ABSTRACT
Mimics of protein secondary and tertiary structure offer rationally-designed inhibitors of biomolecular interactions. ß-Sheet mimics have a storied history in bioorganic chemistry and are typically designed with synthetic or natural turn segments. We hypothesized that replacement of terminal inter-ß-strand hydrogen bonds with hydrogen bond surrogates (HBS) may lead to conformationally-defined macrocyclic ß-sheets without the requirement for natural or synthetic ß-turns, thereby providing a minimal mimic of a protein ß-sheet. To access turn-less antiparallel ß-sheet mimics, we developed a facile solid phase synthesis protocol. We surveyed a dataset of protein ß-sheets for naturally observed interstrand side chain interactions. This bioinformatics survey highlighted an over-abundance of aromatic-aromatic, cation-π and ionic interactions in ß-sheets. In correspondence with natural ß-sheets, we find that minimal HBS mimics show robust ß-sheet formation when specific amino acid residue pairings are incorporated. In isolated ß-sheets, aromatic interactions endow superior conformational stability over ionic or cation-π interactions. Circular dichroism and NMR spectroscopies, along with high-resolution X-ray crystallography, support our design principles.