Litcius/Paper detail

High affinity protein surface binding through co-engineering of nanoparticles and proteins

Moumita Ray, Giorgia Brancolini, David C. Luther, Ziwen Jiang, Roberto Cao‐Milán, Alejandro M. Cuadros, A C Burden, Vincent Clark, Subinoy Rana, Rubul Mout, Ryan F. Landis, Stefano Corni, Vincent M. Rotello

2022Nanoscale18 citationsDOIOpen Access PDF

Abstract

Control over supramolecular recognition between proteins and nanoparticles (NPs) is of fundamental importance in therapeutic applications and sensor development. Most NP-protein binding approaches use 'tags' such as biotin or His-tags to provide high affinity; protein surface recognition provides a versatile alternative strategy. Generating high affinity NP-protein interactions is challenging however, due to dielectric screening at physiological ionic strengths. We report here the co-engineering of nanoparticles and protein to provide high affinity binding. In this strategy, 'supercharged' proteins provide enhanced interfacial electrostatic interactions with complementarily charged nanoparticles, generating high affinity complexes. Significantly, the co-engineered protein-nanoparticle assemblies feature high binding affinity even at physiologically relevant ionic strength conditions. Computational studies identify both hydrophobic and electrostatic interactions as drivers for these high affinity NP-protein complexes.

Topics & Concepts

NanoparticleNanotechnologySurface engineeringPlasma protein bindingSurface (topology)ChemistrySurface proteinBiophysicsMaterials scienceChemical engineeringBiochemistryEngineeringBiologyVirologyMathematicsGeometryMonoclonal and Polyclonal Antibodies ResearchBacteriophages and microbial interactionsBiochemical and Structural Characterization