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Computational Prediction of Cyclic Peptide Structural Ensembles and Application to the Design of Keap1 Binders

F Lopez, J. Miao, Jovan Damjanovic, Luca Bischof, Michael B. Braun, Yingjie Ling, Marcus D. Hartmann, Yu‐Shan Lin, Joshua A. Kritzer

2023Journal of Chemical Information and Modeling16 citationsDOIOpen Access PDF

Abstract

The Nrf2 transcription factor is a master regulator of the cellular response to oxidative stress, and Keap1 is its primary negative regulator. Activating Nrf2 by inhibiting the Nrf2-Keap1 protein-protein interaction has shown promise for treating cancer and inflammatory diseases. A loop derived from Nrf2 has been shown to inhibit Keap1 selectively, especially when cyclized, but there are no reliable design methods for predicting an optimal macrocyclization strategy. In this work, we employed all-atom, explicit-solvent molecular dynamics simulations with enhanced sampling methods to predict the relative degree of preorganization for a series of peptides cyclized with a set of bis-thioether "staples". We then correlated these predictions to experimentally measured binding affinities for Keap1 and crystal structures of the cyclic peptides bound to Keap1. This work showcases a computational method for designing cyclic peptides by simulating and comparing their entire solution-phase ensembles, providing key insights into designing cyclic peptides as selective inhibitors of protein-protein interactions.

Topics & Concepts

KEAP1Cyclic peptideRegulatorChemistryPeptideMolecular dynamicsTranscription factorBinding affinitiesThioetherComputational biologyCombinatorial chemistryBiophysicsStereochemistryBiochemistryComputational chemistryBiologyGeneReceptorGenomics, phytochemicals, and oxidative stressFree Radicals and AntioxidantsRedox biology and oxidative stress