Bioactive models for a delta opioid receptor antagonist are proposed based on the structurally rigid, diketopiperazine containing cyclo 2',6'-dimethyl-L-tyrosyl (Dmt)-1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic). Monte Carlo conformational analysis of c(Dmt-Tic) generated three low energy clusters (I-III) of conformers. The lowest energy conformer representing cluster I superimposed best with the X-ray crystal structures of c(Tyr-Tic), an inactive diketopiperazine with similar framework as c(Dmt-Tic), with H-Tyr-Tic-NH2, a dipeptide of moderate delta opioid affinity and lacking bioactivity, and with H-Tyr-Tic-Phe-Phe-OH (TIPP), a selective and potent delta opioid receptor antagonist. Clusters I and II superimposed best with three different overlays of naltrindole, a potent delta opiate antagonist, and with two other H-Tyr-Tic-NH delta opioid antagonist pharmacophores proposed by Temussi et al. (1994) and Wilkes and Schiller (1995). The 3-dimensional topography of these two clusters of c(Dmt-Tic) conformations may represent bioactive models for interaction of an antagonist at delta opioid receptors. Cluster I conformers exhibited gauche- (- 64 degrees) and gauche+ (53 degrees) orientations of the side chains Dmt and Tic, respectively, while cluster II contained trans (179 degrees) and gauche+ (62 degrees) orientations of those side-chains. Aromatic ring distances were 5.4 A for cluster I conformations and 8.2 A for cluster II structures. Orientation about the peptide bond N-C' was cis (- 5 degrees and 3 degrees) for both clusters, respectively. These structural features may provide optimal alignment of the physicochemical moieties important for delta opioid receptor interaction, such as the hydrophobic methyl groups of Dmt, hydrogen bonding of the dimethyltyrosine hydroxyl group within the receptor pocket and cation-pi interactions involving the aromatic rings of Dmt and Tic, as profiled by the three point attachment hypothesis.
Opioid diketopiperazines: refinement of the delta opioid antagonist pharmacophore
BALBONI, GIANFRANCO;
1997-01-01
Abstract
Bioactive models for a delta opioid receptor antagonist are proposed based on the structurally rigid, diketopiperazine containing cyclo 2',6'-dimethyl-L-tyrosyl (Dmt)-1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic). Monte Carlo conformational analysis of c(Dmt-Tic) generated three low energy clusters (I-III) of conformers. The lowest energy conformer representing cluster I superimposed best with the X-ray crystal structures of c(Tyr-Tic), an inactive diketopiperazine with similar framework as c(Dmt-Tic), with H-Tyr-Tic-NH2, a dipeptide of moderate delta opioid affinity and lacking bioactivity, and with H-Tyr-Tic-Phe-Phe-OH (TIPP), a selective and potent delta opioid receptor antagonist. Clusters I and II superimposed best with three different overlays of naltrindole, a potent delta opiate antagonist, and with two other H-Tyr-Tic-NH delta opioid antagonist pharmacophores proposed by Temussi et al. (1994) and Wilkes and Schiller (1995). The 3-dimensional topography of these two clusters of c(Dmt-Tic) conformations may represent bioactive models for interaction of an antagonist at delta opioid receptors. Cluster I conformers exhibited gauche- (- 64 degrees) and gauche+ (53 degrees) orientations of the side chains Dmt and Tic, respectively, while cluster II contained trans (179 degrees) and gauche+ (62 degrees) orientations of those side-chains. Aromatic ring distances were 5.4 A for cluster I conformations and 8.2 A for cluster II structures. Orientation about the peptide bond N-C' was cis (- 5 degrees and 3 degrees) for both clusters, respectively. These structural features may provide optimal alignment of the physicochemical moieties important for delta opioid receptor interaction, such as the hydrophobic methyl groups of Dmt, hydrogen bonding of the dimethyltyrosine hydroxyl group within the receptor pocket and cation-pi interactions involving the aromatic rings of Dmt and Tic, as profiled by the three point attachment hypothesis.
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