A chemiluminescence fiber-optic biosensor system for the determination of glutamine in mammalian cell cultures.

A chemiluminescence fiber-optic biosensor system has been developed for determining glutamine in hybridoma cell cultures producing monoclonal antibodies against viral surface antigens. Glutaminase and glutamate oxidase (GLO) were immobilized onto aminopropyl glass beads via glutaraldehyde activation separately and packed in a column. Two separate columns containing immobilized GLO and catalase were placed upstream to eliminate endogenous glutamate. In the presence of ferricyanide, luminol reacted with hydrogen peroxide released from the enzymatic reactions to produce a chemiluminescence (CL) light signal which was detected and quantitated with a fiber-optic system. In combination with flow injection analysis it was possible to process samples virtually identically, thus avoiding difficulties in reproducing the CL signal. There was an excellent linear relationship between the CL response and standard glutamine concentration in the range 10(-6) to 10(-3) M. A complete analysis could be performed in 2 min including sampling and washing. Each immobilized enzyme column was stable for at least 300 repeated analyses without any loss of activity. When the biosensor system was used for the determination of glutamine in spent mammalian cell cultures, the values obtained compared well with those of high-performance liquid chromatography, thus validating the applicability of the CL fiber-optic system.     

Pathways of glutamine metabolism in Spodoptera frugiperda (Sf9) insect cells: evidence for the presence of the nitrogen assimilation system, and a metabolic switch by 1H/15N NMR

1H/15N and 13C NMR were used to investigate metabolism in Spodoptera frugiperda (Sf9) cells. Labelled substrates ([2-15N]glutamine, [5-15N]glutamine, [2-15N]glutamate, 15NH4Cl, [2-15N]alanine, and [1-13C]glucose) were added to batch cultures and the concentration of labelled excreted metabolites (alanine, NH4+, glutamine, glycerol, and lactate) were quantified. Cultures with excess glucose and glutamine produce alanine as the main metabolic by-product while no ammonium ions are released. 1H/15N NMR data showed that both the amide and amine-nitrogen of glutamine was incorporated into alanine in these cultures. The amide-nitrogen of glutamine was not transferred to the amine-position in glutamate (for further transamination to alanine) via free NH4+ but directly via an azaserine inhibitable amido-transfer reaction. In glutamine-free media 15NH4+ was consumed and incorporated into alanine. 15NH4+ was also incorporated into the amide-position of glutamine synthesised by the cells. These data suggest that the nitrogen assimilation system, glutamine synthetase/glutamate synthase (NADH-GOGAT), is active in glutamine-deprived cells. In cultures devoid of glucose, ammonium is the main metabolic by-product while no alanine is formed. The ammonium ions stem both from the amide and amine-nitrogen of glutamine, most likely via glutaminase and glutamate dehydrogenase. 13C NMR revealed that the [1-13C] label from glucose appeared in glycerol, alanine, lactate, and in extracellular glutamine. Labelling data also showed that intermediates of the tricarboxylic acid cycle were recycled to glycolysis and that carbon sources, other than glucose-derived acetylCoA, entered the cycle. Furthermore, Sf9 cell cultures excreted significant amounts glycerol (1.9-3.2 mM) and ethanol (6 mM), thus highlighting the importance of sinks for reducing equivalents in maintaining the cytosolic redox balance.     

High-affinity glutamate transporter GLAST/EAAT1 regulates cell surface expression of glutamine/neutral amino acid transporter ASCT2 in human fetal astrocytes

Neutral amino acid transporter ASCT2, together with high-affinity glutamate transporters, belongs to the SLC1 gene family of Na(+)-dependent solute carriers and is one of the major transporters of glutamine in cultured astrocytes. Besides glutamine and other high-affinity substrates--alanine, serine, cysteine or threonine, ASCT2 can also translocate protonated glutamate. The present study elucidated substrate-dependent trafficking of ASCT2 in differentiated primary cultures of human fetal astrocytes. The differentiation induced by 8-bromo-cAMP caused dramatic up-regulation of two co-localized and functionally linked astroglial proteins--glutamate transporter GLAST, that is the only high-affinity router of glutamate into cultured astrocytes, and glutamine synthetase (GS), a cytosolic enzyme that converts at least a part of the arriving glutamate into glutamine. In order to distinguish individual intracellular effects of these two substrates on ASCT2, in some cultures glutamine synthetase was effectively knocked down using siRNA silencing technique. In control conditions, regardless of GS levels, almost the entire ASCT2 immunoreactivity was restricted to the cytosol. Both glutamine and alanine, though to different extents, induced partial redistribution of ASCT2 from the cytosolic compartment to the plasma membrane. However, in cultures with high GS expression, micromolar concentrations of glutamate exhibited more pronounced effect on ASCT2 trafficking than the preferred substrates of this carrier. In contrast, glutamate had no effect on ASCT2 distribution in cultures devoid of GS. D-Aspartate, a metabolically inert substrate effectively transported by GLAST, had no effect in any cell culture utilized. It seems that intracellular glutamine produced by GS from glutamate that, in turn, is supplied by GLAST, is a more potent inducer of ASCT2 trafficking to the cell surface than the ASCT2-mediated translocation of extracellular substrates. At lower pH values (6.2-6.7), the cell surface pool of ASCT2 was significantly larger than at physiological pH. In addition, high concentrations of glutamate, independently from GLAST or glutamate receptor activation, induced further arrival of ASCT2 to the plasma membrane. The pH-dependent functional activation of ASCT2 and the ASCT2-mediated glutamate uptake may play important roles during ischemic acidosis or synaptic activity-induced local acidification.     

Kinetic properties of a phosphate-bond-driven glutamate-glutamine transport system in Streptococcus lactis and Streptococcus cremoris.

In Streptococcus lactis ML3 and Streptococcus cremoris Wg2 the uptake of glutamate and glutamine is mediated by the same transport system, which has a 30-fold higher affinity for glutamine than for glutamate at pH 6.0. The apparent affinity constant for transport (KT) of glutamine is 2.5 +/- 0.3 microM, independent of the extracellular pH. The KTS for glutamate uptake are 3.5, 11.2, 77, and 1200 microM at pH 4.0, 5.1, 6.0, and 7.0, respectively. Recalculation of the affinity constants based on the concentration of glutamic acid in the solution yield KTS of 1.8 +/- 0.5 microM independent of the external pH, indicating that the protonated form of glutamate, i.e., glutamic acid, and glutamine are the transported species. The maximal rates of glutamate and glutamine uptake are independent of the extracellular pH as long as the intracellular pH is kept constant, despite large differences in the magnitude and composition of the components of the proton motive force. Uptake of glutamate and glutamine requires the synthesis of ATP either from glycolysis or from arginine metabolism and appears to be essentially unidirectional. Cells are able to maintain glutamate concentration gradients exceeding 4 X 10(3) for several hours even in the absence of metabolic energy. The t1/2s of glutamate efflux are 2, 12, and greater than 30 h at pH 5.0, 6.0, and 7.0, respectively. After the addition of lactose as energy source, the rate of glutamine uptake and the level of ATP are both very sensitive to arsenate. When the intracellular pH is kept constant, both parameters decrease approximately in parallel (between 0.2 and 1.0 mM ATP) with increasing concentrations of the inhibitor. These results suggest that the accumulation of glutamate and glutamine is energized by ATP or an equivalent energy-rich phosphorylated intermediate and not by the the proton motive force.     

The Astroglial ASCT2 Amino Acid Transporter as a Mediator of Glutamine Efflux

Glutamine release from astrocytes is an essential part of the glutamate-glutamine cycle in the brain. Uptake of glutamine into cultured rat astrocytes occurs by at least four different routes. In agreement with earlier studies, a significant contribution of amino acid transport systems ASC, A, L, and N was detected. It has not been determined whether these systems are also involved in glutamine efflux or whether specific efflux transporters exist. We show here that ASCT2, a variant of transport system ASC, is strongly expressed in rat astroglia-rich primary cultures but not in neuron-rich primary cultures. The amino acid sequence of rat astroglial ASCT2 is 83% identical to that of mouse ASCT2. In Xenopus laevis oocytes expressing rat ASCT2, we observed high-affinity uptake of [U-14C]glutamine (Km = 70 microM) that was Na(+)-dependent, concentrative, and unaffected by membrane depolarization. When oocytes were preloaded with [U-14C]glutamine, no glutamine efflux was detected in the absence of extracellular amino acids. Neither lowering intracellular pH nor raising the temperature elicited efflux. However, addition of 0.1 mM unlabeled alanine, serine, cysteine, threonine, glutamine, or leucine to the extracellular solution resulted in a rapid release of glutamine from the ASCT2-expressing oocytes. Amino acids that are not recognized as substrates by ASCT2 were ineffective in this role. Extracellular glutamate stimulated glutamine release weakly at pH 7.5 but was more effective on lowering pH to 5.5, consistent with the pH dependence of ASCT2 affinity for glutamate. Our findings suggest a significant role of ASCT2 in glutamine efflux from astrocytes by obligatory exchange with extracellular amino acids. However, the relative contribution of this pathway to glutamine release from cells in vivo or in vitro remains to be determined.     

Methods for reducing the ammonia in hybridoma cell cultures

The factors which limit the proliferation of eukaryotic cells in vitro are still not well known. Ammonia is believed to be toxic for mammalian cell proliferation and secretion. We have tried two approaches to reducing the ammonia in the medium. We first limited the ammonia produced by the cells by replacing glutamine by glutamate. Then, we used two chemical engineering methods to eliminate accumulated ammonia. In one the used medium was passed through a natural cation exchanger: the clinoptilolite. In the other, the culture medium was passed through a hydrophobic microporous hollow fiber module. Replacing the glutamine by glutamate reduced the medium ammonia concentration. The physicochemical removal of ammonia induced a better cell growth, but not a better specific antibody secretion.     

Glucocorticoid Stimulation of Glutamine Synthetase Production in Cultured Rat Glioma Cells

Abstract: A sensitive radioisotopic assay has been used to examine the kinetic properties and regulation of biosynthesis of glutamine synthetase in C-6 glioma cultures. The K_m values for glutamate, MgATP, and ammonium ion were 5mM, 14 mM, and 0.042 mM, respectively, when measured at the pH optimum of 7.2. There was an absolute requirement for a divalent metal ion, with 15 mM- Mg²⁺ being the preferred ion at pH 7.2. Activity was completely inhibited after 30 min with 8 mM-L-methionhe sulfoximine. The addition of 1 μM-cortisol to C-6 cultures caused a two to threefold increase in glutamine synthetase specific activity over a 96-h period, while dexamethasone at the same concentration elevated the level some 7-10-fold. This was specific for glucocorticoids, as other steroid hormones or catecholamines did not significantly affect glutamine synthetase specific activity. Cycloheximide (30 μM) or actinomycin D (0.01 μg/ml) blocked the hormone response. The continued presence of hormone was required in order to maintain an elevated enzyme level. The results suggest that glucocorticoids act to induce glutamine synthetase by stimulating new enzyme synthesis.     

Damage to Neurons in Culture Following Medium Change: Role of Glutamine and Extracellular Generation of Glutamate

Abstract— Changing the medium of primary cell cultures of CNS origin causes severe damage that is mediated via the N -methyl- d -aspartate (NMDA)-type of glutamate receptors and dependent on the presence of glutamine in the medium. Data presented here show that glutamine has two roles in culture damage: glutamine is contaminated with a small amount of glutamate, which is responsible for initiating culture damage, and glutamine is the source of the glutamate that is produced extracellularly in damaged cultures. The NMDA receptor plays a critical role minutes after medium change when the glutamate contaminating the glutamine binds to NMDA receptors; during this time, addition of a low level (10–20 μ M ) of 2-amino-5-phos-phonovaleric acid can block most culture damage and the appearance of extracellular glutamate. A higher level (300 μ M ) of 2-amino-5-phosphonovaleric acid can protect cultures when added at much later times (30–60 min). Between 3 and 6 h after medium change, the concentration of extracellular glutamate starts to rise and accumulates until the end of the culture period (20 h). Medium removed from cultures at 3 h or later after medium change and incubated alone (i.e., with no cells) also continues to generate glutamate; filtration (0.22 μrn pore size) or centrifugation (18,000 g) stops the appearance of this glutamate. 6-Diazo-5-oxo- l -norleucine, an inhibitor of the mitochondrial enzyme glutaminase, blocks the generation of glutamate. Mitochondria or mitochondrial fragments are probably released from the damaged cells and then convert extracellular glutamine to glutamate, resulting in generation of a high extracellular glutamate concentration.     

Functional integration of the transport of ammonium, glutamate and glutamine in astrocytes

This short review surveys the effects of extracellular potassium, released by neuronal activity, on the fluxes of ammonium, glutamate and glutamine in astrocytes. There is evidence that each of these fluxes is modulated by potassium-induced changes in astrocytic pH. The result is viewed as an integrated response to neuronal activity. The unusually high permeability of astrocyte cell membrane to ammonium ions, together with the normal transmembrane gradient of pH, enables astrocytes to accumulate ammonium appreciably. However, at loci of neuronal activity, effective ammonium ion permeability is diminished and the cytosol is alkalinized, resulting in a local decline in intracellular ammonium concentration. Intracellular potassium concentration rises at these same loci, creating the conditions for a 'potassium-ammonium countercurrent' in which ammonium ions migrate intracellularly towards sites of neuronal activity as potassium ions diffuse away.Physiologic elevations of extracellular potassium evoke a marked 'paradoxical' increase in the velocity of glutamate uptake in astrocytes. This increase correlates well with the extent of potassium-induced alkalinization. Further, recent evidence identifies a major transporter of glutamine in astrocytes (System N) as a glutamine/proton exchanger. Potassium can reverse the transmembrane gradient of protons in astrocytes, and increase intracellular glutamine concentration, creating the conditions for a reversal of glutamine flux via System N from uptake to export. These flux changes, evoked by potassium released from active neurons, combine to accelerate glutamate-glutamine cycling.     

pH-conditional, ammonia assimilation-deficient mutants of Hydrogenomonas eutropha: evidence for the nature of the mutation

Two amination-deficient mutants of Hydrogenomonas eutropha, characterized by pH-dependent linear growth on non-amino acid substrates, were investigated to determine the exact nature of the mutation. Glutamate dehydrogenase, the only aminating enzyme found in wild-type cells, was present at similar levels in mutant cells. Phenylalanine and aspartate, which allowed normal growth of the mutants, could transaminate 2-oxoglutarate to glutamate, whereas alanine, which does not support normal growth, could not transfer its amino nitrogen to form glutamate. In H. eutropha, l-alanine is apparently synthesized by beta-decarboxylation of aspartate. Studies with NH(4) (+) ions as the sole nitrogen source demonstrated that growth rates of the mutant strains were dependent on both extracellular pH and NH(4) (+) ion concentration. Comparison of these results revealed that the growth rate of mutant cultures was proportional to the concentration of extracellular NH(3). Wild-type cultures were not dependent on extracellular NH(3) since exponential growth rates did not vary with pH or NH(4) (+) ion concentration. The results suggest that the mutant strains lack an NH(4) (+) ion transport system and consequently are dependent on NH(3) diffusion which does not support optimal amination rates. The significance of the findings for the amino acid metabolism of H. eutropha is discussed.     

Regulation of Nicotinamide Adenine Dinucleotide Phosphate-specific Glutamate Dehydrogenase in Germinated Spores of Geotrichum candidum

Germinating spores of Geotrichum candidum produce only a nicotinamide adenine dinucleotide phosphate-linked glutamate dehydrogenase. Synthesis of glutamate dehydrogenase was repressed by the presence of ammonia, whereas urea, glutamate, or glutamine were ineffective. The enzyme was not subject to catabolite repression and was localized in the cell sap fraction. The glutamate dehydrogenase has been purified 93-fold and showed maximal activity at pH 8.2 in the forward and reverse directions. When measuring the initial reaction rate at pH 7.2, a variety of tricarboxylic acid cycle intermediates displayed additive and unidirectional activation of the reductive amination reaction and inhibition of the oxidative deamination reaction. The modulating effects were pH-dependent and diminished at alkaline pH values. Substrate inhibition exerted by α-ketoglutarate was strongest at neutral pH.     

Relation of growth of Streptococcus lactis and Streptococcus cremoris to amino acid transport.

The maximum specific growth rate of Streptococcus lactis and Streptococcus cremoris on synthetic medium containing glutamate but no glutamine decreases rapidly above pH 7. Growth of these organisms is extended to pH values in excess of 8 in the presence of glutamine. These results can be explained by the kinetic properties of glutamate and glutamine transport (B. Poolman, E. J. Smid, and W. N. Konings, J. Bacteriol. 169:2755-2761, 1987). At alkaline pH the rate of growth in the absence of glutamine is limited by the capacity to accumulate glutamate due to the decreased availability of glutamic acid, the transported species of the glutamate-glutamine transport system. Kinetic analysis of leucine and valine transport shows that the maximal rate of uptake of these amino acids by the branched-chain amino acid transport system is 10 times higher in S. lactis cells grown on synthetic medium containing amino acids than in cells grown in complex broth. For cells grown on synthetic medium, the maximal rate of transport exceeds by about 5 times the requirements at maximum specific growth rates for leucine, isoleucine, and valine (on the basis of the amino acid composition of the cell). The maximal rate of phenylalanine uptake by the aromatic amino acid transport system is in small excess of the requirement for this amino acid at maximum specific growth rates. Analysis of the internal amino acid pools of chemostat-grown cells indicates that passive influx of (some) aromatic amino acids may contribute to the net uptake at high dilution rates.     

A novel chemiluminescence paper microfluidic biosensor based on enzymatic reaction for uric acid determination

In this work, chemiluminescence (CL) method was combined with microfluidic paper-based analytical device (μPAD) to establish a novel CL μPAD biosensor for the first time. This novel CL μPAD biosensor was based on enzyme reaction which produced H(2)O(2) while decomposing the substrate and the CL reaction between rhodanine derivative and generated H(2)O(2) in acid medium. Microchannels in μPAD were fabricated by cutting method. And the possible CL assay principle of this CL μPAD biosensor was explained. Rhodanine derivative system was used to reach the purpose of high sensitivity and well-defined signal for this CL μPAD biosensor. And the optimum reaction conditions were investigated. The quantitative determination of uric acid could be achieved by this CL μPAD biosensor with accurate and satisfactory result. And this biosensor could provide good reproducible results upon storage at 4°C for at least 10 weeks. The successful integration of μPAD and CL reaction made the final biosensor inexpensive, easy-to-use, low-volume, and portable for uric acid determination, which also greatly reduces the cost and increases the efficiency required for an analysis. We believe this simple, practical CL μPAD biosensor will be of interest for use in areas such as disease diagnosis.     

Chemiluminescence flow biosensor for glucose based on gold nanoparticle-enhanced activities of glucose oxidase and horseradish peroxidase

In this work, a novel chemiluminescence (CL) flow biosensor for glucose was proposed. Glucose oxidase (GOD), horseradish peroxidase (HRP) and gold nanoparticles were immobilized with sol-gel method on the inside surface of the CL flow cell. The CL detection involved enzymatic oxidation of glucose to d-gluconic acid and H(2)O(2), and then the generated H(2)O(2) oxidizing luminol to produce CL emission in the presence of HRP. It was found that gold nanoparticles could remarkably enhance the CL respond of the glucose biosensor. The enhanced effect was closely related to the sizes of gold colloids, and the smaller the size of gold colloids had the higher CL respond. The immobilization condition and the CL condition were studied in detail. The CL emission intensity was linear with glucose concentration in the range of 1.0 x 10(-5)molL(-1) to 1.0 x 10(-3)molL(-1), and the detection limit was 5 x 10(-6)molL(-1) (3sigma). The apparent Michaelis-Menten constant of GOD in gold nanoparticles/sol-gel matrix was evaluated to be 0.3mmolL(-1), which was smaller than that of GOD immobilized in sol-gel matrix without gold nanoparticles. The proposed biosensor exhibited short response time, easy operation, low cost and simple assembly, and the proposed biosensor was successfully applied to the determination of glucose in human serum.     

Transfer of glutamine between astrocytes and neurons

The export of glutamine from astrocytes, and the uptake of glutamine by neurons, are integral steps in the glutamate-glutamine cycle, a major pathway for the replenishment of neuronal glutamate. We review here the functional and molecular identification of the transporters that mediate this transfer. The emerging picture of glutamine transfer in adult brain is of a dominant pathway mediated by system N transport (SN1) in astrocytes and system A transport (SAT/ATA) in neurons. The participating glutamine transporters are functionally and structurally related, sharing the following properties: (a) unlike many neutral amino acid transporters which have proven to be obligate exchangers, these glutamine transporters mediate net substrate transfer energized by coupling to ionic gradients; (b) they are sensitive to small pH changes in the physiological range; (c) they are susceptible to adaptive and humoral regulation; (d) they are related structurally to the AAAP (amino acid and auxin permeases) family of transporters. A key difference between SN1 and the SAT/ATA transporters is the ready reversibility of glutamine fluxes via SN1 under physiological conditions, which allows SN1 both to sustain a glutamine concentration gradient in astrocytes and to mediate the net outward flux of glutamine. It is likely that the ASCT2 transporter, an obligate exchanger of neutral amino acids, displaces the SN1 transporter as the main carrier of glutamine export in proliferating astrocytes.     

METABOLISM OF AMINO ACIDS AND AMMONIA IN RAT BRAIN CORTEX SLICES IN VITRO: A POSSIBLE ROLE OF AMMONIA IN BRAIN FUNCTION

Abstract— (1) The sum of the values of total (tissue + medium) amino acid-N of glutamate, glutamine, γ-aminobutyrate, and aspartate (referred to as the glutamate system) and of ammonia-N of incubated rat brain cortex slices is approximately constant under a variety of metabolic conditions (presence or absence of glucose or of oxygen or in the presence of metabolic inhibitors such as aminooxyacetate, malonate, methionine sulfoximine, fluoroacetate, ouabain, 2:4 dinitrophenol, or Amytal). Fluctuations in the value of one constituent are compensated by fluctuations in the values of other constituents. The same applies to infant rat brain cortex slices and to rat brain synaptosome preparations. It is suggested that the constancy of the glutamate-ammonia system implies a coupling of neurons and glia in such a manner that glutamate released from the neurons during excitation is taken up by the glia and there converted to glutamine. The glutamine is returned to the neurons where it is hydrolysed to glutamate and ammonia. The glia, on this view, exercise an important buffering effect on the extracellular content of the excitatory amino acid, glutamate, and possibly on that of other functionally active amino acids emanating from the neurons. (2) The magnitude of the glutamate-ammonia system in the infant rat brain cortex is about 43% of that in the adult. It is suggested that, with maturity, the development of the glutamate-ammonia system is linked with the development of the citric acid cycle of operations. (3) The ammonia in the system is tightly linked to the activity of the ATP-controlled glutamine synthetase. (4) Proteolytic ammonia and amino acids are formed, during the incubation, to values that seem to be independent of a wide variety of metabolic conditions. The total value is approximately 10 μmol/g in the first h of incubation. (5) As the ammonium ion is necessary for the return of glutamate to the neuron in the form of glutamine, it is inferred that the ion plays a functional role in the nervous system by helping to maintain the steady state of glutamate in the neuron.     

Chemiluminescence flow biosensor for glucose using Mg-Al carbonate layered double hydroxides as catalysts and buffer solutions

In this work, serving as supports in immobilizing luminol reagent, catalysts of luminol chemiluminescence (CL), and buffer solutions for the CL reaction, Mg-Al-CO(3) layered double hydroxides (LDHs) were found to trigger luminol CL in weak acid solutions (pH 5.8). The silica sol-gel with glucose oxidase and horseradish peroxidase was immobilized in the first half of the inside surface of a clear quartz tube, and luminol-hybrid Mg-Al-CO(3) LDHs were packed in the second half. Therefore, a novel CL flow-through biosensor for glucose was constructed in weak acid solutions. The CL intensity was linear with glucose concentration in the range of 0.005-1.0mM, and the detection limit for glucose (S/N=3) was 0.1μM. The proposed biosensor exhibited excellent stability, high reproducibility and high selectivity for the determination of glucose and has been successfully applied to determine glucose in human plasma samples with satisfactory results. The success of this work has broken the bottleneck of the pH incompatibility between luminol CL and enzyme activity.     

Influence of ammonium and extracellular pH on the amino and organic acid contents of suspension culture cells of Acer pseudoplatanus

The effects of supplied ammonium and nitrate on the amino and organic acid contents and enzyme activities of cell suspension cultures of Acer pseudoplatanus L. were examined. Regardless of nitrogen source the pH of the culture medium strongly affected the malate and citrate contents of the cells; these organic acid pools declined at pH 5, but increased at pH 7 and 8. Over a period of two days, ammonium had little effect on the responses of the organic acid pool sizes to the pH of the medium. In contrast, ammonium had a strong influence on amino acid pool sizes, and this effect was dependent on the pH of the medium. At pH 5 there was no increase in cell ammonium or amino acid contents, but at higher pH values cellular ammonium content rose, accompanied by accumulation of glutamine, glutamate and asparagine. Over several days, supplied ammonium led to an increase in activity of glutamate dehydrogenase irrespective of any changes in internal ammonium and amino acid contents. If the pH of the medium was allowed to fall below pH 4 in the presence of ammonium, phosphoenolpyruvate (PEP) carboxylase activity declined to a very low value over several days; at higher pH, the activity of this enzyme, and that of NAD malic enzyme and NAD malate dehydrogenase, remained substantial irrespective of whether the nitrogen source was NH⁺₄ or NO-₃.     

Glutamine as a precursor for transmitter glutamate, aspartate and GABA in the cerebellum: a role for phosphate-activated glutaminase

Phosphate-activated glutaminase is present at high levels in the cerebellar mossy fiber terminals. The role of this enzyme for the production of glutamate from glutamine in the parallel-fiber terminals is unclear. In order to address this, we used light miroscopic immunoperoxidase and electron microscopic immunogold methods to study the localization of glutamate in rat cerbellar slices incubated with physiological K+ (3 mmol/L) and depolarizing K+ (40 mmol/L) concentrations, and during depolarizing conditions with the addition of glutamine and the glutaminase inhibitor 6-diazo-5-oxo-l-norleucine. During K+-induced depolarization glutamate labeling was redistributed from parallel-fiber terminals to glial cells. The nerve terminal content of glutamate was sustained when the slices were supplied with glutamine, which also reduced the accumulation of glutamate in glia. In spite of glutamine supplementation, the depolarized slices treated with 6-diazo-5-oxo-l-norleucine showed depletion of glutamate from parallel-fiber terminals and accumulation in glial cells. We conclude that cerebellar parallel-fiber terminals contain a glutaminase activity enabling them to synthesize glutamate from glutamine. Our results confirm that this is also true for the mossy fiber terminals. In addition, we show that, like for glutamate, the levels of aspartate in parallel-fiber terminals and GABA in Golgi fiber terminals can be maintained during depolarization if glutamine is present. This process is dependent on the activity of a glutaminase, as it can be inhibited by 6-diazo-5-oxo-l-norleucine, suggesting that the glutaminase reaction is important for glutamine to act as a precursor also for aspartate and GABA. The low levels of the kidney type of glutaminase that previously has been shown to be present in the parallel and Golgi fiber terminals could be sufficient to produce the transmitter amino acids. Alternatively, the amino acids could be produced from the liver type of glutaminase, which is not yet localized on the cellular level, or from an unknown glutminase.     

Regulation of the ammonia assimilatory enzymes in Salmonella typhimurium.

The regulation of glutamate dehydrogenase (EC 1.4.1.4), glutamine synthetase (EC 6.3.1.2), and glutamate synthase (EC 2.6.1.53) was examined for cultures of Salmonella typhimurium grown with various nitrogen and amino acid sources. In contrast to the regulatory pattern observed in Klebsiella aerogenes, the glutamate dehydrogenase levels of S. typhimurium do not decrease when glutamine synthetase is derepressed during growth with limiting ammonia. Thus, it appears that the S. typhimurium glutamine synthetase does not regulate the synthesis of glutamate dehydrogenase as reported for K. aerogenes. The glutamate dehydrogenase activity does increase, however, during growth of a glutamate auxotroph with glutamate as a limiting amino acid source. The regulation of glutamate synthase levels is complex with the enzyme activity decreasing during growth with glutamate as a nitrogen source, and during growth of auxotrophs with either glutamine or glutamate as limiting amino acids.