In the brains of mBSE-inoculated mice, coarse particulate and coalescing types of immunostaining were recognized in the hippocampus and brainstem habenular nuclei. In the cerebral cortex, characteristic lamellar accumulation of PrPSc was detected. In addition, plaque-like deposits
were frequently present in the thalamus, corpus callosum, periventricular area, and brain stem of mBSE-inoculated mice. Therefore, the pathological features of each strain group (Chandler and 79A, ME7 and Obihiro, mBSE) were easily distinguishable. Mean survival times (days ± SD) of mice inoculated with 10% Chandler and 79A, ME7, Obihiro, and mBSE-infected brain homogenates were 141 ± 4.6 and Sotrastaurin datasheet 138 ± 6.9, 150 ± 4.6, 147 ± 2.7, and 160 ± 3.5 days, respectively. Although no significant differences were observed between Chandler and 79A or between ME7 and Obihiro, significant differences
in survival times (P < 0.001) were found among the three strain groups. mBSE and the four scrapie strains, Chandler, 79A, ME7, and Obihiro, could be easily distinguished by their glycoform ratios (Fig. 4b) because the mBSE PrPSc bands migrated faster than scrapie strains. In both the Chandler and 79A strains, monoglycosylated PrPSc predominated, whereas the ME7 and Obihiro strains showed comparable amounts of di- and monoglycosylated protein. These data suggest that classification of the five strains by biological and biochemical characteristics correlates with that derived from the binding and conversion reactions of each strain. In this study, we demonstrated that the Selleck PF-2341066 addition of reducing agents did not inhibit binding and conversion of MoPrP or cysteine-less mutant PrP, and significantly accelerated conversion driven by mBSE PrPSc. Thus, reducing conditions result in an acceleration of PrPSc-dependent conversion in at least some prion strains, as has previously been shown for Immune system spontaneous conversion (3–7). Hermann and Caughey
reported a contradictory result; they found that addition of DTT decreased conversion by about 90% (9). This may have been due to use of a different recombinant expression system, the origin of the recombinant PrP used as a PrPC source, the prion strains used as PrPSc seed, the preparation method of seed PrPSc, and/or the reaction composition. Acidic conditions and addition of detergents or denaturants efficiently induce spontaneous conversion of α-helix-rich PrPC into PrPSc-like β-sheet-rich PrP (17, 18). Reducing conditions also stimulate conversion of α-helix-rich recombinant PrP into the β-sheet-rich form (3). In our study, denaturing and mildly acidic reducing reaction conditions were used for the binding and cell-free conversion assays. The conditions in the environment within endosomes and lysosomes, thought to be the location of conversion of PrPC into PrPSc (19–22), are believed to be similar.