Impact of methionine oxidation as an initial event on the pathway of human prion protein conversion

Prion diseases comprise a group of fatal neurodegenerative disorders characterized by the autocatalytic conversion of the cellular prion protein PrP^C into the infectious misfolded isoform PrP^Sc. Increasing evidence supports a specific role of oxidative stress in the onset of pathogenesis. Although the associated molecular mechanisms remain to be elucidated in detail, several studies currently suggest that methionine oxidation already detected in misfolded PrP^Sc destabilizes the native PrP fold as an early event in the conversion pathway. To obtain more insights about the specific impact of surface-exposed methionine residues on the oxidative-induced conversion of human PrP we designed, produced, and comparatively investigated two new pseudosulfoxidation mutants of human PrP 121–231 that comprises the well-folded C-terminal domain. Applying circular dichroism spectroscopy and dynamic light scattering techniques we showed that pseudosulfoxidation of all surface exposed Met residues formed a monomeric molten globule-like species with striking similarities to misfolding intermediates recently reported by other groups. However, individual pseudosulfoxidation at the polymorphic M129 site did not significantly contribute to the structural destabilization. Further metal-induced oxidation of the partly unfolded pseudosulfoxidation mutant resulted in the formation of an oligomeric state that shares a comparable size and stability with PrP oligomers detected after the application of different other triggers for structural conversion, indicating a generic misfolding pathway of PrP. The obtained results highlight the specific importance of methionine oxidation at surface exposed residues for PrP misfolding, strongly supporting the hypothesis that increased oxidative stress could be one causative event for sporadic prion diseases and other neurodegenerative disorders.     

A simple in vitro assay for assessing the efficacy,mechanisms and kinetics of anti-prion fibril compounds

ABSTRACT

Prion diseases are caused by the conversion of normal cellular prion proteins (PrP) into lethal prion aggregates. These prion aggregates are composed of proteinase K (PK) resistant fibrils and comparatively PK-sensitive oligomers. Currently there are no anti-prion pharmaceuticals available to treat or prevent prion disease. Methods of discovering anti-prion molecules rely primarily on relatively complex cell-based, tissue slice or animal-model assays that measure the effects of small molecules on the formation of PK-resistant prion fibrils. These assays are difficult to perform and do not detect the compounds that directly inhibit oligomer formation or alter prion conversion kinetics. We have developed a simple cell-free method to characterize the impact of anti-prion fibril compounds on both the oligomer and fibril formation. In particular, this assay uses shaking-induced conversion (ShIC) of recombinant PrP in a 96-well format and resolution enhanced native acidic gel electrophoresis (RENAGE) to generate, assess and detect PrP fibrils in a high throughput fashion. The end-point PrP fibrils from this assay can be further characterized by PK analysis and negative stain transmission electron microscopy (TEM). This cell-free, gel-based assay generates metrics to assess anti-prion fibril efficacy and kinetics. To demonstrate its utility, we characterized the action of seven well-known anti-prion molecules: Congo red, curcumin, GN8, quinacrine, chloropromazine, tetracycline, and TUDCA (taurourspdeoxycholic acid), as well as four suspected anti-prion compounds: trans-resveratrol, rosmarinic acid, myricetin and ferulic acid. These findings suggest that this in vitro assay could be useful in identifying and comprehensively assessing novel anti-prion fibril compounds.

Abbreviations: PrP, prion protein; PK, proteinase K; ShIC, shaking-induced conversion; RENAGE, resolution enhanced native acidic gel electrophoresis; TEM, transmission electron microscopy; TUDCA, taurourspdeoxycholic acid; BSE, bovine spongiform encephalopathy; CWD, chronic wasting disease; CJD, Creutzfeldt Jakob disease; GSS, Gerstmann–Sträussler–Scheinker syndrome; FFI, fatal familial insomnia; PrP^c, cellular prion protein; recPrP^C, recombinant monomeric prion protein; PrP^Sc, infectious particle of misfolded prion protein; RT-QuIC, real-time quaking-induced conversion; PMCA, Protein Misfolding Cyclic Amplification; LPS, lipopolysaccharide; EGCG, epigallocatechin gallate; GN8, 2-pyrrolidin-1-yl-N-[4-[4-(2-pyrrolidin-1-yl-acetylamino)-benzyl]-phenyl]-acetamide; DMSO, dimethyl sulfoxide; ScN2A, scrapie infected neuroblastoma cells; IC50, inhibitory concentration for 50% reduction; recMoPrP ^23?231, recombinant full-length mouse prion protein residues 23-231; EDTA; PICUP, photo-induced cross-linking of unmodified protein; BSA, bovine serum albumin;; PMSF, phenylmethanesulfonyl fluoride.     

Insoluble cellular prion protein and its association with prion and Alzheimer diseases

The soluble cellular prion protein (PrP^C) is best known for its association with prion disease (PrD) through its conversion to a pathogenic insoluble isoform (PrP^Sc). However, its deleterious effects independent of PrP^Sc have recently been observed not only in PrD but also in Alzheimer disease (AD), two diseases which mainly affect cognition. At the same time, PrP^C itself seems to have broad physiologic functions including involvement in cognitive processes. The PrP^C that is believed to be soluble and monomeric has so far been the only PrP conformer observed in the uninfected brain. In 2006, we identified an insoluble PrP^C conformer (termed iPrP^C) in uninfected human and animal brains. Remarkably, the PrP^Sc-like iPrP^C shares the immunoreactivity behavior and fragmentation with a newly-identified PrP^Sc species in a novel human PrD termed variably protease-sensitive prionopathy. Moreover, iPrP^C has been observed as the major PrP species that interacts with amyloid β (Aβ) in AD. This article highlights evidence of PrP involvement in two putatively beneficial and deleterious PrP-implicated pathways in cognition and hypothesizes first, that beneficial and deleterious effects of PrP^C are attributable to the chameleon-like conformation of the protein and second, that the iPrP^C conformer is associated with PrD and AD.Key words: prion protein, prion disease, cognition, cognitive deficit, insoluble prion protein, Alzheimer disease, variably protease-sensitive prionopathy, dementia, memory     

PrP N-terminal domain triggers PrP(Sc)-like aggregation of Dpl

Transmissible spongiform encephalopathies are fatal neurodegenerative disorders thought to be transmitted by self-perpetuating conformational conversion of a neuronal membrane glycoprotein (PrP^C, for “cellular prion protein”) into an abnormal state (PrP^Sc, for “scrapie prion protein”). Doppel (Dpl) is a protein that shares significant biochemical and structural homology with PrP^C. In contrast to its homologue PrP^C, Dpl is unable to participate in prion disease progression or to achieve an abnormal PrP^Sc-like state. We have constructed a chimeric mouse protein, composed of the N-terminal domain of PrP^C (residues 23-125) and the C-terminal part of Dpl (residues 58-157). This chimeric protein displays PrP-like biochemical and structural features; when incubated in presence of NaCl, the α-helical monomer forms soluble β-sheet-rich oligomers which acquire partial resistance to pepsin proteolysis in vitro, as do PrP oligomers. Moreover, the presence of aggregates akin to protofibrils is observed in soluble oligomeric species by electron microscopy.     

Identification of PrP sequences essential for the interaction between the PrP polymers and Aβ peptide in a yeast-based assay

Alzheimer disease is associated with the accumulation of oligomeric amyloid β peptide (Aβ), accompanied by synaptic dysfunction and neuronal death. Polymeric form of prion protein (PrP), PrP^Sc, is implicated in transmissible spongiform encephalopathies (TSEs). Recently, it was shown that the monomeric cellular form of PrP (PrP^C), located on the neuron surface, binds Aβ oligomers (and possibly other β-rich conformers) via the PrP_23–27 and PrP_90–110 segments, acting as Aβ receptor. On the other hand, PrP^Sc polymers efficiently bind to Aβ monomers and accelerate their oligomerization. To identify specific PrP sequences that are essential for the interaction between PrP polymers and Aβ peptide, we have co-expressed Aβ and PrP (or its shortened derivatives), fused to different fluorophores, in the yeast cell. Our data show that the 90–110 and 28–89 regions of PrP control the binding of proteinase-resistant PrP polymers to the Aβ peptide, whereas the 23–27 segment of PrP is dispensable for this interaction. This indicates that the set of PrP fragments involved in the interaction with Aβ depends on PrP conformational state.     

Role of polysaccharide and lipid in lipopolysaccharide induced prion protein conversion

Conversion of native cellular prion protein (PrP^c) from an α-helical structure to a toxic and infectious β-sheet structure (PrP^Sc) is a critical step in the development of prion disease. There are some indications that the formation of PrP^Sc is preceded by a β-sheet rich PrP (PrP^β) form which is non-infectious, but is an intermediate in the formation of infectious PrP^Sc. Furthermore the presence of lipid cofactors is thought to be critical in the formation of both intermediate-PrP^β and lethal, infectious PrP^Sc. We previously discovered that the endotoxin, lipopolysaccharide (LPS), interacts with recombinant PrP^c and induces rapid conformational change to a β-sheet rich structure. This LPS induced PrP^β structure exhibits PrP^Sc-like features including proteinase K (PK) resistance and the capacity to form large oligomers and rod-like fibrils. LPS is a large, complex molecule with lipid, polysaccharide, 2-keto-3-deoxyoctonate (Kdo) and glucosamine components. To learn more about which LPS chemical constituents are critical for binding PrP^c and inducing β-sheet conversion we systematically investigated which chemical components of LPS either bind or induce PrP conversion to PrP^β. We analyzed this PrP conversion using resolution enhanced native acidic gel electrophoresis (RENAGE), tryptophan fluorescence, circular dichroism, electron microscopy and PK resistance. Our results indicate that a minimal version of LPS (called detoxified and partially de-acylated LPS or dLPS) containing a portion of the polysaccharide and a portion of the lipid component is sufficient for PrP conversion. Lipid components, alone, and saccharide components, alone, are insufficient for conversion.     

Recombinant Prion Protein Refolded with Lipid and RNA Has the Biochemical Hallmarks of a Prion but Lacks In Vivo Infectivity

During prion infection, the normal, protease-sensitive conformation of prion protein (PrP^C) is converted via seeded polymerization to an abnormal, infectious conformation with greatly increased protease-resistance (PrP^Sc). In vitro, protein misfolding cyclic amplification (PMCA) uses PrP^Sc in prion-infected brain homogenates as an initiating seed to convert PrP^C and trigger the self-propagation of PrP^Sc over many cycles of amplification. While PMCA reactions produce high levels of protease-resistant PrP, the infectious titer is often lower than that of brain-derived PrP^Sc. More recently, PMCA techniques using bacterially derived recombinant PrP (rPrP) in the presence of lipid and RNA but in the absence of any starting PrP^Sc seed have been used to generate infectious prions that cause disease in wild-type mice with relatively short incubation times. These data suggest that lipid and/or RNA act as cofactors to facilitate the de novo formation of high levels of prion infectivity. Using rPrP purified by two different techniques, we generated a self-propagating protease-resistant rPrP molecule that, regardless of the amount of RNA and lipid used, had a molecular mass, protease resistance and insolubility similar to that of PrP^Sc. However, we were unable to detect prion infectivity in any of our reactions using either cell-culture or animal bioassays. These results demonstrate that the ability to self-propagate into a protease-resistant insoluble conformer is not unique to infectious PrP molecules. They suggest that the presence of RNA and lipid cofactors may facilitate the spontaneous refolding of PrP into an infectious form while also allowing the de novo formation of self-propagating, but non-infectious, rPrP-res.     

A novel anti‐prion protein monoclonal antibody and its single‐chain fragment variable derivative with ability to inhibit abnormal prion protein accumulation in cultured cells

mAbs T1 and T2 were established by immunizing PrP gene ablated mice with recombinant MoPrP of residues 121–231. Both mAbs were cross‐reactive with PrP from hamster, sheep, cattle and deer. A linear epitope of mAb T1 was identified at residues 137–143 of MoPrP and buried in PrP^C expressed on the cell surface. mAb T1 showed no inhibitory effect on accumulation of PrP^Sc in cultured scrapie‐infected neuroblastoma (ScN2a) cells. In contrast, mAb T2 recognized a discontinuous epitope ranged on, or structured by, residues 132–217 and this epitope was exposed on the cell surface PrP^C. mAb T2 showed an excellent inhibitory effect on PrP^Sc accumulation in vitro at a 50% inhibitory concentration of 0.02 μg/ml (0.14 nM). The scFv form of mAb T2 (scFv T2) was secreted in neuroblastoma (N2a58) cell cultures by transfection through eukaryotic secretion vector. Coculturing of ScN2a cells with scFv T2‐producing N2a58 cells induced a clear inhibitory effect on PrP^Sc accumulation, suggesting that scFv T2 could potentially be an immunotherapeutic tool for prion diseases by inhibition of PrP^Sc accumulation.     

Molecular model of an alpha-helical prion protein dimer and its monomeric subunits as derived from chemical cross-linking and molecular modeling calculations

Prions are the agents of a series of lethal neurodegenerative diseases. They are composed largely, if not entirely, of the host-encoded prion protein (PrP), which can exist in the cellular isoform PrP^C and the pathological isoform PrP^Sc. The conformational change of the α-helical PrP^C into β-sheet-rich PrP^Sc is the fundamental event of prion disease. The transition of recombinant PrP from a PrP^C-like into a PrP^Sc-like conformation can be induced in vitro by submicellar concentrations of SDS. An α-helical dimer was identified that might represent either the native state of PrP^C or the first step from the monomeric PrP^C to highly aggregated PrP^Sc. In the present study, the molecular structure of these dimers was analyzed by introducing covalent cross-links using 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide. Inter- and intramolecular bonds between directly neighboured amino groups and carboxy groups were generated. The bonds formed in PrP dimers of recombinant PrP (90-231) were identified by tryptic digestion and subsequent mass spectrometric analysis. Intra- and intermolecular cross-links between N-terminal glycine and three acidic amino acid side chains in the globular part of PrP were identified, showing the N-terminal amino acids (90-124) are not as flexible as known from NMR analysis. When the cross-linked sites were used as structural constraint, molecular modeling calculations yielded a structural model for PrP dimer and its monomeric subunit, including the folding of amino acids 90-124 in addition to the known structure. Molecular dynamics of the structure after release of the constraint indicated an intrinsic stability of the domain of amino acids 90-124.     

Antibodies to a Nonconjugated Prion Protein Peptide 95-123 Interfere with PrP<Superscript><Emphasis Type="Bold">Sc</Emphasis></Superscript> Propagation in Prion-Infected Cells

Summary 1. Vaccination-induced anti-prion protein antibodies are presently regarded as a promising approach toward treatment of prion diseases. Here, we investigated the ability of five peptides corresponding to three different regions of the bovine prion protein (PrP) to elicit antibodies interfering with PrP^Sc propagation in prion-infected cells. 2. Rabbits were immunized with free nonconjugated peptides. Obtained immune sera were tested in enzyme-linked immunosorbent assay (ELISA) and immunoblot for their binding to recombinant PrP and cell-derived pathogenic isoform (PrP^Sc) and normal prion protein (PrP^c), respectively. Sera positive in all tests were chosen for PrP^Sc inhibition studies in cell culture. 3. All peptides induced anti-peptide antibodies, most of them reacting with recombinant PrP. Moreover, addition of the serum specific to peptide 95–123 led to a transient reduction of PrP^Sc levels in persistently prion-infected cells. 4. Thus, anti-PrP antibodies interfering with PrP^Sc propagation were induced with a prion protein peptide nonconjugated to a protein carrier. These results point to the potential application of the nonconjugated peptide 95–123 for the treatment of prion diseases.     

Insoluble cellular prion protein and its association with prion and Alzheimer diseases

The soluble cellular prion protein (PrP^C) is best known for its association with prion disease (PrD) through its conversion to a pathogenic insoluble isoform (PrP^Sc). However, its deleterious effects independent of PrP^Sc have recently been observed not only in PrD but also in Alzheimer disease (AD), two diseases which mainly affect cognition. At the same time, PrP^C itself seems to have broad physiologic functions including involvement in cognitive processes. The PrP^C that is believed to be soluble and monomeric has so far been the only PrP conformer observed in the uninfected brain. In 2006, we identified an insoluble PrP^C conformer (termed iPrP^C) in uninfected human and animal brains. Remarkably, the PrP^Sc-like iPrPC shares the immunoreactivity behavior and fragmentation with a newly-identified PrP^Sc species in a novel human PrD termed variably protease-sensitive prionopathy. Moreover, iPrP^C has been observed as the major PrP species that interacts with amyloid β (Aβ) in AD. This article highlights evidence of PrP involvement in two putatively beneficial and deleterious PrP-implicated pathways in cognition, and hypothesizes first, that beneficial and deleterious effects of PrPC are attributable to the chameleon-like conformation of the protein and second, that the iPrP^C conformer is associated with PrD and AD.     

Parallel In-register Intermolecular β-Sheet Architectures for Prion-seeded Prion Protein (PrP) Amyloids

Structures of the infectious form of prion protein (e.g. PrP^Sc or PrP-Scrapie) remain poorly defined. The prevalent structural models of PrP^Sc retain most of the native α-helices of the normal, noninfectious prion protein, cellular prion protein (PrP^C), but evidence is accumulating that these helices are absent in PrP^Sc amyloid. Moreover, recombinant PrP^C can form amyloid fibrils in vitro that have parallel in-register intermolecular β-sheet architectures in the domains originally occupied by helices 2 and 3. Here, we provide solid-state NMR evidence that the latter is also true of initially prion-seeded recombinant PrP amyloids formed in the absence of denaturants. These results, in the context of a primarily β-sheet structure, led us to build detailed models of PrP amyloid based on parallel in-register architectures, fibrillar shapes and dimensions, and other available experimentally derived conformational constraints. Molecular dynamics simulations of PrP(90–231) octameric segments suggested that such linear fibrils, which are consistent with many features of PrP^Sc fibrils, can have stable parallel in-register β-sheet cores. These simulations revealed that the C-terminal residues ∼124–227 more readily adopt stable tightly packed structures than the N-terminal residues ∼90–123 in the absence of cofactors. Variations in the placement of turns and loops that link the β-sheets could give rise to distinct prion strains capable of faithful template-driven propagation. Moreover, our modeling suggests that single PrP monomers can comprise the entire cross-section of fibrils that have previously been assumed to be pairs of laterally associated protofilaments. Together, these insights provide a new basis for deciphering mammalian prion structures.     

Isolation of Soluble and Insoluble PrP Oligomers in the Normal Human Brain

The central event in the pathogenesis of prion diseases involves a conversion of the host-encoded cellular prion protein PrP^C into its pathogenic isoform PrP^{Sc 1}. PrP^C is detergent-soluble and sensitive to proteinase K (PK)-digestion, whereas PrP^Sc forms detergent-insoluble aggregates and is partially resistant to PK^2-6. The conversion of PrP^C to PrP^Sc is known to involve a conformational transition of α-helical to β-sheet structures of the protein. However, the in vivo pathway is still poorly understood. A tentative endogenous PrP^Sc, intermediate PrP* or "silent prion", has yet to be identified in the uninfected brain⁷.Using a combination of biophysical and biochemical approaches, we identified insoluble PrP^C aggregates (designated iPrP^C) from uninfected mammalian brains and cultured neuronal cells^{8, 9}. Here, we describe detailed procedures of these methods, including ultracentrifugation in detergent buffer, sucrose step gradient sedimentation, size exclusion chromatography, iPrP enrichment by gene 5 protein (g5p) that specifically bind to structurally altered PrP forms¹⁰, and PK-treatment. The combination of these approaches isolates not only insoluble PrP^Sc and PrP^C aggregates but also soluble PrP^C oligomers from the normal human brain. Since the protocols described here have been used to isolate both PrP^Sc from infected brains and iPrP^C from uninfected brains, they provide us with an opportunity to compare differences in physicochemical features, neurotoxicity, and infectivity between the two isoforms. Such a study will greatly improve our understanding of the infectious proteinaceous pathogens. The physiology and pathophysiology of iPrP^C are unclear at present. Notably, in a newly-identified human prion disease termed variably protease-sensitive prionopathy, we found a new PrP^Sc that shares the immunoreactive behavior and fragmentation with iPrP^{C 11, 12}. Moreover, we recently demonstrated that iPrP^C is the main species that interacts with amyloid-β protein in Alzheimer disease¹³. In the same study, these methods were used to isolate Abeta aggregates and oligomers in Alzheimer''s disease¹³, suggesting their application to non-prion protein aggregates involved in other neurodegenerative disorders.     

Reversible monomer-oligomer transition in human prion protein

The structure and the dissociation reaction of oligomers PrP^oligo from reduced human prion huPrP^C(23–231) have been studied by ¹H-NMR and tryptophan fluorescence spectroscopy at varying pressure, along with circular dichroism and atomic force microscopy. The ¹H-NMR and fluorescence spectral feature of the oligomer is consistent with the notion that the N-terminal residues including all seven Trp residues, are free and mobile, while residues 105∼210, comprising the AGAAAAGA motif and S1-Loop-HelixA-Loop-S2-Loop-HelixC, are engaged in intra- and/or inter-molecular interactions. By increasing pressure to 200 MPa, the oligomers tend to dissociate into monomers which may be identified with PrP^C*, a rare metastable form of PrP^C stabilized at high pressure (Kachel et al., BMC Struct Biol 6:16). The results strongly suggest that the oligomeric form PrP^oligo is in dynamic equilibrium with the monomeric forms via PrP^C*, namely huPrP^C ⇆ huPrP^C* ⇆ huPrP^oligo.Key words: human prion, oligomer structure, pressure dissociation, reversible monomer-oligomer transition, circular dichroism, high pressure NMR, atomic force microscopy     

In Vivo Generation of Neurotoxic Prion Protein: Role for Hsp70 in Accumulation of Misfolded Isoforms

Prion diseases are incurable neurodegenerative disorders in which the normal cellular prion protein (PrP^C) converts into a misfolded isoform (PrP^Sc) with unique biochemical and structural properties that correlate with disease. In humans, prion disorders, such as Creutzfeldt-Jakob disease, present typically with a sporadic origin, where unknown mechanisms lead to the spontaneous misfolding and deposition of wild type PrP. To shed light on how wild-type PrP undergoes conformational changes and which are the cellular components involved in this process, we analyzed the dynamics of wild-type PrP from hamster in transgenic flies. In young flies, PrP demonstrates properties of the benign PrP^C; in older flies, PrP misfolds, acquires biochemical and structural properties of PrP^Sc, and induces spongiform degeneration of brain neurons. Aged flies accumulate insoluble PrP that resists high concentrations of denaturing agents and contains PrP^Sc-specific conformational epitopes. In contrast to PrP^Sc from mammals, PrP is proteinase-sensitive in flies. Thus, wild-type PrP rapidly converts in vivo into a neurotoxic, protease-sensitive isoform distinct from prototypical PrP^Sc. Next, we investigated the role of molecular chaperones in PrP misfolding in vivo. Remarkably, Hsp70 prevents the accumulation of PrP^Sc-like conformers and protects against PrP-dependent neurodegeneration. This protective activity involves the direct interaction between Hsp70 and PrP, which may occur in active membrane microdomains such as lipid rafts, where we detected Hsp70. These results highlight the ability of wild-type PrP to spontaneously convert in vivo into a protease-sensitive isoform that is neurotoxic, supporting the idea that protease-resistant PrP^Sc is not required for pathology. Moreover, we identify a new role for Hsp70 in the accumulation of misfolded PrP. Overall, we provide new insight into the mechanisms of spontaneous accumulation of neurotoxic PrP and uncover the potential therapeutic role of Hsp70 in treating these devastating disorders.     

Heparin-like molecules bind differentially to prion-proteins and change their intracellular metabolic fate

PrP^Sc is the only known component of the scrapie prion. The difference between PrP^Sc and its normal isoform PrP^c is probably conformational, since no difference has been found in the amino acid sequence or postranslational modifications between both proteins. Heparan sulfate (HS) has been shown to be a component of amyloid plaques in a number of diseases including the prion diseases. We now present evidence that PrP can specifically bind to heparin-like compounds and that this interaction might have a physiological significance. HS can increase the concentration of PrP in normal neuroblastoma cells, whereas low molecular weight heparin (LMWH) does not. In contrast, LMWH and other heparin-like molecules, excluding HS, can inhibit the synthesis of PrP^Sc in scrapie infected cells and reverse their phenotype back to normal as judged by measurement of PrP^Sc by immunoblotting and by infectivity experiments. Whether an interaction between PrP and glycosaminoglycans plays a direct role in the conversion of PrP^c into PrP^Sc remains to be established. © 1993 Wiley-Liss, Inc.     

Intermolecular crosslinking of abnormal prion protein is efficiently induced by a primuline-sensitized photoreaction

In prion diseases, infectious pathogenic particles that are composed of abnormal prion proteins (PrP^Sc) accumulate in the brain. PrP^Sc is biochemically characterized by its protease-resistance core (PrP^res), but its structural features have not been fully elucidated. Here, we report that primuline, a fluorescent dye with photosensitization activity, dramatically enhances UV-irradiation-induced SDS-resistant PrP^Sc/res oligomer formation that can be detected by immunoblot analysis of prion-infected materials. This oligomer formation occurs specifically with PrP^Sc/res but not with normal prion protein, and it was demonstrated using purified PrP^Sc/res as well as unpurified materials. The oligomer formation proceeded in both primuline-dose- and UV irradiation time-dependent manners. Treatment with urea or formic acid did not break oligomers into monomers. Neither did the presence of aromatic amino acids modify oligomer formation. Analysis with a panel of anti-prion protein antibodies showed that the antibodies against the N-terminal region of PrP^res were less reactive in the dimer than the monomer. These findings suggest that the primuline-sensitized photoreaction enhances intermolecular crosslinking of PrP^Sc/res molecules at a hydrophobic area of the N-terminal region of PrP^res. In the screening of other compounds, photoreactive compounds such as luciferin exhibited a similar but lower activity with respect to oligomer formation than primuline. The enhanced photoreaction with these compounds will be useful for evaluating the structural features of PrP^Sc/res, especially the interactions between PrP^Sc/res molecules.     

NMR Structure of the Human Prion Protein with the Pathological Q212P Mutation Reveals Unique Structural Features

Prion diseases are fatal neurodegenerative disorders caused by an aberrant accumulation of the misfolded cellular prion protein (PrP^C) conformer, denoted as infectious scrapie isoform or PrP^Sc. In inherited human prion diseases, mutations in the open reading frame of the PrP gene (PRNP) are hypothesized to favor spontaneous generation of PrP^Sc in specific brain regions leading to neuronal cell degeneration and death. Here, we describe the NMR solution structure of the truncated recombinant human PrP from residue 90 to 231 carrying the Q212P mutation, which is believed to cause Gerstmann-Sträussler-Scheinker (GSS) syndrome, a familial prion disease. The secondary structure of the Q212P mutant consists of a flexible disordered tail (residues 90–124) and a globular domain (residues 125–231). The substitution of a glutamine by a proline at the position 212 introduces novel structural differences in comparison to the known wild-type PrP structures. The most remarkable differences involve the C-terminal end of the protein and the β₂–α₂ loop region. This structure might provide new insights into the early events of conformational transition of PrP^C into PrP^Sc. Indeed, the spontaneous formation of prions in familial cases might be due to the disruptions of the hydrophobic core consisting of β₂–α₂ loop and α₃ helix.     

PrP106-126 amide causes the semi-penetrated poration in the supported lipid bilayers

A major hallmark of prion diseases is the cerebral amyloid accumulation of the pathogenic PrP^Sc, an abnormally misfolded, protease-resistant, and β-sheet rich protein. PrP106-126 is the key domain responsible for the conformational conversion and aggregation of PrP. It shares important physicochemical characteristics with PrP^Sc and presents similar neurotoxicity as PrP^Sc. By combination of fluorescence polarization, dye release assay and in situ time-lapse atomic force microscopy (AFM), we investigated the PrP106-126 amide interacting with the large unilamellar vesicles (LUVs) and the supported lipid bilayers (SLBs). The results suggest that the interactions involve a poration-mediated process: firstly, the peptide binding results in the formation of pores in the membranes, which penetrate only half of the membranes; subsequently, PrP106-126 amide undergoes the poration-mediated diffusion in the SLBs, represented by the formation and expansion of the flat high-rise domains (FHDs). The possible mechanisms of the interactions between PrP106-126 amide and lipid membranes are proposed based on our observations.     

Different antigenicities of the N‐terminal region of cellular and scrapie prion proteins

Limited information is available about conformational differences between the abnormal isoform of prion protein (PrP^Sc) and cellular prion protein (PrP^C) under native conditions. To clarify conformational differences between these two isoforms, PrP‐deficient mice were immunized with brain homogenates of normal and scrapie‐infected animals. All mice generated anti‐PrP antibodies. Peptide array analysis of these serum samples revealed a distinctive epitope of PrP^Sc consisting of QGSPGGN (PrP41–47) at the N‐terminus. This study demonstrated a conformational dissimilarity at the N‐terminus between PrP^Sc and PrP^C, a finding that may provide novel information about conformational features of PrP^Sc.