Generalization testing with atypical and typical antipsychotic drugs in rats trained to discriminate 5.0 mg/kg clozapine from vehicle in a two‐choice drug discrimination task

Clozapine (CLZ) drug discrimination is used as a preclinical model to evaluate compounds for putative atypical antipsychotic properties. In rats, a 1.25 mg/kg CLZ training dose appears to have greater pharmacological specificity for atypical antipsychotic drugs than the traditional 5.0 mg/kg CLZ training dose; however, methodological differences among studies have precluded a direct comparison between these training doses. In the present study, rats were trained to discriminate a 5.0 mg/kg CLZ dose from vehicle in a two‐choice drug discrimination task using methods similar to those in a previous study from our laboratory that used a 1.25 mg/kg CLZ training dose. Clozapine produced full substitution (≥80% CLZ‐lever responding) for itself at the training dose (5.0 mg/kg). The atypical antipsychotics olanzapine, quetiapine, and ziprasidone also produced full substitution for 5.0 mg/kg CLZ, whereas the atypical antipsychotics risperidone and sertindole produced partial substitution (≥60% CLZ‐lever responding). The typical antipsychotic, thioridazine, produced full substitution for the 5.0 mg/kg CLZ training dose, but the typical antipsychotics chlorpromazine, fluphenazine, and haloperidol failed to substitute for clozapine. In a subgroup of 1.25 mg/kg CLZ‐trained rats, ziprasidone produced strong partial substitution (73.0 % CLZ‐lever responding) for the 1.25 mg/kg CLZ training dose. Based on these findings, some atypical antipsychotic drugs (i.e., quetiapine and ziprasidone) produce full substitution only for the 5.0 mg/kg CLZ training dose, whereas other atypical antipsychotic drugs (i.e., sertindole and risperidone) produce full substitution only for the 1.25 mg/kg CLZ training dose. Thus, both of these training doses are important for the screening of putative atypical antipsychotic drugs with the clozapine drug discrimination assay. Drug Dev. Res. 64:55–65, 2005. © 2005 Wiley‐Liss, Inc.     

DNA adduct formation in precision-cut rat liver and lung slices exposed to benzo[a]pyrene.

Chemical-DNA adducts provide an integrated measure of exposure, absorption, bioactivation, detoxification, and DNA repair following exposure to a genotoxic agent. Benzo[a]pyrene (BaP), a prototypical polycyclic aromatic hydrocarbon (PAH), can be bioactivated by cytochrome P-450s (CYPs) and epoxide hydrolase to genotoxic metabolites which form covalent adducts with DNA. In this study, we utilized precision-cut rat liver and lung slices exposed to BaP to investigate tissue-specific differences in chemical absorption and formation of DNA adducts. To investigate the contribution of bioactivating CYPs (such as CYP1A1 and CYP1B1) on the formation of BaP-DNA adducts, animals were also pretreated in vivo with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD, dioxin) prior to in vitro incubation of tissue slices with BaP. Furthermore, the tissue distribution of BaP and BaP-DNA adduct levels from in vivo studies were compared with those from the in vitro tissue slice experiments. The results indicate a time- and concentration-dependent increase in tissue-associated BaP following exposure of rat liver and lung tissue slices to BaP in vitro, with generally higher levels of BaP retained in lung tissue. Furthermore, rat liver and lung slices metabolized BaP to reactive intermediates that formed covalent adducts with DNA. Total BaP-DNA adducts increased with concentration and incubation time. Adduct levels (fmol adduct/microg DNA) in lung slices were greater than liver at all doses. Liver slices contained one major and two minor adducts, while lung slices contained two major and 3 minor adducts. The tissue-specific qualitative profile of these adducts in tissue slices was similar to that observed from in vivo studies, further validating the use of this model. Pretreatment of animals with TCDD prior to in vitro incubation with BaP potentiated the levels of DNA adduct formation. TCDD pretreatment altered the adduct distribution in lung but not in liver slices. Together, the results suggest that tissue-specific qualitative and quantitative differences in BaP-DNA adducts could contribute to the lung being a target tissue for BaP carcinogenesis. Furthermore, the results validate the use of precision-cut tissue slices incubated in dynamic organ culture as a useful model for the study of chemical-DNA adduct formation.     

Spatial Trends and Factors Affecting Mercury Bioaccumulation in Freshwater Fishes of Washington State, USA

Twenty-four lakes in Washington State, United States, were sampled for largemouth and smallmouth bass as well as water chemistry parameters during 2005 to 2009 to evaluate trends in mercury (Hg) concentrations. We analyzed spatial patterns in bass Hg levels across a gradient of land and climate types, lake chemistry parameters, and physical watershed characteristics to identify factors influencing Hg bioaccumulation. Across the state, bass Hg levels followed rainfall patterns and were statistically greater on the coastal west side of the state and lowest in the drier eastern region. Lake and watershed variables with the strongest correlations to Hg bioaccumulation in bass were annual watershed precipitation (+) and lake alkalinity (–). Principal component analysis (PCA) explaining 50.3 % of the variance in the dataset indicated that wet, forested landscapes were more likely to contain lakes with greater fish Hg levels than alkaline lakes in drier agriculture-dominated or open space areas. The PCA did not show wetland abundance and lake DOC levels as variables influencing bass Hg levels, but these were generally associated with small, shallow lakes containing greater chlorophyll levels. The effect of in-lake productivity may have counteracted the role of wetlands in Hg bioaccumulation among this study’s lakes.