Molecular mechanisms of ligand–receptor interactions in transmembrane domain V of the α 2A ‐adrenoceptor

The structural determinants of catechol hydroxyl interactions with adrenergic receptors were examined using 12 α 2 ‐adrenergic agonists and a panel of mutated human α 2A ‐adrenoceptors. The α 2A Ser201 mutant had a Cys → Ser201 (position 5.43) amino‐acid substitution, and α 2A Ser201Cys200 and α 2A Ser201Cys204 had Ser → Cys200 (5.42) and Ser → Cys204 (5.46) substitutions, respectively, in addition to the Cys → Ser201 substitution. Automated docking methods were used to predict the receptor interactions of the ligands. Radioligand‐binding assays and functional [ 35 S]GTP γ S‐binding assays were performed using transfected Chinese hamster ovary cells to experimentally corroborate the predicted binding modes. The hydroxyl groups of phenethylamines were found to have different effects on ligand affinity towards the activated and resting forms of the wild‐type α 2A ‐adrenoceptor. Substitution of Ser200 or Ser204 with cysteine caused a deterioration in the capability of catecholamines to activate the α 2A ‐adrenoceptor. The findings indicate that (i) Cys201 plays a significant role in the binding of catecholamine ligands and UK14,304 (for the latter, by a hydrophobic interaction), but Cys201 is not essential for receptor activation; (ii) Ser200 interacts with the meta ‐hydroxyl group of phenethylamine ligands, affecting both catecholamine binding and receptor activation; while (iii) substituting Ser204 with a cysteine interferes both with the binding of catecholamine ligands and with receptor activation, due to an interaction between Ser204 and the para ‐hydroxyl group of the catecholic ring.British Journal of Pharmacology (2003) 140 , 347–358. doi: 10.1038/sj.bjp.0705439