Reduced peptide bond pseudopeptide analogues of secretin. A new class of secretin receptor antagonists.

The ability to assess the importance of secretin in various physiological processes is limited by the lack of specific potent antagonists. Recently, reduced peptide bond (psi) analogues of bombesin or substance P in which the -CONH- bond is replaced by -CH2NH- are reported to be receptor antagonists. To attempt to develop a new class of secretin receptor antagonists, we have adopted a similar strategy with secretin and sequentially altered the eight NH2-terminal peptide bonds, the biological active portion of secretin. In guinea pig pancreatic acini, secretin caused a 75-fold increase in cyclic AMP (cAMP). Secretin inhibited 125I-secretin binding with a half-maximal effect at 7 nM. Each of the psi analogues inhibited 125I-secretin binding. [psi 4,5]Secretin was the most potent, causing the half-maximal inhibition at 4 microM, and was 2-fold more potent than the [psi 1,2]secretin; 7-fold more than [psi 3,4]secretin, [psi 5,6]secretin, and [psi 8,9]secretin; 9-fold more than [psi 7,8]secretin; 13-fold more potent [psi 6,7]secretin, and 17-fold more than [psi 2,3]secretin. Secretin caused a half-maximal increase in cAMP at 1 nM. At concentrations up to 10 microM, [psi 2,3]secretin, [psi 4,5]secretin, and [psi 8,9]secretin did not alter cAMP whereas [psi 1,2]secretin and [psi 6,7]secretin caused a detectable increase in cAMP at 10 nM, [psi 7,8]secretin at 300 nM, [psi 5,6]secretin at 1 microM, and [psi 3,4]secretin at 10 microM. The [psi 4,5], [psi 2,3], and [psi 8,9] analogues of secretin each inhibited 1 nM secretin-stimulated cAMP as well as [psi 3,4]secretin, which functioned as a partial agonist. [psi 4,5]Secretin was the most potent, causing half-maximal inhibition at 3 microM whereas [psi 8,9]secretin was 6-fold less potent, and [psi 2,3]secretin and [psi 3,4]secretin were 17-fold less potent. [psi 4,5]Secretin inhibited secretin-stimulated cAMP and binding of 125I-secretin in a competitive manner. [psi 4,5]Secretin did not interact with cholecystokinin, bombesin, calcitonin gene-related peptide, or cholinergic receptors but did interact with receptors for vasoactive intestinal peptide, causing half-maximal inhibition at 72 microM and thus had a 18-fold higher affinity for secretin than vasoactive intestinal peptide receptors. These results indicate that reduced peptide bond analogues of the NH2 terminus of secretin represent a new class of secretin receptor antagonists. It is likely that in the future even more potent members of this class can be developed which may be useful to investigate the role of secretin in various physiological processes.

des-Met carboxyl-terminally modified analogues of bombesin function as potent bombesin receptor antagonists, partial agonists, or agonists.

In the present study we examined the effect of carboxyl-terminal modifications of des-Met14-bombesin (Bn) on Bn receptor affinity in murine 3T3 cells, rat and guinea pig pancreatic acini, and the ability to initiate biologic responses by synthesizing 18 des-Met14-Bn(6-13) analogues. With guinea pig acini and 3T3 cells, affinity was affected by the chain length of the alkyl moiety (R) added to [D-Phe6]Bn(6-13)NH2R with relative potencies: propyl greater than ethyl greater than butyl = hexyl greater than heptyl greater than free amide, whereas in rat acini affinity was not increased by the chain length. In each cell system the affinity of the alkylamide was not increased by insertion of a phenyl group in the alkyl side chain, by making the analogue more neuromedin B-like or by addition of a reduced peptide bond. The affinity in each cell system was increased by additions of other electron releasing groups to the COOH-terminal carboxyl group such as [D-Phe6]Bn(6-13)ethyl or methyl ester, or hydrazide. In guinea pig pancreas and 3T3 cells, 12 analogues were antagonists, 1 a full and 5 partial agonists. In rat pancreas, 8 were antagonists, 5 full agonists, and 5 partial agonists. Potent antagonists in each cell system were the methyl and ethyl ester, hydrazide, and ethylamide analogues. In 3T3 cells or guinea pig pancreas, agonist activity of the alkylamide was critically dependent on the chain length, whereas with rat pancreatic Bn receptors any alkylamide longer than the ethylamide had agonist activity. In all three cell systems any alteration that made the alkylamide more neuromedin B-like caused agonist activity. These results demonstrate that the nature of the substitution on the carboxyl terminus of des-Met14-Bn analogues is critically important, not only for determining Bn receptor affinity, but also for determining the ability to initiate a biologic response. In contrast to previous studies, the present results demonstrate that the presence of the COOH-terminal amino acid in position 14 of Bn is not essential for initiating a biologic response. Several des-Met14-Bn analogues were potent partial agonists, whereas others such as the hydrazide or ethyl ester are very potent antagonists.