Gas‐permeable membranes and co‐culture with fibroblasts enable high‐density hepatocyte culture as multilayered liver tissues

To engineer reliable in vitro liver tissue equivalents expressing differentiated hepatic functions at a high level and over a long period of time, it appears necessary to have liver cells organized into a three‐dimensional (3D) multicellular structure closely resembling in vivo liver cytoarchitecture and promoting both homotypic and heterotypic cell–cell contacts. In addition, such high density 3D hepatocyte cultures should be adequately supplied with nutrients and particularly with oxygen since it is one of the most limiting nutrients in hepatocyte cultures. Here we propose a novel but simple hepatocyte culture system in a microplate‐based format, enabling high density hepatocyte culture as a stable 3D‐multilayer. Multilayered co‐cultures of hepatocytes and 3T3 fibroblasts were engineered on collagen‐conjugated thin polydimethylsiloxane (PDMS) membranes which were assembled on bottomless frames to enable oxygen diffusion through the membrane. To achieve high density multilayered co‐cultures, primary rat hepatocytes were seeded in large excess what was rendered possible due to the removal of oxygen shortage generally encountered in microplate‐based hepatocyte cultures. Hepatocyte/3T3 fibroblasts multilayered co‐cultures were maintained for at least 1 week; the so‐cultured cells were normoxic and sustained differentiated metabolic functions like albumin and urea synthesis at higher levels than hepatocytes monocultures. Such a microplate‐based cell culture system appears suitable for engineering in vitro miniature liver tissues for implantation, bioartificial liver (BAL) development, or chemical/drug screening. © 2011 American Institute of Chemical Engineers Biotechnol. Prog., 2011.     

Stable immobilization of rat hepatocytes as hemispheroids onto collagen-conjugated poly-dimethylsiloxane (PDMS) surfaces: importance of direct oxygenation through PDMS for both formation and function

The highly oxygen-permeable material, poly-dimethylsiloxane (PDMS), has the potential to be applied to cell culture microdevices, but cell detachment from PDMS has been a major problem. In this study, we demonstrate that a combination of collagen covalently immobilized PDMS and an adequate oxygen supply enables the establishment of a stable, attached spheroid (hemispheroid) culture of rat hepatocytes. The bottom PDMS surfaces were first treated with oxygen plasma, then coupled with aminosilane followed by a photoreactive crosslinker, and they were finally reacted with a collagen solution. X-ray photoelectron spectroscopy (XPS) and contact angle measurements showed that the covalent immobilization of collagen on the surface occurred only where the crosslinker had been introduced. On the collagen-conjugated PDMS surface, rat hepatocytes organized themselves into hemispheroids and maintained the viability and a remarkably high albumin production at least for 2 weeks of culture. In contrast, hepatocytes on the other types of PDMS surfaces formed suspended spheroids that had low albumin production. In addition, we showed that blocking the oxygen supply through the bottom PDMS surface inhibited the formation of hemispheroids and the augmentation of hepatocellular function. These results show that appropriate surface modification of PDMS is a promising approach towards the development of liver tissue microdevices.     

The importance of physiological oxygen concentrations in the sandwich cultures of rat hepatocytes on gas‐permeable membranes

Oxygen supply is a critical issue in the optimization of in vitro hepatocyte microenvironments. Although several strategies have been developed to balance complex oxygen requirements, these techniques are not able to accurately meet the cellular oxygen demand. Indeed, neither the actual oxygen concentration encountered by cells nor the cellular oxygen consumption rates (OCR) was assessed. The aim of this study is to define appropriate oxygen conditions at the cell level that could accurately match the OCR and allow hepatocytes to maintain liver specific functions in a normoxic environment. Matrigel overlaid rat hepatocytes were cultured on the polydimethylsiloxane (PDMS) membranes under either atmospheric oxygen concentration [20%‐O₂ (+)] or physiological oxygen concentrations [10%‐O₂ (+), 5%‐O₂ (+)], respectively, to investigate the effects of various oxygen concentrations on the efficient functioning of hepatocytes. In parallel, the gas‐impermeable cultures (polystyrene) with PDMS membrane inserts were used as the control groups [PS‐O₂ (?)]. The results indicated that the hepatocytes under 10%‐O₂ (+) exhibited improved survival and maintenance of metabolic activities and functional polarization. The dramatic elevation of cellular OCR up to the in vivo liver rate proposed a normoxic environment for hepatocytes, especially when comparing with PS‐O₂ (?) cultures, in which the cells generally tolerated hypoxia. Additionally, the expression levels of 84 drug‐metabolism genes were the closest to physiological levels. In conclusion, this study clearly shows the benefit of long‐term culture of hepatocytes at physiological oxygen concentration, and indicates on an oxygen‐permeable membrane system to provide a simple method for in vitro studies. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1401–1410, 2014     

Regulation of glutathione S-transferase subunits 3 and 4 in cultured rat hepatocytes

mRNA levels of glutathione S-transferase (GST) subunits 3 and 4 were measured with a specific cDNA probe in adult rat hepatocytes maintained either in conventional culture or in coculture with rat liver epithelial cells. Four media conditions were used, i.e. with or without fetal calf serum (FCS) and with nicotinamide or dimethylsulfoxide (DMSO). When FCS was present in the culture medium, GST subunit 3 and 4 mRNAs were expressed at a level close to that found in freshly isolated hepatocytes during the whole culture period both in conventional culture and in coculture. All other culture conditions resulted in an increase of GST 3 and 4 mRNA levels. After exposure to phenobarbital an increase in GST 3 and 4 mRNA levels was demonstrated in both culture systems. Comparison with previous findings on the expression of GST subunits 1, 2 and 7 in the same culture conditions indicates that the different classes of GST are regulated independently.     

Rapid and enhanced repolarization in sandwich-cultured hepatocytes on an oxygen-permeable membrane

In this study, we established rat primary hepatocyte sandwich cultures on oxygen-permeable membranes and investigated the change in their repolarization. Functional bile canaliculi in sandwich-cultured hepatocytes on oxygen-permeable polydimethylsiloxane (PDMS) membranes were re-established more quickly than those in a conventional sandwich culture on polystyrene (PS). This enhanced biliary excretory activity was also observed in hepatocytes on another oxygen-permeable membrane plate but not on a PDMS surface whose oxygen permeability is blocked. An apical efflux transporter protein, Mrp2, was more rapidly distributed in hepatocytes cultured on PDMS membranes than in hepatocytes cultured on conventional PS plates. Moreover, the area of distribution of the Mrp2 in polarized hepatocytes cultured on PDMS membranes was more widespread than that for the hepatocytes grown on sandwich-cultured PS plates. The observation of ultrastructure in transmission electron microscopy clearly confirmed the presence of bile canalicular lumens possessing microvilli and tight junctions. Additionally, we demonstrated that the 7-ethoxyresorufin-O-deethylation activity of hepatocytes on PDMS membranes was also improved as compared to those on a PS surface. Therefore, sandwich-cultured hepatocytes on oxygen-permeable substrates can provide a simple tool for predicting the hepatic metabolism and toxicity of xenobiotics in vivo with short span and low cost in the course of drug discovery and evaluation.     

QSG‐7701 human hepatocytes form polarized acini in three‐dimensional culture

Hepatocytes are polarized and fulfill a variety of liver‐specific functions in vivo; but the polarized tissue structure and many of these functions are lost when the cells are cultured on plastic. To recapitulate the polarized structure and tissue‐specific function of liver cells in culture, we established a three‐dimensional (3D) culture assay with the human hepatocyte line QSG‐7701. In 3D Matrigel culture, QSG‐7701 cells formed polarized spheroids with a center lumen, which is reminiscent of bile canaliculi in the liver. Immunofluoresence analysis showed that F‐actin bundles and radixin were mainly located at the apical membrane and that α6 and β1 integrins were localized basally in 3D culture. Lumen formation was associated with the selective apoptosis of centrally located cells and was accompanied by proliferative suppression during acinar development. Compared to QSG‐7701 cells in 2D or agarose gel cultures, the cells in 3D Matrigel culture maintained a given direction of biliary excretion and acquired higher levels of cytochrome P450 and albumin expression. Our study shows that the immortal human hepatocytes, QSG‐7701, in 3D Matrigel culture reacquire cardinal features of glandular epithelium in vivo, providing an ex vivo model to study liver‐specific function and tumorigenesis. J. Cell. Biochem. 110: 1175–1186, 2010. Published 2010 Wiley‐Liss, Inc.     

Perfusion culture of fetal human hepatocytes in microfluidic environments

Various types of bioreactors composed of microstructured PDMS (Polydimethylsiloxane) layers have recently been fabricated for perfusion culture of mammalian cells such as adult rat hepatocytes. As a new feature of those bioreactors, in this study, cultivation of fetal human hepatocytes (FHHs) was attempted, because they have high possibility to mature in vitro with preserving their normality, which is suitable for inplantation of liver tissue equivalents reconstituted in vitro. During the perfusion culture in the PDMS bioreactors for 1 week, cells showed good attachment, spreading and reached their confluence over the channels. In addition, their albumin production was significantly enhanced in the perfusion culture using the PDMS bioreactors up to about four times during the FHH perfusion culture when compared in dish-level static culture. Hep G2 cell cultures were also performed and have also shown under perfusion conditions an enhanced cell activity multiplied by 2 compared to static conditions. Although, the cellular activities of FHH cells are still low even compared to those of the Hep G2 cells, the conclusions of this work is encouraging toward future liver tissue engineering based on in vitro propagation and maturation of hepatocyte progenitors combined with microfabrication technologies.     

Promoting effect of feeder cells in maintenance of adult rat hepatocytes

A procedure is described for maintaining primary cultures of adult rat hepatocytes for prolonged periods of time on layer of irradiated mouse fibroblast cell line (C3H/1OT1/2) and on a secondary lung fibroblasts obtained from Sprague Dawley rats. Morphologically and ultrastructurally the cocultivated hepatocytes retained many characteristics of hepatocytes in vivo. Within 24 hours after seeding, the individual cells were attached on the feeder cell layer and the in vivo polarity of the liver cells reappeared. Electron microscope studies demonstrated the appearance of newly developed bile ducts and junctions between hepatocytes as well as between hepatocytes and feeder cells. Histochemically, these cells were positive for glucose-6-phosphatase and for glycogen. After 14 days in culture the hepatocytes could be reseeded onto fresh C3H1OT1/2 cells. In contrast, hepatocytes maintained on plastic substrate lost their glycogen content and the epithelial character of the liver cells after 5 days in culture, and by day 10 this culture became predominantly fibroblastic. It is suggested that hepatocytes maintained on an irradiated fibroblast feeder layer provide a valuable approach for studying the morphogenesis, cytotoxicity, or the metabolism of different chemicals in vitro.     

Stimulation of growth of primary cultured adult rat hepatocytes without growth factors by coculture with nonparenchymal liver cells

DNA synthesis of adult rat parenchymal hepatocytes alone in primary culture can be stimulated only by the addition of humoral growth factors to the culture medium. However, when parenchymal hepatocytes were cocultured with nonparenchymal liver cells from adult rats, their DNA synthesis was markedly stimulated in the absence of added growth factors or calf serum. DNA synthesis of parenchymal hepatocytes was not stimulated by conditioned medium from nonparenchymal liver cells and was greatest when the parenchymal cells were plated on 24-h cultures of nonparenchymal liver cells. A dead feeder layer of nonparenchymal cells was almost as effective as a feeder layer of viable nonparenchymal cells. These results suggest that the stimulation of DNA synthesis in parenchymal hepatocytes was not due to some soluble factors secreted by nonparenchymal liver cells but to an insoluble material(s) produced by the nonparenchymal liver cells. This insoluble material(s) was collagenase- and acid-sensitive, suggesting that it was a protein containing collagen. The effect of nonparenchymal liver cells was specific: coculture with hepatoma cells, liver epithelial cells, or Swiss 3T3 cells did not stimulate DNA synthesis in parenchymal hepatocytes. Added insulin and epidermal growth factor showed additive effects with nonparenchymal cells in the cocultures. These results suggest that DNA synthesis in parenchymal hepatocytes is stimulated not only by various humoral growth factors but also by cell-cell interaction between parenchymal and nonparenchymal hepatocytes, possibly endothelial cells. This cell-cell interaction may be important in repair of liver damage and liver regeneration.     

Prenatal liver stromal cells: Favorable feeder cells for long-term culture of hepatic progenitor cells

Clinical and pharmaceutical applications of primary hepatocytes (PHs) are limited due to inadequate number of donated livers and potential challenges in successful maintenance of PHs in culture. Freshly isolated hepatocytes lose their specific features and rapidly de-differentiate in culture. Bipotent hepatoblasts, as liver precursor cells that can differentiate into both hepatocytes and cholangiocytes (Alb- and Ck19-positive cells, respectively), could be used as an alternative and reliable cell source to produce enough PHs for drug discovery or possible clinical applications. In this study, growth factor-free coculture systems of prenatal or postnatal murine liver stromal cells (pre-LSCs or post-LSCs, respectively) were used as feeder cells to support freshly isolated mice hepatoblasts. DLK1-positive hepatoblasts were isolated from mouse fetuses (E14.5) and cocultured with feeder cells under adherent conditions. The hepatoblasts' bipotent features, proliferation rate, and colony formation capacity were assessed on day 5 and 7 post-seeding. Immunofluorescence staining showed that the hepatoblasts remained double positive for Alb and Ck19 on both Pre- and Post-LSCs, after 5 and 7 days of coculture. Moreover, application of pre-LSCs as feeder cells significantly increased the number of DLK1-positive cells and their proliferation rate (ie, increased the number of Ki-67 positive cells) on day 7, compared to Post-LSCs group. Finally, to address our ultimate goal, which was an extension of hepatoblasts ex vivo maintenance, 3D spheres of isolated hepatoblasts were, cultured in conditioned medium (CM) derived from pre-LSCs until day 30. It was observed that the CM derived from Pre-LSCs could successfully prolong the maintenance of hepatic progenitor cells (HPCs) in 3D suspension culture.     

A thin‐walled polydimethylsiloxane bioreactor for high‐density hepatocyte sandwich culture

In vitro drug testing requires long‐term maintenance of hepatocyte liver specific functions. Hepatocytes cultured at a higher seeding density in a sandwich configuration exhibit an increased level of liver specific functions when compared to low density cultures due to the better cell to cell contacts that promote long term maintenance of polarity and liver specific functions. However, culturing hepatocytes at high seeding densities in a standard 24‐well plate poses problems in terms of the mass transport of nutrients and oxygen to the cells. In view of this drawback, we have developed a polydimethylsiloxane (PDMS) bioreactor that was able to maintain the long‐term liver specific functions of a hepatocyte sandwich culture at a high seeding density. The bioreactor was fabricated with PDMS, an oxygen permeable material, which allowed direct oxygenation and perfusion to take place simultaneously. The mass transport of oxygen and the level of shear stress acting on the cells were analyzed by computational fluid dynamics (CFD). The combination of both direct oxygenation and perfusion has a synergistic effect on the liver specific function of a high density hepatocyte sandwich culture over a period of 9 days. Biotechnol. Bioeng. 2013; 110: 1663–1673. © 2012 Wiley Periodicals, Inc.     

A new technique for primary hepatocyte expansion in vitro

The current application for many potential cell-based treatments for liver failure is limited by the low availability of mature functional hepatocytes. Although adult hepatocytes have a remarkable ability to proliferate in vivo, attempts to proliferate adult hepatocytes in vitro have been less successful. In this study, we investigated the effect of coculture cell type on the proliferative response and the functional activities of hepatocytes. We show, for the first time, a robust proliferative response of primary adult rat hepatocytes when cocultured with mouse 3T3-J2 fibroblasts. Hepatocytes cultured at low density on growth-arrested 3T3-J2 fibroblast feeder layers underwent significantly higher proliferation rates than when cultured on feeder layers made of four other cell types. Increasing colony size correlated with an increase in hepatocellular functions. The proliferating hepatocytes retained their morphologic, phenotypic, and functional characteristics. Using a cell patterning technique, we found that 3T3-J2 fibroblasts stimulate DNA synthesis in hepatocytes by short-range heterotypic cell-cell interactions. When hepatocytes that proliferated in cocultures were harvested and further subcultured either on 3T3-J2 fibroblast feeders or in the collagen sandwich configuration, their behavior was similar to that of freshly isolated hepatocytes. We conclude that adult rat hepatocytes can proliferate in vitro in a coculture cell type-dependent manner, and can be serially propagated by coculturing with 3T3-J2 fibroblasts while maintaining their differentiated characteristics. Our results also suggest that one of the major reasons for the functional differences in hepatocyte cocultures may be due to the different proliferative responses of hepatocytes as a function of coculture cell type. This study provides new insights in the roles of coculture cell types and cell-cell interactions in the modulation of hepatic proliferation and function.     

An in vitro model of rodent nongenotoxic hepatocarcinogenesis.

An in vitro model of liver in which rat hepatocytes are maintained as cocultures with nonparenchymal epithelial cells (NPC) derived from liver has been developed and characterized with respect to maintenance of hepatocyte viability and differentiated function. The system was then evaluated as a model for studying peroxisome proliferator-induced rodent liver nongenotoxic carcinogenesis. Within the coculture model, hepatocyte viability and morphology were maintained for 1 month or more within a system that is both easily accessible for microscopic examination and is free of any additives that may lead to artifacts. Even after 1 month or more, hepatocyte cocultures retained expression of the constitutive liver marker albumin. In addition, they maintained the ability to show induction of the peroxisome proliferator-inducible enzymes peroxisomal bifunctional enzyme (PBE) and cytochrome P450IVA1 in response to the peroxisome proliferator nafenopin. After 4 weeks, NPC cocultures showed a six- and a fourfold induction of PBE and cytochrome P450IVA1 expression, respectively, which compared well with the three- and fivefold induction seen in freshly isolated cells. This was paralleled by an increase in the cytoplasmic volume fraction of peroxisomes averaging eightfold. Interestingly, great heterogeneity was exhibited between adjacent hepatocytes in terms of the degree of peroxisome proliferation, a finding reflected by immunocytochemical staining which indicated heterogeneity in the level of expression of the peroxisome proliferator-inducible enzymes. Other cell lines representing different tissue types, morphologies, and species were also examined for their ability to support hepatocyte survival but were found to be ineffective, with the exception of a bovine corneal endothelial cell line. This line supported hepatocyte survival and maintenance of differentiated function but to a lesser extent than that observed with NPC. Ultrastructural examination of NPC cocultures revealed extensive interhepatocyte junctional complexes and interdigitation of adjacent membranes together with the presence of bile canalicular structures. There were no junctional complexes between the hepatocytes and the supporting feeder cells with any contact being limited to a close association of the hepatocytes with the extracellular matrix presumably produced by the NPC. The data demonstrate that hepatocytes maintained in vitro within an NPC coculture system retain differentiated function and the ability to respond to the peroxisome proliferator class of nongenotoxic carcinogens. Cocultures will provide us with a model system for the study of changes in hepatocyte growth regulation during rodent liver nongenotoxic carcinogenesis.     

Maintenance of periportal and pericentral oxygen tensions in primary rat hepatocyte cultures: influence on cellular DNA and protein content monitored by flow cytometry

Primary hepatocytes were cultured at oxygen tensions similar to those reported to be present in periportal (13% O2) and pericentral (4% O2) regions of the liver lobules. Cellular DNA and protein content of individual hepatocytes were determined simultaneously by two-parameter (DNA/protein) flow cytometry after 1, 4, and 7 days in culture. pO2 tensions monitored on line in conventional plastic culture dishes revealed that the depletion of the pO2 in the culture medium depended on the number of hepatocytes plated. When cultured as monolayer after 4-7 days at periportal (13% O2) and more pronounced at pericentral oxygen concentration (4% O2), up to 90% of the hepatocytes showed degenerated nuclei but normal protein content. By using culture dishes with teflon membrane bottoms the oxygen tension in the culture medium was accurately maintained by the incubator atmosphere. At pericentral oxygen tension the fraction of 2N cells increased by about 20%. That of the 4N cell was not affected, and the contribution of 8N hepatocytes dropped to 70% compared to cultures at periportal oxygen tension. Concomitantly, in the 4% O2 hepatocyte cultures the protein content of the 2N and the 4N cells was better preserved and increased by up to 10%. These results suggest that in vitro at pericentral oxygen conditions (4% O2) ageing of hepatocytes is delayed, regenerating processes are better maintained, and, furthermore, freshly isolated 4N hepatocytes have the potency to adapt their metabolism in vitro to periportal as well as to perivenous oxygen tensions.     

Enhanced liver-specific functions of endothelial cell-covered hepatocyte hetero-spheroids

The performance of an extracorporeal bioartificial liver (BAL) support system depends on the functional activities of the hepatocytes immobilized in the system. One of the most promising techniques in retaining liver-specific functions is co-culturing hepatocytes with other cell types, such as epithelial cells, endothelial cells and dermal fibroblasts. Primary rat hepatocytes were suspension co-cultured with rat prostate endothelial cell line (RPEn) for 20 h in a spinner vessel to form hetero-spheroids, which contain the two types of the cells, i.e., hepatocytes and endothelial cells in the same spheroid. For the subsequent culture, the hetero-spheroids were entrapped in a Ca-alginate gel bead. From the results of incorporation efficiency test, it was found that RPEn cells have a significantly higher attachment affinity to hepatocytes than human dermal fibroblast and rat liver epithelial cells. We clearly found out that RPEn cells located on the surface of the hepatocyte spheroids from immunostained paraffin sections of the hetero-spheroids. Identical with in vivo liver tissue, laminin was stained at the surface of the hetero-spheroids. Ultrastructures of liver tissue, such as bile canaliculus-like and Disse’s space-like structures, were also found at the surface of the hetero-spheroids. In vivo liver tissue, in which hepatocytes were covered with sinusoidal endothelial cells, was partly mimicked by the endothelial cell-covered hepatocyte spheroids. And the hetero-spheroids showed significantly higher and stable albumin secretion and ammonia removal activities than pure spheroids for 12 days of observations.

Therefore, the endothelial cell-covered hepatocyte hetero-spheroids may offer a useful study model of epithelial–mesenchymal interactions and information about liver tissue engineering research as well as a substitute of a cell source of a BAL system.     

Regulation of the activity and synthesis of malic enzyme in 3T3-L1 cells

Malic enzyme activity in differentiated 3T3-L1 cells was about 20-fold greater than activity in undifferentiated cells. A new steady-state level was achieved about 8 days after initiating differentiation of confluent cultures with a 2-day exposure to dexamethasone, isobutylmethylxanthine, and insulin. This increase in enzyme activity resulted from an increase in the mass of malic enzyme as detected by immunotitration of enzyme activity with goat antiserum directed against purified rat liver malic enzyme. Malic enzyme synthesis was undetectable in undifferentiated cells and increased to about 0.2% of soluble protein in differentiated cells, suggesting that the increase in enzyme mass was due primarily to an increase in enzyme synthesis. Thyroid hormone, a potent stimulator of malic enzyme activity in hepatocytes in culture and in liver and adipose tissue in intact animals, decreased or increased malic enzyme activity in differentiating 3T3-L1 cells by about 40% when it was removed or added to the medium, respectively. Insulin, another physiologically important regulator of malic enzyme activity in vivo, had no effect on the initial rate of accumulation of malic enzyme activity in the differentiating cells and caused a 30 to 40% decrease in the final level of enzyme activity in the fully differentiated cells. Cyclic AMP, a potent inhibitor of malic enzyme synthesis in hepatocytes in culture, inhibited this process in 3T3-L1 cells by 30%. Malic enzyme is like several other enzymes in that the large increase in its concentration which accompanies differentiation of 3T3-L1 cells is due to increased synthesis of enzyme protein. However, the hormonal modulation of malic enzyme characteristic of liver and adipose tissue in intact animals does not appear to occur in differentiated 3T3-L1 cells, suggesting that differentiated 3T3-L1 cells may not be an appropriate model system in which to study the hormonal modulation of malic enzyme that occurs in liver and adipose tissue of intact animals.     

Lymphocytes from hepatic inflammatory infiltrate kill rat hepatocytes in primary culture. Comparison with peripheral blood lymphocytes

In the last few years it has become possible in the liver to isolate lymphocytes from inflammatory infiltrates and to culture them in vitro. Most of the lymphocyte clones obtained are CD 8+ cytotoxic cells, but interactions between these lymphocytes and hepatocytes in primary culture have not been analysed previously. In this study, cloned human T lymphocytes from liver biopsies and from the peripheral blood of patients with chronic hepatitis B or primary biliary cirrhosis, after phenotypical and functional characterization into CD 8+ or CD 4+ cytotoxic lymphocytes, were activated in an antigen-independent fashion by adding either anti CD 3 or anti CD 2/R-3 monoclonal antibodies to the cell suspension. The activated cells were then coincubated with rat hepatocytes in primary culture. The killing capacity of the activated lymphocytes was monitored by light and electron microscopy and by measurement of lactic dehydrogenase (LDH)-release into the culture medium. It was found that cytotoxic CD 8+, but not CD 4+ helper lymphocytes very effectively killed hepatocytes. The killing effect was dependent on the time of cocultivation and on effector-target (E/T) ratio. Total breakdown of the hepatocyte monolayer was achieved after 10-20 h coculture and at an E/T ratio of 10 to 1. As LDH-release in the culture medium reached about 80% of the total LDH-content, most of the hepatocytes were lysed by activated lymphocytes. Cytotoxic activity of clones obtained from different biopsies was comparable with that of clones from peripheral blood. Hepatocytes in primary culture seem to be very sensitive to the killing capacity of activated cytotoxic lymphocytes.     

Maintenance of hepatocyte functions in coculture with hepatic stellate cells

Hepatic stellate cells (HSCs) are a type of nonparenchymal liver cells (NPCs) and are present in the perisinusoidal space of Disse. Hepatocytes were cocultured with HSCs isolated from the NPC fraction with the aim of maintaining differentiated liver functions in vitro. Hepatocytes inoculated directly onto the HSC layer (Co-mix) exhibited lower activity of albumin secretion and higher DNA synthesis activity than hepatocytes of the monoculture control. On the contrary, hepatocytes cocultured with HSCs but separated by a semipermeable membrane (Co-sep) maintained the activities of albumin secretion and urea synthesis. The soluble factor(s) secreted from HSCs had the maintenance effect. Subcultured HSCs were activated to myofibroblast-like cells (MFBs) and decreased the maintenance effect on hepatocyte function. However, the MFBs were found to resume the ability to maintain the hepatocyte function by cultivation on type I collagen. The coculture of hepatocytes and HSCS/MFB could be applied to the development of bioartificial liver support system and liver regenerative medicine.     

Viability and differential function of rainbow trout liver cells in primary culture: Coculture with two permanent fish cells

Summary The study investigates the influence of different culture conditions on attachment, viability and functional status of rainbow trout (Oncorhynchus mykiss) liver cells in primary culture. Cells were isolated by a two-step collagenase perfusion and incubated in serum-free, chemically defined minimal essential medium (MEM), (a) as a monolayer on uncoated PRI-MARIA? dishes, (b) as a monolayer on culture dishes coated with calf collagen type 1, and (c) in coculture with the established fish cell lines RTH-149 or RTG-2. Cell attachment was assessed from DNA and protein concentrations per dish, viability was estimated from cellular lactate dehydrogenase release, and the metabolic status was investigated by measuring activities of the phosphoenolpyruvate carboxykinase and biotransformation enzymes as well as the total cytochrome P450 contents. Seeding of hepatocytes on collagen-coated dishes did not alter cell attachment or detachment from the culture substrate, but had a small, but not significant effect on cell viability and metabolic parameters. Coculture of liver cells and RTG-2 cells reduced hepatocyte detachment from the culture substrate, and it was associated with a significant elevation of 7-ethoxyresorufin-O-deethylase activities in the hepatic cells. Cytochrome P450 contents, however, were not altered. The coculture effect on liver cell physiology clearly depended on the type of cell line, because coculture with RTH-149 cells led to similar, but much weaker effects than obtained in cocultures with RTG-2 cells. Electron microscopical observations revealed the existence of gap junctions and possible exocytosis-like transport between cell lines and hepatocytes. The results point to the potential of coculture systems to improve physiological parameters of trout liver cells in primary culture.     

Characterization of calcium accumulation in the brain of rats administered orally calcium: The significance of energy-dependent mechanism

Primary cultures of rat hepatocytes maintained on different matrix proteins such as collagen (Co IV) fibronectin (Fn), Laminin (Ln) or different tissue biomatrices were metabolically labelled with ³⁵[S]-SO₄ and the synthesis of sulphated proteoglycans was studied. The incorporation of the label into total glycosaminoglycan (GAG) was significantly higher in cells maintained on Co IV compared to those maintained on Fn or Ln. Similarly the incorporation of label was maximum in those cells maintained on the aortic biomatrix compared to liver or mammary gland biomatrix. About 80–95% of the GAG synthesised and secreted by cells maintained on individual matrix proteins and liver biomatrix was heparan sulphate (HS). But in the case of cells maintained on collagen IV aortic or mammary biomatrix in addition to HS, significant amount of chondroitin sulphate (CS) was also found. Nearly 50% of the total ³⁵[S]-GAG was associated with the cell layer after 24 h in culture in the case of cells maintained on individual matrix protein while those maintained on tissue biomatrix, retained about 70% of the ³⁵[S]-labelled proteoglycans (PG) with the cell layer. Analysis of the cell surface ³⁵[S]-labelled proteoglycans isolated from cells maintained on different biomatrix showed that it is a hybrid proteoglycan consisting of CS and HS. While the PG isolated from cells maintained on liver biomatrix consists of HS and CS in the ratio of 3:2 that from cells maintained on aorta or mammary gland matrix was about 2:3 indicating an alteration in the nature of the cell surface PGs produced by cells maintained on different tissue biomatrix. These results indicate that depending on the nature of the matrix substratum with which the cells are in contact, the nature and quantity of sulphated proteoglycans produced by hepatocytes vary.