Rat prostaglandin EP3 receptor is highly promiscuous and is the sole prostanoid receptor family member that regulates INS-1 (832/3) cell glucose-stimulated insulin secretion.

Chronic elevations in fatty acid metabolites termed prostaglandins can be found in circulation and in pancreatic islets from mice or humans with diabetes and have been suggested as contributing to the ß-cell dysfunction of the disease. Two-series prostaglandins bind to a family of G-protein-coupled receptors, each with different biochemical and pharmacological properties. Prostaglandin E receptor (EP) subfamily agonists and antagonists have been shown to influence ß-cell insulin secretion, replication, and/or survival. Here, we define EP3 as the sole prostanoid receptor family member expressed in a rat ß-cell-derived line that regulates glucose-stimulated insulin secretion. Several other agonists classically understood as selective for other prostanoid receptor family members also reduce glucose-stimulated insulin secretion, but these effects are only observed at relatively high concentrations, and, using a well-characterized EP3-specific antagonist, are mediated solely by cross-reactivity with rat EP3. Our findings confirm the critical role of EP3 in regulating ß-cell function, but are also of general interest, as many agonists supposedly selective for other prostanoid receptor family members are also full and efficacious agonists of EP3. Therefore, care must be taken when interpreting experimental results from cells or cell lines that also express EP3.

Interaction of prostanoid EP3 and TP receptors in guinea-pig isolated aorta: contractile self-synergism of 11-deoxy-16,16-dimethyl PGE2.

BACKGROUND AND PURPOSE: Surprisingly high contractile activity was reported for 11-deoxy-16,16-dimethyl prostaglandin E2 (DX-DM PGE2) on pig cerebral artery when used as a selective EP3 receptor agonist. This study investigated the selectivity profile of DX-DM PGE2, focusing on the interaction between its EP3 and TP (thromboxane A2-like) agonist activities. EXPERIMENTAL APPROACH: Contraction of guinea-pig trachea (EP1 system) and aorta (EP3 and TP systems) was measured in conventional organ baths. KEY RESULTS: Strong contraction of guinea-pig aorta to sulprostone and 17-phenyl PGE2 (EP3 agonists) was only seen under priming with a second contractile agent such as phenylephrine, histamine or U-46619 (TP agonist). In contrast, DX-DM PGE2 induced strong contraction, which on the basis of treatment with (DG)-3ap (EP3 antagonist) and/or BMS-180291 (TP antagonist) was attributed to self-synergism arising from co-activation of EP3 and TP receptors. EP3/TP self-synergism also accounted for contraction induced by PGF(2α) and its analogues (+)-cloprostenol and latanoprost-FA. DX-DM PGE2 also showed significant EP1 agonism on guinea-pig trachea as defined by the EP1 antagonists SC-51322, (ONO)-5-methyl-1 and AH-6809, although AH-6809 exhibited poor specificity at concentrations ≥3 µM. CONCLUSIONS AND IMPLICATIONS: EP3/TP self-synergism, as seen with PGE/PGF analogues in this study, may confound EP3 agonist potency comparisons and the characterization of prostanoid receptor systems. The competitive profile of a TP antagonist may be distorted by variation in the silent/overt contraction profile of the EP3 system in different studies. The relevance of self-synergism to in vivo actions of natural prostanoid receptor agonists is discussed.