Maintenance of glucokinase activity in primary hepatocyte cultures

AMP-activated protein kinase inhibits the glucose-activated expression of fatty acid synthase gene in rat hepatocytes

Although it is now clearly established that a number of genes involved in glucose and lipid metabolism are up-regulated by high glucose concentrations in both liver and adipose tissue, the signaling pathway arising from glucose to the transcriptional machinery is still poorly understood. We have analyzed the regulation of fatty acid synthase gene expression by glucose in cultured rat hepatocytes. Glucose (25 mM) induces an activation of the transcription of the fatty acid synthase gene, and this effect is markedly reduced by incubation of the cells with okadaic acid, an inhibitor of protein phosphatases 1 and 2A. A similar reduction in glucose-activated fatty acid synthase gene expression is obtained by incubation with 5-amino-imidazolecarboxamide riboside, a cell-permeable activator of the AMP-activated protein kinase. Taken together, these results indicate that the glucose-induced expression of the fatty acid synthase gene involves a phosphorylation/dephosphorylation mechanism and suggest that the AMP-activated protein kinase plays an important role in this process. This is the first evidence that implicates the AMP-activated protein kinase in the regulation of gene expression. AMP-activated protein kinase is the mammalian analog of SNF1, a kinase involved in yeast in the transcriptional regulation of genes by glucose.

Induction of fatty-acid-synthase gene expression by glucose in primary culture of rat hepatocytes. Dependency upon glucokinase activity

Fatty acid synthase (FAS) expression is low in liver and adipose tissue of suckling rats and increases markedly after weaning on to a high-carbohydrate low-fat diet. It has been shown previously that glucose alone, via an increase in intracellular glucose-6-phosphate level, stimulated the accumulation of FAS mRNA in cultured white adipose tissue of suckling rats. The regulation of FAS expression by glucose and hormones (insulin, dexamethasone and triiodothyronine) was studied in cultured hepatocytes from suckling rats. In hepatocytes cultured for 48 h in the absence of hormones and glucose, FAS mRNA, as well as glucokinase mRNA, levels remained undetectable. Glucose alone was unable to stimulate FAS expression. The combination of hormones, in the absence of glucose, has a marginal effect on FAS mRNA levels. However, FAS mRNA levels were increased in the presence of both glucose and the combination of hormones. This demonstrated that the hormonal induction of FAS mRNA was dependent on the presence of glucose in the culture medium. We have then investigated if glucokinase expression could be a prerequisite for the stimulation of FAS expression in response to glucose. Hepatocytes were cultured for 48 h in the absence of glucose but in the presence of insulin, dexamethasone and triiodothyronine. In these conditions, glucokinase mRNA and activity were markedly increased but there was no accumulation of FAS mRNA. When these hepatocytes were then exposed to various levels of glucose, FAS mRNA rapidly accumulated. Glucose stimulation of FAS expression was observed only in hepatocytes which expressed glucokinase activity. The importance of glucokinase expression for the induction of FAS mRNA by glucose is supported by the striking correlation between glucose-6-phosphate concentrations and the levels of FAS mRNA. This study clearly demonstrates that: (a) glucose metabolism is directly involved in the regulation of FAS gene expression; (b) the effect of hormones is partly due to their capacity to induce in the hepatocytes the capacity for glucose phosphorylation.

Hormonal control of substrate cycling in humans

Recent studies have established the existence of substrate cycles in humans, but factors regulating the rate of cycling have not been identified. We have therefore investigated the acute response of glucose/glucose-6P-glucose (glucose) and triglyceride/fatty acid (TG/FA) substrate cycling to the infusion of epinephrine (0.03 microgram/kg.min) and glucagon. The response to a high dose glucagon infusion (2 micrograms/kg.min) was tested, as well as the response to a low dose infusion (5 ng/kg.min), with and without the simultaneous infusion of somatostatin (0.1 microgram/kg.min) and insulin (0.1 mU/kg.min). Additionally, the response to chronic prednisone (50 mg/d) was evaluated, both alone and during glucagon (low dose) and epinephrine infusion. Finally, the response to hyperglycemia, with insulin and glucagon held constant by somatostatin infusion and constant replacement of glucagon and insulin at basal rates, was investigated. Glucose cycling was calculated as the difference between the rate of appearance (Ra) of glucose as determined using 2-d1- and 6,6-d2-glucose as tracers. TG/FA cycling was calculated by first determining the Ra glycerol with d5-glycerol and the Ra FFA with [1-13C]palmitate, then subtracting Ra FFA from three times Ra glycerol. The results indicate that glucagon stimulates glucose cycling, and this stimulatory effect is augmented when the insulin response to glucagon infusion is blocked. Glucagon had minimal effect on TG/FA cycling. In contrast, epinephrine stimulated TG/FA cycling, but affected glucose cycling minimally. Prednisone had no direct effect on either glucose or TG/FA cycling, but blunted the stimulatory effect of glucagon on glucose cycling. Hyperglycemia, per se, had no direct effect on glucose or TG/FA cycling. Calculations revealed that stimulation of TG/FA cycling theoretically amplified the sensitivity of control of fatty acid flux, but no such amplification was evident as a result of the stimulation of glucose cycling by glucagon.

Long-term culture of hepatocytes: effect of hormones on enzyme activities and metabolic capacity

(i) Hepatocytes isolated from adult rats were cultured for 2 to 3 weeks on collagen in a modified, serum-free Waymouth medium containing fatty acids and varying concentrations of glucocorticoid, insulin and glucagon. (ii) In the presence of all three hormones, it was possible to maintain the content of DNA, the activity of glucokinase, pyruvate kinase, hexokinase and lactate dehydrogenase at initial levels for 2 to 3 weeks. The activity of glucokinase and pyruvate kinase was affected by the concentration of insulin. (iii) The activity of alcohol dehydrogenase was stable for 3 days and declined to about 25% of the initial level after 2 weeks of culture, irrespective of the presence of hormones. (iv) Maintenance of albumin secretion was dependent on the presence of glucocorticoid, and glucocorticoid and insulin showed an additive or, at some time points, a synergistic effect on its secretion. (v) The content of cytochrome P-450 could be kept at 65% of the initial level, provided that a relatively high concentration of dexamethasone was present (10(-6) M). (vi) In the absence of hormones, urea synthesis was 70% of initial levels throughout the experimental period. With insulin and glucocorticoid present, a high concentration of glucagon (10(-8) M) was required to maintain the synthesis of urea at this level. (vii) It is concluded that hepatocyte cultures as described in the present study may be a useful, well-defined system for long-term metabolic, pharmacologic and toxicologic studies.

Maintenance and induction of cytochrome P-450 in cultured rat hepatocytes

Maintenance of microsomal cytochrome P-450 content by cultured rat hepatocytes has proven an elusive goal. It is reported here that exogenous heme maintains cytochrome P-450 content of cultured rat hepatocytes at high levels during the first 72 h of incubation. The maintenance studies have been expanded to demonstrate the in vitro induction of cytochrome P-450 by phenobarbital treatment. The induction of P-450 in vitro by phenobarbital required the trace element, selenium, in the presence of exogenous heme. The present findings suggest that selenium, and other trace elements, may have an essential role in the formation of holocytochrome P-450 in vitro.

Transmembrane potential and intracellular potassium ion activity in fetal and maternal liver

We have compared transmembrane potentials (Em) of maternal liver with Em of fetal liver, and as an initial step to account for differences in Em, we have measured intracellular potassium ion activities (aiK) in both tissues. Paired segments of maternal and fetal (day 17) mouse liver were suffused (15 ml/min) with Krebs' physiologic salt solution equilibrated with 95% 02-5% CO2 (pH 7.3-7.4) at 37 degrees C. To measure Em, cells were impaled with open-tip microelectrodes filled with 0.5 M KCl. Intracellular voltage recordings that were stable +/- 2 mV for at least 10 s were considered valid impalements. Maternal liver mean Em = -41 +/- 1 (SEM) mV, n = V 10 animals. In contrast, fetal liver mean Em = -23 +/- 1 (SEM) mV, n = 10 animals. In the same segments we measured aiK with potassium-selective liquid ion-exchanger microelectrodes. Maternal liver mean aik = 95 +/- 7 (SEM) mM and fetal liver mean aiK = 62 +/- 4 (SEM) mM. in addition, Em and aiK of fetal liver increased to values comparable to those of maternal liver during the first 8 days of neonatal life. The differences of Em and aik between fetal and maternal liver, and the changes in these values that occur in the neonate, may result from activity of a membrane Na-K exchange pump that increases with tissue development.

T3 stimulates the synthesis of a specific mRNA in primary hepatocyte culture

The mechanism of triiodothyronine (T3) induction of a thyroid hormone responsive mRNA (mRNAS14) was studied in primary cultures of adult rat hepatocytes. T3 induced mRNAS14 in less than one hour after addition to the cultures. After 24 hours exposure to T3, the level of mRNAS14 was 2.5 to 6 times above the untreated controls. Addition of Actinomycin-D to both induced and control cultures led to similar mRNAS14 disappearance curves, implying that T3 augments the synthesis of mRNAS14 rather than stabilizing pre-formed mature mRNA. Glucagon inhibits the T3 induction of mRNAS14. When added to both induced and control cultures, glucagon leads to similar fractional decay curves for mRNAS14, confirming the Actinomycin-D studies. These findings demonstrate T3 induces mRNAS14 directly in the hepatocyte by increasing the synthesis of the mature mRNA.

Expression of differentiated function by hepatocytes in primary culture: variable effects of glucagon and insulin on gluconeogenesis during cell growth

Hormonal effects on gluconeogenesis from lactate were studied during the growth cycle of adult rat parenchyma liver cells using a primary monolayer culture system previously described [25]. Basal and glucagon-stimulated gluconeogenic ability were found to decline rapidly during log phase, insulin-stimulated growth. A progressive recovery of gluconeogenesis activity was observed after cell division subsided. Rates of lactate-gluconeogenesis were found also to decline in the absence of prior insulin exposure. This decline was not as rapid as the loss observed in cells cultured with insulin. However, in insulin-deficient cultures gluconeogenesis was completely abolished after 12 days and did not reelevate with further incubation unless cells were washed and exposed to glucagon. Decreasing growth rates of insulin-supplemented cultures by decreasing serum concentrations resulted in comparatively higher gluconeogenic activity. The results presented here are consistent with previous observations of hepatic parenchymal expression of 'differentiated function' during cellular growth phases in culture (i.e., differentiated functions are generally lost during rapid growth and regained as cells become quiescent). The present study, however, presents unexpected effects of insulin on the apparent growth-state dependent gluconeogenic recovery. Our data imply that although insulin has long been known to inhibit gluconeogenesis, its presence in culture may facilitate long-term basal maintenance of gluconeogenic enzyme activity. Insulin also functions as a growth factor whose initial mitogenic effect correlates with decreased gluconeogenic function. These changes show no simple or predictive correlation with cyclic nucleotide metabolism.

Rat liver alcohol dehydrogenase. II. Quantitative enzyme-linked immunoadsorbent assay

Monospecific rabbit antibodies against purified Fischer-344 rat liver alcohol dehydrogenase were produced and used to develop an enzyme-linked immunoadsorbent assay for alcohol dehydrogenase. The assay is based upon the competitive inhibition of specific antibody binding to antigen (alcohol dehydrogenase adsorbed onto plastic microtiter plates) by soluble alcohol dehydrogenase (contained in unknown sample extracts or in known standard solutions). The amount of bound antibody is determined following incubation with peroxidase-linked second antibody (goat anti-rabbit IgG antibody-peroxidase conjugate) by colorimetric measurements of peroxidase activity at 490 nm in the presence of O-phenylenediamine. The assay is highly sensitive (it detects 10-1000 ng alcohol dehydrogenase/50 microliter) and it offers a precise (interexperimental variations in samples were less than 10%), rapid (6-8 h), and specific method for measurements of alcohol dehydrogenase in tissue homogenates or cultured hepatocytes. The assay was used to study changes in alcohol dehydrogenase levels during the growth cycle of cultured hepatocytes over a 2-week period and in rat liver homogenates after starving the animals for 72 h. In cultured hepatocytes, alcohol dehydrogenase activity and immunoassayable enzyme levels decreased coordinately during lag and early log phase, from 13.2 +/- 1.2 to 5.0 +/- 1.0 micrograms enzyme/mg protein, respectively. In mid-log phase, the enzyme levels were very low (1.3 +/- 0.4 micrograms enzyme/mg protein). During stationary phase, the levels (5.7 +/- 0.6 micrograms enzyme/mg protein) increased to 35% of the levels of freshly isolated hepatocytes (15.6 +/- 1.4 micrograms enzyme/mg protein). In starved animals, the enzyme levels decreased from 7.56 +/- 0.55 to 2.97 +/- 0.27 mg enzyme/liver. These changes also coincided with decreases in activity from 8.84 +/- 0.35 to 6.56 +/- 0.68 microM/min/liver.

Influence of physical training on insulin release and glucose utilization by islet cells and liver glucokinase activity in the rat

The effect of physical training on insulin release and glucose utilization by perifused islets and on liver glucokinase activity was examined in rats that exercised spontaneously by running (in wheel cage) up to 4-6 mi/day for 36 +/- 4 days and in sedentary controls kept in standard cages. Perifusion of islets with 4 mM glucose resulted in comparable rates of insulin release from islets obtained from trained and sedentary control rats. In contrast, when the perifusion glucose concentration was raised to 10 mM, the biphasic increase in insulin release was 40-50% lower in the trained rats as compared with untrained rats. This decrease in glucose-stimulated insulin release occurred in the face of comparable rates of glucose utilization by islets from control and trained rats. Glucose phosphorylation by liver homogenates from trained rats was reduced at all concentrations of glucose examined (0.5-100 mM). The calculated glucokinase activity was diminished by 40%, whereas hexokinase activity was decreased by 15% in the livers from trained rats. We conclude that 1) hypoinsulinemia induced by exercise training is due to decreased sensitivity of the beta-cell to the stimulant action of glucose independent of changes in islet cell utilization of glucose, and 2) exercise training results in a diminution of liver glucokinase activity that may be a consequence of the hypoinsulinemia.

Induction of lipogenic enzymes in primary cultures of rat hepatocytes. Relationship between lipogenesis and carbohydrate metabolism

Using primary cultures of adult rat hepatocytes, the regulation of the following lipogenic enzymes was studied: glucose-6-phosphate dehydrogenase, malic enzyme, ATP-citrate lyase, acetyl-CoA carboxylase, fatty acid synthetase, and stearoyl-CoA desaturase. The addition to the culture medium of either insulin or triiodothyronine produced a 2-3-fold increase in each of the individual enzyme activities whereas glucagon slightly decreased enzyme activities. The addition to the medium of 8-bromoguanosine 3,'5'-monophosphate had no effect on any of the enzyme activities unless glucose was also added to the culture medium. Glucose addition alone to the culture medium was without any effect; however, glucose enhanced the stimulation of enzyme activity due to insulin. The addition of fructose or glycerol, even in the absence of insulin, increased the activities of each of the enzymes studied 2-3-fold. The increases in enzyme activity brought about by insulin or fructose were apparently the result of de novo enzyme synthesis, as indicated by the observation that the increases were not noted in the presence of cordycepin or cycloheximide. Immunoprecipitation of ATP-citrate lyase from hepatocytes pulse-labeled with [3H]leucine indicated that the induction of this enzyme in response to the addition of fructose or glycerol to the culture medium was the result of an increase in the rate of synthesis of the enzyme. These results indicate that the activity and synthesis of individual enzymes involved in lipogenesis are increased in response to the metabolism of carbohydrate independently in part from hormonal effects.

The induction of synthesis of L-type pyruvate kinase in cultured rat hepatocytes

Hepatocytes were isolated from preweaned neonatal and adult rats and maintained in primary monolayer culture. Cells from preweaned newborns possessed no L-type pyruvate kinase, nor did they synthesize the enzyme. Incubation for 48-72 h in culture medium supplemented with 2 mM-fructose and 0.1 microM-insulin induced the synthesis of L-type pyruvate kinase, as judged by increased enzyme activity and the increased incorporation of [3H]leucine into immunoprecipitable L-type pyruvate kinase. Hepatocytes isolated from 48 h-starved adult rats incorporated less [3H]leucine into L-type pyruvate kinase than did cells isolated from high-carbohydrate-diet-fed rats. The rate of enzyme synthesis by cells from 48 h-starved rats was increased by the inclusion of fructose and insulin in the incubation medium, after a lag phase of 24-48 h. After 4 days in culture in the presence of fructose and insulin, hepatocytes from 48 h-starved rats synthesized L-type pyruvate kinase at similar rates to hepatocytes isolated from high-carbohydrate-diet-fed rats.

Biogenesis of the mitochondrial enzyme, carbamyl phosphate synthetase. Appearance during fetal development of rat liver an rapid repression in freshly dispersed hepatocytes

Synthesis of carbamyl phosphate synthetase was undetectable in fetal rat liver at 16 days gestation but by 4-5 days after birth (11-12 days later), this single protein accounted for approx. 5% of total liver protein and roughly 1% of total liver protein synthesis. Likewise, translatable mRNA coding for the enzyme was absent from 16-day fetal livers but then rapidly accumulated reaching maximum levels just after birth. The in vitro primary translation product of carbamyl phosphate synthetase mRNA corresponded to a higher molecular weight biosynthetic precursor of the enzyme; peptide maps obtained from the precursor synthesized both in vivo and in vitro and from the mature enzyme made in vivo were the same. When livers of neonatal rats were perfused with collagenase and further treated to yield a preparation of freshly dispersed hepatocytes highly active in general protein synthesis, a procedure which took about 45 min to complete, biosynthesis of carbamyl phosphate synthetase was found to be completely absent in these cells. The mRNA coding for the enzyme, however, could be extracted from the dispersed hepatocytes and was actively translatable in vitro, at levels approximately 75% of those for mRNA obtained from intact liver. Repression of biogenesis of carbamyl phosphate synthetase in dispersed hepatocytes, therefore, must involve a mechanism which shifts the mRNA coding for the enzyme out of active polysomal complexes and renders it further untranslatable in vivo but not in vitro.