Albumin synthesis in cultured hempatoma cells. Regulation by essential amino acids.

The effects of essential amino acids on albumin synthesis by a mouse hepatoma cell line have been investigated. The amino acids tested were tryptophan, phenylalanine, histidine, isoleucine and leucine. Cellular rates of synthesis (molecules albumin/cell per min) were determined from rates of [3H]leucine incorporation into immunoprecipitable albumin in the culture medium. The effects of amino acids on albumin synthesis fall into three distinct groups. The concentration of tryptophan producing half-maximal synthesis is 4 micronM. The corresponding concentration for leucine is 100 micronM. Histidine, phenylalanine and isoleucine were very similar, the half-maximal concentrations being approximately 15 micronM. The concentrations of amino acids producing half-maximal synthesis correlate directly with the amino acid composition of albumin. The levels of these essential amino acids necessary to saturate albumin synthesis have been compared with amino acid levels in normal plasma.     

Regulation of glycogen synthesis by amino acids in cultured human muscle cells

Insulin and a number of metabolic factors stimulate glycogen synthesis and the enzyme glycogen synthase. Using human muscle cells we find that glycogen synthesis is stimulated by treatment of the cells with lithium ions, which inhibit glycogen synthase kinase 3. Insulin further stimulates glycogen synthesis in the presence of lithium ions, an effect abolished by wortmannin and rapamycin. We report also that amino acids stimulate glycogen synthesis and glycogen synthase, these effects also being blocked by rapamycin and wortmannin. Amino acids stimulate p70(s6k) and transiently inhibit glycogen synthase kinase 3 without effects on the activity of protein kinase B or the mitogen-activated protein kinase pathway. Thus, the work reported here demonstrates that amino acid availability can regulate glycogen synthesis. Furthermore, it demonstrates that glycogen synthase kinase 3 can be inactivated within cells independent of activation of protein kinase B and p90(rsk).     

Regulation of sulfate uptake by amino acids in cultured tobacco cells

The sulfur requirements of tobacco (Nicotiana tabacum L. var. Xanthi) XD cells grown in chemically defined liquid media can be satisfied by sulfate, thiosulfate, l-cyst(e)ine, l-methionine or glutathione, and somewhat less effectively by d-cyst (e) ine, d-methionine or dl-homocyst (e)ine. Sulfate uptake is inhibited after a 2 hr lag by l-cyst (e)ine, l-methionine, l-homocyst(e)ine or l-isoleucine, but not by any of the other protein amino acids, nor by d-cyst(e)ine. l-cyst(e)ine is neither a competitive nor a non-competitive inhibitor of sulfate uptake. Its action most closely resembles apparent uncompetitive inhibition. Inhibition of sulfate uptake by l-cyst(e)ine can be partially prevented by equimolar l-arginine, l-lysine, l-leucine, l-phenylalanine, l-tyrosine or l-tryptophan, but is little affected by any of the other protein amino acids. The effective amino acids are apparent competitive inhibitors of l-cyst(e)ine uptake after a 2 hr lag. Inhibition of sulfate uptake by l-methionine cannot be prevented, nor can uptake of l-methionine be inhibited by any single protein amino acid. The results suggest the occurrence of negative feedback control of sulfate assimilation by the end products, the sulfur amino acids, in cultured tobacco cells.     

Expression of liver phenotypes in cultured mouse hepatoma cells: synthesis and secretion of serum albumin

A permanent cell line, designated Hepa, has been isolated from a mouse hepatoma, BW 7756. The cell line synthesizes and secretes albumin at rates appreciably higher than previously reported hepatomas adapted to in vitro conditions. Monospecific antimouse serum albumin was produced in rabbits, and mouse serum albumin secreted by the hepatoma cells was identified by double diffusion, immunoelectrophoresis, and radioimmunodiffusion. A quantitative immunoassay was used to measure albumin secretion and to study the effects of culture conditions on albumin secretion. A subclonal analysis was performed to study the homogeneity and stability of cloned hepatoma lines in respect to albumin secretion. Different secretion rates were observed during the culture cycle. Significant clonal variation in respect to albumin secretion was found among ten subclones.The significance of clonal variation is discussed in relation to the study of epigenetic control of albumin expression in somatic hybrid cells.     

Effects of cyclic AMP on the kinetics of serum protein synthesis in cultured mouse hepatoma cells

The mouse hepatoma cell line, Hepa, was cultured in the presence of either 1 mM N⁶, O^2′-dibutyryl cyclic AMP (Bt₂cAMP), 0.5 mM 3-isobutyl-1-methylxanthine, or 1 μg/ml cholera toxin. The synthesis and secretion of albumin, α-fetoprotein, and transferrin were elevated above controls by 24 h reaching two- to fourfold stimulations within 72 h. These effects were reversible and were specific for the serum proteins. The stimulation of serum protein synthesis was accompanied by a decrease in the rate of cell proliferation. Protein synthetic parameters were analyzed in Hepa cells 72 h after exposure to N⁶,O^2′-dibutyryl cyclic AMP. The cellular rate of albumin synthesis was increased fourfold and the relative rate of albumin synthesis was increased approximately threefold. N⁶,O^2′-Dibutyryl cyclic AMP did not affect the size distribution of either total Hepa polyribosomes or of albumin-synthesizing polyribosomes. The elongation rate on total mRNA and on albumin mRNA was decreased by approximately 40%. These results indicate that the rate of initiation of total Hepa mRNA and of albumin mRNA also decreased by 40%. The nonspecific nature of the N⁶,O^2′-dibutyryl cyclic AMP effect on Hepa protein synthetic parameters must be due to an alteration in the level of a common substrate, perhaps ATP. The specific threefold increase in the relative rate of albumin synthesis with no alteration in polyribosome sizes requires a threefold increase in the relative amount of functional albumin mRNA in Hepa cells. This prediction was confirmed by cell-free translation of Hepa polyribosomes.     

Synthesis and secretion of transferrin by cultured mouse hepatoma cells.

The mouse hepatoma cell (Hepa-1) in tissue culture has been shown to synthesize and secrete three electrophoretically distinct transferrins. Each of these forms of transferrin has a molecular weight of 77,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The concentration of each form is indicated by its staining intensity, which is highest in the form with the fastest mobility and lowest in the form with the slowest mobility. The relative rate of transferrin synthesis has been determined in log-phase and stationary-phase cells; the data indicate that the relative rate of synthesis increases twofold in stationary-phase cells. When the incorporation of [3H]leucine into transferrin reaches steady state, the rate of secretion is equal to the rate of synthesis; the rate of secretion also increases twofold in stationary-phase cells. Our studies also show that transferrin synthesis accounts for 0.98% of the total protein synthesis in log-phase cells and for 1.8% in stationary-phase cells. This is the level of synthesis that has been determined by in vivo studies. We conclude that after continuous culture for several years these hepatoma cells have maintained one of the characteristics of the differentiated liver cell, namely, the ability to synthesize and secrete transferrin.     

Coordinated modulation of albumin synthesis and mRNA levels in cultured hepatoma cells by hydrocortisone and cyclic AMP analogs.

The treatment of Hepa-2 cells, a permanent mouse hepatoma cell line, for 72 h with hydrocortisone (10(-6) M), N6,O2-dibutyryl cyclic AMP (10(-3) M), or 8-bromocyclic AMP (10(-3) M) results in a 2-,3- or 4-fold increase, respectively, in rates of synthesis and secretion of mouse serum albumin. Simultaneous treatment with hydrocortisone and N6,O2-dibutyryl cyclic AMP results in a 10-fold stimulation in these parameters, an effect that is significantly more than additive for the two compounds tested. The number of albumin mRNA sequences, determined by hybridization of total cell RNA to albumin complementary DNA, was increased in direct proportion to the increases in albumin synthesis in all experiments. The relative rate of albumin synthesis approaches in vivo levels in cells treated simultaneously with hydrocortisone and N6,O2-dibutyryl cyclic AMP. We propose that these factors may be necessary to maintain the maximal level of differentiated function in the continuous culture of Hepa-2 cells.     

Regulation of alpha-fetoprotein and transferrin synthesis and secretion in mouse hepatoma cells

Significant differences in the glucocorticoid- and cyclic nucleotide-mediated regulation of the secretory glycoproteins, α-fetoprotein and transferrin, have been observed to develop in a mouse hepatoma cell line, Hepa-2, after many passages in culture. Treatment of low-passage cells with hydrocortisone (10^?6m), N⁶,O²-dibutyryl cyclic AMP (10^?3m), or 8-bromo-cyclic AMP (10^?3m) results in 1.5-, 2- to 4-, and 5.5- to 6-fold increases, respectively, in the rates of synthesis and secretion of α-fetoprotein. As expected of secretory proteins, the ratio of synthesis to secretion is 1 and remains unaltered when treatment with hydrocoritsone, N⁶,O²-dibutyryl cyclic AMP, and 8-bromo-cyclic AMP causes a stimulation of synthesis and secretion. Similar studies showing that albumin and transferrin synthesis and secretion are also balanced in these low-passage cells have been published and indicate that the regulation of synthesis and secretion remains coupled in these low-passage cells. In high-passage Hepa-2 cells, however, we have shown that the relative rate of α-fetoprotein synthesis is higher than its rate of secretion and that the ratio of synthesis to secretion is 4. Similarly, the ratio of transferrin synthesis to secretion is 3.6, whereas it remains unaltered for albumin. When the high-passage cells are treated with N⁶,O²-dibutyryl cyclic AMP, there is a greater increase in the rate of secretion for both glycoproteins, resulting in a reduction of the ratio of synthesis to secretion from 4 to 1.63 for α-fetoprotein and from 3.6 to 2.3 for transferrin. This effect on the secretion of α-fetoprotein and transferrin is specific for the cyclic nucleotides and occurs only in high-passage cells. Hydrocortisone treatment causes an increase in α-fetoprotein synthesis and secretion. However, the ratio of synthesis to secretion increases from 3.96 in control to 5.5 in treated cells. Our studies show, therefore, that there is an increase in this ratio because of a slightly greater effect on synthesis which is not reflected in secretion. Similarly, hydrocortisone exerts a greater increase in transferrin synthesis than secretion and causes the ratio of synthesis to secretion to increase from 3.6 to 6.2. We propose that during continued subculturing a Hepa-2 variant is selected in which the regulation of serum glycoprotein synthesis and secretion is uncoupled. Furthermore, this effect is specific for secretory glycoproteins since the regulation of albumin synthesis and secretion by hydrocortisone and cyclic nucleotides remained unaltered.     

Stimulation of albumin synthesis in mouse hepatoma cells by Bt2cAMP: cell cycle specificity

Addition of 1 mm dibutyryl cyclic AMP (Bt₂cAMP) to cultures of mouse hepatoma cells, Hepa, specifically stimulates the synthesis of serum proteins including albumin. This stimulation is accompanied by an inhibition of cell proliferation. We have investigated these phenomena in synchronous cultures of Hepa. Proliferation of Hepa was arrested by isoleucine starvation. Synchronous growth was initiated by addition of complete growth medium or complete growth medium supplemented with 1 mm Bt₂cAMP. S phase and mitosis were estimated by determinations of [³H]thymidine incorporation and by cell numbers. The rate of albumin synthesis relative to total protein synthesis was measured by pulse labeling cultures for 30 min with [³H]leucine and comparing amounts of immunoprecipitable label with trichloroacetic acid-precipitable label. Treatment of synchronous cultures with Bt₂cAMP did not alter the duration of S phase or the onset of mitosis. The relative rate of albumin synthesis in Bt₂cAMP-treated culture began increasing after mitosis. The timing of the Bt₂cAMP stimulation of albumin synthesis was further investigated by adding Bt₂cAMP to cultures of Hepa at various times after the initiation of synchronous growth. The relative rate of albumin synthesis was then measured at a fixed postmitotic time. An increased relative rate of albumin synthesis was observed only in cultures exposed to Bt₂cAMP before or during S phase. Thus the postmitotic increase in the synthesis of albumin requires the presence of Bt₂cAMP during S phase.     

Infection of cultured rat hepatoma cells by mouse mammary tumor virus.

A continuous line of buffalo rat hepatoma (HTC) cells has been successfully infected with mouse mammary tumor virus (MMTV) produced by the GR mammary tumor cell line. Uniform infection required initial exposure of the HTC cells to greater than 10(5) MMTV particles per cell. The resultant chronically infected cell population was found to have stably acquired 20-30 copies of MMTV DNA. The infected cells contain viral RNA and express viral antigens; however, very few MMTV particles are released into the culture medium. In spite of the biochemical evidence for infection, we have not detected any alterations in the morphology or growth properties of the infected HTC cells. As is the case in mammary tumor cells, the intracellular concentration of viral RNA is strongly stimulated (50-150 fold) by the synthetic glucorcorticoid, dexamethasone. Thus it appears that the mechanisms by which glucorticoids regulate MMTV gene expression in mouse cells are maintained when this virus infects nonmurine cells.     

Regulation of initiation of DNA synthesis in relation to mitosis in cultured hepatoma cells

The commitment of Reuber H 35 hepatoma cells to DNA synthesis was studied by exposing cells which were synchronized by serum depletion, to serum. It is shown that the period of commitment is 6--8 during the G2 period of the previous cell cycle.     

Regulation of protein synthesis by branched-chain amino acids in vivo

Recent advances in the understanding of mRNA translation have facilitated molecular studies on the regulation of protein synthesis by nutrients and the interplay between nutrients and hormonal signals. Numerous reports have established that, in skeletal muscle, the branched-chain amino acids (BCAAs) have the unique ability to initiate signal transduction pathways that modulate translation initiation. Of the BCAAs, leucine is the most potent. Oral administration of leucine to food-deprived rats enhances muscle protein synthesis, in part, through activation of the mRNA binding step of translation initiation. Interestingly, leucine signaling in skeletal muscle differs from that in liver, suggesting that the responses may be tissue specific. The purpose of this paper was to briefly review the current knowledge of how BCAAs act as regulators of protein synthesis in physiologically important tissues, with particular focus on the mechanisms by which BCAAs regulate translation initiation.     

Immunoprecipitation assay of alpha-fetoprotein synthesis by cultured mouse hepatoma cells treated with estrogens and glucocorticoids

This investigation was to study the biosynthesis of 3H-labeled alpha-fetoprotein (AFP) by cultured mouse hepatoma (HEPA-2) cells. Both the function and regulation of this oncodevelopmental gene are unknown. However, evidence indicates that mechanisms controlling the expression of AFP involve aspects of both normal embryonic development and neoplastic transformation. the secretion of AFP was analyzed during different phases of the growth cycle to provide information on AFP production using standard culture conditions. The highest rate of secretion occurred during the stationary phase, followed by the late logarithmic and early logarithmic phases of growth, respectively. The production of AFP was then determined following the addition of glucocorticoids and estrogens in an attempt to understand hormonal factors that may be involved. Studies utilizing estradiol-17 beta indicated that the secretion of AFP did not appear to be sensitive to this steroid even though sucrose density gradient analysis of HEPA-2 cytosol, for estrogenic receptors, revealed competitive binding moieties on the 8S and 4S regions of the gradient. In contrast, the secretion of the total complement of proteins, including AFP, was significantly stimulated by the glucocorticoids, dexamethasone and corticosterone. Analysis of HEPA-2 cytosol for glucocorticoid receptors revealed binding components in the 7S and 3-4S regions of the gradient. The 3H-dexamethasone binding appeared to be stereospecific since nonlabeled dexamethasone, but not nonlabeled estradiol-17 beta, effectively displaced the bound radioactivity. The glucocorticoid-binding component in HEPA-2 therefore displayed characteristics reported for glucocorticoid receptors in normal liver and other hepatomas.     

Inhibition of synthesis of alpha-fetoprotein by glucocorticoids in cultured hepatoma cells

alpha-Fetoprotein (AFP) synthesis was studied in the presence and absence of glucocorticoids in rat hepatoma Mc-A-RH-7777 cells. Radioimmunoassay of media from cell cultures grown in the presence of glucocorticoid (dexamethasone or cortisol) showed a reduction in AFP, an increase in albumin, and no significant change in transferrin accumulation, as compared to controls. Labeling experiments with L-[35S]methionine indicated that in both cells and media of dexamethasone-treated cultures there was a 50--80% reduction in polypeptide precipitated by anti-AFP serum, as compared with controls; no change was seen in polypeptide precipitated by anti-transferrin serum. Pulse and pulse-chase experiments demonstrated that dexamethasone inhibited the synthesis of AFP but not its secretion. The half-time for secretion of AFP in the presence and absence of dexamethasone was 43 min.     

Rat serum albumin synthesis in variant rat hepatoma cells

Variant subclones of the rat hepatoma cell line FU5-5 have been isolated that are altered in their production of rat serum albumin. Three of these variants, isolated in a random screening, have been categorized as high, intermediate, and low producers. They secrete albumin into the culture medium at different rates: 16, 1.7, and 0.3 μg/mg cell protein/48 h. A fourth variant, isolated on the basis of altered morphology, secretes no detectable albumin. Unlike the albumin-producing variants, this null variant is also deficient in the level and inducibility of tyrosine aminotransferase activity. Albumin biosynthesis as determined in pulse-labeling experiments is affected similarly in the four variants, yielding albumin synthetic rates of 0.24, 0.035, 0.006, and < 0.002% of total protein synthesis. The translatable albumin messenger RNA content in these variants was measured using a rabbit reticulocyte lysate system. The null variant contains no detectable mRNA, and the three quantitative variants contain levels of translatable albumin messenger RNA corresponding to 0.07, 0.03, and 0.005% of total stimulated polypeptide synthesis. The highest producing variant contains less translatable albumin mRNA than expected on the basis of cellular biosynthetic measurements, suggesting a translation efficiency difference in this clone. Cell hybrids constructed by fusing the high-producing clone and the null variant produce little or no albumin. This extinction indicates that the null variant contains a diffusible regulatory factor capable of decreasing albumin gene expression. The relatively stable and discrete heritable phenotypic changes exhibited by these clones may serve as a model for similar changes that occur during hepatic differentiation.     

Regulation of nerve growth factor synthesis/secretion by catecholamine in cultured mouse astroglial cells

The nerve growth factor (NGF) synthesis/secretion by cultured mouse astroglial cells was modulated by catecholamine. In quiescent cells, epinephrine (EN) and dopamine (DA) markedly increased the NGF content in the conditioned medium (CM). Conversely, EN, DA, and norepinephrine (NE) decreased the NGF content in growing cells. Cholinergic agonists, metacholine and carbamylcholine, slightly increased the NGF content in quiescent cells, but showed no effects on growing cells. Other neurotransmitters tested had no effects on either growing or quiescent cells. These results suggest that catecholamine is one of the molecules responsible for regulation of NGF synthesis/secretion in the mouse brain.