Helix 3 is necessary and sufficient for prion protein's anti-Bax function

To identify the structural elements of the prion protein (PrP) necessary for its protective function against Bcl-2 associated protein X (Bax), we performed structure–function analyses of the anti-Bax function of cytosolic PrP (CyPrP) in MCF-7 cells. Deletions of 1, 2, or 3 N-terminal Bcl-2 homology domain 2-like octapeptide repeats (BORs), but not deletion of all four BORs, abolish CyPrPs anti-Bax function. Deletion of α-helix 3 (PrP23–199) or further C-terminal deletions of α-helix 1 and 2, and β-strand 1 and 2 (PrP23–172, PrP23–160, PrP23–143, and PrP23–127) eliminates CyPrPs protection against Bax-mediated cell death. The substitution of helix 3 amino acid residues K204, V210, and E219 by proline inhibits the anti-Bax function of CyPrP. The substitution of K204, but not V210 and E219, by alanine residues also prevents CyPrPs anti-Bax function. Expression of PrPs helix 3 displays anti-Bax activity in MCF-7 cells and in human neurons. Together, these results indicate that although the BOR domain has an influence on PrPs anti-Bax function, the helix 3 is necessary and sufficient for the anti-Bax function of CyPrP. Identification of helix 3 as the structural element for the anti-Bax function thus provides a molecular target to modulate PrPs anti-Bax function in cancer and neurodegeneration.     

Mammalian prion protein suppresses Bax-induced cell death in yeast

Several lines of evidence suggest that PrP(C), the non-infectious form of the prion protein, may function to protect neurons and other cells from stress or toxicity. In this paper, we report on the use of the yeast Saccharomyces cerevisiae as a model system to assay the cytoprotective activity of PrP(C). The mammalian pro-apoptotic protein, Bax, confers a lethal phenotype when expressed in yeast. Since overexpression of PrP(C) has been found to prevent Bax-mediated cell death in cultured human neurons, we explored whether PrP could also suppress Bax-induced cell death in yeast. We utilized a form of mouse PrP containing a modified signal peptide that we had previously shown is efficiently targeted to the secretory pathway in yeast. We found that this PrP potently suppressed the death of yeast cells expressing mammalian Bax under control of a galactose-inducible promoter. In contrast, cytosolic PrP-(23-231) failed to rescue growth of Bax-expressing yeast, indicating that protective activity requires targeting of PrP to the secretory pathway. Deletion of the octapeptide repeat region did not affect the rescuing activity of PrP, but deletion of a charged region encompassing residues 23-31 partially eliminated activity. We also tested several PrP mutants associated with human familial prion diseases and found that only a mutant containing nine extra octapeptide repeats failed to suppress Bax-induced cell death. These findings establish a simple and genetically tractable system for assaying a putative biological activity of PrP(C).     

Loss of Anti-Bax Function in Gerstmann-Str?ussler-Scheinker Syndrome-Associated Prion Protein Mutants

Previously, we have shown the loss of anti-Bax function in Creutzfeldt Jakob disease (CJD)-associated prion protein (PrP) mutants that are unable to generate cytosolic PrP (CyPrP). To determine if the anti-Bax function of PrP modulates the manifestation of prion diseases, we further investigated the anti-Bax function of eight familial Gerstmann-Sträussler-Scheinker Syndrome (GSS)-associated PrP mutants. These PrP mutants contained their respective methionine (^M) or valine (^V) at codon 129. All of the mutants lost their ability to prevent Bax-mediated chromatin condensation or DNA fragmentation in primary human neurons. In the breast carcinoma MCF-7 cells, the F198S^V, D202N^V, P102L^V and Q217R^V retained, whereas the P102L^M, P105L^V, Y145stop^M and Q212P^M PrP mutants lost their ability to inhibit Bax-mediated condensed chromatin. The inhibition of Bax-mediated condensed chromatin depended on the ability of the mutants to generate cytosolic PrP. However, except for the P102L^V, none of the mutants significantly inhibited Bax-mediated caspase activation. These results show that the cytosolic PrP generated from the GSS mutants is not as efficient as wild type PrP in inhibiting Bax-mediated cell death. Furthermore, these results indicate that the anti-Bax function is also disrupted in GSS-associated PrP mutants and is not associated with the difference between CJD and GSS.     

Crossreaction with an anti-Bax antibody reveals novel multi-endocrine cellular antigen.

We found a novel protein that has crossreactivity with a polyclonal anti-Bax antibody (SCBAX antibody). The protein was localized exclusively in the endocrine cells of hypothalamus, pituitary gland, and pancreatic islets. Immunohistochemical (IHC) double labeling revealed that the cells showing crossreactivity with this antibody corresponded precisely to oxytocin neurons and ACTH, alpha-MSH, and glucagon cells in rat and gerbil. By immunoelectron microscopy, the protein was localized predominantly in and just around the secretory granules in the cytoplasm but not in the mitochondria. Double-labeling IHC with the anti-Bax SCBAX antibody and two anti-Bax monoclonal antibodies (MAbs) showed that cells stained with the anti-Bax SCBAX antibody were not stained with anti-Bax MAbs except for very few cells (probably apoptotic cells). Western blotting analysis revealed that the molecular mass of the protein was approximately 55 kD, which differs from that of Bax protein (21 kD). These findings indicate that the anti-Bax SCBAX antibody recognizes not only pro-apoptotic Bax protein (a 21-kD mitochondrial protein) but also an unknown substance present in one endocrine cell group in each endocrine organ. Therefore, the protein is designated as multi-endocrine cellular antigen (MECA). MECA is probably a 55-kD protein secreted from the particular differentiated cell groups of endocrine tissues.     

Cytosolic prion protein is not toxic and protects against Bax-mediated cell death in human primary neurons

Recently, it was observed that reverse-translocated cytosolic PrP and PrP expressed in the cytosol induce rapid death in neurons (Ma, J., Wollmann, R., and Lindquist, S. (2002) Science 298, 1781-1785). In this study, we investigated whether accumulation of prion protein (PrP) in the cytosol is toxic to human neurons in primary culture. We show that in these neurons, a single PrP isoform lacking signal peptide accumulates in the cytosol of neurons treated with epoxomicin, a specific proteasome inhibitor. Therefore, endogenously expressed PrP is subject to the endoplasmic reticulum-associated degradation (ERAD) pathway and is degraded by the proteasome in human primary neurons. In contrast to its toxicity in N2a cells, reverse-translocated PrP (ERAD-PrP) is not toxic even when neurons are microinjected with cDNA constructs to overexpress either wild-type PrP or mutant PrPD178N. We found that ERAD-PrP in human neurons remains detergent-soluble and proteinase K-sensitive, in contrast to its detergent-insoluble and proteinase K-resistant state in N2a cells. Furthermore, not only is microinjection of a cDNA construct expressing CyPrP not toxic, it protects these neurons against Bax-mediated cell death. We conclude that in human neurons, ERAD-PrP is not converted naturally into a form reminiscent of scrapie PrP and that PrP located in the cytosol retains its protective function against Bax. Thus, it is unlikely that simple accumulation of PrP in the cytosol can cause neurodegeneration in prion diseases.     

The N-terminal, polybasic region is critical for prion protein neuroprotective activity

Several lines of evidence suggest that the normal form of the prion protein, PrP(C), exerts a neuroprotective activity against cellular stress or toxicity. One of the clearest examples of such activity is the ability of wild-type PrP(C) to suppress the spontaneous neurodegenerative phenotype of transgenic mice expressing a deleted form of PrP (Δ32-134, called F35). To define domains of PrP involved in its neuroprotective activity, we have analyzed the ability of several deletion mutants of PrP (Δ23-31, Δ23-111, and Δ23-134) to rescue the phenotype of Tg(F35) mice. Surprisingly, all of these mutants displayed greatly diminished rescue activity, although Δ23-31 PrP partially suppressed neuronal loss when expressed at very high levels. Our results pinpoint the N-terminal, polybasic domain as a critical determinant of PrP(C) neuroprotective activity, and suggest that identification of molecules interacting with this region will provide important clues regarding the normal function of the protein. Small molecule ligands targeting this region may also represent useful therapeutic agents for treatment of prion diseases.     

Cell type-specific neuroprotective activity of untranslocated prion protein

Background

A key pathogenic role in prion diseases was proposed for a cytosolic form of the prion protein (PrP). However, it is not clear how cytosolic PrP localization influences neuronal viability, with either cytotoxic or anti-apoptotic effects reported in different studies. The cellular mechanism by which PrP is delivered to the cytosol of neurons is also debated, and either retrograde transport from the endoplasmic reticulum or inefficient translocation during biosynthesis has been proposed. We investigated cytosolic PrP biogenesis and effect on cell viability in primary neuronal cultures from different mouse brain regions.

Principal Findings

Mild proteasome inhibition induced accumulation of an untranslocated form of cytosolic PrP in cortical and hippocampal cells, but not in cerebellar granules. A cyclopeptolide that interferes with the correct insertion of the PrP signal sequence into the translocon increased the amount of untranslocated PrP in cortical and hippocampal cells, and induced its synthesis in cerebellar neurons. Untranslocated PrP boosted the resistance of cortical and hippocampal neurons to apoptotic insults but had no effect on cerebellar cells.

Significance

These results indicate cell type-dependent differences in the efficiency of PrP translocation, and argue that cytosolic PrP targeting might serve a physiological neuroprotective function.     

Protection from cytosolic prion protein toxicity by modulation of protein translocation

Failure to promptly dispose of undesirable proteins is associated with numerous diseases. In the case of cellular prion protein (PrP), inhibition of the proteasome pathway can generate a highly aggregation-prone, cytotoxic form of PrP implicated in neurodegeneration. However, the predominant mechanisms that result in delivery of PrP, ordinarily targeted to the secretory pathway, to cytosolic proteasomes have been unclear. By accurately measuring the in vivo fidelity of protein translocation into the endoplasmic reticulum (ER), we reveal a slight inefficiency in PrP signal sequence function that generates proteasomally degraded cytosolic PrP. Attenuating this source of cytosolic PrP completely eliminates the dependence on proteasomes for PrP degradation. This allows cells to tolerate both higher expression levels and decreased proteasomal capacity without succumbing to the adverse consequences of misfolded PrP. Thus, the generation of potentially toxic cytosolic PrP is controlled primarily during its initial translocation into the ER. These results suggest that a substantial proportion of the cell's constitutive proteasomal burden may consist of proteins that, like PrP, fail to cotranslationally enter the secretory pathway with high fidelity.     

Mutational analysis of topological determinants in prion protein (PrP) and measurement of transmembrane and cytosolic PrP during prion infection

The prion protein (PrP) can adopt multiple membrane topologies, including a fully translocated form (SecPrP), two transmembrane forms (NtmPrP and CtmPrP), and a cytosolic form. It is important to understand the factors that influence production of these species, because two of them, CtmPrP and cytosolic PrP, have been proposed to be key neurotoxic intermediates in certain prion diseases. In this paper, we perform a mutational analysis of PrP synthesized using an in vitro translation system in order to further define sequence elements that influence the formation of CtmPrP. We find that substitution of charged residues in the hydrophobic core of the signal peptide increases synthesis of CtmPrP and also reduces the efficiency of translocation into microsomes. Combining these mutations with substitutions in the transmembrane domain causes the protein to be synthesized exclusively with the CtmPrP topology. Reducing the spacing between the signal peptide and the transmembrane domain also increases CtmPrP. In contrast, topology is not altered by mutations that prevent signal peptide cleavage or by deletion of the C-terminal signal for glycosylphosphatidylinositol anchor addition. Removal of the signal peptide completely blocks translocation. Taken together, our results are consistent with a model in which the signal peptide and transmembrane domain function in distinct ways as determinants of PrP topology. We also present characterization of an antibody that selectively recognizes CtmPrP and cytosolic PrP by virtue of their uncleaved signal peptides. By using this antibody, as well as the distinctive gel mobility of CtmPrP and cytosolic PrP, we show that the amounts of these two forms in cultured cells and rodent brain are not altered by infection with scrapie prions. We conclude that CtmPrP and cytosolic PrP are unlikely to be obligate neurotoxic intermediates in familial or infectiously acquired prion diseases.     

Ion channels induced by the prion protein

Prion diseases comprise a group of rapidly progressive and invariably fatal neurodegenerative disorders for which there are no effective treatments. While conversion of the cellular prion protein (PrP^C) to a β-sheet rich isoform (PrP^Sc) is known to be a critical event in propagation of infectious prions, the identity of the neurotoxic form of PrP and its mechanism of action remain unclear. Insights into this mechanism have been provided by studying PrP molecules harboring deletions and point mutations in the conserved central region, encompassing residues 105–125. When expressed in transgenic mice, PrP deleted for these residues (Δ105–125) causes a spontaneous neurodegenerative illness that is reversed by co-expression of wild-type PrP. In cultured cells, Δ105–125 PrP confers hypersensitivity to certain cationic antibiotics and induces spontaneous ion channel activity that can be recorded by electrophysiological techniques. We have utilized these drug-hypersensitization and current-inducing activities to identify which PrP domains and subcellular locations are required for toxicity. We present an ion channel model for the toxicity of Δ105–125 PrP and related mutants and speculate how a similar mechanism could mediate PrP^Sc-associated toxicity. Therapeutic regimens designed to inhibit prion-induced toxicity, as well as formation of PrP^Sc, may prove to be the most clinically beneficial.     

The cellular prion protein colocalizes with the dystroglycan complex in the brain

The function of PrP(C), the cellular prion protein (PrP), is still unknown. Like other glycophosphatidylinositol-anchored proteins, PrP resides on Triton-insoluble, cholesterol-rich membranous microdomains, termed rafts. We have recently shown that the activity and subcellular localization of the neuronal isoform of nitric oxide synthase (nNOS) are impaired in adult PrP(0/0) mice as well as in scrapie-infected mice. In this study, we sought to determine whether PrP and nNOS are part of the same functional complex and, if so, to identify additional components of such a complex. To this aim, we looked for proteins that coimmunoprecipitated with PrP in the presence of detergents either that completely dissociate rafts, to identify stronger interactions, or that preserve the raft structure, to identify weaker interactions. Using this detergent-dependent immunoprecipitation protocol we found that PrP interacts strongly with dystroglycan, a transmembrane protein that is the core of the dystrophin-glycoprotein complex (DGC). Additional results suggest that PrP also interacts with additional members of the DGC, including nNOS. PrP coprecipitated only with established presynaptic proteins, consistent with recent findings suggesting that PrP is a presynaptic protein.     

Compartment-restricted biotinylation reveals novel features of prion protein metabolism in vivo

Proteins are often made in more than one form, with alternate versions sometimes residing in different cellular compartments than the primary species. The mammalian prion protein (PrP), a cell surface GPI-anchored protein, is a particularly noteworthy example for which minor cytosolic and transmembrane forms have been implicated in disease pathogenesis. To study these minor species, we used a selective labeling strategy in which spatially restricted expression of a biotinylating enzyme was combined with asymmetric engineering of the cognate acceptor sequence into PrP. Using this method, we could show that even wild-type PrP generates small amounts of the (Ctm)PrP transmembrane form. Selective detection of (Ctm)PrP allowed us to reveal its N-terminal processing, long half-life, residence in both intracellular and cell surface locations, and eventual degradation in the lysosome. Surprisingly, some human disease-causing mutants in PrP selectively stabilized (Ctm)PrP, revealing a previously unanticipated mechanism of (Ctm)PrP up-regulation that may contribute to disease. Thus, spatiotemporal tagging has uncovered novel aspects of normal and mutant PrP metabolism and should be readily applicable to the analysis of minor topologic isoforms of other proteins.     

A transmembrane form of the prion protein is localized in the Golgi apparatus of neurons

(Ctm)PrP is a transmembrane version of the prion protein that has been proposed to be a neurotoxic intermediate underlying prion-induced pathogenesis. In previous studies, we found that PrP molecules carrying mutations in the N-terminal signal peptide (L9R) and the transmembrane domain (3AV) were synthesized exclusively in the (Ctm)PrP form in transfected cell lines. To characterize the properties of (Ctm)PrP in a neuronal setting, we have utilized cerebellar granule neurons cultured from Tg(L9R-3AV) mice that developed a fatal neurodegenerative illness. We found that about half of the L9R-3AV PrP synthesized in these neurons represents (Ctm)PrP, with the rest being (Sec)PrP, the glycolipid anchored form that does not span the membrane. Both forms contained an uncleaved signal peptide, and they are differentially glycosylated. (Sec)PrP was localized on the surface of neuronal processes. Most surprisingly, (Ctm)PrP was concentrated in the Golgi apparatus, rather in the endoplasmic reticulum as it is in transfected cell lines. Our study is the first to analyze the properties of (Ctm)PrP in a neuronal context, and our results suggest new hypotheses about how this form may exert its neurotoxic effects.     

Stress-protective signalling of prion protein is corrupted by scrapie prions

Studies in transgenic mice revealed that neurodegeneration induced by scrapie prion (PrP(Sc)) propagation is dependent on neuronal expression of the cellular prion protein PrP(C). On the other hand, there is evidence that PrP(C) itself has a stress-protective activity. Here, we show that the toxic activity of PrP(Sc) and the protective activity of PrP(C) are interconnected. With a novel co-cultivation assay, we demonstrate that PrP(Sc) can induce apoptotic signalling in PrP(C)-expressing cells. However, cells expressing PrP mutants with an impaired stress-protective activity were resistant to PrP(Sc)-induced toxicity. We also show that the internal hydrophobic domain promotes dimer formation of PrP and that dimerization of PrP is linked to its stress-protective activity. PrP mutants defective in dimer formation did not confer enhanced stress tolerance. Moreover, in chronically scrapie-infected neuroblastoma cells the amount of PrP(C) dimers inversely correlated with the amount of PrP(Sc) and the resistance of the cells to various stress conditions. Our results provide new insight into the mechanism of PrP(C)-mediated neuroprotection and indicate that pathological PrP conformers abuse PrP(C)-dependent pathways for apoptotic signalling.     

Scrapie-like prion protein accumulates in aggresomes of cyclosporin A-treated cells

Prion diseases are infectious, sporadic and inherited fatal neurodegenerations that are propagated by an abnormal refolding of the cellular prion protein PrP(C). Which chaperones assist the normal folding of PrP(C) is unknown. The linkage of familial Gerstmann- Str?ussler-Scheinker (GSS) syndrome with proline substitutions in PrP raised the prospect that peptidylprolyl cis-trans isomerases (PPIases) may play a role in normal PrP metabolism. Here we used cyclo sporin A (CsA), an immunosuppressant, to inhibit the cyclophilin family of PPIases in cultured cells. CsA-treated cells accumulated proteasome-resistant, 'prion-like' PrP species, which deposited in long-lived aggresomes. PrP aggresomes also formed with disease-linked proline mutants when proteasomes were inhibited. These results suggest mechanisms whereby abnormally folded cytosolic PrP may in some cases participate in the development of spontaneous and inherited prion diseases.     

The toxicity of a mutant prion protein is cell-autonomous, and can be suppressed by wild-type prion protein on adjacent cells

Insight into the normal function of PrP(C), and how it can be subverted to produce neurotoxic effects, is provided by PrP molecules carrying deletions encompassing the conserved central region. The most neurotoxic of these mutants, Δ105-125 (called ΔCR), produces a spontaneous neurodegenerative illness when expressed in transgenic mice, and this phenotype can be dose-dependently suppressed by co-expression of wild-type PrP. Whether the toxic activity of ΔCR PrP and the protective activity or wild-type PrP are cell-autonomous, or can be exerted on neighboring cells, is unknown. To investigate this question, we have utilized co-cultures of differentiated neural stem cells derived from mice expressing ΔCR or wild-type PrP. Cells from the two kinds of mice, which are marked by the presence or absence of GFP, are differentiated together to yield neurons, astrocytes, and oligodendrocytes. As a surrogate read-out of ΔCR PrP toxicity, we assayed sensitivity of the cells to the cationic antibiotic, Zeocin. In a previous study, we reported that cells expressing ΔCR PrP are hypersensitive to the toxic effects of several cationic antibiotics, an effect that is suppressed by co-expression of wild type PrP, similar to the rescue of the neurodegenerative phenotype observed in transgenic mice. Using this system, we find that while ΔCR-dependent toxicity is cell-autonomous, the rescuing activity of wild-type PrP can be exerted in trans from nearby cells. These results provide important insights into how ΔCR PrP subverts a normal physiological function of PrP(C), and the cellular mechanisms underlying the rescuing process.     

Association of Bcl-2 with misfolded prion protein is linked to the toxic potential of cytosolic PrP

Protein misfolding is linked to different neurodegenerative disorders like Alzheimer's disease, polyglutamine, and prion diseases. We investigated the cytotoxic effects of aberrant conformers of the prion protein (PrP) and show that toxicity is specifically linked to misfolding of PrP in the cytosolic compartment and involves binding of PrP to the anti-apoptotic protein Bcl-2. PrP targeted to different cellular compartments, including the cytosol, nucleus, and mitochondria, adopted a misfolded and partially proteinase K-resistant conformation. However, only in the cytosol did the accumulation of misfolded PrP induce apoptosis. Apoptotic cell death was also induced by two pathogenic mutants of PrP, which are partially localized in the cytosol. A mechanistic analysis revealed that the toxic potential is linked to an internal domain of PrP (amino acids 115-156) and involves coaggregation of cytosolic PrP with Bcl-2. Increased expression of the chaperones Hsp70 and Hsp40 prevented the formation of PrP/Bcl-2 coaggregates and interfered with PrP-induced apoptosis. Our study reveals a compartment-specific toxicity of PrP misfolding that involves coaggregation of Bcl-2 and indicates a protective role of molecular chaperones.     

Cytosolic Bax: DOES IT REQUIRE BINDING PROTEINS TO KEEP ITS PRO-APOPTOTIC ACTIVITY IN CHECK?*

Bax is kept inactive in the cytosol by refolding its C-terminal transmembrane domain into the hydrophobic binding pocket. Although energetic calculations predicted this conformation to be stable, numerous Bax binding proteins were reported and suggested to further stabilize inactive Bax. Unfortunately, most of them have not been validated in a physiological context on the endogenous level. Here we use gel filtration analysis of the cytosol of primary and established cells to show that endogenous, inactive Bax runs 20-30 kDa higher than recombinant Bax, suggesting Bax dimerization or the binding of a small protein. Dimerization was excluded by a lack of interaction of differentially tagged Bax proteins and by comparing the sizes of dimerized recombinant Bax with cytosolic Bax on blue native gels. Surprisingly, when analyzing cytosolic Bax complexes by high sensitivity mass spectrometry after anti-Bax immunoprecipitation or consecutive purification by gel filtration and blue native gel electrophoresis, we detected only one protein, called p23 hsp90 co-chaperone, which consistently and specifically co-purified with Bax. However, this protein could not be validated as a crucial inhibitory Bax binding partner as its over- or underexpression did not show any apoptosis defects. By contrast, cytosolic Bax exhibits a slight molecular mass shift on SDS-PAGE as compared with recombinant Bax, which suggests a posttranslational modification and/or a structural difference between the two proteins. We propose that in most healthy cells, cytosolic endogenous Bax is a monomeric protein that does not necessarily need a binding partner to keep its pro-apoptotic activity in check.     

Genetic mapping of activity determinants within cellular prion proteins: N-terminal modules in PrPC offset pro-apoptotic activity of the Doppel helix B/B' region

The PrP-like Doppel (Dpl) protein causes apoptotic death of cerebellar neurons in transgenic mice, a process prevented by expression of the wild type (wt) cellular prion protein, PrP(C). Internally deleted forms of PrP(C) resembling Dpl such as PrPDelta32-121 produce a similar PrP(C)-sensitive pro-apoptotic phenotype in transgenic mice. Here we demonstrate that these phenotypic attributes of wt Dpl, wt PrP(C), and PrPDelta132-121 can be accurately recapitulated by transfected mouse cerebellar granule cell cultures. This system was then explored by mutagenesis of the co-expressed prion proteins to reveal functional determinants. By this means, neuroprotective activity of wt PrP(C) was shown to be nullified by a deletion of the N-terminal charged region implicated in endocytosis and retrograde axonal transport (PrPDelta23-28), by deletion of all five octarepeats (PrPDelta51-90), or by glycine replacement of four octarepeat histidine residues required for selective binding of copper ions (Prnp"H/G"). In the case of Dpl, overlapping deletions defined a requirement for the gene interval encoding helices B and B' (DplDelta101-125). These data suggest contributions of copper binding and neuronal trafficking to wt PrP(C) function in vivo and place constraints upon current hypotheses to explain Dpl/PrP(C) antagonism by competitive ligand binding. Further implementation of this assay should provide a fuller understanding of the attributes and subcellular localizations required for activity of these enigmatic proteins.     

Cytosolic prion protein toxicity is independent of cellular prion protein expression and prion propagation

Prion diseases are transmissible neurodegenerative diseases caused by a conformational isoform of the prion protein (PrP), a host-encoded cell surface sialoglycoprotein. Recent evidence suggests a cytosolic fraction of PrP (cyPrP) functions either as an initiating factor or toxic element of prion disease. When expressed in cultured cells, cyPrP acquires properties of the infectious conformation of PrP (PrP(Sc)), including insolubility, protease resistance, aggregation, and toxicity. Transgenic mice (2D1 and 1D4 lines) that coexpress cyPrP and PrP(C) exhibit focal cerebellar atrophy, scratching behavior, and gait abnormalities suggestive of prion disease, although they lack protease-resistant PrP. To determine if the coexpression of PrP(C) is necessary or inhibitory to the phenotype of these mice, we crossed Tg1D4(Prnp(+/+)) mice with PrP-ablated mice (TgPrnp(o/o)) to generate Tg1D4(Prnp(o/o)) mice and followed the development of disease and pathological phenotype. We found no difference in the onset of symptoms or the clinical or pathological phenotype of disease between Tg1D4(Prnp(+/+)) and Tg1D4(Prnp(o/o)) mice, suggesting that cyPrP and PrP(C) function independently in the disease state. Additionally, Tg1D4(Prnp(o/o)) mice were resistant to challenge with mouse-adapted scrapie (RML), suggesting cyPrP is inaccessible to PrP(Sc). We conclude that disease phenotype and cellular toxicity associated with the expression of cyPrP are independent of PrP(C) and the generation of typical prion disease.