Selective coupling of prostaglandin E receptor EP3D to Gi and Gs through interaction of alpha-carboxylic acid of agonist and arginine residue of seventh transmembrane domain.

Prostaglandin (PG) E receptor EP3D is coupled to both Gi and Gs. To examine the roles of the interaction of alpha-carboxylic acid of PGE2 and its putative binding site, the arginine residue in the seventh transmembrane domain of EP3D, in receptor-G protein coupling, we have mutated the arginine residue to the noncharged glutamine. PGE2 with a negatively charged alpha-carboxylic acid and sulprostone, an EP3 agonist with a noncharged modified alpha-carboxylic acid, inhibited the forskolin-stimulated adenylate cyclase activity via Gi activation in the EP3D receptor in the same concentration-dependent manner. In contrast, the adenylate cyclase stimulation via Gs activation by sulprostone was much lower than that by PGE2. On the other hand, both PGE2 and sulprostone showed potent Gi activity but failed to show Gs activity in the mutant receptor. EP3D receptor showed a high affinity binding for PGE2 in the form coupled to either Gi or Gs. Although the mutant receptor showed high affinity binding when coupled to Gi, it lost high affinity binding in the condition of Gs coupling. Furthermore, sulprostone bound to the Gi-coupled EP3D receptor with higher affinity than the Gs-coupled receptor. Among various EP3 agonists, alpha-carboxylic acid-unmodified agonists showed both Gi and Gs activities, but the modified agonists showed only Gi activity. These findings suggest that the interaction between the alpha-carboxylic acid of PGE2 and the arginine residue of the receptor regulates the selectivity of the G protein coupling.