Pathway complexity of prion protein assembly into amyloid

In vivo under pathological conditions, the normal cellular form of the prion protein, PrP(C) (residues 23-231), misfolds to the pathogenic isoform PrP(Sc), a beta-rich aggregated pathogenic multimer. Proteinase K digestion of PrP(Sc) leads to a proteolytically resistant core, PrP 27-30 (residues 90-231), that can form amyloid fibrils. To study the kinetic pathways of amyloid formation in vitro, we used unglycosylated recombinant PrP corresponding to the proteinase K-resistant core of PrP(Sc) and found that it can adopt two non-native abnormal isoforms, a beta-oligomer and an amyloid fibril. Several lines of kinetic data suggest that the beta-oligomer is not on the pathway to amyloid formation. The preferences for forming either a beta-oligomer or amyloid can be dictated by experimental conditions, with acidic pH similar to that seen in endocytic vesicles favoring the beta-oligomer and neutral pH favoring amyloid. Although both abnormal isoforms have high beta-sheet content and bind 1-anilinonaphthalene-8-sulfonate, they are dissimilar structurally. Multiple pathways of misfolding and the formation of distinct beta-sheet-rich abnormal isoforms may explain the difficulties in refolding PrP(Sc) in vitro, the need for a PrP(Sc) template, and the significant variation in disease presentation and neuropathology.     

Extremely rapid folding of the C-terminal domain of the prion protein without kinetic intermediates.

The kinetics of folding of mPrP(121-231), the structured 111-residue domain of the murine cellular prion protein PrP(C), were investigated by stopped-flow fluorescence using the variant F175W, which has the same overall structure and stability as wild-type mPrP(121-231) but shows a strong fluorescence change upon unfolding. At 22 degrees C and pH 7.0, folding of mPrP(121-231)-F175W is too fast to be observable by stopped-flow techniques. Folding at 4 degrees C occurs with a deduced half-life of approximately 170 micros without detectable intermediates, possibly the fastest protein-folding reaction known so far. Thus, propagation of the abnormal, oligomeric prion protein PrP(Sc), which is supposed to be the causative agent of transmissible spongiform encephalopathies, is unlikely to follow a mechanism where kinetic folding intermediates of PrP(C) are a source of PrP(Sc) subunits.     

Assembly of natural and recombinant prion protein into fibrils

The conversion of the alpha-helical, cellular isoform of the prion protein (PrP C ) to the insoluble, beta-sheet-rich, infectious, disease-causing isoform (PrP Sc ) is the fundamental event in the prion diseases. The C-terminal fragment of PrP Sc (PrP 27-30) is formed by limited proteolysis and retains infectivity. Unlike full-length PrP Sc , PrP 27-30 polymerizes into rod-shaped structures with the ultra-structural and tinctorial properties of amyloid. To study the folding of PrP, both with respect to the formation of PrP Sc from PrP C and the assembly of rods from PrP 27-30, we solubilized Syrian hamster (sol SHa) PrP 27-30 in low concentrations (0.2%) of sodium dodecyl sulfate (SDS) under conditions previously used to study the structural transitions of this protein. Sol SHaPrP 27-30 adopted a beta-sheet-rich structure at SDS concentrations between 0.02% and 0.04% and remained soluble. Here we report that NaCl stabilizes SHaPrP 27-30 in a soluble, beta-sheet-rich state that allows fibril assembly to proceed over several weeks. Under these conditions, fibril formation occurred not only with sol PrP 27-30, but also with native SHaPrP C . Addition of sphingolipids seems to increase fibril growth. When recombinant (rec) SHaPrP(90-231) was exposed to low concentrations of SDS, similar to those used to polymerize sol SHaPrP 27-30 in the presence of 250 mM NaCl, fibril formation occurred regularly. When fibrils formed from PrP 27-30 or PrP C were bioassayed in transgenic mice overexpressing full-length SHaPrP, no infectivity was obtained, whereas amyloid fibrils formed of rec mouse PrP(89-230) were infectious. At present, it cannot be determined whether the lack of infectivity is caused by a difference in the structure of the fibrils or in the bioassay conditions.     

Electron paramagnetic resonance evidence for binding of Cu(2+) to the C-terminal domain of the murine prion protein.

Transmissible spongiform encephalopathies in mammals are believed to be caused by scrapie form of prion protein (PrP(Sc)), an abnormal, oligomeric isoform of the monomeric cellular prion protein (PrP(C)). One of the proposed functions of PrP(C) in vivo is a Cu(II) binding activity. Previous studies revealed that Cu(2+) binds to the unstructured N-terminal PrP(C) segment (residues 23-120) through conserved histidine residues. Here we analyzed the Cu(II) binding properties of full-length murine PrP(C) (mPrP), of its isolated C-terminal domain mPrP(121-231) and of the N-terminal fragment mPrP(58-91) in the range of pH 3-8 with electron paramagnetic resonance spectroscopy. We find that the C-terminal domain, both in its isolated form and in the context of the full-length protein, is capable of interacting with Cu(2+). Three Cu(II) coordination types are observed for the C-terminal domain. The N-terminal segment mPrP(58-91) binds Cu(2+) only at pH values above 5.0, whereas both mPrP(121-231) and mPrP(23-231) already show identical Cu(II) coordination in the pH range 3-5. As the Cu(2+)-binding N-terminal segment 58-91 is not required for prion propagation, our results open the possibility that Cu(2+) ions bound to the C-terminal domain are involved in the replication of prions, and provide the basis for further analytical studies on the specificity of Cu(II) binding by PrP.     

Folding intermediates of the prion protein stabilized by hydrostatic pressure and low temperature

Prion diseases are associated with conformational conversion of the cellular prion protein, PrPC, into a misfolded form, PrPSc. We have investigated the equilibrium unfolding of the structured domain of recombinant murine prion protein, comprising residues 121-231 (mPrP-(121-231)). The equilibrium unfolding of mPrP-(121-231) by urea monitored by intrinsic fluorescence and circular dichroism (CD) spectroscopies indicated a two-state transition, without detectable folding intermediates. The fluorescent probe 4,4'-dianilino-1,1'-binaphthyl-5,5-disulfonic acid (bis-ANS) binds to native mPrP-(121-231), indicating exposure of hydrophobic domains on the protein surface. Increasing concentrations of urea (up to 4 M) caused the release of bound bis-ANS, whereas changes in intrinsic fluorescence and CD of mPrP took place only above 4 M urea. This indicates the existence of a partially unfolded conformation of mPrP, characterized by loss of bis-ANS binding and preservation of the overall structure of the protein, stabilized at low concentrations of urea. Hydrostatic pressure and low temperatures were also used to stabilize partially folded intermediates that are not detectable in the presence of chemical denaturants. Compression of mPrP to 3.5 kbar at 25 degrees C and pH 7 caused a slight decrease in intrinsic fluorescence emission and an 8-fold increase in bis-ANS fluorescence. Lowering the temperature to -9 degrees C under pressure reversed the decrease in intrinsic fluorescence and caused a marked (approximately 40-fold) increase in bis-ANS fluorescence. The increase in bis-ANS fluorescence at low temperatures was similar to that observed for mPrP at 1 atm at pH 4. These results suggest that pressure-assisted cold denaturation of mPrP stabilizes a partially folded intermediate that is qualitatively similar to the state obtained at acidic pH. Compression of mPrP in the presence of a subdenaturing concentration of urea stabilized another partially folded intermediate, and cold denaturation under these conditions led to complete unfolding of the protein. Possible implications of the existence of such partially folded intermediates in the folding of the prion protein and in the conversion to the PrPSc conformer are discussed.     

In vitro conversion of full-length mammalian prion protein produces amyloid form with physical properties of PrP(Sc)

The "protein only" hypothesis postulates that the infectious agent of prion diseases, PrP(Sc), is composed of the prion protein (PrP) converted into an amyloid-specific conformation. However, cell-free conversion of the full-length PrP into the amyloid conformation has not been achieved. In an effort to understand the mechanism of PrP(Sc) formation, we developed a cell-free conversion system using recombinant mouse full-length PrP with an intact disulfide bond (rPrP). We demonstrate that rPrP will convert into the beta-sheet-rich oligomeric form at highly acidic pH (<5.5) and at high concentrations, while at slightly acidic or neutral pH (>5.5) it assembles into the amyloid form. As judged from electron microscopy, the amyloid form had a ribbon-like assembly composed of two non-twisted filaments. In contrast to the formation of the beta-oligomer, the conversion to the amyloid occurred at concentrations close to physiological and displayed key features of an autocatalytic process. Moreover, using a shortened rPrP consisting of 106 residues (rPrP 106, deletions: Delta23-88 and Delta141-176), we showed that the in vitro conversion mimicked a transmission barrier observed in vivo. Furthermore, the amyloid form displayed a remarkable resistance to proteinase K (PK) and produced a PK-resistant core identical with that of PrP(Sc). Fourier transform infrared spectroscopy analyses showed that the beta-sheet-rich core of the amyloid form remained intact upon PK-digestion and accounted for the extremely high thermal stability. Electron and real-time fluorescent microscopy revealed that proteolytic digestion induces either aggregation of the amyloid ribbons into large clumps or further assembly into fibrils composed of several ribbons. Fibrils composed of ribbons were very fragile and had a tendency to fragment into short pieces. Remarkably, the amyloid form treated with PK preserved high seeding activity. Our work supports the protein only hypothesis of prion propagation and demonstrates that formation of the amyloid form that recapitulates key physical properties of PrP(Sc) can be achieved in vitro in the absence of cellular factors or a PrP(Sc) template.     

Assembly of the full-length recombinant mouse prion protein I. Formation of soluble oligomers

The conversion of a monomeric alpha-helix-rich isoform to multimeric beta-sheet-rich isoforms is a prominent feature of the conversion between PrP(C) and PrP(SC). We mimicked this process in vitro by exposing an unglycosylated recombinant form of the full-length mouse prion protein ((Mo)PrP(23-231)) to an acidic pH, at 37 degrees C, and we monitored the kinetics of conformational change and assembly. In these conditions, monomeric (Mo)PrP(23-231) converts slowly to two ensembles of soluble oligomers that are separated by size exclusion chromatography. The larger oligomers (I) are unstable, and their formation involves almost no change in secondary structure content. The smaller oligomers (II) form stable spherical or annular particles containing between 8 and 15 monomers as determined by multi-angle laser light scattering (MALLS). Their formation is concomitant with the main, thought limited, change in the secondary structure content (10%) seen by Fourier Transform Infrared (FTIR) spectroscopy. Even if these oligomers conserve a large part of the secondary structure of monomeric PrP, they exhibit amyloid features with the appearance of intermolecular beta-structure as revealed by the appearance of an IR band below 1620 cm(-1).     

DNA converts cellular prion protein into the beta-sheet conformation and inhibits prion peptide aggregation

The main hypothesis for prion diseases proposes that the cellular protein (PrP(C)) can be altered into a misfolded, beta-sheet-rich isoform (PrP(Sc)), which in most cases undergoes aggregation. In an organism infected with PrP(Sc), PrP(C) is converted into the beta-sheet form, generating more PrP(Sc). We find that sequence-specific DNA binding to recombinant murine prion protein (mPrP-(23-231)) converts it from an alpha-helical conformation (cellular isoform) into a soluble, beta-sheet isoform similar to that found in the fibrillar state. The recombinant murine prion protein and prion domains bind with high affinity to DNA sequences. Several double-stranded DNA sequences in molar excess above 2:1 (pH 4.0) or 0.5:1 (pH 5.0) completely inhibit aggregation of prion peptides, as measured by light scattering, fluorescence, and circular dichroism spectroscopy. However, at a high concentration, fibers (or peptide aggregates) can rescue the peptide bound to the DNA, converting it to the aggregating form. Our results indicate that a macromolecular complex of prion-DNA may act as an intermediate for the formation of the growing fiber. We propose that host nucleic acid may modulate the delicate balance between the cellular and the misfolded conformations by reducing the protein mobility and by making the protein-protein interactions more likely. In our model, the infectious material would act as a seed to rescue the protein bound to nucleic acid. Accordingly, DNA would act on the one hand as a guardian of the Sc conformation, preventing its propagation, but on the other hand may catalyze Sc conversion and aggregation if a threshold level is exceeded.     

Methionine oxidation interferes with conversion of the prion protein into the fibrillar proteinase K-resistant conformation

In recent studies, we developed a protocol for in vitro conversion of full-length mouse recombinant PrP (Mo rPrP23-230) into amyloid fibrils [Bocharova et al. (2005) J. Mol. Biol. 346, 645-659]. Because amyloid fibrils produced from recombinant Mo PrP89-230 display infectivity [Legname et al. (2004) Science 305, 673-676], polymerizatiom of rPrPs in vitro represents a valuable model for elucidating the mechanism of prion conversion. Unexpectedly, when the same conversion protocol was used for hamster (Ha) rPrP23-231, we experienced substantial difficulties in forming fibrils. While searching for potential reasons of our failure to produce fibrils, we probed the effect of methionine oxidation in rPrP. We found that oxidation of methionines interferes with the formation of rPrP fibrils and that this effect is more profound for Ha than for Mo rPrP. To minimize the level of spontaneous oxidation, we developed a new protocol for rPrP purification, in which highly amyloidogenic Ha rPrP with minimal levels of oxidized residues was produced. Furthermore, our studies revealed that oxidation of methionines in preformed fibrils inhibited subsequent maturation of fibrils into proteinase K-resistant PrP(Sc)-like conformation (PrP-res). Our data are consistent with the proposition that conformational changes within the central region of the protein (residues 90-140) are essential for adopting PrP-res conformation and demonstrate that methionine oxidation interferes with this process. These studies provide new insight into the mechanism of prion polymerization, solve a long-standing practical problem in producing PrP-res fibrils from full-length PrP, and may help in identifying new genetic and environmental factors that modulate prion disease.     

Self-assembly of recombinant prion protein of 106 residues

The central event in the pathogenesis of prion diseases is a profound conformational change of the prion protein (PrP) from an alpha-helical (PrP(C)) to a beta-sheet-rich isoform (PrP(Sc)). The elucidation of the mechanism of conformational transition has been complicated by the challenge of collecting high-resolution biophysical data on the relatively insoluble aggregation-prone PrP(Sc) isoform. In an attempt to facilitate the structural analysis of PrP(Sc), a redacted chimeric mouse-hamster PrP of 106 amino acids (MHM2 PrP106) with two deletions (Delta23-88 and Delta141-176) was expressed and purified from Escherichia coli. PrP106 retains the ability to support PrP(Sc) formation in transgenic mice, implying that it contains all regions of PrP that are necessary for the conformational transition into the pathogenic isoform [Supattapone, S., et al. (1999) Cell 96, 869-878]. Unstructured at low concentrations, recombinant unglycosylated PrP106 (rPrP106) undergoes a concentration-dependent conformational transition to a beta-sheet-rich form. Following the conformational transition, rPrP106 possesses properties similar to those of PrP(Sc)106, such as high beta-sheet content, defined tertiary structure, resistance to limited digestion by proteinase K, and high thermodynamic stability. In GdnHCl-induced denaturation studies, a single cooperative conformational transition between the unstructured monomer and the assembled beta-oligomer was observed. After proteinase K digestion, the oligomers retain an intact core with unusually high beta-sheet content (>80%). Using mass spectrometry, we discovered that the region of residues 134-215 of rPrP106 is protected from proteinase K digestion and possesses a solvent-independent propensity to adopt a beta-sheet-rich conformation. In contrast to the PrP(Sc)106 purified from the brains of neurologically impaired animals, multimeric beta-rPrP106 remains soluble, providing opportunities for detailed structural studies.     

Aggregation and fibrillization of the recombinant human prion protein huPrP90-231

According to the "protein-only" hypothesis, the critical step in the pathogenesis of prion diseases is the conformational transition between the normal (PrP(C)) and pathological (PrP(Sc)) isoforms of prion protein. To gain insight into the mechanism of this transition, we have characterized the biophysical properties of the recombinant protein corresponding to residues 90-231 of the human prion protein (huPrP90-231). Incubation of the protein under acidic conditions (pH 3.6-5) in the presence of 1 M guanidine-HCl resulted in a time-dependent transition from an alpha-helical conformation to a beta-sheet structure and oligomerization of huPrP90-231 into large molecular weight aggregates. No stable monomeric beta-sheet-rich folding intermediate of the protein could be detected in the present experiments. Kinetic analysis of the data indicates that the formation of beta-sheet structure and protein oligomerization likely occur concomitantly. The beta-sheet-rich oligomers were characterized by a markedly increased resistance to proteinase K digestion and a fibrillar morphology (i.e., they had the essential physicochemical properties of PrP(Sc)). Contrary to previous suggestions, the conversion of the recombinant prion protein into a PrP(Sc)-like form could be accomplished under nonreducing conditions, without the need to disrupt the disulfide bond. Experiments in urea indicate that, in addition to acidic pH, another critical factor controlling the transition of huPrP90-231 to an oligomeric beta-sheet structure is the presence of salt.     

Dominant-negative inhibition of prion formation diminished by deletion mutagenesis of the prion protein

Polymorphic basic residues near the C terminus of the prion protein (PrP) in humans and sheep appear to protect against prion disease. In heterozygotes, inhibition of prion formation appears to be dominant negative and has been simulated in cultured cells persistently infected with scrapie prions. The results of nuclear magnetic resonance and mutagenesis studies indicate that specific substitutions at the C-terminal residues 167, 171, 214, and 218 of PrP(C) act as dominant-negative, inhibitors of PrP(Sc) formation (K. Kaneko et al., Proc. Natl. Acad. Sci. USA 94:10069-10074, 1997). Trafficking of substituted PrP(C) to caveaola-like domains or rafts by the glycolipid anchor was required for the dominant-negative phenotype; interestingly, amino acid replacements at multiple sites were less effective than single-residue substitutions. To elucidate which domains of PrP(C) are responsible for dominant-negative inhibition of PrP(Sc) formation, we analyzed whether N-terminally truncated PrP(Q218K) molecules exhibited dominant-negative effects in the conversion of full-length PrP(C) to PrP(Sc). We found that the C-terminal domain of PrP is not sufficient to impede the conversion of the full-length PrP(C) molecule and that N-terminally truncated molecules (with residues 23 to 88 and 23 to 120 deleted) have reduced dominant-negative activity. Whether the N-terminal region of PrP acts by stabilizing the C-terminal domain of the molecule or by modulating the binding of PrP(C) to an auxiliary molecule that participates in PrP(Sc) formation remains to be established.     

NMR characterization of the pH 4 beta-intermediate of the prion protein: the N-terminal half of the protein remains unstructured and retains a high degree of flexibility

Prion diseases are associated with the misfolding of the PrP (prion protein) from a largely alpha-helical isoform to a beta-sheet-rich oligomer. CD has shown that lowering the pH to 4 under mildly denaturing conditions causes recombinant PrP to convert from an alpha-helical protein into one that contains a high proportion of beta-sheet-like conformation. In the present study, we characterize this soluble pH 4 folding intermediate using NMR. (15)N-HSQC (heteronuclear single-quantum correlation) studies with mPrP (mouse PrP)-(23-231) show that a total of 150 dispersed amide signals are resolved in the native form, whereas only 65 amide signals with little chemical shift dispersion are observable in the pH 4 form. Three-dimensional (15)N-HSQC-TOCSY and NOESY spectra indicate that the observable residues are all assigned to amino acids in the N-terminus: residues 23-118. (15)N transverse relaxation measurements indicate that these N-terminal residues are highly flexible with additional fast motions. These observations are confirmed via the use of truncated mPrP-(112-231), which shows only 16 (15)N-HSQC amide peaks at pH 4. The loss of signals from the C-terminus can be attributed to line broadening due to an increase in the molecular size of the oligomer or exchange broadening in a molten-globule state.     

Tetracycline affects abnormal properties of synthetic PrP peptides and PrP(Sc) in vitro

Prion diseases are characterized by the accumulation of altered forms of the prion protein (termed PrP(Sc)) in the brain. Unlike the normal protein, PrP(Sc) isoforms have a high content of beta-sheet secondary structure, are protease-resistant, and form insoluble aggregates and amyloid fibrils. Evidence indicates that they are responsible for neuropathological changes (i.e. nerve cell degeneration and glial cell activation) and transmissibility of the disease process. Here, we show that the antibiotic tetracycline: (i) binds to amyloid fibrils generated by synthetic peptides corresponding to residues 106-126 and 82-146 of human PrP; (ii) hinders assembly of these peptides into amyloid fibrils; (iii) reverts the protease resistance of PrP peptide aggregates and PrP(Sc) extracted from brain tissue of patients with Creutzfeldt-Jakob disease; (iv) prevents neuronal death and astrocyte proliferation induced by PrP peptides in vitro. NMR spectroscopy revealed several through-space interactions between aromatic protons of tetracycline and side-chain protons of Ala(117-119), Val(121-122) and Leu(125) of PrP 106-126. These properties make tetracycline a prototype of compounds with the potential of inactivating the pathogenic forms of PrP.     

Chaperonin-mediated de novo generation of prion protein aggregates.

The infectious prion protein, PrP(Sc), a predominantly beta-sheet aggregate, is derived from PrP(C), the largely alpha-helical cellular isoform of PrP. Conformational conversion of PrP(C) into PrP(Sc) has been suggested to involve a chaperone-like factor. Here we report that the bacterial chaperonin GroEL, a close homolog of eukaryotic Hsp60, can catalyze the aggregation of chemically denatured and of folded, recombinant PrP in a model reaction in vitro. Aggregates form upon ATP-dependent release of PrP from chaperonin and have certain properties of PrP(Sc), including a high beta-sheet content, the ability to bind the dye Congo red, detergent-insolubility and increased protease-resistance. A conserved sequence segment of PrP (residues 90-121), critical for PrP(Sc) generation in vivo, is also required for chaperonin-mediated aggregate formation in vitro. Initial binding of refolded, alpha-helical PrP to chaperonin is mediated by the unstructured N-terminal segment of PrP (residues 23-121) and is followed by a rearrangement of the globular PrP core-domain. These results show that chaperonins of the Hsp60 class can, in principle, mediate PrP aggregation de novo, i.e. independently of a pre-existent PrP(Sc) template.     

The polybasic N-terminal region of the prion protein controls the physical properties of both the cellular and fibrillar forms of PrP

Individual variations in structure and morphology of amyloid fibrils produced from a single polypeptide are likely to underlie the molecular origin of prion strains and control the efficiency of the species barrier in the transmission of prions. Previously, we observed that the shape of amyloid fibrils produced from full-length prion protein (PrP 23-231) varied substantially for different batches of purified recombinant PrP. Variations in fibril morphology were also observed for different fractions that corresponded to the highly pure PrP peak collected at the last step of purification. A series of biochemical experiments revealed that the variation in fibril morphology was attributable to the presence of miniscule amounts of N-terminally truncated PrPs, where a PrP encompassing residue 31-231 was the most abundant of the truncated polypeptides. Subsequent experiments showed that the presence of small amounts of recombinant PrP 31-231 (0.1-1%) in mixtures with full-length PrP 23-231 had a dramatic impact on fibril morphology and conformation. Furthermore, the deletion of the short polybasic N-terminal region 23-30 was found to reduce the folding efficiency to the native α-helical forms and the conformational stability of α-PrP. These findings are very surprising considering that residues 23-30 are very distant from the C-terminal globular folded domain in α-PrP and from the prion folding domain in the fibrillar form. However, our studies suggest that the N-terminal polybasic region 23-30 is essential for effective folding of PrP to its native cellular conformation. This work also suggests that this region could regulate diversity of prion strains or subtypes despite its remote location from the prion folding domain.     

Elongated oligomers assemble into mammalian PrP amyloid fibrils

In prion diseases, the mammalian prion protein PrP is converted from a monomeric, mainly alpha-helical state into beta-rich amyloid fibrils. To examine the structure of the misfolded state, amyloid fibrils were grown from a beta form of recombinant mouse PrP (residues 91-231). The beta-PrP precursors assembled slowly into amyloid fibrils with an overall helical twist. The fibrils exhibit immunological reactivity similar to that of ex vivo PrP Sc. Using electron microscopy and image processing, we obtained three-dimensional density maps of two forms of PrP fibrils with slightly different twists. They reveal two intertwined protofilaments with a subunit repeat of approximately 60 A. The repeating unit along each protofilament can be accounted for by elongated oligomers of PrP, suggesting a hierarchical assembly mechanism for the fibrils. The structure reveals flexible crossbridges between the two protofilaments, and subunit contacts along the protofilaments that are likely to reflect specific features of the PrP sequence, in addition to the generic, cross-beta amyloid fold.     

Polythiophenes inhibit prion propagation by stabilizing prion protein (PrP) aggregates

Luminescent conjugated polymers (LCPs) interact with ordered protein aggregates and sensitively detect amyloids of many different proteins, suggesting that they may possess antiprion properties. Here, we show that a variety of anionic, cationic, and zwitterionic LCPs reduced the infectivity of prion-containing brain homogenates and of prion-infected cerebellar organotypic cultured slices and decreased the amount of scrapie isoform of PrP(C) (PrP(Sc)) oligomers that could be captured in an avidity assay. Paradoxically, treatment enhanced the resistance of PrP(Sc) to proteolysis, triggered the compaction, and enhanced the resistance to proteolysis of recombinant mouse PrP(23-231) fibers. These results suggest that LCPs act as antiprion agents by transitioning PrP aggregates into structures with reduced frangibility. Moreover, ELISA on cerebellar organotypic cultured slices and in vitro conversion assays with mouse PrP(23-231) indicated that poly(thiophene-3-acetic acid) may additionally interfere with the generation of PrP(Sc) by stabilizing the conformation of PrP(C) or of a transition intermediate. Therefore, LCPs represent a novel class of antiprion agents whose mode of action appears to rely on hyperstabilization, rather than destabilization, of PrP(Sc) deposits.     

Preventing misfolding of the prion protein by trimethylamine N-oxide

Transmissible spongiform encephalopathies are a class of fatal neurodegenerative diseases linked to the prion protein. The prion protein normally exists in a soluble, globular state (PrP(C)) that appears to participate in copper metabolism in the central nervous system and/or signal transduction. Infection or disease occurs when an alternatively folded form of the prion protein (PrP(Sc)) converts soluble and predominantly alpha-helical PrP(C) into aggregates rich in beta-structure. The structurally disordered N-terminus adopts beta-structure upon conversion to PrP(Sc) at low pH. Chemical chaperones, such as trimethylamine N-oxide (TMAO), can prevent formation of PrP(Sc) in scrapie-infected mouse neuroblastoma cells [Tatzelt, J., et al. (1996) EMBO J. 15, 6363-6373]. To explore the mechanism of TMAO protection of PrP(C) at the atomic level, molecular dynamics simulations were performed under conditions normally leading to conversion (low pH) with and without 1 M TMAO. In PrP(C) simulations at low pH, the helix content drops and the N-terminus is brought into the small native beta-sheet, yielding a PrP(Sc)-like state. Addition of 1 M TMAO leads to a decreased radius of gyration, a greater number of protein-protein hydrogen bonds, and a greater number of tertiary contacts due to the N-terminus forming an Omega-loop and packing against the structured core of the protein, not due to an increase in the level of extended structure as with the PrP(C) to PrP(Sc) simulation. In simulations beginning with the "PrP(Sc)-like" structure (derived from PrP(C) simulated at low pH in pure water) in 1 M TMAO, similar structural reorganization at the N-terminus occurred, disrupting the extended sheet. The mechanism of protection by TMAO appears to be exclusionary in nature, consistent with previous theoretical and experimental studies. The TMAO-induced N-terminal conformational change prevents residues that are important in the conversion of PrP(C) to PrP(Sc) from assuming extended sheet structure at low pH.     

Dual nature of the infectious prion protein revealed by high pressure

Crude brain homogenates of terminally diseased hamsters infected with the 263K strain of scrapie (PrP(Sc)) and purified prion fibrils were heated or pressurized at 800 megapascals and 60 degrees C for 2 h in different buffers and in water. Prion proteins (PrP) were analyzed for their proteinase K resistance in immunoblots and for their infectivity in hamster bioassays. A notable decrease in the proteinase K resistance of unpurified prion proteins, probably because of pressure-induced changes in the protein conformation of native PrP(Sc) or the N-truncated PrP-(27-30), could be demonstrated when pressurized at initially neutral conditions in several buffers and in water but not in a slightly acidic pH. A subsequent 6-7 log(10) reduction of infectious units/g in phosphate-buffered saline buffer, pH 7.4, was found. The proteinase K-resistant core was also not detectable after purification of prions extracted from pressurized samples, confirming pressure effects at the level of the secondary structure of prion proteins. However, opposite results were found after pressurizing purified prions, arguing for the existence of pressure-sensitive beta-structures (PrP(Sc)(DeltaPsen)) and extremely pressure-resistant beta-structures (PrP(Sc)(DeltaPres)). Remarkably, after the first centrifugation step at 540,000 x g during isolation, prions remained proteinase K-resistant when pressurized in all tested buffers and in water. It is known that purified fibrils retain infectivity, but the isolated protein (full and N-truncated) behaved differently from native PrP(Sc) under pressure, suggesting a kind of semicrystalline polymer structure.