Tracking protein aggregate interactions

Amyloid fibrils share a structural motif consisting of highly ordered β-sheets aligned perpendicular to the fibril axis.^{1, 2} At each fibril end, β-sheets provide a template for recruiting and converting monomers.³ Different amyloid fibrils often co-occur in the same individual, yet whether a protein aggregate aids or inhibits the assembly of a heterologous protein is unclear. In prion disease, diverse prion aggregate structures, known as strains, are thought to be the basis of disparate disease phenotypes in the same species expressing identical prion protein sequences.^4–7 Here we explore the interactions reported to occur when two distinct prion strains occur together in the central nervous system.Key words: prion, prions, strain, TSE, interaction, amyloid, LCP, neurodegeneration, aggregation     

Structural conservation of prion strain specificities in recombinant prion protein fibrils in real-time quaking-induced conversion

ABSTRACT

A major unsolved issue of prion biology is the existence of multiple strains with distinct phenotypes and this strain phenomenon is postulated to be associated with the conformational diversity of the abnormal prion protein (PrP^Sc). Real-time quaking-induced conversion (RT-QUIC) assay that uses Escherichia coli-derived recombinant prion protein (rPrP) for the sensitive detection of PrP^Sc results in the formation of rPrP-fibrils seeded with various strains. We demonstrated that there are differences in the secondary structures, especially in the β-sheets, and conformational stability between 2 rPrP-fibrils seeded with either Chandler or 22L strains in the first round of RT-QUIC. In particular, the differences in conformational properties of these 2 rPrP-fibrils were common to those of the original PrP^Sc. However, the strain specificities of rPrP-fibrils seen in the first round were lost in subsequent rounds. Instead, our findings suggest that nonspecific fibrils became the major species, probable owing to their selective growth advantage in the RT-QUIC. This study shows that at least some strain-specific conformational properties of the original PrP^Sc can be transmitted to rPrP-fibrils in vitro, but further conservation appears to require unknown cofactors or environmental conditions or both.     

The core of Ure2p prion fibrils is formed by the N-terminal segment in a parallel cross-β structure: evidence from solid-state NMR

Intracellular fibril formation by Ure2p produces the non-Mendelian genetic element [URE3] in Saccharomyces cerevisiae, making Ure2p a prion protein. We show that solid-state NMR spectra of full-length Ure2p fibrils, seeded with infectious prions from a specific [URE3] strain and labeled with uniformly ¹⁵N-¹³C-enriched Ile, include strong, sharp signals from Ile residues in the globular C-terminal domain (CTD) with both helical and nonhelical ¹³C chemical shifts. Treatment with proteinase K eliminates these CTD signals, leaving only nonhelical signals from the Gln-rich and Asn-rich N-terminal segment, which are also observed in the solid-state NMR spectra of Ile-labeled fibrils formed by residues 1-89 of Ure2p. Thus, the N-terminal segment, or “prion domain” (PD), forms the fibril core, while CTD units are located outside the core. We additionally show that, after proteinase K treatment, Ile-labeled Ure2p fibrils formed without prion seeding exhibit a broader set of solid-state NMR signals than do prion-seeded fibrils, consistent with the idea that structural variations within the PD core account for prion strains. Measurements of ¹³C-¹³C magnetic dipole-dipole couplings among ¹³C-labeled Ile carbonyl sites in full-length Ure2p fibrils support an in-register parallel β-sheet structure for the PD core of Ure2p fibrils. Finally, we show that a model in which CTD units are attached rigidly to the parallel β-sheet core is consistent with steric constraints.     

Prion Propagation is Dependent on Key Amino Acids in Charge Cluster 2 within the Prion Protein

To dissect the N-terminal residues within the cellular prion protein (PrP^C) that are critical for efficient prion propagation, we generated a library of point, double, or triple alanine replacements within residues 23–111 of PrP, stably expressed them in cells silenced for endogenous mouse PrP^C and challenged the reconstituted cells with four common but biologically diverse mouse prion strains. Amino acids (aa) 105–111 of Charge Cluster 2 (CC2), which is disordered in PrP^C, were found to be required for propagation of all four prion strains; other residues had no effect or exhibited strain-specific effects. Replacements in CC2, including aa105-111, dominantly inhibited prion propagation in the presence of endogenous wild type PrP^C whilst other changes were not inhibitory. Single alanine replacements within aa105-111 identified leucine 108 and valine 111 or the cluster of lysine 105, threonine 106 and asparagine 107 as critical for prion propagation. These residues mediate specific ordering of unstructured CC2 into β-sheets in the infectious prion fibrils from Rocky Mountain Laboratory (RML) and ME7 mouse prion strains.     

Structural polymorphism of Alzheimer A�� and other amyloid fibrils

Deposits of amyloid fibrils characterize a diverse group of human diseases that includes Alzheimer disease, Creutzfeldt-Jakob disease and type II diabetes. Amyloid fibrils formed from different polypeptides contain a common cross-β spine. Nevertheless, amyloid fibrils formed from the same polypeptide can occur in a range of structurally different morphologies. The heterogeneity of amyloid fibrils reflects different types of polymorphism: (1) variations in the protofilament number, (2) variations in the protofilament arrangement and (3) different polypeptide conformations. Amyloid fibril polymorphism implies that fibril formation can lead, for the same polypeptide sequence, to many different patterns of inter- or intra-residue interactions. This property differs significantly from native, monomeric protein folding reactions that produce, for one protein sequence, only one ordered conformation and only one set of inter-residue interactions.Key words: Alzheimer disease, aggregation, neurodegeneration, prion, protein folding     

Conformational Stability of Mammalian Prion Protein Amyloid Fibrils Is Dictated by a Packing Polymorphism within the Core Region

Mammalian prion strains are believed to arise from the propagation of distinct conformations of the misfolded prion protein PrP^Sc. One key operational parameter used to define differences between strains has been conformational stability of PrP^Sc as defined by resistance to thermal and/or chemical denaturation. However, the structural basis of these stability differences is unknown. To bridge this gap, we have generated two strains of recombinant human prion protein amyloid fibrils that show dramatic differences in conformational stability and have characterized them by a number of biophysical methods. Backbone amide hydrogen/deuterium exchange experiments revealed that, in sharp contrast to previously studied strains of infectious amyloid formed from the yeast prion protein Sup35, differences in β-sheet core size do not underlie differences in conformational stability between strains of mammalian prion protein amyloid. Instead, these stability differences appear to be dictated by distinct packing arrangements (i.e. steric zipper interfaces) within the amyloid core, as indicated by distinct x-ray fiber diffraction patterns and large strain-dependent differences in hydrogen/deuterium exchange kinetics for histidine side chains within the core region. Although this study was limited to synthetic prion protein amyloid fibrils, a similar structural basis for strain-dependent conformational stability may apply to brain-derived PrP^Sc, especially because large strain-specific differences in PrP^Sc stability are often observed despite a similar size of the PrP^Sc core region.     

The Formation and Disaggregation of Soy Protein Isolate Fibril: Effects of pH

To identify the effects of charged states on the formation and disaggregation of soy protein isolate (SPI) fibril, we studied the thermal aggregation behaviors of the constituent peptides of SPI fibril (CPSF) at various pH values (2–10) and investigated the structural changes of SPI fibril with increasing pH (2–11). Results showed that CPSF would assemble into diverse shapes at different pH values, among which the aggregates contained multiple β-sheet structures at pH less than 6, but these β-sheets were stacked to form fibrils only at pH 2. The damages from the increased pH to SPI fibril structure could be roughly divided into two stages, as follows: when pH was less than or equal to 6, the morphology of fibrils changed markedly due to electrostatic neutralization; at pH larger than 6, the fibrils suffered great losses in β-sheet, causing its structure to disintegrate rapidly. This study could provide theoretical reference to improve the pH stability of SPI fibril from the aspects of preparation and structural protection of the fibril.

     

Dissection of Conformational Conversion Events during Prion Amyloid Fibril Formation Using Hydrogen Exchange and Mass Spectrometry

A molecular understanding of prion diseases requires an understanding of the mechanism of amyloid fibril formation by the prion protein. In particular, it is necessary to define the sequence of the structural events describing the conformational conversion of monomeric PrP to aggregated PrP. In this study, the sequence of the structural events in the case of amyloid fibril formation by recombinant mouse prion protein at pH 7 has been characterized by hydrogen–deuterium exchange and mass spectrometry. The observation that fibrils are substantially more stable to hydrogen–deuterium exchange than is native monomer allows both forms to be quantified during the course of the aggregation reaction. Under the aggregation conditions utilized, native monomeric protein and amyloid fibrils are the only forms of the protein detectable during the course of the fibril formation reaction, suggesting that monomer directly adds on to the fibril template. Conformational conversion is shown to occur in two steps after the binding of monomer to fibril, with helix 1 unfolding only after helices 2 and 3 transform into β-sheet. Local stability in the β-sheet core region (residues ~ 159–225) of the fibrils is shown to be sequence dependent in that it varies along the length of the core, and local stability in protein molecules that are ordered in the structurally heterogeneous sequence segment 109–132 is shown to be similar to that in the core. This new understanding of the structural events during prion protein aggregation has important bearing on our comprehension of the molecular basis of prion pathogenesis.     

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.     

The Structural Architecture of an Infectious Mammalian Prion Using Electron Cryomicroscopy

The structure of the infectious prion protein (PrP^Sc), which is responsible for Creutzfeldt-Jakob disease in humans and bovine spongiform encephalopathy, has escaped all attempts at elucidation due to its insolubility and propensity to aggregate. PrP^Sc replicates by converting the non-infectious, cellular prion protein (PrP^C) into the misfolded, infectious conformer through an unknown mechanism. PrP^Sc and its N-terminally truncated variant, PrP 27–30, aggregate into amorphous aggregates, 2D crystals, and amyloid fibrils. The structure of these infectious conformers is essential to understanding prion replication and the development of structure-based therapeutic interventions. Here we used the repetitive organization inherent to GPI-anchorless PrP 27–30 amyloid fibrils to analyze their structure via electron cryomicroscopy. Fourier-transform analyses of averaged fibril segments indicate a repeating unit of 19.1 Å. 3D reconstructions of these fibrils revealed two distinct protofilaments, and, together with a molecular volume of 18,990 ų, predicted the height of each PrP 27–30 molecule as ~17.7 Å. Together, the data indicate a four-rung β-solenoid structure as a key feature for the architecture of infectious mammalian prions. Furthermore, they allow to formulate a molecular mechanism for the replication of prions. Knowledge of the prion structure will provide important insights into the self-propagation mechanisms of protein misfolding.     

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.     

Spontaneous and BSE-prion-seeded amyloid formation of full length recombinant bovine prion protein

The conversion of the cellular isoform of the prion protein into the pathogenic isoform PrP^Sc is the key event in prion diseases. The disease can occur spontaneously genetically or by infection. In earlier studies we presented an in vitro conversion system which simulates the structural transition in recPrP by varying low concentrations of SDS at constant NaCl. In the present study we adopted the conversion system from experimental Scrapie in hamster to bovine recPrP and generated amyloid fibrils. The intermediate state which is optimal for fibril formation is a soluble, β-rich state. The system was extended using BSE-prions as seeds and led to an acceleration of fibril formation by orders of magnitude. This seeded amyloid formation assay avoids any PK-treatment, is therefore able to detect even PK-sensitive PrP^Sc and does not require cellular components.     

Structure-based view on [PSI+] prion properties

ABSTRACT

Yeast [PSI⁺] prion is one of the most suitable and well characterized system for the investigation of the prion phenomenon. However, until recently, the lack of data on the 3D arrangement of Sup35p prion fibrils hindered progress in this area. The recent arrival in this field of new experimental techniques led to the parallel and in-register superpleated β-structure as a consensus model for Sup35p fibrils. Here, we analyzed the effect of amino acid substitutions of the Sup35 protein through the prism of this structural model. Application of a newly developed computational approach, called ArchCandy, gives us a better understanding of the effect caused by mutations on the fibril forming potential of Sup35 protein. This bioinformatics tool can be used for the design of new mutations with desired modification of prion properties. Thus, we provide examples of how today, having progress toward elucidation of the structural arrangement of Sup35p fibrils, researchers can advance more efficiently to a better understanding of prion [PSI⁺] stability and propagation.     

Amyloid fibrillation kinetics: insight from atomistic nucleation theory

We consider the nucleation of nanosized amyloid fibrils composed of successively layered β-sheets at the molecular level when this process takes place by direct polymerization of protein segments (β-strands) into β-sheets. Application of the atomistic nucleation theory (ANT) to amyloid nucleation of β(2)-microglobulin and amyloid β(40) allows us to predict the fibril nucleus size and the fibril nucleation rate as functions of the supersaturation of the protein solution. The ANT predictions are compared to recent time-resolved optical experiments where they measure the effect of the protein concentration and mutations on the initial lag time before amyloid fibrils form in the protein solution. The presented analysis reveals the general principles underlying the nucleation kinetics of nanosized amyloid fibrils and indicates that it can be treated in the framework of existing general theories of the nucleation of new phases.     

Molecular structure of amyloid fibrils controls the relationship between fibrillar size and toxicity

Background

According to the prevailing view, soluble oligomers or small fibrillar fragments are considered to be the most toxic species in prion diseases. To test this hypothesis, two conformationally different amyloid states were produced from the same highly pure recombinant full-length prion protein (rPrP). The cytotoxic potential of intact fibrils and fibrillar fragments generated by sonication from these two states was tested using cultured cells.

Methodology/Principal Findings

For one amyloid state, fibril fragmentation was found to enhance its cytotoxic potential, whereas for another amyloid state formed within the same amino acid sequence, the fragmented fibrils were found to be substantially less toxic than the intact fibrils. Consistent with the previous studies, the toxic effects were more pronounced for cell cultures expressing normal isoform of the prion protein (PrP^C) at high levels confirming that cytotoxicity was in part PrP^C-dependent. Silencing of PrP^C expression by small hairpin RNAs designed to silence expression of human PrP^C (shRNA-PrP^C) deminished the deleterious effects of the two amyloid states to a different extent, suggesting that the role of PrP^C-mediated and PrP^C-independent mechanisms depends on the structure of the aggregates.

Conclusions/Significance

This work provides a direct illustration that the relationship between an amyloid''s physical dimension and its toxic potential is not unidirectional but is controlled by the molecular structure of prion protein (PrP) molecules within aggregated states. Depending on the structure, a decrease in size of amyloid fibrils can either enhance or abolish their cytotoxic effect. Regardless of the molecular structure or size of PrP aggregates, silencing of PrP^C expression can be exploited to reduce their deleterious effects.     

Aβ(1-40) Forms Five Distinct Amyloid Structures whose β-Sheet Contents and Fibril Stabilities Are Correlated

The ability of a single polypeptide sequence to grow into multiple stable amyloid fibrils sets these aggregates apart from most native globular proteins. The existence of multiple amyloid forms is the basis for strain effects in yeast prion biology, and might contribute to variations in Alzheimer's disease pathology. However, the structural basis for amyloid polymorphism is poorly understood. We report here five structurally distinct fibrillar aggregates of the Alzheimer's plaque peptide Aβ(1-40), as well as a non-fibrillar aggregate induced by Zn²⁺. Each of these conformational forms exhibits a unique profile of physical properties, and all the fibrillar forms breed true in elongation reactions under a common set of growth conditions. Consistent with their defining cross-β structure, we find that in this series the amyloid fibrils containing more extensive β-sheet exhibit greater stability. At the same time, side chain packing outside of the β-sheet regions contributes to stability, and to differences of stability between polymorphic forms. Stability comparison is facilitated by the unique feature that the free energy of the monomer (equivalent to the unfolded state in a protein folding reaction) does not vary, and hence can be ignored, in the comparison of ΔG° of elongation values for each polymorphic fibril obtained under a single set of conditions.     

Influence of divalent copper, manganese and zinc ions on fibril nucleation and elongation of the amyloid-like yeast prion determinant Sup35p-NM

There is a large body of evidence that divalent metal ions, particularly copper, might play a role in several protein folding pathologies like Alzheimer’s disease, Parkinson’s disease or the prion diseases. However, contribution of metal ions on pathogenesis and their molecular influence on the formation of amyloid structures is not clear. Therefore, the general influence of metals on the formation of amyloids is still controversially discussed. We have utilized the well established system of yeast Sup35p-NM to investigate the role of three different metal ions, Cu²⁺, Mn²⁺ and Zn²⁺, on amyloidogenesis. Recently, it has been shown that the prion determining region NM of the Saccharomyces cerevisiae prion protein Sup35p, which is responsible for the yeast prion phenotype [PSI⁺], specifically binds Cu²⁺ ions. We further characterized the affinity of NM for Cu²⁺, which were found to be comparable to that of other amyloidogenic proteins like the mammalian prion protein PrP. The specific binding sites could be located in the aminoterminal N-region which is known to initiate formation of amyloidogenic nuclei. In the presence of Cu²⁺, fibril nucleation was significantly delayed, probably due to influences of copper on the oligomeric ensemble of soluble Sup35p-NM, since Cu²⁺ altered the tertiary structure of soluble Sup35p-NM, while no influences on fibril elongation could be detected. The secondary structure of soluble or fibrous protein and the morphology of the fibrils were apparently not altered when assembled in presence of Cu²⁺. In contrast, Mn²⁺ and Zn²⁺ did not bind to Sup35p-NM and did not exhibit significant effects on the formation of NM amyloid fibrils.     

Structural biology of ex vivo mammalian prions

The structures of prion protein (PrP)–based mammalian prions have long been elusive. However, cryo-EM has begun to reveal the near-atomic resolution structures of fully infectious ex vivo mammalian prion fibrils as well as relatively innocuous synthetic PrP amyloids. Comparisons of these various types of PrP fibrils are now providing initial clues to structural features that correlate with pathogenicity. As first indicated by electron paramagnetic resonance and solid-state NMR studies of synthetic amyloids, all sufficiently resolved PrP fibrils of any sort (n > 10) have parallel in-register intermolecular β-stack architectures. Cryo-EM has shown that infectious brain-derived prion fibrils of the rodent-adapted 263K and RML scrapie strains have much larger ordered cores than the synthetic fibrils. These bona fide prion strains share major structural motifs, but the conformational details and the overall shape of the fibril cross sections differ markedly. Such motif variations, as well as differences in sequence within the ordered polypeptide cores, likely contribute to strain-dependent templating. When present, N-linked glycans and glycophosphatidylinositol (GPI) anchors project outward from the fibril surface. For the mouse RML strain, these posttranslational modifications have little effect on the core structure. In the GPI-anchored prion structures, a linear array of GPI anchors along the twisting fibril axis appears likely to bind membranes in vivo, and as such, may account for pathognomonic membrane distortions seen in prion diseases. In this review, we focus on these infectious prion structures and their implications regarding prion replication mechanisms, strains, transmission barriers, and molecular pathogenesis.     

Impact of N-glycosylation site variants during human PrP aggregation and fibril nucleation

Misfolding and aggregation of the human prion protein (PrP) cause neurodegenerative transmissible spongiform encephalopathies such as Creutzfeldt-Jakob disease. Mature native PrP is composed of 209 residues and is folded into a C-terminal globular domain (residues 125–209) comprising a small two-stranded β-sheet and three α-helices. The N-terminal domain (residues 23–124) is intrinsically disordered. Expression of truncated PrP (residues 90–231) is sufficient to cause prion disease and residues 90/100–231 is comprising the amyloid-like fibril core of misfolded infectious PrP. During PrP fibril formation under native conditions in vitro, the disordered N-terminal domain slows down fibril formation likely due to a mechanism of initial aggregation forming morphologically disordered aggregates. The morphological disordered aggregate is a transient phase. Nucleation of fibrils occurs from this initial aggregate. The aggregate phase is largely circumvented by seeding with preformed PrP fibrils. In vivo PrP is N-glycosylated at positions Asn181 and Asn197. Little is known about the importance of these positions and their glycans for PrP stability, aggregation and fibril formation. We have in this study taken a step towards that goal by mutating residues 181 and 197 for cysteines to study the positional impact on these processes. We have further by organic synthetic chemistry and chemical modification generated synthetic glycosylations in these positions. Our data shows that residue 181 when mutated to a cysteine is a key residue for self-chaperoning, rendering a trap in the initial aggregate preventing conformational changes towards amyloid fibril formation. Position 197 is less involved in the aggregate trapping and is more geared towards β-sheet structure conversion within amyloid fibrils. As expected, synthetic glycosylated 197 is less affected towards fibril formation compared to glycosylated 181. Our data are rather compatible with the parallel in-register intermolecular β-sheet model structure of the PrP90–231 fibril and sheds light on the misfolding transitions of PrP in vitro. We hypothesize that glycosylation of position 181 is a key site for prion strain differentiation in vivo.     

Formation of amyloid fibrils from β-amylase

Fibril formation has been considered a significant feature of amyloid proteins. However, it has been proposed that fibril formation is a common property of many proteins under appropriate conditions. We studied the fibril formation of β-amylase, a non-amyloid protein rich in α-helical structure, because the secondary structure of β-amylase is similar to that of prions. With the conditions for the fibril formation of prions, β-amylase proteins were converted into amyloid fibrils. The features of β-amylase proteins and fibrils are compared to prion proteins and fibrils. Furthermore, the cause of neurotoxicity in amyloid diseases is discussed.