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Peptoid Residues Make Diverse, Hyperstable Collagen Triple-Helices

Julian L. Kessler, Grace Kang, Zhao Qin, Helen H. Kang, Frank G. Whitby, Thomas E. Cheatham, Christopher P. Hill, Yang Li, S. Michael Yu

2021Journal of the American Chemical Society47 citationsDOIOpen Access PDF

Abstract

As the only ribosomally encoded N-substituted amino acid, proline promotes distinct secondary protein structures. The high proline content in collagen, the most abundant protein in the human body, is crucial to forming its hallmark structure: the triple-helix. For over five decades, proline has been considered compulsory for synthetic designs aimed at recapitulating collagen's structure and properties. Here we describe that N-substituted glycines (N-glys), also known as peptoid residues, exhibit a general triple-helical propensity similar to or greater than proline, enabling synthesis of stable triple-helical collagen mimetic peptides (CMPs) with unprecedented side chain diversity. Supported by atomic-resolution crystal structures as well as circular dichroism and computational characterizations spanning over 30 N-gly-containing CMPs, we discovered that N-glys stabilize the triple-helix primarily by sterically preorganizing individual chains into the polyproline-II helix. We demonstrated that N-glys with exotic side chains including a "click"-able alkyne and a photosensitive side chain enable CMPs for functional applications including the spatiotemporal control of cell adhesion and migration. The structural principles uncovered in this study open up opportunities for a new generation of collagen-mimetic therapeutics and materials.

Topics & Concepts

ChemistryPeptoidTriple helixHelix (gastropod)StereochemistryBiophysicsBiochemistryPeptideZoologyBiologyGastropodaCollagen: Extraction and CharacterizationChemical Synthesis and AnalysisEnzyme Production and Characterization
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