Direct Observation of Prion Protein Fibril Elongation Kinetics

Abstract

It is widely accepted that prion diseases are caused by the conversion of cellular prion protein (PrPC) to the misfolded form PrPSc, which is self-propagating by seeded aggregation. The molecular mechanism and propagation kinetics are not well understood. Here, we use Total Internal Reflection Fluorescence and Transient Amyloid Binding super-resolution microscopy to investigate the elongation kinetics of mouse prion protein at single fibril level. Recombinant mouse prion protein (recMoPrP 91-231) fibrils formed under partially denaturing conditions were deposited on a glass slide, incubated with recMoPrP 91-231 monomer solution and imaged for up to 70h. We found that PrP fibrils elongated by an intermittent ‘stop-and-go’ mechanism. The elongation rates of growing phase are obtained under different temperature, various concentrations of monomer, denaturant, and sodium chloride, which are then used to calculate the kinetic parameters. This study sheds light on the mechanism of prion protein seeded propagation in vitro and provides a useful system to study the influence of PrP mutants and screening of inhibitors.