Abstract
| - In this study we investigated the role of Cu2+, Mn2+, Zn2+, and Al3+ in inducing defectiveconformational rearrangements of the recombinant human prion protein (hPrP), which trigger aggregationand fibrillogenesis. The research was extended to the fragment of hPrP spanning residues 82−146, whichwas identified as a major component of the amyloid deposits in the brain of patients affected by Gerstmann−Sträussler−Scheinker (GSS) disease. Variants of the 82−146 wild-type subunit [PrP-(82−146)wt] werealso examined, including entirely, [PrP-(82−146)scr], and partially scrambled, [PrP-(82−146)106-126scr]and [PrP-(82−146)127-146scr], peptides. Al3+ strongly stimulated the conversion of native hPrP into thealtered conformation, and its potency in inducing aggregation was very high. Despite a lower rate andextent of prion protein conversion into altered isoforms, however, Zn2+ was more efficient than Al3+ inpromoting organization of hPrP aggregates into well-structured, amyloid-like fibrillar filaments, whereasMn2+ delayed and Cu2+ prevented the process. GSS peptides underwent the fibrillogenesis process muchfaster than the full-length protein. The intrinsic ability of PrP-(82−146)wt to form fibrillar aggregates wasexalted in the presence of Zn2+ and, to a lesser extent, of Al3+, whereas Cu2+ and Mn2+ inhibited theconversion of the peptide into amyloid fibrils. Amino acid substitution in the neurotoxic core (sequence106−126) of the 82−146 fragment reduced its amyloidogenic potential. In this case, the stimulatoryeffect of Zn2+ was lower as compared to the wild-type peptide; on the contrary Al3+ and Mn2+ induceda higher propensity to fibrillation, which was ascribed to different binding modalities to GSS peptides. Inall cases, alteration of the 127−146 sequence strongly inhibited the fibrillogenesis process, thus suggestingthat integrity of the C-terminal region was essential both to confer amyloidogenic properties on GSSpeptides and to activate the stimulatory potential of the metal ions.
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