The prion protein (PrP) binds copper and has antioxidant activity enhancing the survival of neurones in culture. The ability of the PrP to bind other cations was tested and it was found that only manganese could substitute for copper. Although initially manganeseloaded PrP exhibited similar structure and activity to copper-loaded PrP, after aging, manganese-loaded PrP became proteinase resistant and lost function. It was also found that manganese could be incorporated into PrP expressed by astrocytes and that this PrP was partially proteinase resistant. These results show that it is possible to generate proteinase-resistant PrP from cells and suggest a possible mechanism for the formation of the scrapie isoform of the PrP as generated in sporadic prion disease.
We show here that mouse prion protein (PrP(C)) either as recombinant protein or immunoprecipitated from brain tissue has superoxide dismutase (SOD) activity. SOD activity was also associated with recombinant chicken PrP(C) confirming the evolutionary conserved phenotype suggested by sequence similarity. Acquisition of copper by PrP(C) during protein folding endowed SOD activity on the protein but the addition of copper following refolding did not. PrP(C) dependent SOD activity was abolished by deletion of the octapeptide-repeat region involved in copper binding. These results describe an enzymic function for PrP(C) consistent with its cellular distribution and suggest it has a direct role in cellular resistance to oxidative stress.
We show here that mouse prion protein (PrP(C)) either as recombinant protein or immunoprecipitated from brain tissue has superoxide dismutase (SOD) activity. SOD activity was also associated with recombinant chicken PrP(C) confirming the evolutionary conserved phenotype suggested by sequence similarity. Acquisition of copper by PrP(C) during protein folding endowed SOD activity on the protein but the addition of copper following refolding did not. PrP(C) dependent SOD activity was abolished by deletion of the octapeptide-repeat region involved in copper binding. These results describe an enzymic function for PrP(C) consistent with its cellular distribution and suggest it has a direct role in cellular resistance to oxidative stress.
We have developed a method to af®nity-purify mouse prion protein (PrP c ) from mouse brain and cultured cells. PrP c from mouse brain bound three copper atoms; PrP c from cultured cells bound between one and four copper atoms depending on the availability of copper in the culture medium. Puri®ed PrP c exhibited antioxidant activity, as determined by spectrophotometric assay. Incubation of PrP c with the neurotoxic peptide, PrP106-126, inactivated the superoxide dismutase-like activity.Culture experiments showed that PrP c protects cells against oxidative stress relative to the amount of copper it binds. These results suggest that PrP c is a copper-binding protein which can incorporate varying amounts of copper and exhibit protective antioxidant activity.
The prion protein is a glycoprotein expressed by neurones and other cells. In its holo-form it binds copper and exhibits superoxide dismutase activity. Studies in mice have led to the description of two distinct alleles. Differences in these alleles are linked to long and short incubation times following infection with scrapie. We studied recombinant mouse protein corresponding to the products of either allele and two intermediates carrying single amino-acid residue substitutions. The different forms of the prion protein exhibited differences in superoxide dismutase (SOD) activity and conformation. Intermediates with single substitutions were less stable than either allelic product. The findings provide insight into the differences between the two alleles and might have consequences for understanding differences in susceptibility to prion disease.
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