Glutamine metabolism in isolated perfused rat liver. The transamination pathway

In isolated perfused rat liver, added 4-methyl-thio-2-oxobutyrate and phenylpyruvate are rapidly transaminated to the corresponding amino acids with glutamine, the latter being supplied via the portal vein or by endogenous synthesis. With portal glutamine concentrations below 5mM and in the presence of a oxo-acid acceptor, the flux through glutamine transaminases exceeded the ammonium ion-stimulated glutaminase flux. 4-Methylthio-2-oxobutyrate-induced extra glutamine uptake was not dependent on the perfusate pH in the range of pH 7 to 8. During glutamine/4-methylthio-2-oxobutyrate transamination, the amide nitrogen of glutamine is fully recovered as glutamate, ammonia, urea and alanine. Oxoglutarate formed by omega-amidase activity is released as glutamate or oxidized by oxoglutarate dehydrogenase. alpha-Cyanocinnamate, the inhibitor of the monocarboxylate translocator in the mitochondrial membrane inhibited 4-methylthio-2-oxobutyrate-induced glutamine uptake and methionine release by about 30%. This might indicate that about 2/3 of glutamine transaminase flux is cytosolic. alpha-Cyanocinnamate inhibited 4-methylthio-2-oxobutyrate-induced glutamate efflux by about 90%. Stimulation of flux through glutamine transaminases is accompanied by a 70-80% inhibition of glutaminase flux. This is not explained by a direct inhibition of glutaminase by 4-methylthio-2-oxobutyrate but by a substrate competition between glutaminase and glutamine transaminases. 4-Methylthio-2-oxobutyrate decreases glutamine release by the liver due to withdrawal by transamination. The oxo acid itself is without effect on glutamine synthetase flux. With respect to hepatocyte heterogeneity there is no evidence for a zonal distribution of glutamine transaminase activities, as it has been shown for glutamine synthetase and glutaminase activities.     

Interactions between glutamine metabolism and cell-volume regulation in perfused rat liver

1. In the presence of near-physiological glutamine concentrations, exposure of perfused rat liver to hypotonic perfusion media switched glutamine balance across the liver from net release to net uptake. This was due to both stimulation of flux through glutaminase and inhibition of flux through glutamine synthetase. Conversely, during exposure to hypertonic media, net glutamine release from the liver increased due to inhibition of glutaminase flux and slight stimulation of flux through glutamine synthetase. The effect of perfusate osmolarity on glutaminase flux was observed at an NH4Cl concentration (0.5 mM) sufficient for near-maximal ammonia stimulation of glutaminase. This indicates the involvement of different mechanisms of glutaminase flux control by extracellular osmolarity changes and ammonia. The effects of anisotonicity on flux through glutamine-metabolizing enzymes were fully reversible. Glutamine (0.6 mM) stimulated urea synthesis from NH4Cl (0.5 mM) during hypotonic and normotonic conditions. 2. Exposure to hypotonic and hypertonic media led, after initial liver-cell swelling and shrinkage, respectively to volume-regulatory K+ fluxes which largely restored the initial liver-cell volume despite the continuing osmotic challenge. Even after completion of cell-volume regulatory K+ fluxes, the effects of perfusate osmolarity on hepatic glutamine metabolism persisted. This indicates that in anisotonicity the liver cell is left in an altered metabolic state, even after completion of volume-regulatory responses. 3. During perfusion with isotonic media, addition of glutamine (3 mM) led to an increase of liver mass by about 4% within 2 min, which was accompanied by a net K+ uptake by the liver. Thereafter, the new steady state of increased liver mass was maintained throughout glutamine infusion. When the liver mass had reached this new steady state, a net release of K+ from the liver of about 3 mumol/g liver was observed during the following 10 min. Withdrawal of glutamine was followed by a slow reuptake of K+ and the liver mass returned to its initial value. Following exposure to glutamine (3 mM), the intracellular glutamine concentration (as calculated from glutamine tissue levels, taking into account the extracellular space determined with the [3H]inulin technique) rose from about 1 mM to 30-35 mM within about 12 min, indicating a 10-12-fold concentrative uptake of glutamine into the liver cells and an osmotic challenge for the hepatocyte. When intracellular glutamine had reached its steady-state concentration, net K+ efflux from the liver was also terminated.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of phenylephrine on glutamate and glutamine metabolism in isolated perfused rat liver.

Addition of phenylephrine to isolated perfused rat liver is followed by an increased 14CO2 production from [1-14C]glutamate, [1-14C]glutamine, [U-14C]proline and [3-14C]pyruvate, but by a decreased 14CO2 production from [1-14C]pyruvate. Simultaneously, there is a considerable decrease in tissue content of 2-oxoglutarate, glutamate and citrate. Stimulation of 14CO2 production from [1-14C]glutamate is also observed in the presence of amino-oxyacetate, suggesting a stimulation of glutamate dehydrogenase and 2-oxoglutarate dehydrogenase fluxes by phenylephrine. Inhibition of pyruvate dehydrogenase flux by phenylephrine is due to an increased 2-oxoglutarate dehydroxygenase flux. Phenylephrine stimulates glutaminase flux and inhibits glutamine synthetase flux to a similar extent, resulting in an increased hepatic glutamine uptake. Whereas the effects of NH4+ ions and phenylephrine on glutaminase flux were additive, activation of glutaminase by glucagon was considerably diminished in the presence of phenylephrine. The reported effects are largely overcome by prazosin, indicating the involvement of alpha-adrenergic receptors in the action of phenylephrine. It is concluded that stimulation of gluconeogenesis from various amino acids by phenylephrine is due to an increased flux through glutamate dehydrogenase and the citric acid cycle.     

Glutamine synthetase, glutaminase and phosphodiesterase activities in brain under hypoxia: in vitro effect of cortisol, GABA and serotonin on glutamine synthetase.

The effect of hypobaric hypoxia on the activities of glutamine synthetase, glutaminase and cyclic 3'5' AMP phosphodiesterase in rat brain was studied after exposure to 25,000' for 6 h. Glutamine synthetase activity was increased in all the regions of brain studied, and addition of gamma amino butyric acid, serotonin and cortisol in vitro produced a differential response. Glutaminase activity decreased in the whole brain. Cyclic 3'5' AMP phosphodiesterase activity decreased in cerebellum, medulla, hypothalamus and pituitary showing an accumulation of cyclic 3'5' AMP in these regions. The results suggest that glutamine synthesis and degradation are regulated in the central nervous system by cyclic AMP and cortisol: Gamma aminoburyric acid and other compounds can modulate the activity of glutamine synthetase and glutaminase.     

Hepatocyte heterogeneity in glutamine and ammonia metabolism and the role of an intercellular glutamine cycle during ureogenesis in perfused rat liver

1. The metabolism of glutamine and ammonia was studied in isolated perfused rat liver in relation to its dependence on the direction of perfusion by comparing the physiological antegrade (portal to caval vein) to the retrograde direction (caval to portal vein). 2. Added ammonium ions are mainly converted to urea in antegrade and to glutamine in retrograde perfusions. In the absence of added ammonia, endogenously arising ammonium ions are converted to glutamine in antegrade, but are washed out in retrograde perfusions. When glutamine synthetase is inhibited by methionine sulfoximine, direction of perfusion has no effect on urea synthesis from added or endogenous ammonia. 3. 14CO2 production from [1-14C]glutamine is higher in antegrade than in retrograde perfusions as a consequence of label dilution during retrograde perfusions. 4. The results are explained by substrate and enzyme activity gradients along the liver lobule under conditions of limiting ammonia supply for glutamine and urea synthesis, and they are consistent with a perivenous localization of glutamine synthetase and a predominantly periportal localization of glutaminase and urea synthesis. Further, the data indicate a predominantly periportal localization of endogenous ammonia production. The results provide a basis for an intercellular (as opposed to intracellular) glutamine cycling and its role under different metabolic conditions.     

Effect of different dietary proteins on plasma and liver fatty acid compositions in growing rats

The activities of key glutamine and urea cycle enzymes were assayed in liver homogenates from control and chronically acidotic rats and compared with citrulline and urea productions by isolated mitochondria and intact liver slices, respectively. Glutamine-dependent urea and citrulline synthesis were increased significantly in isolated mitochondria and in liver slices; the activities of carbamoyl phosphate synthetase and arginase were unchanged and increased, respectively. Glutamine was not a precursor in the carbamoyl phosphate synthetase system, suggesting that the glutamine effect is an indirect one and that glutamine requires prior hydrolysis. Increased mitochondrial citrulline synthesis was associated with enhanced oxygen consumption, suggesting glutamine acts both as a nitrogen and fuel source. Hepatic phosphate-dependent glutaminase was elevated by chronic acidosis. The results indicate that the acidosis-induced reduction in ureagenesis and reversal from glutamine uptake to release observed in vivo are not reflections of corresponding changes in the hepatic enzyme content. Rather, when available, glutamine readily supports ureagenesis, suggesting a close coupling of hepatic glutaminase flux with citrulline synthesis.     

Renal enzymes during experimental diabetes mellitus in the rat. Role of insulin, carbohydrate metabolism, and ketoacidosis

The activities of various ammoniagenic, gluconeogenic, and glycolytic enzymes were measured in the renal cortex and also in the liver of rats made diabetic with streptozotocin. Five groups of animals were studied: normal, normoglycemic diabetic (insulin therapy), hyperglycemic, ketoacidotic, and ammonium chloride treated rats. Glutaminase I, glutamate dehydrogenase, glutamine synthetase, phosphoenolpyruvate carboxykinase (PEPCK), hexokinase, phosphofructokinase, fructose-1,6-diphosphatase, malate dehydrogenase, malic enzyme, and lactate dehydrogenase were measured. Renal glutaminase I activity rose during ketoacidosis and ammonium chloride acidosis. Glutamate dehydrogenase in the kidney rose only in ammonium chloride treated animals. Glutamine synthetase showed no particular variation. PEPCK rose in diabetic hyperglycemic animals and more so during ketoacidosis and ammonium chloride acidosis. It also rose in the liver of the diabetic animals. Hexokinase activity in the kidney rose in diabetic insulin-treated normoglycemic rats and also during ketoacidosis. The same pattern was observed in the liver of these diabetic rats. Renal and hepatic phosphofructokinase activities were elevated in all groups of experimental animals. Fructose-1,6-diphosphatase and malate dehydrogenase did not vary significantly in the kidney and the liver. Malic enzyme was lower in the kidney and liver of the hyperglycemic diabetic animals and also in the liver of the ketoacidotic rats. Lactate dehydrogenase fell slightly in the liver of diabetic hyperglycemic and NH4Cl acidotic animals. The present study indicates that glutaminase I is associated with the first step of increased renal ammoniagenesis during ketoacidosis. PEPCK activity is influenced both by hyperglycemia and ketoacidosis, acidosis playing an additional role. Insulin appears to prevent renal gluconeogenesis and to favour glycolysis. The latter would seem to remain operative in hyperglycemic and ketoacidotic diabetic animals.     

The effects of ammonium chloride and bicarbonate on the activity of glutaminase in isolated liver mitochondria.

1. Glutamine hydrolysis in liver mitochondria was studied by measuring the production of glutamate under conditions where this compound could not be further metabolized. 2. Glutaminase activity in intact mitochondria was very low in the absence of activators. 3. Glutamine hydrolysis was markedly stimulated by NH4Cl and also by HCO3- ions. 4. The stimulation by each of these compounds was much decreased if the mitochondria were uncoupled. 5. Maximum rates of glutamine hydrolysis required the addition of phosphate. A correlation was observed between the activity of glutaminase in the presence of NH4Cl plus HCO3- and the intramitochondrial content of ATP. 6. In disrupted mitochondria, NH4Cl stimulated glutaminase to a much smaller extent than in intact mitochondria. The NH4Cl stimulation in disrupted mitochondria was much increased by the addition of ATP. KHCO3 also stimulated glutaminase activity in disrupted mitochondria, and ATP increased the magnitude of this stimulation. 7. It was concluded that maximum rates of glutaminase activity in liver mitochondria require the presence of phosphate, ATP and either HCO3- or NH4+. A comparison of the results obtained on intact and broken mitochondria indicates that these effectors have a direct effect on the glutaminase enzyme system rather than an indirect effect mediated by changes in transmembrane ion gradients or in the concentrations of intramitochondrial metabolites.     

Regulation of glutamine synthetase and glutaminase activities in cultured skeletal muscle cells

Glutamine is synthesized in skeletal muscle, released to the circulation, and transported to other tissues, where it may provide important substrate for gluconeogenesis, ammoniagenesis, and energy-yielding pathways. With the ultimate goal of delineating the factors that control glutamine production and release by skeletal muscle, we have studied the regulation of two key enzymes, glutamine synthetase and glutaminase, in the L6 line of rat skeletal muscle cells grown in monolayer culture. The cultured myotubes were found to have glutamine synthetase and phosphate-dependent glutaminase activities. Glutamine synthetase activity was increased following incubation (1) in glutamine-free medium (threefold); (2) in medium containing high glutamic acid concentrations (fourfold); and (3) in medium supplemented with dexamethasone (threefold). In each case the increase in glutamine synthetase activity required several hours to reach a maximum and was prevented by cycloheximide, suggesting that the change occurred through increased enzyme biosynthesis. No substances tested were found to affect glutaminase activity. We conclude that glutamine synthetase in cultured skeletal muscle is responsive to substrate, product, and hormonal regulation.     

Glutamine synthetase and glutaminase activities in various hepatoma cells

Glutamine synthetase and glutaminase activities in a series of hepatoma cells of human and rat origins were determined for comparison with normal liver tissues. Marked decrease in glutamine synthetase activity was observed in the tumor cells. Phosphate-dependent and phosphate-independent glutaminase activities were increased compared with those from normal liver tissues. Well coupled mitochondria were isolated from HuH 13 line of human hepatoma cells and human liver. Oxypolarographic tests showed that glutamine oxidation was prominent in the tumor mitochondria, while mitochondria from the liver showed a feeble glutamine oxidation. Glutamine oxidation was inhibited by prior incubation of the mitochondria with DON (6-diazo-5-oxo-L-norleucine), which inhibited mitochondrial glutaminase. These results indicate that the product of glutamine hydrolysis, glutamate, is catabolized in the tumor mitochondria to supply ATP.     

Glutamine metabolism in the avian host bearing transplantable hepatomatous growth induced by MC-29 virus

The concentrations of free amino acids have been determined in the sera of chickens bearing transplanted hepatomatous growths induced by MC-29 virus and their pair-fed controls. Decreases in serine and glutamine concentrations were observed when the tumors developed; the latter being more prominent. Glutamine synthetase activities in the liver and thigh muscle were increased as the tumors grew larger. Elevation of serum uric acid was observed in the tumor-bearing chickens. Liver glutamine-PRPP-amidotransferase activity was not affected by the tumor growth. In the hepatomatous tissue, activity of glutamine synthetase was low and below one-tenth of that in liver. Glutaminase activities, phosphate-dependent and phosphate-independent, were increased. Glutamine-PRPP-amidotransferase activity was about half compared to that in liver.     

Characterisation of G418-induced metabolic load in recombinant CHO and BHK cells: effect on the activity and expression of central metabolic enzymes

In a previous article (Yallop and Svendsen 2001), recombinant CHO and BHK cell lines, expressing the human glucagon receptor and the gastric inhibitory peptide receptor, respectively, showed reduced growth rates and altered nutrient utilisation when grown with increasing concentrations of G418. This response was associated with an increased expression of the neo ^r protein, while expression of the recombinant membrane receptors remained unaltered. The metabolic response was characterised in both cell lines by an increase in the specific rate of glutamine utilisation and in CHO cells by a decrease in the yield of lactate from glucose, suggesting a change in the flux of glucose through central metabolism. The aim of this study was to further elucidate these metabolic changes by determining the activity and relative expression of key enzymes involved in glucose and glutamine metabolism. For both CHO and BHK cells, there was an increase in the activity of glutaminase, glutamate dehydrogenase and glutamine synthetase, suggesting an increased flux through the glutaminolysis pathway. The activity of glucose-6-phosphate dehydrogenase and pyruvate carboxylase in CHO cells was also increased whilst lactate dehydrogenase activity remained unaltered, suggesting an increased flux to the pentose phosphate pathway and TCA cycle, respectively. The activity of these enzymes in BHK cells was unchanged. Quantitative RT-PCR showed that expression levels of glutaminase and pyruvate carboxylase were the same with and without G418, indicating that the differences in activities were likely due to post-translational modifications. This revised version was published online in July 2006 with corrections to the Cover Date.     

pH control of hepatic glutamine degradation. Role of transport

Glutamine uptake is decreased in isolated perfused rat liver when the extracellular pH is lowered. This is also observed in the presence of ammonia concentrations nearly 20-fold above that required for half-maximal stimulation of glutaminase, indicating that the effect is not explained by a submaximal ammonium activation of the enzyme. In livers perfused with a physiological glutamine concentration (0.6 mM), the tissue glutamine but not glutamate content is strongly dependent on the extracellular pH and increases from 2.9 mumol/g to 4.7 mumol/g liver when the extracellular pH is increased from 7.3 to 7.5. Subfractionation of the livers revealed that the mitochondrial glutamine concentration increases from about 15 mM to 50 mM, when the extracellular pH is raised from 7.3 to 7.7, whereas the cytosolic glutamine concentration increases only slightly. Simultaneously the cytosolic and mitochondrial pH values are largely unaffected, being 7.25 and 7.7 respectively. Thus, the pH gradient between mitochondria and cytosol remains unchanged when the extracellular pH varies. Amiloride (2 mM) inhibits glutamine uptake by the liver and abolishes the extra/intracellular pH gradient. With amiloride present, tissue glutamine levels are no longer dependent on extracellular pH and are only about 2 mumol/g liver. It is concluded that pH control of glutaminase flux is also mediated by variations of the mitochondrial glutamine concentration pointing to a regulatory role of the glutamine carrier in the mitochondrial membrane for hepatic glutamine breakdown.     

Glutamine and ammonium handling by anaesthetized rats

The infusion of ether anesthaetized rats with 0.2 M (1 mmols in total) ammonium acetate or glutamine were compared with the infusion of 0.2 M NaCl. The levels of circulating glucose, amino acids, lactate, urea and ammonium were measured as well as liver glycogen and tissue amino acids and the liver and muscle activities of carbamoyl phosphate synthetases I and II, glutamate dehydrogenase, glutamine synthetase and adenylate deaminase. Neither treatment altered the glucose and glycogen homeostasis. The infusion of ammonium did not result in increases in circulating ammonium, but resulted in increased circulating urea after a short delay; the infusion of glutamine resulted also in urea production but much later on. Glutamine infusion also resulted in increased tissue free amino-acid levels. There was little alteration in enzyme activities, except for decreased glutamine synthetase and adenylate deaminase activity in muscle of glutamine-infused rats and higher tissue carbamoyl phosphate synthetase II. The results agree with a fast removal of infused ammonium, and maintenance of glutamine, with their channeling towards urea production at a rate comparable with that of infusion, that did not alter significantly the homeostasis of the experimental animals.     

Metabolic adaptations to nitrogen excess in late gestation in rat.

Pregnant rats of 19th and 21st days were given an acute nitrogen overload produced by an infusion of either 0.2 M ammonium acetate or 0.2 M glutamine. Metabolic adaptations to nitrogen excess were studied measuring--in fetomaternal unit--non-protein nitrogen content and the activities of enzymes related with ammonia metabolism. Maternal and fetal plasma urea levels were increased by ammonium acetate treatment. Glutamine overload increased more the amino acid content in the mothers than in conceptus. As response to ammonium acetate treatment, glutamate dehydrogenase activity in liver was more sensitive in pregnant than in nonpregnant rats, suggesting more nitrogen incorporation into amino acids in pregnancy. Regarding glutamine synthetase activity, both treatments had an opposite effect except in kidney. The adenylate deaminase activity of pregnant rats was inhibited similarly to nonpregnant rats by nitrogen overloads, but stronger after glutamine infusion. Placenta and fetal metabolism were adjusted, as the dams, to lack of ammonia production by nitrogen overloads and to glutamine synthesis by ammonium acetate infusion.     

Response of rat liver glutaminase to pH. Mediation by phosphate and ammonium ions

The activity of rat liver glutaminase from sedimented fractions of freeze-thawed mitochondria is strongly affected by variation in pH over a physiologically relevant range at approximate physiological concentrations of activators. As pH increases from 7.1 to 7.7 at 0.7 mM ammonium and 10 mM phosphate, the S0.5 for glutamine decreases 3.5-fold, from 38 to 11 mM. This results in an 8-fold increase in reaction velocity at 10 mM glutamine. In addition, the M0.5 for phosphate activation decreases from 21 to 8.9 mM as pH increases from 7.1 to 7.7. This apparent effect of pH on the affinity of glutaminase for phosphate is similar to previous reports of the pH effect on activation by ammonium (Verhoeven, A. J., Van Iwaarden, J. F., Joseph, S. K., and Meijer, A. J. (1983) Eur. J. Biochem. 133, 241-244; McGivan, J. D., and Bradford, N. M. (1983) Biochim. Biophys. Acta 159, 296-302). Glutaminase does not respond to variation in pH between 7.1 and 7.7 when phosphate and ammonium are saturating. The effects of the two modifiers are additive. Each is still effective, as is pH, when the other is saturating. Therefore, it appears that the effects of pH on the apparent affinity of the enzyme for ammonium and phosphate account for the enzyme's response to pH. These results may help explain previous reports of minimal effects of pH on glutaminase at saturating concentrations of related substances (McGivan, J. D., Lacey, J. H., and Joseph, K. (1980) Biochim. J. 192, 537-542; Horowitz, M. L., and Knox, W. E. (1968) Enzymol. Biol. Clin. 9, 241-255; McGivan, J. D., and Bradford, N. M. (1983) Biochim. Biophys. Acta 759, 296-302). Glutaminase binds glutamine cooperatively with Hill coefficients ranging from 1.7 to 2.2, which suggests at least two and probably three or more interacting binding sites for glutamine. The strong response of liver glutaminase to pH and the fact that the reaction can supply metabolites for urea synthesis suggest a possible regulatory role of glutaminase in ureagenesis.     

Changes in the activity levels of glutamine synthetase, glutaminase and glycogen synthetase in rats subjected to hypoxic stress

 Exposure to high altitude causes loss of body mass and alterations in metabolic processes, especially carbohydrate and protein metabolism. The present study was conducted to elucidate the role of glutamine synthetase, glutaminase and glycogen synthetase under conditions of chronic intermittent hypoxia. Four groups, each consisting of 12 male albino rats (Wistar strain), were exposed to a simulated altitude of 7620 m in a hypobaric chamber for 6 h per day for 1, 7, 14 and 21 days, respectively. Blood haemoglobin, blood glucose, protein levels in the liver, muscle and plasma, glycogen content, and glutaminase, glutamine synthetase and glycogen synthetase activities in liver and muscle were determined in all groups of exposed and in a group of unexposed animals. Food intake and changes in body mass were also monitored. There was a significant reduction in body mass (28–30%) in hypoxia-exposed groups as compared to controls, with a corresponding decrease in food intake. There was rise in blood haemoglobin and plasma protein in response to acclimatisation. Over a three-fold increase in liver glycogen content was observed following 1 day of hypoxic exposure (4.76±0.78 mg·g⁻¹ wet tissue in normal unexposed rats; 15.82±2.30 mg·g⁻¹ wet tissue in rats exposed to hypoxia for 1 day). This returned to normal in later stages of exposure. However, there was no change in glycogen synthetase activity except for a decrease in the 21-days hypoxia-exposed group. There was a slight increase in muscle glycogen content in the 1-day exposed group which declined significantly by 56.5, 50.6 and 42% following 7, 14, and 21 days of exposure, respectively. Muscle glycogen synthetase activity was also decreased following 21 days of exposure. There was an increase in glutaminase activity in the liver and muscle in the 7-, 14- and 21-day exposed groups. Glutamine synthetase activity was higher in the liver in 7- and 14-day exposed groups; this returned to normal following 21 days of exposure. Glutamine synthetase activity in muscle was significantly higher in the 14-day exposed group (4.32 μmol γ-glutamyl hydroxamate formed·g protein⁻¹·min⁻¹) in comparison to normal (1.53 μmol γ-glutamyl hydroxamate formed·g protein⁻¹·min⁻¹); this parameter had decreased by 40% following 21 days of exposure. These results suggest that since no dramatic changes in the levels of protein were observed in the muscle and liver, there is an alteration in glutaminase and glutamine synthetase activity in order to maintain nitrogen metabolism in the initial phase of hypoxic exposure. Received: 30 March 1998 / Revised: 18 November 1998 / Accepted: 25 November 1998     

Expression of functional human glutaminase in baculovirus system: affinity purification, kinetic and molecular characterization

Glutaminase catalyzes the hydrolysis of glutamine yielding stoichiometric amounts of glutamate plus ammonium ions. In mammals, there are two different genes encoding for glutaminase, known as liver (L) and kidney (K) types. The human L-type isoform expressed in baculovirus yielded functional recombinant enzyme in Sf9 insect cells. A novel affinity chromatography method, based on its specific interaction with a PDZ protein, was developed for purification. Kinetic constants were determined for the purified human isozyme, which showed an allosteric behaviour for glutamine, with a Hill index of 2.7 and S(0.5) values of 32 and 64 mM for high and low P(i) concentrations, respectively. Whereas the protein showed a low P(i) dependence typical for L-type glutaminases, the enzyme was unexpectedly inhibited by glutamate, a kinetic characteristic exclusive of K-type isozymes, and was slightly activated by ammonia, unlike the classical liver enzymes which show an absolute dependence on ammonia. Subcellular fractionation demonstrates that recombinant human glutaminase was targeted to both mitochondria and nucleus, and in both locations the protein was catalytically active. This is the first report of the expression of a functional L-type mammalian glutaminase enzyme. The study also provides a simple and efficient method for affinity purification of the recombinant enzyme. Moreover, the data imply that this human enzyme may represent a new isoform different from classical kidney and liver isozymes.     

Changes in adenosine receptors during differentiation of 3T3-F442A cells to adipocytes.

We measured the amino acid concentrations in the afferent and efferent vessels of the liver in anaesthetized fed adult rats and in fed suckling rat pups. A much higher content of glutamine in the portal vein and the aorta than in hepatic veins suggests that this amino acid is actively taken up by the liver of fed suckling rat pups, conversely to what is found in adult rats. In an attempt to characterize further the mechanism(s) contributing to this enhanced glutamine uptake, we monitored the time course of 1 mM-glutamine transport into plasma-membrane vesicles purified from the livers of either adult or suckling rats. The concentrative Na+-dependent uptake of glutamine was lower in those vesicles obtained from pups than in those obtained from adult rats. Glutaminase and glutamine synthetase activities in livers from both experimental groups were also measured. Glutaminase and glutamine synthetase activities in suckling rats were about 3-fold higher and 2-fold lower respectively than those in adult rats. It is concluded that glutamine is a main nitrogen carrier to the liver in fed suckling rats. A high availability of this amino acid and an enzyme imbalance between glutamine-synthesizing and -degrading activities may account for the net uptake found in vivo.