Liliane Halab scite author profile

The influence of sequence on turn geometry was examined by incorporating (2S,5R)-5-tert-butylproline (5-(t)BuPro) into a series of dipeptides and tetrapeptides. (2S,5R)-5-tert-Butylproline and proline were respectively introduced at the C-terminal residue of N-acetyl dipeptide N'-methylamides 1 and 2. The conformational analysis of these analogues was performed using NMR and CD spectroscopy as well as X-ray diffraction to examine the factors that control the prolyl amide (in this text, the term "prolyl amide" refers to the tertiary amide composed of the pyrrolidine nitrogen of the prolyl residue and the carbonyl of the N-terminal residue) equilibrium and stabilize type VI beta-turn conformation. The high cis-isomer population with aromatic residues N-terminal to proline was shown to result from a stacking interaction between the partial positive charged prolyl amide nitrogen and the aromatic pi-system as seen in the crystal structure of 1c. The effect of sequence on the prolyl amide equilibrium of 5-(t)BuPro-tetrapeptides (Ac-Xaa-Yaa-5-(t)BuPro-Zaa-XMe, 13 and 14) was studied by varying the amino acids at the Xaa, Yaa, and Zaa positions. High (>80%) cis-isomer populations were obtained with alkyl groups at the Xaa position, an aromatic residue at the Yaa position, and either an alanine or a lysine residue at the Zaa position of the 5-(t)BuPro-tetrapeptide methyl esters in water. Tetrapeptides Ac-Ala-Phe-5-(t)BuPro-Zaa-OMe (Zaa = Ala, Lys), 14d and 14f, with high cis-isomer content adopted type VIa beta-turn conformations as shown by their NMR and CD spectra. Although a pattern of amide proton temperature coefficient values indicative of a hairpin geometry was observed in peptides 14d and 14f, the value magnitudes did not indicate strong hydrogen bonding in water.

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Use of Steric Interactions To Control Peptide Turn Geometry. Synthesis of Type VI β-Turn Mimics with 5-tert-Butylproline

Halab

Lubell

1999

J. Org. Chem.

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The influences of steric interactions on peptide geometry were studied to develop a novel means for generating type VIa beta-turn mimics. (2S,5R)-5-tert-Butylproline and L-proline were respectively introduced at the C-terminal residue of N-(acetyl)dipeptide N'-methylamides 1 and 2. The relative populations of prolyl cis- and trans-amide isomers in dipeptides 1 and 2 were measured in chloroform, DMSO, and water by proton NMR spectroscopy. Although the trans-amide isomer was favored in prolyl peptide 2, the Xaa-Pro peptide bond adopted preferably the cis-amide isomer in the case of 5-tert-butylprolyl peptide 1. Measurements of the influence of solvent and temperature on the chemical shift values for the amide proton signals of 1 in the cis-amide conformer indicated that the N'-methylamide was engaged in a hydrogen bond with the acetamide carbonyl in a type VIa beta-turn conformation. Analysis of N-(acetyl)leucyl-5-tert-butylproline N'-methylamide (1d) in the solid state by X-ray diffraction showed the cis-amide conformer which adopted a geometry characteristic of the central, i + 1 and i + 2 residues of an ideal type VIa beta-turn. In contrast to prolyl peptides 2b and 2d, N-(acetyl)alanyl- and N-(acetyl)leucyl-5-tert-butylproline N'-methylamides (1b and 1d) maintained ordered beta-turn conformations in solution that were shown to be independent of solvent composition by a comparison of their circular dichroism spectra obtained in water and acetonitrile. The NMR, X-ray, and CD data all confirm that the steric interactions of the 5-tert-butylprolyl residue induced dipeptide 1 to adopt a type VIa beta-turn conformation.

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Design, synthesis, and conformational analysis of azacycloalkane amino acids as conformationally constrained probes for mimicry of peptide secondary structures

2000

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Conformationally constrained amino acid and dipeptide units can serve in mimics of specific secondary structures for studying relationships between peptide conformation and biological activity. A variety of mimics are required to study systematically the structure–activity relationships in biologically relevant peptides. We present our efforts on the design, synthesis, and conformational analysis of a series of rigid surrogates of amino acid and dipeptide units for application within constrained peptide analogues, and for employment as inputs for combinatorial science. Conceived to be general and versatile, our methodology has delivered a variety of azacycloalkane and azabicycloalkane amino acids in enantiomerically pure form, via practical methods, from readily available and inexpensive starting materials. ©2000 John Wiley & Sons, Inc. Biopoly 55: 101–122, 2000

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Probing Opioid Receptor Interactions with Azacycloalkane Amino Acids. Synthesis of a Potent and Selective ORL1 Antagonist

et al. 2002

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Azacycloalkane turn mimics 6-9 were used to explore the relationship between conformation and biological activity of peptide ligands to the opioid receptor-like (ORL1) receptor. Three azabicyclo[x.y.0]alkane amino acids and a 5-tBuPro type VI beta-turn mimic were introduced into peptides 10-13 by solid-phase synthesis on MBHA resin. Biological examination of peptides 10-13 showed two new antagonists (10 and 12) exhibiting increased selectivity for the ORL1 receptor.

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Liliane Halab

Effect of Sequence on Peptide Geometry in 5-tert-Butylprolyl Type VI β-Turn Mimics

Use of Steric Interactions To Control Peptide Turn Geometry. Synthesis of Type VI β-Turn Mimics with 5-tert-Butylproline

Design, synthesis, and conformational analysis of azacycloalkane amino acids as conformationally constrained probes for mimicry of peptide secondary structures

Probing Opioid Receptor Interactions with Azacycloalkane Amino Acids. Synthesis of a Potent and Selective ORL1 Antagonist

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