-Some of the principal requisites of toxicity screening methods in drug discovery are their ease to perform and high throughput, as well as the possibility to predict the occurrence of clinical events. Phospholipidosis is one of the toxicities often induced by potential drugs. Several physicochemical methods for the prediction of phospholipidosis have been reported. The purpose of the present study was to examine the predictability of methods based on lipophilicity and charge parameters. We employed a test set of 33 compounds including 11 in-house compounds. The phospholipidosis-inducing potential (PLIP) of the test set compounds was determined by the fluorescence-labeled lipid accumulation assay using isolated rat hepatocytes. This assay was verified by transmission electron microscopy (EM). The usefulness of the ClogP -most basic pK a (pK a -MB) plot to the PLIP of compounds was examined. This plot was unable to predict the PLIP of zwitterions. In order to improve its predictability, the net charge of a given molecule (NC) was introduced instead of pK a -MB, since the NC corresponds directly to the ionization state of compounds in the organelles. Compounds with high ClogP (> 1) and high NC (1≤NC≤2) tended to be positive. This finding was also confirmed using 30 additional validation set compounds obtained from the literature. The ClogP -NC plot differentiated positive and negative compounds with more than 98% accuracy (62/63), indicating its usefulness in drug discovery.
We prepared a monoclonal antibody that recognizes oligodendrocytes and Schwann cells in zebrafish. On immunoblots, the antibody mainly recognized three protein bands of 34 kDa in a membrane fraction from adult zebrafish brain. Medaka fish (Oryzias latipes) also possessed the same protein bands in a membrane fraction. The antibody did not stain neurons, but stained cells in fiber tracts and cranial and spinal nerves. In order to determine the nature of these cells, the staining pattern of the monoclonal antibody was compared with that of a myelin basic protein antiserum. Both antibodies stained oligodendrocytes and Schwann cells in fixed sections from the adult zebrafish. Both antigens were also co-localized in cultured glial cells. Taken together, these results indicate that the new monoclonal antibody recognizes myelinating glial cells in zebrafish and will be useful for the analysis of piscine glia.
-Toxicological responses to acetaminophen (APAP) overdose were evaluated in human hepatocytes transplanted chimeric mice using 2-dimensional gel electrophoresis (2DE)-based proteomics and 1 H-nuclear magnetic resonance (NMR)-based metabonomics. Huge variations, which were supported by histopathological findings, were observed in proteins expression in chimeric mice liver. The proteomic analysis of the livers showed that the proteins involved in the pathways of lipid/fatty acid metabolism, glycolysis and energy metabolism/production were affected. In addition, oxidative stress-related proteins showed altered expression. The metabonomic analysis of urine and plasma revealed alterations of endogenous metabolites, which were the intermediates involved in the tricarboxylic acid (TCA) cycle. Those findings were already confirmed in normal mice. We hypothesized that the mechanism of APAP-induced effects on chimeric mice liver was in accordance with the mechanism observed in normal mice. Therefore, these toxicopanomic approaches successfully revealed that the mechanisms in humans were identical with "known" APAP-induced hepatotoxicity detected in chimeric mice. Further investigations are needed to detect idiosyncratic hepatotoxicity in humans using chimeric mice.
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