Mouse model of neurodegeneration: atrophy of basal forebrain cholinergic neurons in trisomy 16 transplants.

Vulnerability of specific brain regions and neuronal populations is a characteristic feature of Alzheimer disease and Down syndrome. Cholinergic neurons of the basal forebrain degenerate in both disorders. The basis for neuronal degeneration is unknown. Mouse trisomy 16 (Ts 16) is an animal model of Down syndrome. We sought an experimental system in which the survival and development of Ts 16 basal forebrain cholinergic neurons could be examined beyond the fetal period. As Ts 16 mice do not survive birth, we transplanted fetal Ts 16 and control basal forebrain into the hippocampus of young adult mice. Transplanted neurons survived and grew neurites in all grafts. Over time, we observed selective atrophy of cholinergic neurons in Ts 16 grafts. Denervation of the hippocampus produced a significant increase in the size of Ts 16 cholinergic neurons. This suggests that hippocampal-derived neurotrophic factors acted to prevent degeneration. beta/A4-amyloid-containing plaques were not seen. Ts 16 provides a model of spontaneous, genetically determined neurodegeneration that may be used to understand better the molecular pathogenesis of neuronal dysfunction in Alzheimer disease and Down syndrome.

Ultrastructural localization of scrapie prion proteins in cytoplasmic vesicles of infected cultured cells.

Infectious scrapie prions are composed largely, if not entirely, of an abnormal isoform of the prion protein (PrP) designated PrPSc. In scrapie-infected mouse neuroblastoma (ScN2a) and hamster brain (ScHaB) cells, PrPSc accumulates primarily within the cell cytoplasm, whereas cellular PrP (PrPC) is anchored to the external surface of the plasma membrane by a glycoinositol phospholipid moiety. To determine the subcellular localization of PrPSc, scrapie-infected cells were grown to approximately 75% confluency, fixed briefly, and then incubated with guanidine thiocyanate before antibody staining and examination by electron microscopy. PrPSc immunoreactivity was enhanced by denaturation with guanidine isothiocyanate which also permeabilized cells (Taraboulos et al., J Cell Biol 110:2117, 1990). As judged both by deposition of immunoperoxidase reaction product (diaminobenzidine) and by presence of immunogold particles, PrPSc was identified in discrete vesicular foci and some large bodies in the cytoplasm of scrapie-infected cells. Some vesicles with PrPSc staining also contained myelin figures resembling those found in autophagic vacuoles forming secondary lysosomes. The presence of PrPSc in secondary lysosomes is inferred from colocalization of guanidine isothiocyanate enhanced PrP immunoreactivity and acid phosphatase. Neither the diaminobenzidine reaction product nor immunogold particles were observed in association with the nucleus, endoplasmic reticulum, or Golgi stacks. Exposure of scrapie-infected cells to the brefeldin A dispersed the Golgi apparatus but did not alter the morphologic distribution of PrPSc, indicating that no detectable PrPSc was associated with Golgi stacks. It remains to be established whether secondary lysosomes are involved in the post-translational formation of PrPSc.

Scrapie prion rod formation in vitro requires both detergent extraction and limited proteolysis.

Scrapie prion infectivity can be enriched from hamster brain homogenates by using limited proteolysis and detergent extraction. Purified fractions contain both scrapie infectivity and the protein PrP 27-30, which is aggregated in the form of prion rods. During purification, PrP 27-30 is produced from a larger membrane protein, PrPSc, by limited proteolysis with proteinase K. Brain homogenates from scrapie-infected hamsters do not contain prion rods prior to exposure to detergents and proteases. To determine whether both detergent extraction and limited proteolysis are required for the formation of prion rods, microsomal membranes were prepared from infected brains in the presence of protease inhibitors. The isolated membranes were then detergent extracted as well as protease digested to evaluate the effects of these treatments on the formation of prion rods. Neither detergent (2% Sarkosyl) extraction nor limited proteinase K digestion of scrapie microsomes produced recognizable prion amyloid rods. Only after combining detergent extraction with limited proteolysis were numerous prion rods observed. Rod formation was influenced by the protease concentration, the specificity of the protease, and the duration of digestion. Rod formation also depended upon the detergent; some combinations of protease and detergent did not produce prion amyloid rods. Similar results were obtained with purified PrPSc fractions prepared by repeated detergent extractions in the presence of protease inhibitors. These fractions contained amorphous structures but not rods; however, prion rods were produced upon conversion of PrPSc to PrP 27-30 by limited proteolysis. We conclude that the formation of prion amyloid rods in vitro requires both detergent extraction and limited proteolysis. In vivo, amyloid filaments found in the brains of animals with scrapie resemble prion rods in their width and their labeling with prion protein (PrP) antisera; however, filaments are typically longer than rods. Whether limited proteolysis and some process equivalent to detergent extraction are required for amyloid filament formation in vivo remains to be established.

Acquisition of protease resistance by prion proteins in scrapie-infected cells does not require asparagine-linked glycosylation.

The scrapie and cellular isoforms of the prion protein (PrPSc and PrPC) differ strikingly in a number of their biochemical and metabolic properties. The structural features underlying these differences are unknown, but they are thought to result from a posttranslational process. Both PrP isoforms contain complex type oligosaccharides, raising the possibility that differences in the asparagine-linked glycosylation account for the properties that distinguish PrPC and PrPSc. ScN2a and ScHaB cells in culture produce several PrP molecules with relative molecular masses of 26-35 kDa and proteinase K-resistant cores of 19-29 kDa. When the cells were treated with tunicamycin, this heterogeneity was eliminated and a single PrP species of 26 kDa was observed. Several hours after its synthesis, a fraction of this protein became insoluble in detergents and acquired a proteinase K-resistant core, thus displaying two of the biochemical hallmarks of PrPSc. Synthesis in the presence of tunicamycin restricted the proteinase K-resistant cores of PrP to a single species of 19 kDa. No proteinase K-resistant PrP was found in uninfected cells. Expression of a mutated PrP gene lacking both asparagine-linked glycosylation sites in ScN2a cells resulted in the synthesis of 19-kDa proteinase K-resistant PrP molecules. We conclude that asparagine-linked glycosylation is not essential for the synthesis of proteinase K-resistant PrP and that structural differences unrelated to asparagine-linked oligosaccharides must exist between PrPC and PrPSc. Whether unglycosylated PrPSc molecules are associated with scrapie prion infectivity remains to be established.

Three hamster species with different scrapie incubation times and neuropathological features encode distinct prion proteins.

Given the critical role of the prion protein (PrP) in the transmission and pathogenesis of experimental scrapie, we investigated the PrP gene and its protein products in three hamster species, Chinese (CHa), Armenian (AHa), and Syrian (SHa), each of which were found to have distinctive scrapie incubation times. Passaging studies demonstrated that the host species, and not the source of scrapie prions, determined the incubation time for each species, and histochemical studies of hamsters with clinical signs of scrapie revealed characteristic patterns of neuropathology. Northern (RNA) analysis showed the size of PrP mRNA from CHa, AHa, and SHa hamsters to be 2.5, 2.4, and 2.1 kilobases, respectively. Immunoblotting demonstrated that the PrP isoforms were of similar size (33 to 35 kilodaltons); however, the monoclonal antibody 13A5 raised against SHa PrP did not react with the CHa or AHa PrP molecules. Comparison of the three predicted amino acid sequences revealed that each is distinct. Furthermore, differences within the PrP open reading frame that uniquely distinguish the three hamster species are within a hydrophilic segment of 11 amino acids that includes polymorphisms linked to scrapie incubation times in inbred mice and an inherited prion disease of humans. Single polymorphisms in this region correlate with the presence or absence of amyloid plaques for a given hamster species or mouse inbred strain. Our findings demonstrate distinctive molecular, pathological, and clinical characteristics of scrapie in three related species and are consistent with the hypothesis that molecular properties of the host PrP play a pivotal role in determining the incubation time and neuropathological features of scrapie.

Acceleration of scrapie in neonatal Syrian hamsters.

Prions cause Creutzfeldt-Jakob disease, Gerstmann-Sträussler syndrome, and kuru of humans as well as scrapie of animals. Prolonged incubation periods, from months to decades, precede clinical disease. In studies on the biochemical characteristics of prions, weanling Syrian hamsters have been used extensively because they have relatively short incubation periods. In studies reported here, inoculation of neonatal hamsters significantly shortened the scrapie incubation period even further. Our results show that the scrapie incubation period in hamsters is a function of age. The interval between inoculation and death from scrapie plotted as a function of age (0 to 30 days) gave a correlation coefficient (r) of 0.86. The duration of clinical disease was also shortened in the hamsters inoculated as neonates compared with weanlings. Intraventricular injection of nerve growth factor prior to inoculation of neonates with scrapie significantly diminished the acceleration observed with scrapie alone in neonates. Histopathologic studies of brain from scrapie-inoculated neonates showed more extensive neuronal loss in the hippocampus and neocortex as well as a more profound gliosis in the caudate compared with animals inoculated as weanlings. Our results demonstrate an age-dependent acceleration of scrapie in neonatal hamsters and may provide a new experimental system for defining factors that modify the pathogenesis of prion diseases.

Immunoaffinity purification and neutralization of scrapie prions.

The scrapie agent causes a degenerative neurologic disease and can be transmitted to laboratory rodents. The unusual properties of the scrapie agent prompted introduction of the term prion in order to distinguish this class of novel pathogens from viruses and viroids. The scrapie prion protein (PrPSc) is the only component of the infectious scrapie prion identified, to date. Although many biochemical and genetic lines of evidence argue that PrPSc is a major component of the infectious particle, the most convincing data is derived from immunoaffinity purification studies. Limited proteinase K digestion of hamster brain PrPSc produced PrP 27-30. After dispersion of brain microsomes isolated from scrapie-infected hamsters into detergent-lipid-protein complexes (DLPC), copurification of PrPSc and scrapie infectivity was obtained with PrP 27-30 monoclonal antibody affinity columns. PrPSc was enriched approximately 5700-fold with respect to total brain protein while scrapie prion infectivity was enriched approximately -4000-fold. The ratio of prion titer to PrPSc remained constant throughout purification. Heterologous monoclonal antibody columns failed to bind either PrpSc or scrapie infectivity. Polyclonal rabbit PrP antiserum raised against sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)-purified PrP 27-30 reduced scrapie infectivity dispersed into DLPC by a factor of 100. Our findings represent the first direct immunologic and chromatographic demonstrations of a relationship between PrPSc and prion infectivity as well as providing additional support for the contention that PrPSc is a major component of the infectious scrapie particle. While these results and those of other studies establish that PrPSc is a component of the infectious prion, the possibility of a second component such as a small nucleic acid which might be required for infection must still be considered. 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. The mouse PrP gene is on chromosome 2 and is linked to a gene controlling the scrapie incubation time (Prn-i).(ABSTRACT TRUNCATED AT 400 WORDS)

Nerve growth factor increases mRNA levels for the prion protein and the beta-amyloid protein precursor in developing hamster brain.

Deposition of amyloid filaments serves as a pathologic hallmark for some neurodegenerative disorders. The prion protein (PrP) is found in amyloid of animals with scrapie and humans with Creutzfeldt-Jakob disease; the beta protein is present in amyloid deposits in Alzheimer disease and Down syndrome patients. These two proteins are derived from precursors that in the brain are expressed primarily in neurons and are membrane bound. We found that gene expression for PrP and the beta-protein precursor (beta-PP) is regulated in developing hamster brain. Specific brain regions showed distinct patterns of ontogenesis for PrP and beta-PP mRNAs. The increases in PrP and beta-PP mRNAs in developing basal forebrain coincided with an increase in choline acetyltransferase activity, raising the possibility that these markers might be coordinately controlled in cholinergic neurons and regulated by nerve growth factor (NGF). Injections of NGF into the brains of neonatal hamsters increased both PrP and beta-PP mRNA levels. Increased PrP and beta-PP mRNA levels induced by NGF were confined to regions that contain NGF-responsive cholinergic neurons and were accompanied by elevations in choline acetyltransferase. It remains to be established whether or not exogenous NGF acts to increase PrP and beta-PP gene expression selectively in forebrain cholinergic neurons in the developing hamster and endogenous NGF regulates expression of these genes.

Immunoaffinity purification and neutralization of scrapie prion infectivity.

Prions are unusual infectious pathogens causing scrapie of sheep and goats as well as Creutzfeldt-Jakob disease of humans. Biochemical and genetic studies contend that the scrapie isoform of the prion protein (PrPSc) is a major component of the prion. Limited proteinase K digestion of PrPSc produced a protein of 27-30 kDa. After dispersion of brain microsomes isolated from scrapie-infected hamsters into detergent-lipid-protein complexes, copurification of PrPSc and scrapie infectivity was obtained with scrapie prion protein of 27-30 kDa monoclonal antibody-affinity columns. PrPSc was enriched approximately equal to 5700-fold with respect to total brain protein, whereas scrapie prion infectivity was enriched approximately equal to 4000-fold. The ratio of prion titer to PrPSc remained constant throughout purification. Heterologous monoclonal antibody columns failed to bind either PrPSc or scrapie infectivity. Polyclonal rabbit prion protein antiserum raised against NaDodSO4/PAGE-purified scrapie prion protein of 27-30 kDa reduced scrapie infectivity dispersed into detergent-lipid-protein complexes by a factor of 100. These results represent direct immunologic and chromatographic demonstrations of a relationship between PrPSc and prion infectivity as well as providing additional support for the contention that PrPSc is a major component of the infectious scrapie particle. That PrPSc is a host-encoded protein is an important feature distinguishing prions from viruses.

Properties of scrapie prion protein liposomes.

Purified scrapie prions contain one identifiable macromolecule, PrP 27-30, which polymerizes into rod-shaped amyloids. The rods can be dissociated with retention of scrapie infectivity upon incorporation of PrP 27-30 into detergent-lipid-protein complexes (DLPC) as well as liposomes. As measured by end-point titration, scrapie infectivity was increased greater than 100-fold upon dissociating the rods into liposomes. The incorporation of PrP 27-30 into liposomes was demonstrated by immunoelectron microscopy using colloidal gold. Detergent extraction of prion liposomes followed by chloroform/methanol extraction resulted in the reappearance of rods, indicating that this process is reversible. Scrapie prion infectivity in rods and liposomes was equally resistant to inactivation by irradiation at 254 nm and was unaltered by exposure to nucleases. A variety of lipids used for producing DLPC and liposomes did not alter infectivity. Fluorescently labeled PrP 27-30 in liposomes was used to study its entry into cultured cells. Unlike the rods which remained as large fluorescent extracellular masses, the PrP 27-30 in liposomes rapidly entered the cells and was seen widely distributed within the interior of the cell. PrP 27-30 is derived by limited proteolysis from a larger protein designated PrP(Sc) which is membrane bound. PrP(Sc) in membrane fractions was solubilized by incorporation in DLPC, thus preventing its aggregation into amyloid rods. The functional solubilization of scrapie prion proteins in DLPC and liposomes offers new approaches to the study of prion structure and the mechanism by which they cause brain degeneration.

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.

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.

Distinct prion proteins in short and long scrapie incubation period mice.

The Prn-i gene, controlling scrapie incubation period, is linked to or congruent with the murine prion protein (PrP) gene, Prn-p. In prototypic mouse strains with long (l/Ln) and short (NZW) incubation periods, Prn-p transcription is initiated at similar multiple sites. The predicted NZW and l/Ln PrP proteins differ at codons 108 and 189. Codon 189, highly conserved in mammals, lies within a polymorphic BstEll site that is retained in 17 mouse strains known to have short or intermediate incubation times, but is absent in l/Ln and two other inbred mice with long incubation times. Codon 108 in mice with short or intermediate incubation times encodes Leu; in mice with long incubation times it encodes Phe. The correlation of PrP sequence with length of scrapie incubation period suggests, but does not formally prove, congruency between Prn-p and Prn-i.

Purified scrapie prions resist inactivation by procedures that hydrolyze, modify, or shear nucleic acids.

Prions were purified from scrapie-infected hamster brains and incubated for 24 hr at 65 degrees with 2 mM Zn2+ or 5 mM Mg2+; no loss of infectivity was observed. Bacteriophage M13, tobacco mosaic virus (TMV), potato virus X, and potato spindle tuber viroid were all inactivated by divalent metal ions under these conditions. Prions also resisted inactivation by prolonged digestions with DNase I, RNases A and T1, and micrococcal nuclease. Prions were resistant to psoralen photoadduct formation using high concentrations of psoralens; in contrast, M13 bacteriophage was inactivated by low concentrations of all these psoralens. Hydroxylamine failed to inactivate prions even after lengthy exposures to concentrations as high as 1 M, while TMV and M13 were both inactivated. Sonication of prions failed to decrease infectivity even though rod-shaped aggregates were disrupted while both M13 and TMV lost infectivity.

Purified prion proteins and scrapie infectivity copartition into liposomes.

Considerable evidence indicates that the scrapie prion protein (PrP 27-30) is required for infectivity. Aggregates of PrP 27-30 form insoluble amyloid rods that resist dissociation by nondenaturing detergents. Mixtures of the detergent cholate and phospholipids were found to solubilize purified PrP 27-30 in the form of detergent-lipid-protein complexes. Removal of the cholate by dialysis resulted in the formation of closed liposomes. Both the detergent-lipid-protein complexes and the liposomes often but not always exhibited a 10-fold increase in scrapie infectivity compared to that observed with the rods. No evidence for a prion-associated nucleic acid could be found when the phospholipid vesicles containing PrP 27-30 were digested with nucleases and Zn2+ under conditions that allowed hydrolysis of exogenously added nucleic acids. No filamentous or rod-shaped particles were found amongst prion liposomes by electron microscopy in our search for a putative filamentous "scrapie virus." The partitioning of PrP 27-30 and scrapie infectivity into phospholipid vesicles contends that PrP 27-30 has a central role in scrapie pathogenesis, establishes that the prion amyloid rods are not essential for infectivity, and argues that prions are fundamentally different from viruses.

Developmental expression of prion protein gene in brain.

Synthesis of the cellular isoform of the prion protein (PrPC) was found to be regulated during development of the hamster brain. PrP poly A(+) RNA was readily detectable 10 days postpartum; after 20 days of age, no change in its level could be detected through 13 months of age. Low levels of PrP poly A(+) RNA were detectable 1 day after birth. By contrast, myelin basic protein poly A(+) RNA was found at high levels in brain at 30 days of age and thereafter declined steadily. Using monospecific PrP antisera, immunoprecipitable cell-free translation products were detected at low levels 2 days after birth and increased progressively through 10 days of age. How the levels of PrP mRNA participate in brain development and function remains to be established.

Predicted secondary structure and membrane topology of the scrapie prion protein.

The integral membrane sialoglycoprotein PrPSc is the only identifiable component of the scrapie prion. Scrapie in animals and Creutzfeldt-Jakob disease in humans are transmissible, degenerative neurological diseases caused by prions. Standard predictive strategies have been used to analyze the secondary structure of the prion protein in conjunction with Fourier analysis of the primary sequence hydrophobicities to detect potential amphipathic regions. Several hydrophobic segments, a proline- and glycine-rich repeat region and putative glycosylation sites are incorporated into a model for the integral membrane topology of PrP. The complete amino acid sequences of the hamster, human and mouse prion proteins are compared and the effects of residue substitutions upon the predicted conformation of the polypeptide chain are discussed. While PrP has a unique primary structure, its predicted secondary structure shares some interesting features with the serum amyloid A proteins. These proteins undergo a post-translational modification to yield amyloid A, molecules that share with PrP the ability to polymerize into birefringent filaments. Our analyses may explain some experimental observations on PrP, and suggest further studies on the properties of the scrapie and cellular PrP isoforms.