Lysiane Richert

Evaluation of transcriptomic signature as a valuable tool to study drug-induced cholestasis in primary human hepatocytes

Primary human hepatocyte (PHH) sandwich cultures from five different donors were daily exposed to cyclosporine A (CsA), ibuprofen (IBU), chlorpromazine (CPZ), amiodarone (AMI) and paracetamol (APAP) at their respective Cmax (total) for short-term (1–3 days) and long-term treatment (14xa0days). Whole genome mRNA profiles (34,693 genes in total) were conducted using an Illumina microarray platform. The impact of compound treatments on gene signatures involved in liver differentiation, cholestasis and in bile acid homeostasis was evaluated. Notably, PHH from the five donors showed a highly comparable phenotype of terminally differentiated hepatocytes. As expected, PHH exposed to 100xa0µM APAP showed no signs of hepatotoxicity both after short- and long-term treatment. CsA at 0.7xa0µM, IBU at 100xa0µM, AMI at 2.5xa0µM and CPZ at 0.1–0.2xa0µM presented, in line with their cholestatic syndromes reported at therapeutic doses, transcriptomic signatures of cholestasis in PHH cultures; deregulation of genes involved in bile acid homeostasis further confirmed this finding. The strength of the cholestasis signature obtained after treatment with CsA, IBU and AMI could be directly related to the basal expression of the respective drug metabolizing enzymes in the various PHH cultures from different individuals. Our data show that the PHH model system combined with transcriptomics carries the future promise to identify individual gene expression profiles predictive of increased cholestasis risk. As the present work suggests possible correlation between mRNA levels of ADME relevant genes and a transcriptomic signature of cholestasis, particular focus on this research question could be the emphasis of additional data collection.

Extra collagen overlay prolongs the differentiated phenotype in sandwich-cultured rat hepatocytes

INTRODUCTIONnSandwich-cultured rat hepatocytes (SCRH) have become an invaluable in vitro model to study hepatic drug disposition. SCRH are maintained between two layers of extracellular matrix. In this configuration, culture periods of 4days are typically applicable. The aim of the present study was to modify conventional SCRH by applying an additional collagen overlay to prolong the hepatic phenotype in SCRH and thus to extend the applicability of the model.nnnMETHODSnThe cultures receiving an extra top layer (SCRH-plus cultures) were compared with the conventional SCRH by testing the morphology, cell functionality, metabolic capacity and Mrp2-activity.nnnRESULTSnIn the SCRH-plus cultures, cell functionality, evaluated by measuring urea production, was increased from day 5 onwards, compared to conventional cultures. Furthermore, these cells retained the appearance of typical hepatocytes, in contrast with conventional sandwich cultures which showed rapid dedifferentiation. SCRH-plus exhibited significantly improved metabolic clearance mediated by cytochrome P450 3A compared to conventional SCRH whereas UDP-glucuronosyltransferase-mediated metabolism was unaffected. Both conventional SCRH and SCRH-plus showed extensive biliary networks at day 4 of culture. However, from day 4 onwards, a decline in biliary excretion index (BEI) was observed in the conventional SCRH, while BEI values in SCRH-plus cultures did not decrease until day 7.nnnDISCUSSIONnThe application of an extra top layer of collagen on the SCRH prolongs their useful life-span to 7days. Therefore, SCRH-plus cultures will broaden the applications of SCRH in terms of long-term toxicity evaluation and when determining metabolism of low turnover compounds.

Inter-individual differences in the susceptibility of primary human hepatocytes towards drug-induced cholestasis are compound and time dependent

Cholestasis represents a major subtype of drug-induced liver injury and novel preclinical models for its prediction are needed. Here we used primary human hepatocytes (PHH) from different donors in 2D-sandwich (2D-sw) and/or 3D-spheroid cultures to study inter-individual differences in the response towards cholestatic hepatotoxins after short-term (48-72 hours) and long-term repeated exposures (14 days). The cholestatic liabilities of drugs were determined by comparing cell viability upon exposure to the highest non-cytotoxic drug concentration in the presence and absence of a non-cytotoxic concentrated bile acid mixture. In 2D-sw culture, cyclosporine A and amiodarone presented clear cholestatic liabilities in all four PHH donors tested, whereas differences in the susceptibility of the various PHH donors towards the cholestatic toxicity of bosentan, chlorpromazine and troglitazone were observed. In PHH from one donor, the cholestatic liabilities of chlorpromazine and troglitazone could only be detected after long-term repeated exposures when maintained in 3D-spheroid culture, but not after short-term exposures in either 2D-sw or 3D-spheroid culture, suggesting that cholestatic hepatotoxicity may require time to develop. In conclusion, inter-individual susceptibility exists towards drug-induced cholestasis, which depends on the compound as well as the exposure time.

Epistructured catechins, EGCG and EC facilitate apoptosis induction through targeting de novo lipogenesis pathway in HepG2 cells

BackgroundAbnormally high expression of the mammalian de novo lipogenesis (DNL) pathway in various cancer cells promotes cell over-proliferation and resistance to apoptosis. Inhibition of key enzymes in the DNL pathway, namely, ATP citrate lyase, acetyl-CoA carboxylase, and fatty acid synthase (FASN) can increase apoptosis without cytotoxicity to non-cancerous cells, leading to the search for and presentation of novel selective and powerful targets for cancer therapy. Previous studies reported that epistructured catechins, epigallocatechin gallate (EGCG) and epicatechin (EC) exhibit different mechanisms regarding a strong inducer of apoptosis in various cancer cell lines. Thus, the current study investigated the growth inhibitory effect of EGCG and EC, on the enzyme expression and activity of the DNL pathway, which leads to the prominent activity of carnitine palmitoyl transferase-1 (CPT-1) mediating apoptosis in HepG2 cells.MethodsThe cytotoxicity on HepG2 cells of EGCG and EC was determined by MTT assay. Cell death caused by apoptosis, the dissipation of mitochondrial membrane potential (MMP), and cell cycle arrest were then detected by flow cytometry. We further investigated the decrease of fatty acid levels associated with DNL retardation, followed by evaluation of DNL protein expression. Then, the negative inhibitory effect of depleted fatty acid synthesis on malonyl-CoA synthesis followed by regulating of CPT-1 activity was investigated. Thereafter, we inspected the enhanced reactive oxygen species (ROS) generation, which is recognized as one of the causes of apoptosis in HepG2 cells.ResultsWe found that EGCG and EC decreased cancer cell viability by increasing apoptosis as well as causing cell cycle arrest in HepG2 cells. Apoptosis was associated with MMP dissipation. Herein, EGCG and EC inhibited the expression of FASN enzymes contributing to decreasing fatty acid levels. Notably, this decrease consequently showed a suppressing effect on the CPT-1 activity. We suggest that epistructured catechin-induced apoptosis targets CPT-1 activity suppression mediated through diminishing the DNL pathway in HepG2 cells. In addition, increased ROS production was found after treatment with EGCG and EC, indicating oxidative stress mechanism-induced apoptosis. The strong apoptotic effect of EGCG and EC was specifically absent in primary human hepatocytes.ConclusionOur supportive evidence confirms potential alternative cancer treatments by EGCG and EC that selectively target the DNL pathway.