Deconvoluting the Cu2+ Binding Modes of Full-length Prion Protein

Abstract

The prion protein (PrP) is a cell-surface Cu(2+)-binding glycoprotein that when misfolded is responsible for a number of transmissible spongiform encephalopathies. Full-length PrP-(23-231) and constructs in which the octarepeat region has been removed, or His(95) and His(110) is replaced by alanine residues, have been used to elucidate the order and mode of Cu(2+) coordination to PrP-(23-231). We have built on our understanding of the appearance of visible CD spectra and EPR for various PrP fragments to characterize Cu(2+) coordination to full-length PrP. At physiological pH, Cu(2+) initially binds to full-length PrP in the amyloidogenic region between the octarepeats and the structured domain at His(95) and His(110). Only subsequent Cu(2+) ions bind to single histidine residues within the octarepeat region. Ni(2+) ions are used to further probe metal binding and, like Cu(2+), Ni(2+) will bind individually to His(95) and His(110), involving preceding main chain amides. Competitive chelators are used to determine the affinity of the first mole equivalent of Cu(2+) bound to full-length PrP; this approach places the affinity in the nanomolar range. The affinity and number of Cu(2+) binding sites support the suggestion that PrP could act as a sacrificial quencher of free radicals generated by copper redox cycling.