Regulation of the expression of the phosphoenolpyruvate carboxykinase gene in cultured rat hepatocytes by glucagon and insulin

The induction of phosphoenolpyruvate carboxykinase (PEPCK) by glucagon was studied in primary rat hepatocyte cultures by determining the time course of the sequential events, increases in the enzyme's mRNA abundance, synthesis rate, amount and activity, and by investigating the antagonistic action of insulin on the induction by glucagon. 1. The mRNA of PEPCK was induced maximally 2-3 h after addition of 10 nM glucagon, as detected by Northern-blot analysis after hybridization with a biotinylated antisense RNA of PEPCK. 2. The synthesis rate of PEPCK increased maximally 2-3 h after application of glucagon as revealed by pansorbin-linked immunoprecipitation of [35S]methionine-labelled PEPCK. 3. The enzyme amount and activity was maximally induced 4 h after glucagon application. 4. The mRNA of PEPCK was half-maximally induced by 0.1 nM and maximally by 1 nM and 10 nM glucagon. The half-maximal induction by 0.1 nM glucagon was antagonized almost totally, and the maximal induction by 1 nM glucagon partially, while the maximal induction by 10 nM glucagon remained unaffected by 10 nM insulin. The results show that in cultured rat hepatocytes physiological concentrations of glucagon stimulated the induction of PEPCK by an increase in mRNA, that the glucagon-dependent increase in mRNA and enzyme-synthesis rate occurred in parallel and preceded the increase of enzyme amount and activity by 1-1.5 h, and that physiological levels of insulin antagonized the induction by glucagon in the physiological concentration range, with glucagon being the dominant hormone.     

The role of phosphatidylinositol 3-kinase, Src kinase, and protein kinase A signaling pathways in insulin and glucagon regulation of CYP2E1 expression

The signaling pathways involved in insulin and glucagon regulation of CYP2E1 expression were examined in primary cultured rat hepatocytes. Insulin addition to primary cultured rat hepatocytes for 24 h resulted in an approximately 80% and >90% decrease in CYP2E1 mRNA levels at 1 and 10 nM insulin, respectively, relative to untreated cells. Addition of the phosphatidylinositol 3-kinase inhibitor wortmannin, or the Src kinase inhibitor geldanamycin, prior to insulin addition, inhibited the insulin-mediated decline in CYP2E1 mRNA. In contrast, treatment of cells with glucagon (100 nM), or the cAMP analogue dibutyryl-cAMP (50 microM), for 24 h increased CYP2E1 mRNA levels by approximately 7-fold. Addition of the protein kinase A inhibitor H89 prior to glucagon treatment attenuated the glucagon-mediated increase in CYP2E1 mRNA by approximately 70%. Glucagon (100 nM) opposed the effects of insulin (1 nM) on CYP2E1 mRNA expression and conversely, insulin blocked the effects of glucagon. These data provide compelling evidence for the regulation of CYP2E1 expression via mutually antagonistic signaling pathways involving insulin and glucagon.     

A phospho-oligosaccharide mimics insulin action on glycogen phosphorylase and pyruvate kinase activities in isolated rat hepatocytes

A phospho-oligosaccharide which is the polar head group of a novel insulin-sensitive glycophospholipid has recently been involved in insulin action. We have investigated the insulin-like effects of this phospho-oligosaccharide on both glycogen phosphorylase a and pyruvate kinase activities of hepatocytes incubated in the presence of glucagon (0.1 nM). Similarly to insulin, the phospho-oligosaccharide antagonized glucagon-dependent activation of glycogen phosphorylase, as well as the inactivation of pyruvate kinase caused by this hormone. The antagonistic action of the phospho-oligosaccharide on glucagon effects was dose-dependent. Furthermore, it partially antagonized glucagon-stimulated cyclic AMP levels. These results support the hypothesis that this phospho-oligosaccharide mediates at least some insulin actions in hepatocytes.     

Dominant role of glucagon in the initial induction of phosphoenolpyruvate carboxykinase mRNA in cultured hepatocytes from fetal rats.

The injection of streptozotocin to 18-day-old rat fetuses induced, 2 days later, a 50% fall in plasma insulin and a twofold increase in plasma glucagon concentrations and liver cAMP levels. Phosphoenolpyruvate carboxykinase mRNA that were undetectable in the fetal rat liver, accumulated 48 h after streptozotocin injection, their concentration being 30% of that found in the liver of 1-day-old newborn rats in whom liver phosphoenolpyruvate carboxykinase gene expression is maximal. Physiological concentrations of glucagon (0.7 +/- 0.2 nM) induced, within 2 h, phosphoenolpyruvate carboxykinase mRNA accumulation in cultured hepatocytes from 20-day-old fetuses. The addition of insulin (0.01-100 nM) inhibits, by no more than 30%, the glucagon-induced phosphoenolpyruvate carboxykinase mRNA accumulation. Exposure of fetal hepatocytes to insulin for 24 h did not change the glucagon dose/response curve and did not lead to a more efficient inhibition of the glucagon-induced phosphoenolpyruvate carboxykinase mRNA accumulation, despite a clear stimulatory effect on the rate of lipogenesis. In contrast, when hepatocytes were cultured in the presence of dexamethasone, the glucagon-induced phosphoenolpyruvate carboxykinase mRNA accumulation can be totally inhibited by pharmacological concentrations of insulin (10 nM). From these in-vivo and in-vitro studies, it is concluded that, under physiological conditions, the postnatal rise in plasma glucagon concentration is more important than the fall in the plasma insulin concentration for the primary induction of liver phosphoenolpyruvate carboxykinase gene expression.     

Role of cortisol on the glycogenolytic effect of glucagon and on the glycogenic response to insulin in fetal hepatocyte culture.

The effects of insulin and glucagon on glycogen metabolism were studied in cultured fetal hepatocytes transplanted from 15-day-old fetuses. The effects of these hormones were examined just after transplantation, when the cells contained only minute amounts of glycogen, and during the 3 to 4 day culture period, when the hepatocytes were exposed to 10 muM cortisol and actively accumulated glycogen. At all stages of the culture, glucagon addition (10 nM) was followed by a rapid depletion of labeled glycogen, previously synthesized during a pulse labeling with [14C]glucose: this effect was mimicked by N6, O2'-dibutyryl adenosine 3':5'-monophosphate (dibutyryl cyclic AMP) (0.3 to 1 nM). Such a glycogenolytic effect of glucagon was observed even 6 hours after transplantation, i.e. at a time when cortisol was not present. In addition, glucagon clearly induced cyclic adenosine 3':5'-monosphosphate (cyclic AMP) accumulation in cells grown for 18 hours in the absence of cortisol. With cells grown for 3 days in the presence of cortisol, glucagon-dependent glycogenolysis was also obtained when cortisol was removed from the medium 20 hours before hormone addition. Thus the presence of cortisol is not necessary either to maintain a response to glucagon or for the onset of the glycogenolytic effect of glucagon. Insulin addition (10 nM) stimulated [14C]glucose incorporation into glycogen at all stages of the culture when grown in the presence of cortisol; no glycogenic response to insulin was observed 6 hours after transplantation where cortisol was not previously introduced. In addition, if the hepatocytes were grown in the presence of insulin alone (i.e. in the absence of cortisol) no significant storage of glycogen occurred. Maximal storage (or labeling) of glycogen was observed when hepatocytes were grown in the presence of both cortisol and insulin. The presence of cortisol was therefore necessary for the expression of the glycogenic effect of insulin. These data show that marked difference exist between the onset of developmental responses towards glucagon and insulin. The glucagon-dependent regulatory pathway should be present very early in fetal development and should not depend on cortisol. On the contrary, the onset of the insulin-dependent regulatory pathway seems to be induced during culture, and it is likely that this is caused by cortisol.     

Insulin suppresses hepatitis B surface antigen expression in human hepatoma cells

The human hepatoma Hep3B cells contain integrated hepatitis B viral genome and continually secret hepatitis B surface antigen (HBsAg). The production of HBsAg (but not alpha-fetoprotein) was suppressed by addition of low concentrations (0.1-1 nM) of insulin into serum-free medium. In addition, the suppression of HBsAg production by insulin was paralleled with the decrease in HBsAg mRNA abundance. Insulin also cause a rapid rate of disappearance of HBsAg mRNA (t 1/2, 2 h) in Hep3B cells. The Hep3B cells carry specific receptor with high affinity for insulin (Kd = 1.8 nM). The receptor showed an insulin-dependent protein tyrosine kinase activity. The half-maximal insulin concentration for the activation of the receptor kinase was about 5 nM. Only very high concentrations of insulin-like growth factor I and human proinsulin can compete for the insulin receptor binding and suppress HBsAg production, this suggests that insulin may act through its receptor binding to suppress HBsAg expression in human hepatoma Hep3B cells.     

Acute and chronic regulation of phosphoenolpyruvate carboxykinase mRNA by insulin and glucose

Using the well differentiated rat hepatoma Fao we have studied the regulation of phosphoenolpyruvate carboxykinase (PEPCK) mRNA by insulin and glucose and compared these results to glucose production as estimated by glucose release into the medium. Fao cells possess an active gluconeogenic pathway and, when grown in glucose-free medium, release glucose for over 8 h. Addition of the cAMP analog, 8-(4-chlorophenyl-thio) cAMP (8-CTP-cAMP) or increasing the concentration of dihydroxyacetone and oxaloacetate results in an increase in glucose release which can be suppressed by insulin at concentrations between 1 and 100 nM. These effect of cAMP and insulin are associated with parallel changes in the level of mRNAPEPCK. Insulin treatment reduces mRNAPEPCK levels in these cells by 80%; this effect is transient reaching a maximum at 2-4 h. Addition of glucose to cells grown in glucose-free (G-) medium produces a decrease in mRNAPEPCK which is similar in magnitude and kinetics to that produced by insulin. Conversely, when cells grown in normal medium are placed in G- medium mRNAPEPCK levels triple over a period of 8 h, then return toward the basal value. Cells grown in G- medium or in G- medium plus 10nM insulin for 1 yr exhibit only slightly increased levels of mRNAPEPCK and respond to both 8-CTP-cAMP, and insulin, although the response to 8-CTP-cAMP is slightly blunted. These data indicate that glucose and insulin can play independent roles in regulation of PEPCK gene expression, and that these regulatory effects are usually transient.     

Hormonal control of cyclic 3':5'-AMP levels and gluconeogenesis in isolated hepatocytes from fed rats.

Glucagon can stimulate gluconeogenesis from 2 mM lactate nearly 4-fold in isolated liver cells from fed rats; exogenous cyclic adenosine 3':5'-monophosphate (cyclic AMP) is equally effective, but epinephrine can stimulate only 1.5-fold. Half-maximal effects are obtained with glucagon at 0.3 nM, cyclic AMP at 30 muM and epinephrine at 0.2 muM. Insulin reduces by 50% the stimulation by suboptimal concentrations of glucagon (0.5 nM). A half-maximal effect is obtained with 0.3 nM insulin (45 microunits/ml). Glucagon in the presence of theophylline (1 mM) causes a rapid rise and subsequent fall in intracellular cyclic AMP with a peak between 3 and 6 min. Some of the fall can be accounted for by loss of nucleotide into the medium. This efflux is suppressed by probenecid, suggesting the presence of a membrane transport mechanism for the cyclic nucleotide. Glucagon can raise intracellular cyclic AMP about 30-fold; a half-maximal effect is obtained with 1.5 nM hormone. Epinephrine (plus theophylline, 1 mM) can raise intracellular cyclic AMP about 2-fold; the peak elevation is reached in less than 1 min and declines during the next 15 min to near the basal level. Insulin (10 nM) does not lower the basal level of cyclic AMP within the hepatocyte, but suppresses by about 50% the rise in intracellular and total cyclic AMP caused by exposure to an intermediate concentration of glucagon. No inhibition of adenylate cyclase by insulin can be shown. Basal gluconeogenesis is not significantly depressed by calcium deficiency but stimulation by glucagon is reduced by 50%. Calcium deficiency does not reduce accumulation of cyclic AMP in response to glucagon but diminishes stimulation of gluconeogenesis by exogenous cyclic AMP. Glucagon has a rapid stimulatory effect on the flux of 45Ca2+ from medium to tissue.     

Inhibition of acetyl-CoA carboxylase activity in isolated rat adipocytes incubated with glucagon. Interactions with the effects of insulin, adrenaline and adenosine deaminase

1. Adipocytes isolated from epididymal fat-pads of fed rats were incubated with different concentrations of glucagon, insulin, adrenaline and adenosine deaminase, and the effects of these agents on the ;initial' activity of acetyl-CoA carboxylase in the cells were studied. 2. Glucagon (at concentrations between 0.1 and 10nm) inhibited acetyl-CoA carboxylase activity. Maximal inhibition was approx. 70% of the ;control' activity in the absence of added hormone, and the concentration of hormone required for half-maximal inhibition was 0.3-0.5nm-glucagon. 3. Incubation of cells with adenosine deaminase resulted in a similar inhibition of acetyl-CoA carboxylase activity. Preincubation of adipocytes with adenosine deaminase did not alter either the sensitivity of carboxylase activity to increasing concentrations of glucagon or the maximal extent of inhibition. 4. Adrenaline inhibited acetyl-CoA carboxylase to the same extent as glucagon. Preincubation of the cells with glucagon did not alter the sensitivity of enzyme activity to adrenaline or the degree of maximal inhibition. 5. Insulin activated the enzyme by 70-80% of ;control' activity. Preincubation of the cells with glucagon did not alter the concentration of insulin required to produce half the maximal stimulatory effect (about 12muunits of insulin/ml). The effects of insulin and glucagon appeared to be mediated completely independently, and were approximately quantitatively similar but opposite. These characteristics resulted in the mutual cancellation of the effects of the two hormones when they were both present at equally effective concentrations. 6. The implications of these findings with regard to current concepts about the mechanism of regulation of acetyl-CoA carboxylase and to the regulation of the enzyme in vivo are discussed.     

The glucagon-insulin antagonism and glucagon-dexamethasone synergism in the induction of phosphoenolpyruvate carboxykinase in cultured rat hepatocytes

In hepatocytes precultured for 24 h with dexamethasone glucagon increased phosphoenolpyruvate carboxykinase activity 3-4-fold with a half maximal activity increase at 30 pM. The half maximal effective glucagon concentration was enhanced 10-fold to 300 pM when insulin was added simultaneously. The glucagon-insulin antagonism was maximally expressed when glucagon was present at low physiological concentrations. At equimolar doses it was only in the concentration range around 0.1 nM that glucagon and insulin became powerful antagonists; at higher levels glucagon was the dominant hormone. In hepatocytes not pretreated with dexamethasone glucagon still enhanced phosphoenolpyruvate carboxykinase activity, but the half maximal effective dose raised more than 30-fold to 1 nM. The degree of stimulation, however, remained essentially unchanged. Thus dexamethasone shifted the glucagon sensitivity of the cells into the physiological concentration range; it exerted a half maximal effect at 10 nM. Dexamethasone was not required for the enzyme induction proper if the cells had been pretreated with the glucocorticoid. The amount of the glucagon-stimulated enzyme induction was dependent on the time period of cell pretreatment with dexamethasone. Glucagon enhanced enzyme activity to the same constant suboptimal level irrespective of whether cells had been pretreated with glucocorticoid for 1 or for 14 h. If cells were pretreated for more than 15 h, glucagon linearly increased enzyme activity further until the maximal value was reached after 24 h pretreatment. The glucagon-insulin antagonism and the glucagon-glucocorticoid synergism were observed at physiological hormone concentrations indicating that the interaction should be effective also in vivo. Dexamethasone does not seem to be generally permissive for the inducing action of glucagon, but rather sensitizes the cell towards lower physiological hormone concentrations.     

The heterotopic effects of insulin and glucagon on the acinar activity pattern of phosphoenolpyruvate carboxykinase in male and female rat liver

The effects of the administration of insulin and glucagon on the intraacinar heterotopy of phosphoenolpyruvate carboxykinase (PEPCK) were investigated in male and female rat liver. Insulin did not noticeably influence PEPCK activity or its acinar distribution, either in males or in females. But it affected the activities of glucose-6-phosphate dehydrogenase and malic enzyme. Glucagon in supraphysiological concentrations led to an induction of PEPCK activity. Despite high glucagon concentration along the whole sinusoidal length, the inducing effect of glucagon was most pronounced in the periportal and intermediary parts of the acinus; thus indicating that there is no direct interrelationship between local glucagon concentration and PEPCK activity. In both experiments blood glucose levels were kept fairly constant.     

Regulation by insulin of gluconeogenesis in isolated rat hepatocytes.

Insulin (10nM) completely suppressed the stimulation of gluconeogenesis from 2 mM lactate by low concentrations of glucagon (less than or equal to 0.1 nM) or cyclic AMP (less than or equal to 10 muM), but it had no effect on the basal rate of gluconeogenesis in hepatocyctes from fed rats. The effectiveness of insulin diminished as the concentration of these agonists increased, but insulin was able to suppress by 40% the stimulation by a maximally effective concentration of epinephrine (1 muM). The response to glucagon, epinephrine, or insulin was not dependent upon protein synthesis as cycloheximide did not alter their effects. Insulin also suppressed the stimulation by isoproterenol of cyclic GMP. These data are the first demonstration of insulin antagonism to the stimulation of gluconeogenesis by catecholamines. Insulin reduced cyclic AMP levels which had been elevated by low concentrations of glucagon or by 1 muM epinephrine. This supports the hypothesis that the action of insulin to inhibit gluconeogenesis is mediated by the lowering of cyclic AMP levels. However, evidence is presented which indicates that insulin is able to suppress the stimulation of gluconeogenesis by glucagon or epinephrine under conditions where either the agonists or insulin had no measurable effect on cyclic AMP levels. Insulin reduced the glucagon stimulation of gluconeogenesis whether or not extracellular Ca2+ were present, even though insulin only lowered cyclic AMP levels in their presence. Insulin also reduced the stimulation by epinephrine plus propranolol where no significant changes in cyclic AMP were observed without or with insulin. In addition, insulin suppressed gluconeogenesis in cells that had been preincubated with epinephrine for 20 min, even though the cyclic AMP levels had returned to near basal values and were unaffected by insulin. Thus insulin may not need to lower cyclic AMP levels in order to suppress gluconeogenesis.     

Induction in primary culture of 'gluconeogenic' and 'glycolytic' hepatocytes resembling periportal and perivenous cells

Adult rat hepatocytes were kept in primary culture for 48 h under different hormonal conditions to induce an enzyme pattern which with respect to carbohydrate metabolism approximated that of periportal and perivenous hepatocytes in vivo. 1. Glucagon-treated cells compared with control cells possessed a lower activity of glucokinase, a 4.5-fold higher activity of phosphoenolpyruvate carboxykinase and unchanged levels of glucose-6-phosphatase, phosphofructokinase, fructose-bisphosphatase and pyruvate kinase; they resembled in a first approximation the periportal cell type and are called for simplicity 'periportal'. Inversely, insulin-treated cells compared with control cells contained a 2.2-fold higher activity of glucokinase, a slightly decreased activity of phosphoenolpyruvate carboxykinase, increased activities of phosphofructokinase and pyruvate kinase and unaltered levels of glucose-6-phosphatase and fructose-bisphosphatase; they resembled perivenous cells and are called simply 'perivenous'. Gluconeogenesis and glycolysis were studied under various substrate and hormone concentrations. 2. Physiological concentrations of glucose (5 mM) and lactate (2 mM) gave about 80% saturation of gluconeogenesis from lactate and less than 15% saturation of glycolysis at a simultaneous 40% inhibition of the glycolytic rate by lactate. 3. Comparison of the two cell types showed that under identical assay conditions (5 mM glucose, 2 mM lactate, 0.5 nM insulin, 0.1 muM dexamethasone) gluconeogenesis was 1.5-fold faster in the 'periportal' cells and glycolysis was 2.4-fold faster in the 'perivenous' cells. 4. Metabolic rates were under short-term hormonal control. Insulin increased glycolysis three fold in both cell types with a half-maximal effect at about 0.4 nM, but did not influence the gluconeogenic rate. Glucagon inhibited glycolysis by 70% with a half-maximal effect at about 0.1 nM. Gluconeogenesis was stimulated by glucagon (half-maximal dose: 0.5 nM) 1.8-fold only in 'periportal' cells containing high phosphoenolpyruvate carboxykinase activity, not in the 'perivenous' cells with a low level of this enzyme. 5. A comparison of the two cell types showed that with maximally stimulating hormone concentrations gluconeogenesis was threefold faster in 'periportal' cells and glycolysis was eightfold faster in 'perivenous' cells. The results support the view that periportal and perivenous hepatocytes in vivo catalyse gluconeogenesis and glycolysis at inverse rates.     

Inhibition by insulin of glucagon-dependent phospholipid methyltransferase phosphorylation in rat hepatocytes

Addition of insulin to isolated rat hepatocytes prelabeled with [32P]phosphate inhibited glucagon-dependent phospholipid methyltransferase phosphorylation and activation. Insulin alone had no effect on either the phosphorylation of the enzyme or on its activity. The effect of insulin on glucagon-dependent phospholipid methyltransferase phosphorylation was dose-dependent and occurred at physiological doses of the hormone (10(-11)-10(-10) M). Analysis of 32P-labeled peptides after digestion with trypsin revealed only one site of phosphorylation regulated by glucagon (10(-8) M) in isolated rat hepatocytes. This site, as analyzed by HPLC and thin-layer chromatography, coincided with that phosphorylated by the cAMP-dependent protein kinase using purified rat liver phospholipid methyltransferase.