OBJECTIVETo expatiate dynamic changes in hamsters infected with scrapie strain 263K, to observe the presence and aggravation of various forms of PrP and PrP(Sc) during incubation period, and to probe primarily the relationship between the onset of clinic manifestations and the presence of different PrP(Sc) forms.

METHODSHamster-adapted scrapie strain 263K was intracerebrally inoculated into hamsters. Different forms of PrP and PrP(Sc) were monitored dynamically by Western blot and immuno-histochemical assays. The presence of scrapie-associated fibril (SAF) was assayed by electron microscopy analysis (EM) and immuno-golden EM.

RESULTSPrP(Sc) was initially detected in the brain tissues of the animals in 20 days post-inoculation by immunohistochemistry and 40 days with Western blot. Quantitative evaluations revealed that the amounts of PrP and PrP(Sc) in brain tissues increased along with the incubation. Several high and low molecular masses of PrP were seen in the brains of the long-life span infected animals. Deglycosylation assays identified that the truncated PrP in the infected brains showed similar glycosylation patterns as the full-length PrP. The presence of short fragments was seemed to relate with the onset of clinical conditions.

CONCLUSIONThese results indicate that infectious agents exist and accumulate in central nerve system prior to the onset of the illness. Various molecular patterns of PrP(Sc) may indwell in brain tissues during the infection.

Animals ; Blotting, Western ; Brain ; metabolism ; ultrastructure ; Cricetinae ; Disease Models, Animal ; Female ; Glycosylation ; Immunohistochemistry ; Mesocricetus ; Microscopy, Electron ; PrP 27-30 Protein ; analysis ; metabolism ; PrPC Proteins ; analysis ; metabolism ; PrPSc Proteins ; analysis ; metabolism ; Scrapie ; metabolism ; pathology

OBJECTIVETo establish a stable PrP(Sc) panel from brain tissues of experimental hamsters infected with scrapie agent 263K for evaluating diagnostic techniques of human and animals' prion diseases.

METHODSThirty brain tissue samples from hamsters intracerebrally infected with scrapie strain 263K and another 30 samples from normal hamsters were selected to prepare 10%, 1%, and 0.5% brain homogenates, which were aliquoted into stocks. PrP(Sc) in each brain homogenate was determined by proteinase K digestions followed by Western blot assay and partially by immunohistochemistry. Stability and glycoforms of PrP(Sc) were repeatedly detected by PrP(Sc)-specific Western blots in half a year and 3 years later.

RESULTSPrP(Sc) signals were observed in all 10% brain homogenates of infected hamsters. Twenty out of 30 stocks and 19 out of 30 stocks were PrP(Sc) positive in 1% and 0.5% brain homogenatesof infected hamsters, respectively. Twenty-seven out of 30 stocks presented three positive bands in 10% brain homogenates, whereas none of 1% and 0.5% homogenates contained 3 bands. The detection of PrP(Sc)-specific signals stored in half a year and 3 years later demonstrated that the ratio of PrP(Sc) positive samples and glycoforms was almost unchanged. All normal hamsters' brain homogenates were PrP(Sc) negative.

CONCLUSIONA PrP(Sc) panel of prion disease can be established, which displays reliably stable PrP(Sc)-specific signals and glycoforms.

Animals ; Brain ; Cricetinae ; Immunohistochemistry ; Male ; PrPSc Proteins ; classification ; Scrapie

Animals ; PrPSc Proteins ; metabolism ; pathogenicity ; Prion Diseases ; transmission ; Prions ; physiology

In order to establish an amplification system in vitro with which the PrP(Sc) is able to convert PrP(C) into proteinase K-resistant isoform infinitely and whether this system is more efficient than conventional protein misfolding cyclic amplification (PMCA), scrapie strain 263K-infected hamster's brain homogenate and homologous normal brain homogenate were prepared, respectively. A new methodology, namely serial PMCA, was utilized to reveal the continuous propagation ability of PrP(Sc). Totally 8 rounds of serial PMCA were proceeded and each round contained 48 cycles of alternative sonication and incubation. Simultaneously 144 cycles of conventional PMCA was used as a control. The results showed the PrP(Sc) from hamsters' brain tissues of scrapie agent 263K could replicate efficiently and infinitely with serial PMCA compared with finite propagation of PrP(Sc) with conventional PMCA system. The study of PrP(Sc) continuous propagation in brain homogenate with serial PMCA may further provide insight into the unsettled mechanism of prions misfolding and replication and apply to detect trace amount of PrP(Sc).
Animals ; Brain ; metabolism ; Cricetinae ; PrPC Proteins ; chemistry ; PrPSc Proteins ; chemistry ; Protein Folding

BACKGROUNDTo evaluate the influence ultrasonic processing on the aggregation of PrP(Sc) in the brain extracts prepared from the scrapie-infected hamsters, and to seek for the way to prepare lower molecular PrP(Sc) polymer.

METHODSThe extracts of infected brains were prepared with a lysis solution, and treated with ultrasonics at various conditions during the different phases. The distribution and aggregation state of PrP(Sc) were analyzed by proteinase K treated. Western blot, and afterwards, quantitatively calculated with a commercially supplied software Image Totaltech.

RESULTSThe amount of PrP(Sc) in the supernatant of brain homogenates was 1.29-to 1.58-fold increased with appropriate sonication (15 s for 30 times). At the same conditions of ultrasound, the PrP amount in the supernatant prepared from the scrapie-infected hamster brain was significantly increased, whereas that prepared from healthy animal used as normal control showed little change. Comparative analyses of PrP(Sc) pellets prepared by high-speed centrifugation revealed that about 90% PrP(Sc) released into supernatant after ultrasound processing.

CONCLUSIONAppropriate sonication of homogenate of scrapie-infected brain increases the extracted amount of PrP(Sc), being favorable to laboratory diagnosis. Larger molecular PrP(Sc) aggregates can be crashed by ultrasonic processing, engendering lower molecular PrP(Sc) polymers.

Animals ; Blotting, Western ; Brain Chemistry ; Cricetinae ; Image Processing, Computer-Assisted ; PrPSc Proteins ; analysis ; Scrapie ; metabolism ; Sonication

Real-time quaking-induced conversion (RT-QuIC) assay is a newly established PrP -detecting method. The development of RT-QuIC improves the diagnosis of sporadic Creutzfeldt-Jakob disease (sCJD), showing good sensitivity and specificity in many countries when the method was used in cerebrospinal fluid (CSF) samples. However, in China, the sensitivity and specificity of RT-QuIC has yet to be determined due to the lack of definitive diagnosis samples. Recently, 30 definitive sCJD and 30 non-CJD diagnoses were evaluated by RT-QuIC assay. In the 30 sCJD CSF samples, 29 showed positive results. By contrast, all the non-CJD samples were negative. The sensitivity and specificity of our RT-QuIC assay were 96.67% and 100%, respectively, and are comparable to other published data. Results can provide a fundamental basis for the usage of RT-QuIC assay in CJD surveillance in China.
China ; Creutzfeldt-Jakob Syndrome ; diagnosis ; Diagnostic Tests, Routine ; methods ; Humans ; PrPSc Proteins ; cerebrospinal fluid ; Sensitivity and Specificity

OBJECTIVE: To describe the global profiles of acetylated proteins in the brains of scrapie agents 139A- and ME7-infected mice collected at mid-early, mid-late, and terminal stages. METHODS: The acetylated proteins from the cortex regions of scrapie agent (139A- and ME7)-infected mice collected at mid-early (80 days postinfection, dpi), mid-late (120 dpi), and terminal (180 dpi) stages were extracted, and the global profiles of brain acetylated proteins were assayed with proteomic mass spectrometry. The proteins in the infected mice showing 1.5-fold higher or lower levels than that of age-matched normal controls were considered as differentially expressed acetylated peptides (DEAPs). RESULTS: A total of 118, 42, and 51 DEAPs were found in the brains of 139A-80, 139A-120, and 139A-180 dpi mice, respectively. Meanwhile, 390, 227, and 75 DEAPs were detected in the brains of ME7-80, ME7-120, and ME7-180 dpi mice, respectively. The overwhelming majority of DEAPs in the mid-early stage were down-regulated, and more portions of DEAPs in the mid-late and late stages were up-regulated. Approximately 22.1% (328/1,485) of acetylated peptides mapped to 74 different proteins were mitochondrial associated. Kyoto Encyclopedia of Genes and Genomes pathway analysis identified 39 (80 dpi), 13 (120 dpi), and 10 (180 dpi) significantly changed pathways in 139A-infected mice. Meanwhile, 55, 25, and 18 significantly changed pathways were observed in the 80, 120, and 180 dpi samples of 139A- and ME7-infected mice ( P < 0.05), respectively. Six pathways were commonly involved in all tested samples. Moreover, many steps in the citrate cycle (tricarboxylic acid cycle) were affected, represented by down-regulated acetylation for relevant enzymes in the mid-early stage and up-regulated acetylation in the mid-late and late stages. CONCLUSION Our data here illustrated the changes in the global profiles for brain acetylated proteins during prion infection, showing remarkably inhibited acetylation in the early stage and relatively enhanced acetylation in the late stage.
Animals ; Brain/metabolism* ; Citrates/metabolism* ; Mice ; Peptides/metabolism* ; PrPSc Proteins ; Proteomics ; Scrapie/metabolism* ; Sheep

OBJECTIVETo study the possible effect of tetracycline on protease-resistant activity in vitro and infectivity in vivo of a scrapie strain 263K.

METHODSScrapie pathogens were incubated with tetracycline at different concentrations for various periods of time and protease-resistant PrP signals were evaluated with proteinase K-treatment and Western blots. The preparations treated with tetracycline were intracerebrally inoculated into golden hamsters and typical TSE manifestations were noted. PrPSc in brain tissues of the infected animals was detected by PrP specific Western blot assays.

RESULTSProtease-resistant PrP was significantly reduced in or removed from the preparations treated with tetracycline in a dose-dependant manner. Compared with the control group after incubated for 53.75 +/- 0.50 days, the preparations treated with 5 mmol/L and 20 mmol/L tetracycline prolonged the incubation time of 61.5 +/- 1.73 and 59.5 +/- 0.58 days (P < 0.05).

CONCLUSIONTreatment of scrapie pathogen 263K with tetracycline reduces or removes its protease-resistant activity in vitro.

Animals ; Brain ; pathology ; Cricetinae ; Peptide Hydrolases ; metabolism ; PrPSc Proteins ; metabolism ; pathogenicity ; Scrapie ; pathology ; Tetracycline ; pharmacology ; Time Factors

Scrapie is a mammalian transmissible spongiform encephalopathy or prion disease that predominantly affects sheep and goats. Scrapie has been shown to overcome the species barrier via experimental infection of other rodents. To confirm the re-transmissibility of the mouse-adapted ME7 scrapie strain to ovine prion protein (PrP) transgenic mice, mice of an ovinized transgenic mouse line carrying the Suffolk sheep PrP gene that contained the A₁₃₆ R₁₅₄ Q₁₇₁/ARQ allele were intracerebrally inoculated with brain homogenates obtained from terminally ill ME7-infected C57BL/6J mice. Herein, we report that the mouse-adapted ME7 scrapie strain was successfully re-transmitted to the transgenic mice expressing ovine PrP. In addition, we observed changes in the incubation period, glycoform profile, and pattern of scrapie PrP (PrP(Sc)) deposition in the affected brains. PrP(Sc) deposition in the hippocampal region of the brain of 2nd-passaged ovine PrP transgenic mice was accompanied by plaque formation. These results reveal that the mouse-adapted ME7 scrapie strain has the capacity to act as a template for the conversion of ovine normal monomeric precursors into a pathogenic form in ovine PrP transgenic mice. The change in glycoform pattern and the deposition of plaques in the hippocampal region of the brain of the 2nd-passaged PrP transgenic mice are most likely cellular PrP species dependent rather than being ME7 scrapie strain encoded.
Alleles ; Animals ; Brain ; Gliosis ; Goats ; Humans ; Mice ; Mice, Transgenic ; Plaque, Amyloid ; Prion Diseases ; PrPSc Proteins ; Rodentia ; Scrapie ; Sheep ; Terminally Ill

Objective: The definite diagnosis of human and animal prion diseases depends on the examination of special pathological changes and/or detection of PrP in the brain tissues of suspected cases. Thus, developing methods to obtain PrP antibody with good specificity and sensitivity is fundamental for prion identification. Methods: We prepared a PrP-specific polyclonal antibody (pAb P54) in a -knockout mouse model immunization with recombinant full-length human PrP protein residues 23-231. Thereafter, we verified that pAb in Western blot, immunohistochemistry (IHC), and immunofluorescent (IFA) assays. Results: Western blot illustrated that the newly prepared pAb P54 could react with recombinant PrP protein, normal brain PrP from healthy rodents and humans, and pathological PrP in the brains of experimental rodents infected with scrapie and humans infected with different types of prion diseases. The electrophoretic patterns of brain PrP and PrP observed after their reaction with pAb P54 were nearly identical to those produced by commercial PrP monoclonal antibodies. Three glycosylated PrP molecules in the brain homogenates were clearly demonstrated in the reactions of these molecules with pAb P54. IHC assay revealed apparent PrP deposits in the GdnCl-treated brain slices of 139A-infected mice and 263K-infected hamsters. IFA tests with pAb P54 also showed clear green signals surrounding blue-stained cell nuclei. Conclusion The newly prepared pAb P54 demonstrated reliable specificity and sensitivity and, thus, may have potential applications not only in studies of prion biology but also in the diagnosis of human and experimental rodent prion diseases.
Animals ; Antibodies ; immunology ; Blotting, Western ; Fluorescent Antibody Technique ; Immunization ; Immunohistochemistry ; Mice ; Mice, Knockout ; PrPC Proteins ; immunology ; PrPSc Proteins ; immunology ; Prion Proteins ; immunology ; Recombinant Proteins ; immunology