The notion that nanoscale surfaces influence protein conformational transitions stimulates the investigation of fibrillogenic polypeptides adsorbing to nanomaterials. Alpha-synuclein (αS) is a prototypical amyloidogenic protein whose aggregation is associated with severe neurodegenerative disorders. We explored the interaction of αS with silica nanoparticles (SNPs) in diverse solution conditions, ranging from protein-free to protein-rich media. We found that the SNP-binding region of αS, determined by site-resolved NMR spectroscopy, was similar in simple buffer and blood serum. Competition binding experiments with isotopic homologues and different proteins showed that cosolutes elicited molecular exchange in a protein-specific manner. The interaction of an oxidized, fibrillation-resistant protein form with SNPs was similar to that of unmodified αS. SNPs, however, did not stimulate fibrillation of the oxidized protein, which remained fibrillation incompetent. CD experiments revealed SNP-induced perturbations of the structural properties of oxidized and non-oxidized αS. Thus, while αS binding to SNPs is essentially orthogonal to fibril formation, the interaction perturbs the distribution of conformational states populated by the protein in the colloidal suspension. This study sheds light on the dynamic nature of αS interactions with NPs, an aspect that crucially impacts on our ability to control aggregation of αS.
Keywords: Alpha-synuclein; NMR spectroscopy; Protein aggregation; Protein-nanoparticle interactions; Silica nanoparticles.
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