Ionizing radiation induces cross-linking of two noncovalently bound collagen mimetic peptide triple helices in the absence of a molecular environment

Cross-linking is a fundamental molecular process that is highly important for many applications, in particular, to tune the properties of collagen-based biomaterials. Chemical reagents, the action of enzymes or physical factors such as heat or radiation can facilitate collagen cross-linking. Ionizin...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2023-11, Vol.25 (42), p.29249-29256
Main Authors: Abdelmouleh, Marwa, Amin, Muhamed, Lalande, Mathieu, Schlathölter, Thomas, Poully, Jean-Christophe
Format: Article
Language:English
Subjects:
Amino acids
Biocompatibility
Biomedical materials
Chemical Sciences
Collagen
Covalent bonds
Crosslinking
Helices
Ionizing radiation
Peptides
Photoabsorption
Physical factors
Physics
Radiation
Radiation effects
Reagents
Vapor phases
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Summary:Cross-linking is a fundamental molecular process that is highly important for many applications, in particular, to tune the properties of collagen-based biomaterials. Chemical reagents, the action of enzymes or physical factors such as heat or radiation can facilitate collagen cross-linking. Ionizing radiation has the advantages of being fast, efficient and free from potentially toxic reagents. Collagen cross-linking by ionizing radiation is thought to occur via a water-mediated pathway. In the past, synthesized collagen mimetic peptides have proven to be of great value for understanding the influence of the amino acid sequence on the stability of tertiary (fibrous) as well as secondary (triple helical) structures of collagen. Cross-linking of synthetic collagen mimetic peptides is often used for modifying the properties of biomaterials. In this work, for the first time, we apply radiation-induced cross-linking to synthetic collagen mimetic peptides and present an experimental and theoretical study of peptide hexamers consisting of two noncovalently bound triple helices in the absence of a molecular environment, i.e. in the gas phase. Our results show that X-ray photoabsorption of the hydroxylated hexamer leads to ionization and cross-linking of the two triple helices: thus, we found evidence that cross-linking can be achieved by ionizing radiation, without the presence of any reagent or water. We propose a cross-linking mechanism involving the creation of two radicals on hydroxyproline side-chains and their recombination, ultimately leading to covalent bond formation between the triple helices. We show experimental evidence that ionizing radiation is able to cross-link two collagen mimetic peptide triple helices in the gas phase, challenging the previously proposed water-mediated collagen cross-linking mechanism.
ISSN:1463-9076
1463-9084
DOI:10.1039/d3cp03264g