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.     

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.     

Molecular interactions between prions as seeds and recombinant prion proteins as substrates resemble the biological interspecies barrier in vitro

Prion diseases like Creutzfeldt-Jakob disease in humans, Scrapie in sheep or bovine spongiform encephalopathy are fatal neurodegenerative diseases, which can be of sporadic, genetic, or infectious origin. Prion diseases are transmissible between different species, however, with a variable species barrier. The key event of prion amplification is the conversion of the cellular isoform of the prion protein (PrP(C)) into the pathogenic isoform (PrP(Sc)). We developed a sodiumdodecylsulfate-based PrP conversion system that induces amyloid fibril formation from soluble α-helical structured recombinant PrP (recPrP). This approach was extended applying pre-purified PrP(Sc) as seeds which accelerate fibrillization of recPrP. In the present study we investigated the interspecies coherence of prion disease. Therefore we used PrP(Sc) from different species like Syrian hamster, cattle, mouse and sheep and seeded fibrillization of recPrP from the same or other species to mimic in vitro the natural species barrier. We could show that the in vitro system of seeded fibrillization is in accordance with what is known from the naturally occurring species barriers.     

Locally disordered conformer of the hamster prion protein: a crucial intermediate to PrPSc?

A crucial step for transformation of the normal cellular isoform of the prion protein (PrP(C)) to the infectious prion protein (PrP(Sc)) is thought to entail a previously uncharacterized intermediate conformer, PrP*, which interacts with a template PrP(Sc) molecule in the conversion process. By carrying out (15)N-(1)H two-dimensional NMR measurements under variable pressure on Syrian hamster prion protein rPrP(90-231), we found a metastable conformer of PrP(C) coexisting at a population of approximately 1% at pH 5.2 and 30 degrees C, in which helices B and C are preferentially disordered. While the identity is still unproven, this observed metastable conformer is most logically PrP* or a closely related precursor. The structural characteristics of this metastable conformer are consistent with available immunological and pathological information about the prion protein.     

In vitro conversion of mammalian prion protein into amyloid fibrils displays unusual features

The "protein only" hypothesis of prion propagation postulates that the abnormal isoform of the prion protein, PrP(Sc), acts as a causative and transmissible agent of prion disease. In attempt to reconstitute prion infectivity in vitro, we previously developed a cell-free conversion protocol for generating amyloid fibrils from a recombinant prion protein encompassing residues 89-231 (rPrP 89-230) [Baskakov et al. (2002) J. Biol. Chem. 277, 21140]. When inoculated into transgenic mice, these amyloid fibrils induced prion disease, which can be efficiently transmitted to both wild-type and transgenic mice [Legname et al. (2004) Science 305, 673]. Here we show that the polymerization of rPrPs into the fibrils displays a number of distinctive kinetic features that are not typical for polymerization by other amyloidogenic polypeptides. Specifically, the lag phase of polymerization showed only modest dependence on protein concentration, and the conversion reaction displayed a dramatic volume-dependent threshold effect. To explain these unique kinetic features, we proposed that the conversion reaction is regulated by the dynamics between the rates of multiplication and deactivation of self-propagating fibrillar isoforms. Our further studies demonstrated that surface-dependent sorption of fibrillar isoforms is responsible for their deactivation in vitro, while fibril fragmentation seems to account for the multiplication of the active centers of polymerization. Our findings support the hypothesis that development of prion disease is controlled by a fine dynamic balance between self-propagation and clearance/deactivation of PrP(Sc).     

Systematic identification of antiprion drugs by high-throughput screening based on scanning for intensely fluorescent targets

Conformational changes and aggregation of specific proteins are hallmarks of a number of diseases, like Alzheimer's disease, Parkinson's disease, and prion diseases. In the case of prion diseases, the prion protein (PrP), a neuronal glycoprotein, undergoes a conformational change from the normal, mainly alpha-helical conformation to a disease-associated, mainly beta-sheeted scrapie isoform (PrP(Sc)), which forms amyloid aggregates. This conversion, which is crucial for disease progression, depends on direct PrP(C)/PrP(Sc) interaction. We developed a high-throughput assay based on scanning for intensely fluorescent targets (SIFT) for the identification of drugs which interfere with this interaction at the molecular level. Screening of a library of 10,000 drug-like compounds yielded 256 primary hits, 80 of which were confirmed by dose response curves with half-maximal inhibitory effects ranging from 0.3 to 60 microM. Among these, six compounds displayed an inhibitory effect on PrP(Sc) propagation in scrapie-infected N2a cells. Four of these candidate drugs share an N'-benzylidene-benzohydrazide core structure. Thus, the combination of high-throughput in vitro assay with the established cell culture system provides a rapid and efficient method to identify new antiprion drugs, which corroborates that interaction of PrP(C) and PrP(Sc) is a crucial molecular step in the propagation of prions. Moreover, SIFT-based screening may facilitate the search for drugs against other diseases linked to protein aggregation.     

Globular and pre-fibrillar prion aggregates are toxic to neuronal cells and perturb their electrophysiology

Prion diseases are characterised at autopsy by neuronal loss and accumulation of amorphous protein aggregates and/or amyloid fibrils in the brains of humans and animals. These protein deposits result from the conversion of the cellular, mainly alpha-helical prion protein (PrP(C)) to the beta-sheet-rich isoform (PrP(Sc)). Although the pathogenic mechanism of prion diseases is not fully understood, it appears that protein aggregation is itself neurotoxic and not the product of cell death. The precise nature of the neurotoxic species and mechanism of cell death are yet to be determined, although recent studies with other amyloidogenic proteins suggest that ordered pre-fibrillar or oligomeric forms may be responsible for cellular dysfunction. In this study we have refolded recombinant prion protein (rPrP) to two distinct forms rich in beta-sheet structure with an intact disulphide bond. Here we report on the structural properties of globular aggregates and pre-fibrils of rPrP and show that both states are toxic to neuronal cells in culture. We show that exogenous rPrP aggregates are internalised by neuronal cells and found in the cytoplasm. We also measured the changes in electrophysiological properties of cultured neuronal cells on exposure to exogenous prion aggregates and discuss the implications of these findings.     

Synthetic prions generated in vitro are similar to a newly identified subpopulation of PrPSc from sporadic Creutzfeldt-Jakob Disease

In recent studies, the amyloid form of recombinant prion protein (PrP) encompassing residues 89-230 (rPrP 89-230) produced in vitro induced transmissible prion disease in mice. These studies showed that unlike "classical" PrP(Sc) produced in vivo, the amyloid fibrils generated in vitro were more proteinase-K sensitive. Here we demonstrate that the amyloid form contains a proteinase K-resistant core composed only of residues 152/153-230 and 162-230. The PK-resistant fragments of the amyloid form are similar to those observed upon PK digestion of a minor subpopulation of PrP(Sc) recently identified in patients with sporadic Creutzfeldt-Jakob disease (CJD). Remarkably, this core is sufficient for self-propagating activity in vitro and preserves a beta-sheet-rich fibrillar structure. Full-length recombinant PrP 23-230, however, generates two subpopulations of amyloid in vitro: One is similar to the minor subpopulation of PrP(Sc), and the other to classical PrP(Sc). Since no cellular factors or templates were used for generation of the amyloid fibrils in vitro, we speculate that formation of the subpopulation of PrP(Sc) with a short PK-resistant C-terminal region reflects an intrinsic property of PrP rather than the influence of cellular environments and/or cofactors. Our work significantly increases our understanding of the biochemical nature of prion infectious agents and provides a fundamental insight into the mechanisms of prions biogenesis.     

Conversion of bacterially expressed recombinant prion protein

The infectivity associated with prion disease sets it apart from a large group of late-onset neurodegenerative disorders that shares the characteristics of protein aggregation and neurodegeneration. The unconventional infectious agent, PrP(Sc), is an aberrantly folded form of the normal prion protein (PrP(C)) and the PrP(C)-to-PrP(Sc) conversion is a critical pathogenic step in prion disease. Using the Protein Misfolding Cyclic Amplification technique, we converted folded bacterially expressed recombinant PrP into a proteinase K-resistant and aggregated conformation (rPrP-res) in the presence of anionic lipid and RNA molecules. Moreover, high prion infectivity was demonstrated by intracerebral inoculation of rPrP-res into wild-type mice, which caused prion disease with a short incubation period. The establishment of the in vitro recombinant PrP conversion assay makes it feasible for us to explore the molecular basis behind the intriguing properties associated with prion infectivity.     

Lactoferrin induces cell surface retention of prion protein and inhibits prion accumulation

Prion diseases are fatal neurodegenerative disorders, and the conformational conversion of normal cellular prion protein (PrP(C)) into its pathogenic, amyloidogenic isoform (PrP(Sc)) is the essential event in the pathogenesis of these diseases. Lactoferrin (LF) is a cationic iron-binding glycoprotein belonging to the transferrin (TF) family, which accumulates in the amyloid deposits in the brain in neurodegenerative disorders, such as Alzheimer's disease and Pick's disease. In the present study, we have examined the effects of LF on PrP(Sc) formation by using cell culture models. Bovine LF inhibited PrP(Sc) accumulation in scrapie-infected cells in a time- and dose-dependent manner, whereas TF was not inhibitory. Bioassays of LF-treated cells demonstrated prolonged incubation periods compared with non-treated cells indicating a reduction of prion infectivity. LF mediated the cell surface retention of PrP(C) by diminishing its internalization and was capable of interacting with PrP(C) in addition to PrP(Sc). Furthermore, LF partially inhibited the formation of protease-resistant PrP as determined by the protein misfolding cyclic amplification assay. Our results suggest that LF has multifunctional antiprion activities.     

Autocatalytic conversion of recombinant prion proteins displays a species barrier

The most unorthodox feature of the prion disease is the existence of an abnormal infectious isoform of the prion protein, PrP(Sc). According to the "protein-only" hypothesis, PrP(Sc) propagates its abnormal conformation in an autocatalytic manner using the normal isoform, PrP(C), as a substrate. Because autocatalytic conversion is considered a key element of prion replication, in this study I tested whether in vitro conversion of recombinant PrP into abnormal isoform displays specific features of an autocatalytic process. I found that recombinant human PrP formed two distinct beta-sheet rich isoforms, the beta-oligomer and the amyloid fibrils. The kinetics of the fibrils formation measured at different pH values were consistent with a model in which the beta-oligomer was not on the kinetic pathway to the fibrillar form. As judged by electron microscopy, an acidic pH favored to the long fibrils, whereas short fibrils morphologically similar to "prion rods" were formed at neutral pH. At neutral pH the conversion to the fibrils can be seeded with small aliquots of preformed fibrils. As small as 0.001% aliquot displayed seeding activity. The conversion of human PrP was seeded with high efficacy only with the preformed fibrils of human but not mouse PrP and vice versa. These studies illustrate that in vitro conversion of recombinant PrP displays specific features of an autocatalytic process and mimics the transmission barrier of prion propagation observed in vivo. I speculate that this model can be used as a rapid assay for assessing the intrinsic propensities of prion transmission between different species.     

Genesis of mammalian prions: from non-infectious amyloid fibrils to a transmissible prion disease

The transmissible agent of prion disease consists of a prion protein in its abnormal, β-sheet rich state (PrP(Sc)), which is capable of replicating itself according to the template-assisted mechanism. This mechanism postulates that the folding pattern of a newly recruited polypeptide chain accurately reproduces that of a PrP(Sc) template. Here we report that authentic PrP(Sc) and transmissible prion disease can be generated de novo in wild type animals by recombinant PrP (rPrP) amyloid fibrils, which are structurally different from PrP(Sc) and lack any detectable PrP(Sc) particles. When induced by rPrP fibrils, a long silent stage that involved two serial passages preceded development of the clinical disease. Once emerged, the prion disease was characterized by unique clinical, neuropathological, and biochemical features. The long silent stage to the disease was accompanied by significant transformation in neuropathological properties and biochemical features of the proteinase K-resistant PrP material (PrPres) before authentic PrP(Sc) evolved. The current work illustrates that transmissible prion diseases can be induced by PrP structures different from that of authentic PrP(Sc) and suggests that a new mechanism different from the classical templating exists. This new mechanism designated as "deformed templating" postulates that a change in the PrP folding pattern from the one present in rPrP fibrils to an alternative specific for PrP(Sc) can occur. The current work provides important new insight into the mechanisms underlying genesis of the transmissible protein states and has numerous implications for understanding the etiology of neurodegenerative diseases.     

Scrapie infectivity is independent of amyloid staining properties of the N-terminally truncated prion protein

The prion protein undergoes a profound conformational change when the cellular isoform (PrP(C)) is converted into the disease-causing form (PrP(Sc)). Limited proteolysis of PrP(Sc) produces PrP 27-30, which readily polymerizes into amyloid. To study the relationship between PrP amyloid and infectivity, we employed organic solvents that perturb protein conformation. Hexafluoro-2-propanol (HFIP), which promotes alpha-helix formation, modified the ultrastructure of PrP amyloid and decreased the beta-sheet content as well as prion infectivity. HFIP reversibly decreased the binding of Congo red dye to the PrP amyloid rods while inactivation of prion infectivity was irreversible. In contrast, 1,1,1-trifluoro-2-propanol (TFIP) did not inactivate prion infectivity but like HFIP, TFIP did alter the morphology of the rods and abolished Congo red binding. Solubilization using various solvents and detergents produced monomeric and dimeric PrP that lacked infectivity. Proteinase K resistance of detergent-treated PrP 27-30 showed no correlation with scrapie infectivity. Our results separate prion infectivity from the amyloid properties of PrP 27-30 and underscore the dependence of prion infectivity on PrP(Sc) conformation. These findings also demonstrate that the specific beta-sheet-rich structures required for prion infectivity can be differentiated from those required for amyloid formation.     

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.     

Conversion efficiency of bank vole prion protein in vitro is determined by residues 155 and 170, but does not correlate with the high susceptibility of bank voles to sheep scrapie in vivo

The misfolded infectious isoform of the prion protein (PrP(Sc)) is thought to replicate in an autocatalytic manner by converting the cellular form (PrP(C)) into its pathogenic folding variant. The similarity in the amino acid sequence of PrP(C) and PrP(Sc) influences the conversion efficiency and is considered as the major determinant for the species barrier. We performed in vitro conversion reactions on wild-type and mutated PrP(C) to determine the role of the primary sequence for the high susceptibility of bank voles to scrapie. Different conversion efficiencies obtained with bank vole and mouse PrP(C) in reactions with several prion strains were due to differences at amino acid residues 155 and 170. However, the conversion efficiencies obtained with mouse and vole PrP(C) in reactions with sheep scrapie did not correlate with the susceptibility of the respective species to this prion strain. This discrepancy between in vitro and in vivo data may indicate that at least in the case of scrapie transmission to bank voles additional host factors can strongly modulate the species barrier. Furthermore, in vitro conversion reactions with different prion strains revealed that the degree of alteration of the conversion efficiency induced by amino acid exchanges was varying according to the prion strain. These results support the assumption that the repertoire of conformations adopted by a certain PrP(C) primary sequence is decisive for its convertibility to the strain-specific PrP(Sc) conformation.     

Copper(II) inhibits in vitro conversion of prion protein into amyloid fibrils

In recent studies, the amyloid fibrils produced in vitro from recombinant prion protein encompassing residues 89-230 (rPrP 89-230) were shown to produce transmissible form of prion disease in transgenic mice (Legname et al., (2004) Science 305, 673-676). Long incubation time observed upon inoculation of the amyloid fibrils, however, suggests that the fibrils generated in vitro have low infectivity titers. These results emphasize the need to define optimal conditions for prion conversion in vitro, under which high levels of infectivity can be generated in a cell-free system. Because copper(II) has been implicated in normal and pathological functions of the prion protein, here we investigated the effect of Cu(2+) on cell-free conversion of recombinant PrP. Our results show that at pH 7.2 and at micromolar concentrations, Cu(2+) inhibited conversion of full-length recombinant PrP (rPrP 23-230) into amyloid fibrils. This effect was most pronounced for Cu(2+), and less so for Zn(2+), while Mn(2+) had no effect on the conversion. Cu(2+)-dependent inhibition of the amyloid formation was less effective at pH 6.0, at which rPrP 23-230 displays lower Cu(2+)-binding capacity. Using rPrP 89-230, we found that Cu(2+)-dependent inhibition occurred even in the absence of octarepeat region; however, it was less effective. Our further studies indicated that Cu(2+) inhibited conversion by stabilizing a nonamyloidogenic PK-resistant form of alpha-rPrP. Remarkably, Cu(2+) also had a profound effect on preformed amyloid fibrils. When added to the fibrils, Cu(2+) induced long-range coiling of individual fibrils and enhanced their PK-resistance. It, however, produced only minor changes in their secondary structures. In addition, Cu(2+) induced further aggregation of the amyloid fibrils into large clumps, presumably, through interfibrillar coordination of copper ions by octarepeats. Taken together, our studies suggest that the role of Cu(2+) in the pathogenesis of prion diseases is complex. Because Cu(2+) may inhibit prion replication, while at the same time stabilize disease-specific isoform against proteolytic clearance, the final outcome of copper-induced effect on progression of prion disease may not be straightforward.     

Experimental approaches to the interaction of the prion protein with nucleic acids and glycosaminoglycans: Modulators of the pathogenic conversion

The concept that transmissible spongiform encephalopathies (TSEs) are caused only by proteins has changed the traditional paradigm that disease transmission is due solely to an agent that carries genetic information. The central hypothesis for prion diseases proposes that the conversion of a cellular prion protein (PrP(C)) into a misfolded, β-sheet-rich isoform (PrP(Sc)) accounts for the development of (TSE). There is substantial evidence that the infectious material consists chiefly of a protein, PrP(Sc), with no genomic coding material, unlike a virus particle, which has both. However, prions seem to have other partners that chaperone their activities in converting the PrP(C) into the disease-causing isoform. Nucleic acids (NAs) and glycosaminoglycans (GAGs) are the most probable accomplices of prion conversion. Here, we review the recent experimental approaches that have been employed to characterize the interaction of prion proteins with nucleic acids and glycosaminoglycans. A PrP recognizes many nucleic acids and GAGs with high affinities, and this seems to be related to a pathophysiological role for this interaction. A PrP binds nucleic acids and GAGs with structural selectivity, and some PrP:NA complexes can become proteinase K-resistant, undergoing amyloid oligomerization and conversion to a β-sheet-rich structure. These results are consistent with the hypothesis that endogenous polyanions (such as NAs and GAGs) may accelerate the rate of prion disease progression by acting as scaffolds or lattices that mediate the interaction between PrP(C) and PrP(Sc) molecules. In addition to a still-possible hypothesis that nucleic acids and GAGs, especially those from the host, may modulate the conversion, the recent structural characterization of the complexes has raised the possibility of developing new diagnostic and therapeutic strategies.     

The role of rafts in the fibrillization and aggregation of prions

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

Modulation of prion protein oligomerization, aggregation, and beta-sheet conversion by 4,4'-dianilino-1,1'-binaphthyl-5,5'-sulfonate (bis-ANS)

The prion protein (PrP) is the major agent implicated in the diseases known as transmissible spongiform encephalopathies. The onset of transmissible spongiform encephalopathy is related to a change in conformation of the PrP(C), which loses most of its alpha-helical content, becoming a beta-sheet-rich protein, known as PrP(Sc). Here we have used two Syrian hamster prion domains (PrP 109-141 and PrP 109-149) and the murine recombinant PrP (rPrP 23-231) to investigate the effects of anilino-naphtalene compounds on prion oligomerization and aggregation. Aggregation in the presence of bis-ANS (4,4'-dianilino-1,1'-binaphthyl-5,5'-sulfonate), ANS (1-anilinonaphthalene-8-sulfonate), and AmNS (1-amino-5-naphtalenesulfonate) was monitored. Bis-ANS was the most effective inhibitor of prion peptide aggregation. Bis-ANS binds strongly to rPrP 23-231 leading to a substantial increase in beta-sheet content and to limited oligomerization. More strikingly, the binding of bis-ANS to full-length rPrP is diminished by the addition of nanomolar concentrations of oligonucleotides, demonstrating that they compete for the same binding site. Thus, bis-ANS displays properties similar to those of nucleic acids, causing oligomerization and conversion to beta-sheet (Cordeiro, Y., Machado, F., Juliano, L., Juliano, M. A., Brentani, R. R., Foguel, D., and Silva, J. L. (2001) J. Biol. Chem. 276, 49400-49409). This dual effect of bis-ANS on prion protein makes this compound highly important to sequester crucial conformations of the protein, which may be useful to the understanding of the disease and to serve as a lead for the development of new therapeutic strategies.     

pH-dependent prion protein conformation in classical Creutzfeldt-Jakob disease.

In transmissible spongiform encephalopathies, the cellular prion protein (PrP(C)) undergoes a conformational change from a prevailing alpha-helical structure to a beta-sheet-rich, protease-resistant isoform, termed PrP(Sc). PrP(C) has two characteristics: a high affinity for Cu(2+) and a strong pH-dependent conformation. Lines of evidence indicate that PrP(Sc) conformation is dependent on copper and that acidic conditions facilitate the conversion of PrP(C) --> PrP(Sc). In each species, PrP(Sc) exists in multiple conformations, which are associated with different prion strains. In sporadic Creutzfeldt-Jakob disease (sCJD), different biochemical types of PrP(Sc) have been identified according to the size of the protease-resistant fragments, patterns of glycosylation, and the metal-ion occupancy. Based on the site of cleavage produced by proteinase K, we investigated the conformational stability of PrP(Sc) under acidic, neutral, and basic conditions in 42 sCJD subjects. Our study shows that only one type of sCJD PrP(Sc), associated with the classical form, shows a pH-dependent conformation, whereas two other biochemical PrP(Sc) types, detected in distinct sCJD phenotypes, are unaffected by pH variations. This novel approach demonstrates the presence of three types of PrP(Sc) in sCJD.