Structural basis for the dissociation of α-synuclein fibrils triggered by pressure perturbation of the hydrophobic core.

Parkinson's disease is a neurological disease in which aggregated forms of the α-synuclein (α-syn) protein are found. We used high hydrostatic pressure (HHP) coupled with NMR spectroscopy to study the dissociation of α-syn fibril into monomers and evaluate their structural and dynamic properties. Different dynamic properties in the non-amyloid-ß component (NAC), which constitutes the Greek-key hydrophobic core, and in the acidic C-terminal region of the protein were identified by HHP NMR spectroscopy. In addition, solid-state NMR revealed subtle differences in the HHP-disturbed fibril core, providing clues to how these species contribute to seeding α-syn aggregation. These findings show how pressure can populate so far undetected α-syn species, and they lay out a roadmap for fibril dissociation via pathways not previously observed using other approaches. Pressure perturbs the cavity-prone hydrophobic core of the fibrils by pushing water inward, thereby inducing the dissociation into monomers. Our study offers the molecular details of how hydrophobic interaction and the formation of water-excluded cavities jointly contribute to the assembly and stabilization of the fibrils. Understanding the molecular forces behind the formation of pathogenic fibrils uncovered by pressure perturbation will aid in the development of new therapeutics against Parkinson's disease.

Hydration and conformational equilibrium in yeast thioredoxin 1: implication for H(+) exchange.

One of the ancestral features of thioredoxins is the presence of a water cavity. Here, we report that a largely hydrated, conserved, buried aspartic acid in the water cavity modulates the dynamics of the interacting loops of yeast thioredoxin 1 (yTrx1). It is well-established that the aspartic acid, Asp24 for yTrx1, works as a proton acceptor in the reduction of the target protein. We propose a complementary role for Asp24 of coupling hydration and conformational motion of the water cavity and interacting loops. The intimate contact between the water cavity and the interacting loops means that motion at the water cavity will affect the interacting loops and vice versa. The D24N mutation alters the conformational equilibrium for both the oxidized and reduced states, quenching the conformational motion in the water cavity. By measuring the hydration and molecular dynamics simulation of wild-type yTrx1 and the D24N mutant, we showed that Asn24 is more exposed to water than Asp24 and the water cavity is smaller in the mutant, closing the inner part of the water cavity. We discuss how the conformational equilibrium contributes to the mechanism of catalysis and H(+) exchange.