Metabolic fate of a high concentration of glutamine and glutamate in rat brain slices: a ¹³C NMR study

This study was performed to analyze the metabolic fate of a high concentration (5 mM) of glutamine and glutamate in rat brain slices and the participation of these amino acids in the glutamine-glutamate cycle. For this, brain slices were incubated for 60 min with [3-13C]glutamine or [3-13C]glutamate. Tissue plus medium extracts were analyzed by enzymatic and 13C NMR measurements and fluxes through pathways of glutamine and glutamate metabolism were calculated. We demonstrate that both substrates were utilized and oxidized at high rates by rat brain slices and served as precursors of neurotransmitters, tricarboxylic acid (TCA) cycle intermediates and alanine. In order to determine the participation of glutamine synthetase in the appearance of new glutamine molecules with glutamine as substrate, brain slices were incubated with [3-13C]glutamine in the presence of methionine sulfoximine, a specific inhibitor of glutamine synthetase. Our results indicate that 36.5% of the new glutamine appeared was glutamine synthetase-dependent and 63.5% was formed from endogenous substrates. Flux through glutamic acid decarboxylase was higher with glutamine than with glutamate as substrate whereas fluxes from α-ketoglutarate to glutamate and through glutamine synthetase, malic enzyme, pyruvate dehydrogenase, pyruvate carboxylase and citrate synthase were in the same range with both substrates.     

Nitrite metabolism in the cyanobacterium Anabaena cycadeae: Regulation of nitrite uptake and nitrite reductase by ammonia

Abstract Nitrogen regulation of nitrite uptake and nitrite reductase was studied in the cyanobacterium Anabaena cycadeae and its glutamine-auxotrophic mutant. The development of the nitrite-uptake system preceded, and was independent of, the development of nitrate reductase. The levels of both of the systems were higher in the glutamine auxotroph lacking glutamine synthetase (GS) than in the wild-type strain having normal GS activity. The nitrite-uptake system was found to be constitutive and ammonia-repressible whereas the nitrite-reductase system was ammonia-repressible and nitrite-inducible. Ammonia did not inhibit the nitrite-uptake and nitrite reductase activities in the glutamine auxotroph whereas glutamine did so, suggesting that repression of nitrite-uptake and nitrite reductase systems by ammonia requires the operation of GS and probably involves the participation of some organic nitrogen metabolites like glutamine.     

Subunit interaction during catalysis: ammonium ion modulation of catalytic steps in the Escherichia coli glutamine synthetase reaction

A new approach for assessing if catalytic cooperativity may occur between subunits has been applied to Escherichia coli glutamine synthetase. The extent of oxygen exchange between bound [18O]glutamate and phosphate per molecule of glutamine formed was evaluated at various NH4+ concentrations. This allows calculation of the minimum number of reaction reversals in which bound glutamine is converted to bound glutamate prior to release of glutamine. At 1000 microM NH4+ no detectable reversals occurred, and only one glutamate oxygen appeared in product phosphate as required by the reaction mechanism. However, at 10 microM NH4+ over 15 reversals of bound glutamine formation occurred. Controls showed that under the experimental conditions free glutamine does not become significantly involved in exchange and, therefore, the reversal of the oxygen exchange steps appears to be limited to bound glutamine. In contrast to the effect seen with NH4+, adenosine 5'-triphosphate concentration appears to modulate the exchange of oxygen between glutamate and phosphate only slightly. These findings are interpreted as showing that NH4+ either promotes the dissociation of one of the reaction products or decreases the participation of bound products in the exchange. The NH4+ modulation of the oxygen exchange is consistent with binding of NH4+ at one catalytic site promoting catalytic events at an alternate catalytic site but does not eliminate all other explanations.     

An alternative mechanism for the nitrogen transfer reaction in asparagine synthetase.

In the absence of crystallographic data, the mechanism of nitrogen transfer from glutamine in asparagine synthetase (AS) remains under active investigation. Surprisingly, the glutamine-dependent AS from Escherichia coli (AsnB) appears to lack a conserved histidine residue, necessary for nitrogen transfer if the reaction proceeds by the accepted pathway in other glutamine amidotransferases, but retains the ability to synthesize asparagine. We propose an alternative mechanism for nitrogen transfer in AsnB which obviates the requirement for participation of histidine in this step. Our hypothesis may also be more generally applicable to other glutamine-dependent amidotransferases.     

Glutamine Transport in Mouse Cerebral Astrocytes

Abstract: We measured initial influx and exchange of [¹⁴C]glutamine in primary astrocyte cultures in the presence and absence of Na⁺. Kinetic analysis of transport in Na⁺-free solution indicated two saturable Na⁺-independent components, one of which was identifiable functionally as system L₁ transport. In the presence of Na⁺, multiple hyperbolic components were not resolvable from the kinetic data. Nevertheless, other evidence supported participation by at least three Na⁺-dependent neutral amino acid transporters (systems A, ASC, and N). System A transport of glutamine was usually absent or minimal, based on lack of inhibition by α-(methylamino)isobutyric acid. However, vigorous system A-mediated transport emerged after derepression by substrate deprivation. Participation by system ASC was indicated by trans-acceleration of Na⁺-dependent uptake, preferential inhibition of an Li⁺-intolerant component of uptake by cysteine, and inhibition by cysteine of a component resistant to inhibition by histidine and α-(methylamino)isobutyric acid. Because nonsaturable transport of glutamine appeared negligible, and system L transport of glutamine was suppressed in the presence of Na⁺, low-affinity system ASC transport may be the major route of export of glutamine from astrocytes. At 700 µ M glutamine, the primary uptake route was system N transport, identified on the basis of selective inhibition by histidine and asparagine, pH sensitivity, and tolerance of Li⁺ in place of Na⁺.     

PKM2 depletion induces the compensation of glutaminolysis through β-catenin/c-Myc pathway in tumor cells

The metabolic activity in cancer cells primarily rely on aerobic glycolysis. Besides glycolysis, some tumor cells also exhibit excessive addition to glutamine, which constitutes an advantage for tumor growth. M2-type pyruvate kinase (PKM2) plays a pivotal role in sustaining aerobic glycolysis, pentose phosphate pathway and serine synthesis pathway. However, the participation of PKM2 in glutaminolysis is little to be known. Here we demonstrated that PKM2 depletion could provoke glutamine metabolism by enhancing the β-catenin signaling pathway and consequently promoting its downstream c-Myc-mediated glutamine metabolism in colon cancer cells. Treatment with 2-deoxy-d-glucose (2-DG), a glycolytic inhibitor, got consistent results with the above. In addition, the dimeric form of PKM2, which lacks the pyruvate kinase activities, plays a critical role in regulating β-catenin. Moreover, we found that overexpression of PKM2 negatively regulated β-catenin through miR-200a. These insights supply evidence that glutaminolysis plays a compensatory role for cell survival upon glucose metabolism impaired.     

Oxidative modification of glutamine synthetase. II. Characterization of the ascorbate model system

The first step in the proteolytic degradation of bacterial glutamine synthetase is a mixed function oxidation of one of the 16 histidine residues in the glutamine synthetase subunit (Levine, R.L. (1983) J. Biol. Chem. 258, 11823-11827). A model system, consisting of oxygen, a metal ion, and ascorbic acid, mimics the bacterial system in mediating the oxidative modification of glutamine synthetase. This model system was studied to gain an understanding of the mechanism of oxidation and of factors which control the susceptibility of the enzyme to oxidation. Availability of substrates and the extent of covalent modification of the enzyme (adenylylation) interact to modulate susceptibility of the enzyme to oxidation. This interaction provides the biochemical basis for physiologic regulation of intracellular proteolysis of glutamine synthetase. The oxidative modification requires hydrogen peroxide. While the reaction may involve Fenton chemistry, the participation of free radicals, superoxide anion, and singlet oxygen could not be demonstrated.     

Concentration of free amino acids in the blood and liver of cattle, sheep and rabbits

Concentration of free amino acids in the plasma, erythrocytes and the liver of cattle, sheep and rabbits was different in various species. The differences concerned mainly glutamine, glutamic acid, proline, alanine, glycine. The participation of endogenic amino acids in gluconeogenesis and the nitrogen recycle was discussed considering the characteristics of their metabolism in ruminants.     

Transglutaminase-like activity participates in cell wall biogenesis in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Transglutaminases (TGases) catalyze the cross-linking between protein molecules by formation of an amide bond between γ-carboxyamide group of glutamine and the ε-amine group of lysine under deamination of glutamine. We have demonstrated the participation of transglutaminase-like activity in the isolated cell walls and in the process of cell wall regeneration in protoplasts of the yeast Saccharomyces cerevisiae. A radioactive TGase substrate [³H]putrescine was incorporated into the isolated cell walls and into the TCA-insoluble fraction in regenerating protoplasts. The incorporation was increased by adding exogenous artificial substrate of TGase N,N’-dimethylcasein and was inhibited by TGase inhibitor cystamine and/or EDTA. These results suggest the existence of a TGase-type reaction involved in the formation of covalent cross-links between glycoprotein molecules during cell wall construction in S. cerevisiae.     

Role of plasma membrane transport in hepatic glutamine metabolism

In livers of fed rats and in perfused livers supplied with a physiological portal glutamine concentration of 0.6 mM, the mitochondrial and cytosolic glutamine concentrations are 20 mM and 7 mM, respectively, thus, the mitochondrial/cytosolic glutamine concentration gradient is 2-3. Uptake and release of glutamine by periportal and perivenous hepatocytes occurs predominantly by an Na+-dependent transport system (so-called system 'N'). Histidine in near-physiological concentrations inhibits both glutamine uptake by periportal hepatocytes and its release by perivenous hepatocytes. This is not due to an inhibition of glutamine-metabolizing enzymes by histidine or its metabolites. With physiological portal glutamine concentrations (0.6 mM), stimulation of glutaminase flux or of glutamine transaminase flux is followed by a decrease of hepatic glutamine levels to about 80% or 30%, respectively, glutamine levels are further decreased to 50% or 20% in the presence of histidine. When glutamine is synthesized endogenously (no glutamine added), the histidine-induced inhibition of glutamine release is paralleled by a 210% increase of the hepatic tissue level of glutamine. In experiments with and without methionine sulfoximine and in the absence of added glutamine, the glutamine content in the small perivenous hepatocyte population containing glutamine synthetase is estimated to be about 3.5 mumol/g wet weight and that in the periportal hepatocytes as low as 0.1 mumol/g wet weight. In contrast to the prevailing view, it is concluded that glutamine transport across the plasma membrane of hepatocytes is a potential regulatory site in glutamine degradation and synthesis, especially under the influence of effectors like histidine.     

The regulation of glutamine transport and glutamine synthetase in Salmonella typhimurium.

Transport of glutamine by the high-affinity transport system is regulated by the nitrogen status of the medium. With high concentrations of ammonia, transport is repressed; whereas with Casamino acids, transport is elevated, showing behaviour similar to glutamine synthetase. A glutamine auxotroph, lacking glutamine synthetase activity, had elevated transport activity even in the presence of high concentrations of ammonia (and glutamine). This suggests that glutamine synthetase is involved in the regulation of the transport system. A mutant with low glutamate synthase activity had low glutamine transport and glutamine synthetase activities, which could not be derepressed. A mutant in the high-affinity glutamine transport system showed normal regulation of glutamate synthase and glutamine synthetase. Possible mechanisms for this regulation are discussed.     

Muscle glutamine depletion in the intensive care unit

Glutamine is primarily synthesized in skeletal muscle and enables transfer of nitrogen to splanchnic tissues, kidneys and immune system. Discrepancy between increasing rates of glutamine utilization at whole body level and relative impairment of de novo synthesis in skeletal muscle leads to systemic glutamine deficiency and characterizes critical illness. Glutamine depletion at whole body level may contribute to gut, liver and immune system disfunctions, whereas its intramuscular deficiency may directly contribute to lean body mass loss. Severe intramuscular glutamine depletion also develops because of outward transport system upregulation, which is not counteracted by increased de novo synthesis. The negative impact of systemic glutamine depletion on critically ill patients is suggested both by the association between a lower plasma glutamine concentration and poor outcome and by a clear clinical benefit after glutamine supplementation. Enteral glutamine administration preferentially increases glutamine disposal in splanchnic tissues, whereas parenteral supplementation provides glutamine to the whole organism. Nonetheless, systemic administration was ineffective in preventing muscle depletion, due to a relative inability of skeletal muscle to seize glutamine from the bloodstream. Intramuscular glutamine depletion could be potentially counteracted by promoting de novo glutamine synthesis with pharmacological or nutritional interventions.     

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.     

Effects of mitochondrial swelling and calcium on phosphate-activated glutaminase in pig renal mitochondria

The effects of mitochondrial swelling and calcium have been used to study the possible function of the glutamine transporter in regulating glutamine hydrolysis. Salt-induced swelling of pig renal mitochondria and an iso-osmotic mixed salt solution and swelling caused by reducing the osmolarity of the incubation medium, are accompanied by activation of glutamine hydrolysis. Regulation of the glutaminase activity by salt-induced mitochondrial swelling is likely to have physiological importance, similar to the regulation of hepatic glutaminase by changing the matrix volume, that has been described by others. 0.1-1.0 mM calcium stimulates glutamine hydrolysis and the calcium activation curve follows Michaelis-Menten kinetics. The calcium activation is reversible, it is unaffected by phosphate, high glutamine and mitochondrial calcium uptake, as well as by sonication and the activation is calmodulin independent. The calcium activation is additive to that of swelling. Similar to calcium, hypo-osmotic swelling mainly increases the apparent Vmax for glutamine, whereas the apparent Km is little changed, indicating that the effects are primarily on the phosphate-activated glutaminase itself rather than on the glutamine transporter. Furthermore, calcium which activates glutamine hydrolysis, inhibits glutamine uptake into the mitochondria and so does alanine having no effect on glutamine hydrolysis. Therefore, it is indicative that glutamine transport is not rate limiting for glutamine hydrolysis.     

Physiological role of glutaminase activity in Saccharomyces cerevisiae

The participation of glutaminase activity in glutamine degradation was studied in a wild-type strain (S288C) of Saccharomyces cerevisiae. Evidence is presented that this strain has two glutaminase activities, a readily extractable form (glutaminase B) and a membrane-bound enzyme (glutaminase A). Glutaminase A and B activities could also be distinguished by their thermostability, pyruvate sensitivity and pH optimum. Glutaminase B activity was negatively modulated by some 2-oxo acids, and in vivo pyruvate accumulation inhibited this activity. A mutant strain (CN10) with an altered glutaminase B activity was isolated and partially characterized. Its glutaminase B activity was more sensitive to inhibition by pyruvate and 2-oxoglutarate than the wild type, thus resulting in inactivation of this enzyme in vivo. The physiological role of glutaminase activity is discussed with regard to the phenotype shown by the mutant strain.     

Glutamine metabolism and cycling in Neurospora crassa.

Evidence for the existence of a glutamine cycle in Neurospora crassa is reviewed. Through this cycle glutamine is converted into glutamate by glutamate synthase and catabolized by the glutamine transaminase-omega-amidase pathway, the products of which (2-oxoglutarate and ammonium) are the substrates for glutamate dehydrogenase-NADPH, which synthesizes glutamate. In the final step ammonium is assimilated into glutamine by the action of a glutamine synthetase (GS), which is formed by two distinct polypeptides, one catalytically very active (GS beta), and the other (GS alpha) less active but endowed with the capacity to modulate the activity of GS alpha. Glutamate synthase uses the amide nitrogen of glutamine to synthesize glutamate; glutamate dehydrogenase uses ammonium, and both are required to maintain the level of glutamate. The energy expended in the synthesis of glutamine drives the cycle. The glutamine cycle is not futile, because it is necessary to drive an effective carbon flow to support growth; in addition, it facilitates the allocation of nitrogen or carbon according to cellular demands. The glutamine cycle which dissipates energy links catabolism and anabolism and, in doing so, buffers variations in the nutrient supply and drives energy generation and carbon flow for optimal cell function.     

13N isotope studies of glutamine assimilation pathways in Neurospora crassa.

L-[amide-13N]glutamine in Neurospora crassa is metabolized to [13N]glutamate by glutamate synthase and to [13N]ammonium by the glutamine transaminase-omega-amidase pathway. The [13N]ammonium released is assimilated by glutamate dehydrogenase and glutamine synthetase, confirming the operation of a glutamine cycle. Most of the nitrogen is retained during cycling between glutamate and glutamine.     

The role of glutamine in the immune system and in intestinal function in catabolic states

Summary Glutamine is designated a non-essential amino acid: however, evidence is accumulating that glutamine becomes essential when catabolic conditions prevail.It has been established that glutamine is an important fuel for lymphocytes and macrophages, even when resting. Plasma and muscle glutamine concentrations are decreased after trauma such as burns, major surgery, and in sepsis. The effectiveness of the immune system is decreased after trauma: this may be due, in part, to the decrease in plasma glutamine concentrations.Most studies on sepsis in humans have shown plasma glutamine concentrations to bedecreased: this may be due to an increased rate of utilization of glutamine by lymphocytes and macrophages during proliferation or phagocytosis. In contrast, several studies on rats showincreased plasma glutamine levels in sepsis. A species difference in the way in which glutamine is metabolised could be the main reason for the conflicting results. Other contributory factors could be diurnal variation and timing of sample collection.A substantial amount of dietary glutamine is taken up by intestinal cells. When the supply of glutamine via the diet is decreased, glutamine is taken up from the circulation by the intestine. In total parenteral nutrition (TPN) sepsis can sometimes occur because the gut is rested, leading to villous atrophy and increased gut mucosal barrier permeability. There is now a move towards the use of enteral nutrition in preference to TPN. Provision of exogenous glutamine has had beneficial effects in humans and animals, particularly in improving intestinal function. The safety and efficacy of glutamine administration to humans is discussed in detail.     

Differentiation stage-dependent preferred uptake of basolateral (systemic) glutamine into Caco-2 cells results in its accumulation in proteins with a role in cell-cell interaction

Glutamine is an essential amino acid for enterocytes, especially in states of critical illness and injury. In several studies it has been speculated that the beneficial effects of glutamine are dependent on the route of supply (luminal or systemic). The aim of this study was to investigate the relevance of both routes of glutamine delivery to in vitro intestinal cells and to explore the molecular basis for proposed beneficial glutamine effects: (a) by determining the relative uptake of radiolabelled glutamine in Caco-2 cells; (b) by assessing the effect of glutamine on the proteome of Caco-2 cells using a 2D gel electrophoresis approach; and (c) by examining glutamine incorporation into cellular proteins using a new mass spectrometry-based method with stable isotope labelled glutamine. Results of this study show that exogenous glutamine is taken up by Caco-2 cells from both the apical and the basolateral side. Basolateral uptake consistently exceeds apical uptake and this phenomenon is more pronounced in 5-day-differentiated cells than in 15-day-differentiated cells. No effect of exogenous glutamine supply on the proteome was detected. However, we demonstrated that exogenous glutamine is incorporated into newly synthesized proteins and this occurred at a faster rate from basolateral glutamine, which is in line with the uptake rates. Interestingly, a large number of rapidly labelled proteins is involved in establishing cell-cell interactions. In this respect, our data may point to a molecular basis for observed beneficial effects of glutamine on intestinal cells and support results from studies with critically ill patients where parenteral glutamine supplementation is preferred over luminal supplementation.