Pure glucagon antagonists: Biological activities and cAMP accumulation using phosphodiesterase inhibitors

Five new glucagon analogues have been designed, synthesized, characterized and their biological activities tested. The investigation was centered on modifications in the N-terminal region in particular, residues at Thr(5), Phe(6) and Tyr(10) positions, with the goal of obtaining pure glucagon antagonists in our newly developed high sensitivity cAMP accumulation assay. The structures of the designed compounds are: [des-His(1), des-Phe(6), Glu(9)]glucagon-NH2 (1); [des-His(1),des-Phe(6), Glu(9), Phe(10)]glucagon-NH2 (2), [des His(1),Tyr(5), des-Phe(6), Glu(9)] glucagon NH2 (3); [des-His(1) Phe(5), des-Phe(6), Glu(9)]glacagon-NH2 (4) and [des-His(1), des-Phe(6); Glu(9), D-Arg(18)]glucagon-NH2 (5). The binding potencies IC50 values in (nM) were 48.0, 27.4, 26.0, 20.0 and 416.0, respectively. All of these analogues tested in the classical adenylate cyclase assay demonstrate antagonist properties, and in competition experiments, all caused a rightward-shift of the glucagon stimulated adenylate cyclase dose-response curve. The pA(2) values for these analogues were 8.20 (1); 6.25 (2); 6.10 (3); 6.25 (4) and 6.08 (5), respectively. A newly revised assay has been developed to determine the intracellular cAMP accumulation levels in hepatocytes at the highest possible sensitivity. Four of the five glucagon analogues in this report (analogues 1, 2, 4 and 5), did not activate the adenylate cyclase in the presence of Rolipram up to a maximal physiological concentration of 1 mu M, and thus are pure antagonists. (C) 1997 Elsevier Science Inc.