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.

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.

Scrapie infectivity and prion protein are distributed in the same pH range in agarose isoelectric focusing

We separated lysed synaptosomal-microsomal membrane fraction from scrapie-infected hamster brain in preparative agarose isoelectric focusing. We also studied the distribution of PrP27-30 and scrapie infectivity in 13 regions of the gel in the range of pH 3.5 to 9.3. Most of the infectivity remained in the trough, where it had been placed at the beginning of the electrophoresis, along with PrP27-30. Scrapie infectious particles that encountered the gel demonstrated charge heterogeneity and were distributed in the range of pH 5.4 to 9.3. Analysis of charge heterogeneity of PrP27-30 after sodium dodecyl sulfate solubilization showed an isoelectric pattern in the same pH range as that for scrapie infectious particles. The similarity in charge heterogeneity between infectivity and PrP27-30, together with copurification, support the idea that PrP27-30 is an essential component of the scrapie infectious agent.

Changes in the distribution of anionic sites in brain micro-blood vessels with and without amyloid deposits in scrapie-infected mice

Cationic colloidal gold (CCG) and scrapie-infected mouse brain samples embedded in Lowicryl K4M were used for ultrastructural localization of negatively charged microdomains (anionic sites) in the cerebral microvasculature. The distribution of anionic sites on both fronts (luminal and abluminal) of endothelial cells and in the basement membrane (BM) in the majority of micro-blood vessels (MBVs) located outside the plaque area and in the remaining cerebral cortex was similar to that which has been previously observed in non-infected animals. Some MBVs (especially capillaries), however, located inside the plaque areas and surrounded directly by amyloid fibers contained attenuated endothelium, the luminal surface of which showed a segmental lack or diminution of anionic sites. In these vessels the BM was frequently infiltrated and replaced by the amyloid fibers. In some vessels located mainly in the areas of the neuropil vacuolization deposits of homogenous material causing the thickening of the BM were noted. These changes were accompanied by irregular labeling of the BM with gold particles. At the sites of bifurcation of some MBVs, predominantly in the area of the venular estuary at the mouth of capillary (at capillary-venular connections), a discontinuity in the distribution of anionic sites was noted. The observed disturbances in the distribution of anionic sites can be associated with a previously noted increased permeability of some MBVs in the brains of scrapie-infected mice.

Changes in brain gene expression shared by scrapie and Alzheimer disease

We have isolated two recombinant cDNAs whose corresponding RNAs have an increased abundance in scrapie-infected hamster brain. DNA sequence analysis has shown that these two recombinants represent the genes for sulfated glycoprotein 2 and transferrin. The abundance of sulfated glycoprotein 2 RNA is increased in hippocampus from patients with Alzheimer disease and Pick disease, whereas transferrin RNA is not strongly modulated in these conditions. Expression of two previously identified scrapie-modulated genes, encoding glial fibrillary acidic protein and metallothionein, is also increased in both of these neurodegenerative diseases.

Precise targeting of the pathology of the sialoglycoprotein, PrP, and vacuolar degeneration in mouse scrapie

Widespread immunostaining of PrP protein was demonstrated in scrapie mouse brain, distributed diffusely in the neuropil and focally in amyloid plaques, microglia and 2-5 microns structures resembling neuronal processes. With the 87V scrapie strain, which produces focal vacuolation in particular areas, PrP pathology was precisely targeted to these same areas, predating vacuolar degeneration by at least several weeks. On the other hand, both vacuolar and PrP changes were widely distributed throughout the brain with the ME7 scrapie strain. It is likely that the precise targeting of PrP pathology, followed by vacuolar degeneration, reflects an underlying targeting and localised replication of infectious agent.

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.

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.

Cerebrovascular amyloid in scrapie-affected sheep reacts with antibodies to prion protein

In an immunohistochemical study of naturally-occurring and experimental scrapie in sheep, deposits of cerebrovascular amyloid were found to react with antibodies to hamster scrapie prion protein (PrP 27-30), but not with antibodies to the amyloid beta-protein of Alzheimer's disease. It is concluded that this vascular amyloid is formed from PrP and is therefore closely associated with scrapie infection. It is likely that this amyloid is formed from a host precursor protein as a specific pathological consequence of invasion by the scrapie agent.

Purification and properties of the cellular and scrapie hamster prion proteins

During scrapie infection an abnormal isoform of the prion protein (PrP), designated PrPSc, accumulates and is found to copurify with infectivity; to date, no nucleic acid has been found which is scrapie-specific. Both uninfected and scrapie-infected cells synthesize a PrP isoform, denoted PrPC, which exhibits physical properties that differentiate it from PrPSc. PrPC was purified by immunoaffinity chromatography using a PrP-specific monoclonal antibody cross-linked to protein-A--Avidgel. PrPSc was purified by detergent extraction, poly(ethylene glycol) precipitation and repeated differential centrifugation of PrPSc polymers. Both PrP isoforms were found to have the same N-terminal amino acid sequence which begins at a predicted signal peptide cleavage site. The first 8 residues of PrPC were found to be KKXPKPGG and the first 29 residues of PrPSc were found to be KKXPKPGGWNTGGSXYPGQGSPGGNRYPP. Arg residues 3 and 15 in PrPSc and 3 in PrPC appear to be modified since no detectable signals (denoted X) were found at these positions during gas-phase sequencing. Both PrP isoforms were found to contain an intramolecular disulfide bond, linking Cys 179 and 214, which creates a loop of 36 amino acids containing the two N-linked glycosylation sites. Development of a purification protocol for PrPC should facilitate comparisons of the two PrP isoforms and lead to an understanding of how PrPSc is synthesized either from PrPC or a precursor.

In vitro expression in eukaryotic cells of a prion protein gene cloned from scrapie-infected mouse brain

It has been proposed that the causative agent of scrapie represents a class of infectious particle that is devoid of nucleic acid and that an altered form of the endogenous prion protein (PrP) is the agent. However, it has been difficult to exclude the possibility that PrP purified from scrapie tissues might be contaminated with a more conventional viral agent. To obtain PrP uncontaminated by scrapie-infected tissues, PrP cDNA cloned from a scrapie-infected mouse brain was expressed in mouse C127 cells in vitro. mRNA and protein encoded by the cloned PrP gene were identified. The expressed PrP polypeptides appeared to be glycosylated and were released from the cell surface into the medium. Homogenates of the cells expressing the cloned PrP gene were inoculated into susceptible mice but failed to induce clinical signs of scrapie. Thus, either PrP is not the transmissible agent of scrapie or the expressed PrP requires additional modification to be infectious.

Influence of stereotaxically injected scrapie on neurotransmitter systems of mouse cerebellum

The 22L strain of scrapie was injected stereotaxically into the cerebellum of C57BL/6J mice to determine its effect on several cerebellar neurotransmitter systems during the early clinical stages of the disease. In this model vacuolar lesions are restricted to the cerebellum with no evidence of vacuolization in other brain regions. Although vacuolar lesions develop throughout all cell layers of the cerebellum, they are most severe in the granule cell layer. Modest but significant (P less than 0.01) reductions in cerebellar weight, glutamate decarboxylase activity, and in the affinity of the N6-[adenine-2,8-3H]cyclohexyladenosine binding sites, were observed in scrapie affected mice. The densities of the high- and low-affinity adenosine receptors were unaffected. Adenosine receptors in the cerebellum are highly localized to the axon terminals of the glutamatergic, GABA receptive granule cells. GABA, benzodiazepine, glutamate, and muscarinic cholinergic receptors were not significantly altered. In addition, the high-affinity uptake of glutamate, and the activity of choline acetyltransferase were not significantly changed. GABA high-affinity uptake was slightly increased. Even though the granule cell layer of the cerebellum had undergone severe vacuolation, only modest neurotransmitter changes were apparent. Although these results suggest a tenuous relationship between scrapie pathology and the integrity of neurotransmitter systems, it is possible that compensatory neurochemical changes in uncompromised neuronal populations may have masked potentially specific neurotransmitter effects.

Western blot detection of scrapie-associated fibril protein in tissues outside the central nervous system from preclinical scrapie-infected mice

We describe a method of sample preparation to detect scrapie-associated fibril (SAF) proteins in small amounts of scrapie-infected mouse tissues by Western blot analysis using an antiserum to a synthetic peptide that corresponds to the N-terminal region of hamster prion protein. SAF proteins were efficiently detected in brain tissue by this procedure. The proteins were also detected in preparations from spleen and lymph node. SAF proteins were detected in brain samples at 24 weeks after intraperitoneal infection. Using spleen samples, the proteins were detected from mice in the preclinical stage (from 4 weeks after infection), clinical symptoms of scrapie were observed in some mice from 22 weeks after infection.

Molecular pathology of scrapie-associated fibril protein (PrP) in mouse brain affected by the ME7 strain of scrapie

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 (PrP). Abnormal post-translational modification of PrP has been suggested to explain its aberrant properties in scrapie-affected brains and although there is a form of PrP in SAF indistinguishable in size from the protein in uninfected brain, lower-molecular-mass variants of PrP are also found in SAF fractions. We report the characterisation of the multiple forms of PrP found in SAF fractions purified from mouse brain affected by the ME7 strain of scrapie. The quantitatively major forms of PrP in SAF prepared without the use of proteinase K have the amino-terminal sequence Lys-Lys-Arg-Pro-Lys-Pro-Gly-Gly-, identical to that predicted for the amino-terminus of normal mouse brain PrP. However N-terminal cleavage of some 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. This suggests the conformation of the protein in aggregates in vivo does not differ extensively from that in detergent-treated SAF in vitro. We conclude that the size diversity of PrP in SAF is only partly due to N-terminal proteolysis and is independent of the proteolysis that occurs if proteinase K is used in the purification of SAF. Apart from proteolytic changes in the structure of PrP, we found a novel, as yet unidentified, amino-acid derivative of the arginine residue at position 3 in mouse PrP, which may predispose PrP to form SAF.

Ultrastructural studies of glycoconjugates in brain micro-blood vessels and amyloid plaques of scrapie-infected mice

Lectin or glycoprotein-gold complexes and samples of scrapie-infected mouse brain embedded in Lowicryl K4M were used for ultrastructural localization of glycoconjugates. The lectins tested recognize the following residues: beta-D-galactosyl [RCA, Ricinus communis agglutinin (aggl.) 120], N-acetyl and N-glycolyl neuraminic acid (LFA, Limax flavus aggl.), N-acetyl-D-glucosaminyl and sialyl (WGA, Wheat germ aggl.), N-acetyl-D-galactosaminyl (HPA, Helix pomatia aggl., and DBA, Dolichos biflorus aggl.), alpha-D-mannosyl/alpha-D-glucosyl (Con A, Concanavalin A), alpha-D-galactosyl and alpha-D-galactopyranoside (BSA, Bandeirea simplicifolia aggl., izolectin B4). Labeling of the majority of micro-blood vessels (MBVs) located outside the plaque area and in the remaining cerebral cortex was similar to that which has been previously observed in non-infected animals. Some MBVs, however, located inside the plaque area and surrounded directly by amyloid fibers showed attenuation of the endothelium, the surface of which was scarcely and irregularly decorated with RCA, LFA, WGA and Con A. These abnormalities in the composition of glycoconjugates can be associated with previously noted increased permeability of some MBVs in the brains of scrapie-infected mice. Some vessels in the plaque area were encapsulated by perivascular deposits of homogeneous or flocculogranular material containing several glycoconjugates. A very intimate structural relation between reactive (microglial-like) cells and amyloid fibers suggests the participation of these cells in elaboration of plaque material. Labeling of the cell surface and adjacent amyloid fibers with the same lectins (RCA, WGA, DBA, Con A) suggests the possibility that the glycosylation of these fibers occurs extracellularly. Only WGA and DBA were occasionally labeling some Golgi elements of the reactive cells.

Immuno-gold localization of prion filaments in scrapie-infected hamster brains

The brains of scrapie-infected hamsters have been examined for the presence of structures antigenically related to the prion protein (PrP 27-30). Glutaraldehyde-perfused hamster brains, 72 days postinfection, were immunostained using rabbit monospecific antisera raised against synthetic peptides corresponding to the N-terminal 13 or 15 amino acids of PrP 27-30, and using rabbit antisera raised against infectious prions or PrP 27-30 purified from scrapie-infected hamster brains. Antisera to the synthetic peptides stained extracellular filaments in agreement with previous immunoperoxidase studies which used affinity-purified PrP 27-30 antibodies; in addition to subependymal and subpial localization, we show ventricular and perivascular staining. Using a colloidal gold-secondary antibody technique, we have demonstrated that the antibodies labeled filaments measuring 7 to 17 nm in diameter. Whereas most of the periventricular and perivascular filaments appeared extracellular, some appeared to be within processes intimately associated with ependymal cells, degenerating membranes of astrocytes, and neurites.

Cloning of rat "prion-related protein" cDNA

Rat prion-related protein (PrP) cDNA has been cloned and sequenced. Comparison of this cDNA with those from human, hamster, and mouse indicates extremely high conservation (about 95%). The deduced partial rat PrP possesses: (a) a highly conserved region composed of repetitive sequences in what is presumably an extracellular domain, (b) a hydrophobic transmembrane domain, (c) a highly charged region which should stop membrane transfer, (d) a substantial cytoplasmic domain (which contains all of the nonconservative substitutions and a high proportion of conservative substitutions), and (e) a hydrophobic C-terminus. Dot and Northern blot analyses suggest a limited expression of PrP in rat tissues and indicate that PrP expression is decreased in the brain during the acute phase response systemically. Our results lend support to the notion that PrP is a highly conserved, normal cellular membrane protein of essential (although unknown) biologic function, which may be deposited in fibrillar amyloid form as a result of abnormal processing.

Changes in the localization of brain prion proteins during scrapie infection

Prion proteins (PrP) were localized in the brains of normal and scrapie-infected hamsters by immunohistochemistry and Western blotting. PrP monoclonal antibodies and monospecific anti-PrP peptide sera, which react with both the cellular (PrPC) and scrapie (PrPSc) isoforms of the prion protein, were used to locate PrP in tissue sections. In normal hamsters, PrPC was located primarily in nerve cell bodies throughout the CNS; whereas, in the terminal stages of scrapie, PrP immunoreactivity was shifted to the neuropil and was absent from most nerve cell bodies. Prion proteins were not uniformly dispersed throughout the gray matter of scrapie-infected hamster brains; rather, they were concentrated in those regions that exhibited spongiform degeneration and reactive astrogliosis. Since earlier studies showed that the level of PrPC remains constant during scrapie infection as measured in whole brain homogenates and no antibodies are presently available that can distinguish PrPC from PrPSc, we analyzed individual brain regions by Western blotting. Analysis of proteinase K-digested homogenates of dissected brain regions showed that most of the regional changes in PrP immunoreactivity that are seen during scrapie infection are due to the accumulation of PrPSc. These observations indicate that the tissue pathology of scrapie can be directly correlated with the accumulation of PrPSc in the neuropil, and they suggest that the synthesis and distribution of the prion protein has a central role in the pathogenesis of this disorder.

The comparative immunoreactivities of brain amyloids in Alzheimer's disease and scrapie

An antibody was raised to a synthetic peptide corresponding to a published sequence for the first 24 residues of a cerebrovascular amyloid peptide (CVAP). Immunohistochemical staining of tissue sections revealed that the antibody bound extensively to cerebrovascular amyloid in Alzheimer disease (AD/SDAT) and Down's syndrome cases. The antibody bound less extensively to neuritic plaques (primitive and mature) and indetectably to neurofibrillary tangles. The antibody did not label scrapie plaques, scrapie-associated fibrils, or Gerstmann-Sträussler syndrome plaques. Immunoblotting experiments showed that the cerebrovascular amyloid peptide epitopes contaminating the neurofibrillary tangle preparations could be extracted with urea, leaving the neurofibrillary tangles intact. These data confirm that the cerebrovascular amyloid peptide is a component of cerebrovascular amyloid, and suggest that its epitopes are also components of neuritic plaque amyloid. The reduced level of immunostaining on amyloid cores in tissue sections suggests that either the cerebrovascular amyloid peptide epitopes are a minor component of amyloid cores, or that their mode of packing or state of processing in amyloid cores renders them relatively inaccessible to the antibody. We also conclude that the cerebrovascular amyloid peptide is not a component of neurofibrillary tangles. The synthetic cerebrovascular amyloid peptide possesses amyloid-like properties: at neutral pH it forms insoluble aggregates consisting of 5-7-nm fibrils, which form red-green birefringent adducts with Congo red and fluoresce with thioflavine S.

Ultrastructural observations of spinal cord lesions and blood-brain barrier changes in scrapie-infected mice

Spinal cord samples from IM or VM mice injected intracerebrally with the 87V scrapie agent were examined ultrastructurally at the clinical stage of disease for changes in blood vessel permeability and for pathological alterations. In several animals, (3 of 16), massive changes were noted in the cervical spinal cords in the subependymal area of the cortical gray matter immediately surrounding the central canal including ependymal cell changes, the presence of amyloid plaque in close association with microglial cells, extensive neuropil vacuolation, the appearance of reactive astrocytes, degenerating neurites and vacuolated neurons. In those regions showing structural damage, localized increased permeability to horseradish peroxidase across the blood-brain barrier was noticed along with the appearance of numerous vesiculo-canalicular profiles in micro-blood vessel endothelial cells with extravasation of the tracer to the neuropil. Some damaged neurons appeared flooded with this tracer. These changes were not observed in either the thoracic or lumbar spinal cord regions. The occurrence of pathological changes in the spinal cords of a small percentage of intracerebrally injected mice was probably due to a high concentration of the scrapie agent which localized in the cervical spinal cord, presumably after entering the spinal fluid via the lateral ventricle at the time of injection.

Chromatin structure in scrapie and Alzheimer's disease

Scrapie affected brains exhibit a number of pathological features in common with the human neurodegenerative condition, Alzheimer's disease. The present report describes studies on chromatin structure seen in these two disease processes. Chromatin associated proteins influence transcriptional activity of DNA through an effect upon chromatin structure. We examined chromatin structure by: measuring the capacity of the enzyme micrococcal nuclease to release mono- and dinucleosomes from isolated nuclei and measuring DNA-histone interactions by examining the effect of ambient tonicity upon the release of chromatin proteins. In two strains of mice infected with two strains of scrapie agent there was reduced accessibility to micrococcal nuclease and an increased content on dinucleosomes of the histone H1 and H1(0) types. These changes precede clinical signs of scrapie and resemble those found in the human conditions of Alzheimer's and Pick's disease. Scrapie mouse brain differs from Alzheimer brain in that scrapie does not alter histone-DNA interactions as monitored by ionically induced histone release from chromatin. Despite similarities, the scrapie agent appears to operate upon different molecular mechanisms than those found in Alzheimer's disease.

Immunological comparison of scrapie-associated fibrils isolated from animals infected with four different scrapie strains

Scrapie-associated fibrils (SAFs) are abnormal filamentous structures that are uniquely associated with unconventional slow virus diseases. The antigenic relationships of SAFs from animals infected with four biologically distinct scrapie strains were investigated by using antisera raised to purified SAF proteins. Rabbit antisera were raised to SAFs isolated from mice infected with the ME7 scrapie strain and to SAFs isolated from hamsters infected with the 263K scrapie strain. A strong antigenic relationship was shown among SAF proteins (PrPs) isolated from all scrapie-infected animals (ME7, 139A, and 87V in mice and 263K in hamsters), and this relationship was demonstrable regardless of which antiserum was used. SAF proteins were antigenically distinct from those of paired helical filaments or amyloid isolated from patients with Alzheimer disease. Distinct Western blot profiles were demonstrated for SAFs isolated from animals infected with each scrapie strain. Differences seen among SAFs were independent, at least in part, of host species or genotype, implying that certain specific structural and molecular properties of SAFs are mediated by the strain of scrapie agent.

Brain histamine metabolism in transmissible spongiform encephalopathy (scrapie)

The histamine (Hi) content and the activity of L-histidine decarboxylase (HD) in brains of scrapie infected hamsters were measured. No significant changes in Hi levels in particular brain areas were found when compared to controls. Decreased activity of HD was found in hypothalamus (p less than 0.02). Increased activity of the enzyme was observed in "rest of brain", which consisted mainly of thalamus and striatum (p less than 0.05).