The ability to design foldamers that mimic the defined structural motifs of natural biopolymers is critical for the continued development of functional biomimetic molecules. Peptoids, or oligomers of N-substituted glycine, represent a versatile class of foldamers capable of folding into defined secondary and tertiary structures. However, the rational design of discretely folded polypeptoids remains a challenging task, due in part to an incomplete understanding of the covalent and noncovalent interactions that direct local peptoid folding. We have found that simple, peptoid monomer model systems allow for the effective isolation of individual interactions within the peptoid backbone and side chains and can facilitate the study of the role of these interactions in restricting local peptoid conformation. Herein, we present an analysis of a set of peptoid monomers and an oligomer containing N-aryl side chains capable of hydrogen bonding with the peptoid backbone. These model peptoids were found to exhibit well-defined local conformational preferences, allowing for control of the ω, ϕ, and ψ dihedral angles adopted by the systems. Fundamental studies of the peptoid monomers enabled the design and synthesis of an acyclic peptoid reverse-turn structure, in which N-aryl side chains outfitted with ortho-hydrogen bond donors were hypothesized to play a critical role in the stabilization of the turn. This trimeric peptoid was characterized by X-ray crystallography and 2D NMR spectroscopy and was shown to adopt a unique acyclic peptoid reverse-turn conformation. Further analysis of this turn revealed an n→π*(C═O) interaction within the peptoid backbone, which represents the first reported example of this type of stereoelectronic interaction occurring exclusively within a polypeptoid backbone. The installation of N-aryl side chains capable of hydrogen bonding into peptoids is straightforward and entirely compatible with current solid-phase peptoid synthesis methodologies. As such, we anticipate that the strategic incorporation of these N-aryl side chains should facilitate the construction of peptoids capable of adopting discrete structural motifs, both turnlike and beyond, and will facilitate the continued development of well-folded peptoids.
The ability to design foldamers that mimic the defined structural motifs of natural biopolymers is critical for the continued development of functional biomimetic molecules. n class="Chemical">Peptoids, or oligomers of N-substituted glycine, represent a versatile class of foldamers capable of folding into defined secondary and tertiary structures. However, the rational design of discretely folded polypeptoids remains a challenging task, due in part to an incomplete understanding of the covalent and noncovalent interactions that direct local peptoid folding. We have found that simple, peptoid monomer model systems allow for the effective isolation of individual interactions within the peptoid backbone and side chains and can facilitate the study of the role of these interactions in restricting local peptoid conformation. Herein, we present an analysis of a set of peptoid monomers and an oligomer containing N-aryl side chains capable of hydrogen bonding with the peptoid backbone. These model peptoids were found to exhibit well-defined local conformational preferences, allowing for control of the ω, ϕ, and ψ dihedral angles adopted by the systems. Fundamental studies of the peptoid monomers enabled the design and synthesis of an acyclic peptoid reverse-turn structure, in which N-aryl side chains outfitted with ortho-hydrogen bond donors were hypothesized to play a critical role in the stabilization of the turn. This trimeric peptoid was characterized by X-ray crystallography and 2D NMR spectroscopy and was shown to adopt a unique acyclic peptoid reverse-turn conformation. Further analysis of this turn revealed an n→π*(C═O) interaction within the peptoid backbone, which represents the first reported example of this type of stereoelectronic interaction occurring exclusively within a polypeptoid backbone. The installation of N-aryl side chains capable of hydrogen bonding into peptoids is straightforward and entirely compatible with current solid-phase peptoid synthesis methodologies. As such, we anticipate that the strategic incorporation of these N-aryl side chains should facilitate the construction of peptoids capable of adopting discrete structural motifs, both turnlike and beyond, and will facilitate the continued development of well-folded peptoids.
Authors: K Kirshenbaum; A E Barron; R A Goldsmith; P Armand; E K Bradley; K T Truong; K A Dill; F E Cohen; R N Zuckermann Journal: Proc Natl Acad Sci U S A Date: 1998-04-14 Impact factor: 11.205
Authors: Nathaniel P Chongsiriwatana; James A Patch; Ann M Czyzewski; Michelle T Dohm; Andrey Ivankin; David Gidalevitz; Ronald N Zuckermann; Annelise E Barron Journal: Proc Natl Acad Sci U S A Date: 2008-02-19 Impact factor: 11.205
Authors: Neel H Shah; Glenn L Butterfoss; Khanh Nguyen; Barney Yoo; Richard Bonneau; Dallas L Rabenstein; Kent Kirshenbaum Journal: J Am Chem Soc Date: 2008-12-10 Impact factor: 15.419
Authors: Cindy W Wu; Kent Kirshenbaum; Tracy J Sanborn; James A Patch; Kai Huang; Ken A Dill; Ronald N Zuckermann; Annelise E Barron Journal: J Am Chem Soc Date: 2003-11-05 Impact factor: 15.419
Authors: Glenn L Butterfoss; Barney Yoo; Jonathan N Jaworski; Ilya Chorny; Ken A Dill; Ronald N Zuckermann; Richard Bonneau; Kent Kirshenbaum; Vincent A Voelz Journal: Proc Natl Acad Sci U S A Date: 2012-08-20 Impact factor: 11.205