Litcius/Paper detail

Self-assembly of a barnacle cement protein into intertwined amyloid fibres and determination of their adhesive and viscoelastic properties

Maura A. Tilbury, Thi Quynh Tran, Dilip Shingare, Mathilde Lefevre, Anne Power, Philippe Leclère, J. Gerard Wall

2023Journal of The Royal Society Interface16 citationsDOIOpen Access PDF

Abstract

The stalked barnacle Pollicipes pollicipes uses a multi-protein cement to adhere to highly varied substrates in marine environments. We investigated the morphology and adhesiveness of a component 19 kDa protein in barnacle cement gland- and seawater-like conditions, using transmission electron microscopy and state-of-the art scanning probe techniques. The protein formed amyloid fibres after 5 days in gland-like but not seawater conditions. After 7–11 days, the fibres self-assembled under gland-like conditions into large intertwined fibrils of up to 10 µm in length and 200 nm in height, with a distinctive twisting of fibrils evident after 11 days. Atomic force microscopy (AFM)-nanodynamic mechanical analysis of the protein in wet conditions determined E ′ (elasticity), E ′′ (viscosity) and tan δ values of 2.8 MPa, 1.2 MPa and 0.37, respectively, indicating that the protein is a soft and viscoelastic material, while the adhesiveness of the unassembled protein and assembled fibres, measured using peak force quantitative nanomechanical mapping, was comparable to that of the commercial adhesive Cell-Tak™. The study provides a comprehensive insight into the nanomechanical and viscoelastic properties of the barnacle cement protein and its self-assembled fibres under native-like conditions and may have application in the design of amyloid fibril-based biomaterials or bioadhesives.

Topics & Concepts

BarnacleAdhesiveViscoelasticityComposite materialMaterials scienceCementRheologyPolymer scienceBiologyEcologyLayer (electronics)LarvaPolymer Surface Interaction StudiesCalcium Carbonate Crystallization and Inhibition