Litcius/Paper detail

Building block aspect ratio controls assembly, architecture, and mechanics of synthetic and natural protein networks

Matt D. G. Hughes, Sophie Cussons, Benjamin S. Hanson, Kalila R Cook, Tímea Feller, Najet Mahmoudi, Daniel L. Baker, Robert A.S. Ariëns, David Head, David J. Brockwell, Lorna Dougan

2023Nature Communications23 citationsDOIOpen Access PDF

Abstract

Fibrous networks constructed from high aspect ratio protein building blocks are ubiquitous in nature. Despite this ubiquity, the functional advantage of such building blocks over globular proteins is not understood. To answer this question, we engineered hydrogel network building blocks with varying numbers of protein L domains to control the aspect ratio. The mechanical and structural properties of photochemically crosslinked protein L networks were then characterised using shear rheology and small angle neutron scattering. We show that aspect ratio is a crucial property that defines network architecture and mechanics, by shifting the formation from translationally diffusion dominated to rotationally diffusion dominated. Additionally, we demonstrate that a similar transition is observed in the model living system: fibrin blood clot networks. The functional advantages of this transition are increased mechanical strength and the rapid assembly of homogenous networks above a critical protein concentration, crucial for in vivo biological processes such as blood clotting. In addition, manipulating aspect ratio also provides a parameter in the design of future bio-mimetic and bio-inspired materials.

Topics & Concepts

Aspect ratio (aeronautics)NanotechnologyMaterials scienceBlock (permutation group theory)Globular proteinSynthetic biologyRheologyComputer scienceBiological systemChemistryGeometryComposite materialBioinformaticsCrystallographyMathematicsBiologyBlood properties and coagulationCellular Mechanics and InteractionsHemoglobin structure and function