Cofactor and glycosylation preferences for in vitro prion conversion are predominantly determined by strain conformation.

Prion diseases are caused by the misfolding of a host-encoded glycoprotein, PrPC, into a pathogenic conformer, PrPSc. Infectious prions can exist as different strains, composed of unique conformations of PrPSc that generate strain-specific biological traits, including distinctive patterns of PrPSc accumulation throughout the brain. Prion strains from different animal species display different cofactor and PrPC glycoform preferences to propagate efficiently in vitro, but it is unknown whether these molecular preferences are specified by the amino acid sequence of PrPC substrate or by the conformation of PrPSc seed.

Cofactor molecules maintain infectious conformation and restrict strain properties in purified prions.

Prions containing misfolded prion protein (PrP(Sc)) can be formed with cofactor molecules using the technique of serial protein misfolding cyclic amplification. However, it remains unknown whether cofactors materially participate in maintaining prion conformation and infectious properties. Here we show that withdrawal of cofactor molecules during serial propagation of purified recombinant prions caused adaptation of PrP(Sc) structure accompanied by a reduction in specific infectivity of >10(5)-fold, to undetectable levels, despite the ability of adapted "protein-only" PrP(Sc) molecules to self-propagate in vitro.

Isolation of phosphatidylethanolamine as a solitary cofactor for prion formation in the absence of nucleic acids.

Infectious prions containing the pathogenic conformer of the mammalian prion protein (PrP(Sc)) can be produced de novo from a mixture of the normal conformer (PrP(C)) with RNA and lipid molecules. Recent reconstitution studies indicate that nucleic acids are not required for the propagation of mouse prions in vitro, suggesting the existence of an alternative prion propagation cofactor in brain tissue. However, the identity and functional properties of this unique cofactor are unknown.

Species-dependent differences in cofactor utilization for formation of the protease-resistant prion protein in vitro.

The cofactor preferences for in vitro propagation of the protease-resistant isoforms of the prion protein (PrP(Sc)) from various rodent species were investigated using the serial protein misfolding cyclic amplification (sPMCA) technique. Whereas RNA molecules facilitate hamster PrP(Sc) propagation, RNA and several other polyanions do not promote the propagation of mouse and vole PrP(Sc) molecules. Pretreatment of crude Prnp(0/0) (PrP knockout) brain homogenate with RNase A or micrococcal nuclease inhibited hamster but not mouse PrP(Sc) propagation in a reconstituted system.

The effects of prion protein proteolysis and disaggregation on the strain properties of hamster scrapie.

Native mammalian prions exist in self-propagating strains that exhibit distinctive clinical, pathological and biochemical characteristics. Prion strain diversity is associated with variations in PrP(Sc) conformation, but it remains unknown precisely which physical properties of the PrP(Sc) molecules are required to encipher mammalian prion strain phenotypes. In this study, we subjected prion-infected brain homogenates derived from three different hamster scrapie strains to either (i) proteinase K digestion or (ii) sonication, and inoculated the modified samples into normal hamsters.

Amplification of purified prions in vitro.

The infectious agents of prion diseases are unorthodox, and they seem to be composed primarily of a misfolded glycoprotein called the prion protein (PrP). Replication of prion infectivity is associated with the conversion of PrP from its normal, cellular form (PrP(C)) into a pathogenic form (PrP(Sc)), which is characterized biochemically by relative detergent insolubility and protease resistance. Several techniques have been developed in which PrP(C) molecules can be converted into the PrP(Sc) conformation in vitro.

Selective incorporation of polyanionic molecules into hamster prions.

The central pathogenic event of prion disease is the conformational conversion of a host protein, PrPC, into a pathogenic isoform, PrPSc. We previously showed that the protein misfolding cyclic amplification (PMCA) technique can be used to form infectious prion molecules de novo from purified native PrPC molecules in an autocatalytic process requiring accessory polyanions (Deleault, N. R.

Formation of native prions from minimal components in vitro.

The conformational change of a host protein, PrP(C), into a disease-associated isoform, PrP(Sc), appears to play a critical role in the pathogenesis of prion diseases such as Creutzfeldt-Jakob disease and scrapie. However, the fundamental mechanism by which infectious prions are produced in neurons remains unknown. To investigate the mechanism of prion formation biochemically, we conducted a series of experiments using the protein misfolding cyclic amplification (PMCA) technique with a preparation containing only native PrP(C) and copurified lipid molecules.

Accelerated accumulation of misfolded prion protein and spongiform degeneration in a Drosophila model of Gerstmann-Sträussler-Scheinker syndrome.

Prion diseases are CNS disorders that can occur in sporadic, infectious, and inherited forms. Although all forms of prion disease are associated with the accumulation of pathogenic conformers of the prion protein, collectively termed PrP(Sc), the mechanisms by which PrP(Sc) molecules form and cause neuronal degeneration are unknown. Using the bipartite galactosidase-4-upstream activating sequence expression system, we generated transgenic Drosophila melanogaster heterologously expressing either wild-type (WT) or mutant, disease-associated (P101L) mouse PrP molecules in cholinergic neurons.

The stoichiometry of host PrPC glycoforms modulates the efficiency of PrPSc formation in vitro.

A central event in the formation of infectious prions is the conformational change of a host-encoded glycoprotein, PrPC, into a pathogenic isoform, PrPSc. However, the molecular requirements for efficient PrP conversion remain unknown. In this study, we employed the recently developed protein misfolding cyclic amplification (PMCA) and scrapie cell assay (SCA) techniques to study the role of N-linked glycosylation on prion formation in vitro.

Copper (II) ions potently inhibit purified PrPres amplification.

The structural conversion of a host protein, PrP(C), into a protease-resistant isoform, PrPres, is the central event in the pathogenesis of infectious prion diseases. Purification of native PrP(C) molecules from hamster brain by either cation exchange or immobilized chelator chromatographic resins yielded preparations that supported efficient amplification of scrapie-induced PrPres in vitro. Using these purified preparations, we determined that in vitro PrPres amplification was inhibited by CuCl2 and ZnCl2 at IC50 concentrations of approximately 400 nm and 10 microM, respectively.

Protease-resistant prion protein amplification reconstituted with partially purified substrates and synthetic polyanions.

Little is currently known about the biochemical mechanism by which induced prion protein (PrP) conformational change occurs during mammalian prion propagation. In this study, we describe the reconstitution of PrPres amplification in vitro using partially purified and synthetic components. Overnight incubation of purified PrP27-30 and PrPC molecules at a molar ratio of 1:250 yielded approximately 2-fold baseline PrPres amplification.

In vitro prion protein conversion in detergent-solubilized membranes.

A fundamental event in the pathogenesis of prion disease is the conversion of PrP(C), a normal glycophosphatidyl-anchored glycoprotein, into an infectious isoform designated PrP(Sc). In a modified version of the protein misfolding cyclic amplification (PMCA) technique [Saborio et al. (2001) Nature 411, 810-813], protease-resistant PrP(Sc)-like molecules (PrPres) can be amplified in vitro in a species- and strain-specific manner from crude brain homogenates, providing a biochemical model of the prion conversion reaction [Lucassen et al.

RNA molecules stimulate prion protein conversion.

Much evidence supports the hypothesis that the infectious agents of prion diseases are devoid of nucleic acid, and instead are composed of a specific infectious protein. This protein, PrP(Sc), seems to be generated by template-induced conformational change of a normally expressed glycoprotein, PrP(C) (ref. 2).

Post-transcriptional suppression of pathogenic prion protein expression in Drosophila neurons.

A wealth of evidence supports the view that conformational change of the prion protein, PrPC, into a pathogenic isoform, PrPSc, is the hallmark of sporadic, infectious, and inherited forms of prion disease. Although the central role played by PrPSc in the pathogenesis of prion disease is appreciated, the cellular mechanisms that recognize PrPSc and modulate its production, clearance, and neural toxicity have not been elucidated. To address these questions, we used a tissue-specific expression system to express wild-type and disease-associated PrP molecules heterologously in Drosophila melanogaster.