Molecular Dynamic simulations of Aβ42 dimers with solid-state NMR restraints capture the key structural motifs in Aβ42 fibrillation pathways

Formation of the {beta}-amyloid (A{beta}) plaques is a pathological hallmark of Alzheimers disease (AD), and is believed to be a primary cause of dementia in elderly individuals. In the present work, we simulated the conformational evolution of A{beta}42 dimers in solution and in membrane-like environment to explore the folding of A{beta}42 along fibrillation. The molecular dynamics (MD) simulation was steered by experimental internuclear distance restraints obtained using solid-state nuclear magnetic resonance (ssNMR) spectroscopy. Our results revealed that several hydrophobic and polar motifs within the A{beta}42 sequence played key roles in the early-stage nucleation process of fibrillation and those motifs are also the stabilizing agents in the mature fibrils judged by the energy contribution. Our results also indicated that the peptide association with membrane bilayers could modulate the structural evolution pathways towards fibrillation. These findings contributed to a better understanding of the molecular level structural polymorphisms inherent to A{beta}42 fibrils. Further, the current work demonstrated that the combination of MD simulations with ssNMR-based experimental restraints provided a reliable method for studying structural changes of A{beta}. HighlightO_LIUsing solid-state NMR restraints guided molecular dynamic simulation, {beta}-amyloid dimers displayed consistent {beta}-strand-prone regions, which are major stabilizing segments for mature fibrils. C_LIO_LI{beta}-amyloid dimers evolved differently with or without interacting with the lipid bilayers. C_LIO_LIExperimental restraints guided simulation provided molecular level insights about early-stage interactions along the progress of {beta}-amyloid fibrillation C_LI