fold less effective at inhibiting rat P2X(7) receptor-mediated currents with less than 50% inhibition occurring at 10 microM. CONCLUSIONS AND IMPLICATIONS: AZ11645373 is a highly selective and potent antagonist at human but not rat P2X(7) receptors and will have much practical value in studies of human cells.

Novel P2X7 receptor antagonists.

The synthesis and pharmacological evaluation of a new series of potent P2X(7) receptor antagonists is disclosed. The compounds inhibit BzATP-mediated pore formation in THP-1 cells. The distribution of the P2X(7) receptor in inflammatory cells, most notably the macrophage, mast cell and lymphocyte, suggests that P2X(7) antagonists have a significant role to play in the treatment of inflammatory disease.

Adventures in the pharmacological analysis of P2 receptors.

The pharmacological classification of P2 receptors owes its origin to the pioneering efforts of Geoff Burnstock and those who followed him, research that was conducted primarily in physiological experimental systems. Over recent years, the techniques of molecular biology have been increasingly applied in the study of P2 receptors while, at the same time, advances in their pharmacological analysis have been limited by a lack of potent and selective agonist or antagonist ligands. This has resulted in a classification scheme which is largely structural in nature, with relatively little contribution from pharmacology. Our endeavours in this area have been directed towards the discovery of ligands with which the pharmacological analysis and definition of P2 receptors could be advanced, the ultimate goal being the design of therapeutic agents. This article will describe some of our experiences in this challenging but rewarding area.

P2Y1-receptors in human platelets which are pharmacologically distinct from P2Y(ADP)-receptors.

1. In the present study we have classified the receptor(s) mediating increases in intracellular calcium concentration ([Ca2+]i) in human washed platelets and compared the pharmacological profile obtained with that observed in Jurkat cells, stably transfected with a bovine P2Y1-receptor. 2. The P2Y1-receptor antagonist, adenosine-3'-phosphate-5'-phosphate (A3P5P), competitively antagonized agonist responses in both Jurkat cells, and in platelets with similar affinities (pK(B) of 5.8 and 6.0, respectively). 3. The selective P2Y(ADP) antagonist, AR-C66096, exhibited partial agonism in the Jurkat cells with an affinity (pK(A)) of 4.9. This value is consistent with its known P2Y1-receptor activity. In platelets, AR-C66096 at a concentration (0.1 microM) approximately 100 fold greater than its known P2Y(ADP) receptor affinity, had no effect on ADP-induced increases in [Ca2+]i. 4. The ability of adenine nucleotide analogues to elevate [Ca2+]i in the Jurkat cells was also determined. The rank order of agonist potency (p[A]50) was: 2-MeSADP (8.3)>2-ClATP (7.8)>ADP (7.5)=2-MeSATP (7.4)>ATPgammaS (6.5)>ATP (6.2), with ATP appearing to be a partial agonist. 5. The same rank order of potency was observed when similar experiments were performed in platelets. However, the absolute potencies of all the agonists and the intrinsic activities of both ATPgammaS and ATP were lower in platelets. 6. The operational model of agonism was used to test whether the agonist concentration-effect profiles obtained in these two cell types could be explained on the basis of differences in receptor reserve. The analysis indicated that the data obtained in platelets closely resembled that predicted for a low density or poorly coupled P2Y1-receptor system. 7. The hypothesis that the observed partial agonist behaviour of ATP was the result of receptor activation by contaminating ADP with concomitant receptor blockade by ATP, was tested in the platelet system. This hypothesis was supported by a theoretical analysis, which yielded an affinity value for ATP similar to that obtained previously at P2Y1-receptors. 8. In summary, the results of this study indicate that human washed platelets contain P2Y1-receptors which mediate increases in [Ca2+]i and that this receptor population is pharmacologically distinct from P2Y(ADP)-receptors.

Pharmacological classification of alpha 1-adrenoceptors mediating contractions of rabbit isolated ear artery: comparison with rat isolated thoracic aorta.

1. The present study attempted to classify pharmacologically the alpha 1-adrenoceptor subtype(s) present in two isolated, vascular ring preparations, the rabbit ear artery and rat thoracic aorta. 2. In the ear artery, the agonist effects of phenylephrine were antagonized by 5-methyl urapidil (pA2 = 7.90; Schild slope = 0.85) and BMY 7378 (pA2 = 6.11; Schild slope = 0.80) but not in a simple competitive manner. The shallow Schild slopes are consistent with the activation of a heterogeneous receptor population. Indeed the 5-methyl urapidil data set could be fitted to a two-receptor model yielding a high antagonist affinity (pKBH) estimate of 7.85 and a low affinity (pKBL) estimate of 6.03. 3. The effects of clonidine in the ear artery were competitively antagonised by 5-methyl urapidil (pKB = 7.91) and BMY 7378 (pKB = 5.53). These data are consistent with contractions to clonidine being mediated by a single receptor subtype. 4. In the aorta, the effects of phenylephrine were antagonized by 5-methyl urapidil (pA2 = 7.95; Schild slope = 1.11) and BMY 7378 (pA2 = 9.08; Schild slope = 0.73). Neither data set was consistent with a simple competitive interaction. The BMY 7378 data suggested again, that phenylephrine was acting at a heterogeneous receptor population. Subsequent analysis by the two-receptor model yielded a high affinity (pKBH) estimate of 8.95 and a low affinity (pKBL) estimate of 7.00. 5. The alkylating agent, chloroethylclonidine (CEC) elicited concentration-dependent contractions in the ear artery with a potency (p[A]50) of 5.57. Pretreatment of this tissue with CEC (5 microM, 30 min incubation) had no effect on subsequent responses to phenylephrine. In contrast, in the aorta, CEC demonstrated no agonism but pretreatment with this agent (5 microM, 15 min incubation) caused a rightward shift and depression of subsequent phenylephrine concentration-effect curves. 6. The affinity of clonidine in the rabbit ear artery (pKA = 6.17) was found to be significantly different to its affinity in the rat thoracic aorta (pKA = 7.12) suggesting that this agonist activates different alpha 1-adrenoceptor subtypes in the two tissues. 7. These results suggest that heterogeneous populations of alpha 1-adrenoceptors are present in both tissues. In the ear artery, the profile of antagonist and agonist activity is most consistent with alpha 1A-adrenoceptors being the predominant receptor subtype. The second receptor population does not appear to correspond to any of the recognized alpha 1-adrenoceptor subtypes. In the aorta alpha 1D-adrenoceptors appear to predominate, with alpha 1A-adrenoceptors being the most likely candidate for the second receptor population.