The role of rafts in the fibrillization and aggregation of prions

A key molecular event in prion diseases is the conversion of the prion protein (PrP) from its normal cellular form (PrP(C)) to the disease-specific form (PrP(Sc)). The transition from PrP(C) to PrP(Sc) involves a major conformational change, resulting in amorphous aggregates and/or fibrillar amyloid deposits. Here several lines of evidence implicating membranes in the conversion of PrP are reviewed with a particular emphasis on the role of lipid rafts in the conformational transition of prion proteins. New correlations between in vitro biophysical studies and findings from cell biology work on the role of rafts in prion conversion are highlighted and a mechanism for the role of rafts in prion conversion is proposed.     

Binding of prion proteins to lipid membranes

A key molecular event in prion diseases is the conversion of the normal cellular form of the prion protein (PrPC) to an aberrant form known as the scrapie isoform, PrPSc. Under normal physiological conditions PrPC is attached to the outer leaflet of the plasma membrane via a GPI-anchor. It has been proposed that a direct interaction between PrP and lipid membranes could be involved in the conversion of PrPC to its disease-associated corrupted conformation, PrPSc. Recombinant PrP can be refolded into an alpha-helical structure, designated alpha-PrP isoform, or into beta-sheet-rich states, designated beta-PrP isoform. The current study investigates the binding of recombinant PrP isoforms to model lipid membranes using surface plasmon resonance spectroscopy. The binding of alpha- and beta-PrP to negatively charged lipid membranes of POPG, zwitterionic membranes of DPPC, and model raft membranes composed of DPPC, cholesterol, and sphingomyelin is compared at pH 7 and 5, to simulate the environment at the plasma membrane and within endosomes, respectively. It is found that PrP binds strongly to lipid membranes. The strength of the association of PrP with lipid membranes depends on the protein conformation and pH, and involves both hydrophobic and electrostatic lipid-protein interactions. Competition binding measurements established that the binding of alpha-PrP to lipid membranes follows a decreasing order of affinity to POPG>DPPC>rafts.     

The elusive intermediate on the folding pathway of the prion protein

A key molecular event in prion diseases is the conversion of the cellular conformation of the prion protein (PrP(C)) to an altered disease-associated form, generally denoted as scrapie isoform (PrP(Sc)). The molecular details of this conformational transition are not fully understood, but it has been suggested that an intermediate on the folding pathway of PrP(C) may be recruited to form PrP(Sc). In order to investigate the folding pathway of PrP we designed and expressed two mutants, each possessing a single strategically located tryptophan residue. The secondary structure and folding properties of the mutants were examined. Using conventional analyses of folding transition data determined by fluorescence and CD, and novel phase-diagram analyses, we present compelling evidence for the presence of an intermediate species on the folding pathway of PrP. The potential role of this intermediate in prion conversion is discussed.     

Role of Lipid Rafts and GM1 in the Segregation and Processing of Prion Protein

The prion protein (PrP^C) is highly expressed within the nervous system. Similar to other GPI-anchored proteins, PrP^C is found in lipid rafts, membrane domains enriched in cholesterol and sphingolipids. PrP^C raft association, together with raft lipid composition, appears essential for the conversion of PrP^C into the scrapie isoform PrP^Sc, and the development of prion disease. Controversial findings were reported on the nature of PrP^C-containing rafts, as well as on the distribution of PrP^C between rafts and non-raft membranes. We investigated PrP^C/ganglioside relationships and their influence on PrP^C localization in a neuronal cellular model, cerebellar granule cells. Our findings argue that in these cells at least two PrP^C conformations coexist: in lipid rafts PrP^C is present in the native folding (α-helical), stabilized by chemico-physical condition, while it is mainly present in other membrane compartments in a PrP^Sc-like conformation. We verified, by means of antibody reactivity and circular dichroism spectroscopy, that changes in lipid raft-ganglioside content alters PrP^C conformation and interaction with lipid bilayers, without modifying PrP^C distribution or cleavage. Our data provide new insights into the cellular mechanism of prion conversion and suggest that GM1-prion protein interaction at the cell surface could play a significant role in the mechanism predisposing to pathology.     

Role of lipid rafts in the processing of the pathogenic prion and Alzheimer's amyloid-beta proteins

The conformational conversion of the cellular form of the prion protein (PrP C) into the infectious form (PrP Sc) and the proteolytic processing of the amyloid-beta (Abeta) peptide are central pathogenetic events in the prion diseases and Alzheimer's disease, respectively. Cholesterol- and sphingolipid-rich lipid rafts have emerged as important sites for the conversion of PrP C into PrP Sc, and for the proteolytic production, degradation and aggregation of Abeta. Here, we discuss these findings and their implications for our understanding of these disease processes. In addition, the potential for rafts as sites for therapeutic intervention in prion diseases and Alzheimer's disease is considered.     

PrP(C) association with lipid rafts in the early secretory pathway stabilizes its cellular conformation

The pathological conversion of cellular prion protein (PrP(C)) into the scrapie prion protein (PrP(Sc)) isoform appears to have a central role in the pathogenesis of transmissible spongiform encephalopathies. However, the identity of the intracellular compartment where this conversion occurs is unknown. Several lines of evidence indicate that detergent-resistant membrane domains (DRMs or rafts) could be involved in this process. We have characterized the association of PrP(C) to rafts during its biosynthesis. We found that PrP(C) associates with rafts already as an immature precursor in the endoplasmic reticulum. Interestingly, compared with the mature protein, the immature diglycosylated form has a different susceptibility to cholesterol depletion vs. sphingolipid depletion, suggesting that the two forms associate with different lipid domains. We also found that cholesterol depletion, which affects raft-association of the immature protein, slows down protein maturation and leads to protein misfolding. On the contrary, sphingolipid depletion does not have any effect on the kinetics of protein maturation or on the conformation of the protein. These data indicate that the early association of PrP(C) with cholesterol-enriched rafts facilitates its correct folding and reinforce the hypothesis that cholesterol and sphingolipids have different roles in PrP metabolism.     

The prion protein and lipid rafts

Prions are the causative agent of the transmissible spongiform encephalopathies, such as Creutzfeldt-Jakob disease in humans. In these prion diseases the normal cellular form of the prion protein (PrP(C)) undergoes a post-translational conformational conversion to the infectious form (PrP(Sc)). PrP(C) associates with cholesterol- and glycosphingolipid-rich lipid rafts through association of its glycosyl-phosphatidylinositol (GPI) anchor with saturated raft lipids and through interaction of its N-terminal region with an as yet unidentified raft associated molecule. PrP(C) resides in detergent-resistant domains that have different lipid and protein compositions to the domains occupied by another GPI-anchored protein, Thy-1. In some cells PrP(C) may endocytose through caveolae, but in neuronal cells, upon copper binding to the N-terminal octapeptide repeats, the protein translocates out of rafts into detergent-soluble regions of the plasma membrane prior to endocytosis through clathrin-coated pits. The current data suggest that the polybasic region at its N-terminus is required to engage PrP(C) with a transmembrane adaptor protein which in turn links with the clathrin endocytic machinery. PrP(C) associates in rafts with a variety of signalling molecules, including caveolin-1 and Fyn and Src tyrosine kinases. The clustering of PrP(C) triggers a range of signal transduction processes, including the recruitment of the neural cell adhesion molecule to rafts which in turn promotes neurite outgrowth. Lipid rafts appear to be involved in the conformational conversion of PrP(C) to PrP(Sc), possibly by providing a favourable environment for this process to occur and enabling disease progression.     

Semiautomated cell-free conversion of prion protein: applications for high-throughput screening of potential antiprion drugs

Transmissible spongiform encephalitis (TSE) is a lethal illness with no known treatment. Conversion of the cellular prion protein (PrP(C)) into the infectious isoform (PrP(Sc)) is believed to be the central event in the development of this disease. Recombinant PrP (rPrP) protein folded into the amyloid conformation was shown to cause the transmissible form of prion disease in transgenic mice and can be used as a surrogate model for PrP(Sc). Here, we introduced a semiautomated assay of in vitro conversion of rPrP protein to the amyloid conformation. We have examined the effect of known inhibitors of prion propagation on this conversion and found good correlation between their activity in this assay and that in other in vitro assays. We thus propose that the conversion of rPrP to the amyloid isoform can serve as a high-throughput screen for possible inhibitors of PrP(Sc) formation and potential anti-TSE drugs.     

Atypical effect of salts on the thermodynamic stability of human prion protein

Prion diseases are associated with the conversion of cellular prion protein, PrPC, into a misfolded oligomeric form, PrPSc. Previous studies indicate that salts promote conformational conversion of the recombinant prion protein into a PrPSc-like form. To gain insight into the mechanism of this effect, here we have studied the influence of a number of salts (sodium sulfate, sodium fluoride, sodium acetate, and sodium chloride) on the thermodynamic stability of the recombinant human prion protein. Chemical unfolding studies in urea show that at low concentrations (below approximately 50 mm), all salts tested significantly reduced the thermodynamic stability of the protein. This highly unusual response to salts was observed for both the full-length prion protein as well as the N-truncated fragments huPrP90-231 and huPrP122-231. At higher salt concentrations, the destabilizing effect was gradually reversed, and salts behaved according to their ranking in the Hofmeister series. The present data indicate that electrostatic interactions play an unusually important role in the stability of the prion protein. The abnormal effect of salts is likely because of the ion-induced destabilization of salt bridges (Asp144-Arg148 and/or Asp147-Arg151) in the extremely hydrophilic helix 1. Contrary to previous suggestions, this effect is not due to the interaction of ions with the glycine-rich flexible N-terminal region of the prion protein. The results of this study suggest that ionic species present in the cellular environment may control the PrPC to PrPSc conversion by modulating the thermodynamic stability of the native PrPC isoform.     

Cell-lysate conversion of prion protein into its protease-resistant isoform suggests the participation of a cellular chaperone.

A conformational transition between the normal cellular prion protein (PrPC) and the beta-sheet-rich pathological isoform (PrPSc) is a central event in the pathogenesis of spongiform encephalopathies. The prion infectious agent seems to contain mainly, if not exclusively, PrPSc, which has the ability to propagate its abnormal conformation by transforming the host PrPC into the pathological isoform. We have developed an in vitro system to induce the PrPC --> PrPSc conversion by incubating a cell-lysate containing mouse PrPC with partially purified mouse PrPSc. After 48 h of incubation with a 10-fold molar excess of PrPSc, the cellular protein acquired PK-resistance resembling a PrPSc-like state. Time course experiments suggest that the conversion follows a stepwise mechanism involving kinetic intermediates. The conversion was induced by PrPSc extracted from mice infected with two different prion strains, each propagating its characteristic Western blot profile. The latter results and the fact that all the cellular components are present in the conversion reaction suggest that PrPC-PrPSc interaction is highly specific and required for the conversion. No transformation was observed under the same conditions using purified proteins without cell-lysate. However, when PrPC-depleted cell-lysate was added to the purified proteins the conversion was recovered. These findings provide direct evidence for the participation of a chaperone-like activity involved in catalyzing the conversion of PrPC into PrPSc.     

Solution structure of the E200K variant of human prion protein. Implications for the mechanism of pathogenesis in familial prion diseases

Prion propagation in transmissible spongiform encephalopathies involves the conversion of cellular prion protein, PrP(C), into a pathogenic conformer, PrP(Sc). Hereditary forms of the disease are linked to specific mutations in the gene coding for the prion protein. To gain insight into the molecular basis of these disorders, the solution structure of the familial Creutzfeldt-Jakob disease-related E200K variant of human prion protein was determined by multi-dimensional nuclear magnetic resonance spectroscopy. Remarkably, apart from minor differences in flexible regions, the backbone tertiary structure of the E200K variant is nearly identical to that reported for the wild-type human prion protein. The only major consequence of the mutation is the perturbation of surface electrostatic potential. The present structural data strongly suggest that protein surface defects leading to abnormalities in the interaction of prion protein with auxiliary proteins/chaperones or cellular membranes should be considered key determinants of a spontaneous PrP(C) --> PrP(Sc) conversion in the E200K form of hereditary prion disease.     

Most of the structural elements of the globular domain of murine prion protein form fibrils with predominant beta-sheet structure

The conversion of the cellular prion protein into the beta-sheet-rich scrapie prion protein is thought to be the key step in the pathogenesis of prion diseases. To gain insight into this structural conversion, we analyzed the intrinsic structural propensity of the amino acid sequence of the murine prion C-terminal domain. For that purpose, this globular domain was dissected into its secondary structural elements and the structural propensity of the protein fragments was determined. Our results show that all these fragments, excepted that strictly encompassing helix 1, have a very high propensity to form structured aggregates with a dominant content of beta-sheet structures.     

Squalestatin cures prion-infected neurons and protects against prion neurotoxicity

A key feature of prion diseases is the conversion of the normal, cellular prion protein (PrP(C)) into beta-sheet-rich disease-related isoforms (PrP(Sc)), the deposition of which is thought to lead to neurodegeneration. In the present study, the squalene synthase inhibitor squalestatin reduced the cholesterol content of cells and prevented the accumulation of PrP(Sc) in three prion-infected cell lines (ScN2a, SMB, and ScGT1 cells). ScN2a cells treated with squalestatin were also protected against microglia-mediated killing. Treatment of neurons with squalestatin resulted in a redistribution of PrP(C) away from Triton X-100 insoluble lipid rafts. These effects of squalestatin were dose-dependent, were evident at nanomolar concentrations, and were partially reversed by cholesterol. In addition, uninfected neurons treated with squalestatin became resistant to the otherwise toxic effect of PrP peptides, a synthetic miniprion (sPrP106) or partially purified prion preparations. The protective effect of squalestatin, which was reversed by the addition of water-soluble cholesterol, correlated with a reduction in prostaglandin E(2) production that is associated with neuronal injury in prion disease. These studies indicate a pivotal role for cholesterol-sensitive processes in controlling PrP(Sc) formation, and in the activation of signaling pathways associated with PrP-induced neuronal death.     

Insight into early events in the aggregation of the prion protein on lipid membranes

The key molecular event underlying prion diseases is the conversion of the monomeric and α-helical cellular form of the prion protein (PrP^C) to the disease-associated state, which is aggregated and rich in β-sheet (PrP^Sc). The molecular details associated with the conversion of PrP^C into PrP^Sc are not fully understood. The prion protein is attached to the cell membrane via a GPI lipid anchor and evidence suggests that the lipid environment plays an important role in prion conversion and propagation. We have previously shown that the interaction of the prion protein with anionic lipid membranes induces β-sheet structure and promotes prion aggregation, whereas zwitterionic membranes stabilize the α-helical form of the protein. Here, we report on the interaction of recombinant sheep prion protein with planar lipid membranes in real-time, using dual polarization interferometry (DPI). Using this technique, the simultaneous evaluation of multiple physical properties of PrP layers on membranes was achieved. The deposition of prion on membranes of POPC and POPC/POPS mixtures was studied. The properties of the resulting protein layers were found to depend on the lipid composition of the membranes. Denser and thicker protein deposits formed on lipid membranes containing POPS compared to those formed on POPC. DPI thus provides a further insight on the organization of PrP at the surface of lipid membranes.     

The mechanism of internalization of glycosylphosphatidylinositol-anchored prion protein

The mode of internalization of glycosylphosphatidylinositol-anchored proteins, lacking any cytoplasmic domain by which to engage adaptors to recruit them into coated pits, is problematical; that of prion protein in particular is of interest since its cellular trafficking appears to play an essential role in its pathogenic conversion. Here we demonstrate, in primary cultured neurons and the N2a neural cell line, that prion protein is rapidly and constitutively endocytosed. While still on the cell surface, prion protein leaves lipid 'raft' domains to enter non-raft membrane, from which it enters coated pits. The N-terminal domain (residues 23-107) of prion protein is sufficient to direct internalization, an activity dependent upon its initial basic residues (NH(2)-KKRPKP). The effect of this changing membrane environment upon the susceptibility of prion protein to pathogenic conversion is discussed.     

Solid-state NMR studies of the prion protein H1 fragment.

Conformational changes in the prion protein (PrP) seem to be responsible for prion diseases. We have used conformation-dependent chemical-shift measurements and rotational-resonance distance measurements to analyze the conformation of solid-state peptides lacking long-range order, corresponding to a region of PrP designated H1. This region is predicted to undergo a transformation of secondary structure in generating the infectious form of the protein. Solid-state NMR spectra of specifically 13C-enriched samples of H1, residues 109-122 (MKHMAGAAAAGAVV) of Syrian hamster PrP, have been acquired under cross-polarization and magic-angle spinning conditions. Samples lyophilized from 50% acetonitrile/50% water show chemical shifts characteristic of a beta-sheet conformation in the region corresponding to residues 112-121, whereas samples lyophilized from hexafluoroisopropanol display shifts indicative of alpha-helical secondary structure in the region corresponding to residues 113-117. Complete conversion to the helical conformation was not observed and conversion from alpha-helix back to beta-sheet, as inferred from the solid-state NMR spectra, occurred when samples were exposed to water. Rotational-resonance experiments were performed on seven doubly 13C-labeled H1 samples dried from water. Measured distances suggest that the peptide is in an extended, possibly beta-strand, conformation. These results are consistent with the experimental observation that PrP can exist in different conformational states and with structural predictions based on biological data and theoretical modeling that suggest that H1 may play a key role in the conformational transition involved in the development of prion diseases.     

The effect of disease-associated mutations on the folding pathway of human prion protein

Propagation of transmissible spongiform encephalopathies is believed to involve the conversion of cellular prion protein, PrP(C), into a misfolded oligomeric form, PrP(Sc). An important step toward understanding the mechanism of this conversion is to elucidate the folding pathway(s) of the prion protein. We reported recently (Apetri, A. C., and Surewicz, W. K. (2002) J. Biol. Chem. 277, 44589-44592) that the folding of wild-type prion protein can best be described by a three-state sequential model involving a partially folded intermediate. Here we have performed kinetic stopped-flow studies for a number of recombinant prion protein variants carrying mutations associated with familial forms of prion disease. Analysis of kinetic data clearly demonstrates the presence of partially structured intermediates on the refolding pathway of each PrP variant studied. In each case, the partially folded state is at least one order of magnitude more populated than the fully unfolded state. The present study also reveals that, for the majority of PrP variants tested, mutations linked to familial prion diseases result in a pronounced increase in the thermodynamic stability, and thus the population, of the folding intermediate. These data strongly suggest that partially structured intermediates of PrP may play a crucial role in prion protein conversion, serving as direct precursors of the pathogenic PrP(Sc) isoform.     

The key-role of tyrosine 155 in the mechanism of prion transconformation as highlighted by a study of sheep mutant peptides

Prion protein is a strongly conserved and ubiquitous glycoprotein. The conformational conversion of the non-pathogenic cellular prion isoform (PrP(C)) into a pathogenic scrapie isoform (PrP(Sc)) is a fundamental event in the onset of transmissible spongiform encephalopathies (TSE). During this conversion, helix H1 and its two flanking loops are known to undergo a conformational transition into a beta-like structure. In order to understand mechanisms which trigger this transconformation, sheep prion protein synthetic peptides spanning helix 1 and beta-strand 2 (residues 142-166) were studied: (1) the N3 peptide, studied earlier, is known to fold into beta-hairpin-like conformation in phosphate buffer at neutral pH and to adopt a helix H1 conformation when dissolved in trifluoroethanol/phosphate buffer mixture, (2) The R156A mutant (peptide R15) and (3) the Y155A mutant (peptide Y14) of the N3 peptide are studied by circular dichroism and NMR spectroscopy in this article. Structural characterization of these peptides highlights the key role of tyrosine 155 in the stabilization of the beta-hairpin-like conformation of the sheep peptide in phosphate buffer. We propose a model where tyrosine 155 could stabilize the beta-hairpin structure by creating a hydrophobic core in phosphate buffer, necessary to initiate the beta-type structure formation. In the turn, the side chain ionic interaction, E152-R156 described before, seems to play a minor role relative to the hydrophobic packing, as observed with the R156A mutation (peptide R15). Interestingly, homology at amino acid residue 155 could be responsible for the species barrier in TSE.     

Structural requirements for efficient prion protein conversion

To understand why cross species infection of prion disease often results in inefficient transmission and reduced protein conversion, most research has focussed on defining the effect of variations in PrP primary structures, including sequence compatibility of substrate and seed. By contrast, little research has been aimed at investigating structural differences between different variants of PrP^C and secondary structural requirements for efficient conversion. This is despite a clear role for molecular chaperones in formation of prions in non-mammalian systems, indicating the importance of secondary/tertiary structure during the conversion process. Recent data from our laboratory on the cellular location of disease-specific prion cofactors supports the critical role of specific secondary structural motifs and the stability of these motifs in determining the efficiency of disease-specific prion protein conversion. In this paper we summarise our recent results and build on the hypothesis previously suggested by Wuthrich and colleagues, that stability of certain regions of the prion protein is crucial for protein conversion to abnormal isoforms in vivo. It is suggested that one role for molecular co-factors in the conversion process is to stabilise PrP^C structure in a form that is amenable for conversion to PrP^Sc.