Prion propagation involves a conformational transition of the cellular form of prion protein (PrP C ) to a disease-specific isomer (PrP Sc ), shifting from a predominantly ␣-helical conformation to one dominated by -sheet structure. This conformational transition is of critical importance in understanding the molecular basis for prion disease. Here, we elucidate the conformational properties of a disulfide-reduced fragment of human PrP spanning residues 91-231 under acidic conditions, using a combination of heteronuclear NMR, analytical ultracentrifugation, and circular dichroism. We find that this form of the protein, which similarly to PrP Sc , is a potent inhibitor of the 26 S proteasome, assembles into soluble oligomers that have significant -sheet content. The monomeric precursor to these oligomers exhibits many of the characteristics of a molten globule intermediate with some helical character in regions that form helices I and III in the PrP C conformation, whereas helix II exhibits little evidence for adopting a helical conformation, suggesting that this region is a likely source of interaction within the initial phases of the transformation to a -rich conformation. This precursor state is almost as compact as the folded PrP C structure and, as it assembles, only residues 126 -227 are immobilized within the oligomeric structure, leaving the remainder in a mobile, random-coil state.
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