Inherent Conformational Preferences of Ac-Gln-Gln-NHBn: Sidechain Hydrogen Bonding Supports a β-Turn in the Gas Phase

Gas-phase single-conformation spectroscopy is used to study Ac-Gln-Gln-NHBn in order to probe the interplay between sidechain hydrogen bonding and backbone conformational preferences. This small, amide-rich peptide offers many possibilities for backbone-backbone, sidechain-backbone, and sidechain-sidechain interactions. The major conformer observed experimentally features a type-I β-turn with a canonical 10-membered ring C=O-H-N hydrogen bond between backbone amide groups. In addition, the C=O group of each Gln sidechain participates in a seven-membered ring hydrogen bond with the backbone NH of the same residue. Thus, sidechain hydrogen-bonding potential is satisfied in a manner that is consistent with and stabilizes the β-turn secondary structure. This turn-forming propensity may be relevant to pathogenic amyloid formation by polyglutamine segments in human proteins.