Exploring Conformational Preferences of Leu-enkephalin Using the Conformational Search and Double-Hybrid DFT Energy Calculations

Abstract: The conformational preferences of Leu-enkephalin (Leu-Enk) were explored by the conformational search and density functional theory (DFT) calculations. By a combination of low-energy conformers of each residue, the initial structures of the neutral Leu-Enk were generated and optimized using the ECEPP3 force field in the gas phase. These structures were reoptimized at the HF/3-21G(d) and M06-2X levels of theory with 6-31G(d) and 6-31+G(d) basis functions. We finally located the 139 structures with the relative … Show more

“…10 The design of new analogs was aided by molecular modelling and receptor structure determination. 11–13 Therefore, the synthesis of conformationally constrained leu-enkephalin analogs has been developed over many decades in the search for new peptidomimetics with improved stability and biological activity. Numerous analogs were obtained by cyclization, 14 substitution of single amino acid residues with natural or unnatural amino acids, 15 incorporation of cyclopropane-based scaffolds, 16 introduction of linear and oligoheterocyclic motifs, 17 introduction of amide bond isosters (ester, N -methylamide, triazole, alkene, trifluoroethylamine, azapeptide and fluoroalkene), 18 introduction of sugar moieties, 19 β-turn mimetic synthesis 20 and retropeptide synthesis.…”

Stapling of leu-enkephalin analogs with bifunctional reagents for prolonged analgesic activity

“…10 The design of new analogs was aided by molecular modelling and receptor structure determination. 11–13 Therefore, the synthesis of conformationally constrained leu-enkephalin analogs has been developed over many decades in the search for new peptidomimetics with improved stability and biological activity. Numerous analogs were obtained by cyclization, 14 substitution of single amino acid residues with natural or unnatural amino acids, 15 incorporation of cyclopropane-based scaffolds, 16 introduction of linear and oligoheterocyclic motifs, 17 introduction of amide bond isosters (ester, N -methylamide, triazole, alkene, trifluoroethylamine, azapeptide and fluoroalkene), 18 introduction of sugar moieties, 19 β-turn mimetic synthesis 20 and retropeptide synthesis.…”

Stapling of leu-enkephalin analogs with bifunctional reagents for prolonged analgesic activity