Loss of prion protein control of glucose metabolism promotes neurodegeneration in model of prion diseases

Corruption of cellular prion protein (PrP^C) function(s) at the plasma membrane of neurons is at the root of prion diseases, such as Creutzfeldt-Jakob disease and its variant in humans, and Bovine Spongiform Encephalopathies, better known as mad cow disease, in cattle. The roles exerted by PrP^C, however, remain poorly elucidated. With the perspective to grasp the molecular pathways of neurodegeneration occurring in prion diseases, and to identify therapeutic targets, achieving a better understanding of PrP^C roles is a priority. Based on global approaches that compare the proteome and metabolome of the PrP^C expressing 1C11 neuronal stem cell line to those of PrP^null-1C11 cells stably repressed for PrP^C expression, we here unravel that PrP^C contributes to the regulation of the energetic metabolism by orienting cells towards mitochondrial oxidative degradation of glucose. Through its coupling to cAMP/protein kinase A signaling, PrP^C tones down the expression of the pyruvate dehydrogenase kinase 4 (PDK4). Such an event favors the transfer of pyruvate into mitochondria and its conversion into acetyl-CoA by the pyruvate dehydrogenase complex and, thereby, limits fatty acids β-oxidation and subsequent onset of oxidative stress conditions. The corruption of PrP^C metabolic role by pathogenic prions PrP^Sc causes in the mouse hippocampus an imbalance between glucose oxidative degradation and fatty acids β-oxidation in a PDK4-dependent manner. The inhibition of PDK4 extends the survival of prion-infected mice, supporting that PrP^Sc-induced deregulation of PDK4 activity and subsequent metabolic derangements contribute to prion diseases. Our study posits PDK4 as a potential therapeutic target to fight against prion diseases.     

Convection-Enhanced Delivery of AAV2-PrPshRNA in Prion-Infected Mice

Prion disease is caused by a single pathogenic protein (PrP^Sc), an abnormal conformer of the normal cellular prion protein PrP^C. Depletion of PrP^C in prion knockout mice makes them resistant to prion disease. Thus, gene silencing of the Prnp gene is a promising effective therapeutic approach. Here, we examined adeno-associated virus vector type 2 encoding a short hairpin RNA targeting Prnp mRNA (AAV2-PrP-shRNA) to suppress PrP^C expression both in vitro and in vivo. AAV2-PrP-shRNA treatment suppressed PrP levels and prevented dendritic degeneration in RML-infected brain aggregate cultures. Infusion of AAV2-PrP-shRNA-eGFP into the thalamus of CD-1 mice showed that eGFP was transported to the cerebral cortex via anterograde transport and the overall PrP^C levels were reduced by ∼70% within 4 weeks. For therapeutic purposes, we treated RML-infected CD-1 mice with AAV2-PrP-shRNA beginning at 50 days post inoculation. Although AAV2-PrP-shRNA focally suppressed PrP^Sc formation in the thalamic infusion site by ∼75%, it did not suppress PrP^Sc formation efficiently in other regions of the brain. Survival of mice was not extended compared to the untreated controls. Global suppression of PrP^C in the brain is required for successful therapy of prion diseases.     

Liposome-siRNA-Peptide Complexes Cross the Blood-Brain Barrier and Significantly Decrease PrPC on Neuronal Cells and PrPRES in Infected Cell Cultures

Background

Recent advances toward an effective therapy for prion diseases employ RNA interference to suppress PrP^C expression and subsequent prion neuropathology, exploiting the phenomenon that disease severity and progression correlate with host PrP^C expression levels. However, delivery of lentivirus encoding PrP shRNA has demonstrated only modest efficacy in vivo.

Methodology/Principal Findings

Here we describe a new siRNA delivery system incorporating a small peptide that binds siRNA and acetylcholine receptors (AchRs), acting as a molecular messenger for delivery to neurons, and cationic liposomes that protect siRNA-peptide complexes from serum degradation.

Conclusions/Significance

Liposome-siRNA-peptide complexes (LSPCs) delivered PrP siRNA specifically to AchR-expressing cells, suppressed PrP^C expression and eliminated PrP^RES formation in vitro. LSPCs injected intravenously into mice resisted serum degradation and delivered PrP siRNA throughout the brain to AchR and PrP^C-expressing neurons. These data promote LSPCs as effective vehicles for delivery of PrP and other siRNAs specifically to neurons to treat prion and other neuropathological diseases.     

Naturally prion resistant mammals: A utopia?

Each known abnormal prion protein (PrP^Sc) is considered to have a specific range and therefore the ability to infect some species and not others. Consequently, some species have been assumed to be prion disease resistant as no successful natural or experimental challenge infections have been reported. This assumption suggested that, independent of the virulence of the PrP^Sc strain, normal prion protein (PrP^C) from these ‘resistant’ species could not be induced to misfold. Numerous in vitro and in vivo studies trying to corroborate the unique properties of PrP^Sc have been undertaken. The results presented in the article “Rabbits are not resistant to prion infection” demonstrated that normal rabbit PrP^C, which was considered to be resistant to prion disease, can be misfolded to PrP^Sc and subsequently used to infect and transmit a standard prion disease to leporids. Using the concept of species resistance to prion disease, we will discuss the mistake of attributing species specific prion disease resistance based purely on the absence of natural cases and incomplete in vivo challenges. The BSE epidemic was partially due to an underestimation of species barriers. To repeat this error would be unacceptable, especially if present knowledge and techniques can show a theoretical risk. Now that the myth of prion disease resistance has been refuted it is time to re-evaluate, using the new powerful tools available in modern prion laboratories, whether any other species could be at risk.     

Prion Protein Modulates Cellular Iron Uptake: A Novel Function with Implications for Prion Disease Pathogenesis

Converging evidence leaves little doubt that a change in the conformation of prion protein (PrP^C) from a mainly α-helical to a β-sheet rich PrP-scrapie (PrP^Sc) form is the main event responsible for prion disease associated neurotoxicity. However, neither the mechanism of toxicity by PrP^Sc, nor the normal function of PrP^C is entirely clear. Recent reports suggest that imbalance of iron homeostasis is a common feature of prion infected cells and mouse models, implicating redox-iron in prion disease pathogenesis. In this report, we provide evidence that PrP^C mediates cellular iron uptake and transport, and mutant PrP forms alter cellular iron levels differentially. Using human neuroblastoma cells as models, we demonstrate that over-expression of PrP^C increases intra-cellular iron relative to non-transfected controls as indicated by an increase in total cellular iron, the cellular labile iron pool (LIP), and iron content of ferritin. As a result, the levels of iron uptake proteins transferrin (Tf) and transferrin receptor (TfR) are decreased, and expression of iron storage protein ferritin is increased. The positive effect of PrP^C on ferritin iron content is enhanced by stimulating PrP^C endocytosis, and reversed by cross-linking PrP^C on the plasma membrane. Expression of mutant PrP forms lacking the octapeptide-repeats, the membrane anchor, or carrying the pathogenic mutation PrP^102L decreases ferritin iron content significantly relative to PrP^C expressing cells, but the effect on cellular LIP and levels of Tf, TfR, and ferritin is complex, varying with the mutation. Neither PrP^C nor the mutant PrP forms influence the rate or amount of iron released into the medium, suggesting a functional role for PrP^C in cellular iron uptake and transport to ferritin, and dysfunction of PrP^C as a significant contributing factor of brain iron imbalance in prion disorders.     

Glycosylation-related genes are variably expressed depending on the differentiation state of a bioaminergic neuronal cell line: implication for the cellular prion protein

A striking feature of the cellular prion protein (PrP^C) is the heterogeneity of its glycoforms, whose contribution to PrP^C function has yet to be defined. Using the 1C11 neuronal bioaminergic differentiation model and a glycomics approach, we show here a correlation between differential PrP^C N-glycosylations in 1C11^5-HT serotonergic and 1C11^NE noradrenergic cells compared to their 1C11 precursor cells and a variation of the glycogenome expression status in these cells. In particular, expression of genes involved in N-glycan synthesis or in the modeling of chondroitin and heparan sulfate proteoglycans appeared to be modulated. Our results highlight that, the expression of glycosylation-related genes is regulated during bioaminergic neuronal differentiation, consistent with a participation of glycoconjugates in neuronal development and plasticity. A neuronal regulation of glycosylation processes may have direct implications on some neurospecific functions of PrP^C and may participate in specific brain targeting of prion strains. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Disease-associated Mutations in the Prion Protein Impair Laminin-induced Process Outgrowth and Survival

Prions, the agents of transmissible spongiform encephalopathies, require the expression of prion protein (PrP^C) to propagate disease. PrP^C is converted into an abnormal insoluble form, PrP^Sc, that gains neurotoxic activity. Conversely, clinical manifestations of prion disease may occur either before or in the absence of PrP^Sc deposits, but the loss of normal PrP^C function contribution for the etiology of these diseases is still debatable. Prion disease-associated mutations in PrP^C represent one of the best models to understand the impact of PrP^C loss-of-function. PrP^C associates with various molecules and, in particular, the interaction of PrP^C with laminin (Ln) modulates neuronal plasticity and memory formation. To assess the functional alterations associated with PrP^C mutations, wild-type and mutated PrP^C proteins were expressed in a neural cell line derived from a PrP^C-null mouse. Treatment with the laminin γ1 chain peptide (Ln γ1), which mimics the Ln binding site for PrP^C, increased intracellular calcium in cells expressing wild-type PrP^C, whereas a significantly lower response was observed in cells expressing mutated PrP^C molecules. The Ln γ1 did not promote process outgrowth or protect against staurosporine-induced cell death in cells expressing mutated PrP^C molecules in contrast to cells expressing wild-type PrP^C. The co-expression of wild-type PrP^C with mutated PrP^C molecules was able to rescue the Ln protective effects, indicating the lack of negative dominance of PrP^C mutated molecules. These results indicate that PrP^C mutations impair process outgrowth and survival mediated by Ln γ1 peptide in neural cells, which may contribute to the pathogenesis of genetic prion diseases.     

Role of α7 Nicotinic Acetylcholine Receptor in Calcium Signaling Induced by Prion Protein Interaction with Stress-inducible Protein 1

The prion protein (PrP^C) is a conserved glycosylphosphatidylinositol-anchored cell surface protein expressed by neurons and other cells. Stress-inducible protein 1 (STI1) binds PrP^C extracellularly, and this activated signaling complex promotes neuronal differentiation and neuroprotection via the extracellular signal-regulated kinase 1 and 2 (ERK1/2) and cAMP-dependent protein kinase 1 (PKA) pathways. However, the mechanism by which the PrP^C-STI1 interaction transduces extracellular signals to the intracellular environment is unknown. We found that in hippocampal neurons, STI1-PrP^C engagement induces an increase in intracellular Ca²⁺ levels. This effect was not detected in PrP^C-null neurons or wild-type neurons treated with an STI1 mutant unable to bind PrP^C. Using a best candidate approach to test for potential channels involved in Ca²⁺ influx evoked by STI1-PrP^C, we found that α-bungarotoxin, a specific inhibitor for α7 nicotinic acetylcholine receptor (α7nAChR), was able to block PrP^C-STI1-mediated signaling, neuroprotection, and neuritogenesis. Importantly, when α7nAChR was transfected into HEK 293 cells, it formed a functional complex with PrP^C and allowed reconstitution of signaling by PrP^C-STI1 interaction. These results indicate that STI1 can interact with the PrP^C·α7nAChR complex to promote signaling and provide a novel potential target for modulation of the effects of prion protein in neurodegenerative diseases.     

Insoluble cellular prion protein and its association with prion and Alzheimer diseases

The soluble cellular prion protein (PrP^C) is best known for its association with prion disease (PrD) through its conversion to a pathogenic insoluble isoform (PrP^Sc). However, its deleterious effects independent of PrP^Sc have recently been observed not only in PrD but also in Alzheimer disease (AD), two diseases which mainly affect cognition. At the same time, PrP^C itself seems to have broad physiologic functions including involvement in cognitive processes. The PrP^C that is believed to be soluble and monomeric has so far been the only PrP conformer observed in the uninfected brain. In 2006, we identified an insoluble PrP^C conformer (termed iPrP^C) in uninfected human and animal brains. Remarkably, the PrP^Sc-like iPrP^C shares the immunoreactivity behavior and fragmentation with a newly-identified PrP^Sc species in a novel human PrD termed variably protease-sensitive prionopathy. Moreover, iPrP^C has been observed as the major PrP species that interacts with amyloid β (Aβ) in AD. This article highlights evidence of PrP involvement in two putatively beneficial and deleterious PrP-implicated pathways in cognition and hypothesizes first, that beneficial and deleterious effects of PrP^C are attributable to the chameleon-like conformation of the protein and second, that the iPrP^C conformer is associated with PrD and AD.Key words: prion protein, prion disease, cognition, cognitive deficit, insoluble prion protein, Alzheimer disease, variably protease-sensitive prionopathy, dementia, memory     

A Visual Dual-Aptamer Logic Gate for Sensitive Discrimination of Prion Diseases-Associated Isoform with Reusable Magnetic Microparticles and Fluorescence Quantum Dots

Molecular logic gates, which have attracted increasing research interest and are crucial for the development of molecular-scale computers, simplify the results of measurements and detections, leaving the diagnosis of disease either “yes” or “no”. Prion diseases are a group of fatal neurodegenerative disorders that happen in human and animals. The main problem with a diagnosis of prion diseases is how to sensitively and selectively discriminate and detection of the minute amount of PrP^Res in biological samples. Our previous work had demonstrated that dual-aptamer strategy could achieve highly sensitive and selective discrimination and detection of prion protein (cellular prion protein, PrP^C, and the diseases associated isoform, PrP^Res) in serum and brain. Inspired by the advantages of molecular logic gate, we further conceived a new concept for dual-aptamer logic gate that responds to two chemical input signals (PrP^C or PrP^Res and Gdn-HCl) and generates a change in fluorescence intensity as the output signal. It was found that PrP^Res performs the “OR” logic operation while PrP^C performs “XOR” logic operation when they get through the gate consisted of aptamer modified reusable magnetic microparticles (MMPs-Apt1) and quantum dots (QDs-Apt2). The dual-aptamer logic gate simplifies the discrimination results of PrP^Res, leaving the detection of PrP^Res either “yes” or “no”. The development of OR logic gate based on dual-aptamer strategy and two chemical input signals (PrP^Res and Gdn-HCl) is an important step toward the design of prion diseases diagnosis and therapy systems.     

The P’s and Q’s of cellular PrP-Aβ interactions

Prion disease research has opened up the “black-box” of neurodegeneration, defining a key role for protein misfolding wherein a predominantly alpha-helical precursor protein, PrP^C, is converted to a disease-associated, β-sheet enriched isoform called PrP^Sc. In Alzheimer disease (AD) the Aβ peptide derived from the β-amyloid precuror protein APP folds in β-sheet amyloid. Early thoughts along the lines of overlap may have been on target,¹ but were eclipsed by a simultaneous (but now anachronistic) controversy over the role of PrP^Sc in prion diseases.^2,3 Nonetheless, as prion diseases such as Creutzfeldt-Jakob Disease (CJD) are themselves rare and can include an overt infectious mode of transmission, and as familial prion diseases and familial AD involve different genes, an observer might reasonably have concluded that prion research could occasionally catalyze ideas in AD, but could never provide concrete overlaps at the mechanistic level. Surprisingly, albeit a decade or three down the road, several prion/AD commonalities can be found within the contemporary literature. One important prion/AD overlap concerns seeded spread of Aβ aggregates by intracerebral inoculation much like prions,⁴ and, with a neuron-to-neuron ‘spreading’ also reported for pathologic forms of other misfolded proteins, Tau^5,6 and α-synuclein in the case of Parkinson Disease.^7,8 The concept of seeded spread has been discussed extensively elsewhere, sometimes under the rubric of “prionoids”⁹, and lies outside the scope of this particular review where we will focus upon PrP^C. From this point the story can now be subdivided into four strands of investigation: (1) pathologic effects of Aβ can be mediated by binding to PrP^C,¹⁰ (2) the positioning of endoproteolytic processing events of APP by pathologic (β-cleavage + γ-cleavage) and non-pathologic (α-cleavage + γ-cleavage) secretase pathways is paralleled by seemingly analogous α- and β-like cleavage of PrP^C (Fig. 1) (3) similar lipid raft environments for PrP^C and APP processing machinery,^11-13 and perhaps in consequence, overlaps in repertoire of the PrP^C and APP protein interactors (“interactomes”),^14,15 and (4) rare kindreds with mixed AD and prion pathologies.¹⁶ Here we discuss confounds, consensus and conflict associated with parameters that apply to these experimental settings.     

Lipopolysaccharide induced conversion of recombinant prion protein

The conformational conversion of the cellular prion protein (PrP^C) to the β-rich infectious isoform PrP^Sc is considered a critical and central feature in prion pathology. Although PrP^Sc is the critical component of the infectious agent, as proposed in the “protein-only” prion hypothesis, cellular components have been identified as important cofactors in triggering and enhancing the conversion of PrP^C to proteinase K resistant PrP^Sc. A number of in vitro systems using various chemical and/or physical agents such as guanidine hydrochloride, urea, SDS, high temperature, and low pH, have been developed that cause PrP^C conversion, their amplification, and amyloid fibril formation often under non-physiological conditions. In our ongoing efforts to look for endogenous and exogenous chemical mediators that might initiate, influence, or result in the natural conversion of PrP^C to PrP^Sc, we discovered that lipopolysaccharide (LPS), a component of gram-negative bacterial membranes interacts with recombinant prion proteins and induces conversion to an isoform richer in β sheet at near physiological conditions as long as the LPS concentration remains above the critical micelle concentration (CMC). More significant was the LPS mediated conversion that was observed even at sub-molar ratios of LPS to recombinant ShPrP (90–232).     

Unaltered prion protein expression in Alzheimer disease patients

The suggested role of cellular prion protein (PrP^C) in mediating the toxic effects of oligomeric amyloid β peptide (Aβ) in Alzheimer disease (AD) is controversial. To address the hypothesis that variable PrP^C expression is involved in AD pathogenesis, we analyzed PrP^C expression in the frontal and temporal cortices and hippocampus of individuals with no cognitive impairment (NCI), amnestic mild cognitive impairment (aMCI), mild AD (mAD) and AD. We found that PrP^C expression in all brain regions was not significantly altered among the various patient groups. In addition, PrP^C levels in all groups did not correlate with expression of methionine (M) or valine (V) at codon 129 of the PrP gene, a polymorphism that has been linked in some studies to increased risk for AD, and which occurs in close proximity to the proposed binding region for the oligomeric Aβ peptide. Our results indicate that, if PrP^C is involved in mediating the toxic effects of the oligomeric Aβ peptide, these effects occur independently of steady state levels of PrP or the codon 129 polymorphism.Key words: prion protein, PrP codon 129 polymorphism, Alzheimer disease, oligomeric Aβ, Alzheimer precursor protein     

Inhibition of the FKBP family of peptidyl prolyl isomerases induces abortive translocation and degradation of the cellular prion protein

Prion diseases are fatal neurodegenerative disorders for which there is no effective treatment. Because the cellular prion protein (PrP^C) is required for propagation of the infectious scrapie form of the protein, one therapeutic strategy is to reduce PrP^C expression. Recently FK506, an inhibitor of the FKBP family of peptidyl prolyl isomerases, was shown to increase survival in animal models of prion disease, with proposed mechanisms including calcineurin inhibition, induction of autophagy, and reduced PrP^C expression. We show that FK506 treatment results in a profound reduction in PrP^C expression due to a defect in the translocation of PrP^C into the endoplasmic reticulum with subsequent degradation by the proteasome. These phenotypes could be bypassed by replacing the PrP^C signal sequence with that of prolactin or osteopontin. In mouse cells, depletion of ER luminal FKBP10 was almost as potent as FK506 in attenuating expression of PrP^C. However, this occurred at a later stage, after translocation of PrP^C into the ER. Both FK506 treatment and FKBP10 depletion were effective in reducing PrP^Sc propagation in cell models. These findings show the involvement of FKBP proteins at different stages of PrP^C biogenesis and identify FKBP10 as a potential therapeutic target for the treatment of prion diseases.     

Identification of a Compound That Disrupts Binding of Amyloid-β to the Prion Protein Using a Novel Fluorescence-based Assay

The prion protein (PrP) has been implicated both in prion diseases such as Creutzfeldt-Jakob disease, where its monomeric cellular isoform (PrP^C) is recruited into pathogenic self-propagating polymers of misfolded protein, and in Alzheimer disease, where PrP^C may act as a receptor for synaptotoxic oligomeric forms of amyloid-β (Aβ). There has been considerable interest in identification of compounds that bind to PrP^C, stabilizing its native fold and thereby acting as pharmacological chaperones to block prion propagation and pathogenesis. However, compounds binding PrP^C could also inhibit the binding of toxic Aβ species and may have a role in treating Alzheimer disease, a highly prevalent dementia for which there are currently no disease-modifying treatments. However, the absence of a unitary, readily measurable, physiological function of PrP makes screening for ligands challenging, and the highly heterogeneous nature of Aβ oligomer preparations makes conventional competition binding assays difficult to interpret. We have therefore developed a high-throughput screen that utilizes site-specifically fluorescently labeled protein to identify compounds that bind to PrP and inhibit both Aβ binding and prion propagation. Following a screen of 1,200 approved drugs, we identified Chicago Sky Blue 6B as the first small molecule PrP ligand capable of inhibiting Aβ binding, demonstrating the feasibility of development of drugs to block this interaction. The interaction of Chicago Sky Blue 6B was characterized by isothermal titration calorimetry, and its ability to inhibit Aβ binding and reduce prion levels was established in cell-based assays.     

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.     

Isolation of Soluble and Insoluble PrP Oligomers in the Normal Human Brain

The central event in the pathogenesis of prion diseases involves a conversion of the host-encoded cellular prion protein PrP^C into its pathogenic isoform PrP^{Sc 1}. PrP^C is detergent-soluble and sensitive to proteinase K (PK)-digestion, whereas PrP^Sc forms detergent-insoluble aggregates and is partially resistant to PK^2-6. The conversion of PrP^C to PrP^Sc is known to involve a conformational transition of α-helical to β-sheet structures of the protein. However, the in vivo pathway is still poorly understood. A tentative endogenous PrP^Sc, intermediate PrP* or "silent prion", has yet to be identified in the uninfected brain⁷.Using a combination of biophysical and biochemical approaches, we identified insoluble PrP^C aggregates (designated iPrP^C) from uninfected mammalian brains and cultured neuronal cells^{8, 9}. Here, we describe detailed procedures of these methods, including ultracentrifugation in detergent buffer, sucrose step gradient sedimentation, size exclusion chromatography, iPrP enrichment by gene 5 protein (g5p) that specifically bind to structurally altered PrP forms¹⁰, and PK-treatment. The combination of these approaches isolates not only insoluble PrP^Sc and PrP^C aggregates but also soluble PrP^C oligomers from the normal human brain. Since the protocols described here have been used to isolate both PrP^Sc from infected brains and iPrP^C from uninfected brains, they provide us with an opportunity to compare differences in physicochemical features, neurotoxicity, and infectivity between the two isoforms. Such a study will greatly improve our understanding of the infectious proteinaceous pathogens. The physiology and pathophysiology of iPrP^C are unclear at present. Notably, in a newly-identified human prion disease termed variably protease-sensitive prionopathy, we found a new PrP^Sc that shares the immunoreactive behavior and fragmentation with iPrP^{C 11, 12}. Moreover, we recently demonstrated that iPrP^C is the main species that interacts with amyloid-β protein in Alzheimer disease¹³. In the same study, these methods were used to isolate Abeta aggregates and oligomers in Alzheimer''s disease¹³, suggesting their application to non-prion protein aggregates involved in other neurodegenerative disorders.     

Comparison of the Anti-Prion Mechanism of Four Different Anti-Prion Compounds,Anti-PrP Monoclonal Antibody 44B1, Pentosan Polysulfate,Chlorpromazine, and U18666A,in Prion-Infected Mouse Neuroblastoma Cells

Molecules that inhibit the formation of an abnormal isoform of prion protein (PrP^Sc) in prion-infected cells are candidate therapeutic agents for prion diseases. Understanding how these molecules inhibit PrP^Sc formation provides logical basis for proper evaluation of their therapeutic potential. In this study, we extensively analyzed the effects of the anti-PrP monoclonal antibody (mAb) 44B1, pentosan polysulfate (PPS), chlorpromazine (CPZ) and U18666A on the intracellular dynamics of a cellular isoform of prion protein (PrP^C) and PrP^Sc in prion-infected mouse neuroblastoma cells to re-evaluate the effects of those agents. MAb 44B1 and PPS rapidly reduced PrP^Sc levels without altering intracellular distribution of PrP^Sc. PPS did not change the distribution and levels of PrP^C, whereas mAb 44B1 appeared to inhibit the trafficking of cell surface PrP^C to organelles in the endocytic-recycling pathway that are thought to be one of the sites for PrP^Sc formation. In contrast, CPZ and U18666A initiated the redistribution of PrP^Sc from organelles in the endocytic-recycling pathway to late endosomes/lysosomes without apparent changes in the distribution of PrP^C. The inhibition of lysosomal function by monensin or bafilomycin A1 after the occurrence of PrP^Sc redistribution by CPZ or U18666A partly antagonized PrP^Sc degradation, suggesting that the transfer of PrP^Sc to late endosomes/lysosomes, possibly via alteration of the membrane trafficking machinery of cells, leads to PrP^Sc degradation. This study revealed that precise analysis of the intracellular dynamics of PrP^C and PrP^Sc provides important information for understanding the mechanism of anti-prion agents.