Mechanistic Understanding of the Interactions between Nano-Objects with Different Surface Properties and alpha-Synuclein

摘要

Aggregation of the natively unfolded protein a-synuclein (alpha-syn) is key to the development of Parkinson's disease (PD). Some nanoparticles (NPs) can inhibit this process and in turn be used for treatment of PD. Using simulation strategies, we show here that alpha-syn self-assembly is electrostatically driven. Dimerization by head-to-head monomer contact is triggered by dipole-dipole interactions and subsequently stabilized by van der Waals interactions and hydrogen bonds. Therefore, we hypothesized that charged nano-objects could interfere with this process and thus prevent alpha-syn fibrillation. In our simulations, positively and negatively charged graphene sheets or superparamagnetic iron oxide NPs first interacted with alpha-syn's N/C terminally charged residues and then with hydrophobic residues in the non-amyloid-beta component (61-95) region. In the experimental setup, we demonstrated that the charged nano-objects have the capacity not only to strongly inhibit alpha-syn fibrillation (both nucleation and elongation) but also to disaggregate the mature fibrils. Through the alpha-syn fibrillation process, the charged nano-objects induced the formation of off-pathway oligomers.