Stabilization of Synthetic Collagen Triple Helices: Charge Pairs and Covalent Capture

Cole, Carson C.; Yu, Le Tracy; Misiura, Mikita; Williams, Joseph; Bui, Thi H.; Hartgerink, Jeffrey D.

doi:10.1021/acs.biomac.3c00680

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2024

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Cited by 2 publications

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Heterotrimeric collagen helix with high specificity of assembly results in a rapid rate of folding

Cole,

Walker,

Hulgan

et al. 2024

Nat. Chem.

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Heterotrimeric collagen helix with high specificity of assembly results in a rapid rate of folding

Cole,

Walker,

Hulgan

et al. 2024

Nat. Chem.

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Covalent Stabilization of Collagen Mimetic Triple Helices and Assemblies by Dopa Crosslinking

Cole,

Pogostin,

Vardanyan

et al. 2024

Preprint

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Creating thermally stable collagen mimetic peptides (CMPs) is a persistent challenge. Nature leverages covalent crosslinking to stabilize collagens signature triple helical tertiary structure and higher-order assemblies. Here, we demonstrate that crosslinking between levodopa (Dopa) and lysine, amino acids present in native collagen, can covalently stabilize the triple helix in collagen mimetic peptides. Since alkaline conditions catalyze the oxidation of the catechol on Dopa to a benzoquinone while being in proximity to the nucleophilic lysine, we hypothesized that this reaction could be a facile method to covalently capture the supramolecular structure of CMPs by simply increasing the pH of the aqueous solvent with the addition of sodium hydroxide. This covalent capture strategy successfully stabilizes CMP homotrimers and a de novo designed ABC-type heterotrimer, demonstrating that the lysine-Dopa covalent bond is best templated by a supramolecular, axial cation-π ; pairwise interaction. In nature, collagen can hierarchically assemble into fibers. This behavior can be mimicked by the self-assembly of CMPs, but the resulting nanofibers typically exhibit thermal stability below body temperature. In a final application, we demonstrate that Dopa-lysine covalent capture also enhances the thermal stability of CMP nanofibers well above °37 C. This biomimetic covalent capture strategy can stabilize a wide variety of CMP systems and potentially enable the biomedical application of these materials.

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Stabilization of Synthetic Collagen Triple Helices: Charge Pairs and Covalent Capture

Cited by 2 publications

References 34 publications

Heterotrimeric collagen helix with high specificity of assembly results in a rapid rate of folding

Heterotrimeric collagen helix with high specificity of assembly results in a rapid rate of folding

Covalent Stabilization of Collagen Mimetic Triple Helices and Assemblies by Dopa Crosslinking

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