Combining transcriptomics and PBPK modeling indicates a primary role of hypoxia and altered circadian signaling in dichloromethane carcinogenicity in mouse lung and liver.

Dichloromethane (DCM) is a lung and liver carcinogen in mice at inhalation exposures≥2000ppm. The modes of action (MOA) of these responses have been attributed to formation of genotoxic, reactive metabolite(s). Here, we examined gene expression in lung and liver from female B6C3F1 mice exposed to 0, 100, 500, 2000, 3000 and 4000ppm DCM for 90days. We also simulated dose measures - rates of DCM oxidation to carbon monoxide (CO) in lung and liver and expected blood carboxyhemoglobin (HbCO) time courses with a PBPK model inclusive of both conjugation and oxidation pathways. Expression of large numbers of genes was altered at 100ppm with maximal changes in the numbers occurring by 500 or 2000ppm. Most changes in genes common to the two tissues were related to cellular metabolism and circadian clock. At the lower concentrations, the changes in metabolism-related genes were discordant - up in liver and down in lung. These processes included organelle biogenesis, TCA cycle, and respiratory electron transport. Changes in circadian cycle genes - primarily transcription factors - showed strong concentration-related response at higher concentrations (Arntl, Npas2, and Clock were down-regulated; Cry2, Wee1, Bhlhe40, Per3, Nr1d1, Nr1d2 and Dbp) were up-regulated with similar directionality in both tissues. Overall, persistently elevated HbCO from DCM oxidation appears to cause extended periods of hypoxia, leading to altered circadian coupling to cellular metabolism. The dose response for altered circadian processes correlates with the cancer outcome. We found no evidence of changes in genes indicative of responses to cytotoxic, DNA-reactive metabolites.

Pharmacological and genetic targeting of the PI4KA enzyme reveals its important role in maintaining plasma membrane phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate levels.

Phosphatidylinositol 4-kinase type IIIα (PI4KA) is a host factor essential for hepatitis C virus replication and hence is a target for drug development. PI4KA has also been linked to endoplasmic reticulum exit sites and generation of plasma membrane phosphoinositides. Here, we developed highly specific and potent inhibitors of PI4KA and conditional knock-out mice to study the importance of this enzyme in vitro and in vivo. Our studies showed that PI4KA is essential for the maintenance of plasma membrane phosphatidylinositol 4,5-bisphosphate pools but only during strong stimulation of receptors coupled to phospholipase C activation. Pharmacological blockade of PI4KA in adult animals leads to sudden death closely correlating with the drug's ability to induce phosphatidylinositol 4,5-bisphosphate depletion after agonist stimulation. Genetic inactivation of PI4KA also leads to death; however, the cause in this case is due to severe intestinal necrosis. These studies highlight the risks of targeting PI4KA as an anti-hepatitis C virus strategy and also point to important distinctions between genetic and pharmacological studies when selecting host factors as putative therapeutic targets.

Xenobiotics inhibit hepatic uptake and biliary excretion of taurocholate in rat hepatocytes.

Reports suggest that troglitazone, and to a lesser extent bosentan, may alter bile acid homeostasis by inhibiting the bile salt export pump. The present studies examined the hypothesis that these xenobiotics may modulate multiple hepatic bile acid transport mechanisms. In suspended rat hepatocytes, troglitazone (10 microM) decreased the initial rate of taurocholate uptake approximately 3-fold; the initial uptake rate of estradiol-17beta-D-glucuronide, a substrate of the organic anion transporting polypeptides, also was decreased approximately 4-fold. Bosentan (100 microM) decreased the initial uptake rate of taurocholate and estradiol-17beta-D-glucuronide by approximately 12- and approximately 7-fold, respectively. In sandwich-cultured rat hepatocytes, 10-min accumulation of taurocholate in cells + bile canaliculi (408 +/- 57 pmol/mg protein) was decreased significantly by troglitazone (157 +/- 17 pmol/mg protein, respectively) only in the presence of Na+, the driving force for the sodium taurocholate cotransporting polypeptide. A similar decrease with 10-fold higher concentrations of bosentan was noted. The biliary excretion index of taurocholate (55 +/- 8%) was decreased in the presence of 10 microM troglitazone (27 +/- 2%) and 100 microM bosentan (10 +/- 6%). In conclusion, xenobiotics may alter hepatic bile acid transport by inhibiting both hepatic uptake and biliary excretion.

Viability assessment in sandwich-cultured rat hepatocytes after xenobiotic exposure.

Troglitazone, bosentan and glibenclamide inhibit the bile salt export pump (Bsep) which transports taurocholate into bile. Sandwich-cultured rat hepatocytes maintain functional sodium taurocholate co-transporting polypeptide and Bsep transport proteins, and may be useful to study inhibition of transport by xenobiotics at concentrations below the lowest observable adverse effect level (LOAEL). The purpose of this study was to compare viability assessments determined with the neutral red, lactate dehydrogenase (LDH), alamar blue, 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT) and propidium iodide assays in sandwich-cultured rat hepatocytes following exposure to xenobiotics known to inhibit Bsep, and to define the LOAEL for these xenobiotics in this system. The neutral red assay was not amenable to use in this model due to crystal formation on the collagen. Troglitazone decreased viability in every assay examined, with a LOAEL approximately 100 microM. Bosentan also decreased viability as measured by the LDH, MTT and propidium iodide assays, with a LOAEL approximately 200 microM; however, a significant decrease in viability was not observed with the alamar blue assay. Glibenclamide did not decrease viability with any assay at the xenobiotic concentrations examined in this study. Based on the results of this study, the LDH or propidium iodide assays would be the methods of choice to assess viability in sandwich-cultured rat hepatocytes after xenobiotic exposure.

Characterization of raloxifene glucuronidation in vitro: contribution of intestinal metabolism to presystemic clearance.

Raloxifene, a selective estrogen receptor modulator used for the treatment of osteoporosis, undergoes extensive conjugation to the 6-beta- and 4'-beta-glucuronides in vivo. This paper investigated raloxifene glucuronidation by human liver and intestinal microsomes and identified the responsible UDP-glucuronosyltransferases (UGTs). UGT1A1 and 1A8 were found to catalyze the formation of both the 6-beta- and 4'-beta-glucuronides, whereas UGT1A10 formed only the 4'-beta-glucuronide. Expressed UGT1A8 catalyzed 6-beta-glucuronidation with an apparent K(m) of 7.9 microM and a V(max) of 0.61 nmol/min/mg of protein and 4'-beta-glucuronidation with an apparent K(m) of 59 microM and a V(max) of 2.0 nmol/min/mg. Kinetic parameters for raloxifene glucuronidation by expressed UGT1A1 could not be determined due to limited substrate solubility. Based on rates of raloxifene glucuronidation and known extrahepatic expression, UGT1A8 and 1A10 appear to be primary contributors to raloxifene glucuronidation in human jejunum microsomes. For human liver microsomes, the variability of 6-beta- and 4'-beta-glucuronide formation was 3- and 4-fold, respectively. Correlation analyses revealed that UGT1A1 was responsible for 6-beta- but not 4'-beta-glucuronidation in liver. Treatment of expressed UGTs with alamethicin resulted in minor increases in enzyme activity, whereas in human intestinal microsomes, maximal increases of 8-fold for the 6-glucuronide and 9-fold for the 4'-glucuronide were observed. Intrinsic clearance values in intestinal microsomes were 17 microl/min/mg for the 6-glucuronide and 95 microl/min/mg for the 4'-isomer. The corresponding values for liver microsomes were significantly lower, indicating that intestinal glucuronidation may be a significant contributor to the presystemic clearance of raloxifene in vivo.