Stereoselective synthesis of 3-substituted 2-aminocyclopentanecarboxylic acid derivatives and their incorporation into short 12-helical beta-peptides that fold in water.

A stereoselective synthetic route is reported for the introduction of side chains at the 3-position of trans-2-aminocyclopentanecarboxylic acid (ACPC). Ring opening of the aziridine 2-benzyloxymethyl-6-azabicyclo[3.1.0]hexane with selected nucleophiles occurs in a regioselective manner and provides ACPC precursors with functional groups at the 3-position, trans to the 2-amino group. Oligomers composed of the 3-substituted ACPC residues maintain the 12-helical conformation displayed by the nonsubstituted analogues, as shown by their similar circular dichroism signatures. The added diversity of the new residues provides good dispersion of NMR signals, allowing the assignment of nearly all the NOE signals of a selected hexamer in aqueous solution. The NOEs between protons on nonadjacent residues are characteristic of the 12-helix. 3-Substituted ACPC residues allow one to arrange specific functional groups in a geometrically defined fashion, which should facilitate the design of beta-peptides for biological applications.

Tolerance of acyclic residues in the beta-peptide 12-helix: access to diverse side-chain arrays for biological applications.

Oligomeric backbones with well-defined conformational propensities can serve as scaffolds for displaying sets of functional groups in specific three-dimensional arrangements. beta-Peptides are particularly interesting in this regard because several distinct secondary structures can be induced by appropriate choice of beta-amino acid substitution pattern.3 The beta-peptide 12-helix (defined by 12-membered ring C=O(i)- -H-N(i + 3) hydrogen bonds) is of particular interest because this helix resembles the alpha-helix. To date 12-helices have been observed in beta-peptides comprised exclusively of residues containing a five-membered ring constraint. Here we show that 12-helical propensity is maintained when some cyclic beta-amino acid residues are replaced with more flexible acyclic residues. This result is important because use of acyclic residues greatly facilitates introduction of diverse side chains at specific sites along the 12-helix. We demonstrate the utility of this advance in the context of antibiotic design.