Impact of azaproline on Peptide conformation

The amino acid analog azaproline (azPro) contains a nitrogen atom in place of the C(alpha) of proline. Peptides containing azPro were shown to stabilize the cis-amide conformer for the acyl-azPro bond and prefer type VI beta-turns both in crystals and in organic solvents by NMR. The increased stability for cis-amide conformers was relatively minor with respect to the trans-conformers. Further, their conformational preferences were depended on solvent. To elucidate the impact of azPro substitution on amide cis-trans isomerism and peptide conformation, this paper reports ab initio studies on azPro derivatives and a comparison with their cognate Pro derivatives: 1-acetyl-2-methyl pyrrolidine (1), 1-acetyl-2-methyl pyrazolidine (2), Ac-Pro-NHMe (3), Ac-azPro-NHMe (4), Ac-azPro-NMe(2) (5), Ac-azAzc-NHMe (6), and Ac-azPip-NHMe (7). Conformational preferences were explored at the MP2/6-31+G** level of theory in vacuo. Solvation effects for 1 and 2 were studied implicitly using the polarizable continuum model and explicitly represented by interactions with a single water molecule. An increase in the conformational preference for the cis-amide conformer of azPro was clearly seen. An intramolecular hydrogen bond occurred solely in the trans-amide conformer that reduced the preference for the cis-conformer by 2.2 kcal/mol. The larger ring homolog aza-pipecolic acid (azPip), in which this internal hydrogen bond was diminished, significantly augmented stabilization of the cis-amide conformer. In aqueous solution, the preference for the cis-amide conformers was greatly reduced, mainly as a result of interaction between water and the lone pair of the alpha-nitrogen in the trans-amide conformer that was 3.8 kcal/mol greater than that in the cis-conformer. In the azPro analog, the energy barrier for cis-trans amide isomerization was 6 kcal/mol less than that in the cognate Pro derivative. Because the azPro derivatives can stabilize the cis-amide bond and mimic a type VI beta-turn without incorporation of additional steric bulk, such a simple chemical modification of the peptide backbone provides a useful conformational constraint when incorporated into the structure of selected bioactive peptides. Such modifications can scan receptors for biological recognition of reverse turns containing cis-amide bonds by the incorporation of type VI beta-turn scaffolds with oriented appended side chains.     

Cavity search: An algorithm for the isolation and display of cavity-like binding regions

Summary A set of algorithms designed to enhance the display of protein binding cavities is presented. These algorithms, collectively entitled CAVITY SEARCH, allow the user to isolate and fully define the extent of a particular cavity. Solid modeling techniques are employed to produce a detailed cast of the active site region, which can then be color-coded to show electrostatic and steric interactions between the protein cavity and a bound ligand.