Constant-pH Molecular Dynamics Simulations Reveal a β-Rich Form of the Human Prion Protein

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Abstract

The misfolding of the prion protein (PrP) into a pathogenic β-rich form (PrP(Sc)) has been suggested to occur in the endocytic pathway, triggered by low pH. In this work we performed several constant-pH molecular dynamics simulations of human PrP 90-231 in the pH range 2-7, totaling more than 2 μs. We observed a strong conformational pH dependence where on average the helix content decreased and the β content increased toward acidic pH. Unlike some proposed models, the flexible N-terminus region did not gain stable structure at low pH. Rather, the main structural changes occurred on the helix-rich C-terminus core, as proposed in other models, namely, in the regions around 135-155 and 185-200. The protonation of His187 is found to be associated with a loss of interaction between two PrP subdomains, potentially playing a major role in the misfolding process. In one of the simulations at pH 2, a stable β-rich structure was formed that may be an intermediate of PrP(Sc) formation, indicating that misfolding may precede dimerization.

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