Small Protease Sensitive Oligomers of PrPSc in Distinct Human Prions Determine Conversion Rate of PrPC

The mammalian prions replicate by converting cellular prion protein (PrP^C) into pathogenic conformational isoform (PrP^Sc). Variations in prions, which cause different disease phenotypes, are referred to as strains. The mechanism of high-fidelity replication of prion strains in the absence of nucleic acid remains unsolved. We investigated the impact of different conformational characteristics of PrP^Sc on conversion of PrP^C in vitro using PrP^Sc seeds from the most frequent human prion disease worldwide, the Creutzfeldt-Jakob disease (sCJD). The conversion potency of a broad spectrum of distinct sCJD prions was governed by the level, conformation, and stability of small oligomers of the protease-sensitive (s) PrP^Sc. The smallest most potent prions present in sCJD brains were composed only of∼20 monomers of PrP^Sc. The tight correlation between conversion potency of small oligomers of human sPrP^Sc observed in vitro and duration of the disease suggests that sPrP^Sc conformers are an important determinant of prion strain characteristics that control the progression rate of the disease.     

Infectivity-associated PrPSc and disease duration-associated PrPSc of mouse BSE prions

ABSTRACT

Disease-related prion protein (PrP^Sc), which is a structural isoform of the host-encoded cellular prion protein, is thought to be a causative agent of transmissible spongiform encephalopathies. However, the specific role of PrP^Sc in prion pathogenesis and its relationship to infectivity remain controversial. A time-course study of prion-affected mice was conducted, which showed that the prion infectivity was not simply proportional to the amount of PrP^Sc in the brain. Centrifugation (20,000 ×g) of the brain homogenate showed that most of the PrP^Sc was precipitated into the pellet, and the supernatant contained only a slight amount of PrP^Sc. Interestingly, mice inoculated with the obtained supernatant showed incubation periods that were approximately 15 d longer than those of mice inoculated with the crude homogenate even though both inocula contained almost the same infectivity. Our results suggest that a small population of fine PrP^Sc may be responsible for prion infectivity and that large, aggregated PrP^Sc may contribute to determining prion disease duration.     

Prions,proteinase K and infectivity

It has been described that the breakdown of β-sheets in PrP^Sc by denaturation results in loss of infectivity and PK-sensitivity, suggesting a relationship between the structure and PK-resistance. It is also known that an important fraction of total PrP^Sc is PK-sensitive and can be isolated by the method we already described. Consequently, we decided to employ the PK-sensitive fraction of PrP^Sc as a potential and useful tool for structural studies. Thus, two essential questions were addressed in our recent article. First, the difference in the infectivity between the sensitive and resistant fractions and second, whether sensitive and resistant PrP^Sc shared the same conformation or were only different size multimers with the same basic conformation. Here we discuss our latest data in light of recent infectivity studies and their possible implications on the conformation of the prion.     

Prions,proteinase K and infectivity

It has been described that the breakdown of β-sheets in PrP^Sc by denaturation results in loss of infectivity and PK-sensitivity, suggesting a relationship between the structure and PK-resistance. It is also known that an important fraction of total PrP^Sc is PK-sensitive and can be isolated by the method we already described. Consequently, we decided to employ the PK-sensitive fraction of PrP^Sc as a potential and useful tool for structural studies. Thus, two essential questions were addressed in our recent article. First, the difference in the infectivity between the sensitive and resistant fractions and second, whether sensitive and resistant PrP^Sc shared the same conformation or were only different size multimers with the same basic conformation. Here we discuss our latest data in light of recent infectivity studies and their possible implications on the conformation of the prion.     

Prion Seeding Activities of Mouse Scrapie Strains with Divergent PrPSc Protease Sensitivities and Amyloid Plaque Content Using RT-QuIC and eQuIC

Different transmissible spongiform encephalopathy (TSE)-associated forms of prion protein (e.g. PrP^Sc) can vary markedly in ultrastructure and biochemical characteristics, but each is propagated in the host. PrP^Sc propagation involves conversion from its normal isoform, PrP^C, by a seeded or templated polymerization mechanism. Such a mechanism is also the basis of the RT-QuIC and eQuIC prion assays which use recombinant PrP (rPrP^Sen) as a substrate. These ultrasensitive detection assays have been developed for TSE prions of several host species and sample tissues, but not for murine models which are central to TSE pathogenesis research. Here we have adapted RT-QuIC and eQuIC to various murine prions and evaluated how seeding activity depends on glycophosphatidylinositol (GPI) anchoring and the abundance of amyloid plaques and protease-resistant PrP^Sc (PrP^Res). Scrapie brain dilutions up to 10⁻⁸ and 10⁻¹³ were detected by RT-QuIC and eQuIC, respectively. Comparisons of scrapie-affected wild-type mice and transgenic mice expressing GPI anchorless PrP showed that, although similar concentrations of seeding activity accumulated in brain, the heavily amyloid-laden anchorless mouse tissue seeded more rapid reactions. Next we compared seeding activities in the brains of mice with similar infectivity titers, but widely divergent PrP^Res levels. For this purpose we compared the 263K and 139A scrapie strains in transgenic mice expressing P101L PrP^C. Although the brains of 263K-affected mice had little immunoblot-detectable PrP^Res, RT-QuIC indicated that seeding activity was comparable to that associated with a high-PrP^Res strain, 139A. Thus, in this comparison, RT-QuIC seeding activity correlated more closely with infectivity than with PrP^Res levels. We also found that eQuIC, which incorporates a PrP^Sc immunoprecipitation step, detected seeding activity in plasma from wild-type and anchorless PrP transgenic mice inoculated with 22L, 79A and/or RML scrapie strains. Overall, we conclude that these new mouse-adapted prion seeding assays detect diverse types of PrP^Sc.     

Mutant PrPSc conformers induced by a synthetic peptide and several prion strains

Gerstmann-Sträussler-Scheinker (GSS) disease is a dominantly inherited, human prion disease caused by a mutation in the prion protein (PrP) gene. One mutation causing GSS is P102L, denoted P101L in mouse PrP (MoPrP). In a line of transgenic mice denoted Tg2866, the P101L mutation in MoPrP produced neurodegeneration when expressed at high levels. MoPrP^Sc(P101L) was detected both by the conformation-dependent immunoassay and after protease digestion at 4°C. Transmission of prions from the brains of Tg2866 mice to those of Tg196 mice expressing low levels of MoPrP(P101L) was accompanied by accumulation of protease-resistant MoPrP^Sc(P101L) that had previously escaped detection due to its low concentration. This conformer exhibited characteristics similar to those found in brain tissue from GSS patients. Earlier, we demonstrated that a synthetic peptide harboring the P101L mutation and folded into a β-rich conformation initiates GSS in Tg196 mice (29). Here we report that this peptide-induced disease can be serially passaged in Tg196 mice and that the PrP conformers accompanying disease progression are conformationally indistinguishable from MoPrP^Sc(P101L) found in Tg2866 mice developing spontaneous prion disease. In contrast to GSS prions, the 301V, RML, and 139A prion strains produced large amounts of protease-resistant PrP^Sc in the brains of Tg196 mice. Our results argue that MoPrP^Sc(P101L) may exist in at least several different conformations, each of which is biologically active. Such conformations occurred spontaneously in Tg2866 mice expressing high levels of MoPrP^C(P101L) as well as in Tg196 mice expressing low levels of MoPrP^C(P101L) that were inoculated with brain extracts from ill Tg2866 mice, with a synthetic peptide with the P101L mutation and folded into a β-rich structure, or with prions recovered from sheep with scrapie or cattle with bovine spongiform encephalopathy.The discovery that brain fractions enriched for prion infectivity contain a protein (rPrP^Sc) that is resistant to limited proteolytic digestion advanced prion research (8, 37). N-terminal truncation of rPrP^Sc produced a protease-resistant fragment, denoted PrP 27-30, that is readily measured by Western blotting, enzyme-linked immunosorbent assay, or immunohistochemistry. The measurement of PrP^Sc was dramatically changed with the development of the conformation-dependent immunoassay (CDI), which permitted detection of full-length rPrP^Sc as well as previously unrecognized protease-sensitive forms of PrP^Sc (39).The CDI depends on using anti-PrP antibodies that react with an epitope exposed in native PrP^C but that do not bind to native PrP^Sc. Upon denaturation, the buried epitope in PrP^Sc becomes exposed and readily reacts with anti-PrP antibodies. Using the CDI, we discovered that most PrP^Sc is protease sensitive, which we designate sPrP^Sc. Whether sPrP^Sc is an intermediate in the formation of rPrP^Sc remains to be determined. In Syrian hamsters inoculated with eight different strains of prions, the ratio of rPrP^Sc to sPrP^Sc was different for each strain and the concentration of sPrP^Sc was proportional to the length of the incubation time (39).In earlier studies, transgenic (Tg) mice, denoted Tg2866, expressing high levels of PrP(P101L) were used to model Gerstmann-Sträussler-Scheinker (GSS) disease caused by the P102L point mutation. In the brains of several lines of mice expressing high levels of PrP(P101L), no rPrP^Sc(P101L) was detectable (26, 27, 47). This was particularly perplexing since these Tg mice expressing high levels of PrP(P101L) developed all facets of prion-induced neurodegeneration, including multicentric PrP amyloid plaques. Moreover, brain extracts from ill Tg2866 mice transmitted disease to Tg196 mice expressing low levels of PrP(P101L) that infrequently developed spontaneous neurodegeneration (29).In humans with GSS, several different mutations of the PrP gene (PRNP) resulting in nonconservative amino acid substitutions have been identified (23). In these patients, the clinical presentation, disease course, and amounts of rPrP^Sc in the brain are variable. Brain extracts from humans who died of GSS were inoculated into apes and monkeys, but the transmission rates were not correlated with the levels of PrP^Sc in the inoculum (1, 2, 9, 32). In a limited study, GSS(P102L) was transmitted to Tg mice expressing a chimeric mouse-human (MHu2 M) PrP transgene carrying the P102L mutation but not to Tg mice expressing MHu2M PrP without the mutation (47). In another study, GSS(P102L) human prions were transmitted to Tg mice expressing MoPrP(P101L) in which the transgene was incorporated through gene replacement (31). The use of gene replacement permits all of the regulatory elements that control the wild-type (wt) MoPrP gene to modulate the expression of MoPrP(P101L). In these mice, the expression level of MoPrP(P101L) in brain is likely to be similar to that in Tg196 mice.When we synthesized a 55-mer MoPrP peptide composed of residues 89 to 143 containing the P101L mutation and folded it under conditions favoring a β-structure, it induced neurodegeneration in Tg196 mice (29). When the peptide was not folded into a β-structure, it did not produce disease in Tg196 mice. We report here that the peptide-initiated disease in Tg196 mice could be serially transmitted to other Tg196 mice using brain extracts from the peptide-inoculated Tg196 mice. Using procedures derived from the CDI, brain extracts from inoculated Tg196 mice were found to contain sPrP^Sc(P101L), from which a 22- to 24-kDa PrP fragment was generated by limited digestion with proteinase K (PK) at 4°C and selective precipitation with phosphotungstate (PTA) (25, 39). In the interest of clarity, we have designated digestion at 4°C as “cold PK” and simply refer to standard digestion at 37°C as “PK.” To aid in distinguishing rPrP^Sc(P101L) from sPrP^Sc(P101L), their properties based on the work reported here and in other previously published papers are listed in Table ​Table11 (39, 40).

TABLE 1.

Characteristics of PrP(P101L) isoforms

Establishment of a simple cell-based ELISA for the direct detection of abnormal isoform of prion protein from prion-infected cells without cell lysis and proteinase K treatment

Prion-infected cells have been used for analyzing the effect of compounds on the formation of abnormal isoform of prion protein (PrP^Sc). PrP^Sc is usually detected using anti-prion protein (PrP) antibodies after the removal of the cellular isoform of prion protein (PrP^C) by proteinase K (PK) treatment. However, it is expected that the PK-sensitive PrP^Sc (PrP^Sc-sen), which possesses higher infectivity and conversion activity than the PK-resistant PrP^Sc (PrP^Sc-res), is also digested through PK treatment. To overcome this problem, we established a novel cell-based ELISA in which PrP^Sc can be directly detected from cells persistently infected with prions using anti-PrP monoclonal antibody (mAb) 132 that recognizes epitope consisting of mouse PrP amino acids 119–127. The novel cell-based ELISA could distinguish prion-infected cells from prion-uninfected cells without cell lysis and PK treatment. MAb 132 could detect both PrP^Sc-sen and PrP^Sc-res even if all PrP^Sc molecules were not detected. The analytical dynamic range for PrP^Sc detection was approximately 1 log. The coefficient of variation and signal-to-background ratio were 7%–11% and 2.5–3.3, respectively, demonstrating the reproducibility of this assay. The addition of a cytotoxicity assay immediately before PrP^Sc detection did not affect the following PrP^Sc detection. Thus, all the procedures including cell culture, cytotoxicity assay, and PrP^Sc detection were completed in the same plate. The simplicity and non-requirement for cell lysis or PK treatment are advantages for the high throughput screening of anti-prion compounds.     

Re-Assessment of PrPSc Distribution in Sporadic and Variant CJD

Human prion diseases are fatal neurodegenerative disorders associated with an accumulation of PrP^Sc in the central nervous system (CNS). Of the human prion diseases, sporadic Creutzfeldt-Jakob disease (sCJD), which has no known origin, is the most common form while variant CJD (vCJD) is an acquired human prion disease reported to differ from other human prion diseases in its neurological, neuropathological, and biochemical phenotype. Peripheral tissue involvement in prion disease, as judged by PrP^Sc accumulation in the tonsil, spleen, and lymph node has been reported in vCJD as well as several animal models of prion diseases. However, this distribution of PrP^Sc has not been consistently reported for sCJD. We reexamined CNS and non-CNS tissue distribution and levels of PrP^Sc in both sCJD and vCJD. Using a sensitive immunoassay, termed SOFIA, we also assessed PrP^Sc levels in human body fluids from sCJD as well as in vCJD-infected humanized transgenic mice (Tg666). Unexpectedly, the levels of PrP^Sc in non-CNS human tissues (spleens, lymph nodes, tonsils) from both sCJD and vCJD did not differ significantly and, as expected, were several logs lower than in the brain. Using protein misfolding cyclic amplification (PMCA) followed by SOFIA, PrP^Sc was detected in cerebrospinal fluid (CSF), but not in urine or blood, in sCJD patients. In addition, using PMCA and SOFIA, we demonstrated that blood from vCJD-infected Tg666 mice showing clinical disease contained prion disease-associated seeding activity although the data was not statistically significant likely due to the limited number of samples examined. These studies provide a comparison of PrP^Sc in sCJD vs. vCJD as well as analysis of body fluids. Further, these studies also provide circumstantial evidence that in human prion diseases, as in the animal prion diseases, a direct comparison and intraspecies correlation cannot be made between the levels of PrP^Sc and infectivity.     

Structural Organization of Mammalian Prions as Probed by Limited Proteolysis

Elucidation of the structure of PrP^Sc continues to be one major challenge in prion research. The mechanism of propagation of these infectious agents will not be understood until their structure is solved. Given that high resolution techniques such as NMR or X-ray crystallography cannot be used, a number of lower resolution analytical approaches have been attempted. Thus, limited proteolysis has been successfully used to pinpoint flexible regions within prion multimers (PrP^Sc). However, the presence of covalently attached sugar antennae and glycosylphosphatidylinositol (GPI) moieties makes mass spectrometry-based analysis impractical. In order to surmount these difficulties we analyzed PrP^Sc from transgenic mice expressing prion protein (PrP) lacking the GPI membrane anchor. Such animals produce prions that are devoid of the GPI anchor and sugar antennae, and, thereby, permit the detection and location of flexible, proteinase K (PK) susceptible regions by Western blot and mass spectrometry-based analysis. GPI-less PrP^Sc samples were digested with PK. PK-resistant peptides were identified, and found to correspond to molecules cleaved at positions 81, 85, 89, 116, 118, 133, 134, 141, 152, 153, 162, 169 and 179. The first 10 peptides (to position 153), match very well with PK cleavage sites we previously identified in wild type PrP^Sc. These results reinforce the hypothesis that the structure of PrP^Sc consists of a series of highly PK-resistant β-sheet strands connected by short flexible PK-sensitive loops and turns. A sizeable C-terminal stretch of PrP^Sc is highly resistant to PK and therefore perhaps also contains β-sheet secondary structure.     

Sialylation of Prion Protein Controls the Rate of Prion Amplification,the Cross-Species Barrier,the Ratio of PrPSc Glycoform and Prion Infectivity

The central event underlying prion diseases involves conformational change of the cellular form of the prion protein (PrP^C) into the disease-associated, transmissible form (PrP^Sc). PrP^C is a sialoglycoprotein that contains two conserved N-glycosylation sites. Among the key parameters that control prion replication identified over the years are amino acid sequence of host PrP^C and the strain-specific structure of PrP^Sc. The current work highlights the previously unappreciated role of sialylation of PrP^C glycans in prion pathogenesis, including its role in controlling prion replication rate, infectivity, cross-species barrier and PrP^Sc glycoform ratio. The current study demonstrates that undersialylated PrP^C is selected during prion amplification in Protein Misfolding Cyclic Amplification (PMCAb) at the expense of oversialylated PrP^C. As a result, PMCAb-derived PrP^Sc was less sialylated than brain-derived PrP^Sc. A decrease in PrP^Sc sialylation correlated with a drop in infectivity of PMCAb-derived material. Nevertheless, enzymatic de-sialylation of PrP^C using sialidase was found to increase the rate of PrP^Sc amplification in PMCAb from 10- to 10,000-fold in a strain-dependent manner. Moreover, de-sialylation of PrP^C reduced or eliminated a species barrier of for prion amplification in PMCAb. These results suggest that the negative charge of sialic acid controls the energy barrier of homologous and heterologous prion replication. Surprisingly, the sialylation status of PrP^C was also found to control PrP^Sc glycoform ratio. A decrease in PrP^C sialylation levels resulted in a higher percentage of the diglycosylated glycoform in PrP^Sc. 2D analysis of charge distribution revealed that the sialylation status of brain-derived PrP^C differed from that of spleen-derived PrP^C. Knocking out lysosomal sialidase Neu1 did not change the sialylation status of brain-derived PrP^C, suggesting that Neu1 is not responsible for desialylation of PrP^C. The current work highlights previously unappreciated role of PrP^C sialylation in prion diseases and opens multiple new research directions, including development of new therapeutic approaches.     

The N-Terminal Sequence of Prion Protein Consists an Epitope Specific to the Abnormal Isoform of Prion Protein (PrPSc)

The conformation of abnormal prion protein (PrP^Sc) differs from that of cellular prion protein (PrP^C), but the precise characteristics of PrP^Sc remain to be elucidated. To clarify the properties of native PrP^Sc, we attempted to generate novel PrP^Sc-specific monoclonal antibodies (mAbs) by immunizing PrP-deficient mice with intact PrP^Sc purified from bovine spongiform encephalopathy (BSE)-affected mice. The generated mAbs 6A12 and 8D5 selectivity precipitated PrP^Sc from the brains of prion-affected mice, sheep, and cattle, but did not precipitate PrP^C from the brains of healthy animals. In histopathological analysis, mAbs 6A12 and 8D5 strongly reacted with prion-affected mouse brains but not with unaffected mouse brains without antigen retrieval. Epitope analysis revealed that mAbs 8D5 and 6A12 recognized the PrP subregions between amino acids 31–39 and 41–47, respectively. This indicates that a PrP^Sc-specific epitope exists in the N-terminal region of PrP^Sc, and mAbs 6A12 and 8D5 are powerful tools with which to detect native and intact PrP^Sc. We found that the ratio of proteinase K (PK)-sensitive PrP^Sc to PK-resistant PrP^Sc was constant throughout the disease time course.     

Generation of antisera to purified prions in lipid rafts

Prion diseases are fatal neurodegenerative disorders caused by prion proteins (PrP). Infectious prions accumulate in the brain through a template-mediated conformational conversion of endogenous PrP^C into alternately folded PrP^Sc. Immunoassays toward pre-clinical detection of infectious PrP^Sc have been confounded by low-level prion accumulation in non-neuronal tissue and the lack of PrP^Sc selective antibodies. We report a method to purify infectious PrP^Sc from biological tissues for use as an immunogen and sample enrichment for increased immunoassay sensitivity. Significant prion enrichment is accomplished by sucrose gradient centrifugation of infected tissue and isolation with detergent resistant membranes from lipid rafts (DRMs). At equivalent protein concentration a 50-fold increase in detectable PrP^Sc was observed in DRM fractions relative to crude brain by direct ELISA. Sequential purification steps result in increased specific infectivity (DRM >20-fold and purified DRM immunogen >40-fold) relative to 1% crude brain homogenate. Purification of PrP^Sc from DRM was accomplished using phosphotungstic acid protein precipitation after proteinase-K (PK) digestion followed by size exclusion chromatography to separate PK and residual protein fragments from larger prion aggregates. Immunization with purified PrP^Sc antigen was performed using wild-type (wt) and Prnp^0/0 mice, both on Balb/cJ background. A robust immune response against PrP^Sc was observed in all inoculated Prnp^0/0 mice resulting in antisera containing high-titer antibodies against prion protein. Antisera from these mice recognized both PrP^C and PrP^Sc, while binding to other brain-derived protein was not observed. In contrast, the PrP^Sc inoculum was non-immunogenic in wt mice and antisera showed no reactivity with PrP or any other protein.Key words: prion, scrapie, Prnp0/0 mice, purification methodology, antibody, antisera, lipid-rafts, detergent resistant membranes, neuroscience, immunization, diagnostic     

Scrapie prion protein structural constraints obtained by limited proteolysis and mass spectrometry

Elucidation of the structure of scrapie prion protein (PrP^Sc), essential to understand the molecular mechanism of prion transmission, continues to be one of the major challenges in prion research and is hampered by the insolubility and polymeric character of PrP^Sc. Limited proteolysis is a useful tool to obtain insight on structural features of proteins: proteolytic enzymes cleave proteins more readily at exposed sites, preferentially within loops, and rarely in β-strands. We treated PrP^Sc isolated from brains of hamsters infected with 263K and drowsy prions with varying concentrations of proteinase K (PK). After PK deactivation, PrP^Sc was denatured, reduced, and cleaved at Cys179 with 2-nitro-5-thiocyanatobenzoic acid. Fragments were analyzed by nano-HPLC/mass spectrometry and matrix-assisted laser desorption/ionization. Besides the known cleavages at positions 90, 86, and 92 for 263K prions and at positions 86, 90, 92, 98, and 101 for drowsy prions, our data clearly demonstrate the existence of additional cleavage sites at more internal positions, including 117, 119, 135, 139, 142, and 154 in both strains. PK concentration dependence analysis and limited proteolysis after partial unfolding of PrP^Sc confirmed that only the mentioned cleavage sites at the N-terminal side of the PrP^Sc are susceptible to PK. Our results indicate that besides the “classic” amino-terminal PK cleavage points, PrP^Sc contains, in its middle core, regions that show some degree of susceptibility to proteases and must therefore correspond to subdomains with some degree of structural flexibility, interspersed with stretches of amino acids of high resistance to proteases. These results are compatible with a structure consisting of short β-sheet stretches connected by loops and turns.     

Prion formation,but not clearance,is supported by protein misfolding cyclic amplification

Prion diseases are fatal transmissible neurodegenerative disorders that affect animals including humans. The kinetics of prion infectivity and PrP^Sc accumulation can differ between prion strains and within a single strain in different tissues. The net accumulation of PrP^Sc in animals is controlled by the relationship between the rate of PrP^Sc formation and clearance. Protein misfolding cyclic amplification (PMCA) is a powerful technique that faithfully recapitulates PrP^Sc formation and prion infectivity in a cell-free system. PMCA has been used as a surrogate for animal bioassay and can model species barriers, host range, strain co-factors and strain interference. In this study we investigated if degradation of PrP^Sc and/or prion infectivity occurs during PMCA. To accomplish this we performed PMCA under conditions that do not support PrP^Sc formation and did not observe either a reduction in PrP^Sc abundance or an extension of prion incubation period, compared to untreated control samples. These results indicate that prion clearance does not occur during PMCA. These data have significant implications for the interpretation of PMCA based experiments such as prion amplification rate, adaptation to new species and strain interference where production and clearance of prions can affect the outcome.     

Rapid, high-throughput detection of PrPSc by 96-well immunoassay

Prion diseases are emerging infectious disorders that affect several mammalian species including humans. The transmissible agent is comprised of PrP^Sc, a misfolded isoform of the normal host-encoded prion protein PrP^C. Immunodetection of PrP^Sc is often utilized for prion disease diagnosis and tracking spread of the infectious agent through the host. We have developed a rapid, high-throughput 96-well immunoassay, which is specific for the detection of PrP^Sc. This assay has PrP^Sc detection limits similar to western blot and is advantageous because of its comparatively shorter running time, smaller start-up and operation costs and large sample capacity.Key words: prion disease, immunodetection, PrP^Sc     

Protease-Sensitive Synthetic Prions

Prions arise when the cellular prion protein (PrP^C) undergoes a self-propagating conformational change; the resulting infectious conformer is designated PrP^Sc. Frequently, PrP^Sc is protease-resistant but protease-sensitive (s) prions have been isolated in humans and other animals. We report here that protease-sensitive, synthetic prions were generated in vitro during polymerization of recombinant (rec) PrP into amyloid fibers. In 22 independent experiments, recPrP amyloid preparations, but not recPrP monomers or oligomers, transmitted disease to transgenic mice (n = 164), denoted Tg9949 mice, that overexpress N-terminally truncated PrP. Tg9949 control mice (n = 174) did not spontaneously generate prions although they were prone to late-onset spontaneous neurological dysfunction. When synthetic prion isolates from infected Tg9949 mice were serially transmitted in the same line of mice, they exhibited sPrP^Sc and caused neurodegeneration. Interestingly, these protease-sensitive prions did not shorten the life span of Tg9949 mice despite causing extensive neurodegeneration. We inoculated three synthetic prion isolates into Tg4053 mice that overexpress full-length PrP; Tg4053 mice are not prone to developing spontaneous neurological dysfunction. The synthetic prion isolates caused disease in 600–750 days in Tg4053 mice, which exhibited sPrP^Sc. These novel synthetic prions demonstrate that conformational changes in wild-type PrP can produce mouse prions composed exclusively of sPrP^Sc.     

Chemically Induced Accumulation of GAGs Delays PrPSc Clearance but Prolongs Prion Disease Incubation Time

Prion diseases are a group of fatal neurodegenerative diseases affecting humans and animals. The only identified component of the infectious prion is PrP^Sc, an aberrantly folded isoform of PrP^C. Glycosaminoglycans, which constitute the main receptor for prions on cells, play a complex role in the pathogenesis of prion diseases. For example, while agents inducing aberrant lysosomal accumulation of GAGs such as Tilorone and Quinacrine significantly reduced PrP^Sc content in scrapie-infected cells, administration of Quinacrine to prion-infected subjects did not improve their clinical status. In this study, we investigated the association of PrP^Sc with cells cultured with Tilorone. We found that while the initial incorporation of PrP^Sc was similar in the treated and untreated cells, clearance of PrP^Sc from the Tilorone-treated cells was significantly impaired. Interestingly, prolonged administration of Tilorone to mice prior to prion infection resulted in a significant delay in disease onset, concomitantly with in vivo accumulation of lysosomal GAGs. We hypothesize that GAGs may complex with newly incorporated PrP^Sc in lysosomes and further stabilize the prion protein conformation. Over-stabilized PrP^Sc molecules have been shown to comprise reduced converting activity.     

Biochemical Characteristics and PrPSc Distribution Pattern in the Brains of Cattle Experimentally Challenged with H-type and L-type Atypical BSE

Besides the classical form of bovine spongiform encephalopathy (BSE) that has been known for almost three decades, two atypical forms designated H-type and L-type BSE have recently been described. While the main diagnostic feature of these forms is the altered biochemical profile of the accumulated PrP^Sc, it was also observed in the initial analysis that L-type BSE displays a distribution pattern of the pathological prion protein (PrP^Sc), which clearly differs from that observed in classical BSE (C-type). Most importantly, the obex region in the brainstem is not the region with the highest PrP^Sc concentrations, but PrP^Sc is spread more evenly throughout the entire brain. A similar distribution pattern has been revealed for H-type BSE by rapid test analysis. Based on these findings, we performed a more detailed Western blot study of the anatomical PrP^Sc distribution pattern and the biochemical characteristics (molecular mass, glycoprofile as well as PK sensitivity) in ten different anatomical locations of the brain from cattle experimentally challenged with H- or L-type BSE, as compared to cattle challenged with C-type BSE. Results of this study revealed distinct differences in the PrP^Sc deposition patterns between all three BSE forms, while the biochemical characteristics remained stable for each BSE type among all analysed brain areas.     

PrPST,a Soluble,Protease Resistant and Truncated PrP Form Features in the Pathogenesis of a Genetic Prion Disease

While the conversion of PrP^C into PrP^Sc in the transmissible form of prion disease requires a preexisting PrP^Sc seed, in genetic prion disease accumulation of disease related PrP could be associated with biochemical and metabolic modifications resulting from the designated PrP mutation. To investigate this possibility, we looked into the time related changes of PrP proteins in the brains of TgMHu2ME199K/wt mice, a line modeling for heterozygous genetic prion disease linked to the E200K PrP mutation. We found that while oligomeric entities of mutant E199KPrP exist at all ages, aggregates of wt PrP in the same brains presented only in advanced disease, indicating a late onset conversion process. We also show that most PK resistant PrP in TgMHu2ME199K mice is soluble and truncated (PrP^ST), a pathogenic form never before associated with prion disease. We next looked into brain samples from E200K patients and found that both PK resistant PrPs, PrP^ST as in TgMHu2ME199K mice, and “classical” PrP^Sc as in infectious prion diseases, coincide in the patient''s post mortem brains. We hypothesize that aberrant metabolism of mutant PrPs may result in the formation of previously unknown forms of the prion protein and that these may be central for the fatal outcome of the genetic prion condition.     

PrP Expression,PrPSc Accumulation and Innervation of Splenic Compartments in Sheep Experimentally Infected with Scrapie

Background

In prion disease, the peripheral expression of PrP^C is necessary for the transfer of infectivity to the central nervous system. The spleen is involved in neuroinvasion and neural dissemination in prion diseases but the nature of this involvement is not known. The present study undertook the investigation of the spatial relationship between sites of PrP^Sc accumulation, localisation of nerve fibres and PrP^C expression in the tissue compartments of the spleen of scrapie-inoculated and control sheep.

Methodology/Principal Findings

Laser microdissection and quantitative PCR were used to determine PrP mRNA levels and results were compared with immunohistochemical protocols to distinguish PrP^C and PrP^Sc in tissue compartments of the spleen. In sheep experimentally infected with scrapie, the major sites of accumulation of PrP^Sc in the spleen, namely the lymphoid nodules and the marginal zone, expressed low levels of PrP mRNA. Double immunohistochemical labelling for PrP^Sc and the pan-nerve fibre marker, PGP, was used to evaluate the density of innervation of splenic tissue compartments and the intimacy of association between PrP^Sc and nerves. Some nerve fibres were observed to accompany blood vessels into the PrP^Sc-laden germinal centres. However, the close association between nerves and PrP^Sc was most apparent in the marginal zone. Other sites of close association were adjacent to the wall of the central artery of PALS and the outer rim of germinal centres.

Conclusions/Significance

The findings suggest that the degree of PrP^Sc accumulation does not depend on the expression level of PrP^C. Though several splenic compartments may contribute to neuroinvasion, the marginal zone may play a central role in being the compartment with most apparent association between nerves and PrP^Sc.