Hypoxia-inducible factor-1 alpha regulates prion protein expression to protect against neuron cell damage

The human prion protein fragment, PrP (106-126), may contain a majority of the pathological features associated with the infectious scrapie isoform of PrP, known as PrP(Sc). Based on our previous findings that hypoxia protects neuronal cells from PrP (106-126)-induced apoptosis and increases cellular prion protein (PrP(C)) expression, we hypothesized that hypoxia-related genes, including hypoxia-inducible factor-1 alpha (HIF-1α), may regulate PrP(C) expression and that these genes may be involved in prion-related neurodegenerative diseases. Hypoxic conditions are known to elicit cellular responses designed to improve cell survival through adaptive processes. Under normoxic conditions, a deferoxamine-mediated elevation of HIF-1α produced the same effect as hypoxia-inhibited neuron cell death. However, under hypoxic conditions, doxorubicin-suppressed HIF-1α attenuated the inhibitory effect on neuron cell death mediated by PrP (106-126). Knock-down of HIF-1α using lentiviral short hairpin (sh) RNA-induced downregulation of PrP(C) mRNA and protein expression under hypoxic conditions, and sensitized neuron cells to prion peptide-mediated cell death even in hypoxic conditions. In PrP(C) knockout hippocampal neuron cells, hypoxia increased the HIF-1α protein but the cells did not display the inhibitory effect of prion peptide-induced neuron cell death. Adenoviruses expressing the full length Prnp gene (Ad-Prnp) were utilized for overexpression of the Prnp gene in PrP(C) knockout hippocampal neuron cells. Adenoviral transfection of PrP(C) knockout cells with Prnp resulted in the inhibition of prion peptide-mediated cell death in these cells. This is the first report demonstrating that expression of normal PrP(C) is regulated by HIF-1α, and PrP(C) overexpression induced by hypoxia plays a pivotal role in hypoxic inhibition of prion peptide-induced neuron cell death. These results suggest that hypoxia-related genes, including HIF-1α, may be involved in the pathogenesis of prion-related diseases and as such may be a therapeutic target for prion-related neurodegenerative diseases.     

Prion replication alters the distribution of synaptophysin and caveolin 1 in neuronal lipid rafts

The main event in the pathogenesis of prion diseases is the conversion of the cellular prion protein (PrP(C)) into the abnormal, protease-resistant prion protein (PrP(res)). PrP(C) is a GPI-anchored protein located in lipid rafts or detergent-resistant membranes (DRMs). Here we describe the association of PrP with DRMs in neuronal cell bodies and axons during the course of murine scrapie and its relation with the distribution of the PrP-interacting proteins caveolin 1 and synaptophysin. Scrapie infection triggered the accumulation of PrP(res) in DRMs from retinas and optic nerves from early stages of the disease before evidence of neuronal cell loss. Most of the PrP(res) remained associated with lipid rafts throughout different stages in disease progression. In contrast to PrP(res), caveolin 1 and synaptophysin in retina and optic nerves shifted to non-DRM fractions during the course of scrapie infection. The accumulation of PrP(res) in DRMs was not associated with a general alteration in their composition, because no change in the total protein distribution across the sucrose gradient or in the flotation characteristics of the glycosphingolipid GM1 or Thy-1 were observed until advanced stages of the disease. However, an increase in total cholesterol levels was observed in optic nerve and retinas. Only during late stages of the disease was a decrease in the number of neuronal cell bodies observed, suggesting that synaptic abnormalities are the earliest sign of neuronal dysfunction that ultimately results in neuronal death. These results indicate that prion replication triggers an abnormal localization of caveolin 1 and synaptophysin, which in turn may alter neuronal function.     

Neuroprotective effects of the cellular prion protein in autoimmune optic neuritis

Although the pathologic role of the prion protein in transmissible spongiform encephalopathic diseases has been widely investigated, the physiologic role of the cellular prion protein (PrP(C)) is not known. Among the many functions attributed to PrP(C), there is increasing evidence that it is involved in cell survival and mediates neuroprotection. A potential role in the immune response has also been suggested. However, how these two functions interplay in autoimmune disease is unclear. To address this, autoimmune optic neuritis, a model of multiple sclerosis, was induced in C57Bl/6 mice, and up-regulation of PrP(C) was observed throughout the disease course. In addition, compared with wild-type mice, in PrP(C)-deficient mice and mice overexpressing PrP(C), histopathologic analysis demonstrated that optic neuritis was exacerbated, as indicated by axonal degeneration, inflammatory infiltration, and demyelination. However, significant neuroprotection of retinal ganglion cells, the axons of which form the optic nerve, was observed in mice that overexpressed PrP(C). Conversely, mice lacking PrP(C) demonstrated significantly more neurodegeneration. This suggests that PrP(C) may have a neuroprotective function independent of its role in regulating the immune response.     

Involvement of the cellular prion protein in the migration of brain microvascular endothelial cells

The conversion of cellular prion protein (PrP(C)) to its protease-resistant isoform is involved in the pathogenesis of prion disease. Although PrP(C) is a ubiquitous glycoprotein that is present in various cell types, the physiological role of PrP(C) remains obscure. The present study aimed to determine whether PrP(C) mediates migration of brain microvascular endothelial cells. Small interfering RNAs (siRNAs) targeting PrP(C) were transfected into a mouse brain microvascular endothelial cell line (bEND.3 cells). siPrP1, selected among three siRNAs, reduced mRNA and protein levels of PrP(C) in bEND.3 cells. Cellular migration was evaluated with a scratch-wound assay. siPrP1 suppressed migration without significantly affecting cellular proliferation. This study provides the first evidence that PrP(C) may be necessary for brain microvascular endothelial cells to migrate into damaged regions in the brain. This function of PrP(C) in the brain endothelium may be a mechanism by which the neurovascular unit recovers from an injury such as an ischemic insult.     

Packaging of prions into exosomes is associated with a novel pathway of PrP processing

Prion diseases are fatal, transmissible neurodegenerative disorders associated with conversion of the host-encoded prion protein (PrP(C)) into an abnormal pathogenic isoform (PrP(Sc)). Following exposure to the infectious agent (PrP(Sc)) in acquired disease, infection is propagated in lymphoid tissues prior to neuroinvasion and spread within the central nervous system. The mechanism of prion dissemination is perplexing due to the lack of plausible PrP(Sc)-containing mobile cells that could account for prion spread between infected and uninfected tissues. Evidence exists to demonstrate that the culture media of prion-infected neuronal cells contain PrP(Sc) and infectivity but the nature of the infectivity remains unknown. In this study we have identified PrP(C) and PrP(Sc) in association with endogenously expressing PrP neuronal cell-derived exosomes. The exosomes from our prion-infected neuronal cell line were efficient initiators of prion propagation in uninfected recipient cells and to non-neuronal cells. Moreover, our neuronal cell line was susceptible to infection by non-neuronal cell-derived exosome PrP(Sc). Importantly, these exosomes produced prion disease when inoculated into mice. Exosome-associated PrP is packaged via a novel processing pathway that involves the N-terminal modification of PrP and selection of distinct PrP glycoforms for incorporation into these vesicles. These data extend our understanding of the relationship between PrP and exosomes by showing that exosomes can establish infection in both neighbouring and distant cell types and highlight the potential contribution of differentially processed forms of PrP in disease distribution. These data suggest that exosomes represent a potent pool of prion infectivity and provide a mechanism for studying prion spread and PrP processing in cells endogenously expressing PrP.     

Neural stem cell model for prion propagation

The study of prion transmission and targeting is a major scientific issue with important consequences for public health. Only a few cell culture systems that are able to convert the cellular isoform of the prion protein into the pathologic scrapie isoform of the prion protein (PrP(Sc)) have been described. We hypothesized that central nervous system neural stem cells (NSCs) could be the basis of a new cell culture model permissive to prion infection. Here, we report that monolayers of differentiated fetal NSCs and adult multipotent progenitor cells isolated from mice were able to propagate prions. We also demonstrated the large influence of neural cell fate on the production of PrP(Sc), allowing the molecular study of prion neuronal targeting in relation with strain differences. This new stem cell-based model, which is applicable to different species and to transgenic mice, will allow thoughtful investigations of the molecular basis of prion diseases, and will open new avenues for diagnostic and therapeutic research.     

Spread of classic BSE prions from the gut via the peripheral nervous system to the brain

An experimental oral bovine spongiform encephalopathy (BSE) challenge study was performed to elucidate the route of infectious prions from the gut to the central nervous system in preclinical and clinical infected animals. Tissue samples collected from the gut and the central and autonomic nervous system from animals sacrificed between 16 and 44 months post infection (mpi) were examined for the presence of the pathological prion protein (PrP(Sc)) by IHC. Moreover, parts of these samples were also bioassayed using bovine cellular prion protein (PrP(C)) overexpressing transgenic mice (Tgbov XV) that lack the species barrier for bovine prions. A distinct accumulation of PrP(Sc) was observed in the distal ileum, confined to follicles and/or the enteric nervous system, in almost all animals. BSE prions were found in the sympathetic nervous system starting at 16 mpi, and in the parasympathetic nervous system from 20 mpi. A clear dissociation between prion infectivity and detectable PrP(Sc) deposition became obvious. The earliest presence of infectivity in the brain stem was detected at 24 mpi, whereas PrP(Sc) accumulation was first detected after 28 mpi. In summary, our results decipher the centripetal spread of BSE prions along the autonomic nervous system to the central nervous system, starting already halfway in the incubation time.     

Neuroinvasion of prions: insights from mouse models

The prion was defined by Stanley B. Prusiner as the infectious agent that causes transmissible spongiform encephalopathies. A pathological protein accumulating in the brain of scrapie-infected hamsters was isolated in 1982 and termed prion protein (PrPSc). Its cognate gene Prnp was identified more than a decade ago by Charles Weissmann, and shown to encode the host protein PrP(C). Since the latter discovery, transgenic mice have contributed many important insights into the field of prion biology, including the understanding of the molecular basis of the species barrier for prions. By disrupting the Prnp gene, it was shown that an organism that lacks PrP(C) is resistant to infection by prions. Introduction of mutant PrP genes into PrP-deficient mice was used to investigate the structure-activity relationship of the PrP gene with regard to scrapie susceptibility. Ectopic expression of PrP in PrP knockout mice proved a useful tool for the identification of host cells competent for prion replication. Finally, the availability of PrP knockout mice and transgenic mice overexpressing PrP allows selective reconstitution experiments aimed at expressing PrP in neurografts or in specific populations of haemato- and lymphopoietic cells. The latter studies have allowed us to clarify some of the mechanisms of prion spread and disease pathogenesis.     

Effect of the E200K mutation on prion protein metabolism. Comparative study of a cell model and human brain

The hallmark of prion diseases is the cerebral accumulation of a conformationally altered isoform (PrP(Sc)) of a normal cellular protein, the prion protein (PrP(C)). In the inherited form, mutations in the prion protein gene are thought to cause the disease by altering the metabolism of the mutant PrP (PrP(M)) engendering its conversion into PrP(Sc). We used a cell model to study biosynthesis and processing of PrP(M) carrying the glutamic acid to lysine substitution at residue 200 (E200K), which is linked to the most common inherited human prion disease. PrP(M) contained an aberrant glycan at residue 197 and generated an increased quantity of truncated fragments. In addition, PrP(M) showed impaired transport of the unglycosylated isoform to the cell surface. Similar changes were found in the PrP isolated from brains of patients affected by the E200K variant of Creutzfeldt-Jakob disease. Although the cellular PrP(M) displayed some characteristics of PrP(Sc), the PrP(Sc) found in the E200K brains was quantitatively and qualitatively different. We propose that the E200K mutation cause the same metabolic changes of PrP(M) in the cell model and in the brain. However, in the brain, PrP(M) undergoes additional modifications, by an age-dependent mechanism that leads to the formation of PrP(Sc) and the development of the disease.     

Disease-associated prion protein is not detectable in human systemic amyloid deposits

Cerebral and cardiac amyloid deposits have been reported after scrapie infection in transgenic mice expressing variant prion protein (PrP(C)) lacking the glycophosphatidylinositol anchor. The amyloid fibril protein in the systemic amyloid deposits was not characterized, and there is no clinical or pathological association between prion diseases and systemic amyloidosis in humans. Nevertheless, in view of the potential clinical significance of these murine observations, we tested both human amyloidotic tissues and isolated amyloid fibrils for the presence of PrP(Sc), the prion protein conformation associated with transmissible spongiform encephalopathy (TSE). We also sequenced the complete prion protein gene, PRNP, in amyloidosis patients. No specific immunohistochemical staining for PrP(Sc) was obtained in the amyloidotic cardiac and other visceral tissues of patients with different types of systemic amyloidosis. No protease-resistant prion protein, PrP(res), was detectable by Western blotting of amyloid fibrils isolated from cardiac and other systemic amyloid deposits. Only the complete normal wild-type PRNP gene sequence was identified, including the usual distribution of codon 129 polymorphisms. These reassuringly negative results do not support the idea that there is any relationship of prions or TSE with human systemic amyloidosis, including cardiac amyloid deposition.     

Application of a novel in vitro selection technique to isolate and characterise high affinity DNA aptamers binding mammalian prion proteins

Clinical diagnosis and research into transmissible spongiform encephalopathies are hampered by the lack of sufficiently sensitive and specific reagents able to adequately detect the normal cellular form of the prion protein, PrP(C), and the pathological isoform, PrP(Sc). In order to provide such reagents, we applied Systematic Evolution of Ligands by EXponential enrichment (SELEX) against a recombinant murine prion protein, to select single-stranded DNA ligands (aptamers) of high affinity. The SELEX protocol and subsequent aptamer characterisation employed protein immobilisation/partitioning using nickel-complexed magnetic particles and a novel SYBR Green-mediated quantitative real-time PCR technique. Following eight rounds of selection, the enriched aptamer pool was cloned and 24 clones sequenced. Seven of these were 'orphan' clones and the remainder were grouped into three separate T-rich families. All but four of the aptamer clones exhibited specific binding to the murine prion protein and the majority also bound to human and ovine prion proteins. Dissociation constants (K(d)) ranged from 18 to 79 nM. Flow cytometry with fluorescein-labelled aptamers confirmed that binding to cells was dependent on the expression of PrP(C). Preliminary studies also indicate that a trivalent aptamer pool is capable of binding the pathological isoform PrP(Sc) following guanidinium denaturation.     

Family reunion--the ZIP/prion gene family

Prion diseases are fatal neurodegenerative diseases of humans and animals which, in addition to sporadic and familial modes of manifestation, can be acquired via an infectious route of propagation. In disease, the prion protein (PrP(C)) undergoes a structural transition to its disease-causing form (PrP(Sc)) with profoundly different physicochemical properties. Surprisingly, despite intense interest in the prion protein, its function in the context of other cellular activities has largely remained elusive. We recently employed quantitative mass spectrometry to characterize the interactome of the prion protein in a murine neuroblastoma cell line (N2a), an established cell model for prion replication. Extensive bioinformatic analyses subsequently established an evolutionary link between the prion gene family and the family of ZIP (Zrt-, Irt-like protein) metal ion transporters. More specifically, sequence alignments, structural threading data and multiple additional pieces of evidence placed a ZIP5/ZIP6/ZIP10-like ancestor gene at the root of the PrP gene family. In this review we examine the biology of prion proteins and ZIP transporters from the viewpoint of a shared phylogenetic origin. We summarize and compare available data that shed light on genetics, function, expression, signaling, post-translational modifications and metal binding preferences of PrP and ZIP family members. Finally, we explore data indicative of retropositional origins of the prion gene founder and discuss a possible function for the prion-like (PL) domain within ZIP transporters. While throughout the article emphasis is placed on ZIP proteins, the intent is to highlight connections between PrP and ZIP transporters and uncover promising directions for future research.     

Distinct proteinase K-resistant prion protein fragment in goats with no signs of disease in a classical scrapie outbreak

Considerable efforts have been directed toward the identification of small-ruminant prion diseases, i.e., classical and atypical scrapie as well as bovine spongiform encephalopathy (BSE). Here we report the in-depth molecular analysis of the proteinase K-resistant prion protein core fragment (PrP(res)) in a highly scrapie-affected goat flock in Greece. The PrP(res) profile by Western immunoblotting in most animals was that of classical scrapie in sheep. However, in a series of clinically healthy goats we identified a unique C- and N-terminally truncated PrP(res) fragment, which is akin but not identical to that observed for atypical scrapie. These findings reveal novel aspects of the nature and diversity of the molecular PrP(res) phenotypes in goats and suggest that these animals display a previously unrecognized prion protein disorder.     

The normal cellular form of prion protein modulates T cell responses

Expression of the normal form of prion protein (PrP(C)) has been reported on a wide range cells including lymphocytes and antigen presenting cells, however the functional role of PrP(C) remains to be fully elucidated. Here we report the effect of reintroducing the PrP gene into splenocytes derived from prion knockout (PrP 0/0) mice and comparing their responses with splenocytes lacking a functional PrP gene. Reintroduction of the PrP gene was carried out by transfecting cells with pC1PrPEH, a plasmid expressing mouse PrP. Following transfection, T cells demonstrated an increased capacity to proliferate in response to ConA and PMA/ionomycin compared to T cells lacking the functional PrP gene. A bioassay used to determine IL-2 levels indicated that the reintroduction of the PrP gene might enhance IL-2 expression in response to ConA. Levels of IFN-gamma produced also showed an increase following transfection with PrP expressing plasmid. A comparison between splenocytes derived from PrP 0/0 and PrP +/+ also demonstrated some differences in cytokine production and proliferation. Together these results show PrP(C) has an impact on the normal T cell activation and proliferation in response to mitogens and also potentially antigen responsiveness.     

Identification of an epitope on the recombinant bovine PrP that is able to elicit a prominent immune response in wild-type mice

The main cause for the development of transmissible spongiform encephalopathies (TSE) is the conformational change of prion protein from the normal cellular isoform (PrP(C)) into the abnormal isoform, named prion (PrP(Sc)). The two isoforms have the same primary structure, and with PrP being highly conserved among different species, no immune response to PrP(Sc) has been observed in infected humans or other mammals so far. The problem of inducing immune response was encountered when producing monoclonal antibodies against PrP, therefore mice lacking a functional Prnp gene were predominantly used for the immunization. In the present paper we report that by immunizing wild-type BALB/c mice with chemically unmodified recombinant bovine PrP a potent humoral immune response was achieved. Furthermore, we were able to isolate the monoclonal antibody (mAb) E12/2 and few other mAbs, all reacting specifically with bovine and human PrP, but not with PrP from several other mammals. The epitope of mAb E12/2 is located at the C-terminal end of helix 1, with His155 being crucial for binding. It has been proven that mAb E12/2 is useful for human and bovine TSE research as well as for diagnostics. Our results show that there are sufficient structural differences between mouse and bovine PrP to provoke a prominent humoral immune response.     

Upregulation of cellular prion protein (PrPc) after focal cerebral ischemia and influence of lesion severity

The pathological isoform of the prion protein (PrP(Sc)) has been identified to mediate transmissible spongiform encephalopathies like Creutzfeldt-Jakob disease (CJD). In contrast, the physiological function of the normal cellular prion protein (PrP(c)) is not yet understood. Recent findings suggest that PrP(c) may have neuroprotective properties and that its absence increases susceptibility to oxidative stress and neuronal injury. To determine whether PrP(c) is part of the cellular response to neuronal injury in vivo, we investigated PrP(c) regulation after severe and mild focal ischemic brain injury in mice using the thread occlusion stroke model. Western Blot and ELISA analysis showed a significant upregulation of PrP(c) in the ischemic hemisphere at 4 and 8h after onset of permanent focal ischemia, which was no longer detectable at 24h after lesion induction when compared to control animals. In contrast, transient focal ischemia (60 min) did only lead to slightly but not significantly elevated PrP(c) levels in the ischemic hemisphere when compared to controls. These results demonstrate that cerebral PrP(c) is upregulated early in response to focal cerebral ischemia. The extent of upregulation, however, seems to depend on the severity of ischemia and may therefore reflect the extent of ischemia induced neuronal damage. Given the known neuroprotective effects of PrP(c) in vitro, ischemia-induced upregulation of cerebral PrP(c) supports the hypothesis that, as part of an early adaptive cellular response to ischemic brain injury, PrP(c) may be involved in the regulation of ischemia-induced neuronal cell death in vivo.