Studies on the persistence of differentiated functions in rat hepatocytes set into primary tissue culture. II. Production of specific exportable proteins and the effect of purine cyclic nucleotides: an immunofluorescent study

Morphology, growth, and gene expression in five newly isolated murine hepatocellular tumor cell lines

Five murine hepatocellular tumor cell lines (HepM-1-5) were isolated and grown in a synthetic medium added with hormones, growth factors and/or serum. The morphology of these lines ranged from a nearly homogeneous epithelial-like shape (HepM-2) to a stromal appearance (HepM-1). The remaining lines displayed a mixed morphology. For their proliferation all of the cell lines retained a clear dependence on the extracellular calcium level and hormonal and/or serum growth factors and, rather homogeneously, they did not express the albumin, alpha-fetoprotein (with the exception of HepM-2 cells), tyrosine aminotransferase, and ornithine transcarbamylase genes, whereas they all exhibited discrete levels of the ornithine aminotransferase mRNA. Only HepM-3 and HepM-5 lines expressed the procollagen type I gene.

Studies on the mechanisms by which tumor promoters stimulate the growth of primary neonatal rat hepatocytes

A single exposure to a low concentration (10(-10) mol/L) of several tumor promoters, namely 12-O-tetradecanoylphorbol-13-acetate (TPA), phenobarbital (PB), nafenopin, saccharin, teleocidin, benzoyl peroxide, butylated hydroxytoluene (BHT), dichlorodiphenyltrichloroethane (DDT), lindane, clofibrate, and melittin significantly stimulated DNA synthesis of neonatal rat hepatocytes in 4-day-old primary cultures. These cultures were kept in low-calcium (0.01 mmol/L) HiWoBa2000 synthetic medium, thereby evoking a neoplastic phenotype in otherwise normal (i.e., non-initiated) cells. The simultaneous addition of a single dose of alpha-tocopherol (10(-4) mol/L) or selenous acid (10(-5) mol/L), just as that of exogenous superoxide dismutase (SOD) (4), together with each of the above agents fully suppressed the stimulation of hepatocytic DNA synthesis by the xenobiotics. Hence, these findings strengthen the view that superoxide anions (or some other oxidizing compounds) act as the common mediators of the mitogenic effects of various tumor promoters in hepatocytes. Inhibition kinetics studies, in which TPA in a single dose (10(-10) mol/L) was used as the paradigmatic compound together with several kinds of inhibitors of its activity showed that the early mitogenic effects of TPA, i.e., the commitment of quiescent (G0) hepatocytes and the reentry into active cycling of hepatocytes spontaneously poised at the G1/S boundary, required oxidizing compounds, arachidonate metabolism derivatives, and plasmalemmal calcium-binding sites and transmembrane calcium fluxes. Instead, a later TPAs effect, the flow into DNA synthesis of hepatocytes previously committed to cycle, was shown to be controlled by retinoid-modulable activities, by some product(s) of the lipoxygenase pathway, and again by plasmalemmal calcium-binding sites and transmembrane calcium fluxes. Such results reveal that in the neonatal rat hepatocyte the ability to answer to a single mitogenic stimulus and the metabolic pathways by which this answer is enacted depend upon the mitotic cycle setting of the hepatocytes at the moment of the experimental treatment.

Modulation of human fetal hepatocyte survival and differentiation by interactions with a rat liver epithelial cell line

Fetal human hepatocytes were isolated by collagenase digestion of liver fragments and cultured either alone or mixed with rat liver epithelial cells. Whereas they did not survive more than 2-3 weeks and showed rapid morphologic and functional alterations in conventional culture, fetal hepatocytes survived and retained or reverted to a globular morphology for several weeks and showed active albumin secretion for at least 13 days when cultured with rat liver cells. Increased levels of secreted albumin correlated with deposition of an insoluble extracellular material containing fibronectin and type III collagen located principally between the two cell types and around parenchymal cells. These observations show that fetal human hepatocytes are able to interact in vitro with another epithelial liver cell type obtained from a divergent species and that these cell-cell interactions influence both hepatocyte survival and expression of albumin.

The tumor promoters TPA, phenobarbital, and nafenopin and the prostaglandins of A, E, and F series overcome the G1/S block imposed by extracellular calcium deprivation on neonatal rat hepatocytes

A single exposure to a low concentration (10(-9) mole/l) of exogenous arachidonic acid or of prostaglandins of A, E, and F series significantly stimulated primary neonatal rat hepatocytes to enter S phase irrespective of whether the extracellular calcium concentration was high (i.e., 1.8 mmole/l) or markedly reduced (i.e., 0.01 mmole/l). Similarly, a single treatment with an even smaller (10(-10) mole/l) dose of the known tumor promoters 12-O-tetradecanoylphorbol-13-acetate (TPA), phenobarbital, and nafenopin enhanced hepatocytic DNA synthesis when the environmental calcium level was both high and low. By contrast, a single application of a small concentration (10(-11)-10(-10) mole/l) of hormones such as epidermal growth factor (EGF), glucagon, and insulin, and of drugs such as imidazole and indomethacin only increased the hepatocytic flow into DNA synthesis when the extracellular calcium was high. These findings reveal that the mechanisms of physiological or pharmacological, calcium-dependent stimulation of hepatocellular growth are likely to be different from those of pathological, calcium-independent stimulation, as the latter, but not the former, would involve prostaglandin-mediated metabolic processes.

The cGMP system in irradiated animals. Changes in cGMP content and activities of guanylate cyclase and cyclic nucleotide phosphodiesterase

Changes in the functioning of the cGMP system of the thymocytes and liver of mice subjected to 8 Gy roentgen irradiation were found. Within one hour after irradiation an increase in the cGMP level in thymocytes was noted; two rises in the cGMP concentration in the liver were established, at 0.5 and 24 hours after irradiation. These changes in the cGMP level were correlated to an increase in the guanylate cyclase activities in the thymocytes and liver of the mice subjected to irradiation, and to a lesser extent to changes in the activities of cGMP phosphodiesterase in these tissues. A post-irradiation increase in the rat liver guanylate cyclase activity was also observed. A decrease in cGMP phosphodiesterase activity in the liver of the irradiated mice was followed by a change in the enzymatic kinetics and an increase in cGMP phosphodiesterase thermolability. The post-irradiation rise in guanylate cyclase activity was produced by activation of the enzyme.

Unscheduled DNA synthesis tests. A report of the U.S. Environmental Protection Agency Gene-Tox Program

The utility of unscheduled DNA synthesis (UDS) testing for screening potentially hazardous chemicals was evaluated using the published papers and technical reports available to the UDS Work Group. A total of 244 documents were reviewed. Based on criteria defined in advance for evaluation of the results, 169 were rejected. From the 75 documents accepted, results were reviewed for 136 chemicals tested using autoradiographic approaches and for 147 chemicals tested using liquid scintillation counting (LSC) procedures; 38 chemicals were tested by both approaches to measure UDS. Since there were no documents available that provided detailed recommendations of UDS screening protocols or criteria for evaluating the results, the UDS Work Group presents suggested protocols and evaluation criteria suitable for measuring and evaluating UDS by autoradiography in primary rat hepatocytes and diploid human fibroblasts and by the LSC approach in diploid human fibroblasts. UDS detection is an appropriate system for inclusion in carcinogenicity and mutagenicity testing programs, because it measures the repair of DNA damage induced by many classes of chemicals over the entire mammalian genome. However, for this system to be utilized effectively, appropriate metabolic activation systems for autoradiographic measurements of UDS in human diploid fibroblasts must be developed, the nature of hepatocyte-to-hepatocyte variability in UDS responses must be determined, and the three suggested protocols must be thoroughly evaluated by using them to test a large number of coded chemicals of known in vivo mutagenicity and carcinogenicity.

Prostaglandins of the F series are extremely powerful growth factors for primary neonatal rat hepatocytes

At low concentrations (i.e., 10(-12)-10(-9) mol/1), PGF1 alpha and PGF2 alpha very intensely stimulated both the DNA-synthetic and mitotic activities of hepatocytes in 4-day-old primary cultures of neonatal rat liver. DNA replication was more intensely enhanced by PGF2 alpha than by PGF1 alpha, whereas mitotic activity was nearly equally affected by the two prostaglandins. On the whole, the growth-promoting activity of PGF1 alpha used by itself or in equimolar mixtures with other prostaglandins (e.g., A1, E1, etc.) mimicked that of arachidonic acid we previously reported (1). On a molar basis, PGF2 alpha by itself stimulated hepatocytes' DNA synthesis more powerfully than arachidonate did, and when used in equimolar mixtures with other prostaglandins was at least as potent as arachidonic acid. These observations establish prostaglandins of the F series as quite powerful commitment factors and, though by a lesser degree, also intracycle regulators for neonatal rat hepatocytes in primary culture. However, the understanding of the role(s) of prostaglandins of F and other series in the physiological control of hepatocytes' proliferative activation must await the clarification of their interaction(s) with other arachidonate derivative(s) and polypeptide growth factor(s) which also may be involved in the process.

The calcium-dependence of the stimulation of neonatal rat hepatocyte DNA synthesis and division by epidermal growth factor, glucagon and insulin

A low concentration (10(-11) mol/l) of epidermal growth factor (EGF) and/or an equimolar (10(-14) mol/l) mixture of glucagon and insulin stimulated DNA synthesis in hepatocytes in 4-day-old primary cultures of neonatal rat liver. EGF seems to have acted by inducing quiescent hepatocytes to begin cycling, while the glucagon-insulin combination seems to have acted mainly by shortening the cell cycle time. Incubation in low calcium medium blocked untreated hepatocytes in the G1 phase of their cycle and prevented EGF and the glucagon-insulin mixture from stimulating DNA synthesis. Nevertheless, hepatocytes in calcium-deficient medium did respond to these agents, as they reached a late stage of prereplicative development before being blocked: in fact, they initiated DNA synthesis soon after the addition of calcium. EGF, but not the glucagon-insulin combination, also enabled the already cycling hepatocytes (but not the newly activated ones) to overcome the block imposed by the extracellular calcium deficiency after a delay of several hours.

Modulation of functional activities in cultured rat hepatocytes

Rat hepatocytes isolated by enzymatic dissociation of the liver must attach in order to survive for more than a few hours. In conventional culture conditions, they rapidly lose their highly differentiated functions, e.g. adult isozymic forms, enzyme response to specific hormones and cytochrome P-450-dependent monooxygenase activities. Incompletely differentiated cells such as perinatal and regenerating hepatocytes, can transiently exhibit a more differentiated state. Therefore, regulation of hepatic functions, particularly enzyme activities cannot be studied for more than a few days. Hepatocyte survival rate and maintenance of specific functions are dependent on nutrient composition of the medium as well as the substrate. Complex matrices, particularly that derived from the connective liver biomatrix, appear to have an important favorable effect. However, regardless of culture conditions specific functions cannot be quantitatively maintained for more than several days. Recent observations strongly suggest that such a problem may be overcome by mimicking in vivo specific cell-cell interactions. Thus when co-cultured with a liver epithelial cell line, probably derived from biliary ductular cells, adult hepatocytes remain able to synthesize high levels of albumin and to conjugate drugs. In these conditions, the cells secrete an abundant heterogeneous extracellular material. The co-cultures can be maintained in a serum-free medium and specific liver functions can be altered experimentally. Such a model could be appropriate for studying long-term induction and modulation of liver enzyme activities under defined experimental conditions.

Growth and functional activities of neonatal and adult rat hepatocytes cultured on fibronectin coated substratum in serum-free medium

Hepatocytes isolated from neonatal (NN) and adult (AD) rats were seeded on fibronectin coated substratum and cultured in arginine-free medium supplemented with various combinations of insulin, dexamethasone, triiodothyronine (T3), albumin, and transferrin, in presence or absence of fibronectin depleted serum (FDS). The main finding is that in response to certain hormone mixtures, both NN and AD hepatocytes can be stimulated to proliferate, as revealed by an increase in cell number, a [3H]thymidine incorporation into nuclei, and extractable DNA as well as the appearance of mitotic figures. Moreover, this proliferative activity is associated with changes in hepatocyte ploidy. However, the proliferative response of NN hepatocytes to hormone action is much different from that of AD hepatocytes, and the addition of FDS amplifies this activity in NN but inhibits it in AD hepatocyte cultures. Measurements of tyrosine aminotransferase and lactate dehydrogenase activities indicate a good preservation of NN and AD hepatocyte functional integrity under certain culture conditions. A good maintenance of albumin production in NN and AD hepatocyte cultures requires the presence of dexamethasone, whereas the alpha-fetoprotein production in NN hepatocyte cultures is reduced quite rapidly under most conditions. No alpha-fetoprotein is detectable in AD hepatocyte cultures.

The calcium-dependent stimulation of the proliferation of neonatal rat hepatocytes by imidazole and indomethacin

Low concentrations (e.g. 10(-12) and 10(-11) mol/l) of imidazole and indomethacin strongly stimulated DNA synthesis and mitosis of hepatocytes in 4-day-old primary cultures of neonatal rat liver. These agents seem to have acted by inducing quiescent hepatocytes to begin cycling rather than by affecting already cycling cells, because they did not shorten the total cell cycle time. Neither compound stimulated DNA synthesis by hepatocytes cultured in low (0.010 mol/l) calcium medium. Nevertheless, hepatocytes in calcium-deficient medium must have been mitogenically activated by these compounds and, hence, been able to reach a late stage of prereplicative development because they did initiate DNA synthesis very soon after the addition of calcium.

Hepatocytes from newborn and weanling rats in monolayer culture: isolation by perfusion, fibronectin-mediated adhesion, spreading, and functional activities

The two-step collagenase perfusion method originally developed for the high yield isolation of parenchymal cells from adult rat livers has been adapted to rats of 1 day, 1 week, and 2 weeks of age. The use of this method to isolate hepatocytes from five or six rats of the respective ages demonstrated its reliability in terms of cell yield, percentage of single cells, and cell viability. In all cases, hepatocytes attach with high efficiency to fibronectin precoated dishes using serum-free culture medium. The dynamics of spreading is faster for newborn hepatocytes than adult ones. The functional integrity of these parenchymal liver cells was assessed by their capacity to secrete albumin and alpha-fetoprotein in serum-free medium and to express lactate dehydrogenase activity over a 24-hr period in primary culture.

The stimulation by epidermal growth factor (urogastrone) of the growth of neonatal rat hepatocytes in primary tissue culture and its modulation by serum and associated pancreatic hormones

Epidermal growth factor (EGF) added in a single dose (between 10(-16) and 1.7 X 10(-9)M) to neonatal rat hepatocytes in primary culture with subsequent incubation for 12 and 24 hours in Eagle's MEM fortified with 10% (v/v) FBS stimulated their entry into S and M phases, as shown by (3H)thymidine labeling and autoradiography and by a 4-hour exposure to colchicine (0.1 mM). Growth stimulation by EGF was detectable after 4 hours, peaking between 12 and 16 hours, and thereafter declining in intensity. Rat hepatocytes exposed for 72 hours (between the fourth and the seventh day in vitro) to no serum or to 10% fresh FBS possessed similar growth rates and absolute numbers in the cultures. A 24-hour exposure to 20 to 50% FBS stimulated hepatocytic DNA synthesis and mitotic activity and resulted (except for the 50% FBS treatment) in increased hepatocytes' numbers, which were relatively greater than the concurrent increases in connective tissue cell numbers. In serum-devoid medium EGF (10(-11)M) enhanced hepatocytic mitotic, but not DNA-synthetic activity. To be fully effective EGF required a 10% FBS addition to the medium, then eliciting within 24 hours a marked increase in hepatocytes' number with respect to cultures incubated with 10% serum only. When associated with 20 to 30% FBS, EGF stimulated parenchymal cell growth at rates slightly higher, but not significantly different, than those elicited by the same serum concentrations alone. However, when used in conjunction with 10 to 30% FBS, EGF preferentially increased the number of hepatocytes rather than that of non-parenchymal cells. Moreover, comparative proliferation kinetic studies showed that in the presence of 10% FBS, an equimolar (10(-14)M) mixture of EGF, insulin, and glucagon promoted an early and marked increase in the DNA-synthetic and mitotic activities of hepatocytes, which peaked after 8 hours. Within a 24-hour time lag this growth stimulation was as effective in increasing the final hepatocytes' number as was a 1000-fold higher EGF concentration, and was twice as active as either an equimolar (10(-14)M) mixture of the two pancreatic hormones or EGF by itself at 10(-14)M. These results show that the growth-promoting effect of EGF on primary neonatal rat hepatocytes is modulated by serum factor(s) and can be additively amplified by the simultaneous administration of subphysiological doses of glucagon and insulin.

Changes in some chromatin and cytoplasmic enzymes of perinatal rat hepatocytes during culture

Hepatocytes prepared from rats at various perinatal stages were cultured in selective medium that does not allow fibroblastic cell growth. Cell population remained homogeneous during the culture. Hepatocytes undergo divisions for a period, which varies according to the stage of development of the rat. Light and electron microscope observations showed the presence of numerous cytoplasmic organelles; moreover, hydrocortisone-induced structures similar to bile canaliculi. Chromatin protein kinase decreased rapidly during culture except in samples prepared from 17-day fetuses in which it remained unchanged for 2 days and decreased to a lesser extent afterwards. Chromatin nonhistone proteins were incubated with (gamma-32P) ATP and the phosphorylation pattern analyzed on polyacrylamide gels. Many radioactive peaks were observed in chromatin proteins from 17-day fetuses; they were much lower in proteins than 19-day fetuses. The phosphorylation pattern was analyzed in hepatocytes after 2 days of culture. Many radioactive peaks were observed with proteins from hepatocytes taken from 17-day fetuses; no radioactivity was observed in proteins from 19-day fetuses. This is in contrast with the absence of radioactive peaks in chromatin proteins from adult rat hepatocytes. In cytoplasm, aldolase and pyruvate kinase specific activities varied according to the age of the rat. They strongly decreased during culture except in hepatocytes and 15- and 17-day fetuses, in which they remained stable for a least 5 days. The stability of chromatin and cytoplasmic enzymes in hepatocytes from 17-day fetuses could result from their ability to be regulated by hormones that are secreted at this stage of development.