Dewetting transitions in the self-assembly of two amyloidogenic β-sheets and the importance of matching surfaces.

We use molecular dynamics simulations to investigate the water-mediated self-assembly of two amyloidogenic β-sheets of hIAPP(22-27) peptides (NFGAIL). The initial configurations of β-sheet pairs are packed with two different modes, forming a tube-like nanoscale channel and a slab-like 2-D confinement, respectively. For both packing modes, we observe strong water drying transitions occurring in the intersheet region with high occurrence possibilities, suggesting that the "dewetting transition"-induced collapse may play an important role in promoting the amyloid fibrils formation. However, contrary to general dewetting theory prediction, the slab-like confinement (2-D) shows stronger dewetting phenomenon than the tube-like channel (1-D). This unexpected observation is attributed to the different surface roughness caused by different packing modes. Furthermore, we demonstrated the profound influence of internal surface topology of β-sheet pairs on the dewetting phenomenon through an in silico mutagenesis study. The present study highlights the important role of packing modes (i.e., surface roughness) in the assembly process of β-sheets, which improves our understanding toward the molecular mechanism of the amyloid fibrils formation. In addition, our study also suggests a potential route to regulate controllably the self-assembly process of β-sheets through mutations, which may have future applications in nanotechnology and biotechnology.