ABSTRACT
A series of diastereoisomers of endomorphin-1 (EM1, Tyr(1)-Pro(2)-Trp(3)-Phe(4)-NH(2)) have been synthesized and their potency measured using the guinea pig ileum assay. [D-Phe(4)]EM1 possessed 1/10 the potency of EM1, while potencies of [D-Tyr(1)]EM1 and [D-Trp(3)]EM1 were 50- and 100-fold lower, respectively. Drastic loss of activity occurred in the [D-Pro(2)]EM1 peptide. The structural determinants for the inactivity and reduced potency of the diastereoisomers were investigated using NMR spectroscopy and conformational analysis. Simulations of trans-[D-Pro(2)]EM1 using NOE-derived distance constraints afforded well-defined structures in which Tyr and Trp side chains stack against the proline ring. The inactivity of [D-Pro(2)]EM1 was explained by structural comparison with EM1 (, FEBS Lett. 439:13-20). The two peptides showed an opposite orientation of the Trp(3) residue with respect to Tyr(1), thus suggesting a role of Pro(2) as a stereochemical spacer in orienting Trp(3) and Phe(4) toward regions suitable for mu-receptor interaction. The agonist activity of [D-Tyr(1)]EM1 and [D-Trp(3)]EM1 was attributed to their ability to adopt low-energy conformations that mimic those of EM1. The requirements for mu-receptor activation were examined further by comparing EM1 with the mu-peptide [D-Ala(2), MePhe(4), Gly-ol]-enkephalin (DAMGO). Conformations of DAMGO with a Tyr(1)-MePhe(4) phenyl ring separation of approximately 12 A were found to mimic Tyr(1)-Phe(4) of EM1, thus suggesting overlapping binding modes between these two peptides.
Subject(s)
Oligopeptides/chemistry , Receptors, Opioid, mu/chemistry , Animals , Enkephalin, Ala(2)-MePhe(4)-Gly(5)-/chemistry , Guinea Pigs , Ileum/drug effects , Magnetic Resonance Spectroscopy , Models, Molecular , Oligopeptides/pharmacology , Protein Conformation , Stereoisomerism , Structure-Activity RelationshipABSTRACT
Peripheral membrane association with high calcium stoichiometry is shared by three families of proteins: annexins, pentraxins and vitamin-K-dependent proteins. Recent crystal structure determinations, biophysical studies of membrane binding and analyses of protein electrostatic properties offer striking and different concepts for membrane association by each of these protein families.