Novel amplification mechanism of prions through disrupting sortilin-mediated trafficking

Conformational conversion of the cellular prion protein, PrP^C, into the abnormally folded isoform of prion protein, PrP^Sc, which leads to marked accumulation of PrP^Sc in brains, is a key pathogenic event in prion diseases, a group of fatal neurodegenerative disorders caused by prions. However, the exact mechanism of PrP^Sc accumulation in prion-infected neurons remains unknown. We recently reported a novel cellular mechanism to support PrP^Sc accumulation in prion-infected neurons, in which PrP^Sc itself promotes its accumulation by evading the cellular inhibitory mechanism, which is newly identified in our recent study. We showed that the VPS10P sorting receptor sortilin negatively regulates PrP^Sc accumulation in prion-infected neurons, by interacting with PrP^C and PrP^Sc and trafficking them to lysosomes for degradation. However, PrP^Sc stimulated lysosomal degradation of sortilin, disrupting the sortilin-mediated degradation of PrP^C and PrP^Sc and eventually evoking further accumulation of PrP^Sc in prion-infected neurons. These findings suggest a positive feedback amplification mechanism for PrP^Sc accumulation in prion-infected neurons.     

Identification of an Intracellular Site of Prion Conversion

Prion diseases are fatal, neurodegenerative disorders in humans and animals and are characterized by the accumulation of an abnormally folded isoform of the cellular prion protein (PrP^C), denoted PrP^Sc, which represents the major component of infectious scrapie prions. Characterization of the mechanism of conversion of PrP^C into PrP^Sc and identification of the intracellular site where it occurs are among the most important questions in prion biology. Despite numerous efforts, both of these questions remain unsolved. We have quantitatively analyzed the distribution of PrP^C and PrP^Sc and measured PrP^Sc levels in different infected neuronal cell lines in which protein trafficking has been selectively impaired. Our data exclude roles for both early and late endosomes and identify the endosomal recycling compartment as the likely site of prion conversion. These findings represent a fundamental step towards understanding the cellular mechanism of prion conversion and will allow the development of new therapeutic approaches for prion diseases.     

Chemically Induced Accumulation of GAGs Delays PrPSc Clearance but Prolongs Prion Disease Incubation Time

Prion diseases are a group of fatal neurodegenerative diseases affecting humans and animals. The only identified component of the infectious prion is PrP^Sc, an aberrantly folded isoform of PrP^C. Glycosaminoglycans, which constitute the main receptor for prions on cells, play a complex role in the pathogenesis of prion diseases. For example, while agents inducing aberrant lysosomal accumulation of GAGs such as Tilorone and Quinacrine significantly reduced PrP^Sc content in scrapie-infected cells, administration of Quinacrine to prion-infected subjects did not improve their clinical status. In this study, we investigated the association of PrP^Sc with cells cultured with Tilorone. We found that while the initial incorporation of PrP^Sc was similar in the treated and untreated cells, clearance of PrP^Sc from the Tilorone-treated cells was significantly impaired. Interestingly, prolonged administration of Tilorone to mice prior to prion infection resulted in a significant delay in disease onset, concomitantly with in vivo accumulation of lysosomal GAGs. We hypothesize that GAGs may complex with newly incorporated PrP^Sc in lysosomes and further stabilize the prion protein conformation. Over-stabilized PrP^Sc molecules have been shown to comprise reduced converting activity.     

Brain delivery of AAV9 expressing an anti-PrP monovalent antibody delays prion disease in mice

Prion diseases are caused by a conformational modification of the cellular prion protein (PrP^C) into disease-specific forms, termed PrP^Sc, that have the ability to interact with PrP^C promoting its conversion to PrP^Sc. In vitro studies demonstrated that anti-PrP antibodies inhibit this process. In particular, the single chain variable fragment D18 antibody (scFvD18) showed high efficiency in curing chronically prion-infected cells. This molecule binds the PrP^C region involved in the interaction with PrP^Sc thus halting further prion formation. These findings prompted us to test the efficiency of scFvD18 in vivo. A recombinant Adeno-Associated Viral vector serotype 9 was used to deliver scFvD18 to the brain of mice that were subsequently infected by intraperitoneal route with the mouse-adapted scrapie strain RML. We found that the treatment was safe, prolonged the incubation time of scrapie-infected animals and decreased the burden of total proteinase-resistant PrP^Sc in the brain, suggesting that scFvD18 interferes with prion replication in vivo. This approach is relevant for designing new therapeutic strategies for prion diseases and other disorders characterized by protein misfolding.     

Sialic Acid on the Glycosylphosphatidylinositol Anchor Regulates PrP-mediated Cell Signaling and Prion Formation

The prion diseases occur following the conversion of the cellular prion protein (PrP^C) into disease-related isoforms (PrP^Sc). In this study, the role of the glycosylphosphatidylinositol (GPI) anchor attached to PrP^C in prion formation was examined using a cell painting technique. PrP^Sc formation in two prion-infected neuronal cell lines (ScGT1 and ScN2a cells) and in scrapie-infected primary cortical neurons was increased following the introduction of PrP^C. In contrast, PrP^C containing a GPI anchor from which the sialic acid had been removed (desialylated PrP^C) was not converted to PrP^Sc. Furthermore, the presence of desialylated PrP^C inhibited the production of PrP^Sc within prion-infected cortical neurons and ScGT1 and ScN2a cells. The membrane rafts surrounding desialylated PrP^C contained greater amounts of sialylated gangliosides and cholesterol than membrane rafts surrounding PrP^C. Desialylated PrP^C was less sensitive to cholesterol depletion than PrP^C and was not released from cells by treatment with glimepiride. The presence of desialylated PrP^C in neurons caused the dissociation of cytoplasmic phospholipase A₂ from PrP-containing membrane rafts and reduced the activation of cytoplasmic phospholipase A₂. These findings show that the sialic acid moiety of the GPI attached to PrP^C modifies local membrane microenvironments that are important in PrP-mediated cell signaling and PrP^Sc formation. These results suggest that pharmacological modification of GPI glycosylation might constitute a novel therapeutic approach to prion diseases.     

Prion Infection Impairs Cholesterol Metabolism in Neuronal Cells

Conversion of prion protein (PrP^C) into a pathological isoform (PrP^Sc) during prion infection occurs in lipid rafts and is dependent on cholesterol. Here, we show that prion infection increases the abundance of cholesterol transporter, ATP-binding cassette transporter type A1 (ATP-binding cassette transporter type A1), but reduces cholesterol efflux from neuronal cells leading to the accumulation of cellular cholesterol. Increased abundance of ABCA1 in prion disease was confirmed in prion-infected mice. Mechanistically, conversion of PrP^C to the pathological isoform led to PrP^Sc accumulation in rafts, displacement of ABCA1 from rafts and the cell surface, and enhanced internalization of ABCA1. These effects were abolished with reversal of prion infection or by loading cells with cholesterol. Stimulation of ABCA1 expression with liver X receptor agonist or overexpression of heterologous ABCA1 reduced the conversion of prion protein into the pathological form upon infection. These findings demonstrate a reciprocal connection between prion infection and cellular cholesterol metabolism, which plays an important role in the pathogenesis of prion infection in neuronal cells.     

Brain delivery of AAV9 expressing an anti-PrP monovalent antibody delays prion disease in mice

Prion diseases are caused by a conformational modification of the cellular prion protein (PrP^C) into disease-specific forms, termed PrP^Sc, that have the ability to interact with PrP^C promoting its conversion to PrP^Sc. In vitro studies demonstrated that anti-PrP antibodies inhibit this process. In particular, the single chain variable fragment D18 antibody (scFvD18) showed high efficiency in curing chronically prion-infected cells. This molecule binds the PrP^C region involved in the interaction with PrP^Sc thus halting further prion formation. These findings prompted us to test the efficiency of scFvD18 in vivo. A recombinant Adeno-Associated Viral vector serotype 9 was used to deliver scFvD18 to the brain of mice that were subsequently infected by intraperitoneal route with the mouse-adapted scrapie strain RML. We found that the treatment was safe, prolonged the incubation time of scrapie-infected animals and decreased the burden of total proteinase-resistant PrP^Sc in the brain, suggesting that scFvD18 interferes with prion replication in vivo. This approach is relevant for designing new therapeutic strategies for prion diseases and other disorders characterized by protein misfolding.     

Does the tail wag the dog? How the structure of a glycosylphosphatidylinositol anchor affects prion formation

There is increasing interest in the role of the glycosylphosphatidylinositol (GPI) anchor attached to the cellular prion protein (PrP^C). Since GPI anchors can alter protein targeting, trafficking and cell signaling, our recent study examined how the structure of the GPI anchor affected prion formation. PrP^C containing a GPI anchor from which the sialic acid had been removed (desialylated PrP^C) was not converted to PrP^Sc in prion-infected neuronal cell lines and in scrapie-infected primary cortical neurons. In uninfected neurons desialylated PrP^C was associated with greater concentrations of gangliosides and cholesterol than PrP^C. In addition, the targeting of desialylated PrP^C to lipid rafts showed greater resistance to cholesterol depletion than PrP^C. The presence of desialylated PrP^C caused the dissociation of cytoplasmic phospholipase A₂ (cPLA₂) from PrP-containing lipid rafts, reduced the activation of cPLA₂ and inhibited PrP^Sc production. We conclude that the sialic acid moiety of the GPI attached to PrP^C modifies local membrane microenvironments that are important in PrP-mediated cell signaling and PrP^Sc formation.     

Identifying critical sites of PrPc-PrPSc interaction in prion-infected cells by dominant-negative inhibition

A direct physical interaction of the prion protein isoforms is a key element in prion conversion. Which sites interact first and which parts of PrP^c are converted subsequently is presently not known in detail. We hypothesized that structural changes induced by PrP^Sc interaction occur in more than one interface and subsequently propagate within the PrP^C substrate, like epicenters of structural changes. To identify potential interfaces we created a series of systematically-designed mutant PrPs and tested them in prion-infected cells for dominant-negative inhibition (DNI) effects. This showed that mutant PrPs with deletions in the region between first and second α-helix are involved in PrP-PrP interaction and conversion of PrP^C into PrP^Sc. Although some PrPs did not reach the plasma membrane, they had access to the locales of prion conversion and PrP^Sc recycling using autophagy pathways. Using other series of mutant PrPs we already have identified additional sites which constitute potential interaction interfaces. Our approach has the potential to characterize PrP-PrP interaction sites in the context of prion-infected cells. Besides providing further insights into the molecular mechanisms of prion conversion, this data may help to further elucidate how prion strain diversity is maintained.     

Establishment of a simple cell-based ELISA for the direct detection of abnormal isoform of prion protein from prion-infected cells without cell lysis and proteinase K treatment

Prion-infected cells have been used for analyzing the effect of compounds on the formation of abnormal isoform of prion protein (PrP^Sc). PrP^Sc is usually detected using anti-prion protein (PrP) antibodies after the removal of the cellular isoform of prion protein (PrP^C) by proteinase K (PK) treatment. However, it is expected that the PK-sensitive PrP^Sc (PrP^Sc-sen), which possesses higher infectivity and conversion activity than the PK-resistant PrP^Sc (PrP^Sc-res), is also digested through PK treatment. To overcome this problem, we established a novel cell-based ELISA in which PrP^Sc can be directly detected from cells persistently infected with prions using anti-PrP monoclonal antibody (mAb) 132 that recognizes epitope consisting of mouse PrP amino acids 119–127. The novel cell-based ELISA could distinguish prion-infected cells from prion-uninfected cells without cell lysis and PK treatment. MAb 132 could detect both PrP^Sc-sen and PrP^Sc-res even if all PrP^Sc molecules were not detected. The analytical dynamic range for PrP^Sc detection was approximately 1 log. The coefficient of variation and signal-to-background ratio were 7%–11% and 2.5–3.3, respectively, demonstrating the reproducibility of this assay. The addition of a cytotoxicity assay immediately before PrP^Sc detection did not affect the following PrP^Sc detection. Thus, all the procedures including cell culture, cytotoxicity assay, and PrP^Sc detection were completed in the same plate. The simplicity and non-requirement for cell lysis or PK treatment are advantages for the high throughput screening of anti-prion compounds.     

Rapid, high-throughput detection of PrPSc by 96-well immunoassay

Prion diseases are emerging infectious disorders that affect several mammalian species including humans. The transmissible agent is comprised of PrP^Sc, a misfolded isoform of the normal host-encoded prion protein PrP^C. Immunodetection of PrP^Sc is often utilized for prion disease diagnosis and tracking spread of the infectious agent through the host. We have developed a rapid, high-throughput 96-well immunoassay, which is specific for the detection of PrP^Sc. This assay has PrP^Sc detection limits similar to western blot and is advantageous because of its comparatively shorter running time, smaller start-up and operation costs and large sample capacity.Key words: prion disease, immunodetection, PrP^Sc     

Anti-Prion Activity of a Panel of Aromatic Chemical Compounds: In Vitro and In Silico Approaches

The prion protein (PrP) is implicated in the Transmissible Spongiform Encephalopathies (TSEs), which comprise a group of fatal neurodegenerative diseases affecting humans and other mammals. Conversion of cellular PrP (PrP^C) into the scrapie form (PrP^Sc) is the hallmark of TSEs. Once formed, PrP^Sc aggregates and catalyzes PrP^C misfolding into new PrP^Sc molecules. Although many compounds have been shown to inhibit the conversion process, so far there is no effective therapy for TSEs. Besides, most of the previously evaluated compounds failed in vivo due to poor pharmacokinetic profiles. In this work we propose a combined in vitro/in silico approach to screen for active anti-prion compounds presenting acceptable drugability and pharmacokinetic parameters. A diverse panel of aromatic compounds was screened in neuroblastoma cells persistently infected with PrP^Sc (ScN2a) for their ability to inhibit PK-resistant PrP (PrP^Res) accumulation. From ∼200 compounds, 47 were effective in decreasing the accumulation of PrP^Res in ScN2a cells. Pharmacokinetic and physicochemical properties were predicted in silico, allowing us to obtain estimates of relative blood brain barrier permeation and mutagenicity. MTT reduction assays showed that most of the active compounds were non cytotoxic. Compounds that cleared PrP^Res from ScN2a cells, were non-toxic in the MTT assay, and presented a good pharmacokinetic profile were investigated for their ability to inhibit aggregation of an amyloidogenic PrP peptide fragment (PrP^109–149). Molecular docking results provided structural models and binding affinities for the interaction between PrP and the most promising compounds. In summary, using this combined in vitro/in silico approach we have identified new small organic anti-scrapie compounds that decrease the accumulation of PrP^Res in ScN2a cells, inhibit the aggregation of a PrP peptide, and possess pharmacokinetic characteristics that support their drugability. These compounds are attractive candidates for prion disease therapy.     

Double-Edge Sword of Sustained ROCK Activation in Prion Diseases through Neuritogenesis Defects and Prion Accumulation

In prion diseases, synapse dysfunction, axon retraction and loss of neuronal polarity precede neuronal death. The mechanisms driving such polarization defects, however, remain unclear. Here, we examined the contribution of RhoA-associated coiled-coil containing kinases (ROCK), key players in neuritogenesis, to prion diseases. We found that overactivation of ROCK signaling occurred in neuronal stem cells infected by pathogenic prions (PrP^Sc) and impaired the sprouting of neurites. In reconstructed networks of mature neurons, PrP^Sc-induced ROCK overactivation provoked synapse disconnection and dendrite/axon degeneration. This overactivation of ROCK also disturbed overall neurotransmitter-associated functions. Importantly, we demonstrated that beyond its impact on neuronal polarity ROCK overactivity favored the production of PrP^Sc through a ROCK-dependent control of 3-phosphoinositide-dependent kinase 1 (PDK1) activity. In non-infectious conditions, ROCK and PDK1 associated within a complex and ROCK phosphorylated PDK1, conferring basal activity to PDK1. In prion-infected neurons, exacerbated ROCK activity increased the pool of PDK1 molecules physically interacting with and phosphorylated by ROCK. ROCK-induced PDK1 overstimulation then canceled the neuroprotective α-cleavage of normal cellular prion protein PrP^C by TACE α-secretase, which physiologically precludes PrP^Sc production. In prion-infected cells, inhibition of ROCK rescued neurite sprouting, preserved neuronal architecture, restored neuronal functions and reduced the amount of PrP^Sc. In mice challenged with prions, inhibition of ROCK also lowered brain PrP^Sc accumulation, reduced motor impairment and extended survival. We conclude that ROCK overactivation exerts a double detrimental effect in prion diseases by altering neuronal polarity and triggering PrP^Sc accumulation. Eventually ROCK emerges as therapeutic target to combat prion diseases.     

Volatile Anesthetic Sevoflurane Precursor 1,1,1,3,3,3-Hexafluoro-2-Propanol (HFIP) Exerts an Anti-Prion Activity in Prion-Infected Culture Cells

Prion disease is a neurodegenerative disorder with progressive neurologic symptoms and accelerated cognitive decline. The causative protein of prion disease is the prion protein (PrP), and structural transition of PrP from the normal helix rich form (PrP^C) to the abnormal β-sheet rich form (PrP^Sc) occurs in prion disease. While so far numerous therapeutic agents for prion diseases have been developed, none of them are still useful. A fluorinated alcohol, hexafluoro isopropanol (HFIP), is a precursor to the inhalational anesthetic sevoflurane and its metabolites. HFIP is also known as a robust α-helix inducer and is widely used as a solvent for highly aggregated peptides. Here we show that the α-helix-inducing activity of HFIP caused the conformational transformation of the fibrous structure of PrP into amorphous aggregates in vitro. HFIP added to the ScN2a cell medium, which continuously expresses PrP^Sc, reduced PrP^Sc protease resistance after 24-h incubation. It was also clarified that ScN2a cells are more susceptible to HFIP than any of the cells being compared. Based on these findings, HFIP is expected to develop as a therapeutic agent for prion disease.

     

Propagation of RML Prions in Mice Expressing PrP Devoid of GPI Anchor Leads to Formation of a Novel, Stable Prion Strain

PrP^C, a host protein which in prion-infected animals is converted to PrP^Sc, is linked to the cell membrane by a GPI anchor. Mice expressing PrP^C without GPI anchor (tgGPI^- mice), are susceptible to prion infection but accumulate anchorless PrP^Sc extra-, rather than intracellularly. We investigated whether tgGPI⁻ mice could faithfully propagate prion strains despite the deviant structure and location of anchorless PrP^Sc. We found that RML and ME7, but not 22L prions propagated in tgGPI⁻ brain developed novel cell tropisms, as determined by the Cell Panel Assay (CPA). Surprisingly, the levels of proteinase K-resistant PrP^Sc (PrP^res) in RML- or ME7-infected tgGPI⁻ brain were 25–50 times higher than in wild-type brain. When returned to wild-type brain, ME7 prions recovered their original properties, however RML prions had given rise to a novel prion strain, designated SFL, which remained unchanged even after three passages in wild-type mice. Because both RML PrP^Sc and SFL PrP^Sc are stably propagated in wild-type mice we propose that the two conformations are separated by a high activation energy barrier which is abrogated in tgGPI⁻ mice.     

Poly-L-histidine inhibits prion propagation in a prion-infected cell line

ABSTRACT

Transmissible spongiform encephalopathies (TSEs) are a group of lethal neurodegenerative diseases involving the structural conversion of cellular prion protein (PrP^C) into the pathogenic isoform (PrP^Sc) for which no effective treatment is currently available. Previous studies have implicated that a polymeric molecule with a repeating unit, such as pentosane polysulfate and polyamidoamide dendrimers, exhibits a potent anti-prion activity, suggesting that poly-(amino acid)s could be a candidate molecule for inhibiting prion propagation. Here, by screening a series of poly-(amino acid)s in a prion-infected neuroblastoma cell line (GT^FK), we identified poly-L-His as a novel anti-prion compound with an IC₅₀ value of 1.8 µg/mL (0.18 µM). This potent anti-prion activity was specific to a high-molecular-weight poly-L-His and absent in monomeric histidine or low-molecular-weight poly-L-His. Solution NMR data indicated that poly-L-His directly binds to the loop region connecting Helix 2 and Helix 3 of PrP^C and sterically blocks the structural conversion toward PrP^Sc. Poly-L-His, however, did not inhibit prion propagation in a prion-infected mouse when administered intraperitoneally, suggesting that the penetration of blood-brain barrier and/or the chemical stability of this polypeptide must be addressed before its application in vivo. Taken together, this study revealed the potential use of poly-L-His as a novel treatment against TSEs. (203 words)     

Sialylation of Prion Protein Controls the Rate of Prion Amplification,the Cross-Species Barrier,the Ratio of PrPSc Glycoform and Prion Infectivity

The central event underlying prion diseases involves conformational change of the cellular form of the prion protein (PrP^C) into the disease-associated, transmissible form (PrP^Sc). PrP^C is a sialoglycoprotein that contains two conserved N-glycosylation sites. Among the key parameters that control prion replication identified over the years are amino acid sequence of host PrP^C and the strain-specific structure of PrP^Sc. The current work highlights the previously unappreciated role of sialylation of PrP^C glycans in prion pathogenesis, including its role in controlling prion replication rate, infectivity, cross-species barrier and PrP^Sc glycoform ratio. The current study demonstrates that undersialylated PrP^C is selected during prion amplification in Protein Misfolding Cyclic Amplification (PMCAb) at the expense of oversialylated PrP^C. As a result, PMCAb-derived PrP^Sc was less sialylated than brain-derived PrP^Sc. A decrease in PrP^Sc sialylation correlated with a drop in infectivity of PMCAb-derived material. Nevertheless, enzymatic de-sialylation of PrP^C using sialidase was found to increase the rate of PrP^Sc amplification in PMCAb from 10- to 10,000-fold in a strain-dependent manner. Moreover, de-sialylation of PrP^C reduced or eliminated a species barrier of for prion amplification in PMCAb. These results suggest that the negative charge of sialic acid controls the energy barrier of homologous and heterologous prion replication. Surprisingly, the sialylation status of PrP^C was also found to control PrP^Sc glycoform ratio. A decrease in PrP^C sialylation levels resulted in a higher percentage of the diglycosylated glycoform in PrP^Sc. 2D analysis of charge distribution revealed that the sialylation status of brain-derived PrP^C differed from that of spleen-derived PrP^C. Knocking out lysosomal sialidase Neu1 did not change the sialylation status of brain-derived PrP^C, suggesting that Neu1 is not responsible for desialylation of PrP^C. The current work highlights previously unappreciated role of PrP^C sialylation in prion diseases and opens multiple new research directions, including development of new therapeutic approaches.     

Glimepiride Reduces the Expression of PrPC,Prevents PrPSc Formation and Protects against Prion Mediated Neurotoxicity

Background

A hallmark of the prion diseases is the conversion of the host-encoded cellular prion protein (PrP^C) into a disease related, alternatively folded isoform (PrP^Sc). The accumulation of PrP^Sc within the brain is associated with synapse loss and ultimately neuronal death. Novel therapeutics are desperately required to treat neurodegenerative diseases including the prion diseases.

Principal Findings

Treatment with glimepiride, a sulphonylurea approved for the treatment of diabetes mellitus, induced the release of PrP^C from the surface of prion-infected neuronal cells. The cell surface is a site where PrP^C molecules may be converted to PrP^Sc and glimepiride treatment reduced PrP^Sc formation in three prion infected neuronal cell lines (ScN2a, SMB and ScGT1 cells). Glimepiride also protected cortical and hippocampal neurones against the toxic effects of the prion-derived peptide PrP82–146. Glimepiride treatment significantly reduce both the amount of PrP82–146 that bound to neurones and PrP82–146 induced activation of cytoplasmic phospholipase A₂ (cPLA₂) and the production of prostaglandin E₂ that is associated with neuronal injury in prion diseases. Our results are consistent with reports that glimepiride activates an endogenous glycosylphosphatidylinositol (GPI)-phospholipase C which reduced PrP^C expression at the surface of neuronal cells. The effects of glimepiride were reproduced by treatment of cells with phosphatidylinositol-phospholipase C (PI-PLC) and were reversed by co-incubation with p-chloromercuriphenylsulphonate, an inhibitor of endogenous GPI-PLC.

Conclusions

Collectively, these results indicate that glimepiride may be a novel treatment to reduce PrP^Sc formation and neuronal damage in prion diseases.     

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

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