Sphingomyelinase treatment of rat hepatocytes inhibits cell-swelling-stimulated glycogen synthesis by causing cell shrinkage.

Breakdown of plasma-membrane sphingomyelin caused by TNF-alpha is known to inhibit glucose metabolism and insulin signalling in muscle and fat cells. In hepatocytes, conversion of glucose to glycogen is strongly activated by amino acid-induced cell swelling. In order to find out whether breakdown of plasma-membrane sphingomyelin also inhibits this insulin-independent process, the effect of addition of sphingomyelinase was studied in rat hepatocytes. Sphingomyelinase (but not ceramide) inhibited glycogen synthesis, caused cell shrinkage, decreased the activity of glycogen synthase a, but had no effect on phosphorylase a. Cell integrity was not affected by sphingomyelinase addition as gluconeogenesis and the intracellular concentration of ATP were unchanged. As a control, glycogen synthesis was studied in HepG2 cells. In these cells, the basal rate of glycogen production was high, could not be stimulated by amino acids, nor be inhibited by sphingomyelinase. Regarding the mechanism responsible for the inhibition of glycogen synthase a, sphingomyelinase did not affect amino acid-induced, PtdIns 3-kinase-dependent, phosphorylation of p70S6 kinase, but caused an increase in intracellular chloride, which is known to inhibit glycogen synthase phosphatase. It is concluded that the decrease in cell volume, following the breakdown of sphingomyelin in the plasma membrane of the hepatocyte, may contribute to the abnormal metabolism of glucose when TNF-alpha levels are high.

Nitric oxide inhibits glycogen synthesis in isolated rat hepatocytes.

There is increasing evidence for the existence of intrahepatic regulation of glucose metabolism by Kupffer cell products. Nitric oxide (NO) is known to inhibit gluconeogenic flux through pyruvate carboxylase and phosphoenolpyruvate carboxykinase. However, NO may also influence glucose metabolism at other levels. Using hepatocytes from fasted rats incubated with the NO-donor S-nitroso-N-acetylpenicillamine, we have now found that the synthesis of glycogen from glucose is even more sensitive to inhibition by NO than gluconeogenesis. Inhibition of glycogen production by NO was accompanied by a rise in intracellular glucose 6-phosphate and UDPglucose. Activity of glycogen synthase, as measured in extracts of hepatocytes after the cells had been exposed to NO, was decreased. Experiments with gel-filtered liver extracts revealed that inhibition of glycogen synthase was caused by an inhibitory effect of NO on the conversion of glycogen synthase b into glycogen synthase a.

Cell swelling and glycogen metabolism in hepatocytes from fasted rats.

Cell swelling is known to increase net glycogen production from glucose in hepatocytes from fasted rats by activating glycogen synthase. Since both active glycogen synthase and phosphorylase are present in hepatocytes, suppression of flux through phosphorylase may also contribute to the net increase in glycogen synthesis by cell swelling. We have developed an isotopic procedure to estimate the fluxes through glycogen synthase and phosphorylase in intact hepatocytes and we have examined the effect of cell swelling on both enzyme fluxes. The following observations were made. (1) Hypotonic or glutamine-induced cell swelling increased net glycogen production by activating flux through glycogen synthase with little effect on phosphorylase flux. Proline, previously shown to increase glycogen synthesis more than could be accounted for by its ability to cause cell swelling, increased flux through glycogen synthase and inhibited phosphorylase flux. (2) Incorporation of [14C]glucose into glycogen preceded complete mixing of [14C]glucose with the intracellular pool of UDPglucose. It is concluded that cell swelling affects glycogen synthase only and that UDPglucose is compartmentalized.

Phosphorylation of ribosomal protein S6 is inhibitory for autophagy in isolated rat hepatocytes.

In rat hepatocytes, autophagy is known to be inhibited by amino acids. Insulin and cell swelling promote inhibition by amino acids. Each of the conditions leading to inhibition of autophagic proteolysis was found to be associated with phosphorylation of a 31-kDa protein that we identified as ribosomal protein S6. A combination of leucine, tyrosine, and phenylalanine, which efficiently inhibits autophagic proteolysis, was particularly effective in stimulating S6 phosphorylation. The relationship between the percentage inhibition of proteolysis and the degree of S6 phosphorylation was linear. Thus, inhibition of autophagy and phosphorylation of S6 are under the control of the same signal transduction pathway. Stimulation of S6 phosphorylation by the presence of amino acids was due to activation of S6 kinase and not to inhibition of S6 phosphatase. The inhibition by amino acids of both autophagic proteolysis and autophagic sequestration of electro-injected cytosolic [14C]sucrose was partially prevented by rapamycin, a compound known to inhibit activation of p70 S6 kinase. In addition, rapamycin partially inhibited the rate of protein synthesis. We conclude that the fluxes through the autophagic and protein synthetic pathways are regulated in an opposite manner by the degree to which S6 is phosphorylated. Possible mechanisms by which S6 phosphorylation can cause inhibition of autophagy are discussed.

Carbamoyl phosphate and ureagenesis are not involved in amino-acid-stimulated glycogenesis.

Amino acids are known to stimulate glycogen synthesis via an increase in cell volume [Baquet, A., Hue, L., Meijer, A. J., van Woerkom, G. M. & Plomp, P. J. A. M. (1990) J. Biol. Chem. 265, 955-959]. It has recently been postulated, however, that carbamoyl phosphate, an intermediate of ureagenesis, can function as a substrate for glucose phosphorylation via carbamoyl-phosphate:glucose phosphotransferase activity of the glucose-6-phosphatase system. This hypothesis would account for the stimulation of glycogenesis by amino acids such as glutamine and proline [Bode, A. M. & Nordlie, R. C. (1993) J. Biol. Chem. 268, 16298-16301]. To further examine the role carbamoyl phosphate may play in glycogenesis, isolated hepatocytes were incubated under a variety of conditions to manipulate ureagenesis, glycogenesis and carbamoyl-phosphate levels. Our data indicate that carbamoyl-phosphate levels do not correlate with amino-acid-stimulated glycogenesis and that ureagenesis and glycogenesis are not competing metabolic pathways.

Cell swelling and the sensitivity of autophagic proteolysis to inhibition by amino acids in isolated rat hepatocytes.

In the isolated perfused rat liver, autophagic proteolysis is inhibited by hypo-osmotic perfusion media [Häussinger, D., Hallbrucker, C., vom Dahl, S., Lang, F. & Gerok, W. (1990) Biochem. J. 272, 239-242]. Here we report that in isolated hepatocytes, incubated in the absence of amino acids to ensure maximal proteolytic flux, proteolysis was not inhibited by hypo-osmolarity while the synthesis of glycogen from glucose, a process known to be very sensitive to changes in cell volume [Baquet, A., Hue, L., Meijer, A. J., van Woerkom, G. M. & Plomp, P. J. A. M. (1990) J. Biol. Chem. 265, 955-959], was stimulated under identical conditions. However, in isolated hepatocytes, hypo-osmolarity increased the sensitivity of autophagic proteolysis to inhibition by low concentrations of amino acids. The anti-proteolytic effect of hypo-osmolarity in our experiments was not due to stimulation of amino-acid transport into the hepatocytes: neither the consumption of most amino acids, nor the rate of urea synthesis was appreciably affected by hypo-osmotic incubation conditions. In the course of these studies we also found that hypo-osmolarity increased the affinity of protein synthesis for amino acids. In the presence of amino acids the intracellular level of ATP was not much affected. However, because of cell swelling under these conditions the intracellular concentration of ATP decreased. It is proposed that a small part of the inhibition of proteolysis by amino acids may be due to this fall in ATP concentration.

Mechanism of activation of liver glycogen synthase by swelling.

The mechanism linking the stimulation of liver glycogen synthesis to swelling induced either by amino acids or hypotonicity was studied in hepatocytes, in gel-filtered liver extracts, and in purified preparations of particulate glycogen to which glycogen-metabolizing enzymes are bound. High concentrations of KCl, but not of potassium glutamate, were found to inhibit glycogen synthesis in permeabilized hepatocytes. Similarly, physiological concentrations (30-50 mM) of Cl- ions were also found to inhibit synthase phosphatase in vitro, whereas 10-20 mM Cl- ions, a concentration found in swollen hepatocytes, did not inhibit synthase phosphatase. Synthase phosphatase activity was more sensitive to inhibition by Cl- ions at low (0.1%) than at high (1%) concentrations of glycogen. By contrast, 10 mM glutamate and aspartate, a concentration observed in hepatocytes incubated with glutamine or proline, stimulated synthase phosphatase in vitro. Therefore, it is proposed that the fall in intracellular Cl- concentration as well as the increase in intracellular glutamate and aspartate concentrations, that are observed in swollen hepatocytes in the presence of amino acids, are responsible, at least in part, for the stimulation of synthase phosphatase and, hence, of glycogen synthesis.

Swelling of rat hepatocytes stimulates glycogen synthesis.

In hepatocytes from fasted rats, several amino acids are known to stimulate glycogen synthesis via activation of glycogen synthase. The hypothesis that an increase in cell volume resulting from amino acid uptake may be involved in the stimulation of glycogen synthesis is supported by the following observations. 1) The extent of stimulation of glycogen synthesis by both metabolizable and nonmetabolizable amino acids was directly proportional to their ability to increase cell volume, except for proline, which stimulated glycogen synthesis more than could be accounted for by the increase in cell volume. 2) Both cell swelling and stimulation of glycogen synthesis by amino acids were prevented when hepatocytes were incubated in hyperosmotic media containing sucrose or raffinose. 3) Increasing the cell volume by incubating hepatocytes in Na(+)-depleted media in the absence of amino acids also stimulated glycogen synthesis. 4) Stimulation of glycogen synthesis by Na+ depletion was prevented by restoring the normal osmolarity with sucrose, but not with choline chloride which, by itself, stimulated glycogen synthesis and increased the cell volume. It is concluded that stimulation of glycogen synthesis by amino acids is due, at least in part, to an increase in hepatocyte volume resulting from amino acid uptake, and that hepatocyte swelling per se stimulates glycogen synthesis.

Turnover of N-acetylglutamate in isolated rat hepatocytes.

Isolated hepatocytes from starved rats were loaded with N-[14C]acetylglutamate by preincubating them with [14C]bicarbonate, oleate, NH3, ornithine and lactate. Turnover of N-acetylglutamate in these cells was subsequently measured in an unlabelled medium under conditions of minimal flux (oleate alone present) and maximal flux (oleate, NH3, ornithine and lactate present) through the urea cycle. 1. Direct measurement of the distribution of N-[14C]acetylglutamate across the mitochondrial membrane in the hepatocytes showed that, under the conditions studied, the rate of degradation of total intracellular N-[14C]acetylglutamate was about equal to the rate of efflux of N-acetylglutamate from the mitochondria. 2. In the presence of oleate alone, intramitochondrial N-acetylglutamate decreased because mitochondrial N-acetylglutamate efflux predominated over the synthesis of N-acetylglutamate in the mitochondria. 3. In the presence of oleate, NH3, ornithine and lactate both the rate of synthesis of N-acetylglutamate and the rate of its transport out of the mitochondria were increased when compared with the condition with oleate alone. However, the intramitochondrial concentration of N-acetylglutamate increased because initially the rate of its synthesis exceeded that of its efflux from the mitochondria. Finally, a steady state was reached in which both rates were equal. 4. The data indicate that in hepatocytes from starved rats N-acetylglutamate transport out of the mitochondria takes place at a rate proportional to its intramitochondrial concentration. It is concluded that transport of N-acetylglutamate either occurs by diffusion or is mediated by a transport system with a high Km for intramitochondrial N-acetylglutamate.

Transport of N-acetylglutamate in rat-liver mitochondria.

The permeability properties of the rat-liver mitochondrial membrane for N-acetylglutamate, the activator of carbamoyl-phosphate synthetase (ammonia), were studied. 1. Transport of N-acetylglutamate into the mitochondria was only observed in partially or fully de-energized mitochondria and when the extramitochondrial concentration was unphysiologically high (in the mM range). However, even under these conditions the intramitochondrial concentration of N-acetylglutamate was much lower than that outside. 2. Mitochondrial N-acetylglutamate efflux only occurs when the mitochondria are in an energized state. At 25 degrees C, at an intramitochondrial N-acetylglutamate concentration of 0.7-1.0 nmol/mg protein, efflux proceeds at a rate of about 0.05 nmol X min-1 X mg protein-1. This is 10-fold lower than the maximal rate of N-acetylglutamate synthesis in the mitochondria. 3. Homologous exchange between intramitochondrial N-[14C]acetylglutamate and extramitochondrial unlabelled N-acetylglutamate could not be demonstrated. 4. It is concluded that transport of N-acetylglutamate in vivo is effectively unidirectional, out of the mitochondria. This behaviour is in accordance with the physiological requirement for efflux of N-acetylglutamate from the mitochondria in order to be degraded in the cytosol.

Inhibition of Ca2+ of carbamoylphosphate synthetase (ammonia).

The effect of Ca2+ ions on carbamoylphosphate synthetase (ammonia) (EC 6.3.4.16) of rat liver mitochondria was studied. In lysed mitochondria, carbamoylphosphate synthetase (ammonia) was inhibited by Ca2+ ions. In intact rat liver mitochondria, the rate of citrulline production from added ammonia, ornithine, and bicarbonate was inversely correlated with the magnitude of the intramitochondrial concentration of Ca2+. This effect was found at concentrations of Ca2+ which are within the physiological range. The inhibition was reversed by added Mg2+ and was not due to effects of Ca2+ on mitochondrial energy production. It is proposed that the activity of carbamoylphosphate synthetase (ammonia) may be modulated in vivo by changes in the concentration of Ca2+ ions in the mitochondrial matrix.

Relationship between the rate of citrulline synthesis and bulk changes in the intramitochondrial ATP/ADP ratio in rat-liver mitochondria.

1. The relationship between intramitochondrial and extramitochondrial ATP-utilizing systems and the intramitochondrial ATP/ADP ratio was studied in isolated rat-liver mitochondria. Citrulline synthesis was used as an intramitochondrial ATP-utilizing system, and glucose-6-phosphate synthesis as an extramitochondrial ATP-utilizing system. The intramitochondrial ATP/ADP ratio was manipulated in three ways: with succinate and different concentrations of malonate and/or hexokinase; with 2-oxoglutarate (plus oligomycin) and different concentrations of hexokinase; and with added ATP in uncoupled mitochondria (oligomycin present). 2. Under all conditions used, citrulline synthesis was strictly correlated with the bulk intramitochondrial ATP/ADP ratio. 3. The curve relating citrulline synthesis and intramitochondrial ATP/ADP was shifted towards lower ATP/ADP ratios when the activity of carbamoyl-phosphate synthetase was enhanced by increasing the mitochondrial content of N-acetylglutamate. 4. It is concluded that under the experimental conditions used the intramitochondrial adenine nucleotides behave as a homogeneous pool.

Relationship between intramitochondrial citrate and the activity of carbamoyl-phosphate synthase (ammonia).

The possibility of control of the activity of carbamoyl-phosphate synthase (ammonia) (EC 2.7.2.5) in rat-liver mitochondria by variation in the intramitochondrial free Mg2+ concentration has been investigated. Carbamoyl-phosphate synthase activity was measured by coupling the formation of carbamoylphosphate to the synthesis of citrulline in a reaction mixture containing ammonia, bicarbonate, a source of ATP, and ornithine. The synthesis of citrulline was inhibited by lowering the concentration of intramitochondrial free Mg2+. This could be achieved not only by depleting the mitochondria of Mg2+ (by adding the ionophore A23187), but also by increasing the intramitochondrial concentration of citrate. Under various conditions an inverse relationship between the rate of citrulline synthesis and the magnitude of the intramitochondrial concentration of citrate was observed. Inhibition of citrulline synthesis by intramitochondrial citrate could be partly reversed by addition of Mg2+ in the presence of A23187. Possible implications of the regulation of carbamoyl-phosphate synthase (ammonia) activity by intramitochondrial citrate for nitrogen metabolism in the liver are discussed.

Rate-limiting factors in the oxidation of ethanol by isolated rat liver cells.

The oxidation of ethanol by isolated liver cells from starved rats is limited by the rate of removal of reducing equivalents generated in the cytosol by alcohol dehydrogenase. Evidence is presented suggesting that, in these cells, transfer of reducing equivalents from the cytosol to the mitochondria is regulated by the intracellular concentrations of the intermediates of the malate-aspartate and glycerol 3-phosphate cycles, as well as by flux through the respiratory chain. In liver cells isolated from fed rats, the availability of substrate increased the cell content of intermediates of the hydrogen-transfer cycles, and enhanced ethanol uptake. Under these conditions, ethanol consumption is limited by the availability of ADP for oxidative phosphorylation.