Magnetic microparticle-based multimer detection system for the detection of prion oligomers in sheep.

Transmissible spongiform encephalopathies (TSEs) are zoonotic fatal neurodegenerative diseases in animals and humans. TSEs are commonly known as bovine spongiform encephalopathy in cattle, scrapie in sheep and goats, chronic wasting disease in cervids, and Creutzfeldt-Jakob disease in humans. The putative transmissible agents are infectious prion proteins (PrP(Sc)), which are formed by the conversion of the normal prion protein on the glycoprotein cell surface in the presence of other PrP(Sc). Reports of the transmission of TSEs through blood raised considerable concern about the safety of blood and blood products. To address this issue, many laboratories attempted to develop a sensitive and accurate blood diagnostic test to detect PrP(Sc). Previously, we reported that, compared to normal controls, the multimer detection system (MDS) was more efficient in detecting PrP(Sc) in infected hamster brain homogenate, mouse plasma spiked with purified PrP(Sc) from scrapie mouse brain, and scrapie-infected hamster plasmas. MDS differentiates prion multimers from the cellular monomer through the multimeric expression of epitopes on prion multimers, in contrast to the monomeric form. In this study, MDS detected PrP(Sc) in plasma samples from scrapie-infected sheep expressing clinical symptoms, demonstrating 100% sensitivity and specificity in these samples. Plasma samples from asymptomatic lambs at the preclinical stage (8-month-old naturally infected offspring of scrapie-infected parents expressing a highly susceptible genotype) tested positive with 50% sensitivity and 100% specificity. In the first of two coded analyses using clinical scrapie-infected sheep and normal healthy samples, MDS successfully identified all but one of the clinical samples with 92% sensitivity and 100% specificity. Similar results were obtained in the second coded analysis using preclinical samples. MDS again successfully identified all but one of the samples with 87% sensitivity and 100% specificity. The false-negative sample was subjected to a protease pretreatment. In conclusion, MDS could accurately detect scrapie in plasma samples at both preclinical and clinical stages. From these studies, we conclude that MDS could be a promising tool for the early diagnosis of TSEs from blood samples.

Application of capillary immunoelectrophoresis revealed an age- and gender-dependent regulated expression of PrPC in liver.

The cellular prion protein (PrPC) is a glycoprotein, anchored to the plasma membrane and abundantly expressed in the central nervous system. The expression of PrPC in the peripheral tissues is low and only little information is available on its functions in the nonneuronal tissues. The antioxidant function of PrPC during the activation of hepatic stellate cells has already been reported. Therefore, the aim of the study was to expand our knowledge on the functions of PrPC by detailed characterization of its expressional profile in the liver. In a combined strategy by using capillary immunoelectrophoresis and standard techniques, we have shown a sexually dimorphic expression of PrPC in mice and human liver tissues. Further, we showed a significant age-dependent upregulation of PrPC expression in the liver of 14- and 9-month-old mice as compared to 3 months of age. Therefore, this study may provide new insights into the gender-specific role of PrPC in the liver, which may further be linked to its protective role against oxidative stress during aging. In addition, the current study also shows an application of immunoelectrophoresis with a low coefficient of variation to analyze the miniscule amount of PrPC in the mouse liver tissue.

Intraspecies prion transmission results in selection of sheep scrapie strains.

BACKGROUND: Sheep scrapie is caused by multiple prion strains, which have been classified on the basis of their biological characteristics in inbred mice. The heterogeneity of natural scrapie prions in individual sheep and in sheep flocks has not been clearly defined. METHODOLOGY/PRINCIPAL FINDINGS: In this study, we intravenously injected 2 sheep (Suffolk and Corriedale) with material from a natural case of sheep scrapie (Suffolk breed). These 3 sheep had identical prion protein (PrP) genotypes. The protease-resistant core of PrP (PrPres) in the experimental Suffolk sheep was similar to that in the original Suffolk sheep. In contrast, PrPres in the Corriedale sheep differed from the original PrPres but resembled the unusual scrapie isolate, CH1641. This unusual PrPres was not detected in the original sheep. The PrPres distributions in the brain and peripheral tissues differed between the 2 breeds of challenged sheep. A transmission study in wild-type and TgBoPrP mice, which overexpressing bovine PrP, led to the selection of different prion strains. The pathological features of prion diseases are thought to depend on the dominantly propagated strain. CONCLUSIONS/SIGNIFICANCE: Our results indicate that prion strain selection occurs after both inter- and intraspecies transmission. The unusual scrapie prion was a hidden or an unexpressed component in typical sheep scrapie.

Application of an immunocapillary electrophoresis assay to the detection of abnormal prion protein in brain, spleen and blood specimens from patients with variant Creutzfeldt-Jakob disease.

Sensitive and specific detection of abnormal prion protein in blood could provide a diagnostic test or screening assay for animal and human prion diseases. Here, the application of an immunocapillary electrophoresis (ICE) method developed for sheep scrapie to brain, spleen and blood from patients with Creutzfeldt-Jakob disease (CJD) is described. The assay involves organic-solvent extraction, a competitive immunoassay using fluorescently labelled synthetic prion protein peptides and polyclonal antibodies specific for those sequences, and analysis by capillary electrophoresis using laser-induced fluorescence detection. The test was evaluated by using clinical blood specimens from patients with variant (n=5) or sporadic (n=4) CJD and patients initially suspected of having CJD who were given an alternative diagnosis (n=6). In this context, the ICE assay was specific, but incompletely sensitive (55%). The method was unable to detect abnormal prion protein in variant CJD brain or spleen reference materials due to its loss during the extraction process.

Evaluation of a preclinical blood test for scrapie in sheep using immunocapillary electrophoresis.

An analytical method is described for detection of endogenous disease-associated prion protein in the buffy coat fraction from the blood of sheep infected with scrapie. The method has been improved and evaluated for its performance in the preclinical diagnosis of ovine transmissible spongiform encephalopathies. The test system uses a protocol for sample preparation that includes extraction and concentration and a test method that uses a liquid-phase competitive immunoassay for prion protein. Antibodies directed to a peptide sequence at the C-terminus of the prion protein (PrP) and a fluorescein-labeled peptide conjugate are used in the assay. Free zone capillary electrophoresis with laser-induced fluorescence for detection is used to separate the antibody-bound fluorescently labeled peptide and free labeled peptide. In this assay, the PrP competes with the fluorescently labeled peptide for limited antibody binding sites, which results in a reduction of the peak representing the immunocomplex of the antibody bound to the fluorescently labeled peptide. When blood samples from scrapie-infected sheep aged 7-12 months and of the scrapie-susceptible PrP genotypes VRQ/VRQ and VRQ/ARQ were analyzed, the abnormal PrP was found in blood samples. These results correlated with the post-mortem diagnosis of scrapie. The sheep were preclinical and appeared normal at the time of testing but later died with clinical disease approximately 12 months after testing. In older animals, and those with clinical signs, a smaller percentage of animals tested positive. This study has demonstrated that this technology can be used as a sensitive, rapid preclinical test to detect the disease-associated PrP in the blood of scrapie-infected sheep. Improvements in the extraction protocol and capillary electrophoresis conditions will enhance the robustness of this test.

Rapid PrP(Sc) detection in lymphoid tissue and application to scrapie surveillance of fallen stock in Japan: variable PrP(Sc) accumulation in palatal tonsil in natural scrapie.

Rapid western blot (WB) procedure for an abnormal isoform of prion protein (PrP(Sc) ) detection in lymphoid tissues was established and has been applied to the surveillance of fallen stock. In this program, brain and palatal tonsil were examined by WB and three cases of sheep scrapie were detected. While one clinically scrapie-infected sheep harbored PrP(Sc) in the brain and palatal tonsil, the two sheep in the pre-clinical stage harbored PrP(Sc) in the brain, but not in the palatal tonsil. This study shows that PrP(Sc) accumulation in palatal tonsil is variable in natural scrapie, even among genetically susceptible sheep.

Capillary electrophoresis-based noncompetitive immunoassay for the prion protein using fluorescein-labeled protein A as a fluorescent probe.

A novel CE-based noncompetitive immunoassay for prion protein (PrP) was established. Fluorescein isothiocyanate (FITC)-labeled protein A (FITC-PrA) was used as a fluorescent probe to tag monoclonal antibody through noncovalent binding of FITC-PrA to the Fc region of the antibody. The FITC-PrA-Ab was incubated with the analyte, prion protein, under optimized condition, forming the immunocomplex FITC-PrA-Ab-PrP. The complex was separated and analyzed by capillary zone electrophoresis. The addition of carboxymethyl-beta-cyclodextrin in the running buffer as dynamical coating reagent improved the reproducibility and the resolution. The complex was isolated in less than 1 min with theoretical plates of 3.8 x 10(4). Relative standard deviations of peak height and migration time for the complex were 3.46 and 1.48%, respectively. A linear relationship was established for the bovine recombinant prion protein (rPrP) concentration in the range from 0.2 to 2.0 mug/mL and the peak height. The correlation factor was r2 = 0.9969. The estimated detection limit for rPrP was approximately 6 ng/mL, which is 3 times the signal-to-noise ratio. The method was successfully applied for testing blood samples from scrapie-infected sheep.

Conformational biosensor for diagnosis of prion diseases.

A fluorescence technology to monitor the proliferation of amyloidogenic neurological disorders is proposed. A crude brain homogenate (0.01%) from animals infected with a transmissible spongiform encephalopathy is employed as a catalytic medium initiating conformational changes in 520 nM polypeptide biosensors (Tris/trifluoroethanol 50% mixture at pH 7). The fluorescence methods utilize pyrene residues covalently attached to the peptide ends. The coil-to-beta-strand transitions in biosensor molecules cause elevation of a distinct fluorescence band of the pyrene aggregates (i.e. excimers). This approach enables the detection of infectious prion proteins at fmol, does not require antibody binding or protease treatment. Technology might be adopted for diagnosing a large variety of conformational disorders as well as for generic high-throughput screening of the amyloidogenic potential in plasma.

Detection of prion protein using a capillary electrophoresis-based competitive immunoassay with laser-induced fluorescence detection and cyclodextrin-aided separation.

The development of capillary electrophoresis (CE)-based competitive immunoassay for prion protein (PrP) using carboxymethyl beta-cyclodextrin (CM-beta-CD) as a buffer additive is described here. The assay was based on the competitive binding of PrP and a fluorescein-labeled peptide from the prion protein with a limiting amount of specific antibody. The amount of both free and fluorescein-labeled peptide bound to antibody (immunocomplex) were determined by CE with laser-induced fluorescence detection. In the presence of PrP, the peak height ratio of the immunocomplex and the free peptide was altered compared to the control. These changes were directly proportional to the amount of PrP present. The fluorescently labeled peptide spanning amino acid positions 140-158 of the PrP and its corresponding monoclonal antibody is reported here. The reaction times of the antibody with either the peptide or the recombinant PrP was less than 1 min and is a large improvement over the 16-18 h required to achieve equilibrium for polyclonal antibodies. CM-beta-CD was explored as a buffer additive to suppress analyte adsorption and enhance separation selectivity in the CE analysis. A fast (1.1 min), selective (resolution 4.7), and reproducible (relative standard deviations of migration time for free and bound fluorescein isothiocyanate (FITC)-peptide 0.56% and 0.64%, respectively) separation was obtained with 0.6% CM-beta-CD in 25 mM N-tris(hydroxymethyl)methyl-3-aminopropanesulfonic acid (TAPS) at pH 8.8. The concentration detection limit of the assay for recombinant PrP was determined to be 80 ng/mL (or mass detection limit 1 pg). When blood samples from scrapie-infected sheep and from normal sheep were tested, the results of the blood assay were consistent with scrapie status of the sheep as determined post mortem by Western blot analysis. Development of this assay will lead to a potentially robust, rapid, and specific preclinical diagnosis for transmissible spongiform encephalopathies (TSEs) in animals and humans.

Analysis of the performance of antibody capture methods using fluorescent peptides with capillary zone electrophoresis with laser-induced fluorescence.

A method to analyze the performance of an antibody capture method using fluorescent peptides by capillary zone electrophoresis using laser-induced fluorescence (CZE-LIF) for detection has been developed. Fluorescent peptides from the prion protein were synthesized and the corresponding antibodies were produced in rabbits against these peptides. The antibodies were used to capture the fluorescent peptides. The antibodies were then bound to protein A Sepharose. After elution, the amount of fluorescent peptide that was captured vs. the total amount placed in the assay was evaluated by CZE-LIF. Of the three peptides used in this evaluation, it was found that the recovery was approximately 25-35%. When the abnormal prion protein was prepared from scrapie-infected brain samples from hamsters and a sheep using the previously described extraction method and this method, the amount of abnormal prion protein that was measured in the fluorescence immunoassay correlated with amounts estimated from Western blot. We conclude that this method can be used to detect abnormal prion protein in a tissue sample.