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Bi-terminal fusion of intrinsically-disordered mussel foot protein fragments boosts mechanical strength for protein fibers

Jingyao Li, Bojing Jiang, Xinyuan Chang, Yu Han, Yichao Han, Fuzhong Zhang

2023Nature Communications59 citationsDOIOpen Access PDF

Abstract

Abstract Microbially-synthesized protein-based materials are attractive replacements for petroleum-derived synthetic polymers. However, the high molecular weight, high repetitiveness, and highly-biased amino acid composition of high-performance protein-based materials have restricted their production and widespread use. Here we present a general strategy for enhancing both strength and toughness of low-molecular-weight protein-based materials by fusing intrinsically-disordered mussel foot protein fragments to their termini, thereby promoting end-to-end protein-protein interactions. We demonstrate that fibers of a ~60 kDa bi-terminally fused amyloid-silk protein exhibit ultimate tensile strength up to 481 ± 31 MPa and toughness of 179 ± 39 MJ*m −3 , while achieving a high titer of 8.0 ± 0.70 g/L by bioreactor production. We show that bi-terminal fusion of Mfp5 fragments significantly enhances the alignment of β-nanocrystals, and intermolecular interactions are promoted by cation-π and π-π interactions between terminal fragments. Our approach highlights the advantage of self-interacting intrinsically-disordered proteins in enhancing material mechanical properties and can be applied to a wide range of protein-based materials.

Topics & Concepts

Ultimate tensile strengthToughnessFusion proteinPolymerMaterials scienceIntrinsically disordered proteinsChemistryBiophysicsNanotechnologyBiochemistryComposite materialRecombinant DNABiologyGeneSilk-based biomaterials and applicationsElectrospun Nanofibers in Biomedical ApplicationsPolymer Surface Interaction Studies
Bi-terminal fusion of intrinsically-disordered mussel foot protein fragments boosts mechanical strength for protein fibers | Litcius