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

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

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 ␥1 chain peptide (Ln ␥1), 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 ␥1 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 ␥1 peptide in neural cells, which may contribute to the pathogenesis of genetic prion diseases.
The cellular prion protein (PrP C ) is a glycosylphosphatidylinositol-anchored protein whose conformationally modified isoform, PrP Sc , is the major component of prions. Prions may be defined as infectious agents that cause the neurodegenerative diseases known as transmissible spongiform encephalopathies (TSEs) 3 or prion diseases. These illnesses affect humans and other mammals and present sporadic, genetic, or infectious forms (1). The accumulation of the toxic, insoluble PrP Sc has been described to be the most likely event responsible for neuronal death in prion diseases (2). This idea is supported by the findings that deletion of PrP C or its knockdown in early stages of the disease reverted spongiosis, neuron loss, and cognitive and behavioral deficits as well as impaired neurophysiological function in mice (3)(4)(5).
On the other hand, neuronal loss may be observed even in the absence of characteristic PrP Sc deposits in sporadic, genetic, and iatrogenic forms of prion diseases (6 -8). Small, punctate synaptic deposits of PrP Sc correlate with neuronal loss, whereas the larger, focal types of deposits show an inverse correlation with neuronal counts (9). These findings could be related to the generation of oligomers of low molecular weight, present in brains of sporadic Creutzfeldt-Jakob (CJD) disease patients, that control the progression rate of the disease (10). Remarkably, neurotoxicity was associated not only with PrP C interaction with PrP Sc but also with other ␤-sheet-rich conformers of different origin in which toxicity was independent of prions replication (11). Whether toxic signaling is due to gain-of-function of PrP C or by the impairment of a normal signaling is unknown. Indeed, it is possible that PrP C loss-of-function may also play a major role in the etiology of these maladies (12)(13)(14).
Interestingly, PrP C -null mice do not have an obvious phenotype, implying that PrP C may not have an essential function or that its loss may be compensated by other molecules (15,16). However, the expression of mutated PrP C proteins carrying various deletions result in diverse phenotypic abnormalities that parallel neurodegenerative processes. These findings are consistent with the existence of domains within the PrP C protein that have physiologically relevant functions (17). In fact, PrP C domains have been shown to be involved with some neurotrophic functions (14). Remarkably, several disease-associated mutations in PrP C have been localized to these domains, and although these mutations account for only a small fraction of prion diseases, mutated PrP C proteins provide us with an ideal model system to study PrP C loss-of-function.
The genetic human spongiform encephalopathies, including CJD, fatal familial insomnia, and Gerstmann-Straussler-Scheinker disease, are among the TSEs that have been linked to specific mutations in the PRNP gene that encodes PrP C (18,19). A common human PrP C polymorphism at amino acid residue 129, which may be either a methionine or a valine, specifies the disease phenotype associated with an aspartate to glutamine mutation at position 178 (D178N). Specifically, the Met-129/ Asn-178 haplotype is linked to fatal familial insomnia, whereas the Val-129/Asp-178 haplotype causes CJD (20). These disorders are autosomal dominant, fully penetrant inherited conditions, and the age of disease onset is around 50 years (OMIM entry 176640).
A vast number of ligands and signaling pathways have also been associated with PrP C functions (78), and PrP C has been proposed to organize a dynamic cell surface platform for the assembly of signaling modules (13). In addition, the neurotrophic functions attributed to PrP C may reside in its ability to drive the assembly of multicomponent complexes at the cell surface (14). Laminin (Ln), an extracellular matrix protein, is one of the high affinity ligands for PrP C (24). The mouse PrP C -Ln binding sites map to amino acids 1575-1584 (RNI-AEIIKDI) in the ␥1 chain region of Ln (Ln ␥1; Ref. 24) and to amino acids 173-182 in PrP C (22). Administration of the Ln ␥1 peptide, which represents the PrP C binding site, induces PrP Cdependent neuritogenesis and reproduces the neuronal maturation phenotype that is dependent upon the binding of Ln to PrP C (24). The PrP C -Ln ␥1 interaction requires the activity of the group I metabotropic glutamate receptors, mGluR1 and mGluR5, to promote neuritogenesis through activation of phospholipase C and intracellular Ca 2ϩ mobilization (35). The formation of a PrP C -Ln-mGluR1/5 signaling complex is consistent with the scaffold properties of PrP C and its possible role in allosteric regulation of signal transduction (36). In agreement with the idea that the PrP C -Ln ␥1 peptide interaction induces physiological signals in the nervous system, the activity of this complex has been shown to enhance memory consolidation (22).
In the present report we determined whether PrP C mutations associated with genetic prion diseases corrupt PrP C -Lndependent signaling pathways. The wild-type mouse PrP C as well as mouse PrP C carrying mutations at codons Leu-101, Leu-104, Val-116, Asn-177, Ile-179, and Lys-199 (equivalent to human mutated proteins Leu-102, Leu-105, Val-117, Asn-178, Ile-180, and Lys-200, respectively) were expressed in cells immortalized from primary neural cultures derived from PrP Cnull mice. The exogenous wild-type and mutant PrP C proteins were evaluated for cell membrane expression and proteinase K resistance. The ability to interact with the Ln-␥1 chain peptide upon Ca 2ϩ signaling to effect process outgrowth and induction of protective response was also determined. Our findings contribute to the identification of cellular mechanisms associated with PrP C loss-of-function.
Transfection, Selection, and Sorting-We used a site-directed mutagenesis kit (Stratagene #200518) to make the following amino acid substitutions in the PrP C protein: P101L, P104L, A116V, D177N, V179I, and E199K using a pcDNA3 PrP3F4 wild-type vector (41). The sequences of the primers used for the mutagenesis are shown in Table 1. PCR was carried out according to the manufacturer's recommendations: 1 l (20 units) of DpnI (New England Biolabs) was added to the plasmid DNA and incubated at 37°C for 1 h to digest methylated DNA. All constructs were sequenced to confirm the presence of the desired mutations and the integrity of the rest of the sequence and were used to transform competent Escherichia coli JM109 cells. CF10 cells were transfected using Lipofectamine 2000 (Invitrogen) according to the manufacturer's instructions using a 1:3 ratio of DNA to Lipofectamine. After transfection, cells were selected with G418 (2 mg/ml; Invitrogen) for 15 days, and resistant cells were subjected to magnetic cell sorting using 3F4 antibody (Dako), magnetic micro beads, and magnetic separation columns (Miltenyi Biotec). Cells were maintained as a nonclonal population. DNAs from all cell lines were also sequenced to confirm the presence of the desired mutations and the integrity of the rest of the PrP C sequence.
Flow Cytometry-To analyze PrP C expression on the plasma membrane, transfected CF10 cells and non-transfected controls were incubated with blocking solution (0.5% BSA in PBS) plus 10 g/ml 3F4 antibody followed by anti-mouse IgG conjugated to R-phycoerythrin (1:200), both for 1 h at 4°C. Analyses were performed using a FACSCalibur flow cytometer (BD Biosciences), and data acquired from 10,000 events were analyzed using CellQuest software (BD Biosciences).
Immunofluorescence-Cells were plated on glass coverslips, fixed with 4% paraformaldehyde in 0.12 M sucrose in PBS, and permeabilized with 0.2% Triton X-100 in PBS for 5 min at room temperature. After rinsing with PBS, cells were blocked with PBS plus 5% BSA and incubated with 1 g/ml 3F4 antibody or mouse monoclonal anti-MAP2 (1:200) for 16 h. After washes in PBS, cells were incubated with the secondary antibodies (1:1000), anti-mouse Alexa Fluor 488 for microtubule-associated protein 2 (MAP2) and 546 for PrP C , and also nuclear staining with 5 M TO PRO-3 (Invitrogen) for 1 h. Coverslips were mounted on slides using Fluorsave Reagent (Calbiochem). Immunolabeled cells were imaged using confocal microscopy (Leica TCS SP5 II).
Proteinase K Resistance-Transfected CF10 and control cells were washed twice with cold PBS, scraped from the plate, pel-leted by centrifugation, and lysed in cold buffer (0.5% Triton X-100, 0.5% sodium deoxycholate in PBS, 10 mM Tris-HCl, 10 mM NaCl, and 10 mM EDTA). For proteolysis experiments, lysates were shared (25% for control and 75% for digestion) and incubated for 30 min at 4°C with proteinase K (PK) (Roche Diagnostics) at the concentrations indicated. Samples were precipitated with methanol. One volume of sample was mixed with 2.5 volumes of methanol. After 2 h at Ϫ80°C, the mix was centrifuged at 10000 ϫ g for 30 min at 4°C, the supernatant was discarded, and pellets were air-dried. The dried pellets were dissolved in resuspension buffer (150 mM NaCl, 50 mM Tris-HCl, 50 mM EDTA). The presence of residual, proteinase K-resistant PrP C was evaluated by Western blotting using mouse anti-PrP C antibody (1:1000; 33). To quantification, the values were relativized by the extract concentration.
Calcium Signaling and Data Analysis-CF10 cells (transfected or non-transfected) were plated onto coverslips and serum-starved for 48 h before the experiments. Cells were loaded with 10 M intracellular Ca 2ϩ indicator Fluo3 AM (Invitrogen) for 30 min at 37°C in DMEM (Invitrogen) supplemented with 2 mM CaCl 2 . Cells were washed 3 times with PBS and resuspended in Krebs buffer (124 mM NaCl, 4 mM KCl, 25 mM HEPES, 1.2 mM MgSO 4 , 10 mM glucose) supplemented with 2 mM CaCl 2 . Ca 2ϩ -free experiments were performed in Krebs buffer without CaCl 2 plus 2 mM EGTA. Cells were preincubated in the presence or absence of mGluR1 and/or mGluR5 inhibitors LY367385 (50 M) or MPEP (5 M), respectively, for 30 min followed by treatment with Ln-␥1 peptide (37 M). In some experiments, CF10 cells were treated with Ln-␥1 peptide (37 M) followed by the mGluR1/mGluR5 agonist DHPG (100 M). In control experiments, cells were also treated with the sarco/endoplasmic reticulum Ca 2ϩ -ATPase inhibitor thapsigargin (1 M). All experiments were done at 37°C. Image acquisition was performed using confocal microscopy. The fluorescent signal was normalized as F1/F0 (F1, maximal fluorescence after drug addition; F0, basal fluorescence before drug addition). Software-based analysis (WCIF ImageJ) measured the change in the fluorescent signal in the selected cell as function of time. Experiments were carried out in at least three distinct cell cultures, and 40 -50 cells were monitored in each experiment. Traces represent typical single cell responses.
Process Outgrowth Assay-CF10 cells (transfected and nontransfected) were pretreated with 10 g/ml mitomycin C for 3 h at 37°C in a 5% CO 2 atmosphere. After washing, cells were detached with 0.02% EDTA in PBS and plated onto coverslips (12 mm 2 ) coated with 5 g/ml poly-L-lysine (PL) plus 37 M BSA-Ln-␥1 peptide, 37 M BSA-SCR peptide or laminin, and incubated for 48 h at 37°C and 5% CO 2 atmosphere. Cells were fixed with 4% paraformaldehyde in 0.12 M sucrose in PBS for 20 min at room temperature, washed 3 times with PBS, and processed for immunocytochemistry. Morphometric analysis was performed using Image J software (National Institute of Health) and the Neuron J plug-in. The analyzed parameters consisted of the percentage of cells with cytoplasmic processes. A total of 200 cells were analyzed per sample.
Cell Death Assay-The effect of mitomycin C upon cell death was evaluated after 3 or 48 h of treatment using trypan blue exclusion or by activation of caspase 3, respectively. For cell  DECEMBER 21, 2012 • VOLUME 287 • NUMBER 52 death protection assays, non-transfected CF10 cells and cells transfected with wild-type PrP C (PrP3F4) or with the PrP C mutants Leu-101, Leu-104, Val-116, Asn-177, Ile-179, and Lys-199 were cultured on 5 g/ml PL plus 37 M Ln ␥1 SCR peptide or 5 g/ml PL plus 37 M Ln ␥1 peptide for 32 h followed by incubation with 100 nM staurosporine (nonselective protein kinase inhibitor) for 16 h. Cell cultures were fixed for 20 min with 4% paraformaldehyde plus 0.12 M sucrose in PBS, pH 7.4. The staurosporine-induced cell death was detected by immunofluorescence in permeabilized cells using anti-active caspase-3 antibody (1:300) and DAPI. Coverslips were mounted on slides using Fluorsave Reagent (Calbiochem). Immunolabeled cells were imaged using Nikon TE2000U microscope.

PrP C Mutations Impair Ln-induced Process Outgrowth and Survival
Statistical Analysis-The statistical analyses were performed using GraphPad Prism 5 (GraphPad, San Diego, CA). Results are represented as the means Ϯ S.E., and the number of experiments performed in each experiment is stated in the respective figure legend. Data were compared by one-way analysis of variance and Dunnett's post test. Differences were considered significant at p Ͻ 0.05.

CF10 Cells Transfected with Wild-type and Mutated Murine PrP C Express Similar Levels of Proteins with Localization to the
Cell Surface-PrP C -null CF10 cells (38,39) were transiently transfected with cDNAs encoding a 3F4-tagged full-length murine wild-type PrP C (PrP3F4) or the 3F4-tagged PrP C mutants, Leu-101, Leu-104, Val-116, Asn-177, Ile-179, and Lys-199, which correspond to the disease-associated human mutations at amino acids 102, 105, 117, 178, 180, and 200, respectively. All the transfected PrP C proteins carried a methionine at amino acid 128. Transfected CF10 cells were selected for similar expression of either wild-type or mutated PrP C molecules, maintained as a non-clonal population, and verified by flow cytometry in non-permeabilized cells using 3F4 antibody (Fig.  1A), immunofluorescence of permeabilized cells (Fig. 1B), and Western blotting (Fig. 1C). Wild-type and mutated PrP C expression was properly reconstituted in CF10 cells, and similar amounts of the proteins are present at the plasma membrane (Fig. 1A). However, as described previously (42,43), the mutant, but not the wild-type, proteins displayed an intracellular accumulation (Fig. 1B). Western blot analysis also demonstrated the expression of di-, mono-, and non-glycosylated forms of PrP C , with a molecular mass ranging from 24 to 38 kDa (Fig. 1C). As expected, no endogenous PrP C expression was present in nontransfected CF10 cells (Fig. 1, A-C). The localization of these proteins at the cell surface is of major importance to this study, as PrP C distribution at the membrane is crucial for laminin binding (24,35).
PrP C Mutants Show Minor Resistance to Proteinase K Digestion-The TSEs are characterized by the conversion of the protease-sensitive prion protein into aggregates of proteaseresistant isoform associated with the neuropathogenic process in vivo (44). Our results show that the proteinase K (PK) resistance of the Lys-101, Val-116, Asn-177, and Lys-199 mutants was essentially identical to that of wild-type PrP C . The Lys-104 and Ile-179 mutants have a slight increase in resistance to PKmediated degradation compared with wild-type PrP C (Fig. 2). However, it is also possible that the apparent proteinase resistance of these mutants compared with wild-type proteins is caused by their relative insolubility in Triton X-100. These results are in agreement with similar findings for pathological PrP C mutants in different cell models (45)(46)(47)(48). However, it is important to note that the PK concentrations used in the current study are at least 5 times lower than those used to show resistance of the prion isoform associate with infection (49 -51), thus suggesting that a putative function of these proteins may not be affected by aggregation.
The Ectopic Expression of Wild-type PrP C Reconstitutes Ln ␥1 Peptide Signaling in CF10 Cells-Our previous results demonstrated that the interaction of PrP C with the Ln ␥1 peptide in primary neuronal cultures leads to the mobilization of Ca 2ϩ from intracellular stores followed by Ca 2ϩ influx and the activation of PKC and ERK1/2 (35). This PrP C -mediated transmembrane signaling is dependent on the activity of group I mGluR (mGluR1 and/or mGluR5) receptors, which were found to associate with PrP C (35). . PrP C mutants show minor resistance to proteinase K digestion. Extracts from CF10 cells expressing wild-type (PrP3F4) or PrP C mutants were treated or not with increasing concentrations of PK (0, 0.5, 1, and 4 g/ml) for 30 min at 4°C. The condition where cells were treated with PK had three times more total protein than the undigested condition. The remaining undigested PrP C was detected by Western blotting (anti-PrP C antibody). A, the relative levels of PrP C represent the ratio between the levels of PrP C after PK treatment and the total load of PrP C (control). Relative values are represented as the mean Ϯ S.E. (n ϭ 3). B, representative Western blots contain 3 times more total protein in the PK digestion conditions than in non-digested ones. The asterisk on the left side of the panel is to shown the migration of the molecular marker of 30 kDa.
A pharmacological approach was conducted to evaluate the activity of mGluR1 and/or mGluR5 in CF10 cells. The treatment with DHPG, a group I mGluR agonist, causes an increase in cytoplasmic calcium levels in non-transfected CF10 cells and those expressing wild-type PrP C (Figs. 3, A and B, respectively). This effect was partially impaired by LY367385 and MPEP, which are specific inhibitors of mGluR1 and mGluR5, respectively (Figs. 3, F and H), and DHPG-mediated calcium increases were completely abolished upon treatment with both inhibitors (Fig. 3J). Thus, non-transfected and wild-type PrP C -transfected CF10 cells (PrP3F4) express functional mGluR1 and mGluR5.
When wild-type PrP C -transfected CF10 (PrP3F4) cells were treated with the Ln ␥1 peptide, a significant increase in cytoplasmic calcium levels was observed (Fig. 3C). Conversely, no increases in intracellular Ca 2ϩ were induced by Ln ␥1 application in non-transfected PrP-null CF10 cells. These cells have normal levels of intracellular store calcium, as evidenced by their response to thapsigargin (Fig. 3D). Treatment with LY367385 (Fig. 3E) or MPEP (Figs. 3G) partially inhibited intracellular Ca 2ϩ mobilization by Ln ␥1 peptide in wild-type PrP Ctransfected cells, whereas a combination of the two inhibitors completely abolished the Ln ␥1 peptide-induced increases in the calcium signal (Fig. 3I). Quantitative analyses of these data are presented in Fig. 3K. These results are in accordance with our previous findings in primary hippocampal neurons (35) and indicate that the expression of wild-type PrP C in PrP C -null neuronal CF10 cells is able to reconstitute the cellular signaling modulated by the PrP C -Ln ␥1-mGluR1/5 pathway.
CF10 Cells Expressing Mutant Prion Proteins Present Impaired Ln ␥1-induced Calcium Signaling-Because calcium is one of the major intracellular signals triggered by PrP C -Ln ␥1 peptide mGluR1/5, we then examined whether disease-related mutations in the PrP C protein cause disturbances in Ln ␥1 peptide-induced intracellular calcium signaling. As previously demonstrated (Fig. 3C), the expression of wild-type PrP C , PrP3F4, rescued Ca 2ϩ signaling triggered by Ln ␥1 peptide (Fig.  4A) in CF10 cells. Interestingly, the expression of PrP C proteins carrying TSE-related mutations only partially rescued Ln ␥1 peptide-induced Ca 2ϩ signaling in CF10 cells when compared with cells expressing the wild-type protein (Fig. 4, C-H and I).
In addition, when treated with DHPG, all cells bearing mutant proteins show an increment in calcium signaling similar to those expressing wild-type protein (Fig. 4J), indicating that they have similar levels and activity of mGluR1/5. These data indicate that TSE-associated PrP C mutations result in deficiencies in intracellular calcium mobilization triggered by Ln ␥1 peptide.
PrP C Mutations Impaired Process Outgrowth Triggered by Ln ␥1 Peptide-As previously demonstrated (35), the association of PrP C and the Ln ␥1 peptide co-opts mGluR1/5 to promote neuronal differentiation and neuritogenesis in primary neuronal cultures through the mobilization of intracellular Ca 2ϩ . CF10 cells are strongly positive for nestin (36) and neuronspecific enolase but are negative for ␤III tubulin and NeuN (data not shown); thus, it is likely that they are neural progenitor cells. In addition, CF10 cells were immortalized via expression of the SV40 large T antigen and are, therefore, unable to arrest in the cell cycle, preventing the possibility of morphological alterations such as process outgrowth that resembles cell polarization and neurite extension observed in post-mitotic neurons (52,53). Even the treatment with the full-length Ln, a powerful molecule associated with neurite extension (54), was unable to promote process outgrowth in CF10 cells with (PrP3F4) or without PrP C expression (Fig. 5A). To promote cell cycle arrest, CF10 cells were treated with mitomycin C, a well known inhibitor of cell proliferation in vitro (55-57). We found that at the concentration used, mitomycin C impaired cell growth (Fig. 5B) without affecting cell viability (Fig. 5C). Morphometric analyses showed that mitomycin C-treated CF10 cells either non-transfected or transfected with wild-type PrP C (PrP3F4) extended robust cytoplasmic processes when plated onto full-length laminin (Fig. 5D). Nonetheless, these cells do  . Process outgrowth mediated by the Ln ␥1-peptide can be rescued after the reconstitution of PrP C expression in CF10 cells. A, CF10 cell lines with and without transfections of wild-type PrP C (PrP3F4) were cultured 48 h on coverslips pretreated with 10 g/ml full-length laminin or 5 g/ml poly-L-lysine (PL). Cells were fixed and labeled, and process outgrowth was quantified. B and C, PrP3F4-and non-transfected CF10 cells were treated with 10 g/ml mitomycin C or vehicle for 3 h, washed, and plated on PL for 48 h to assess. The total cell number (proliferation) after 48 h (B) or cell death (using trypan blue) (C) after 3 h of mitomycin treatment. Values represent the mean Ϯ S.E. (n ϭ 3). *, p Ͻ 0.05 versus control. D, PrP3F4-and non-transfected CF10 cells pretreated with 10 g/ml mitomycin C for 3 h were cultured on 5 g/ml PL, PL plus laminin (2.5 or 5 g/ml), or PL plus Ln ␥1 peptide (Pep g1) (16.8 or 37 M) for 48 h. Values represent the mean Ϯ S.E. n ϭ 3. *, p Ͻ 0.05 compared with the control PrP3F4 or CF10 in PL; **, p Ͻ 0.05 compared with the control PrP3F4 in PL. DECEMBER 21, 2012 • VOLUME 287 • NUMBER 52 not express ␤III tubulin and NeuN (data not shown) after this treatment. Yet, under specific experimental conditions, these cells are able to grow neurite-like processes; in addition, when full-length Ln is present, other receptors besides PrP C , probably integrins, may contribute to the phenotype. In contrast, process outgrowth was observed when wild-type PrP C -expressing cells (PrP3F4), but not the non-transfected CF10 one, was plated onto Ln ␥1 peptide (Fig. 5D). These results confirm that the outgrowth of neurite-like processes, mediated by the PrP C -Ln ␥1 interaction, can be rescued in CF10 cells expressing the wildtype PrP C .

PrP C Mutations Impair Ln-induced Process Outgrowth and Survival
In CF10 cells that express mutated PrP C , mitomycin C also inhibited cell growth (Fig. 6A) without affecting viability measured by trypan blue exclusion (Fig. 6B). Cell death induced by mitomycin C 48 h after treatment was also evaluated by activation of caspase 3. Contrary to the positive control, staurosporine, mytomycin C did not induce cell death (Fig. 6C). These cells together with non-transfected and wild-type PrP C -expressing CF10 cells (PrP3F4) were also evaluated for process outgrowth mediated by the Ln ␥1 peptide. Fig. 6E shows representative images of the morphology of these cells after Ln ␥1 peptide treatment and immunolabeling with MAP2. CF10 cells transfected with wild-type PrP C (PrP3F4) presented long cytoplasmic processes (arrows in the first panel; upper left).
Remarkably, the addition of the Ln ␥1 peptide was unable to promote process outgrowth in CF10 cells expressing mutated PrP C molecules (quantification in Fig. 6D). These results indicate that CF10 cells lacking PrP C or expressing mutated PrP C are unable to extend cytoplasmic processes upon Ln ␥1 peptide treatment.
PrP C Mutations Impaired Protection against Cell Death Triggered by Ln ␥1 Peptide-PrP C has been involved in neuronal protection against cell death, and consensus results from different groups showed that neurons from PrP C -null mice presented a higher sensitivity to agents that induce cell death, including staurosporine, than neurons from wild-type animals (for review, see Ref. 13). Remarkably, our results (Fig. 6C) demonstrated that CF10 cells or cells expressing mutated PrP C also presented a higher sensitivity to staurosporine than cells that were reconstituted with wild-type PrP C .
We then tested whether Ln ␥1 chain peptide induces protection against staurosporine-induced cell death. Ln ␥1 peptide, but not the SCR peptide, was able to protect PrP3F4 cells against staurosporine-induced cell death. However, any protective effect was observed when CF10 or CF10 cells expressing PrP C mutants were cultured on Ln ␥1 peptide (Fig. 7A).
Finally, some experiments were conducted to evaluate if mutant PrP C molecules present dominant negative or prion effects upon wild-type PrP C . CF10, PrP3F4, and CF10 cells expressing the mutants Lys-101 and Ile-179 were transiently transfected with PrP3F4 (Fig. 7B) and tested for Ln ␥1 protection against cell death induced by staurosporine. The expression of PrP3F4 was able to rescue the neuroprotective effects of Ln ␥1 even when in the presence of mutated PrP C molecules (Fig. 7C), thus indicating that these mutants do not have a dominant negative or prion effect upon wild-type PrP C and may have lost their function triggered by engagement with Ln ␥1 peptide.

DISCUSSION
The goal of this study was to investigate the consequences of PrP C loss-of-function that result from disease-associated mutations in the PrP C protein. To model the function of PrP C we expressed wild-type and mutant PrP C proteins on a PrP C -null background neural cell line (CF10). Our results show that substitutions within the PrP C protein decrease calcium signaling and impair process outgrowth and protective response that are mediated by the interaction between PrP C and Ln ␥1 chain peptide.
The effects of PrP C and PrP C mutants expression have been previously investigated at the cellular level using neuroblastoma, breast cancer, fibroblasts, and Fischer rat thyroid cell lines (43, 58 -61). However, data regarding the cellular and biochemical properties of prion proteins are controversial; disparities between groups may reflect differences in the cell types in which these proteins have been expressed (21,27,(62)(63)(64). In the current application, we have addressed this question in non-tumor-derived neural cells; a model may more faithfully replicate the effects of prion proteins in neurons. Remarkably, the reconstitution of wild-type PrP C in PrP C -null neural CF10 cells was able to reproduce all the effects that have been observed in primary neuronal cultures after the interaction of PrP C with stress-inducible protein 1 (STI1) (39) and with Ln ␥1 chain peptide (33).
The current study also demonstrates the utility of the CF10 cell lines as a model for the study of exogenously-expressed prion mutated proteins. We found that these cells expressed PrP C at the cell surface, where it should be to interact with ligands at the membrane or at the extracellular matrix (including Ln) and whose interaction modulates cellular functions (13). In addition, transfected CF10 cells express similar levels of the wild-type or mutated PrP C at the cell membrane, although some intracellular accumulation of the mutant PrP C proteins was detected. Moreover, only a minor PK resistance was observed in two of six PrP C mutants, suggesting that aggregation may not interfere with the function of these proteins.
PrP C binds to the carboxy-terminal domain of the Ln ␥1 chain, a region where no other laminin receptors have been mapped (24). Thus, the use of the Ln ␥1 peptide allows to specifically examinate phenotypes associated with the PrP C -Ln interaction (24). We recently demonstrated that the Ln ␥1 peptide induces PrP C -dependent neuritogenesis via increases in intracellular Ca 2ϩ and the activation of PKC and ERK1/2 in a manner dependent upon the participation of mGluR1/5, which also interact with PrP C (35).
Our data show that calcium signaling mediated by the Ln ␥1 peptide and mGLUR1/5 is partially impaired in cells expressing the Leu-101, Leu-104, Val-116, Asn-177, Ile-179, and Lys-199 PrP C mutants compared with wild-type PrP C . Remarkably, in the course of TSE disease, it has been demonstrated that prion infection modifies Ca 2ϩ responses (65) and impairs mGluR1/ PLC/PKC pathway signaling in neurons derived from a murine model of BSE as well as humans with sporadic Creutzfeldt-Jakob disease (66,67). Together, these results suggest that modifications in the PrP C protein impact type 1 mGluR-mediated cell signaling pathways and that these alterations play a role in both sporadic and genetic prion diseases.
Although only a partial decrease on the Ln ␥1-mediated Ca 2ϩ response was observed in cells expressing mutant PrP C proteins, we found that Ln ␥1-induced process outgrowth was completely abolished in the presence of mutant PrP C molecules. One simple explanation is that the increment in Ca 2ϩ levels did not achieve the threshold necessary to promote this phenotype in these cells. It is important to note that the Asn-177 and Ile-179 mutants are in the vicinity of the Ln ␥1 binding site on the PrP C molecule, amino acids 173-182 (22). Thus, these alterations may abrogate the interaction between PrP C and laminin. On the other hand, we show similar results with PrP C molecules carrying disease-association mutations in the amino-terminal domain (Lys-101, Lys-104, and Val-116) or in the vicinity of the third ␣-helix region (Lys-199). It is possible that these mutations instead affect the interaction between PrP C and mGluR1/5; however, the binding site between these molecules has not yet been identified.
PrP C was also pointed to protect neurons against injury both in vitro and in vivo (13,19,25). PrP C protein is itself a receptor for the secreted form of STI1, an interaction that has been shown to promote neuroprotection and neuronal differentia-tion (25,68,69). Our present data indicate that Ln ␥1 peptide impaired staurosporine-induced cell death in PrP3F4 cells, whereas Ln ␥1 peptide fails to rescue CF10 and CF10 cells expressing PrP C mutants from death. Indeed, the results are consistent with the participation of the Ln ␥1 peptide-PrP C complex in neuroprotection and that mutations within PrP C abolish its neuroprotective function. Furthermore, when the wild-type PrP C is co-expressed with mutant PrP C molecules, Ln ␥1 peptide rescues staurosporine-induced cell death. This seems to show the absence of a dominant-negative effect, which is consistent with previous data showing that neurodegeneration mediated by expression of PrP C deletion mutants (some of the deleted sites include amino acids mutated here) could be reversed by expression of the wild-type protein (70 -72).
The results of the current study may provide support to the idea that PrP C plays an important role as a scaffolding protein that has allosteric functions and dysfunctions (36). The interaction between PrP C and STI1 or between PrP C and the STI1 peptide 230 -245, which mimics the PrP C binding site, has been shown to alter the structure of both components, potentially impacting the ability of either protein to interact with other ligands (73) and to organize a functional signaling platform (13). The conformational alterations imposed by the PrP C -Ln ␥1 interaction remain unknown. However, some PrP C mutants have been shown to destabilize the native PrP C structure, possibly by increasing the stability of partially folded intermediate species (74 -77). The conformational alterations imposed by these mutations may alter the ability of PrP C to interact with ligands such as laminin or mGluR1/5 and may even impair the interactions of these ligands with other proteins. Depending on the multicomplex formed, a specific cellular event could be partially impaired, as is observed for Ca 2ϩ signaling, or completely blocked, as is the case for process outgrowth, by mutations in PrP C .
PrP C -mutated molecules may lose the ability to modulate Ln ␥1-mediated neuronal plasticity and survival, thus representing the loss of a physiological function associated with the PrP C . This study points toward the necessity of further evaluation of the role of native and mutated PrP C proteins in neuronal plasticity in animal models of genetic prion diseases even before the onset of clinical symptoms.