The development of inhibitors of intracellular protein–protein interactions (PPIs) is of great significance for drug discovery, but the generation of a cell-permeable molecule with high affinity to protein is challenging....
Functionalizable synthetic molecules with nanometer sizes and defined shapes in water are useful as molecular scaffolds to mimic the functions of biomacromolecules and develop chemical tools for manipulating biomacromolecules. Herein, we propose oligo(N-methylalanine) (oligo-NMA) as a peptide-based molecular scaffold with a minimal structure and a high density of functionalizable sites. Oligo-NMA forms a defined shape in water without hydrogen-bonding networks or ring constraints, which enables the molecule to act as a scaffold with minimal atomic composition. Furthermore, functional groups can be readily introduced on the nitrogens and α-carbons of oligo-NMA. Computational and NMR spectroscopic analysis suggested that the backbone structure of oligo-NMA is not largely affected by functionalization. Moreover, the usefulness of oligo-NMA was demonstrated by the design of protein ligands. The ease of synthesis, minimal structure, and high functionalization flexibility makes oligo-NMA a useful scaffold for chemical and biological applications.
N-Substituted peptides, such as peptoids and β-peptoids, have been reported to have unique structures with diverse functions, like catalysis and manipulation of biomolecular functions. Recently, the preorganization of monomer shape...
Functionalizable synthetic molecules with nanometer sizes and defined shapes in water are useful as molecular scaffolds to mimic the functions of biomacromolecules and develop chemical tools for manipulating biomacromolecules. Herein, we propose oligo(N-methylalanine) (oligo-NMA) as a peptide-based molecular scaffold with a minimal structure and a high density of functionalizable sites. Oligo-NMA forms a defined shape in water without hydrogen-bonding networks or ring constraints, which enables the molecule to act as a scaffold with minimal atomic composition. Furthermore, functional groups can be readily introduced on the nitrogens and α-carbons of oligo-NMA. Computational and NMR spectroscopic analysis suggested that the backbone structure of oligo-NMA is not largely affected by functionalization. Moreover, the usefulness of oligo-NMA was demonstrated by the design of protein ligands. The ease of synthesis, minimal structure, and high functionalization flexibility makes oligo-NMA a useful scaffold for chemical and biological applications.
De novo design of peptide nanoshapes is of great interest in biomolecular science since the local peptide nanoshapes formed by a short peptide chain in the proteins are often key to the biological activities. Here, we show that the de novo design of peptide nanoshapes with sub-nanometer conformational control can be realized using peptides consisting of N-methyl-L-alanine and N-methyl-D-alanine residues as studied by NMR, X-ray and XFEL crystallographic and computational analyses as well as by direct imaging of the dynamics of the peptide’s nanoshape using cinematographic electron microscopic technique. The conformation of N-methyl-L/D-alanine residue is largely fixed because of the restricted bond rotation, and hence can serve as a scaffold on which we can build a peptide into a designed nanoshape. The local shape control by per-residue conformational restriction by torsional strains starkly contrasts with the global shape stabilization of proteins based on many remote interactions. The oligomers allow the bottom-up design of diverse peptide nanoshapes with a small number of amino acid residues and would offer unique opportunities to realize the de novo design of biofunctional molecules, such as catalysts and drugs.
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<p>The development of inhibitors of intracellular protein–protein interactions (PPIs) is of great significance
for drug discovery, but the generation of a cell-permeable molecule with high affinity to protein is
challenging. Oligo(N-substituted glycines) (oligo-NSGs), referred to as peptoids, are attractive as
potential intracellular PPI inhibitors owing to their high membrane permeability. However, their
intrinsically flexible backbones make the rational design of inhibitors difficult. Here, we propose a
peptoid-based rational approach to develop cell-permeable PPI inhibitors using oligo(N-substituted
alanines) (oligo-NSAs). The rigid structures of oligo-NSAs enable independent optimization of each
N-substituent to improve binding affinity and membrane permeability, while preserving the backbone
shape. A molecule with optimized N-substituents inhibited a target PPI in cells, which demonstrated the
utility of oligo-NSA as a reprogrammable template to develop intracellular PPI inhibitors.
</p>
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<div>
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<p>The development of inhibitors of intracellular protein–protein interactions (PPIs) is of great significance
for drug discovery, but the generation of a cell-permeable molecule with high affinity to protein is
challenging. Oligo(N-substituted glycines) (oligo-NSGs), referred to as peptoids, are attractive as
potential intracellular PPI inhibitors owing to their high membrane permeability. However, their
intrinsically flexible backbones make the rational design of inhibitors difficult. Here, we propose a
peptoid-based rational approach to develop cell-permeable PPI inhibitors using oligo(N-substituted
alanines) (oligo-NSAs). The rigid structures of oligo-NSAs enable independent optimization of each
N-substituent to improve binding affinity and membrane permeability, while preserving the backbone
shape. A molecule with optimized N-substituents inhibited a target PPI in cells, which demonstrated the
utility of oligo-NSA as a reprogrammable template to develop intracellular PPI inhibitors.
</p>
</div>
</div>
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