Discriminating between cellular and misfolded prion protein by using affinity to 9-aminoacridine compounds

Quinacrine and related 9-aminoacridine compounds are effective in eliminating the alternatively folded prion protein, termed PrPSc, from scrapie-infected cultured cells. Clinical evaluations of quinacrine for the treatment of human prion diseases are progressing in the absence of a clear understanding of the molecular mechanism by which prion replication is blocked. Here, insight into the mode of action of 9-aminoacridine compounds was sought by using a chemical proteomics approach to target identification. Cellular macromolecules that bind 9-aminoacridine ligands were affinity-purified from tissue lysates by using a 9-aminoacricline-functionalized solid-phase matrix. Although the 9-aminoacridine matrix was conformationally selective for PrPSc, it was inefficient: approximately 5 % of PrPSc was bound under conditions that did not support binding of the cellular isoform, PrPSc. Our findings suggest that 9-aminoacridine compounds may reduce the PrPSc burden either by occluding epitopes necessary for templating on the surface of PrPSc or by altering the stability of PrPSc oligomers, where a one-to-one stoichionnetry is not necessary.