Intermittent selective clamping improves rat liver regeneration by attenuating oxidative and endoplasmic reticulum stress.

Intermittent clamping of the portal trial is an effective method to avoid excessive blood loss during hepatic resection, but this procedure may cause ischemic damage to liver. Intermittent selective clamping of the lobes to be resected may represent a good alternative as it exposes the remnant liver only to the reperfusion stress. We compared the effect of intermittent total or selective clamping on hepatocellular injury and liver regeneration. Entire hepatic lobes or only lobes to be resected were subjected twice to 10 min of ischemia followed by 5 min of reperfusion before hepatectomy. We provided evidence that the effect of intermittent clamping can be damaging or beneficial depending to its mode of application. Although transaminase levels were similar in all groups, intermittent total clamping impaired liver regeneration and increased apoptosis. In contrast, intermittent selective clamping improved liver protein secretion and hepatocyte proliferation when compared with standard hepatectomy. This beneficial effect was linked to better adenosine-5'-triphosphate (ATP) recovery, nitric oxide production, antioxidant activities and endoplasmic reticulum adaptation leading to limit mitochondrial damage and apoptosis. Interestingly, transient and early chaperone inductions resulted in a controlled activation of the unfolded protein response concomitantly to endothelial nitric oxide synthase, extracellular signal-regulated kinase-1/2 (ERK1/2) and p38 MAPK activation that favors liver regeneration. Endoplasmic reticulum stress is a central target through which intermittent selective clamping exerts its cytoprotective effect and improves liver regeneration. This procedure could be applied as a powerful protective modality in the field of living donor liver transplantation and liver surgery.

Automated detection of hepatotoxic compounds in human hepatocytes using HepaRG cells and image-based analysis of mitochondrial dysfunction with JC-1 dye.

In this study, our goal was to develop an efficient in situ test adapted to screen hepatotoxicity of various chemicals, a process which remains challenging during the early phase of drug development. The test was based on functional human hepatocytes using the HepaRG cell line, and automation of quantitative fluorescence microscopy coupled with automated imaging analysis. Differentiated HepaRG cells express most of the specific liver functions at levels close to those found in primary human hepatocytes, including detoxifying enzymes and drug transporters. A triparametric analysis was first used to evaluate hepatocyte purity and differentiation status, mainly detoxication capacity of cells before toxicity testing. We demonstrated that culturing HepaRG cells at high density maintained high hepatocyte purity and differentiation level. Moreover, evidence was found that isolating hepatocytes from 2-week-old confluent cultures limited variations associated with an ageing process occurring over time in confluent cells. Then, we designed a toxicity test based on detection of early mitochondrial depolarisation associated with permeability transition (MPT) pore opening, using JC-1 as a metachromatic fluorescent dye. Maximal dye dimerization that would have been strongly hampered by efficient efflux due to the active, multidrug-resistant (MDR) pump was overcome by coupling JC-1 with the MDR inhibitor verapamil. Specificity of this test was demonstrated and its usefulness appeared directly dependent on conditions supporting hepatic cell competence. This new hepatotoxicity test adapted to automated, image-based detection should be useful to evaluate the early MPT event common to cell apoptosis and necrosis and simultaneously to detect involvement of the multidrug resistant pump with target drugs in a human hepatocyte environment.

Blocking Wnt signaling by SFRP-like molecules inhibits in vivo cell proliferation and tumor growth in cells carrying active ß-catenin.

Constitutive activation of Wnt/ß-catenin signaling in cancer results from mutations in pathway components, which frequently coexist with autocrine Wnt signaling or epigenetic silencing of extracellular Wnt antagonists. Among the extracellular Wnt inhibitors, the secreted frizzled-related proteins (SFRPs) are decoy receptors that contain soluble Wnt-binding frizzled domains. In addition to SFRPs, other endogenous molecules harboring frizzled motifs bind to and inhibit Wnt signaling. One of such molecules is V3Nter, a soluble SFRP-like frizzled polypeptide that binds to Wnt3a and inhibits Wnt signaling and expression of the ß-catenin target genes cyclin D1 and c-myc. V3Nter is derived from the cell surface extracellular matrix component collagen XVIII. Here, we used HCT116 human colon cancer cells carrying the ΔS45 activating mutation in one of the alleles of ß-catenin to show that V3Nter and SFRP-1 decrease baseline and Wnt3a-induced ß-catenin stabilization. Consequently, V3Nter reduces the growth of human colorectal cancer xenografts by specifically controlling cell proliferation and cell cycle progression, without affecting angiogenesis or apoptosis, as shown by decreased [(3)H]-thymidine (in vitro) or BrdU (in vivo) incorporation, clonogenesis assays, cell cycle analysis and magnetic resonance imaging in living mice. Additionally, V3Nter switches off the ß-catenin target gene expression signature in vivo. Moreover, experiments with ß-catenin allele-targeted cells showed that the ΔS45 ß-catenin allele hampers, but does not abrogate, inhibition of Wnt signaling by SFRP-1 or by the SFRP-like frizzled domain. Finally, neither SFRP-1 nor V3Nter affect ß-catenin signaling in SW480 cells carrying nonfunctional Adenomatous polyposis coli. Thus, SFRP-1 and the SFRP-like molecule V3Nter can inhibit tumor growth of ß-catenin-activated tumor cells in vivo.

Trout gill cells in primary culture on solid and permeable supports.

Trout gill cells in primary culture on solid and permeable supports were compared. Cultures were carried out by directly seeding cells on each support after gill dissociation. Most of the cell types present in culture were similar, regardless of culture support (pavement cells, mucous cells (3-4%), but no mitochondria-rich cells). However, insertion of mucous cells in cultured epithelium on permeable support presented a morphology more similar to gills in situ. Gene expression of ion transporters and hormonal receptors indicated similar mRNA levels in both systems. Cortisol inhibited cell proliferation on both supports and maintained or increased the total cell number on solid and permeable membranes, respectively. This inhibition of mitosis associated with an increase or maintenance of total gill cells suggests that cortisol reduced cell degeneration. In the presence of cortisol, transepithelial resistance of cultured gill cells on permeable membranes was increased and maintained for a longer time in culture. In conclusion, gill cells in primary culture on permeable support present: (i) a morphology more similar to epithelium in situ; and (ii) specific responses to cortisol treatment. New findings and differences with previous studies on primary cultures of trout gill cells on permeable membrane are discussed.

[Differentiation of hepatic and hematopoietic stem cells: study of liver regulation protein (LRP)]. / Différenciation des progéniteurs hépatocytaires et hématopoïétiques: étude de la Liver Regulating Protein" (LRP).

In the adult liver, the plasma membrane Liver Regulating Protein (LRP) has been found to participate in the recognition signals between hepatocytes and rat liver epithelial cells (RLECs) and to play a critical role in the functional stability of hepatocytes. Here, we report the involvement of LRP in hematopoiesis. First, LRP was evidenced in the hematopoietic fetal rat liver and in adult rat bone marrow. Then, the involvement of LRP in adult rat and human hematopoiesis was investigated in coculture of hematopoietic cells with RLECs. In the rat, RLECs sustain long-term production of hematopoietic cells and committed progenitors as well as bone marrow stroma cells. These effects can be specifically blocked by addition of anti-LRP antibodies to both culture systems. The supportive activity of RLECs on human hematopoiesis was assessed by comparison to the reference MS-5 cell line from both unifractioned and purified CD34(+)CD38(-) hematopoietic cells. Taken together, our results argue for the involvement of LRP in heterotypic interaction signals mediated by RLEC and bone marrow stromal cells which lead to hematopoietic primitive progenitors development. They might lead to interesting applications in fundamental research, pharmacology and therapeutics.

Pattern of cytokine expression by rat liver epithelial cells supporting long-term culture of human CD34(+)umbilical cord blood cells.

Fetal liver is the main site of haematopoiesis during mid-gestation. The adult liver still provides a favourable environment for extramedullary haematopoiesis. Nevertheless, regulation of liver haematopoiesis by cell-cell contacts or by cytokines remains poorly understood. Recently, we have shown that rat liver epithelial cells (RLECs) support long-term survival and multilineage differentiation of adult human CD34(+)and CD34(+)/CD38(-)haematopoietic cells obtained from granulocyte-colony stimulating factor mobilized peripheral blood and from bone marrow respectively. In addition, the importance of physical proximity between haematopoietic cells and RLECs was clearly demonstrated. Here, our findings give evidence that RLECs belonging to the epithelial but non-parenchymal liver compartment also sustain the long-term production of progenitors from human CD34(+)umbilical cord blood cells. Moreover, to better analyse the regulation of haematopoiesis in this RLEC coculture model, we have investigated the cytokine expression by RLECs alone and by RLECs coming from coculture with CD34(+)cells from umbilical cord blood. We demonstrated that a broad spectrum of cytokines acting at different stages of haematopoiesis is produced by RLECs. Interestingly, an upregulation of leukemia inhibitory factor expression by RLECs in presence of CD34(+)haematopoietic cells was observed. These data suggest an important role of cell-cell interactions in the regulation of haematopoiesis.

Hematopoiesis-promoting activity of rat liver biliary epithelial cells: involvement of a cell surface molecule, liver-regulating protein.

Stromal cell lines from bone marrow and other blood-forming organs including fetal liver have been found to support hematopoiesis. In this paper, we demonstrate that rat liver biliary epithelial cells (RLEC), most likely originating from primitive bile ductules, are able to support long-term hematopoietic cell growth as well as burst-forming unit-erythroid (BFU-E) and colony-forming unit-granulocyte/macrophage (CFU-GM) production. RLEC have previously been shown to express a cell surface molecule named liver-regulating protein (LRP), which is involved in the long-term maintenance of hepatocyte functions in a coculture system. In addition, LRP-like molecules have been found in spleen, thymus, lymph nodes, and peripheral blood cells. In the present study, we found that hematopoietic cells and several stromal cell types from bone marrow were LRP-positive, and immunoprecipitation revealed polypeptides similar to those found in RLEC. We then investigated the biological role of LRP on hematopoiesis using short-term RLEC and bone marrow stromal cell culture systems. Addition of specific anti-LRP antibody to both systems reduced hematopoietic cell proliferation and committed progenitor production, whereas it did not directly affect the clonal proliferation and maturation of these progenitors in methylcellulose assays. Moreover, using diffusible chamber cultures that suppress direct contacts with hematopoietic cells, we observed low cell growth and no effect of monoclonal antibody (mAb) L8 treatment. All these results strongly argue for a cell proximity signal mediated by RLEC and bone marrow stromal cells and for the involvement of LRP-like molecules in this signal in liver and bone marrow hematopoietic function.

Rat liver biliary epithelial cells support long-term production of haemopoietic progenitors from human CD34 cells.

In this study we report the supportive activity of rat liver epithelial cells (RLEC) on human haemopoiesis in the absence of exogeneously supplied growth factors. RLEC is a rat cell line derived from primitive biliary cells with epithelial characteristics which induce the long-term differentiation of hepatocytes through cell-cell contacts. We have established the ability of these cells to sustain long-term survival and multilineage differentiation of human haemopoietic progenitors from unfractionated bone marrow and growth-factor mobilized peripheral blood cells, and from human CD34+ and CD34+ CD38- haemopoietic cells, with a higher efficiency than the murine MS-5 stromal cell line: the numbers of committed progenitors recovered from RLEC cocultures after 8 weeks were 3-fold higher than from MS-5 cocultures, with an unusually high BFU-E production. Furthermore, using diffusible insert cultures, we demonstrated that, despite the lack of strong adhesive interaction between haemopoietic cells and RLEC, physical proximity was absolutely required for optimum stimulation of LTC-IC by RLEC. Taken together, these results show that biliary epithelial cells support human haemopoiesis and cause speculation that common mechanisms might be used by RLEC to regulate both the hepatocyte and the haemopoietic progenitors differentiation.

Up-regulation of P-glycoprotein expression in rat liver cells by acute doxorubicin treatment.

Expression of P-glycoprotein, a plasma-membrane glycoprotein involved in multidrug resistance and encoded by mdr genes, was investigated in cultured rat liver cells acutely exposed to doxorubicin. This anticancer drug was shown to increase mdr mRNA levels in a dose-dependent manner in both rat liver epithelial (RLE) cells and primary rat hepatocytes. This induction of mdr transcripts was detected as early as a 4-h exposure to doxorubicin used at 0.5 microg/ml. It occurred through increased expression of the mdr1 gene as assessed by northern blot analysis using rat mdr-gene-specific probes. In addition, RLE cells exposed to doxorubicin displayed an overexpression of a 140-kDa P-glycoprotein as demonstrated by western blotting. Moreover, doxorubicin-treated RLE cells displayed enhanced cellular efflux of the P-glycoprotein substrate rhodamine 123 that was inhibited by the P-glycoprotein blocker verapamil, thus providing evidence that doxorubicin-induced P-glycoprotein was functional in liver cells. Doxorubicin-mediated mdr mRNA induction was found to be fully inhibited by actinomycin D, thus indicating its dependence on RNA synthesis; it was demonstrated to be not associated with alteration of protein synthesis, suggesting it differed from the known mdr mRNA overexpression occurring in response to cycloheximide. In contrast to P-glycoprotein, other liver detoxification pathways such as cytochromes P-450 1A were not induced by doxorubicin treatment. These data indicate that doxorubicin can act as a potent acute inducer of functional P-glycoprotein in rat liver cells and therefore may modulate both chemosensitivity of hepatic cells and P-glycoprotein-mediated biliary secretion of xenobiotics.

Reconstituted human gingival epithelium: nonsubmerged in vitro model.

Many studies have shown that human gingival keratinocytes grown in submerged culture fail to attain optimal differentiation. This study reports an in vitro culture system for oral gingival epithelial cells, in which they are grown at the air-liquid interface, on polycarbonate inserts, in the presence of an NIH-3T3 feeder layer. This model was compared with two submerged culture methods for gingival keratinocytes, on type 1 collagen gel and on an NIH-3T3 feeder layer. Transmission electron microscopy showed an advanced level of stratification (over six layers of cells) for cultures grown at the air-liquid interface. Immunofluorescence and electrophoretic patterns showed the presence of cytokeratins 10 and 11 in cytoskeletal protein extracts of these cultured keratinocytes. In this air-liquid interface culture model, in the presence of NIH-3T3 feeder cells, keratinocytes can achieve an advanced level of stratification and differentiation and a resemblance to in vivo gingiva. The obtention of a highly differentiated epithelium will permit in vitro pharmacological studies and studies on the biocompatability of certain alloys with the superficial periodontium; it will also provide grafts for patients undergoing periodontal surgery.

P-glycoprotein induction in rat liver epithelial cells in response to acute 3-methylcholanthrene treatment.

Expression of P-glycoprotein (P-gp), a plasma membrane glycoprotein involved in multidrug resistance and encoded by mdr genes, was investigated in nonparenchymal rat liver epithelial (RLE) cells in response to acute exposure to carcinogenic polycyclic aromatic hydrocarbons (PAHs). High levels of mdr mRNAs were evidenced by Northern blotting in two independent RLE cell lines after treatment by either 3-methylcholanthrene (MC) or benzo-(a)pyrene. MC-mediated mdr mRNA induction was demonstrated to be dose-dependent; it occurred through enhanced expression of the mdr 1 gene, as indicated by reverse transcriptase-polymerase chain reaction analysis using rat mdr gene-specific primers and paralleled an induction of a 140 kDa P-gp as demonstrated by Western blotting. In addition, MC-induced P-gp appeared to be fully functional because RLE cells exposed to MC displayed enhanced cellular efflux of rhodamine 123, a known P-gp substrate, compared to their untreated counterparts. Analysis of time-course induction revealed that mdr mRNA levels were maximally increased when RLE cells were treated for 48 to 96 hr and returned to low levels after the PAH was removed. In contrast to P-gp, both cytochrome P-450 1A1 and cytochrome P-450 1A2 were not detected after exposure to MC, thus indicating that these liver detoxification pathways are not coordinately regulated with P-gp in RLE cells. In addition, MC-mediated P-gp regulation was not associated with major cellular disturbances such as alteration of protein synthesis and, thereby, differed from the known mdr mRNA induction occurring in response to cycloheximide. Moreover, cotreatment with MC and cycloheximide led to a superinduction of mdr mRNAs, thus suggesting that the effects of the two xenobiotics were, at least partly, additive. In contrast to MC and benzo(a)pyrene, 2,3,7,8-tetrachlorodibenzo-p-dioxin and benzo(e)pyrene were unable to increase P-gp expression. These results indicate that some PAHs can act as potent inducers of P-gp in RLE cells and may be interpreted as an adaptive reaction of these cells in lowering cellular accumulation of toxic drugs, including carcinogens transported by P-gp and, therefore, conferring protection on these compounds.

Progression through G1 and S phases of adult rat hepatocytes.

Regenerating liver, hepatocyte primary cultures and differentiated hepatoma cell lines are widely used to study the proliferation/differentiation/apoptosis equilibrium in liver. In hepatocytes, priming factors (TNF alpha, IL6) target G0/G1 transition while growth factors (HGF, EGF, TGF alpha) control a mid-late G1 restriction point. A characteristic pattern of cdk/cyclin expression is observed in hepatocytes, presumably related to their ability to proliferate a limited number of times and to undergo a reversible differentiation. Interestingly, cell-cell interactions between hepatocytes and liver biliary cells in co-cultures, result in a cell cycle arrest in mid G1 of hepatocytes which are insensitive to mitogens. Apoptosis exists in hepatocytes but is still poorly documented. However, hepatoma cell lines stimulated by TGF beta undergo cell death in a p53-independent pathway. In conclusion, the interplay of growth and apoptosis regulators and cell-cell interactions control the proliferation/differentiation/apoptosis balance which is a specific feature of hepatocytes.

Specialization switch in differentiating embryonic rat liver progenitor cells in response to sodium butyrate.

Embryonic (E) 12 rat liver epithelial cells constitute a population of bipotential progenitor cells which can differentiate along the hepatocyte (Hep) or biliary epithelial cell (BEC) lineage in primary culture. In the present study, E12 cells were seeded on fibronectin-coated substratum and exposed to sodium butyrate (SB) for various exposure times, and the emergence of the Hep or BEC phenotype was monitored by following the variations in albumin production and assessing the appearance of the two surface-exposed markers HES6 and BDS7. Continuous exposure to SB resulted into a major reduction in albumin production and, at Day 9 postseeding, few cells coexpressed BDS7 and albumin. When cells were exposed to SB for 5 days and then cultured for an additional 5 days without SB, they massively express BDS7, but very little HES6. Moreover, the reverse sequence, i.e., 5 days without SB followed by 5 days with it, led to the appearance of many cells expressing both HES6 and BDS7. These results indicate that progenitors committed preferentially along the Hep lineage still have the option to switch to BECs, at a transitional stage that we refer to as a "differentiation window."

Furosemide-sensitive K+ transport in transformed and nontransformed rat liver epithelial cells: regulation by protein kinase C and involvement in cell growth.

Using Rb+ as a K+ tracer and atomic absorption spectrophotometry for measuring the Rb+ stable isotope, we studied K+ transport systems and their regulation by protein kinase C in nontransformed and spontaneously transformed rat liver epithelial cells. Ouabain-sensitive Na+/K(+)-ATPase and the furosemide-sensitive Na+/K+/Cl- cotransport had comparable activity ratios in both cell types (0.92 and 1 in nontransformed and transformed rat liver epithelial cells, respectively). The protein kinase C activators, dioctanoylglycerol and phorbol myristate acetate, partly inhibited the Na+/K+/Cl- cotransport in both cell types but their effect was stronger in nontransformed cells, suggesting that, in transformed cells, the Na+/K+/Cl- cotransport had partly lost the ability to be inhibited by protein kinase C. In both cell types, phorbol myristate acetate had little and dioctanoylglycerol had no inhibitory effect on Na+/K(+)-ATPase. Furosemide (1 mM) partly inhibited the [3H]thymidine incorporation in both cell types, suggesting an involvement of the Na+/K+/Cl- cotransport in rat liver epithelial cell growth.

Tissue distribution of liver regulating protein. Evidence for a cell recognition signal common to liver, pancreas, gonads, and hemopoietic tissues.

Liver regulating protein (LRP) is an integral plasma membrane protein that plays a critical role in maintaining the differentiated phenotype of adult rat hepatocytes by mediating cell-cell interactions with rat liver epithelial cells. Using a specific monoclonal antibody (MAb L8) capable of inhibiting the interactions between these two cell types, the cellular distribution of LRP was analyzed in the liver. Various cell types, including hepatocytes and several sinusoidal cells, were found to be positive, whereas vascular endothelial cells and bile duct cells were consistently negative. This observation led us to question whether cells of nonhepatic origin would also express LRP. We show that MAb L8 immunoreactive material was detected in only three groups of tissues and corresponded to molecules similar to LRP but with different molecular weights. LRP-like molecules were demonstrated on acinar cells of the exocrine pancreas and on all hemopoietic cells regardless of their localization in the organism. LRP-like molecules were also expressed by germ cells and surrounding feeder cells in the testis and ovary in a stage-dependent manner. These results demonstrate the existence of a family of LRP proteins and strongly suggest a critical role for these molecules in regulating cell-cell communication in specific tissues.

[Intercellular communications in cell differentiation and in hepatic carcinogenesis]. / Les communications intercellulaires dans la différenciation et la carcinogenèse hépatiques.

The liver epoch like other tissue epochs occurs after that different events have induced heterogeneity in embryonic cells which results in distinct evolutionary processes. These events and those of organogenesis like "induction" are deeply dependent on cell-cell communications. Cell-cell interactions involve either soluble factors (hormones, growth factors), extracellular matrix or plasma membrane proteins responsible for cell-cell recognition and/or adhesion. All these plasma membrane signals are transduced to the nucleus and modulate the expression of groups of genes. To be functionally stable along the adult stage the liver has to maintain an ordered activity of cell renewal. This balance between proliferation and differentiation is, at least in part, controlled by cell-cell communications. Therefore, it is not surprising that intercellular communications are altered during hepatocarcinogenesis. They involve changes in the distribution of junctions, in the amounts of extracellular matrix components and/or growth factors which all result in modifying the differentiation/proliferation balance. Cell culture models have been used for these different studies; new in vitro systems should be set up in the near future by taking advantage of the targeted hepatocarcinogenesis in transgenic mouse.

[Role of intercellular communications in hepatic differentiation and carcinogenesis]. / Les communications intercellulaires dans la différenciation et la carcinogenèse hépatiques.

The liver epoch like other tissue epochs, occurs after that different events have induced heterogeneity in embryonic cells which result in distinct evolutionary processes. These events and those of organogenesis like "induction", are deeply dependent on cell-cell communications. Cell-cell interactions involve either soluble factors (hormones, growth factors), extracellular matrix or plasma membrane proteins responsible for cell-cell recognition and/or adhesion. All these plasma membrane signals are transduced to the nucleus and modulate the expression of groups of genes. To be functionally stable along the adult stage the liver has to maintain an ordered activity of cell renewal. This balance between proliferation and differentiation is at least in part, controlled by cell-cell communications. Therefore, it is not surprising that intercellular communications are altered during hepatocarcinogenesis. They involve changes in the distribution of junctions, in the amounts of extracellular matrix components and/or growth factors which all result in modifying the differentiation/proliferation balance. Cell culture models have been used for these different studies; new in vitro systems should be set up in the near future by taking advantage of the targeted hepatocarcinogenesis in transgenic mouse.

A plasma membrane protein is involved in cell contact-mediated regulation of tissue-specific genes in adult hepatocytes.

We have identified the liver-regulating protein (LRP), a cell surface protein involved in the maintenance of hepatocyte differentiation when cocultured with rat liver epithelial cells (RLEC). LRP was defined by immunoreactivity to a monoclonal antibody (mAb L8) prepared from RLEC. mAb L8 specifically detected two polypeptides of 85 and 73 kD in immunoprecipitation of both hepatocyte- and RLEC-iodinated plasma membranes. The involvement of these polypeptides, which are integral membrane proteins, in cell interaction-mediated regulation of hepatocytes was assessed by evaluating the perturbing effects of the antibody on cocultures with RLEC. Several parameters characteristic of differentiated hepatocytes were studied, such as liver-specific and house-keeping gene expression, cytoskeletal organization and deposition of extracellular matrix (ECM). An early cytoskeletal disturbance was evidenced and a marked alteration of hepatocyte functional capacity was observed in the presence of the antibody, together with a loss of ECM deposition. By contrast, cell-cell aggregation or cell adhesion to various extracellular matrix components were not affected. These findings suggest that LRP is distinct from an extracellular matrix receptor. The fact that early addition of mAb L8 during cell contact establishment was necessary to be effective may indicate that LRP is a novel plasma membrane protein that plays an early pivotal role in the coordinated metabolic changes which lead to the differentiated phenotype of mature hepatocytes.

Regulation by dimethylsulfoxide, insulin, and corticosteroids of hepatitis B virus replication in a transfected human hepatoma cell line.

A human hepatoblastoma cell clone E4 was obtained by transfection of HepG2 cells with a plasmid DNA containing four tandem copies of hepatitis B virus (HBV) genome. Analysis of both intracellular and extracellular viral DNA revealed that this clone exhibited the main steps of the replication process previously found in normal hepatocyte primary cultures experimentally infected in vitro. Indeed, relaxed-circular, covalently closed circular, and single-stranded forms of viral DNA were identified in the cells together with complete virions and immature cores in the medium. Furthermore, the ability of these secreted particles to infect normal human hepatocyte cultures was established. These E4 cells were used to evaluate the effect of various soluble factors on HBV replication. Corticosteroids and, to a greater extent, dimethylsulfoxide (DMSO) increased intracellular viral DNA, whereas insulin reduced it dramatically. Parallel changes in the amounts of viral DNA secreted in the medium were observed. Measurement of the albumin secretion rate indicated that cellular and viral activities could be regulated, at least in part, in a coordinated manner.