Abstract
The fragment 106-126 of prion protein exhibits similar properties to full-length prion. Experiments have shown that the A117V mutation enhances the aggregation of PrP106-126, while the H111S mutation abolishes the assembly. However, the mechanism of the change in the aggregation behavior of PrP106-126 upon the two mutations is not fully understood. In this study, replica exchange molecular dynamics simulations were performed to investigate the conformational ensemble of the WT PrP106-126 and its two mutants A117V and H111S. The obtained results indicate that the three species are all intrinsically disordered but they have distinct morphological differences. The A117V mutant has a higher propensity to form β-hairpin structures than the WT, while the H111S mutant has a higher population of helical structures. Furthermore, the A117V mutation increases the hydrophobic solvent accessible surface areas of PrP106-126 and the H111S mutation reduces the exposure of hydrophobic residues. It can be concluded that the difference in populations of β-hairpin structures and the change of hydrophobic solvent accessible areas may induce the different aggregation behaviors of the A117V and the H111S mutated PrP106-126. Understanding why the two mutations have contrary effects on the aggregation of PrP106-126 is very meaningful for further elucidation of the mechanism underlying aggregation and design of inhibitor against aggregation process.
Highlights
Prion diseases, such as bovine spongiform encephalopathy, scrapie disease in sheeps, Creuzfeldt-Jacob disease and Gerstmann-Straussler-Scheinker disease in humans, are characterized by accumulations of abnormal forms of prion protein (PrPSc) in neuronal tissue[1,2,3]
Replica exchange molecular dynamics simulation is an enhanced sampling algorithm that can facilitate the system to escape from local minima in free energy landscape by exchanging temperatures [34]
The distributions of end-toend distances of three systems in the two time intervals are roughly the same. These results demonstrated that the three replica exchange molecular dynamics simulations (REMD) simulations reasonably converged in 200 ns
Summary
Prion diseases, such as bovine spongiform encephalopathy, scrapie disease in sheeps, Creuzfeldt-Jacob disease and Gerstmann-Straussler-Scheinker disease in humans, are characterized by accumulations of abnormal forms of prion protein (PrPSc) in neuronal tissue[1,2,3]. Prion disorders are fatal neurodegenerative diseases that are closely linked to misfolding and aggregation of the cellular prion protein (PrPC). PrPC has a high content of α-helix, while PrPSc has a high content of β-sheet[5,6]. PrPC is soluble, monomeric and protease K sensitive, while PrPSc tends to aggregate into insoluble and protease K resistant amyloid fibril [1,2,7]. According to the “protein only hypothesis” [3,8], PrPSc acts as a template to induce the misfolding of cellular prion protein and is considered to be the causative agent. The mechanism underlying the spontaneous conversion from PrPC to PrPSc has not been completely elucidated
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