Synthetic analogs of cholecystokinin terminal tetrapeptide that stimulate insulin but not glucagon release from pancreatic islets

Evidence for cholecystokinin receptor subtype in endocrine pancreas

Cholecystokinin (CCK) is a gut hormone that regulates pancreatic endocrine functions via CCKA receptors. CCK4 (Trp-Met-Asp-Phe-NH2) has an insulinotropic effect, but is 1000-fold less potent than CCK8. The in vitro potencies and selectivity of newly synthesized CCK4 analogs were investigated. Exchanging various a amino acids, for example Met by Nle and modifying Phe and/or Trp, led to compounds that were much more effective than CCK4 itself and show insulinotropic effects comparable with those of CCK8. Compounds that possess electron withdrawing groups on the C-terminal phenylalanine were especially effective; compounds with electron-donating groups had no effect. In contrast to CCK8 the synthetic CCK4 compounds were selective for the endocrine pancreas: they had no agonistic or antagonistic effect on the contraction of the guinea pig ileum, amylase release from isolated acini, and no major effect on the feeding behavior of mice being supplied with either compound by an implantable AlzetR pump for 8 days. The data indicate that some of the synthetic tetrapeptides exhibit a high affinity for the CCK receptor of the endocrine pancreas and that they are highly selective for this (peripheral) CCKA receptor subtype. The beta-cell CCKA receptors are different from those in exocrine pancreas, smooth muscle, and those for regulating appetite; these peripheral receptor subtypes can be discriminated for the first time.

Selective stimulation of insulin secretion by CCK-4 analogues having N-terminal modifications

Synthetic analogues of CCK-4 in which Trp was replaced by D-Pro (peptide I), Thz (peptide II) and delta Pro (peptide III) have been studied for their insulin and glucagon releasing activities from the islets of Langerhans in vitro. Peptide I has been found to be the most potent insulin releaser among the three analogues and its activity is comparable to that of CCK-4. Unlike CCK-4, its three analogues (peptides I-III) do not stimulate the release of glucagon with basal concentration of glucose in the medium. However, with increasing glucose concentration, all the three analogues potentiate the glucose stimulus for insulin release.

Effect of some novel synthetic analogues of CCK-4 on insulin and glucagon secretion

The biologic activities of three synthetic analogues of CCK-4 (Trp-Met-Asp-Phe-NH2) in which (i) the C-terminal residue Phe was N-methylated (peptide I); (ii) the C-terminal Phe residue was N-methylated and Ser is substituted for Met in position 2 (peptide II); (iii) Pro was substituted for Trp in position 1 and the C-terminal amino nitrogen was methylated (peptide III), have been described. Peptides I and II have been found to inhibit the release of both insulin and glucagon, while peptide III was found to be a potent releasing agent for insulin and an inhibitor for glucagon.