PACAP (6-27)

In these structure activity studies, the 46 analogs of the 27-amino-acid form of the pituitary-adenylate-cyclase-activating peptide, PACAP(1-27), and the 38-amino-acid form, PACAP(1-38), were either monosubstituted or bisubstituted at positions 1-3, 20 and 21 or N-terminally shortened. All analogs were compared on human neuroblastoma NB-OK-1 cell membranes for their ability to occupy 125I-[AcHis1]PACAP(1-27)-labelled receptors (AcHis, N alpha-acetylhistidine) and to activate adenylate cyclase (in terms of potency and intrinsic activity). The monophasic slope of dose/effect curves on both parameters suggested interaction with one class of PACAP receptor. Residues 28-38 in the C-terminally extended peptide, PACAP(1-38), played a favorable role in recognition, in that receptors coupled to adenylate cyclase were, in general, more sensitive to PACAP(1-38) analogs than to the corresponding PACAP(1-27) analogs. At variance with PACAP(6-27), PACAP(6-38) was well recognized and acted as a potent competitive antagonist (Ki 1.5 nM). Residues 1-3 were all important in enzyme activation: modification of the beta-turn potential gave full agonists (the LAla2 and DAla2 derivatives) or partial agonists (LPhe2 and DPhe2; LArg2 and DArg2; Glu3 and Asn3). Finally, a proper alpha-helix was also important: the combined substitution of Lys21/Lys22 by Gly21/Gly22 decreased the binding affinity sharply.

The existence of specific receptors for the two PACAPs (Pituitary Adenylate Cyclase Activating Peptides of 27 and 38 amino acids) was previously demonstrated on membranes from the pancreatic acinar cell line AR 4-2J (Buscail et al., FEBS Lett. 202, 77-81, 1990) by [125I]PACAP-27 binding. Here we demonstrate, by comparing Scatchard analysis of saturation curves and competition binding curves obtained with [125I]PACAP-27 and [125I]PACAP-38 as radioligands, the coexistence of two classes of receptors: 1/PACAP-A receptors that recognize PACAP-27 and PACAP-38 with the same high affinity (Kd 0.3 nM) and 2/PACAP-B receptors that recognize PACAP-38 with a high affinity (Kd 0.3 nM) and PACAP-27 with a lower affinity (Kd 30 nM). These two receptors are coupled to adenylate cyclase but can be clearly distinguished by the ability of PACAP(6-27) to specifically inhibit PACAP-27 adenylate cyclase activation.

We investigated the effects of a neuropeptide, pituitary adenylate cyclase-activating polypeptide- (PACAP) 27, on the sinoatrial nodal pacemaker activity and the mechanisms for the cardiac effects of PACAP-27 in the autonomically decentralized heart of the anesthetized dog. PACAP-27 (0.01-0.3 nmol) injected into the sinus node artery increased followed by decreased sinus rate. PACAP-27 (0.1 and 0.3 nmol) caused atrial fibrillation spontaneously. After atropine, PACAP-27 never decreased but only increased sinus rate as did vasoactive intestinal peptide. However, propranolol did not affect the negative and positive chronotropic effects. Tetrodotoxin but not hexamethonium abolished the negative chronotropic response to PACAP-27 in atropine nontreated dogs, and tetrodotoxin also inhibited the positive chronotropic response by 34% in atropine-treated dogs. In atropine- and propranolol-treated dogs, positive chronotropic responses to PACAP-27 were inhibited by PACAP-(6-27), a PACAP receptor antagonist but not by vasoactive intestinal peptide (10-28), a vasoactive intestinal peptide receptor antagonist. These results indicate that PACAP-27 causes the negative chronotropic effect through the postganglionic parasympathetic nerve activation and it produces the positive chronotropic effect mediated by PACAP receptors with an activation of non-adrenergic, nonvasoactive intestinal peptide-ergic nerves at least in part in the dog heart. Atropine and tetrodotoxin abolished atrial fibrillation induced by PACAP-27 but other blockers did not. These results suggest that neurally released acetylcholine induced by PACAP-27 participates in the induction of atrial fibrillation.