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.     

Anabolic regulation of gluconeogenesis by insulin in isolated rat hepatocytes

The role of substrate availability in the regulation of gluconeogenesis in isolated rat hepatocytes was studied using [U-14C]alanine as a tracer in the presence of different concentrations of L-alanine in the incubation medium. At low alanine concentrations (0.5 mM) insulin decreased the 14C incorporation into the glucose pool and increased the incorporation of tracer carbons into the protein and lipid pools and into CO2. The net radioactivity lost from the glucose pool was only a small percentage of the total increase in the activity of the protein, lipid, CO2, or glycogen pools, supporting the notion that the effect of insulin in diminishing gluconeogenesis is secondary to its effects on pathways using pyruvate. At higher concentrations of alanine (2.5, 5.0, and 10.0 mM) in the incubation medium insulin increased the movement of alanine carbons into protein and glucose. This suggests that at higher substrate concentrations the ability of the liver to synthesize proteins is overwhelmed and the pyruvate carbons are forced into the gluconeogenesis pathway. These results were further confirmed by using [U-14C]lactate. The increases in observed specific activity of glucose following insulin administration would not be possible if insulin acted by affecting the activity of any enzyme directly involved in the formation or utilization of pyruvate, most of which have been proposed as sites of insulin action. Data presented show that insulin "inhibits" gluconeogenesis by affecting a change in substrate availability.     

Inhibition of gluconeogenesis by 2,5-anhydro-D-mannitol in isolated rat hepatocytes

2,5-Anhydro-D-mannitol inhibited glucose synthesis, increased the pyruvate/phosphoenolpyruvate ratio and altered adenine nucleotide concentrations in hepatocytes isolated from fasted rats. The accumulations of 2,5-anhydro-D-mannitol 1,6-diphosphate, an allosteric activator of pyruvate kinase, and of ADP in treated hepatocytes can account for the increase in pyruvate/phosphoenolpyruvate ratio and the inhibition of glucose synthesis from lactate.     

Metabolism of adenosine through adenosine kinase inhibits gluconeogenesis in isolated rat hepatocytes

In isolated hepatocytes from fasted rats, 0.5 mM adenosine inhibited gluconeogenesis from glutamine, lactate and pyruvate. This inhibition was due to adenosine conversion through adenosine kinase. An increase in ketone body release was only observed in the presence of lactate or pyruvate, and the two phenomena (i.e. inhibition of gluconeogenesis and increased ketone-body release) were linked. With alanine, dihydroxyacetone or serine as substrates, adenosine did not change gluconeogenesis; however, its conversion through adenosine kinase also inhibited gluconeogenesis. With asparagine as substrate, 0.5 mM adenosine increased gluconeogenesis; this increase was due to adenosine conversion through adenosine deaminase. However, adenosine conversion through adenosine kinase inhibited gluconeogenesis from asparagine. Thus, whatever the substrate used, adenosine conversion through adenosine kinase inhibited gluconeogenesis. The inhibitory effect of adenosine on gluconeogenesis cannot be related to the decrease in Pi concentration and to the increase in ATP pool. Beside its effect on gluconeogenesis, adenosine inhibited ketogenesis measured without added substrate; adenosine conversion through adenosine kinase was also involved in the inhibition of ketogenesis.     

Kinetic analysis of short-term effects of alpha-agonists on gluconeogenesis in isolated rat hepatocytes

Isolated hepatocytes from fasted rats were perifused with glycerol as gluconeogenic substrate. Stimulation of gluconeogenesis with phenylephrine (10(-5) M) as alpha-adrenergic agonist consisted of two distinct phases. The first phase was a transient stimulation of gluconeogenesis and was accompanied by transient changes in cytosolic and mitochondrial redox state; this phase was abolished by the transaminase inhibitor aminooxyacetate. The second phase was a stable stimulation of less magnitude, without change in redox state and insensitive to addition of aminooxyacetate. It is concluded that the first phase is due to a transient enhancement of flux through the malate/aspartate shuttle and that the stable phase is probably due to a stimulation of mitochondrial glycerol-3-phosphate dehydrogenase and glycerol kinase.     

Mechanisms of increased gluconeogenesis from alanine in rat isolated hepatocytes after endurance training

This work aimed at further investigating the mechanisms by which liver gluconeogenic capacity from alanine is improved after training in rats, with an isolated hepatocyte model. Compared with controls in hepatocytes from trained rats incubated with gluconeogenic precursors (20 mM), the glucogenic flux (J(glucose)) was increased by 64% from alanine (vs. 21% for glycerol, 18% for lactate-pyruvate 10:1, and 10% for dihydroxyacetone). Maximal intracellular alanine accumulation capacity was also increased by 50%. Further experiments conducted on perifused hepatocytes showed that the putative adaptation at the level of the phosphoenolpyruvate-pyruvate cycle, which could be involved in the increased J(glucose) from lactate-pyruvate, was not involved in the increased J(glucose) from alanine after training. For alanine concentration higher than approximately 1 mM, an increased flux through alanine aminotransferase appeared responsible for the increased J(glucose). This could, in turn, depend on an increased supply of cytosolic 2-oxoglutarate because of the higher mitochondrial respiration observed in hepatocytes from trained rats and the activation of the malate-aspartate shuttle. At lower alanine concentration, the increase in J(glucose) appeared to be entirely due to the improved transport capacity.     

Effect of methylamalonic acid on gluconeogenesis in isolated rat and guinea-pig hepatocytes.

Gluconeogenesis from pyruvate, alanine, lactate and propionate was inhibited by methylmalonate in both rat and guinea-pig hepatocytes. The effect was dose-dependent. Gluconeogenesis from glycerol and xylitol was not affected.     

Aminooxyacetate inhibits gluconeogenesis by isolated chicken hepatocytes

Although the pathway for glucose synthesis from lactate in avian liver is not thought to involve transamination steps, inhibitors of transamination (aminooxyacetate and L-2-amino-4-methoxy-trans-3-butenoic acid) block lactate gluconeogenesis by isolated chicken hepatocytes. Inhibition of glucose synthesis from lactate by aminooxyacetate is accompanied by a large increase in the lactate-to-pyruvate ratio. Oleate largely relieves inhibition by aminooxyacetate and lowers the lactate-to-pyruvate ratio. In parallel studies with rat hepatocytes, oleate did not overcome aminooxyacetate inhibition of glucose synthesis. The ratios of lactate used to glucose formed were greater than 2 with both rat and chicken hepatocytes, were increased by aminooxyacetate, and were restored toward 2 by oleate. Thus, in the absence of oleate, lactate is oxidized to provide the energy needed to meet the metabolic demand of chicken hepatocytes. Excess cytosolic reducing equivalents generated by the oxidation of lactate to pyruvate are transferred from the cytosol to the mitosol by the malate-aspartate shuttle. Aminooxyacetate inhibits the shuttle and, consequently, glucose synthesis for want of pyruvate.     

Effects of glutathione depletion on gluconeogenesis in isolated hepatocytes

Glutathione-depleted hepatocytes, by incubation with diethylmaleate (DEM) or phorone (2,6-dimethyl-2,5-heptadiene-4-one), i.e., substrates of the GSH S-transferases (EC 2.5.1.18), showed rates of gluconeogenesis from various precursors significantly lower than controls; however the rate of glucose synthesis from fructose was similar to that of controls. Isolated hepatocytes from rats pretreated with those substrates 1 h before isolation to deplete hepatic glutathione (GSH) also showed a decrease of the rate of gluconeogenesis from lactate plus pyruvate. Incubation of hepatocytes with L-buthionine sulfoximine, a specific inhibitor of gamma-glutamyl-cysteine synthetase (EC 6.3.2.2), resulted in a decreased rate of gluconeogenesis from lactate plus pyruvate only when GSH values were lower than 1 mumol/g cells. Freeze-clamped livers from GSH-depleted rats showed a higher concentration of malate and glycerol 3-phosphate, indicating that GSH depletion probably affects phosphoenolpyruvate carboxykinase and glycerol-3-phosphate dehydrogenase activities. Several indicators of cell viability, such as lactate dehydrogenase leakage, malondialdehyde accumulation, ATP concentration, or urea synthesis from different precursors, were not affected by GSH depletion under the experimental conditions used here. Besides, the GSH/GSSG ratio remained unchanged in all cases.     

Pathway of gluconeogenesis from tagatose in rat hepatocytes

Hepatocytes from fasted rats were incubated with a combination of substrate levels of fructose plus tagatose, and either [3-¹⁴C]fructose or [3-¹⁴C]tagatose. The ¹⁴C distribution in the glucose formed was identical, suggesting that tagatose and fructose are metabolized by identical pathways. When these sugars were incubated separately, the rate of gluconeogenesis from tagatose was about half that from fructose.     

Epidermal-growth-factor stimulation of gluconeogenesis in isolated rat hepatocytes involves the inactivation of pyruvate kinase.

Preincubation of rat hepatocytes with EGF (epidermal growth factor) caused a stimulation of gluconeogenesis from alanine. The effect was maximal after preincubation of 20 min, and a half-maximal effect of EGF was obtained at 10 nM. EGF also stimulated gluconeogenesis from lactate and asparagine, but not from glutamine or from proline. Preincubation of hepatocytes with EGF caused a stable inactivation of pyruvate kinase, which may account, at least in part, for the observed effects of EGF on gluconeogenesis.     

Iron mobilization from isolated hepatocytes

It is not known which message and mechanism triggers the cell to mobilize iron from ferritin. In this paper we present the results of incubation experiments with 59Fe-labelled hepatocytes. Anemic serum gives a significant higher rate of iron mobilization than normal serum. The involvement of apo-transferrin is ruled out because it did not increase iron mobilization. Citrate increased iron mobilization which is not the result of an increase in NADH/NAD+-ratio because addition of ethanol did not stimulate iron mobilization. Desferrioxamine is used clinically in iron overloaded patients and it is known that iron removal is a very slow process. Although desferrioxamine can mobilize iron from ferritin in hepatocytes, a considerable amount remains inside the cell as a low molecular weight fraction. This fraction represents chelator bound iron and is slowly released into the circulation.     

Interrelationship between drug oxidation ureogenesis and gluconeogenesis in isolated hepatocytes

1. The effect of increased ureogenesis--provoked by NH4Cl and ornithine--on gluconeogenesis and aminopyrine oxidation was studied in isolated hepatocytes prepared from 24 hr starved mice; lactate or fructose was used as gluconeogenic precursor. 2. Increased ureogenesis caused about 40% inhibition both on aminopyrine oxidation and gluconeogenesis when lactate was added as gluconeogenic substrate. 3. On the other hand, only 10% inhibition of aminopyrine oxidation and about 15% inhibition of gluconeogenesis were observed when fructose was used as gluconeogenic precursor. 4. Aminopyrine has been reported to inhibit gluconeogenesis from fructose by 30% and from lactate by 85%. The inhibitory effect of the combined addition of aminopyrine, NH4Cl and ornithine on gluconeogenesis was also dependent on the applied gluconeogenic precursor. 5. The provoked ureogenesis by ammonia and ornithine was not inhibited by aminopyrine. N6, O2-dibutyryl cAMP known to cause an increase of gluconeogenesis a decrease of aminopyrine oxidation enhanced the inhibitory action of increased ureogenesis on aminopyrine oxidation and on gluconeogenesis further. 6. The role of NADPH in the regulation of drug oxidation and ureogenesis is underlined.     

Studies on gluconeogenesis and protein synthesis in isolated hepatocytes.

Glucose production was studied in isolated hepatocytes using various substrates and with increasing substrate concentrations (0-10 mM). Fructose was the best gluconeogenic substrate while other substrates studied stimulated net glucose production in the following decreasing order: lactate, pyruvate, glycerol, galactose, alanine, and succinate. Studies on oxygen consumption showed that endogenous respiration was linear for 60 min and was not altered by extracellular calcium. Studies on the incorporation of 14C-leucine into protein was linear for only 3-4 hr in cells containing low glycogen. However, cells containing high glycogen incorporated 14C-leucine into protein linearly for 8-10 hr. About 3 mg of protein per g per hr was synthesized by isolated cells when incubated for 4 hr with amino acids mixture, glucose, lactate, and insulin.     

Effect of selenium deficiency and vitamin E deficiency on glutathione metabolism in isolated rat hepatocytes

Selenium deficiency and vitamin E deficiency both affect xenobiotic metabolism and toxicity. In addition, selenium deficiency causes changes in the activity of some glutathione-requiring enzymes. We have studied glutathione metabolism in isolated hepatocytes from selenium-deficient, vitamin E-deficient, and control rats. Cell viability, as measured by trypan blue exclusion, was comparable for all groups during the 5-h incubation. Freshly isolated hepatocytes had the same glutathione concentration regardless of diet group. During the incubation, however, the glutathione concentration in selenium-deficient hepatocytes rose to 1.4 times that in control hepatocytes. The selenium-deficient cells also released twice as much glutathione into the incubation medium as did the control cells. Total glutathione (intracellular plus extracellular) in the incubation flask increased from 47.7 +/- 8.9 to 152 +/- 16.5 nmol/10(6) selenium-deficient cells over 5 h compared with an increase from 46.7 +/- 7.1 to 92.0 +/- 17.4 nmol/10(6) control cells and from 47.7 +/- 11.7 to 79.5 +/- 24.9 nmol/10(6) vitamin E-deficient cells. This overall increase in glutathione concentration suggested that glutathione synthesis was accelerated by selenium deficiency. The activity of gamma-glutamylcysteine synthetase was twice as great in selenium-deficient liver supernatant (105,000 X g) as in vitamin E-deficient or control liver supernatant (105,000 X g). Hemoglobin-free perfused livers were used to determine the form of glutathione released and its route. Selenium-deficient livers released 4 times as much GSH into the caval perfusate as did control livers. Plasma glutathione concentration in selenium-deficient rats was found to be 2-fold that in control rats, suggesting that increased GSH synthesis and release is an in vivo phenomenon associated with selenium deficiency.     

Stimulatory effect of the intestinal peptide PHI on glycogenolysis and gluconeogenesis in isolated rat hepatocytes.

The newly isolated peptide PHI provoked a dose-dependent stimulation of glycogenolysis and gluconeogenesis in isolated rat hepatocytes; at 1 microM-PHI, both processes were increased 1.6-fold as compared with basal values. These PHI-mediated effects were accompanied by the activation of glycogen phosphorylase and the inactivation of pyruvate kinase. PHI (1 microM) also caused a 2-fold increase in hepatocyte cyclic AMP.     

A multichannel perifusion system for the continuous monitoring of glycogenolysis and gluconeogenesis in isolated rat hepatocytes

A multichannel perifusion system for isolated rat hepatocytes entrapped in a Sephadex matrix is described and criteria for the choice of matrices are discussed. This system overcomes the usual problem of clogged filters and impaired flow rates encountered in suspension perifusion systems, and is assembled from standard widely available components. Gluconeogenic capability and mitochondrial respiratory control ratios were unaltered. Decreases in trypan blue viability index and respiration rate were small when compared with flask-incubated hepatocytes. The endogenous rate of glycogenolysis was slightly higher in perifused hepatocytes but hormone response, as judged by glucagon stimulation of glycogenolysis, was unimpaired. The potential of this system is indicated by experiments monitoring glycogenolysis and gluconeogenesis in recycling and non-recycling modes.