Analysis of ligand activation of alpha 2-adrenoceptor subtypes under conditions of equal G alpha protein stoichiometry.

Abstract

Variations in the measurement of ligand's intrinsic activity between receptor subtypes is a common consequence of unequal receptor:G protein density ratios. We have investigated ligand activation at the alpha2-adrenoceptor (alpha2-AR) subtypes under defined expression conditions of one receptor molecule for one Galpha protein molecule using fusion proteins. Fusion between either a wt alpha2C AR or a mutant Thr382Lys alpha2C AR and a chimeric Galphaq/il protein displayed robust, transient (-)-adrenaline-mediated Ca2+ responses with similar potencies (pEC50: 7.78 and 7.66) and kinetic properties. A comparison of the intrinsic activities of alpha2 AR agonists found d-medetomidine to be the only compound with an efficacy similar to that of (-)-adrenaline. The Ca2+ responses as mediated by UK 14304, oxymetazoline and clonidine became more potent and efficacious at the Thr381Lys alpha2C AR, whereas the response as mediated by talipexole displayed a higher potency with an unaltered maximal response. Whereas only small differences in ligand's intrinsic activities between the wt alpha2A, alpha2B and alpha2C AR fusion proteins were observed with most ligands, oxymetazoline was virtually silent at the alpha2A AR while active as a partial and apparently full agonist at the alpha2C AR and alpha2B AR, respectively. The mutant alpha2 AR subtypes could be differentiated using the apparent positive efficacy of ligands that used to be defined as antagonists. The following rank order of maximal responses was observed for the Thr381Lys alpha2C AR: idazoxan approximately equals SKF 86466 > atipamezole >> dexefaroxan; Thr373Lys alpha2A AR: SKF 86466 > idazoxan = atipamezole > dexefaroxan; and Thr370Lys alpha2B AR: atipamezole > idazoxan dexefaroxan. RX 811059 (10 microM) was the only compound to be completely silent at both the wt and mutant alpha2 AR subtypes. In conclusion, silent alpha2 AR ligands are probably rare in these specified alpha2 AR systems. Most antagonists may actually possess partial agonist properties at the alpha2 AR subtypes, which are facilitated by the same mutation in the distal portion of their third intracellular loop.