Spongiform encephalopathy in free-ranging mule deer (Odocoileus hemionus), white-tailed deer (Odocoileus virginianus) and Rocky Mountain elk (Cervus elaphus nelsoni) in northcentral Colorado.

Between March 1981 and June 1995, a neurological disease characterized histologically by spongiform encephalopathy was diagnosed in 49 free-ranging cervids from northcentral Colorado (USA). Mule deer (Odocoileus hemionus) were the primary species affected and accounted for 41 (84%) of the 49 cases, but six Rocky Mountain elk (Cervus elaphus nelsoni) and two white-tailed deer (Odocoileus virginianus) were also affected. Clinical signs included emaciation, excessive salivation, behavioral changes, ataxia, and weakness. Emaciation with total loss of subcutaneous and abdominal adipose tissue and serous atrophy of remaining fat depots were the only consistent gross findings. Spongiform encephalopathy characterized by microcavitation of gray matter, intraneuronal vacuolation and neuronal degeneration was observed microscopically in all cases. Scrapie-associated prion protein or an antigenically indistinguishable protein was demonstrated in brains from 26 affected animals, 10 using an immunohistochemical staining procedure, nine using electron microscopy, and seven using Western blot. Clinical signs, gross and microscopic lesions and ancillary test findings in affected deer and elk were indistinguishable from those reported in chronic wasting disease of captive cervids. Prevalence estimates, transmissibility, host range, distribution, origins, and management implications of spongiform encephalopathy in free-ranging deer and elk remain undetermined.

Immune electron microscopic characterization of monoclonal antibodies to Alzheimer neurofibrillary tangles.

Characterization of eleven monoclonal antibodies (MAbs), raised to isolated sodium dodecyl sulfate (SDS)-treated Alzheimer's neurofibrillary tangles (ANT), has revealed the presence of at least two different epitopes. MAbs were tested for reactivity to ubiquitin and paired helical filaments (PHF) isolated by three different procedures. The effect of protease and/or alkaline phosphatase pretreatment on the reactivity of the MAbs with isolated PHF was also examined. All MAbs that had reacted strongly in the ELISA with sonicated SDS-treated ANT also immune decorated isolated PHF to varying degrees. Two MAbs exhibited a high reactivity to PHF: 3-39 and 5-25. MAb 3-39 was found to recognize a protease sensitive epitope. In contrast MAb 5-25 was found to consistently decorate isolated PHF in all preparations and exhibited a strong reactivity to ubiquitin, and the epitope in isolated PHF was not protease sensitive. Thus structural PHF after protease treatment and detergent treatment contain an antigenic site that is present in ubiquitin.

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.

Q beta RNA bacteriophage: mapping cis-acting elements within an RNA genome.

We have identified, for the first time, regions of cis-acting RNA elements within the bacteriophage Q beta replicase cistron by analyzing the infectivities of 76 replicase gene mutant phages in the presence of a helper replicase. Two separate classes of mutant Q beta phage genomes (35 different insertion mutants, each containing an insertion of 3 to 15 nucleotides within the replicase gene, and 41 deletion genomes, each having from 15 to 935 nucleotides deleted from different regions of the gene) were constructed, and their corresponding RNAs were tested for the ability to direct the formation of progeny virus particles. Each mutant phage was tested for plaque formation in an Escherichia coli (F+) host strain that supplied helper Q beta replicase in trans from a plasmid DNA. Of the 76 mutant genomes, 34% were able to direct virus production at or close to wild-type levels (with plaque yield ratios of greater than 0.5), another 36% also produced virus particles, but at much lower levels than those of wild-type virus (with plaque yield ratios of less than 0.05), and the remaining 30% produced no virus at all. From these data, we have been able to define regions within the Q beta replicase gene that contain functional cis-acting RNA elements and further correlate them with regions of RNA that are solely required to code for functional RNA polymerase.

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.

Classic genetics of scrapie.

Many years ago, observations of natural scrapie revealed differences in clinical manifestations and in the areas of the brain that showed the most intense histopathological changes. In experimental work with scrapie in mice two fundamental points were established in early studies: (1) A mouse gene, termed Sinc for scrapie incubation, affects the length of the incubation period. (2) In a single strain of mice, incubation periods of different "strains" of scrapie can differ by as much as 3-4 fold, e.g., the incubation period of the ME7 scrapie strain in C57BL mice is approximately 122 days, whereas the incubation period for the 22A strain is 360 days. From this "classic" beginning our knowledge about the parameters influenced by genetic characteristics of both host and agent have expanded. In a number of instances, initial examination of an aspect of host-agent interaction has subsequently revealed surprising influences of informational molecules from both host and agent. A partial list of the parameters under genetic control follows: (1) The extent of vacuolation in various regions of the brain; (2) The quantity of amyloid plaques in the brain; (3) The occurrence of increased weight in the preclinical phase of disease; (4) The development of aberrant glucose tolerance; (5) The area of the brain which yields the shortest incubation period after stereotaxic injection; and (6) The physical-chemical and immunological characteristics of scrapie associated fibrils. In several well documented instances differences between scrapie strains were evident after repeated passages of the strains in the same host strain.(ABSTRACT TRUNCATED AT 250 WORDS)

Mouse polyclonal and monoclonal antibody to scrapie-associated fibril proteins.

Antibody response in mice to scrapie-associated fibril proteins (protease-resistant proteins [PrPs]) was generated to different epitopes depending on the source of antigen. Mice responded differently to PrPs isolated from scrapie-infected animals of homologous (mouse) versus heterologous (hamster) species. An enzyme-linked immunosorbent assay established to monitor this antibody response in mice immunized with PrPs was unable to detect such a response in scrapie-infected mice. A monoclonal antibody (MAb), 263K 3F4, derived from a mouse immunized with hamster 263K PrPs reacted with hamster but not mouse PrPs. MAb 263K 3F4 also recognized normal host protein of 33 to 35 kilodaltons in brain tissue from hamsters and humans but not from bovine, mouse, rat, sheep, or rabbit brains. This is the first demonstration of epitope differences on this host protein in different species. The defining of various epitopes on PrP through the use of MAbs will lead to a better understanding of the relationship of PrPs to their host precursor protein and to the infectious scrapie agent.

Detection of scrapie-associated fibrils (SAF) and SAF proteins from scrapie-affected sheep.

Scrapie-associated fibrils (SAF) were detected by negative-stain electron microscopy in the brains (by two different isolation procedures) and spleens of sheep naturally and experimentally infected with scrapie. Although the numbers of SAF varied from case to case, the yield of SAF from brains of naturally affected sheep was lower than that from experimentally affected sheep. SAF-specific, protease-resistant proteins (PrPs) were detected by silver staining and western blot analysis in most samples of brain from experimentally affected sheep. PrPs, however, could be detected in only a limited number of natural cases of sheep scrapie because of the lower yields of SAF. PrPs from sheep SAF appear biochemically and antigenically similar to PrPs from other species infected with unconventional agents. This study further establishes the unique association of SAF and PrPs with natural or experimentally induced scrapie in its natural host.

In vitro assembly and isolation of neurofilaments and microtubules from mammalian CNS.

Neurofilaments were assembled in vitro from the high speed supernatant of mammalian CNS homogenate in a disassembly buffer containing 4-morpholine-ethane sulfonic acid, MgCl2 and EGTA at 4 degrees C in the presence of 4 M glycerol. The assembled neurofilaments were depolymerized by dialysis against the disassembly buffer and repolymerized by the addition of glycerol to the clarified supernatant obtained afer disassembly. The filament assembly reaction was complete in less than 30 s as measured by turbidimetric changes at 415 nm and did not require any added nucleotide. No assembly of filaments was detected when using frozen tissue. The assembled filaments corresponded to the enrichment of neurofilament triplet, the 210,000, 160,000 and 70,000 dalton polypeptides on SDS-polyacrylamide gels and appeared morphologically and immunochemically identical to neurofilaments isolated by axonal flotation methods. These studies demonstrate in vitro assembly of neurofilaments under native conditions which raises the possibility that like microtubules, neurofilaments or a subpopulation of neurofilaments might be in a dynamic state of assembly--disassembly in situ.

Antisera to scrapie-associated fibril protein and prion protein decorate scrapie-associated fibrils.

Scrapie-associated fibrils (SAF) are an infection-specific structure observed in the unconventional-agent diseases. Polyclonal antisera raised to scrapie proteins were used to test the antigenic relationship between purified fibrils and SAF isolated from non-protease-treated synaptosomal-mitochondrial preparations. The experimental design utilized fibrils from scrapie strain 263K-infected hamsters, scrapie strain 139A-infected mice, and scrapie strain ME7-infected mice. Preparations were examined by negative-stain immune electron microscopy and Western blot analysis of the polypeptides. Fibrils and polypeptides from each preparation reacted with a rabbit antiserum raised to each of the following: hamster 263K prion protein (PrP 27-30), hamster 263K SAF protein, and mouse ME7 SAF protein. Immune electron microscopy and Western blot analysis revealed similar antigenic relationships among the three scrapie antisera. Thus, fibrils and polypeptides can be considered to be the same in each preparation. No reactivity of the fibrils was observed with antisera raised to Alzheimer neurofibrillary tangles or a synthetic peptide of cerebrovascular amyloid. Thus, the fibrils observed in purified preparations share structural and antigenic similarities plus biochemically related peptides with SAF present in non-protease-treated preparations.

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.

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.

Defective brain microtubule assembly in Alzheimer's disease.

Brains obtained within 2-4 hours post mortem and histopathologically confirmed for Alzheimer's disease and non-Alzheimer brains from age-matched controls were examined for in-vitro assembly of microtubules and neurofilaments. Microtubule assembly was observed only in control but not in Alzheimer brains, and neurofilaments were obtained from both types of brain. The microtubule-associated protein tau, which stimulates assembly of microtubules from tubulin, was abnormally phosphorylated in Alzheimer but not in control brain microtubule preparations. Alzheimer brains did not show the presence of any inhibitor of microtubule assembly or any abnormality of tubulin. DEAE-dextran, a polycation which mimics tau in stimulating microtubule assembly, induced the assembly of microtubules in Alzheimer brain. Tubulin from both normal and Alzheimer brains was labelled on western blots by a monoclonal antibody to the tyrosinylated carboxy-terminal epitope of alpha tubulin. These studies suggest that in Alzheimer's disease tubulin can be assembled into brain microtubules, but the process is defective, probably because of abnormal phosphorylation of tau. This post-translational alteration of tau might be the cause of the neurofibrillary abnormality in Alzheimer's disease.

Paired helical filaments associated with Alzheimer disease are readily soluble structures.

Considerable controversy exists concerning the origin and composition of Alzheimer neurofibrillary tangles (ANT) and of paired helical filaments (PHF), the abnormal cytoplasmic fibers which ultrastructurally are the major components of ANT. Thus far, the unusual solubility properties of PHF have hindered the analysis of ANT. A new procedure is presented for isolating purified PHF which are soluble in the presence of sodium dodecyl sulfate. The purification protocol involves differential and rate zonal centrifugation, treatment with the detergents sarcosyl and sulfobetain 3-14, and sonication. The isolated PHF from Alzheimer disease/senile dementia of the Alzheimer type (7 cases) and Down's syndrome (one case) have been characterized structurally by negative-stain electron microscopy, biochemically by PAGE, and immunologically by both the ELISA technique and Western blot analysis using a monoclonal antibody prepared against ANT. Distinct polypeptides were shown to be associated with this structure and not seen in preparations from young and age-matched normal brains.

Detection of scrapie-associated fibril (SAF) proteins using anti-SAF antibody in non-purified tissue preparations.

Antisera raised to scrapie-associated fibril (SAF) proteins were used to detect scrapie-specific polypeptides in three different non-purified brain preparations: a synaptosomal-mitochondrial fraction, 20% brain homogenate and 20% brain homogenate extracted with Sarkosyl. The concentration of SAF proteins in the preparations was greater than the quantity of SAF as detected by negative stain electron microscopy. This suggests that not all of the protein exists in the form of SAF. An immunologically reactive 33K to 35K protein was detected in both normal and scrapie brain preparations. This protein was susceptible to complete proteinase K (PK) digestion in normal brain preparations and it is suggested that scrapie infection is responsible for post-translational modifications which confer PK resistance in scrapie preparations. These modifications may also play a role in the antigenic differences seen in a variety of scrapie agents. SAF-specific proteins were also detected in the spinal cords and spleens from scrapie-affected animals. Detergent extraction of material followed by PK treatment and Western blot analysis is a highly specific and sensitive method for the detection of SAF proteins. This procedure could be applied to human neurological diseases of unknown aetiology.

Partial copurification of scrapie-associated fibrils and scrapie infectivity.

The association between scrapie infectivity and scrapie-associated fibrils (SAF) during a partial purification procedure for infectivity was investigated. Scrapie infectivity and SAF can be separated from most membrane components by subcellular fractionation of infected mouse brain to obtain a synaptosomal fraction, followed by detergent treatment and density gradient centrifugation. After different detergent treatments, with either octyl glucoside or sodium N-lauroyl sarcosinate, SAF showed differing sedimentation characteristics but nevertheless cosedimented with scrapie infectivity in both cases. Copurification under two different conditions provides more evidence that SAF may be a form of the infectious agent of scrapie.

Biochemical differences among scrapie-associated fibrils support the biological diversity of scrapie agents.

Scrapie-associated fibrils (SAF) were isolated and purified from animals infected with three different scrapie agents: ME7 and 139A in mice, and 263K in hamsters. Mouse ME7 and 139A SAF differed from hamster 263K SAF in morphology, sedimentation rate and protein composition. SAF from the three scrapie agents were distinguishable from each other by their sensitivity to proteinase K digestion. SAF copurified with infectivity in both the hamster and mouse systems. SAF appear to be a unique class of structures which are related but specific for each individual scrapie agent. These properties may correlate with the biological and pathological differences seen among these agents.

Ultrastructure of paired helical filaments of Alzheimer's neurofibrillary tangle.

Isolated paired helical filaments (PHF) of Alzheimer's disease and senile dementia of the Alzheimer type (AD/SDAT) were studied by negative stain techniques and electron microscopy (EM). The helical structure of the PHF was confirmed by tilt analysis of negatively stained isolated PHF. A substructure of four protofilaments, each 3-5 nm in diameter, was also observed. A comparison of PHF substructure, neurofilaments and microtubules, revealed no similarity among the three structures.