The metabolism of glycosaminoglycans is impaired in prion diseases

It is well established that the conversion of PrP(C) to PrP(Sc) is the key event in prion disease biology. In addition, several lines of evidence suggest that glycosaminoglycans (GAGs) and in particular heparan sulfate (HS) may play a role in the PrP(C) to PrP(Sc) conversion process. It has been proposed that PrP(Sc) accumulation in prion diseases may induce aberrant activation of lysosomal activity, which has been shown to result in neurodegeneration in a number of diseases, especially lysosomal storage disorders. Among such diseases, only the ones resulting from defects in GAGs degradation are accompanied by secretion of large amounts of GAG metabolites in urine. In this work, we show that GAGs are secreted in the urine of prion-infected animals and humans, and surprisingly, also in the urine of mice ablated for the PrP gene. We hypothesize that both the presence of PrP(Sc) or the absence of PrP(C) may alter the metabolism of GAGs.

Absence of evidence for the participation of the macrophage cellular prion protein in infection with Brucella suis

Brucella spp. are stealthy bacteria that enter host cells without major perturbation. The molecular mechanism involved is still poorly understood, although numerous studies have been published on this subject. Recently, it was reported that Brucella abortus utilizes cellular prion protein (PrP(C)) to enter the cells and to reach its replicative niche. The molecular mechanisms involved were not clearly defined, prompting us to analyze this process using blocking antibodies against PrP(C). However, the behavior of Brucella during cellular infection under these conditions was not modified. In a next step, the behavior of Brucella in macrophages lacking the prion gene and the infection of mice knocked out for the prion gene were studied. We observed no difference from results obtained with the wild-type control. Although some contacts between PrP(C) and Brucella were observed on the surface of the cells by using confocal microscopy, we could not show that Brucella specifically bound recombinant PrP(C). Therefore, we concluded from our results that prion protein (PrP(C)) was not involved in Brucella infection.

Bovine prion is endocytosed by human enterocytes via the 37 kDa/67 kDa laminin receptor

Some forms of transmissible spongiform encephalopathies result from oral infection. We have thus analyzed the early mechanisms that could account for an uptake of infectious prion particles by enterocytes, the major cell population of the intestinal epithelium. Human Caco-2/TC7 enterocytes cultured on microporous filters were incubated with different prion strains and contaminated brain homogenates in the apical compartment. Internalization of infectious particles was analyzed by Western blotting and immunofluorescence. We observed internalization by enterocytes of prion particles from bovine spongiform encephalopathy brain homogenates but not from mouse-adapted scrapie-strain brain homogenates or purified bovine spongiform encephalopathy scrapie-associated fibrils. Bovine prion particles were internalized via endocytosis within minutes of infection and were associated with subapical vesicular structures related to early endosomes. The endocytosis of the infectious bovine PrP(Sc) was reduced by preincubating the cells with an anti-LRP/LR blocking antibody, identifying the 37 kDa/67 kDa laminin receptor (LRP/LR), which is apically expressed in Caco-2/TC7 cells, as the receptor for the infectious prion protein. Altogether, our results underscore a potential role of enterocytes in the absorption of bovine prions during oral infection through specific LRP/LR-dependent endocytosis.

Skin-derived dendritic cells acquire and degrade the scrapie agent following in vitro exposure

The accumulation of the scrapie agent in lymphoid tissues following inoculation via the skin is critical for efficient neuroinvasion, but how the agent is initially transported from the skin to the draining lymph node is not known. Langerhans cells (LCs) are specialized antigen-presenting cells that continually sample their microenvironment within the epidermis and transport captured antigens to draining lymph nodes. We considered LCs probable candidates to acquire and transport the scrapie agent after inoculation via the skin. XS106 cells are dendritic cells (DCs) isolated from mouse epidermis with characteristics of mature LC cells. To investigate the potential interaction of LCs with the scrapie agent XS106 cells were exposed to the scrapie agent in vitro. We show that XS106 cells rapidly acquire the scrapie agent following in vitro exposure. In addition, XS106 cells partially degrade the scrapie agent following extended cultivation. These data suggest that LCs might acquire and degrade the scrapie agent after inoculation via the skin, but data from additional experiments demonstrate that this ability could be lost in the presence of lipopolysaccharide or other immunostimulatory molecules. Our studies also imply that LCs would not undergo maturation following uptake of the scrapie agent in the skin, as the expression of surface antigens associated with LC maturation were unaltered following exposure. In conclusion, although LCs or DCs have the potential to acquire the scrapie agent within the epidermis our data suggest it is unlikely that they become activated and stimulated to transport the agent to the draining lymph node.

The prion protein requires cholesterol for cell surface localization

The cellular prion protein PrP(c) is attached to the plasma membrane by a glycosyl-phosphatidyl-inositol (GPI-) anchor and is localized in lipid rafts, membrane microdomains characterized by a high content of sphingolipids and cholesterol. Previous studies revealed that perturbation of cholesterol synthesis prevents prion conversion, explained by redistribution of PrP(c) at the plasma membrane. We investigated the influence of inhibition of cholesterol synthesis by the HMG-CoA-reductase inhibitor mevinolin on the trafficking of PrP(c) in neuronal cells. Treatment with mevinolin significantly reduces the amount of surface PrP(c) and leads to its accumulation in the Golgi compartment. Analysis of mutant PrPs highlights the importance of the GPI-anchor for raft localization and provides information about domains implicated in lipid raft association of PrP in the secretory pathway. Our data show that cholesterol is essential for the cell surface localization of PrP(c), known to be necessary for prion conversion.

Predicted consequences of site-directed mutagenesis and the impact of species variation on prion protein misfolding through the N-terminal domain

Variant Creutzfeldt-Jacob disease (vCJD) is considered to afflict humans through the acquisition of variant isomers and misfolding of the normal cellular prion polypeptide, PrP(C). Although the exact mechanism of the misfolding is not been yet clearly understood, this paper provides four additional pieces of evidence in support of the hypothesis that misfolding within PrP(C) involves N-terminal residues, up to and including Asn178. Structural predictions for N-terminal residues between Leu4 and Gly124 revealed that Leu4-Leu19 might adopt a helical conformation. Furthermore, measurement of C(alpha) distance variations, as determined from available NMR solution structures of wild type, as well as the biologically significant Val166, Asn170 and Lys220 variants of PrP(C), revealed previously unreported global and local conformational differences may occur in PrP(C) as a result of these amino-acid substitutions. Notably, three regions, His140-Tyr150 and Met166-Phe175 showed deviations greater than 3 A in their C(alpha)-coordinates (cf wild type) indicating that the majority of the N-terminal domain is likely to contribute to the misfolding of PrP(C). Minor variations in the orientation of amino acids Thr193-Glu200, located towards the C terminus of the protein, were also noted. This most likely indicates the presence of a hinge mechanism, inherent to a Helix-Loop-helix (HLH) motif formed by amino acids within alpha2, LIII and alpha3, in order to accommodate reorientation of the motif in response to misalignment of the N-terminal domain. An unexpected 3 angstroms deviation from the coordinates of the wild type polypeptide, absent from either Val166, Asn170 variants was observed over the region Arg154-Tyr155 within the Val166 form of PrP(C). This may contribute to the explanation as to why patients carrying the Val166 isoform of PrP(C) may be more susceptible to vCJD.

Extended period of asymptomatic prion disease after low dose inoculation: Assessment of detection methods and implications for infection control

We used quantal dose-titration of a mouse-adapted human transmissible spongiform encephalopathy strain (M470) to compare different analytical methods for their ability to detect asymptomatic brain prion infection after low dose inoculation. At a time point approximately 2.5-fold beyond the mean incubation period of high dose inocula, asymptomatic brain infection was commonly observed using histologic examination, Western blot, and "blind" bioassay following intracerebral inoculation with low titer inocula. At this time point, when a clinical end-point titration would usually be determined, evidence of infection was seen in all healthy animals inoculated with up to 100-fold lower inoculation doses than the lowest causing consistent clinical disease. For the assessment of the presence of asymptomatic infection, we compared different Western immunoblot and histopathological methods in relation to "blind" bioassay using transgenic Tga/20 mice overexpressing mouse prion protein (PrP). Sodium phosphotungstic acid (NaPTA) precipitation of protease-resistant PrP isoforms (PrP(res)) prior to Western blotting was found to approach the sensitivity of the Tga/20 bioassay and was superior to conventional Western blot and histopathological methods, wherein infectivity was commonly found when both of the latter were negative. Re-scaling the original titer by incorporating "blind" transmission data from surviving asymptomatic mice revises the estimate two orders of magnitude higher than the value derived using the conventional clinical disease outcome approach. We also found that the sensitivity of the NaPTA Western blot technique, if used with a diluent such as PBS compared with 10% normal brain homogenate, is adversely affected by up to around 20-fold. We postulate that infectious titer estimates based on more sensitive detection systems such as we report provide a more accurate indication of ultimate transmission risk.

Aggravation of ischemic brain injury by prion protein deficiency: Role of ERK-1/-2 and STAT-1

The cellular isoform of prion protein, PrPc, may confer neuroprotection in the brain, according to recent studies. To elucidate the role of PrPc in stroke pathology, we subjected PrPc-knockout (Prnp(0/0)), wild-type and PrPc-transgenic (tga20) mice to 30 min of intraluminal middle cerebral artery occlusion, followed by 3, 24 or 72 h reperfusion, and examined how PrPc levels influence brain injury and cell signaling. In immunohistochemical experiments and Western blots, we show that PrPc expression is absent in the brains of Prnp(0/0) mice, detectable in wild-type controls and approximately 4.0-fold elevated in tga20 mice. We provide evidence that PrPc deficiency increases infarct size by approximately 200%, while transgenic PrPc restores tissue viability, albeit not above levels in wild-type animals. To elucidate the mechanisms underlying Prnp(0/0)-induced injury, we performed Western blots, which revealed increased activities of ERK-1/-2, STAT-1 and caspase-3 in ischemic brains of Prnp(0/0)mice. Our data suggest a role of cytosolic signaling pathways in Prnp(0/0)-induced cell death.

Assigning functions to distinct regions of the N-terminus of the prion protein that are involved in its copper-stimulated, clathrin-dependent endocytosis

The cellular prion protein (PrPC) is essential for the pathogenesis and transmission of prion diseases. Although PrPC is known to be located in detergent-insoluble lipid rafts at the surface of neuronal cells, the mechanism of its internalisation is unclear, with both raft/caveolae-based and clathrin-mediated processes being proposed. We have investigated the mechanism of copper-induced internalisation of PrPC in neuronal cells by immunofluorescence microscopy, surface biotinylation assays and buoyant sucrose density gradient centrifugation in the presence of Triton X-100. Clathrin-mediated endocytosis was selectively blocked with tyrphostin A23, which disrupts the interaction between tyrosine motifs in the cytosolic domains of integral membrane proteins and the adaptor complex AP2, and a dominant-negative mutant of the adaptor protein AP180. Both these agents inhibited the copper-induced endocytosis of PrPC. Copper caused PrPC to move laterally out of detergent-insoluble lipid rafts into detergent-soluble regions of the plasma membrane. Using mutants of PrPC that lack either the octapeptide repeats or the N-terminal polybasic region, and a construct with a transmembrane anchor, we show that copper binding to the octapeptide repeats promotes dissociation of PrPC from lipid rafts, whereas the N-terminal polybasic region mediates its interaction with a transmembrane adaptor protein that engages the clathrin endocytic machinery. Our results provide an experimental basis for reconciling the apparently contradictory observations that the prion protein undergoes clathrin-dependent endocytosis despite being localised in lipid rafts. In addition, we have been able to assign distinct functions in the endocytic process to separate regions of the protein.

Processing of ovine PrP(ARQ)C-EGFP chimeras containing Asn138 and Cys151 polymorphisms

Polymorphisms in the prion protein, PrP(C), affect the susceptibility of sheep to scrapie. Three rare polymorphisms, M137T, S138N, and R151C, have been found in Icelandic sheep. Observations suggest that R151C may be associated with lower scrapie susceptibility, whereas S138N is neutral. The effects of the S138N and R151C polymorphisms on the cellular processing of PrP(C) were examined in a model system consisting of the expression of ovine PrP(C)-EGFP (green fluorescent protein) chimeras in the mouse neuroblastoma cell line N2a. Chimeras with the haplotypes A136R154Q171 (ARQ), AN138RQ, and AC151RQ were compared. The chimeras did not differ regarding their translocation into the secretory system, glycosylation, and transport to the cell surface. However, the AC151RQ chimera differed from the other chimeras regarding disulfide bonding characteristics; furthermore, a slight difference was detected between AC151RQ and the other chimeras by limited proteolysis. The processing of the ARQ and AN138RQ chimeras was identical in the experiments performed consistent with observations that it is neutral.

Detection of prion epitopes on PrP c and PrP sc of transmissible spongiform encephalopathies using specific monoclonal antibodies to PrP

Amino acid residues 90-120 of the prion protein (PrP) are likely to be critical for the conversion of PrP(c) to PrP(sc) in the transmissible spongiform encephalopathies. We raised 10 monoclonal antibodies against the 90-120 amino acid region, mapped the epitope specificity of these anti-PrP antibodies, and investigated the expression of epitopes recognized by the antibodies in both PrP(c) and PrP(sc). Four out of five of the anti-PrP antibodies raised in a prion knockout mouse immunized with the linear peptide of PrP90-120 could detect PrP(sc) in 'native' and denatured forms and PrP(c) in normal cells, as well as recognize epitopes within PrP93-112 residues. In contrast, the other six anti-PrP reagents, including five raised from the two knockout mice immunized with conformationally modified PrP90-120 peptide, could detect PrP(c) and recognize epitopes within PrP93-107 residues. Four of these reagents could also detect denatured PrP(sc) on western blots but not PrP(sc) plaques in brain tissue. The results indicate that residues PrP93-102 are exposed in PrP(c) but are buried upon conversion to the PrP(sc) isoform. Furthermore, PrP103-107 residues are partially buried in PrP(sc) while only the PrP107-112 epitope remains exposed, suggesting that the region PrP93-112 undergoes conformational changes during its conversion to PrP(sc).

Sheep scrapie susceptibility-linked polymorphisms do not modulate the initial binding of cellular to disease-associated prion protein prior to conversion

Conversion of the host-encoded protease-sensitive cellular prion protein (PrPC) into the scrapie-associated protease-resistant isoform (PrPSc) of prion protein (PrP) is the central event in transmissible spongiform encephalopathies or prion diseases. Differences in transmissibility and susceptibility are largely determined by polymorphisms in PrP, but the exact molecular mechanism behind PrP conversion and the modulation by disease-associated polymorphisms is still unclear. To assess whether the polymorphisms in either PrPC or PrPSc modulate the initial binding of PrPC to PrPSc, several naturally occurring allelic variants of sheep PrPC and PrPSc that are associated with differential scrapie susceptibility and transmissibility [the phylogenetic wild-type (ARQ), the codon 136Val variant (VRQ) and the codon 171Arg variant (ARR)] were used. Under cell-free PrP conversion conditions known to reproduce the observed in vivo differential scrapie susceptibility, it was found that the relative amounts of PrPC allelic variants bound by various allelic PrPSc variants are PrP-specific and have comparable binding efficiencies. Therefore, the differential rate-limiting step in conversion of sheep PrP variants is not determined by the initial PrPC–PrPSc-binding efficiency, but seems to be an intrinsic property of PrPC itself. Consequently, a second step after PrPC–PrPSc-binding should determine the observed differences in PrP conversion efficiencies. Further study of this second step may provide a future tool to determine the mechanism underlying refolding of PrPC into PrPSc and supports the use of conversion-resistant polymorphic PrPC variants as a potential therapeutic approach to interfere with PrP conversion in transmissible spongiform encephalopathy development.

Preparation of monoclonal antibodies against prion proteins with full-length hamster PrP

OBJECTIVE

To prepare the PrP specific monoclonal antibodies (mAbs) that can be used for the detection of mammalian prions and study of pathogenesis of prion diseases.

METHODS

Several BALB/c mice were immunized with recombinant hamster prion protein (HaPrP). Three hybridoma cell lines designated as B7, B9, and B10, secreting monoclonal antibodies against HaPrP, were established by hybridoma technique. The mAbs reactivities were evaluated with ELISA, Western blot, and immunohistochemistry.

RESULTS

The mAbs produced by these cell lines reacted well with different recombinant hamster PrP proteins. Western blot analyses showed that mAbs B7 and B9 reacted with PrPSc from the scrapie-infected animals after proteinase K digestion with three glycosylated forms. The mAbs exhibited cross-reactivity with various PrPC from several other mammalian species, including humans and cattles. Immunohistochemistry assays confirmed that mAbs B7 and B9 could recognize not only extracellular but also intracellular PrPsSc.

CONCLUSION

The mAbs of prion protein are successfully generated by hybridoma technique and can be applied for the diagnosis of prion associated diseases.

Prion protein (PrPc) promotes β-amyloid plaque formation

Prion protein (PrP) has been localized to amyloid-beta (Abeta) senile plaques in aging and Alzheimer disease, but it is unknown whether PrP is directly involved in plaque formation or represents a reaction to amyloid deposition. To evaluate possible functional effects of PrP in Abeta plaque formation, we analyzed bigenic mice (TgCRND8/Tg7), carrying mutant human amyloid precursor protein (APP) 695 (APP(Swed+Ind), TgCRND8) as well as the wild-type Syrian hamster prion protein gene (sHaPrP, Tg7), showing Abeta plaques at 3 months of age as well as highly increased HaPrP(c) levels. Compared to the control group, consisting of animals carrying only mutant APP, bigenic mice showed a higher number of senile plaques in the cerebral cortex, while APP transcription and Abeta40/Abeta42 levels were unchanged. Double-labelling immunofluorescence showed co-localization of Abeta and PrP in virtually all plaques in the brains of both control and experimental animals. Our data suggest that PrP promotes plaque formation, and that this hitherto unknown functional role of PrP appears to be mediated by increased Abeta aggregation rather than by altered APP transcription or processing.

Proteolytic processing and glycosylation influence formation of porcine prion protein complexes

High level of heterogeneity seems to be a ubiquitous feature of mammalian PrPs (prion proteins) and may be relevant to the pathogenesis of prion diseases. In the present study, we describe the heterogeneity of PrP(C) (cellular form of PrP) from porcine brain. It was disclosed and characterized by a combination of one-dimensional PAGE and two-dimensional PAGE analyses with enzymic deglycosylation and copper-affinity experiments. We found that the identified two main populations of porcine PrP(C) consist of diglycosylated forms and correspond to the full-length (molecular mass 32-36 kDa) and proteolytically modified protein (molecular mass 25-30 kDa), known as C1. The two populations were fully separated during Cu2+-loaded immobilized metal affinity chromatography, indicating different affinity for copper ions. The more basic forms, migrating as species of higher molecular mass, exhibited stronger affinity for copper ions, whereas those with more acidic pI and of lower molecular mass were low-affinity Cu2+-binding molecules and thus could represent N-terminally truncated PrP(C). Size-exclusion chromatography revealed that most of the PrP(C) molecules in porcine brain extracts exist in the form of high-molecular-mass complexes (probably with other proteins). The heterogeneity of porcine PrP(C), resulting from proteolytic modification and glycosylation, influences its ability to assemble into these complexes. N-truncated molecules dominate over full-length PrP(C) in fractions of molecular mass over the range 65-130 kDa, whereas the full-length species are the major forms of PrP(C) present in the monomeric fraction and in complexes above 130 kDa. Two-dimensional PAGE analysis indicated that the complexed PrP(C) differs in the composition of pI forms from the monomers.

Birth of a Prion: Spontaneous Generation Revisited

The proposal that the transmissible agent in prion diseases can be a conformationally altered host protein that multiplies by autocatalytic conversion has gained wide acceptance. Recent work shows that the agent, the prion, can be replicated in a cell-free system, that it can be generated de novo, and that the strain-specific properties of prions are encoded by conformational variations of the underlying protein.

Use of a new immunoassay to measure PrP Sc levels in scrapie-infected sheep brains reveals PrP genotype-specific differences

The diagnosis of prion diseases, such as scrapie and BSE, has traditionally relied upon the identification of the disease-associated form of the prion protein, PrP(Sc), based on its resistance to digestion by proteinase K (PK). A more recent development is the conformation-dependent immunoassay (CDI), which distinguishes between PrP Sc and normal PrP (PrP C) based on their differing solubility in guanidine hydrochloride rather than resistance or sensitivity to PK. We have developed a CDI-formatted sandwich immunoassay for the measurement of PrP Sc in sheep brain, which discriminates between clinically affected scrapie cases (natural or experimental) and uninfected controls of the same PrP genotype. Using this method, we have shown for the first time that, in sheep, the PrP genotype has a significant influence on the amount of PrP Sc deposited in the brains of animals experimentally infected with scrapie.

Prion protein recruits its neuronal receptor NCAM to lipid rafts to activate p59fyn and to enhance neurite outgrowth

In spite of advances in understanding the role of the cellular prion protein (PrP) in neural cell interactions, the mechanisms of PrP function remain poorly characterized. We show that PrP interacts directly with the neural cell adhesion molecule (NCAM) and associates with NCAM at the neuronal cell surface. Both cis and trans interactions between NCAM at the neuronal surface and PrP promote recruitment of NCAM to lipid rafts and thereby regulate activation of fyn kinase, an enzyme involved in NCAM-mediated signaling. Cis and trans interactions between NCAM and PrP promote neurite outgrowth. When these interactions are disrupted in NCAM-deficient and PrP-deficient neurons or by PrP antibodies, NCAM/PrP-dependent neurite outgrowth is arrested, indicating that PrP is involved in nervous system development cooperating with NCAM as a signaling receptor.

The expression of prion protein (PrP(C)) in the megakaryocyte lineage

BACKGROUND

Cellular prion protein (PrP(C)) is a naturally occurring protein in normal individuals which adopts an abnormal conformation, termed scrapie prion protein (PrP(Sc)) that is associated with disease. There is great concern that clinically asymptomatic variant Creutzfeldt-Jacob disease (vCJD) may transmit PrP(Sc) in blood transfusion products. PrP(C) is widely expressed and has been found in human blood. The majority of cellular borne PrP(C) is associated with platelets (84%). Although PrP(C) mRNA has been demonstrated in platelets, the quantity is unknown and may not reflect the total PrP(C) present.

OBJECTIVE

To investigate the expression of PrP(C) in the megakaryocyte lineage.

METHODS

The expression of PrP(C) was studied in CD34+ cells, cultured megakaryocytes and platelets using electron microscopy, flow cytometry, semi-quantitative RT-PCR and immunofluorescence confocal microscopy.

RESULTS AND CONCLUSIONS

The expression of PrP(C) appeared to increase with differentiation and polyploidization in the megakaryocyte lineage. PrP(C) was located within platelet alpha-granules and its source is likely to be from megakaryocyte precursors. If PrP(Sc) has a similar distribution, these results have implications for the selection of blood donors and preparation of cell-depleted blood products.

The AGAAAAGA palindrome in PrP is required to generate a productive PrPSc-PrPC complex that leads to prion propagation

The molecular hallmark of prion disease is the conversion of normal prion protein (PrPC) to an insoluble, proteinase K-resistant, pathogenic isoform (PrPSc). Once generated, PrPSc propagates by complexing with, and transferring its pathogenic conformation onto, PrPC. Defining the specific nature of this PrPSc-PrPC interaction is critical to understanding prion genesis. To begin to approach this question, we employed a prion-infected neuroblastoma cell line (ScN2a) combined with a heterologous yeast expression system to independently model PrPSc generation and propagation. We additionally applied fluorescence resonance energy transfer analysis to the latter to specifically study PrP-PrP interactions. In this report we focus on an N-terminal hydrophobic palindrome of PrP (112-AGAAAAGA-119) thought to feature intimately in prion generation via an unclear mechanism. We found that, in contrast to wild type (wt) PrP, PrP lacking the palindrome (PrPDelta112-119) neither converted to PrPSc when expressed in ScN2a cells nor generated proteinase K-resistant PrP when expressed in yeast. Furthermore, PrPDelta112-119 was a dominant-negative inhibitor of wtPrP in ScN2a cells. Both wtPrP and PrPDelta112-119 were highly insoluble when expressed in yeast and produced distinct cytosolic aggregates when expressed as fluorescent fusion proteins (PrP::YFP). Although self-aggregation was evident, fluorescence resonance energy transfer studies in live yeast co-expressing PrPSc-like protein and PrPDelta112-119 indicated altered interaction properties. These results suggest that the palindrome is required, not only for the attainment of the PrPSc conformation but also to facilitate the proper association of PrPSc with PrPC to effect prion propagation.

Combined pharmacological, mutational and cell biology approaches indicate that p53-dependent caspase 3 activation triggered by cellular prion is dependent on its endocytosis

We have previously established that cellular prion PrP(c) elicited p53-dependent caspase 3 activation in various transfected cells and primary cultured neurons. Although we showed that PrP(c) modulates p53 expression at both transcriptional and post-transcriptional levels, it remained unclear as to whether cellular prion signals at the membrane to trigger intracellular messages or if prion proapoptotic activity necessitated its translocation into the cytoplasm. Here, we compare the processing and cell death-related functions of PrP(c) with those of a mutated PrP(c) protein (N-3F4 MoPrP(c)) in which three basic N-terminal residues responsible for PrP(c) internalization had been mutated. As expected, N-3F4 MoPrP(c) remains exclusively located at the membrane, whereas PrP(c) partitions between membrane-associated and intracellular compartments, but both, proteins undergo constitutive and protein kinase C-regulated disintegrin-mediated proteolysis, leading to N1 fragment production. Unlike PrP(c), N-3F4 MoPrP(c) expression does not induce caspase 3 activation after stimulation by staurosporine and was inert on p53 expression and promoter transactivation in both human cells and TSM1 mouse neurons. Interestingly, PrP(c)-induced caspase 3 activation was closely linked to its endocytosis. This phenotype was enhanced by proteasomal inhibition and prevented by sucrose treatment. Accordingly, immunohistochemical analysis showed that protection towards degradation increased intracellular PrP(c)-like immunoreactivity, while sucrose treatments fully abolished PrP(c) intracellular expression and co-localization with transferrin. Altogether, we, establish here, using combined biochemical, mutational and cell biology approaches, that the caspase 3 activation associated with cellular prion is closely related to its ability to undergo endocytosis. This is, to our knowledge, the first direct description of an endocytosis-dependent PrP(c)-associated function.

Neutralization of transthyretin reverses the neuroprotective effects of secreted amyloid precursor protein (APP) in APPSW mice resulting in tau phosphorylation and loss of hippocampal neurons: support for the amyloid hypothesis

Alzheimer's disease (AD) may be caused by the abnormal processing of the amyloid precursor protein (APP) and the accumulation of beta-amyloid (Abeta). The amyloid precursor protein can be proteolytically cleaved into multiple fragments, many of which have distinct biological actions. Although a high level of Abeta can be toxic, the alpha-secretase cleaved APP (sAPPalpha) is neuroprotective. However, the mechanism of sAPPalpha protection is unknown. Here, we show that sAPPalpha increases the expression levels of several neuroprotective genes and protects organotypic hippocampal cultures from Abeta-induced tau phosphorylation and neuronal death. Antibody interference and small interfering RNA knock-down demonstrate that the sAPPalpha-driven expression of transthyretin and insulin-like growth factor 2 is necessary for protection against Abeta-induced neuronal death. Mice overexpressing mutant APP possess high levels of sAPPalpha and transthyretin and do not develop the tau phosphorylation or neuronal loss characteristic of human AD. Chronic infusion of an antibody against transthyretin into the hippocampus of mice overexpressing APP with the Swedish mutation (APP(Sw)) leads to increased Abeta, tau phosphorylation, and neuronal loss and apoptosis within the CA1 neuronal field. Therefore, the elevated expression of transthyretin is mediated by sAPPalpha and protects APP(Sw) mice from developing many of the neuropathologies observed in AD.

Human Prion Diseases

Compared with that of other human pathogens, the proposed replicative cycle of prions is disarmingly simple. It encompasses misfolding of a single protein, the cellular prion protein (PrPC), into a disease-associated form called PrPSc. This is followed by PrPSc aggregation and possibly fragmentation of aggregates, which may augment the number of replicative units. Although there is no formal proof of the correctness of this model, a wealth of evidence indicates that pathogen-encoded informational nucleic acids are dispensable for prion replication. Despite the simplicity of the replicative process, the human phenotypic range of prion diseases is extremely variable and includes the sporadic, inherited, and acquired forms of Creutzfeldt-Jakob disease. In addition, prion diseases occur in a wide range of animals and can be propagated within and between animal species. The present review article discusses current concepts and controversies surrounding the basic biological features of prions.

A neuronal cell line that does not express either prion or doppel proteins

Prions have been extensively studied since they represent a new class of infectious agents, the pathogenic prion protein (PrPSc). However, a central question on the physiological function of the normal prion protein (PrPC) remains unresolved. A cell model which was previously established from Rikn mice (PrP-/-) remains problematic because of its ectopic expression of the doppel (Dpl) which may have a neurotoxic effect. Here we established neuronal cell lines from Zürich I (PrP-/-) which do not express Dpl protein and ICR mice (PrP+/+) by transfecting with plasmid encoding for the large T antigen of SV40. The transformed cells have shown neuronal characteristics and, thus, these cell lines may provide a useful model to explore the function of neuronal PrPC.

The prion protein and its paralogue Doppel affect calcium signaling in Chinese hamster ovary cells

The function of the prion protein (PrP(c)), implicated in transmissible spongiform encephalopathies (TSEs), is largely unknown. We examined the possible influence of PrP(c) on Ca(2+) homeostasis, by analyzing local Ca(2+) fluctuations in cells transfected with PrP(c) and Ca(2+)-sensitive aequorin chimeras targeted to defined subcellular compartments. In agonist-stimulated cells, the presence of PrP(c) sharply increases the Ca(2+) concentration of subplasma membrane Ca(2+) domains, a feature that may explain the impairment of Ca(2+)-dependent neuronal excitability observed in TSEs. PrP(c) also limits Ca(2+) release from the endoplasmic reticulum and Ca(2+) uptake by mitochondria, thus rendering unlikely the triggering of cell death pathways. Instead, cells expressing Doppel, a PrP(c) paralogue, display opposite effects, which, however, are abolished by the coexpression of PrP(c). These findings are consistent with the functional interplay and antagonistic role attributed to the proteins, whereby PrP(c) protects, and Doppel sensitizes, cells toward stress conditions.