posted on 2019-11-25, 19:05authored byAndrew
W. Wijaya, Andy I. Nguyen, Leah T. Roe, Glenn L. Butterfoss, Ryan K. Spencer, Nan K. Li, Ronald N. Zuckermann
Sequence-defined peptoids, or N-substituted
glycines,
are an attractive class of bioispired polymer due to their biostability
and efficient synthesis. However, the de novo design of folded peptoids with precise three-dimensional structures
has been hindered by limited means to deterministically control backbone
conformation. Peptoid folds are generally destabilized by the cis/trans backbone-amide isomerization,
and few side-chains are capable of enforcing a specific amide conformation.
Here, we show that a novel class of cationic alkyl ammonium ethyl
side-chains demonstrates significant enforcement of the cis-amide backbone (Kcis/trans up to 70) using an unexpected ensemble of weak
intramolecular CH–O and/or NH–O hydrogen bonds between
the side-chain and the backbone carbonyl moieties. These interactions
are evidenced by X-ray crystallography, variable-temperature NMR spectroscopy,
and DFT calculations. Moreover, these side-chains are inexpensive,
structurally diverse, hydrophilic, and can be integrated into
longer peptoid sequences via solid-phase synthesis. Notably, we extended
these concepts to synthesize a water-soluble peptoid 10-mer that adopts
one predominant fold in solution, as determined by multidimensional
NMR spectroscopy. This decamer, to the best of our knowledge, is the
longest linear peptoid sequence atomically characterized to retain
a well-folded structure. These findings fill a critical gap in peptoid
folding and should propel the development of peptoid applications
in a broad range of contexts, from pharmaceutical to material sciences.