Effect of corynetoxin isolated from parasitized annual ryegrass on albumin and transferrin synthesis and secretion by cultured fetal rat hepatocytes

A group of glycolipid toxins, corynetoxin (CT), isolated from parasitized annual ryegrass, was shown to suppress the synthesis of both albumin and transferrin by cultured fetal rat hepatocytes. Based on [³H]leucine incorporation, inhibition of transferrin synthesis was greater than that of both albumin and total protein synthesis. As a result, the secretion of albumin and transferrin was decreased. The incorporation of [³H]N-AcGlc into cellular glycoproteins was only marginally affected by CT, although a dramatic reduction was observed with respect to the secreted proteins. Transferrin secreted into the culture medium was substantially non-glycosylated, judging by the absence of [³H]N-AcGlc. These studies suggested that the toxin preferentially affects the synthesis, and hence the secretion of glycoproteins, although it did not block the secretion of the proteins albumin and transferrin, as these did not accumulate intercellularly. Since transferrin labelled with [³H]leucine but not [³H]N-AcGlc is detected in the culture medium of hepatocytes exposed to CT, it was concluded that glycosylation of the protein is not required for secretion. This study shows that the effects of CT on protein synthesis and secretion in cultured hepatocytes are similar to those reported for tunicamycin (TM).     

Synthesis and secretion of albumin and transferrin by foetal rat hepatocyte cultures

Hepatocytes derived from foetal rat liver synthesize and secrete albumin and transferrin when maintained in primary culture. These proteins are produced for at least seven days under the conditions of culture. Studies on hepatocyte cultures derived from 12, 13, 14, 15 and 19-day foetal rats show that the maximal cellular rate of secretion of both proteins increases about 50-fold over this period. The maximal rate of albumin secretion in all cultures is achieved after one day in culture and decreases in hepatocytes from early foetuses after the fourth to sixth day in culture. Transferrin secretion by hepatocytes from 12 to 15 day foetuses increases markedly during the second day of culture and is relatively constant thereafter. In contrast, secretion of transferrin by hepatocytes from 19-day foetuses is constant from the first day of culture. The results show that both albumin and transferrin are synthesized and secreted by the foetal liver as early as the twelfth day of gestation. The increase in the rate of transferrin secretion that occurs during culture of hepatocytes from 12 to 15 day foetuses may reflect the development of a secretory mechanism that is different from that for albumin.     

The effects of an antibody to the rat transferrin receptor and of rat serum albumin on the uptake of diferric transferrin by rat hepatocytes

The role of high-affinity specific transferrin receptors and low-affinity, non-saturable processes in the uptake of transferrin and iron by hepatocytes was investigated using fetal and adult rat hepatocytes in primary monolayer culture, rat transferrin, rat serum albumin and a rabbit anti-rat transferrin receptor antibody. The intracellular uptake of transferrin and iron occurred by saturable and non-saturable mechanisms. Treatment of the cells with the antibody almost completely eliminated the saturable uptake of iron but had little effect on the non-saturable process. Addition of albumin to the incubation medium reduced the endocytosis of transferrin by the cells but had no significant effect on the intracellular accumulation of iron. The maximum effect of rat serum albumin was observed at concentrations of 3 mg/ml and above. At a low incubation concentration of transferrin (0.5 microM), the presence of both rat albumin and the antibody decreased the rate of iron uptake by the cells to about 15% of the value found in their absence, but to only 40% when the diferric transferrin concentration was 5 microM. These results confirm that the uptake of transferrin-bound iron by both fetal and adult rat hepatocytes in culture occurs by a specific, receptor-mediated process and a low-affinity, non-saturable process. The low-affinity process increases in relative importance as the iron-transferrin concentration is raised.     

Regulation of albumin gene expression in a series of rat hepatocyte cell lines immortalized by simian virus 40 and maintained in chemically defined medium.

A series of simian virus 40 (SV40)-immortalized hepatocyte cell lines were characterized for albumin production, the regulation of albumin production, and the expression of other liver-specific genes. This series of cell lines is particularly useful for studying the regulation of hepatocyte gene expression because the cell lines express liverlike levels of a number of liver-specific functions and do so while growing in a chemically defined medium. SV40-immortalized hepatocyte cell lines were derived from colonies of albumin-producing epithelial cells that arose after primary hepatocytes maintained in chemically defined medium were transfected with SV40 DNA. Some cell lines secreted albumin at levels equal to or greater than those secreted by freshly plated primary hepatocytes, and all but one line continued to produce albumin for more than 20 passages. The variation in albumin secretion among cell lines reflected differences in the amount of albumin produced per cell and not in the percentage of albumin-producing cells in each line. The characterization of selected cell lines showed that albumin production was regulated by cell density during the growth cycle. Albumin production in most cell lines was also regulated by dexamethasone; however, one cell line continued to produce high levels of albumin when the cells were grown in medium lacking dexamethasone, demonstrating that although glucocorticoid can induce albumin production in some cell lines, it is not required for high levels of albumin production by all cells in culture. Regulation of albumin production measured at the level of protein secretion was paralleled by changes in steady-state levels of a 2.3-kilobase albumin RNA. Albumin-producing SV40-immortalized hepatocytes secreted a variety of other plasma proteins, including transferrin, hemopexin, and the third component of complement. These cells also expressed tyrosine aminotransferase activity that was inducible by dexamethasone. Alpha-fetoprotein production was not detected in any of the cell lines examined.     

Modulation of alpha-fetoprotein, albumin and transferrin gene expression by cellular interactions and dexamethasone in cocultures of fetal rat hepatocytes

Fetal hepatocytes were cultured alone or in association with primitive biliary cells (RLEC) in the presence or absence of dexamethasone. Cell-cell contacts were established 3 h or five days after hepatocyte seeding and their effects on hepatocyte growth and functional activities were evaluated in the presence or absence of dexamethasone. Establishment of cellular interactions with RLEC in coculture decreased hepatocyte growth, while it stimulated production of alpha-fetoprotein, albumin and transferrin. Addition of dexamethasone to coculture inhibited alpha-fetoprotein secretion and maintained the synthesis rate of albumin and transferrin together with an additional inhibition of DNA synthesis. The levels of mRNAs corresponding to the three proteins were also measured. We observed that the levels of alpha-fetoprotein, albumin and transferrin secretion in cocultures maintained in the presence or absence of dexamethasone were well correlated with the relative amounts of their corresponding mRNAs. Consequently, it may be assumed that the primitive mechanism involved in the increased functional activity of fetal hepatocytes in coculture is of pretranslational origin. Furthermore, the present data provide evidence that heterotypic interactions and dexamethasone act as distinct modulators of growth and maturation of fetal rat hepatocytes.     

Origin of corticosteroid-binding globulin in fetal rat. Comparative dynamics of corticosteroid-binding globulin, alpha-fetoprotein, and albumin secretion in primary cultures of fetal rat hepatocytes

The origin of corticosteroid-binding globulin (CBG) and its evolution in comparison with alpha-fetoprotein (AFP) and albumin synthesis, during early development of rat liver (days 13 and 15 of fetal life), have been investigated using cultured fetal hepatocytes. Synthesis and secretion of CBG, AFP, and albumin is evidence by cycloheximide-sensitive [14C]leucine incorporation into immunoprecipitable polypeptides secreted by cultured hepatocytes into the medium, two-dimensional immunoelectrophoretic and autoradiographic identification of newly synthesized labeled proteins, corticosterone and estradiol-17 beta binding to CBG and AFP, respectively, and indirect immunofluorescence localization of AFP, albumin, and CBG in cultured fetal hepatocytes. CBG, albumin, and AFP accounted for 6, 11, and 25% (in 13-day-old rat fetuses) and 5, 15, and 28% (15-day-old rat fetuses), respectively, of the total secreted proteins in the culture medium. The rates of CBG, AFP, and albumin (counts/minute of secretion [14C]leucine incorporated per milligram of cell protein/hour of culture) in the hepatocytes of 15-day-old rat fetuses were 1.48-, 2.1-, and 2.57-fold higher, respectively, than in the 13-day-old rat fetuses. These results indicate that fetal liver is also active in CBG synthesis, along with AFP and albumin, as early as day 13 of fetal life and that the synthetic rates of these secretory proteins depend upon the developmental stage of the fetal liver. This developmental related change in the rate of synthesis of CBG by the fetal hepatocytes may regulate the level of free (active) glucocorticoid in the fetal circulation and thereby the initiation and regulation of glucocorticoid-dependent processes during the crucial stages of the differentiation of fetal liver and other developing tissues.     

Acute regulation of hepatic lipase secretion by rat hepatocytes.

Hepatic lipase is involved in cholesterol uptake by the liver. Although it is known that catecholamines are responsible for the daily variation of enzyme activity, the mechanisms involved are poorly understood. Rat hepatocytes incubated with adrenaline or other Ca(2+)-mobilizing hormones were used as an experimental model. Adrenaline reduced in a similar proportion the secretion of both hepatic lipase and albumin. The effect of adrenaline disappeared completely in cells exposed to cycloheximide. Adrenaline decreased incorporation of [35S]Met into cellular and secreted proteins, but it affected neither degradation of [35S]Met-prelabeled proteins nor the abundance of total and specific (albumin, hepatic lipase, beta-actin) mRNA. Other Ca(2+)-mobilizing agents had the opposite effect on hepatic lipase secretion: it was decreased by vasopressin but was increased by epidermal growth factor. Vasopressin and epidermal growth factor had the opposite effect on [35S]Met incorporation into cellular and secreted proteins, but neither affected hepatic lipase mRNA. The acute effect of adrenaline, vasopressin, and epidermal growth factor on hepatic lipase secretion is the consequence of the effect of these hormones on protein synthesis and is therefore nonspecific.     

Long term production of acute-phase proteins by adult rat hepatocytes co-cultured with another liver cell type in serum-free medium

Three acute-phase proteins, haptoglobin, alpha 2-macroglobulin and hemopexin, as well as albumin, have been measured daily in the hydrocortisone-supplemented serum-free medium of pure and mixed cultures of adult rat hepatocytes for 5 and 20 days respectively. Whereas plasma protein production rapidly declined in pure culture, it remained relatively stable when hepatocytes were co-cultured with rat liver epithelial cells. In the latter cultures, an early stimulation of albumin and alpha 2-macroglobulin secretion was observed. In addition, four other plasma proteins, fibrinogen, alpha 1-acute-phase protein, alpha 1-acid glycoprotein and alpha 1-antitrypsin were shown by immunodiffusion to still be produced by day 20 of co-culture. These results suggest that hepatocyte co-cultures represent a suitable model for studying the mechanism which controls synthesis of plasma proteins, including acute-phase proteins by liver cells.     

Long-term culture of fetal rat hepatocytes in media supplemented with fetal calf-serum Ultroser SF or Ultroser G

Fetal hepatocytes cultured in medium supplemented with fetal calf serum (FCS) or Ultroser SF do not maintain production of albumin or transferrin beyond one week of culture. When dexamethasone (10(-7) M) is present, secretion of albumin and transferrin can be extended to two weeks, however, levels are extremely low. By three weeks, neither plasma protein can be detected in the culture medium in either conditions of culture. In contrast, hepatocytes maintained in medium supplemented with Ultroser G continue to produce albumin and transferrin at high levels for the entire three week period of this study. The morphology of the cultures are different. In FCS and Ultroser SF supplemented medium there are many more fibroblast and epithelial-like cells and relatively fewer cells which are distinctly hepatocytes when compared with Ultroser G supplemented medium. The level of tyrosine aminotransferase, which is a dexamethasone inducible enzyme, is found to be much higher in Ultroser G cultures, with no further increase demonstrable by addition of dexamethasone. In contrast, dexamethasone induces the enzyme by about eight-fold in cultures maintained in FCS supplemented medium. Therefore it appears that Ultroser G already contains sufficient steroid activity to maximize the level of tyrosine aminotransferase. A comparison between Ultroser C and SF (steroid-free) suggests that the mixture of steroid and steroid derivatives in the G formulation must be important in the maintenance of differentiated functions of hepatocytes in culture. However, supplementation of FCS cultures with dexamethasone, which is known to be present in Ultroser G, does not allow hepatocytes to retain their differentiated functions over an extended period. Therefore it is concluded that other components besides dexamethasone must be important.     

Growth-stimulating effect of transferrin on a hybridoma cell line: Relation to transferrin iron-transporting function

The relation of the growth-stimulating capacity of transferrin to its iron-transporting function was investigated in mouse hybridoma PLV-01 cells cultivated in a chemically defined medium. The cells were precultivated in protein-free medium supplemented either with ferric citrate (cells with a high intracellular iron level) or with iron-saturated transferrin (cells with a low intracellular iron level). Iron uptake was monitored after the application of 59Fe-labeled ferric citrate or pig transferrin. Cultivation of the cells at the optimum growth-stimulating concentration (500 microM) of ferric citrate resulted in an intracellular iron level about 100-fold higher than that of cells cultivated at the optimum transferrin concentration (5 micrograms/ml). Replacement of pig transferrin with bovine transferrin resulted in similar intracellular iron levels, but the growth-stimulating effect of bovine transferrin was more than one order of magnitude lower. Cells with a high intracellular iron level grew equally well when cultivated with iron-saturated transferrin or with apotransferrin + deferoxamine (2 micrograms/ml). On the other hand, cells with a low intracellular iron level required iron-saturated transferrin for further growth and apotransferrin + deferoxamine was ineffective. The results suggest that transferrin can act as a cell growth factor only in the iron-saturated form. However, several findings of this work indicate that supplying cells with iron cannot be accepted as the full explanation of the transferrin growth-stimulating effect.     

Isolation of rat hepatocytes with EDTA and their metabolic functions in primary culture

Summary Isolated hepatocytes from adult rat liver were prepared after dissociation of the liver with EDTA. The morphological appearance, viability (94.5%) and yield (1.76.10⁷ cells/g liver) compare well with those of previously described methods using collagenase. Differentiated functions of the hepatocytes in primary culture such as albumin secretion (10.9 μg/mg cell protein/d) and triglyceride synthesis and secretion are maintained. Induction of triglyceride synthesis and secretion by oleic acid takes place to an extent similar to that observed in vivo and liver perfusion. Particles with a lipid composition resembling circulating very low density lipoproteins are secreted into the medium. These characteristics demonstrate the ability of hepatocytes isolated with EDTA and subsequently used in primary culture to retain complex and highly differentiated functions of the intact liver.     

Susceptibility of cultured rat hepatocytes to oxidative stress by peroxides and iron. The extracellular matrix affects the toxicity of tert-butyl hydroperoxide

The aim of this study was to set up an in vitro model for studying the importance of an altered extra-cellular matrix composition and its importance for the resistance to oxidative stress, in hepatocytes from normal and iron loaded rats. Primary cultures of hepatocytes from iron loaded and normal rats were plated on a laminin rich extracellular matrix or on collagen type I, and incubated with tert-butyl hydroperoxide (TBH). Malon dialdehyde (MDA) and the activities of lactate dehydrogenase (LDH) in cell culture medium were analyzed. The protein synthesis, the concentrations of glutathione and the expression of manganese-superoxide dismutase and ferritin genes were measured. All hepatocytes contained lower concentrations of glutathione when plated on collagen than on EHS. Ferritin H and Mn-SOD gene expression showed no difference. The rate of lipid peroxidation in iron loaded hepatocytes exposed to TBH was higher on collagen than in those plated on EHS (0.95 +/- 0.28 microM MDA vs. 1.62 +/- 0.22 microM MDA, p < 0.05). Iron loaded cells were in general more susceptible to TBH than were normal hepatocytes (MDA, LDH, protein synthesis and glutathione content). Lipid peroxidation could be prevented by adding desferrioxamine. In conclusion, we show that the combination of iron overload and collagen matrix in rat hepatocytes leads to an increased susceptibility to oxidative stress. These findings may be of interest for the further studies on effects of iron overload and the altered matrix composition in liver fibrosis.     

Effects of hexamethylene bisacetamide onα-fetoprotein,albumin, and transferrin production by two rat hepatoma cell lines

Summary α-Fetoprotein (AFP), albumin, and transferrin production by two rat hepatoma cell lines, McA-RH 7777 (7777) and McA-RH 8994 (8994), was determined after treatment with hexamethylene bisacetamide (HMBA, 2 to 6 mM). Radioimmunoassays were used to determine the levels of both secreted and intracellular AFP, albumin, and transferrin. Line 7777 normally produces large quantities of AFP and small quantities of albumin, thus resembling the less differentiated fetal liver with respect to the synthesis of these two proteins. Line 8994 normally produces small quantities of AFP and relatively larger amounts of albumin, thus resembling hepatic functions characteristic of a more differentiated state. After treatment with HMBA for a period of 28 to 96 h a threefold increase in AFP secretion by 7777 and a dose related increase in AFP, albumin, and transferrin secretion by 8994 were observed. In contrast, the secretion of albumin and transferrin in 7777 was inhibited by 60 and 40%, respectively, following treatment with HMBA. The intracellular concentrations of AFP in 7777 and AFP, albumin, and transferrin in 8994 were increased by treatment with HMBA indicating that HMBA is able to stimulate the synthesis of these proteins. The intracellular concentration of AFP, albumin, and transferrin in 7777, when expressed as a percentage of the extracellular concentration of these proteins, did not change significantly during HMBA treatment, indicating that the observed decrease in secreted albumin and transferrin by 7777 is due to decreased synthesis. Similarly, in Line 8994, when the intracellular concentration of the three proteins was expressed as percentage of the extracellular concentration, the only significant change observed was an increase in AFP after 72 h of HMBA (5 mM) treatment. The observed changes in the synthesis of AFP, albumin, and transferrin in both 7777 and 8994 after HMBA treatment were reversible, as judged by the return to control values upon removal of HMBA from the culture medium. Thus, HMBA stimulates synthesis of the oncofetal protein AFP, a result that appears to be independent of the stage of differentiation of the cell. However, its effect on the synthesis of albumin and transferrin are opposite in the two cell lines, suggesting that the regulation of the synthesis of these two proteins is controlled by factors or conditions that are dependent upon the stage of differentiation of the hepatoma cell lines.     

Maintenance of liver function in long term culture of hepatocytes following In Vitro or In Vivo Ha-ras EJ transfection

Collagenase isolated rat hepatocytes were transfected with liposome encapsulated pEJ (LE-pEJ), a plasmid carrying the human cellular activated Ha-ras^EJ oncogene. A proliferative cell line was cloned from these cells transfected in vitro. It secreted per day 0.87 µg albumin and 0.32 µg transferrin per 10⁶ cells, and 11.06 nmol free and conjugated bile acids (BA) per mg protein. Also, it metabolized 2-acetylaminoflourene (2-AFAF) into N- and ring-hydroxylated metabolites and 2-aminofluorene at rates of 1.50, 9.73, and 1.98 nmol/mg cell protein/24 hr, respectively. Rats were i.v. injected with both LE-pEJ and LE-p17hGHnneo carrying the hGH cDNA gene, and secreted hGH in the plasma which induced the synthesis of anti-hGH antibodies. A cell line was cloned from cultures of primary hepatocytes isolated from the liver of transfected rats. After 2 to 3 months in culture, this cell line secreted per day 18.9 µg albumin and 11.0 µg transferrin per 10⁶ cells, 38.75 nmol total BA per mg cell protein, and up to 31 ng hGHper 10⁶ cells without cloning hGH recombinant cells. A 24 hr control culture of primary hepatocytes isolated from non transfected rats secreted 25.5 µg albumin and 11.7 µg transferrin per 10⁶ cells, and produced 21.64 nmol total BA and 2.13 nmol N-OH-2-AFAF per mg cell protien. Hence, Ha-ras ^EJ transfection of either hepatocytes in vitro or liver cells in vivo, initiated cell cycles leading to presumptive proliferating hepatocytes which express liver function.Abbreviations BWE basal Williams' medium E - FBS fetal bovine serum - F10 or F12 basal Ham's F10 or F12 medium - Ha-ras ^EJ EJ allele of the human cellular ras oncogen of Harvey - hGH human growth hormone - hsp heat shock protein gene - LE-p liposome encapsulated plasmid - N-OH-2-AFAF N-hydroxy-2-acetylaminofluorene - RLECC rat liver epithelial cell - SF serum-free - SS serum-supplemented - UGG serum substitute UGltroser G® - 1-OH-, 3-OH-2-AFAFF 1-hydroxy-, 3-hydroxy-2-acetylaminofluorene - 2-AFAF 2-acetylaminofluorene - 2-AFF 2-aminofluorene     

Primary culture of chicken hepatocytes in serum-free medium (pH 7.8) secreted albumin and transferrin for a long period in free gas exchange with the atmosphere

To study the liver functions of chicken, we examined the primary culture of chicken hepatocytes, and found an easy method of long-term culture with free atmosphere exchange. Chicken hepatocytes were obtained by collagenase perfusion and cultured at 37°C as a monolayer without substratum in serum-free L-15 medium (pH 7.8) with free atmosphere exchange. The amounts of albumin and transferrin in medium were assayed by ELISA. The culture of chicken hepatocytes was maintained in the serum-free L-15 medium (pH 7.8) at 37°C with free atmosphere exchange for 20 days. The amount of albumin secreted in the medium decreased to low levels early in culture; however, this was followed by marked increase from day 9 to day 17 of culture. The amount of transferrin was constant until day 6, then it too increased considerably with further culture. We reported an easy method for the simple monolayer culture of chicken hepatocytes in serum-free L-15 medium (pH 7.8) with free atmosphere exchange over an extended period. Expression of liver-specific functions, viz. albumin and transferrin synthesis, was observed after 1 week of culture.     

Study of liver differentiation in vitro

A clonal rat fetal liver cell line that expresses the functions of differentiated liver cells under controllable conditions has been established. Normal fetal liver cells were transformed by a temperature-sensitive A (tsA) mutant (tsA209) of simian virus 40. At the permissive temperature (33 degrees C), the tsA209-transformed liver cell line (RLA209-15) can be cultured indefinitely and cloned readily. The RLA209-15 cells were temperature sensitive for maintenance of the transformed phenotype. These transformed liver cells selectively lost four characteristics of the transformed phenotype at the restrictive temperature (40 degrees C): generation time of the cells increased, the saturation density decreased, the efficiency of growth on nontransformed cell layers decreased, and the ability to clone in soft agar was lost. The transformation can be reversed simply by a shift in temperature. RLA209-15 fetal liver cells synthesized alpha-fetoprotein albumin, and transferrin. At 33 degrees C, the levels of these liver proteins were relatively low. At 40 degrees C the transformed phenotype was lost and the levels of alpha-fetoprotein, albumin, and transferrin were greatly increased. At the restrictive temperature, maximal induction of the synthesis of alpha-fetoprotein, albumin, and transferrin was achieved 3-4 d after the upward shift in temperature. The synthesis of alpha-fetoprotein then decreased; the synthesis of albumin and transferrin, however, was maintained. A second phase of albumin and transferrin synthesis was observed in all cultures after 6 d or more at 40 degrees C. Alpha-Fetoprotein, albumin, and transferrin secreted by RLA209-15 cells were immunologically indistinguishable from authentic alpha-fetoprotein, albumin, and transferrin, respectively. RLA209-15 cells, like primary cultures of hepatocytes and a simian virus 40 tsA255-transformed fetal liver cell line (RLA255-4) reported earlier from this laboratory, responded to glucagon with markedly elevated levels of cyclic AMP. Thus, it appears that glucagon receptors characteristic of hepatocytes are retained in the simian virus 40 tsA-transformed fetal liver cells.     

Colony isolation and secondary culture of fetal porcine hepatocytes on STO feeder cells

Summary The secondary culture of non-transformed parenchymal hepatocytes has not been possible. STO feeder cell-dependent secondary cultures of fetal pig hepatocytes were established by colony isolation from primary cultures of 26-d fetal livers. The liver cells had the typical polygonal morphology of parenchymal hepatocytes. They also spontaneously differentiated to form small biliary canaliculi between individual cells or progressed further to large multicellular duct-like structures or cells undergoing gross lipid accumulation and secretion. The secondary hepatocyte cultures expressed alpha-fetoprotein (AFP), albumin, and β-fibrinogen mRNA, and conditioned medium from the cells contained elevated levels of transferrin and albumin. STO feeder cell co-culture may be useful for the sustainable culture of hepatocytes from other species.     

Regulation of gene expression in adult rat hepatocytes cultured on a basement membrane matrix

Freshly isolated adult rat hepatocytes, when cultured on type I collagen (commercially available as Vitrogen), assume a polygonal shape, form a stable monolayer within 24 hours, but lose the capacity to express some liver-specific functions over time in culture. We incubated hepatocytes in a serum-free medium on a reconstituted basement membrane gel, "matrigel" (prepared from an extract of extracellular matrix of the murine Engelbreth-Holm-Swarm sarcoma), and observed that the cells adhered firmly, remained rounded as single cells or clusters, and maintained liver-specific gene expression for more than 1 week in vitro. Hepatocytes on matrigel secreted substantially higher amounts of albumin, transferrin, haptoglobin, and hemopexin, Northern blot analyses of extracted cellular RNA, expressed increased amounts of mRNA for the liver-specific protein albumin (as compared with cells on vitrogen). In cultures treated with phenobarbital, cytochrome P-450b, and cytochrome P-450e, mRNAs and proteins were barely detectable in cells on Vitrogen but were induced to levels similar to those in the liver in vivo in matrigel cultures. Likewise, the use of matrigel greatly enhanced the induction of mRNA and protein for P-450c by 3-methylcholanthrene and for P-450p by steroidal and nonsteroidal inducers. However, neither substratum permitted induction of P-450d by 3-methylcholanthrene, suggesting that the effects of matrigel are selective even for expression in liver of members of the superfamily of cytochrome P-450 genes. Within 5 days in cultures on Vitrogen, hepatocytes expressed detectable amounts of fetal liver aldolase activity and also mRNA for vimentin and type I collagen, each considered a phenotypic change reflecting hepatocyte "dedifferentiation." None of these was present in cells on matrigel. Responsiveness to mitogenic stimuli, as judged by incorporation of 3H-thymidine into DNA, was also decreased in hepatocytes cultured on matrigel. Finally, there was a remarkable increase in the levels of both matrices during the first 2 days in culture. However, the continuously cytoskeleton mRNA over time in culture than did the rounded cells on matrigel. We conclude that hepatocytes cultured on matrigel, as opposed to the standard collagen, exhibit remarkably enhanced expression of many liver-specific functions.     

Long-term culture of rat liver cell spheroids in hormonally defined media

Liver cells of new-born rats, which were found to be able to form spheroidal aggregates when cultured on a nonadherent plastic substratum, were studied under various conditions of culture, mainly by adding different nutrients and growth factors to the culture medium. Analysis of hepatocyte-specific functions was carried out by immunoprecipitation to detect specific proteins newly secreted by liver cell spheroids on different days of culture. When no supplement was added to culture medium, the secretion of albumin and transferrin by liver cell spheroids was no longer detectable after 2 weeks of culture. When dexamethasone, glucagon, insulin, and EGF were added to culture medium, the secretion of albumin and transferrin remained detectable at least until 60 days of culture. This was even more striking when trace elements were added in addition to the three hormones and EGF. The effects of addition of these various factors to culture medium were also detectable with respect to alpha-FP secretion. Even after 54 days of culture in total supplemented medium, these liver cell spheroids could be transferred on a collagen-coated plastic substratum to form a monolayer of uniform liver parenchyma-like cells. The presence of extracellular matrix-like material was observed on the surface of cell spheroids. This could be responsible for attachment and fusion between cell spheroids. Thus, liver cell spheroids cultured in total supplemented medium ensured cell attachment to a biological matrix and cell-cell contact, which is thought to help maintain cell differentiation. Liver cell spheroids offer the possibility of toxicological and pharmacological studies as well as cultures in biomatrix and coculture systems. In addition these liver cells can be used for experiments in liver cell transplantation.