Developmental regulation of prion protein mRNA in brain

During development of the hamster brain, synthesis of the cellular isoform of the scrapie prion protein (PrPC) was found to be regulated. Low levels of PrP poly(A)+ mRNA were detectable one day after birth. PrP poly(A)+ mRNA reached maximal levels between 10 and 20 days post-partum; thereafter, no change in its level could be detected at ages up to 13 months. In contrast, myelin basic protein poly(A)+ mRNA was shown to reach maximal levels by 30 days of age and thereafter steadily declined in adult brain. Using monospecific PrP antisera, immunoprecipitable cell-free translation products were detected at low levels two days after birth and progressively increased up to 10 days of age. How the PrP mRNA participates in brain development and its function in scrapie prion infection are being investigated.

Novel mechanisms of degeneration of the central nervous system--prion structure and biology

Prion is a term for the novel infectious agents which cause scrapie and Creutzfeldt-Jakob disease; these infectious pathogens are composed largely, if not entirely, of prion protein (PrP) molecules. No prion-specific polynucleotide has been identified. Considerable evidence indicates that PrP 27-30 is required for and inseparable from scrapie infectivity. PrP 27-30 is derived from a larger protein, denoted PrPSc. A cellular isoform, designated PrPC, and PrPSc are both encoded by a single copy chromosomal gene and both proteins appear to be translated from the same 2.1 kb mRNA. Monoclonal antibodies to PrP 27-30 as well as antisera to PrP synthetic peptides, react with both PrPC and PrPSc, establishing the relatedness of these proteins. PrPC is completely digested by proteinase K; PrPSc is converted to PrP 27-30 under the same conditions. Detergent extraction of microsomal membranes isolated from scrapie-infected hamster brains solubilizes PrPC but induces PrPSc to polymerize into amyloid rods. This procedure allows separation of the two prion protein isoforms and the demonstration that PrPSc accumulates during scrapie infection while the level of PrPC does not change. The prion amyloid rods generated by detergent extraction are identical morphologically, except for length, to extracellular collections of prion amyloid filaments which form plaques in scrapie- and CJD-infected brains. The prion amyloid plaques stain with antibodies to PrP 27-30 and PrP peptides. Prion rods composed of PrP 27-30 dissociate into phospholipid vesicles with full retention of scrapie infectivity. The murine PrP gene (Prn-p) is linked to the Prn-i gene, which controls the length of the scrapie incubation period. Prolonged incubation times are a cardinal feature of scrapie and CJD. While the central role of PrPSc in scrapie pathogenesis is well established, the chemical and conformational differences between PrPC and PrPSc are unknown but presumably arise from post-translational events.

Scrapie-associated fibrils, PrP protein and the Sinc gene

Scrapie-associated fibrils (SAF) are disease-specific structures found in extracts of the brains of animals affected with scrapie. These structures are pathological aggregates of a normal host protein called PrP. In collaboration with Konrad Beyreuther (Heidelberg), we have characterized the multiple forms of PrP found in SAF fractions from mouse brain affected by the ME7 strain of scrapie. There is no in vivo N-terminal cleavage of the most abundant forms of PrP. However, N-terminal cleavage of some minor forms of PrP does occur in vivo within a domain of repetitive sequences at sites similar to but distinct from those cut by proteinase K in vitro. We suggest that such covalently modified forms of PrP may be the result of enzymic degradation occurring as a consequence rather than as a cause of disease. We also found a novel, as yet unidentified, amino acid derivative of the arginine residue at position 3 in both hamster and mouse PrP 33-35, which may predispose PrP to form SAF. Carlson and colleagues have discovered a linkage between the PrP gene and the murine gene provisionally called Prn-i which, from the work of Carp and coworkers, appears identical to the Sinc gene. The Sinc gene is the major gene determining the incubation period of all strains of scrapie in mice. We have evidence for a linkage of the PrP gene and Sinc using inbred mice of known Sinc genotype, including VM(Sincp7) and VM(Sincs7) congenic mice. PrP may even be the protein product of the Sinc gene.

Properties of scrapie prion proteins in liposomes and amyloid rods

The scrapie prion protein (PrP 27-30) has been demonstrated to be required for infectivity. Aggregates of PrP 27-30 form insoluble amyloid rods which resist dissociation by non-denaturing detergents. Mixtures of the detergent cholate and phospholipids were found to solubilize PrP 27-30 with full retention of scrapie prion infectivity. No evidence for a prion-associated nucleic acid could be found when the phospholipid vesicles with PrP 27-30 were digested with nucleases and Zn2+. Under digestion conditions which allowed hydrolysis of exogenous nucleic acids, no diminution of prion infectivity was observed. Tobacco mosaic virions added to the liposomes at a concentration 100 times lower than the scrapie prion titre could be seen by electron microscopy. These studies indicate that there is no subpopulation of filamentous scrapie viruses hidden amongst the prion rods - indeed, they would have been observed among the liposomes. The partitioning of PrP 27-30 and scrapie infectivity into phospholipid vesicles argues for a central role of PrP 27-30 in scrapie pathogenesis and establishes that the prion amyloid rods are not essential for infectivity.

Scrapie: a virus-induced amyloidosis of the brain

We have studied the pathogenesis of scrapie in hamsters, in particular the increase of infectivity and the formation of scrapie-associated fibrils in relation to clinical disease. The results of such studies after intraperitoneal or intracerebral infection are consistent with the idea that transmissible spongiform encephalopathies are a type of virus-induced, brain-specific amyloidosis. Therefore, an appropriate name for the class of viruses that cause these diseases might be amyloid-inducing viruses.

Characterisation of antisera raised against species-specific peptide sequences from scrapie-associated fibril protein and their application for post-mortem immunodiagnosis of spongiform encephalopathies

Transmissible spongiform encephalopathies (TSE), such as scrapie or Creutzfeldt-Jakob disease (CJD), are fatal neurodegenerative diseases of the central nervous system caused by a yet unidentified virus. They are accompanied by a brain specific amyloidosis, during which a host coded protein irreversibly aggregates to form the scrapie-associated fibrils. The diagnosis of TSE relies on histopathological detection of spongiform lesions, on electron microscopical detection of fibrils, or on the immunological detection of SAF protein, which is the most specific diagnostic marker. In order to improve the diagnosis of TSE, we developed a protocol for rapid tissue fractionation and enrichment of SAF protein which subsequently allows the specific detection of SAF protein by western blotting and immunodetection. Using some new antisera raised against synthetic peptides with sequences specific for the hamster, sheep, cattle and human SAF protein, several samples can be diagnosed for TSE within 24 hours, starting with only 10-100 mg of brain tissue from different species.

Thermal stability and conformational transitions of scrapie amyloid (prion) protein correlate with infectivity

The scrapie amyloid (prion) protein (PrP27-30) is the protease-resistant core of a larger precursor (PrPSc) and a component of the infectious scrapie agent; the potential to form amyloid is a result of posttranslational event or conformational abnormality. The conformation, heat stability, and solvent-induced conformational transitions of PrP27-30 were studied in the solid state in films by CD spectroscopy and correlated with the infectivity of rehydrated and equilibrated films. The exposure of PrP27-30 in films to 60 degrees C, 100 degrees C, and 132 degrees C for 30 min did not change the beta-sheet secondary structure; the infectivity slightly diminished at 132 degrees C and correlated with a decreased solubility of PrP27-30 in sodium dodecyl sulfate (SDS), probably due to cross-linking. Exposing PrP27-30 films to formic acid (FA), trifluoroacetic acid (TFA), trifluoroethanol (TFE), hexafluoro-2-propanol (HFIP), and SDS transformed the amide CD band, diminished the mean residue ellipticity of aromatic bands, and inactivated scrapie infectivity. The convex constraint algorithm (CAA) deconvolution of the CD spectra of the solvent-exposed and rehydrated solid state PrP27-30 identified five common spectral components. The loss of infectivity quantitatively correlated with a decreasing proportion of native, beta-pleated sheet-like secondary structure component, an increasing amount of alpha-helical component, and an increasingly disordered tertiary structure. The results demonstrate the unusual thermal stability of the beta-sheet secondary structure of PrP27-30 protein in the solid state. The conformational perturbations of PrP27-30 parallel the changes in infectivity and suggest that the beta-sheet structure plays a key role in the physical stability of scrapie amyloid and in the ability to propagate and replicate scrapie.

Conformational transitions, dissociation, and unfolding of scrapie amyloid (prion) protein

The infectious form of the scrapie amyloid (prion) precursor, PrPSc, is a host-derived protein and a component of the infectious agent causing scrapie. PrPSc and the carboxyl-terminal proteinase K resistant core, PrP27-30, have the potential to form amyloid as a result of a post-translational event or conformational abnormality. We have studied the conformational transitions of both proteins reconstituted into liposomes, associated in solid state in thin films, and dissociated by guanidine HCl. The secondary structure of PrPSc in liposomes deduced from analysis of circular dichroism spectra contained approximately 34% beta-sheets, approximately 20% alpha-helix, and approximately 46% beta-turns and random coil. Cleavage of the amino-terminal region of PrPSc resulted in all-beta PrP27-30, with an estimated approximately 43% beta-sheet, no alpha-helix, and approximately 57% beta-turns and random coil. The PrPSC associated in thin films with a tertiary structure perturbation corresponding to unfolding, while the secondary structure was preserved. The PrP27-30 assembled into the solid state with a similar perturbation of tertiary structure but with a large increase in the beta-sheet content, probably due to an intermolecular alignment of the external beta-sheets, or to a secondary structure transition, or both. The various conformational states had little or no impact on infectivity. Equilibrium dissociation and unfolding demonstrated a greater resistance of PrP27-30 to denaturation. The dissociated monomers unfolded through intermediate(s), suggesting the presence of protein domains with distinct secondary structure stabilities. The results provide experimental evidence for the beta-sheet type assembly of scrapie amyloid PrP27-30 in the solid state and demonstrate the importance of amino-terminal cleavage in the stability and alignment of the amyloid-forming monomers.

Immunolocalization of scrapie amyloid in non-congophilic, non-birefringent deposits in golden Syrian hamsters with experimental transmissible mink encephalopathy

Transmissible mink encephalopathy (TME), a naturally occurring subacute spongiform encephalopathy in commercially ranch-reared mink (Mustela vision), is characterized neuropathologically by spongiform changes in the neuropil, intracytoplasmic neuronal vacuolation and astrocytic hypertrophy and hyperplasia. Amyloid deposits have not been observed in brain tissue sections from animals with natural and experimental TME using conventional histochemical stains such as Congo red. To determine if amyloid deposits be visualized by immunocytochemical techniques, we stained formalin-fixed, formic acid-treated brain tissue sections from several animal species with natural and experimental TME, using a rabbit antiserum directed against scrapie amyloid (PrP27-30). Scrapie amyloid-immunoreactive deposits were found in golden Syrian hamsters experimentally infected with TME, but were absent in mink with natural and experimental TME, as well as in ferrets and squirrel monkeys with experimental TME. The scrapie amyloid-immunoreactive deposits, which were non-congophilic and non-birefringent, were distributed in the subependymal, subpial and perivascular regions of the brain, as in hamsters infected with the 263K strain of scrapie. Ultrastructurally, scrapie amyloid-immunoreactive deposits revealed a collection of degenerating neurites with numerous abnormal mitochondria and degenerating synapses. Amyloid fibrils were not observed. Anti-scrapie amyloid antibodies immunoabsorbed with scrapie amyloid abolished immunostaining. Our data indicate the presence of scrapie amyloid lacking the molecular conformation of amyloid fibrils in hamsters with experimental TME.

Brain regional distribution of prion protein PrP27-30 in mice stereotaxically microinjected with different strains of scrapie

Stereotaxic inoculation was used to examine the role of scrapie agent strain, inoculum, and injection site on the brain regional distribution of the prion protein, PrP27-30. Neither the type of inoculum nor the injection site influenced the distribution of PrP27-30 in brains of mice. Among the parameters examined, only the strain of agent affected the pattern of distribution and the yield of PrP27-30. Although mice injected into the cerebellum had the shortest incubation period, the cerebellum gave the lowest yield of the PrP27-30 among the seven brain regions examined. The positive correlation between PrP27-30 regional distribution and lesion profile (degree of vacuolation) reinforces the role of the PrPSC protein in scrapie pathogenesis.

Amphotericin B treatment dissociates in vivo replication of the scrapie agent from PrP accumulation

Scrapie and related animal and human disorders are neurodegenerative diseases characterized by the formation of a modified, partly proteinase-resistant protein (PrP) of the host, which tends to aggregate as amyloid fibrils and accumulate in the brain of infected individuals. There is a general consensus that the pathological form of PrP (PrPSc) is essential for the clinical appearance of the disease, but whether it is part of the scrapie agent or a by-product of viral infection is still controversial. Here we report that treatment of scrapie-infected hamsters with amphotericin B delays the accumulation in the brain of the proteinase-resistant portion of PrPSc by about 30 days without affecting scrapie replication. The consequence is that hamsters treated with amphotericin B developed clinical signs of disease later than infected controls. We argue that the proteinase-resistant portion of PrPSc is necessary for the development of the disease but that it is unlikely to be essential for scrapie replication.

Hidden amyloidoses

The pathogenesis as well as the genetic disposition to develop clinical symptoms in transmissible spongiform encephalopathies (e.g. Creutzfeldt-Jakob disease, scrapie, bovine spongiform encephalopathy) relate these diseases to classical noninfectious amyloidoses (familial amyloidotic polyneuropathy as an example) and to Alzheimer's disease. This is not obvious to the nonexpert at first glance. This communication tries to elucidate this association, to reveal which immunochemical techniques have contributed their share.

Scrapie-associated tubulofilamentous particles in human Creutzfeldt-Jakob disease

Scrapie-associated fibrils (SAF) were demonstrated by a simple negative staining method for electron microscopy from fresh and frozen brains with naturally occurring human Creutzfeldt-Jakob disease (CJD). The findings confirm that SAF occur as an internal part of a larger three-layer particle. The two outer coats of SAF can be disrupted by detergent alone or can be digested in two stages by a combination of proteolytic enzymes and subsequent treatment with DNase and mung bean nuclease. Examination of thin sections from the cerebral cortex of brains from patients with CJD revealed the presence of 26-30-nm diameter tubulofilamentous particles, identical to those previously described in natural scrapie of sheep and bovine spongiform encephalopathy and also in experimentally induced scrapie in mice and hamsters and CJD-infected mice and chimpanzees. Thus, it would appear that the particles are not contaminants passaged in experimental animals.

Relationship of protease-resistant protein, scrapie-associated fibrils and tubulofilamentous particles to the agent of spongiform encephalopathies

Tubulofilamentous particles and scrapie-associated fibrils (SAF) are ultrastructural markers, while protease-resistant protein (PrP) is a molecular biological marker for all spongiform encephalopathies. Review of all published work has suggested that PrP molecules aggregate to form a three-dimensional SAF. Further reports have suggested that a single-stranded DNA wraps round SAF and acquires an outer protein coat to form tubulofilamentous particles. As incubation period increases in the infected animals, larger amounts of PrP molecules are committed to form SAF, interfering with the normal supply of PrP to cell membranes which become disrupted and eventually fragment, resulting in vacuoles typical of those found in spongiform encephalopathies.

Secondary structure analysis of the scrapie-associated protein PrP 27-30 in water by infrared spectroscopy

A protease-resistant form of the protein PrP (PrP-res) accumulates in tissues of mammals infected with scrapie, Creutzfeldt-Jakob disease, and related transmissible neurodegenerative diseases. This abnormal form of PrP can aggregate into insoluble amyloid-like fibrils and plaques and has been identified as the major component of brain fractions enriched for scrapie infectivity. Using a recently developed technique in Fourier transform infrared spectroscopy which allows protein conformational analysis in aqueous media, we have studied the secondary structure of the proteinase K resistant core of PrP-res (PrP-res 27-30) as it exists in highly infectious fibril preparations. Second-derivative analysis of the infrared spectra has enabled us to quantitate the relative amounts of different secondary structures in the PrP-res aggregates. The analysis indicated that PrP-res 27-30 is predominantly composed of beta-sheet (47%), which is consistent with its amyloid-like properties. In addition, significant amounts of turn (31%) and alpha-helix (17%) were identified, indicating that amyloid-like fibrils need not be exclusively beta-sheet. The infrared-based secondary structure compositions were then used as constraints to improve the theoretical localization of the secondary structures within PrP-res 27-30.

Scrapie-infected spleens: analysis of infectivity, scrapie-associated fibrils, and protease-resistant proteins

Scrapie-associated fibrils (SAF) and protease-resistant proteins (PrP) were isolated from spleens and brains of clinical animals (mice and hamsters) from three scrapie agent-host strain combinations, and their concentrations were compared with infectivity levels. The spleens of infected animals contained lower levels of infectivity, PrP, and SAF than did brains. Regardless of the route of infection, both SAF and infectivity were detected in spleen before brain. Infectivity increased in brains and spleens of 139A-infected mice before the detection and increase in SAF, suggesting that the synthesis of SAF and PrP may not be the limiting factor in agent replication. In contrast to those in ME7- and 263K-infected animals, the Western blot profiles for PrP from brain and spleen of 139A-infected mice exhibited distinct differences. Results indicate that SAF and PrP found in the spleens are both organ- and scrapie strain-specific.

Immunolocalization of scrapie amyloid (PrP27-30) in chronic wasting disease of Rocky Mountain elk and hybrids of captive mule deer and white-tailed deer

Scrapie amyloid-immunoreactive plaques are present in brain tissues of captive mule deer with chronic wasting disease (CWD), a progressive neurological disorder characterized neuropathologically by widespread spongiform change of the neuropil, intracytoplasmic vacuolation in neuronal perikarya and astrocytic hypertrophy and hyperplasia. We report here the immunolocalization of scrapie amyloid (PrP27-30) in plaques observed in brain tissues of Rocky Mountain elk (Cervus elaphus nelsoni) and hybrids of mule deer and white-tailed deer (Odocoileus virginianus) naturally affected with CWD. Similar findings have been shown in kuru, Creutzfeldt-Jakob disease, and Gerstmann-Sträussler syndrome in humans. Our data corroborate that CWD in Rocky Mountain elk and hybrids of mule deer and white-tailed deer belongs to the subacute spongiform virus encephalopathies (transmissible cerebral amyloidoses).

Morphological and biochemical evidence that scrapie-associated fibrils are derived from aggregated amyloid-like filaments

The membrane fraction from scrapie infected mouse brains was dissolved in saturated urea, centrifuged on a 10 to 50% glycerol gradient at 35,000 rpm for 24 h, and fractionated from the bottom of the tube into 11 fractions. PrP was detected throughout the gradient. However, the relative PrP concentrations of fractions 4 and 8 were the highest. The relative PrP concentration versus protein concentration of fractions 1 to 4 was higher than that of the other fractions. Scrapie infectivity also was detected in all fractions. Fractions 2, 3, 4, 7, and 8 produced the shortest incubation periods. Positively stained filamentous aggregates with sizes varying from about 40 x 60 nm to more than 4 microns were observed in fractions 2 and 4 by negative staining. These resembled amyloid filaments. Congo red-stained aggregates showed birefringence under polarized light. Aggregation of the filamentous aggregates was observed by incubation with anti-mouse SAF serum. Fine fibrils 10-18 nm in width were partially dissociated from the aggregates by brief exposure to the detergent Sarkosyl. These facts suggest that SAF are not products of self-assembly from subunit structures liberated from membranes by exposure to detergent, but exist as aggregates of amyloid-like filaments from which SAF are dissociated by detergent extraction.

Chemoprophylaxis of scrapie in mice

Three applications of the polyanion pentosanpolysulphate about 2 months before infection of mice with scrapie completely protected animals infected with up to 100 LD50, and considerably prolonged the lifespan of those infected with 100 to 10,000 LD50. The clinical diagnosis was confirmed by immunoblot analysis for the protein of scrapie-associated fibrils.

The scrapie fibril protein and its cellular isoform

Proteins need help to fold and attain their functional conformation (Ellis and Hemmingsen 1989), and mechanisms have evolved to prevent the accumulation of misfolded protein aggregates within cells (Pelham 1988). These mechanisms fail to prevent the formation of protease-resistant, misfolded forms of PrP (ScPrP) during the development of scrapie and other transmissible spongiform encephalopathies, and ScPrP is a biochemical marker of these diseases. Much is now known about the structure and expression of the PrP gene, but the physiological function of the PrP protein and the mechanism by which the TDE pathogen replicates and specifically interferes with PrP metabolism remain a mystery--a mystery which will entertain prion-ophiliacs for some time yet.

Molecular biology and transgenetics of prion diseases

Considerable progress has been made deciphering the role of an abnormal isoform of the prion protein (PrP) in scrapie of animals and Gerstmann-Sträussler syndrome (GSS) of humans. Some transgenic (Tg) mouse (Mo) lines that carry and express a Syrian hamster (Ha) PrP gene developed scrapie 75 d after inoculation with Ha prions; non-Tg mice failed to show symptoms after greater than 500 d. Brains of these infected Tg(HaPrP) mice featured protease-resistant HaPrPSc, amyloid plaques characteristic for Ha scrapie, and 10(9) ID50 units of Ha-specific prions upon bioassay. Studies on Syrian, Armenian, and Chinese hamsters suggest that the domain of the PrP molecule between codons 100 and 120 controls both the length of the incubation time and the deposition of PrP in amyloid plaques. Ataxic GSS in families shows genetic linkage to a mutation in the PrP gene, leading to the substitution of Leu for Pro at codon 102. Discovery of a point mutation in the Prp gene from humans with GSS established that GSS is unique among human diseases--it is both genetic and infectious. These results have revised thinking about sporadic Creutzfeldt-Jakob disease, suggesting it may arise from a somatic mutation. These findings combined with those from many other studies assert that PrPSc is a component of the transmissible particle, and the PrP amino acid sequence controls the neuropathology and species specificity of prion infectivity. The precise mechanism of PrPSc formation remains to be established. Attempts to demonstrate a scrapie-specific nucleic acid within highly purified preparations of prions have been unrewarding to date. Whether transmissible prions are composed only of PrPSc molecules or do they also contain a second component such as small polynucleotide remains uncertain.

Evidence of ssDNA in tubulofilamentous particles: their relationship to scrapie-associated fibrils

Abnormal tubulofilamentous particles were identified by electron microscopy using a simple touch negative staining technique from brains of mice infected with four strains of the scrapie agent. Treatment by three proteolytic enzymes and subsequent treatment with DNase and mung bean nuclease of grids prepared from the infected animals confirmed previous observations that the tubulofilamentous particles observed in scrapie-effected brains are complex structures. The core of the tubulofilamentous particle scrapie-associated fibrils was revealed by treatment with SDS. Treatment with proteolytic enzymes and subsequent treatment with DNase or mung bean nuclease or S1 nuclease also revealed typical and transitional stages of scrapie-associated fibrils. However, treatment with RNase A had no effect. The data suggest that nucleic acid is a single-stranded DNA protected by a protein coat.

The mRNA encoding the scrapie agent protein is present in a variety of non-neuronal cells

PrP 27-30, a unique protease-resistant protein associated with scrapie infectivity, derives from the proteolytic cleavage of a larger precursor encoded by a host gene. To identify sites of PrP biosynthesis, in situ hybridization was done using cloned PrP cDNA as a probe. In rodent brain, PrP mRNA was expressed in neurons, ependymal cells, choroid plexus epithelium, astrocytes, pericytes, endothelial cells and meninges of both scrapie-infected and uninfected animals. PrP mRNA was also detected in vitro in isolated brain microglia cells. Pulmonary cells and heart muscle cells contained high levels of this mRNA. Hybridization was not detected in spleen, confirming earlier RNA blot experiments indicating extremely low levels of PrP mRNA in this tissue. Results indicate that PrP mRNA is a normal component in a variety of non-neuronal tissues and may explain the origin of the amyloid plaques present in the subependymal region of scrapie-infected brain.

Scrapie-associated precursor proteins: antigenic relationship between species and immunocytochemical localization in normal, scrapie, and Creutzfeldt-Jakob disease brains

We describe the antigenic properties and detection of a normal isoform of scrapie-associated precursor protein (PrP33-35C) in normal, and both normal and scrapie isoforms in scrapie- or Creutzfeldt-Jakob disease (CJD)-infected mouse, hamster, and human brains, using a variety of specific antibodies. Polyclonal antibodies raised against mouse and hamster PrP27-30 and against a synthetic peptide of the N-terminal sequence of this protein were used as immunologic probes. PrP27-30 purified as a primary immunogen corresponded to the lower molecular mass peptide, with Mr between 9.3 and 13.5 kd as estimated by size-exclusion high-pressure liquid chromatography. ELISA and immunoblot techniques demonstrated that antibodies recognized homologous antigens as well as precursor proteins from brains (PrP33-35C) and the scrapie isoform of scrapie-associated proteins (PrP33-35Sc/CJD and PrP27-30) from scrapie- and CJD-infected brains. The normal, scrapie, and CJD isoforms of scrapie-associated proteins share common epitopes with varying degrees of interspecies homology. Specific antigen detected in neurons indicated that these proteins are synthesized primarily in these cells. In infected brains, extracellular amyloid deposits formed by the scrapie isoform of PrP protein also strongly reacted with anti-PrP antibodies.

Immunohistochemical localization of prion protein in spongiform encephalopathies and normal brain tissue

We used polyclonal antibodies raised against hamster and mouse PrP27-30 as immunologic probes to study the localization of intracellular and extracellular deposits of prion protein in normal and scrapie-infected mouse and hamster brains and in Creutzfeldt-Jakob disease (CJD)-infected mouse brains. In addition, we examined normal human brain and brain tissues from patients with CJD, kuru, Alzheimer's disease, and idiopathic chronic encephalitis. There was positive staining in the cytoplasm of neurons of normal and scrapie- and CJD-infected mice, and in the neurons of normal and scrapie-infected hamsters. The staining pattern suggests the localization of PrP in an intracellular membrane compartment, most likely the rough endoplasmic reticulum or Golgi apparatus. Antibodies raised against a 15-amino-acid synthetic peptide of the N-terminal of hamster PrP27-30 displayed a similar pattern of staining in mouse brain sections. We observed no intracellular staining in human brain sections obtained at autopsy. Antibodies prepared against mouse and hamster PrP27-30 reacted with amyloid plaques in scrapie-infected mouse and kuru- and CJD-infected human brain sections but not with amyloid plaques in the brain of a patient with Alzheimer's disease.

Linkage of the gene for the scrapie-associated fibril protein (PrP) to the Sip gene in Cheviot sheep

The gene Sip with two alleles, sA and pA, is the major gene determining the incubation period of scrapie in its natural host, sheep. Two lines of Cheviot sheep have been bred which differ in their response to experimental infection with SSBP/1 scrapie. The negative line have a decreased incidence of disease caused by SSBP/1 and are SippApA. The positive line have an increased incidence of disease and the majority are either SipsAsA or SipsApA; it is not possible to distinguish between the two genotypes on the basis of scrapie incubation time because the sA allele is fully dominant with SSBP/1 scrapie. There are also rare SippApA segregants in the positive line. The major protein (PrP) of scrapie-associated fibrils is encoded by a cellular gene and a cDNA copy of the hamster PrP mRNA has been used to analyse the restriction fragment length polymorphism of the two lines of Cheviot sheep. Two polymorphisms of the sheep PrP gene were found, by using HindIII and EcoRI, which appear to act as markers for the alleles of Sip. Using these polymorphisms it is now possible to assign a Sip genotype to the sheep in the Cheviot flock. Preliminary results from Anglo-Nubian goats and a cow are also reported.

Post-mortem immunodiagnosis of scrapie and bovine spongiform encephalopathy

Two polyclonal antisera were raised in rabbits against the scrapie-associated fibril protein (PrP) prepared from sheep and mice which were terminally infected with experimental scrapie. The anti-mouse PrP serum identifies the proteins of scrapie-associated fibrils (SAF) from all the host species studied (mouse, hamster, sheep and goat) and bovine spongiform encephalopathy (BSE) fibrils from cow. The anti-sheep PrP serum displays species restricted immunoreactivity. While it identifies several PrP polypeptides from terminally affected sheep, goat and cow material, only the highest molecular weight band is recognised from hamster and there is no detection of mouse PrP. The use of these antisera in routine laboratory testing at post mortem provides a highly sensitive test for scrapie and BSE and may allow the identification of infected animals prior to the onset of clinical signs.

Linkage of a prion protein missense variant to Gerstmann-Sträussler syndrome

Gerstmann-Sträussler syndrome is a rare familial neurodegenerative condition that is vertically transmitted, in an apparently autosomal dominant way. It can also be horizontally transmitted to non-human primates and rodents through intracerebral inoculation of brain homogenates from patients with the disease. The exact incidence of the syndrome is unknown but is estimated to be between one and ten per hundred million. Patients initially suffer from ataxia or dementia and deteriorate until they die, in one to ten years. Protease-resistant prion protein (PrP) and PrP-immunoreactive amyloid plaques with characteristic morphology accumulate in the brains of these patients. Current diagnostic criteria for Gerstmann-Sträussler syndrome incorporate clinical and neuropathological features, as animal transmission studies can be unreliable. PrP is implicated in the pathogenesis and transmission of the condition and in scrapie, an equivalent animal disease. It was discovered by enriching scrapie-infected hamster brain fractions for infectivity. Because there is compelling evidence that the scrapie isoform of PrP is a necessary component of the infectious particle, it seemed possible that the PrP gene on the short arm of human chromosome 20 in Gerstmann-Sträussler syndrome might be abnormal. We show here that PrP codon 102 is linked to the putative gene for the syndrome in two pedigrees, providing the best evidence to date that this familial condition is inherited despite also being infectious, and that substitution of leucine for proline at PrP codon 102 may lead to the development of Gerstmann-Sträussler syndrome.

Apparent non-involvement of prions in the pathogenesis of spongiform change in HIV-infected brain

Characteristic neuropathological white matter changes in the brains of patients dying from the acquired immune deficiency syndrome (AIDS) suggest pathogenetic involvement of either the PrP27-30 gene or a scrapie-related prion; however, proteinase-K resistant scrapie-like proteins could not be detected in brain tissue from AIDS patients.

Isolation and purification of scrapie-associated fibrils and prion protein from scrapie-infected hamster brain

We report the purification of prion protein (PrP) 27-30 and scrapie-associated fibrils (SAF) from hamsters infected with the 263K strain of scrapie. SDS-PAGE of fractions purified from scrapie-infected brains revealed several bands at approximately 28.5 kDa, 23.9 kDa and 14.3 kDa and, in one set of preparations, a protein of Mr 26 kDa was found in both scrapie-infected and sham-inoculated animals. The specificity of PrPs was confirmed by Western blotting. Ultrastructural analysis of fractions from scrapie-infected brains revealed numerous fibrils measuring approximately 20 nm in diameter and 100 to 200 nm in length. The substructure of these fibrils consisted of protofilaments which were usually straight and rarely helically arranged. We conclude that the electron microscopical appearance of SAF depends much on the purification scheme. The PrP27-30 as well as proteins of lower Mr are easily detectable in scrapie-infected brains. The detection of protein of a Mr 26 kDa in both scrapie-infected and sham-inoculated animals suggests that this form of PrP may exist in equilibrium with PrP33-35c.

Creutzfeldt-Jakob disease and scrapie prions

Creutzfeldt-Jakob disease, kuru, and Gerstmann-Sträussler syndrome are transmissible degenerative diseases of the central nervous system caused by novel infectious pathogens designated prions. Scrapie is a neurodegenerative disease of sheep and goats and is also caused by prions. Experimental scrapie has been extensively studied in hamsters and mice. The scrapie prion protein (PrPSc) is the only component of the infectious scrapie prion identified, to date. Scrapie infectivity and PrPSc copartition into membranes, rods, and liposomes raising the possibility that only PrPSc might be required for infection; however, a second component such as a small nucleic acid cannot be eliminated. PrPSc is encoded by a single copy cellular gene and not by a hypothetical nucleic acid within purified prion preparations. Normal, uninfected cells express the cellular prion protein (PrPc). Both PrPSc and PrPc appear to be translated from the same 2.1-kb mRNA. The N-terminal amino acid sequences of hamster PrPC and PrPSc are identical; both correspond to that predicted by the translated prion protein (PrP) gene sequence. While the chemical difference between PrPc and PrPSc remains unknown, the organization of the PrP gene argues that it results from a posttranslational event. Six posttranslational modifications of both PrP isoforms have been identified: (1) cleavage of an N-terminal signal peptide, (2) an intramolecular disulfide bond, (3) an N-linked oligosaccharide attached to Asn 181, (4) a second oligosaccharide attached to Asn 197, (5) cleavage of a C-terminal hydrophobic peptide, and (6) a phosphatidylinositol glycolipid attached to the C-terminus. The mouse PrP gene is on chromosome 2 and is linked to a gene controlling the scrapie incubation time (Prn-i). PrP genes from inbred mice with short and long incubation times differ by two amino acids, a finding consistent with but not proving that PrP modulates susceptibility to scrapie. PrPSc stimulation of a posttranslational process which converts PrPc or its precursor into PrPSc is one possible mechanism for prion replication. This is consistent with observations showing that human prion diseases are manifest as infectious, sporadic and genetic disorders.

The nature of the unconventional slow infection agents remains a puzzle

Unconventional slow infections are progressive transmissible degenerative disorders of the central nervous system. The human diseases belonging to this group are Creutzfeld-Jakob disease, kuru, and Gerstmann-Straussler syndrome. Scrapie, transmissible mink encephalopathy, chronic wasting disease of mule deer and elk, and the recently discovered bovine spongiform encephalopathy are similar diseases found in animals. Unusual characteristics of the unconventional slow infections clearly distinguish these disorders from conventional infections. These include: unusually long incubation periods (from months to years); progressive CNS degeneration with characteristic histopathological lesions; the lack of an immune or inflammatory response; unconventional biological and physical properties of the etiologic agents. There has been considerable controversy concerning the nature of the causative agent. The 3 main hypotheses, virus, virino, and modified host protein, are reviewed relative to their ability to explain the properties of the agent and the unusual characteristics of the disease process. The discovery of an abnormal structure, termed scrapie associated fibrils (SAF) and an abnormally modified 33-37 kDa host-encoded glycoprotein unique to unconventional slow infections opened new areas of intense interest and investigation. SAF are abnormal filamentous structures which copurify with infectivity and possess characteristics of "amyloids." The major component of SAF is the host-encoded scrapie-specific protease resistant glyco-protein. Considerable data has accumulated on the biochemistry, immunology and molecular biology of this host coded scrapie protein. The relationship of SAF and the scrapie-specific protein to the infectious agent is discussed in the context of each of the "nature of the agent" hypotheses.

Structural and biochemical evidence that scrapie-associated fibrils assemble in vivo

Scrapie-associated fibrils (SAF) are a ubiquitous pathological feature of brains affected by scrapie and the other scrapie-like agents. They are composed of PrP, a heterogeneous glycoprotein which is also present in normal brain but not as SAF. The PrP protein associated with SAF is partially resistant to proteinase K, whereas the soluble form is not. It has been proposed that SAF do not exist as such in vivo, but rather self-assemble from subunit structures liberated from membranes by detergent extraction during purification. We have purified SAF by a method that does not employ proteinase K. We show that the PrP protein from infected but not uninfected brain is partially resistant to protease digestion before and after detergent extraction. Likewise, SAF can be sheared by sonication before or after detergent extraction. In addition, SAF from mice infected with different strains of scrapie have different sedimentation properties. Since SAF-dependent properties exist before detergent extraction, then so must SAF. They are therefore not a detergent-induced artefact but most probably assemble in vivo.

Prion protein biosynthesis in scrapie-infected and uninfected neuroblastoma cells

Numerous studies have indicated that a modified proteinase K-resistant form of an endogenous brain protein, prion protein (PrP), is associated with scrapie infection in animals. This scrapie-associated PrP modification appears to occur posttranslationally in brain, but its molecular nature is not known. To learn about the normal PrP biosynthesis and whether it is altered by scrapie infection in vitro, we did metabolic labeling experiments with uninfected and scrapie-infected mouse neuroblastoma tissue culture cells. Pulse-chase labeling experiments indicated that, in both cell types, two major PrP precursors of 28 and 33 kilodaltons (kDa) were processed to mature 30- and 35- to 41-kDa forms. Endoglycosidase H, tunicamycin, and phospholipase treatments revealed that the 28- and 33-kDa precursors resulted from the addition of high-mannose glycans to a 25-kDa polypeptide containing a phosphatidylinositol moiety and that maturation of the precursors involved the conversion of the high-mannose glycans to hybrid or complex glycans. Treatments of the live cells with trypsin and phosphatidylinositol-specific phospholipase C indicated that the mature PrP species were expressed solely on the cell surface, where they were anchored by covalent linkage to phosphatidylinositol. Once on the cell surface, the major PrP forms had half-lives of 3 to 6 h. No differences in PrP biosynthesis were observed between the scrapie-infected versus uninfected neuroblastoma cells.

Purification and partial characterization of the normal cellular homologue of the scrapie agent protein

The scrapie agent protein (Sp33-37) is a degradation-resistant protein that aggregates into fibrils and amyloid plaques. This protein is derived from a normal cellular protein (Cp33-37). Understanding the mechanism responsible for the conversion of Cp33-37 to Sp33-37 may explain scrapie agent replication. Cp33-37 was extracted from normal hamster brain and purified 2700-fold by an immunoaffinity method. Both Cp33-37 purified from normal hamster brain and Sp33-37 purified from scrapie-affected hamster brain had apparent masses of 33-37 kilodaltons and displayed microheterogeneity characteristic of glycoproteins. Cp33-37 was completely digested by proteinase K under conditions that resulted in conversion of Sp33-37 to the protease-resistant fragment PrP27-30. Cp33-37 did not cause scrapie when inoculated intracerebrally into hamsters. Fractions containing purified Sp33-37 had average titers of greater than 10(11) LD50 of the scrapie agent/mg of protein; these titers were not diminished by proteinase K. These results indicate that altered sensitivity to proteolysis in vitro reflects an intrinsic difference between Sp33-37 and Cp33-37.