Efficient transport of bile acids, a typical characteristic of hepatocytes, is partially lost in most hepatoma cell lines and in normal hepatocytes after some days in culture. We have tested whether the polarized rat hepatoma-human fibroblast hybrid WIF (hybrids between W138 and Fao cells) cells previously obtained by our group were able to perform vectorial transport of the fluorescent bile acid derivative cholylglycylamidofluorescein (CGamF) towards the bile canaliculi (BC). Four different WIF clones were analyzed. All were well polarized, as shown by the formation of spherical and even tubular BC-like structures and by the restricted localization at the BC, visualized by immunofluorescence, of the apical membrane marker HA4, a possible bile acid carrier. WIF-B and its subclone WIF-B9 were found to accumulate CGamF in 65% to 75% of their BC. This transport was time, temperature, and partly sodium dependent and was inhibited by coincubation with the parental natural bile salt cholylglycine. Dinitrophenyl glutathione, a substrate of the canalicular multispecific organic anion transporter, did not inhibit CGamF canalicular secretion, whereas it greatly impaired the canalicular secretion of a non-bile acid organic anion, fluorescein, generated intracellularly from fluorescein diacetate. Confocal microscopy confirmed the presence of CGamF in the cytoplasm, supporting a transcellular route from medium to BC. In contrast, two other polarized clones exhibited a poor ability (WIF 12-6) or no ability (WIF12-1 TG␦) to vectorially transport CGamF. In conclusion, WIF-B and WIF-B9 exhibit not only structural but also functional polarity, at least as far as vectorial organic anion transport is concerned. (HEPATOL-OGY 1998;27:576-583.)
Background information. WIF-B9 is a hybrid cell line obtained by fusion of rat hepatoma cells (Fao) and human fibroblasts (WI38). It exhibits the structural and functional characteristics of differentiated hepatocytes, including active bile canaliculi. The aim of the present study was to characterize the WIF-B9 cell line as a model for analysing drug-induced hepatic effects. The drug metabolism potential of WIF-B9 cells was identified by studying the rat and human CYP (cytochrome P450) mRNA constitutive expression profile and induction potential after exposure to reference inducers. The morphological alterations provoked by chemical entities were also characterized.Results. Competitive reverse transcriptase-PCR revealed that four rat (1A1, 2B1/2, 2E1 and 4A1) and four human (1A1, 2Cs, 2D6 and 2E1) CYP mRNA isoforms were constitutively expressed in WIF-B9 cells. The rat CYP forms were expressed at levels 2-4 orders of magnitude higher than the human forms. Exposure for 20-72 h to increasing concentrations of CYP reference inducers (β-naphthoflavone, 3-methyl cholanthrene, dexamethasone, phenobarbital, clofibrate and pregnenolone 16α-carbonitrile) revealed that the rat CYP 1A1, 1A2, 3A1, 3A2 and 4A1 and human CYP 1A1 and 2Cs mRNAs were inducible. Rat CYP 1A1 and 1A2 were the most inducible isoforms since they were overexpressed up to 100-fold after 20-48 h of treatment with β-naphthoflavone. Human CYP 1A1 and 2Cs mRNAs were induced 3-fold after 48 h of treatment with phenobarbital. Other mechanisms involved in hepatotoxicity were explored using microscopy and immunofluorescence. The WIF-B9 cell line exhibited fragmentation and dilatation of bile canaliculi upon exposure to erythromycin, and to isoniazid and cytochalasins, respectively. Monensin promoted cell depolarization and cytoplasmic granulation. Ethionine promoted cytoplasmic vacuolation and dilatation of the Golgi structures.Conclusions. These results indicate that the CYP expression and induction profiles and the morphological features of WIF-B9 cells allow prediction in vitro of the induction and hepatotoxicity profiles of chemical entities.
WIF-B cells were generated previously to obtain a good in vitro model expressing the structural and functional polarity of hepatocytes. Here we tested the stability and the strength of the WIF-B polarized phenotype. WIF-B cells stayed polarized and formed functional bile canaliculi even after 3 months in culture or after injection in nude mice and culture of the resulting tumors. WIF-B was subcloned and 10,000 colonies were examined; all (except for 3) were composed of bile canaliculi forming cells. Some subclones were characterized; the polarized ones presented the same properties and karyotype as the WIF-B cells; the 3 unpolarized subclones had a lower level of E-cadherin and different karyotypes. WIF-B cells were fused with their nonpolarized hepatic parental cells. The polarity state of the resulting FWIF hybrids was studied from day 11 to day 38 after fusion, by immunolocalization of hepatocyte domainspecific plasma membrane proteins. Most FWIF colonies (G80%) were composed of polarized cells. Soon after fusion these cells were exclusively polarized as simple epithelial cells. The percent of colonies containing cells expressing the typical hepatocyte polarity increased with time and reached 80% at day 38. This result confirms the two-step polarization process previously described for WIF-B. Chromosomally complete FWIF hybrids were examined several months after fusion. As shown by the study of bile acid transport and by confocal analysis of the localization of membrane domain markers, FWIF cells expressed a functional and fully polarized hepatic phenotype. In conclusion, polarity is a stable and dominant trait of WIF-B. (HEPATOLOGY 1999;30:1002-1010.)In vitro polarized cell systems, such as renal Madin-Darby canine kidney 1 or intestinal Caco-2 2 and HT-29 3 lines, have been successfully exploited to study how simple epithelial cells establish and maintain their polarity. However, for hepatocytes that display a complex polarity and deliver apical proteins via an indirect route, 4 in vitro studies have been hampered for a long time by lack of well-polarized hepatic lines. Starting from the well differentiated but nonpolarized Fao rat hepatoma cells, we have previously isolated by hybridization (followed by human chromosome segregation), the highly differentiated and polarized hybrid subclone, WIF 12-1. 5 From this clone, which forms bile canaliculi (BC)-like structures, the derivative WIF-B, with improved hepatic characteristics, was generated. 6 It has been shown that WIF-B constitutes a good in vitro model, not only for structural studies of hepatocyte polarity, 7,8 but also for functional studies of hepatocyte-specific properties, such as vectorial bile acid transport, 9 and intercellular communication via connexin 32-constituted gap junctions. 10 Many aspects of hepatocytes are now approachable by use of WIF-B. For instance these cells have been used to study how exogeneous bile salts stimulate their own hepatic uptake 11 and how apical plasma membrane (PM) proteins travel from the basolateral domain to t...
Tagged versions of HNF4 or HNF1alpha cDNAs in expression vectors have been introduced by transient and stable transfection into three cell lines of hepatic origin that all fail to express these two liver-enriched transcription factors and hepatic functions. C2 and H5 cells are dedifferentiated rat hepatoma variants and WIF12-E cells are human fibroblast-rat hepatoma hybrids with a reduced complement of human chromosomes. Transfectants were analyzed for the expression state of the endogenous genes coding for these transcription factors and for hepatic functions. Each cell line showed a different response to the forced expression of the transcription factors. In C2 cells, no measurable effect was observed, either upon transitory or stable expression. H5 cells reexpressed the endogenous HNF4 gene only upon transient HNF1alpha transfection, and the endogenous HNF1alpha gene only in stable HNF4 transfectants. WIF12-E cells responded to the forced transient or stable expression of either HNF1alpha or HNF4 by cross-activation of the corresponding endogenous gene. In addition, the stable transfectants reexpress HNF3alpha and C/EBPalpha, as well as all of the hepatic functions examined. Hybrid cells similar to WIF12-E had previously been observed to show pleiotropic reexpression of the hepatic phenotype in parallel with loss of human chromosome 2. For the stable WIF12-E transfectants, it was verified that reexpression of the hepatic phenotype was not due to loss of human chromosome 2. The demonstration of reciprocal cross-regulation between HNF4 and HNF1alpha in transient as well as stable transfectants implies that direct effects are involved.
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