A Cyclized Helix-Loop-Helix Peptide as a Molecular Scaffold for the Design of Inhibitors of Intracellular Protein-Protein Interactions by Epitope and Arginine Grafting.

The design of inhibitors of intracellular protein-protein interactions (PPIs) remains a challenge in chemical biology and drug discovery. We propose a cyclized helix-loop-helix (cHLH) peptide as a scaffold for generating cell-permeable PPI inhibitors through bifunctional grafting: epitope grafting to provide binding activity, and arginine grafting to endow cell-permeability. To inhibit p53-HDM2 interactions, the p53 epitope was grafted onto the C-terminal helix and six Arg residues were grafted onto another helix. The designed peptide cHLHp53-R showed high inhibitory activity for this interaction, and computational analysis suggested a binding mode for HDM2. Confocal microscopy of cells treated with fluorescently labeled cHLHp53-R revealed cell membrane penetration and cytosolic localization. The peptide inhibited the growth of HCT116 and LnCap cancer cells. This strategy of bifunctional grafting onto a well-structured peptide scaffold could facilitate the generation of inhibitors for intracellular PPIs.

Macrocyclization and labeling of helix-loop-helix peptide with intramolecular bis-thioether linkage.

Conformationally constrained peptides have been developed as an inhibitor for protein-protein interactions (PPIs), and we have de novo designed cyclized helix-loop-helix (cHLH) peptide with a disulfide bond consisting of 40 amino acids to generate molecular-targeting peptides. However, synthesis of long peptides has sometimes resulted in low yield according to the respective amino acid sequences. Here we developed a method for efficient synthesis and labeling for cHLH peptides. First, we synthesized two peptide fragments and connected them by the copper-mediated alkyne and azide cycloaddition (CuAAC) reaction. Cyclization was performed by bis-thioether linkage using 1,3-dibromomethyl-5-propargyloxybenzene, and subsequently, the cHLH peptide was labeled with an azide-labeled probe. Finally, we designed and synthesized a peptide inhibitor for the p53-HDM2 interaction using a structure-guided design and successfully labeled it with a fluorescent probe or a functional peptide, respectively, by click chemistry. This macrocyclization and labeling method for cHLH peptide would facilitate the discovery of de novo bioactive ligands and therapeutic leads. © 2016 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 106: 415-421, 2016.