PrP(106-126) does not interact with membranes under physiological conditions

Transmissible spongiform encephalopathies are neurodegenerative diseases characterized by the accumulation of an abnormal isoform of the prion protein PrP^Sc. Its fragment 106-126 has been reported to maintain most of the pathological features of PrP^Sc, and a role in neurodegeneration has been proposed based on the modulation of membrane properties and channel formation. The ability of PrP^Sc to modulate membranes and/or form channels in membranes has not been clearly demonstrated; however, if these processes are important, peptide-membrane interactions would be a key feature in the toxicity of PrP^Sc. In this work, the interaction of PrP(106-126) with model membranes comprising typical lipid identities, as well as more specialized lipids such as phosphatidylserine and GM1 ganglioside, was examined using surface plasmon resonance and fluorescence methodologies. This comprehensive study examines different parameters relevant to characterization of peptide-membrane interactions, including membrane charge, viscosity, lipid composition, pH, and ionic strength. We report that PrP(106-126) has a low affinity for lipid membranes under physiological conditions without evidence of membrane disturbances. Membrane insertion and leakage occur only under conditions in which strong electrostatic interactions operate. These results support the hypothesis that the physiological prion protein PrP^C mediates PrP(106-126) toxic effects in neuronal cells.     

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.     

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

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

Small stress molecules inhibit aggregation and neurotoxicity of prion peptide 106-126

In prion diseases, the posttranslational modification of host-encoded prion protein PrP^c yields a high β-sheet content modified protein PrP^sc, which further polymerizes into amyloid fibrils. PrP106-126 initiates the conformational changes leading to the conversion of PrP^c to PrP^sc. Molecules that can defunctionalize such peptides can serve as a potential tool in combating prion diseases. In microorganisms during stressed conditions, small stress molecules (SSMs) are formed to prevent protein denaturation and maintain protein stability and function. The effect of such SSMs on PrP106-126 amyloid formation is explored in the present study using turbidity, atomic force microscopy (AFM), and cellular toxicity assay. Turbidity and AFM studies clearly depict that the SSMs—ectoine and mannosylglyceramide (MGA) inhibit the PrP106-126 aggregation. Our study also connotes that ectoine and MGA offer strong resistance to prion peptide-induced toxicity in human neuroblastoma cells, concluding that such molecules can be potential inhibitors of prion aggregation and toxicity.     

Electron crystallography of the scrapie prion protein complexed with heavy metals

The insolubility of the disease-causing isoform of the prion protein (PrP^Sc) has prevented studies of its three-dimensional structure at atomic resolution. Electron crystallography of two-dimensional crystals of N-terminally truncated PrP^Sc (PrP 27-30) and a miniprion (PrP^Sc106) provided the first insights at intermediate resolution on the molecular architecture of the prion. Here, we report on the structure of PrP 27-30 and PrP^Sc106 negatively stained with heavy metals. The interactions of the heavy metals with the crystal lattice were governed by tertiary and quaternary structural elements of the protein as well as the charge and size of the heavy metal salts. Staining with molybdate anions revealed three prominent densities near the center of the trimer that forms the unit cell, coinciding with the location of the β-helix that was proposed for the structure of PrP^Sc. Differential staining also confirmed the location of the internal deletion of PrP^Sc106 at or near these densities.     

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

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

Immunopurification of Pathological Prion Protein Aggregates

Background

Prion diseases are fatal neurodegenerative disorders that can arise sporadically, be genetically inherited or acquired through infection. The key event in these diseases is misfolding of the cellular prion protein (PrP^C) into a pathogenic isoform that is rich in β-sheet structure. This conformational change may result in the formation of PrP^Sc, the prion isoform of PrP, which propagates itself by imprinting its aberrant conformation onto PrP^C molecules. A great deal of effort has been devoted to developing protocols for purifying PrP^Sc for structural studies, and testing its biological properties. Most procedures rely on protease digestion, allowing efficient purification of PrP27-30, the protease-resistant core of PrP^Sc. However, protease treatment cannot be used to isolate abnormal forms of PrP lacking conventional protease resistance, such as those found in several genetic and atypical sporadic cases.

Principal Findings

We developed a method for purifying pathological PrP molecules based on sequential centrifugation and immunoprecipitation with a monoclonal antibody selective for aggregated PrP. With this procedure we purified full-length PrP^Sc and mutant PrP aggregates at electrophoretic homogeneity. PrP^Sc purified from prion-infected mice was able to seed misfolding of PrP^C in a protein misfolding cyclic amplification reaction, and mutant PrP aggregates from transgenic mice were toxic to cultured neurons.

Significance

The immunopurification protocol described here isolates biologically active forms of aggregated PrP. These preparations may be useful for investigating the structural and chemico-physical properties of infectious and neurotoxic PrP aggregates.     

PrP106-126 peptide disrupts lipid membranes: Influence of C-terminal amidation

PrP106-126 is located within the important domain concerning membrane related conformational conversion of human Prion protein (from cellular isoform PrP^C to scrapie isoform PrP^Sc). Recent advances reveal that the pathological and physicochemical properties of PrP106-126 peptide are very sensitive to its N-terminal amidation, however, the detailed mechanism remains unclear. In this work, we studied the interactions of the PrP106-126 isoforms (PrP106-126_CONH2 and PrP106-126_COOH) with the neutral lipid bilayers by atomic force microscopy, surface plasmon resonance and fluorescence spectroscopy. The membrane structures were disturbed by the two isoforms in a similarly stepwise process. The distinct morphological changes of the membrane were characterized by formation of semi-penetrated defects and sigmoidal growth of flat high-rise domains on the supported lipid bilayers. However, PrP106-126_COOH displayed a higher peptide-lipid binding affinity than PrP106-126_CONH2 (∼2.9 times) and facilitated the peptide-lipid interactions by shortening the lag time. These results indicate that the C-terminal amidation may influence the pathological actions of PrP106-126 by lowering the interaction potentials with lipid membranes.     

Overexpression of Nonconvertible PrPcΔ114–121 in Scrapie-Infected Mouse Neuroblastoma Cells Leads to trans-Dominant Inhibition of Wild-Type PrPSc Accumulation

One hallmark of prion diseases is the accumulation of the abnormal isoform PrP^Sc of a normal cellular glycoprotein, PrP^c, which is characterized by a high content of β-sheet structures and by its partial resistance to proteinase K. It was hypothesized that the PrP region comprising amino acid residues 109 to 122 [PrP(109–122)], which spontaneously forms amyloid when it is synthesized as a peptide but which does not display significant secondary structure in the context of the full-length PrP^c molecule, should play a role in promoting the conversion into PrP^Sc. By using persistently scrapie-infected mouse neuroblastoma (Sc⁺-MNB) cells as a model system for prion replication, we set out to design dominant-negative mutants of PrP^c that are capable of blocking the conversion of endogenous, wild-type PrP^c into PrP^Sc. We constructed a deletion mutant (PrP^cΔ114–121) lacking eight codons that span most of the highly amyloidogenic part, AGAAAAGA, of PrP(109–122). Transient transfections of mammalian expression vectors encoding either wild-type PrP^c or PrP^cΔ114–121 into uninfected mouse neuroblastoma cells (Neuro2a) led to overexpression of the respective PrP^c versions, which proved to be correctly localized on the extracellular face of the plasma membrane. Transfection of Sc⁺-MNB cells revealed that PrP^cΔ114–121 was not a substrate for conversion into a proteinase K-resistant isoform. Furthermore, its presence led to a significant reduction in the steady-state levels of PrP^Sc derived from endogenous PrP^c. Thus, we showed that the presence of amino acids 114 to 121 of mouse PrP^c plays an important role in the conversion process of PrP^c into PrP^Sc and that a deletion mutant lacking these codons indeed behaves as a dominant-negative mutant with respect to PrP^Sc accumulation. This mechanism could form a basis for a new gene therapy and/or a prevention concept for prion diseases.     

Mapping the Prion Protein Using Recombinant Antibodies

The fundamental event in prion disease is thought to be the posttranslational conversion of the cellular prion protein (PrP^C) into a pathogenic isoform (PrP^Sc). The occurrence of PrP^C on the cell surface and PrP^Sc in amyloid plaques in situ or in aggregates following purification complicates the study of the molecular events that underlie the disease process. Monoclonal antibodies are highly sensitive probes of protein conformation which can be used under these conditions. Here, we report the rescue of a diverse panel of 19 PrP-specific recombinant monoclonal antibodies from phage display libraries prepared from PrP deficient (Prnp^0/0) mice immunized with infectious prions either in the form of rods or PrP 27-30 dispersed into liposomes. The antibodies recognize a number of distinct linear and discontinuous epitopes that are presented to a varying degree on different PrP preparations. The epitope reactivity of the recombinant PrP(90-231) molecule was almost indistinguishable from that of PrP^C on the cell surface, validating the importance of detailed structural studies on the recombinant molecule. Only one epitope region at the C terminus of PrP was well presented on both PrP^C and PrP^Sc, while epitopes associated with most of the antibodies in the panel were present on PrP^C but absent from PrP^Sc.     

Octapeptide repeat region of prion protein (PrP) is required at an early stage for production of abnormal prion protein in PrP-deficient neuronal cell line

An abnormal isoform of prion protein (PrP^Sc), which is composed of the same amino acids as cellular PrP (PrP^C) and has proteinase K (PK)-resistance, hypothetically converts PrP^C into PrP^Sc. To investigate the region important for PrP^Sc production, we examined the levels of PrP^Sc in PrP gene-deficient cells (HpL3-4) expressing PrP^C deleted of various regions including the octapeptide repeat region (OR) or hydrophobic region (HR). After Chandler or Obihiro prion infection, PrP^Sc was produced in HpL3-4 cells expressing wild-type PrP^C or PrP^C deleted of HR at an early stage and further reduced to below the detectable level, whereas cells expressing PrP^C deleted of OR showed no PrP^Sc production. The results suggest that OR of PrP^C is required for the early step of efficient PrP^Sc production.     

The number of octapeptide repeat affects the expression and conversion of prion protein

The human prion protein (PrP) has five copies of an octapeptide repeat (OR). The mutant PrP with 6-14 OR causes the genetic form of Creutzfeldt-Jakob disease (CJD). To determine the influence of OR on the conversion of PrP, we examined the conversion efficiency of mouse mutant PrP molecules with 1-16 OR in scrapie-infected cells. The expression level of mutant PrP and the glycoform ratio of the abnormal isoform of PrP (PrP^Sc) were affected by the number of OR. The conversion efficiency was almost equivalent among mutant PrP molecules with 5-16 OR, whereas that of mutant PrP with 1-4 OR was decreased. The present study suggests that CJD patients with the longer extra OR, who usually show only a trace of PrP^Sc in the brain, can produce the authentic triplet PrP^Sc if secondary prion infection occurs.     

Protocol for aerosol-free recombinant production and NMR analysis of prion proteins

The central hallmark of prion diseases is the misfolding of cellular prion protein (PrP^C) into a disease-associated aggregated isoform known as scrapie prion protein (PrP^Sc). NMR spectroscopy has made many essential contributions to the characterization of recombinant PrP in its folded, unfolded and aggregated states. Recent studies reporting on de novo generation of prions from recombinant PrP and infection of animals using prion aerosols suggest that adjustment of current biosafety measures may be necessary, particularly given the relatively high protein concentrations required for NMR applications that favor aggregation. We here present a protocol for the production of recombinant PrP under biosafety level 2 conditions that avoids entirely exposure of the experimenter to aerosols that might contain harmful PrP aggregates. In addition, we introduce an NMR sample tube setup that allows for safe handling of PrP samples at the spectrometer that usually is not part of a dedicated biosafety level 2 laboratory.     

Prion Protein—Antibody Complexes Characterized by Chromatography-Coupled Small-Angle X-Ray Scattering

Aberrant self-assembly, induced by structural misfolding of the prion proteins, leads to a number of neurodegenerative disorders. In particular, misfolding of the mostly α-helical cellular prion protein (PrP^C) into a β-sheet-rich disease-causing isoform (PrP^Sc) is the key molecular event in the formation of PrP^Sc aggregates. The molecular mechanisms underlying the PrP^C-to-PrP^Sc conversion and subsequent aggregation remain to be elucidated. However, in persistently prion-infected cell-culture models, it was shown that treatment with monoclonal antibodies against defined regions of the prion protein (PrP) led to the clearing of PrP^Sc in cultured cells. To gain more insight into this process, we characterized PrP-antibody complexes in solution using a fast protein liquid chromatography coupled with small-angle x-ray scattering (FPLC-SAXS) procedure. High-quality SAXS data were collected for full-length recombinant mouse PrP [denoted recPrP(23–230)] and N-terminally truncated recPrP(89–230), as well as their complexes with each of two Fab fragments (HuM-P and HuM-R1), which recognize N- and C-terminal epitopes of PrP, respectively. In-line measurements by fast protein liquid chromatography coupled with SAXS minimized data artifacts caused by a non-monodispersed sample, allowing structural analysis of PrP alone and in complex with Fab antibodies. The resulting structural models suggest two mechanisms for how these Fabs may prevent the conversion of PrP^C into PrP^Sc.     

A Specific Population of Abnormal Prion Protein Aggregates Is Preferentially Taken Up by Cells and Disaggregated in a Strain-Dependent Manner

Prion diseases are characterized by the conversion of the soluble protease-sensitive host-encoded prion protein (PrP^C) into its aggregated, protease-resistant, and infectious isoform (PrP^Sc). One of the earliest events occurring in cells following exposure to an exogenous source of prions is the cellular uptake of PrP^Sc. It is unclear how the biochemical properties of PrP^Sc influence its uptake, although aggregate size is thought to be important. Here we show that for two different strains of mouse prions, one that infects cells (22L) and one that does not (87V), a fraction of PrP^Sc associated with distinct sedimentation properties is preferentially taken up by the cells. However, while the fraction of PrP^Sc and the kinetics of uptake were similar for both strains, PrP^Sc derived from the 87V strain was disaggregated more rapidly than that derived from 22L. The increased rate of PrP^Sc disaggregation did not correlate with either the conformational or aggregate stability of 87V PrP^Sc, both of which were greater than those of 22L PrP^Sc. Our data suggest that the kinetics of disaggregation of PrP^Sc following cellular uptake is independent of PrP^Sc stability but may be dependent upon some component of the PrP^Sc aggregate other than PrP. Rapid disaggregation of 87V PrP^Sc by the cell may contribute, at least in part, to the inability of 87V to infect cells in vitro.     

Parkin Overexpression Ameliorates PrP106–126-Induced Neurotoxicity via Enhanced Autophagy in N2a Cells

Transmissible spongiform encephalopathies (TSEs) are caused by the accumulation of the abnormal prion protein scrapie (PrP^Sc). Prion protein aggregation, misfolding, and cytotoxicity in the brain are the major causes of neuronal dysfunction and ultimate neurodegeneration in all TSEs. Parkin, an E3 ubiquitin ligase, has been studied extensively in all major protein misfolding aggregating diseases, especially Parkinson’s disease and Alzheimer’s disease, but the role of parkin in TSEs remains unknown. Here we investigated the role of parkin in a prion disease cell model in which neuroblastoma2a (N2a) cells were treated with prion peptide PrP106–126. We observed a gradual decrease in the soluble parkin level upon treatment with PrP106–126 in a time-dependent manner. Furthermore, endogenous parkin colocalized with FITC-tagged prion fragment106–126. Overexpression of parkin in N2a cells via transfection repressed apoptosis by enhancing autophagy. Parkin-overexpressing cells also showed reductions in apoptotic BAX translocation to the mitochondria and cytochrome c release to the cytosol, which ultimately inhibited activation of proapoptotic caspases. Taken together, our findings reveal a parkin-mediated cytoprotective mechanism against PrP106–126 toxicity, which is a novel potential therapeutic target for treating prion diseases.     

Pathologic Prion Protein Infects Cells by Lipid-Raft Dependent Macropinocytosis

Transmissible spongiform encephalopathies, including variant-Creutzfeldt-Jakob disease (vCJD) in humans and bovine spongiform encephalopathies in cattle, are fatal neurodegenerative disorders characterized by protein misfolding of the host cellular prion protein (PrP^C) to the infectious scrapie form (PrP^Sc). However, the mechanism that exogenous PrP^Sc infects cells and where pathologic conversion of PrP^C to the PrP^Sc form occurs remains uncertain. Here we report that similar to the mechanism of HIV-1 TAT-mediated peptide transduction, processed mature, full length PrP contains a conserved N-terminal cationic domain that stimulates cellular uptake by lipid raft-dependent, macropinocytosis. Inhibition of macropinocytosis by three independent means prevented cellular uptake of recombinant PrP; however, it did not affect recombinant PrP cell surface association. In addition, fusion of the cationic N-terminal PrP domain to a Cre recombinase reporter protein was sufficient to promote both cellular uptake and escape from the macropinosomes into the cytoplasm. Inhibition of macropinocytosis was sufficient to prevent conversion of PrP^C to the pathologic PrP^Sc form in N2a cells exposed to strain RML PrP^Sc infected brain homogenates, suggesting that a critical determinant of PrP^C conversion occurs following macropinocytotic internalization and not through mere membrane association. Taken together, these observations provide a cellular mechanism that exogenous pathological PrP^Sc infects cells by lipid raft dependent, macropinocytosis.     

Induction of ligand-specific PrPC signaling in human neuronal cells

Cellular prion protein (PrP^C) has attracted considerable attention for its role in transmissible spongiform encephalopathies (TSEs). In spite of being a point of intense research effort critical questions still remain regarding the physiological function of PrP^C and how these functions may change with the conversion of the protein into the infectious and pathological conformation (PrP^Sc). While emerging evidence suggests PrP^C/Sc are involved in signal transduction there is little consensus on the signaling pathways associated with the normal and diseased states. The purported involvement of PrP^C in signal transduction, and the association of TSEs with neural pathology, makes kinome analysis of human neurons an interesting and appropriate model to characterize patterns of signal transduction following activation of PrP^C by two commonly employed experimental ligands; antibody-induced dimerization by 6H4 and the amino acids 106-126 PrP peptide fragment (PrP 106–126). Analysis of the induced kinome responses reveals distinct patterns of signaling activity following each treatment. Specifically, stimulation of human neurons with the 6H4 antibody results in alterations in mitogen activated protein kinase (MAPK) signaling pathways while the 106-126 peptide activates growth factor related signaling pathways including vascular endothelial growth factor (VEGF) signaling and the phosphoinositide-3 kinase (PI3K) pathway. These pathways were validated through independent functional assays. Collectively these results indicate that stimulation of PrP^C with distinct ligands, even within the same cell type, results in unique patterns of signaling. While this investigation highlights the apparent functional versatility of PrP^C as a signaling molecule and may offer insight into cellular mechanisms of TSE pathology it also emphasizes the potential dangers associated with attributing activation of specific intracellular events to particular receptors through artificial models of receptor activation.     

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.