Prion-induced toxicity in PrP transgenic Drosophila

Prion diseases are fatal transmissible neurodegenerative diseases of humans and various vertebrate species. In their natural hosts these conditions are characterised by prolonged incubation times prior to the onset of clinical signs of terminal disease. Accordingly, tractable models of mammalian prion disease are required in order to better understand the mechanisms of prion replication and prion-induced neurotoxicity. Transmission of prion diseases can occur across a species barrier and this is facilitated in recipients transgenic for the same PrP gene as the individual from which the infectious prions are derived. Here we have tested the hypothesis that exogenous ovine prions can induce neurotoxicity in Drosophila melanogaster transgenic for ovine PrP. Drosophila that expressed ovine PrP pan neuronally and inoculated with ovine prions at the larval stage by oral exposure to scrapie-infected sheep brain homogenate showed markedly accelerated locomotor and survival defects. ARQ PrP transgenic Drosophila exposed to scrapie-infected brain homogenate showed a significant and progressive reduction in locomotor activity compared to similar flies exposed to normal sheep brain homogenate. The prion-induced locomotor defect was accompanied by the accumulation of potentially misfolded PrP in the brains of prion-inoculated flies. VRQ PrP transgenic Drosophila, which expressed less ovine PrP than ARQ flies, showed a reduced median survival compared to similar flies exposed to normal sheep brain homogenate. These prion-induced phenotypic effects were PrP-mediated since ovine prions were not toxic in non-PrP transgenic control flies. Our observations provide the basis of an invertebrate model of transmissible mammalian prion disease.     

Effects of agent strain and host genotype on PrP accumulation in the brain of sheep naturally and experimentally affected with scrapie

Different cellular and neuroanatomical types of disease-specific prion protein (PrP(d)) accumulation in the brain were identified in sheep of different breeds and PrP genotypes exposed to experimental or natural scrapie infection. Immunohistochemical examination of the brains of 43 sheep with clinical signs compatible with scrapie revealed 12 different PrP(d)types, which were subjectively quantified in eight different brain regions. The PrP(d)types were grouped into four PrP(d)patterns, the relative magnitude of which provided the PrP(d)profile of each sheep examined. The analysis of the differences in magnitude and relative proportion of each of these PrP(d)types and patterns indicated (1) an effect of the scrapie strain on the PrP(d)profile, and (2) a possible effect of the host genotype on the magnitude of PrP(d)accumulation in the brain, apparently related to the incubation period. Furthermore, intraneuronal deposition of PrP(d)was the type most closely associated with the development of clinical disease. We conclude that different scrapie strains can be distinguished by PrP immunohistochemical examination of brains of affected animals.     

Minimal involvement of the circumventricular organs in the pathogenesis of spontaneously arising and experimentally induced classical bovine spongiform encephalopathy

In sheep infected experimentally with the bovine spongiform encephalopathy (BSE) agent, amplification of infectivity in peripheral organs during early preclinical stages is thought to contribute to high titres of the agent being detected in blood, with subsequent haematogenous neuroinvasion through the circumventricular organs (CVOs). In contrast, little disease-associated prion protein (PrP(d)) or infectivity is detected in the peripheral tissues of cattle during the preclinical and clinical stages of BSE. The aim of this study was to investigate immunohistochemically the role of haematogenous neuroinvasion in cattle with spontaneously arising and experimentally induced BSE. There was almost complete absence of PrP(d) in the peripheral organs of BSE infected cattle. Additionally, there was minimal involvement of the CVOs during preclinical disease and there was progressive caudorostral accumulation of PrP(d) in the brain. These findings do not support haematogenous neuroinvasion in the bovine disease.     

Increased immunohistochemical labelling for prion protein occurs in diverse neurological disorders of sheep: relevance for normal cellular PrP function

The classical prion diseases (e.g. scrapie of sheep and goats and bovine spongiform encephalopathy of cattle) are characterized by the accumulation of abnormal forms of the prion protein (PrP), usually recognized by their relative resistance to proteolysis compared with the physiological cellular forms of PrP. However, novel prion diseases have been detected in sheep, cattle and man, in which the abnormal PrP has less resistance to proteolysis than identified previously. These more subtle differences between abnormal and normal forms of PrP can be problematic in routine diagnostic tests and raise questions in respect of the range of PrP disorders. Abnormal accumulations of PrP in atypical and classical prion diseases can be recognized by immunohistochemistry. To determine whether altered PrP expression or trafficking might occur in nosological entities not previously connected with prion disease, the brains of sheep affected with diverse neurological conditions were examined for evidence of altered PrP labelling. Such altered immunolabelling was detected in association with either basic lesions or specific diseases. Some reactive glial cells and degenerate neurons found in several different recognized disorders and non-specific inflammatory processes were associated with abnormal PrP labelling, which was absent from brains of healthy, age-matched sheep. The results agree with previous indications that normal PrP function may be linked with the oxidative stress response, but the data also suggest that PrP functions are more extensive than simple protective responses against stress insults.     

Close vicinity of PrP expressing cells (FDC) with noradrenergic fibers in healthy sheep spleen

In naturally and experimentally occurring scrapie in sheep, prions invade the immune system and replicate in lymphoid organs. Here we analysed immunohistochemically, in seven spleens of 6-month-old healthy sheep, the nature of the cells expressing prion protein (PrP) potentially supporting prion replication, as well as their relationship with autonomic innervation. PrP was identified using either RB1 rabbit antiserum or 4F2 monoclonal antibody directed against AA 108-123 portion of the bovine and AA 79-92 of human prion protein respectively. Using double labelling analysis, we demonstrated that PrPc is expressed by follicular dendritic cells using a specific monoclonal antibody (CNA42). We also showed the close vicinity of these PrP expressing cells with noradrenergic fibers, using a polyclonal tyrosine hydroxylase antibody. Our results may help the study of the cellular requirements for the possible neuroinvasion from the spleen.     

Protease-resistant prion protein in brain and lymphoid organs of sheep within a naturally scrapie-infected flock

The hallmark of transmissible spongiform encephalopathies (TSE), such as scrapie in sheep, is the accumulation in tissues of an insoluble and protease resistant form (PrPres) of the cellular prion protein. In this study, we evaluated whether the diversity in both the clinical pattern and the PrP genotypes of scrapied sheep from the same flock was connected with different levels and/or glycoform patterns of the PrPres in the brain and lymphoid organs of the animals. Whereas the PrPres levels in spleen, lymph nodes and tonsils from sheep of different PrP genotypes and clinical status appeared comparable, they were highly variable in brain, particularly in the brain stem and the cerebellum. PrPres was only detected in sheep bearing at least one VRQ allele, including three asymptomatic sheep and the highest PrPres load was found in the cerebellum of VRQ/VRQ animals. All together, levels of PrPres in brain did not necessarily correlate with the severity of the clinical disease but might depend on the PrP genotype of the animals. Different brain regions from a given sheep displayed a similar glycopattern of PrPres, whereas the apparent molecular sizes of the unglycosylated and diglycosylated forms of the protein differed between brain and lymphoid tissues. We did not find any notifiable differences in the glycopattern of PrPres in brain from sheep of different PrP genotypes or different clinical status and this PrPres glycotype was also similar to that found in brain from four cattle BSE.     

Differential diagnosis of infections with the bovine spongiform encephalopathy (BSE) and scrapie agents in sheep.

Scrapie, bovine spongiform encephalopathy (BSE), and variant Creutzfeldt-Jakob disease belong to the group of disorders called transmissible spongiform encephalopathies or prion diseases. The possibility that some sheep may be infected with the BSE agent is of human and animal health concern. Immunohistochemical methods were used to identify specific prion protein (PrP) peptide sequences in specific cell types of the brain and lymphoreticular system (LRS) of sheep with natural scrapie and Suffolk and Romney sheep infected experimentally with the BSE agent. Clinically affected and some pre-clinical cases of BSE infection could be distinguished from scrapie cases by the lesser amount of labelling of PrP containing the 84-102 amino-acid peptide sequences in phagocytic cells of the LRS and brain. Additionally, BSE-infected sheep had higher degrees of intra-neuronal PrP accumulation in the brain, as detected by labelling for a range of PrP peptide sequences. These results suggest that there is strain-dependent processing of PrP in specific cell types within the nervous system and LRS which can be used to distinguish BSE- and scrapie-infected sheep.     

Selective expression of prion protein in peripheral tissues of the adult mouse

The level of expression of normal cellular prion protein, PrP(c) (cellular prion protein), controls both the rate and the route of neuroinvasive infection, from peripheral entry portal to the CNS. Paradoxically, an overview of the distribution of PrP(c) within tissues outside the CNS is lacking. We have used novel antibodies that recognise cellular prion protein in glutaraldehyde-fixed tissue (in order to optimise immunohistochemical labelling of this conformationally labile protein), in combination with in situ hybridisation, to examine the expression of PrP(c) in peripheral tissues of the adult mouse. We found that although prion protein is expressed in many tissues, it is expressed at high levels only in discrete subpopulations of cells. Prominent amongst these are elements of the "hardwired neuroimmune network" that integrate the body's immune defence and neuroendocrine systems under CNS control. These prion protein-expressing elements include small diameter afferent nerves in the skin and the lamina propria of the aerodigestive tract, sympathetic ganglia and nerves, antigen presenting and processing cells (both follicular and non-follicular dendritic cells) and sub-populations of lymphocytes particularly in skin, gut- and bronchus-associated lymphoid tissues. Prion protein is also expressed in the parasympathetic and enteric nervous systems, in the dispersed neuroendocrine system, and in peripheral nervous system axons and their associated Schwann cells. This selective expression of cellular prion protein provides a variety of alternative routes for the propagation and transport of prion infection entering from peripheral sites, either naturally (via the aerodigestive tract or abraded skin) or experimentally (by intraperitoneal injection) to the brain. Key regulatory cells that express prion protein, and in particular enteroendocrine cells in the mucosal wall of the gut, and dendritic cells that convey pathogens from epithelial layers to secondary lymphoid organs, may be particularly important in the transmission of infection in the periphery.     

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.     

Vacuolar lesion profile in sheep scrapie: factors influencing its variation and relationship to disease-specific PrP accumulation

Detailed neuropathological examination for vacuolar lesions was performed on the brains of 42 sheep with clinical signs compatible with scrapie. The sheep were grouped according to their breed (Poll-Dorset, Cheviot, Welsh Mountain, Shetland and Suffolk), their PrP genotype at codons 136, 154 and 171 (VRQ/VRQ, VRQ/ARQ, VRQ/ARR and ARQ/ARQ) and the type of infection (experimental infection with SSBP/1, or natural disease). Twenty-two neuroanatomical sites from seven brain regions were examined for vacuolation in the neuropil and five sites at the level of the obex were examined for intraneuronal vacuolation. In 36 sheep, immunohistochemical examination for disease-specific PrP (PrP(d)) accumulation had also been performed in the same brain regions in an earlier study. The magnitude of total neuropil vacuolation was highest in the naturally affected ARQ/ARQ Suffolk sheep and lowest in the experimentally infected VRQ/VRQ Cheviot sheep and VRQ/ARR Poll-Dorset sheep. The severity of neuropil vacuolation at nine of the 22 neuroanatomical sites examined was used to generate a vacuolar lesion profile, which showed variations between the different sheep groups. These variations could be attributed to both PrP genotype and sheep breed and also possibly to scrapie agent; there was, however, considerable individual variation in lesion profile within sheep groups. All groups showed a similar ratio of neuropil vacuolation to neuronal vacuolation at the level of the obex. Although a positive correlation between neuropil vacuolation and PrP(d) deposition was generally observed, it was low except for the astrocyte-associated pattern of PrP(d) accumulation. The study suggests that vacuolar lesion profiles in sheep are affected by several factors and, by comparison with lesion profiles in mice, are of no more than limited value for discriminating between scrapie strains.     

Detection of PrP(Sc) in rectal biopsy and necropsy samples from sheep with experimental scrapie

Scrapie diagnosis is based on the demonstration of disease-associated prion protein (PrP(Sc)) in brain or, in the live animal, in readily accessible peripheral lymphoid tissue. Lymphatic tissues present at the rectoanal line were readily obtained from sheep without the need for anaesthesia. The presence of PrP(Sc) in such tissue was investigated in sheep infected orally with scrapie-infected brain material. The methods used consisted of immunohistochemistry and histoblotting on biopsy and post-mortem material. PrP(Sc) was detected in animals with PrP genotypes associated with high susceptibility to scrapie from 10 months after infection, i.e., from about the time of appearance of early clinical signs. In the rectal mucosa, PrP(Sc) was found in lymphoid follicles and in cells scattered in the lamina propria, often near and sometimes in the crypt epithelium. By Western blotting, PrP(Sc) was detected in rectal biopsy samples of sheep with the PrP genotype VRQ/VRQ, after electrophoresis of material equivalent to 8 mg of tissue. This study indicated that rectal biopsy samples should prove useful for the diagnosis of scrapie in sheep.     

Occurrence and distribution of infection-specific PrP in tissues of clinical scrapie cases and cull sheep from scrapie-affected farms in Shetland

The prion protein (PrP) genotypes of all cull sheep originating from four scrapie-affected farms in Shetland in 1998-1999 were determined and a representative sample of the different genotypes was selected for necropsy. Samples of brain and selected viscera were removed from 159 such sheep aged 2-11 years. These samples were examined immunohistochemically and by Western blotting for infection-specific forms of PrP. None of the sheep bearing the following genotypes showed any evidence of PrP accumulation in brain, intestine, selected lymph nodes or the cranial mesenteric ganglia: ARQ/ARQ (n = 41), ARQ/ARH (n = 12), ARH/ARH (n = 2), ARQ/ARR (n = 24), ARR/ARR (n= 2). In five of 71 sheep bearing a single VRQ allele, PrP accumulation was detected immunohistochemically in viscera or brain, or both. These results suggested that only a small proportion of susceptible sheep showed evidence of infection (accumulation of PrP) on the farms studied, and that even sheep of the most susceptible genotype (VRQ/VRQ) did not invariably develop disease in an infected environment. Furthermore, there was no evidence that, in sheep of semi-resistant or fully resistant genotypes, infection could be sequestered within the lymphoreticular system or peripheral nervous system and thereby provide a possible "carrier" source of infection. Rather, the data suggested that some sheep, possibly because they had been exposed to a relatively low infective dose, became infected and accumulated the infective agent over a protracted pre-clinical phase of the disease. Such sheep might be potentially infective for many years. In two VRQ/ARR genotype sheep, PrP was confined to the brain. Infection-specific PrP was also confined to the brain in two of 24 clinical cases of VRQ/ARQ scrapie. Thus, direct neuroinvasion, apparently without a prior phase of replication in the lymphoreticular system, occurred in a proportion of VRQ/ARQ sheep. Possibly it may occur in all sheep of the VRQ/ARR genotype. The factors responsible for direct neuroinvasion are not understood. However, it cannot be attributed to genotype alone.     

Detection of ultra-low levels of pathologic prion protein in scrapie infected hamster brain homogenates using real-time immuno-PCR

Pathologic prion protein (PrP(Sc)), implicated in transmissible spongiform encephalopathies, is detected by antibody-based tests or bioassays to confirm the diagnosis of prion diseases. Presently, the Western blot or an ELISA is officially used to screen the brain stem in cattle for the presence of PrP(Sc). The immuno-polymerase chain reaction (IPCR), a technique whereby the exponential amplification ability of PCR is coupled to the detection of proteins by antibodies in an ELISA format, was applied in a modified real-time IPCR method to detect ultra-low levels of prion protein. Using IPCR, recombinant hamster PrP(C) was consistently detected at 1 fg/mL and proteinase K (PK)-digested scrapie infected hamster brain homogenates diluted to 10(-8) (approximately 10-100 infectious units) was detected with a semi-quantitative dose response. This level of detection is 1 million-fold more sensitive than the levels detected by Western blot or ELISA and poises IPCR as a method capable of detecting PrP(Sc) in the pre-clinical phase of infection. Further, the data indicate that unless complete PK digestion of PrP(C) in biological materials is verified, ultrasensitive assays such as IPCR may inaccurately classify a sample as positive.     

Detection of type 1 prion protein in variant Creutzfeldt-Jakob disease

Molecular typing of the abnormal form of the prion protein (PrP(Sc)) has come to be regarded as a powerful tool in the investigation of the prion diseases. All evidence thus far presented indicates a single PrP(Sc) molecular type in variant Creutzfeldt-Jakob disease (termed type 2B), presumably resulting from infection with a single strain of the agent (bovine spongiform encephalopathy). Here we show for the first time that the PrP(Sc) that accumulates in the brain in variant Creutzfeldt-Jakob disease also contains a minority type 1 component. This minority type 1 PrP(Sc) was found in all 21 cases of variant Creutzfeldt-Jakob disease tested, irrespective of brain region examined, and was also present in the variant Creutzfeldt-Jakob disease tonsil. The quantitative balance between PrP(Sc) types was maintained when variant Creutzfeldt-Jakob disease was transmitted to wild-type mice and was also found in bovine spongiform encephalopathy cattle brain, indicating that the agent rather than the host specifies their relative representation. These results indicate that PrP(Sc) molecular typing is based on quantitative rather than qualitative phenomena and point to a complex relationship between prion protein biochemistry, disease phenotype and agent strain.     

A domain responsible for spontaneous conversion of bank vole prion protein

Bank vole is a small rodent that shows high susceptibility to infection with diverse prion strains. To determine whether the increased susceptibility of bank voles to prion diseases can be attributed to the intrinsic nature of bank vole prion protein (PrP) or to host factors other than PrP, we produced transgenic mice overexpressing bank vole PrP. These transgenic mice spontaneously developed neurological illness with spongiform changes and the accumulation of abnormal PrP in the brain. Then, we produced transgenic mice overexpressing chimeric mouse/bank vole PrP, which differs from mouse PrP only at two residues located at the C‐terminus, to determine the minimum essential domain for the induction of spontaneous generation of abnormal PrP. These transgenic mice also developed spontaneous neurological illness with spongiform changes and the accumulation of abnormal PrP in the brain. In addition, knock‐in mice expressing bank vole PrP at the same level as that of wild‐type mice did not develop spontaneous disease but showed high susceptibility to infection with diverse prion strains, similarly to bank voles. Taken together, these findings show that bank vole PrP has a high propensity for the conformational conversion both in spontaneous disease and in prion infection, probably due to the characteristic structural properties of the C‐terminal domain.     

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.     

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.