Inhibition of Glutamine Transport in Rat Brain Mitochondria by Some Amino Acids and Tricarboxylic Acid Cycle Intermediates

Glutamine transport into rat brain synaptic and non-synaptic mitochondria has been monitored by the uptake of [³H]glutamine and by mitochondrial swelling. The concentration of glutamate in brain mitochondria is calculated to be high, 5–10 mM, indicating that phosphate activated glutaminase localized inside the mitochondria is likely to be dormant and the glutamine taken up not hydrolyzed. The uptake of [³H]glutamine is largely stereospecific. It is inhibited by glutamate, asparagine, aspartate, 2-oxoglutarate and succinate. Glutamate inhibits this uptake into synaptic and non-synaptic mitochondria by 95 and 85%, respectively. The inhibition by glutamate, asparagine, aspartate and succinate can be explained by binding to an inhibitory site whereas the inhibition by 2-oxoglutarate is counteracted by aminooxyacetic acid, which indicates that it is dependent on transamination. The glutamine-induced swelling, a measure of a very low affinity uptake, is inhibited by glutamate at a glutamine concentration of 100 mM, but this inhibition is abolished when the glutamine concentration is raised to 200 mM. This suggests that the very low affinity glutamine uptake is competitively inhibited by glutamate. Furthermore, glutamine-induced swelling is inhibited by 2-oxoglutarate, succinate and malate, similarly to that of the [³H]glutamine uptake. The properties of the mitochondrial glutamine transport are not identical with those of a recently purified renal glutamine carrier.     

Alpha-adrenergic stimulation of glutamine metabolism in isolated rat hepatocytes.

The mechanisms by means of which phenylephrine stimulates glutamine metabolism were studied in isolated rat hepatocytes. In the first 2 min after phenylephrine addition there was a rapid fall in the concentrations of intracellular 2-oxoglutarate and glutamate, presumably owing to activation of 2-oxoglutarate dehydrogenase. This was followed 2-3 min later by activation of glutaminase and by increases in glutamate and 2-oxoglutarate. Activation of glutaminase by phenylephrine was due to direct stimulation of the enzyme rather than to reversal of inhibition by the decrease in 2-oxoglutarate and glutamate. The stimulation of glutaminase by phenylephrine is partly due to an increase in the affinity of the enzyme for ammonia, its essential activator. It is concluded that stimulation of steady-state flux through the pathway from glutamine to glucose and urea can only be achieved by stimulation of glutaminase, the first enzyme in the pathway.     

Intracellular localization and properties of phosphate-dependent glutaminase in rat mesenteric lymph nodes.

Phosphate-dependent glutaminase was present at approximately similar activities in lymph nodes from mammals other than rat, and in thymus, spleen, Peyer's patches and bone marrow of the rat. This suggests that glutamine is important in all lymphoid tissues. Phosphate-dependent glutaminase activity was shown to be present primarily in the mitochondria of rat mesenteric lymph nodes, and most of the activity could be released by detergents. The properties of the enzyme in mitochondrial extracts were investigated. The pH optimum was 8.6 and the Km for glutamine was 2.0 mM. The enzyme was activated by phosphate, other phosphorylated compounds including phosphoenolpyruvate, and also leucine: 50% activation occurred at 5, 0.2 and 0.6 mM for phosphate, phosphoenolpyruvate and leucine respectively. The enzyme was inhibited by glutamate, 2-oxoglutarate, citrate and ammonia, and by N-ethylmaleimide and diazo-5-oxo-L-norleucine; 50% inhibition was observed at 0.7 and 0.1 mM for glutamate and 2-oxoglutarate respectively. Some of these properties may be important in the control of the enzyme activity in vivo.     

Transport of glutamine by Streptococcus bovis and conversion of glutamine to pyroglutamic acid and ammonia

Streptococcus bovis JB1 cells energized with glucose transported glutamine at a rate of 7 nmol/mg of protein per min at a pH of 5.0 to 7.5; sodium had little effect on the transport rate. Because valinomycin-treated cells loaded with K and diluted into Na (pH 6.5) to create an artificial delta psi took up little glutamine, it appeared that transport was driven by phosphate-bond energy rather than proton motive force. The kinetics of glutamine transport by glucose-energized cells were biphasic, and it appeared that facilitated diffusion was also involved, particularly at high glutamine concentrations. Glucose-depleted cultures took up glutamine and produced ammonia, but the rate of transport per unit of glutamine (V/S) by nonenergized cells was at least 1,000-fold less than the V/S by glucose-energized cells. Glutamine was converted to pyroglutamate and ammonia by a pathway that did not involve a glutaminase reaction or glutamate production. No ammonia production from pyroglutamate was detected. S. bovis was unable to take up glutamate, but intracellular glutamate concentrations were as high as 7 mM. Glutamate was produced from ammonia via a glutamate dehydrogenase reaction. Cells contained high concentrations of 2-oxoglutarate and NADPH that inhibited glutamate deamination and favored glutamate formation. Since the carbon skeleton of glutamine was lost as pyroglutamate, glutamate formation occurred at the expense of glucose. Arginine deamination is often used as a taxonomic tool in classifying streptococci, and it had generally been assumed that other amino acids could not be fermented. To our knowledge, this is the first report of glutamine conversion to pyroglutamate and ammonia in streptococci.     

Mechanistic studies on Azospirillum brasilense glutamate synthase.

The reaction mechanism of Azospirillum brasilense glutamate synthase has been investigated by several approaches. 15N nuclear magnetic resonance studies demonstrate that the amide nitrogen of glutamine is reductively transferred to 2-oxoglutarate in an irreversible manner with no release of the transferred ammonia group into the medium. Identical results were obtained using thio-NADPH and acetylpyridine-NADPH, which are shown to be less efficient substrates of the enzyme than NADPH. Similarly, no exchange of the ammonia group being transferred with exogenous ammonium ion was observed during catalysis. The glutamate formed as the product of the iminoglutarate reduction was determined to be in the L configuration. The enzyme was also found to catalyze, under anaerobic conditions, the exchange of the 4proS H of NADPH with solvent both in the absence and in the presence of 2-oxoglutarate and glutamine. The reductive half-reaction is therefore a reversible segment of the overall irreversible amidotransferase reaction. 15N NMR studies also showed that the enzyme does not catalyze glutamate dehydrogenase/oxidase reactions or any observable glutaminase activity under neutral (pH 7.5) conditions. Glutaminase activity was also not observable with the reduced enzyme alone or in the presence of D-glutamate (a competitive inhibitor of glutamate synthase with respect to 2-oxoglutarate, with a Ki of about 11 microM) or with the oxidized enzyme in the presence of 2-oxoglutarate, D-glutamate, or NADP+. These data confirm species-dependent differences of A. brasilense glutamate synthase with respect to the enzyme from other sources.     

Properties of phosphate activated glutaminase in astrocytes cultured from mouse brain

Astrocytes in primary cultures contain a relatively high activity, of phosphate activated glutaminase, although it is significantly lower than that of synaptosomal enriched preparations. The relatively high glutaminase activity in the astrocytes appears not to be caused by substrate induction, since a 10-fold variation in the glutamine concentration of the culture medium does not affect the activity. Of the reaction products, only glutamate inhibits astrocytic glutaminase whereas that of synaptosomal enriched preparations is inhibited by both glutamate and ammonia. Similar to the synaptosomal enzyme, glutaminase in astrocytes is inhibited about 50% by N-ethylmaleimide, indicating N-ethylmaleimide-sensitive and-insensitive compartments of the enzyme. Calcium activates glutaminase in astrocytes as in synaptosomes, by promoting phosphate activation. Except for the lower activity and the lack of effect of ammonia, the properties of the astroglial glutaminase has been found to be no different from that of the synaptosomal one. The relatively unrestrained astroglial glutaminase may, however, argue against the concept of a glutamine cycle operating in a stoichiometric manner.Abbreviations NEM N-ethylmaleimide - PAG Phosphate-activated glutaminase - PMB p-mercuribenzoate     

Phosphate-Activated Glutaminase in the Crude Mitochondrial Fraction (P2 Fraction) from Human Brain Cortex

The kinetics and other properties of phosphate-activated glutaminase have for the first time been studied in the crude mitochondrial fraction (P2 fraction) from human brain. The enzyme is for unexplained reasons inactivated postmortem. The enzyme activity decreases by storing the tissue or homogenate at 37 degrees C. The inactivation is not caused by formation of a dialysable inhibiting compound. No large proteolytic degradation has occurred, since the phosphate-activated glutaminase-like immunoreactive band did not disappear during the storage. The molecular weight of the subunit of the enzyme as determined by immunoblots of sodium dodecyl sulfate-treated homogenates from human brain is estimated to be approximately 64 K. The enzyme has been shown to have a pH optimum of 8.6; it is activated by phosphate, inhibited by glutamate, and partially inhibited by ammonia. Double-inverse plots of enzyme activity against phosphate are concave-upward, and more so in the presence of an inhibitor. The inhibition by glutamate appears to be noncompetitive with the substrate glutamine, and competitive with the activator phosphate. These kinetic properties are not significantly different from our earlier observations concerning phosphate-activated glutaminase from pig brain and pig kidney.     

Glutaminase in neurons and astrocytes cultured from mouse brain: Kinetic properties and effects of phosphate,glutamate, and ammonia

Phosphate activated glutaminase comprises two kinetically distinguishable enzyme forms in cultures of cerebellar granule cells, of cortical neurons and of astrocytes. Specific activity of glutaminase is higher in cultured neurons compared with astrocytes. Glutaminase is activated by phosphate in all cell types investigated, however, glutaminase in astrocytes reguires a much higher concentration of phosphate for half maximal activation. One of the products, glutamate, inhibits the enzyme strongly, whereas the other product ammonia has only a slight inhibitory action on the enzyme.     

Activation and coupling of the glutaminase and synthase reaction of glutamate synthase is mediated by E1013 of the ferredoxin-dependent enzyme, belonging to loop 4 of the synthase domain

Crystal structures of glutamate synthase suggested that a conserved glutamyl residue of the synthase domain (E1013 of Synechocystis sp. PCC 6803 ferredoxin-dependent glutamate synthase, FdGltS) may play a key role in activating glutamine binding and hydrolysis and ammonia transfer to the synthase site in this amidotransferase, in response to the ligation and redox state of the synthase site. The E1013D, N, and A, variants of FdGltS were overproduced in Escherichia coli cells, purified, and characterized. The amino acyl substitutions had no effect on the reactivity of the synthase site nor on the interaction with ferredoxin. On the contrary, a dramatic decrease of activity was observed with the D (approximately 100-fold), N and A (approximately 10,000-fold) variants, mainly due to an effect on the maximum velocity of the reaction. The E1013D variant showed coupling between glutamine hydrolysis at the glutaminase site and 2-oxoglutarate-dependent L-glutamate synthesis at the synthase site, but a sigmoid dependence of initial velocity on L-glutamine concentration. The E1013N variant exhibited hyperbolic kinetics, but the velocity of glutamine hydrolysis was twice that of glutamate synthesis from 2-oxoglutarate at the synthase site. These results are consistent with the proposed role of E1013 in signaling the presence of 2-oxoglutarate (and reducing equivalents) at the synthase site to the glutaminase site in order to activate it and to promote ammonia transfer to the synthase site through the ammonia tunnel. The sigmoid dependence of the initial velocity of the glutamate synthase reaction of the E1013D mutant on glutamine concentration provides evidence for a participation of glutamine in the activation of glutamate synthase during the catalytic cycle.     

Subcellular localization of enzymes involved in the assimilation of Ammonia by soybean root nodules

Ammonia, the primary product of nitrogen fixation is rapidly incorporated into a number of amino acids such as glutamate and aspartate. A novel enzyme system glutamine: 2-oxoglutarate aminotransferase oxidoreductase, which probably has an important role in ammonia assimilation has been detected, in the present studies, in the rhizobial fraction of soybean root nodules and in Rhizobium japonicum grown in culture. The role of this latter enzyme and other enzymes such as glutamate dehydrogenase, aspartate aminotransferase and alanine aminotransferase in ammonia assimilation by soybean nodules is discussed.     

Glutamine metabolism by rumen microorganisms: effect of monensin]

Transformation of glutamine of mixed population of microorganisms-symbionts is demonstrated. Protection of glutamine and its intermediates (glutamate and pyroglutamate) under the influence of ionophore (monensin) is found. It is accompanied by the reduced (by 30-70 per cent and more) levels of ammonia formation, total VFA, acetate, butyrate, pH, alpha-ketoglutarate dehydrogenase and glutamine synthetase at parallel increase of L-aspartate and L-alanine: 2-oxoglutarate, aminotransferase activity, redox potential of stability of protein content. It is suggested that the rapid change of Eh level on the 24th hour of incubation reflects the main stage of pyroglutamate formation being one of the final products of glutamine degradation when monensin is used. Ionophore affects first of all the inhibition of metabolic processes in gram-positive rumen microorganisms.     

Glutamate Dehydrogenase Reaction as a Source of Glutamic Acid in Synaptosomes

The role of the glutamate dehydrogenase reaction as a pathway of glutamate synthesis was studied by incubating synaptosomes with 5 mM 15NH4Cl and then utilizing gas chromatography-mass spectrometry to measure isotopic enrichment in glutamate and aspartate. The rate of formation of [15N]glutamate and [15N]aspartate from 5 mM 15NH4Cl was approximately 0.2 nmol/min/mg of protein, a value much less than flux through glutaminase (4.8 nmol/min/mg of protein) but greater than flux through glutamine synthetase (0.045 nmol/min/mg of protein). Addition of 1 mM 2-oxoglutarate to the medium did not affect the rate of [15N]glutamate formation. O2 consumption and lactate formation were increased in the presence of 5 mM NH3, whereas the intrasynaptosomal concentrations of glutamate and aspartate were unaffected. Treatment of synaptosomes with veratridine stimulated reductive amination of 2-oxoglutarate during the early time points. The production of ([15N]glutamate + [15N]aspartate) was enhanced about twofold in the presence of 5 mM beta-(+/-)-2-aminobicyclo [2.2.1]heptane-2-carboxylic acid, a known effector of glutamate dehydrogenase. Supplementation of the incubation medium with a mixture of unlabelled amino acids at concentrations similar to those present in the extracellular fluid of the brain had little effect on the intrasynaptosomal [glutamate] and [aspartate]. However, the enrichment in these amino acids was consistently greater in the presence of supplementary amino acids, which appeared to stimulate modestly the reductive amination of 2-oxoglutarate. It is concluded: (a) compared with the phosphate-dependent glutaminase reaction, reductive amination is a relatively minor pathway of synaptosomal glutamate synthesis in both the basal state and during depolarization; (b) NH3 toxicity, at least in synaptosomes, is not referable to energy failure caused by a depletion of 2-oxoglutarate in the glutamate dehydrogenase reaction; and (c) transamination is not a major mechanism of glutamate nitrogen production in nerve endings.     

Activation of Glutamate Dehydrogenase by Leucine and Its Nonmetabolizable Analogue in Rat Brain Synaptosomes

Leucine and beta-(+/-)-2-aminobicyclo[2.2.1]heptane-2-carboxylic acid (BCH) stimulated, in a dose-dependent manner, reductive amination of 2-oxoglutarate in rat brain synaptosomes treated with Triton X-100. The concentration dependence curves were sigmoid, with 10-15-fold stimulations at 15 mM leucine (or BCH); oxidative deamination of glutamate also was enhanced, albeit less. In intact synaptosomes, leucine and BCH elevated oxygen uptake and increased ammonia formation, consistent with stimulation of glutamate dehydrogenase (GDH). Enhancement of oxidative deamination was seen with endogenous as well as exogenous glutamate and with glutamate generated inside synaptosomes from added glutamine. With endogenous glutamate, the stimulation of oxidative deamination was accompanied by a decrease in aspartate formation, which suggests a concomitant reduction in flux through aspartate aminotransferase. Activation of reductive amination of 2-oxoglutarate by BCH or leucine could not be demonstrated even in synaptosomes depleted of internal glutamate. It is suggested that GDH in synaptosomes functions in the direction of glutamate oxidation, and that leucine may act as an endogenous activator of GDH in brain in vivo.     

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.     

Developmental change of endogenous glutamate and gamma-glutamyl transferase in cultured cerebral cortical interneurons and cerebellar granule cells,and in mouse cerebral cortex and cerebellum in vivo

The developmental change of endogenous glutamate, as correlated to that of gamma-glutamyl transferase and other glutamate metabolizing enzymes such as phosphate activated glutaminase, glutamate dehydrogenase and aspartate, GABA and ornithine aminotransferases, has been investigated in cultured cerebral cortex interneurons and cerebellar granule cells. These cells are considered to be GABAergic and glutamatergic, respectively. Similar studies have also been performed in cerebral cortex and cerebellum in vivo. The developmental profiles of endogenous glutamate in cultured cerebral cortex interneurons and cerebellar granule cells corresponded rather closely with that of gamma-glutamyl transferase and not with other glutamate metabolizing enzymes. In cerebral cortex and cerebellum in vivo the developmental profiles of endogenous glutamate, gamma-glutamyl transferase and phosphate activated glutaminase corresponded with each other during the first 14 days in cerebellum, but this correspondence was less good in cerebral cortex. During the time period from 14 to 28 days post partum the endogenous glutamate concentration showed no close correspondence with any particular enzyme. It is suggested that gamma-glutamyltransferase regulates the endogenous glutamate concentration in culture neurons. The enzyme may also be important for regulation of endogenous glutamate in brain in vivo and particularly in cerebellum during the first 14 days post partum. Gamma-glutamyl transferase in cultured neurons and brain tissue in vivo appears to be devoid of maleate activated glutaminase.Abbreviations used Asp-T aspartate aminotransferase (EC 2.6.1.1) - GABA-T GABA aminotransferase (EC 2.6.1.19) - GAD glutamate decarboxylase (EC 4.1.1.15) - gamma-GT gamma-glutamyl transferase (gamma-glutamyl transpeptidase) (EC. 2.3.2.2) - Glu glutamate - GDH glutamate dehydrogenase (EC 1.4.1.3) - GS glutamine synthetase (EC 6.3.1.2) - MAG maleate activated glutaminase - Orn-T ornithine aminotransferase (EC 2.6.1.13) - PAG phosphate activated glutaminase (EC 3.5.1.1)     

Utilization of [15N]glutamate by cultured astrocytes.

The metabolism of 0.25 mM-[15N]glutamic acid in cultured astrocytes was studied with gas chromatography-mass spectrometry. Almost all 15N was found as [2-15N]glutamine, [2-15N]glutamine, [5-15N]glutamine and [15N]alanine after 210 min of incubation. Some incorporation of 15N into aspartate and the 6-amino position of the adenine nucleotides also was observed, the latter reflecting activity of the purine nucleotide cycle. After the addition of [15N]glutamate the ammonia concentration in the medium declined, but the intracellular ATP concentration was unchanged despite concomitant ATP consumption in the glutamine synthetase reaction. Some potential sources of glutamate nitrogen were identified by incubating the astrocytes for 24 h with [5-15N]glutamine, [2-15N]glutamine or [15N]alanine. Significant labelling of glutamate was noted with addition of glutamine labelled on either the amino or the amide moiety, reflecting both glutaminase activity and reductive amination of 2-oxoglutarate in the glutamate dehydrogenase reaction. Alanine nitrogen also is an important source of glutamate nitrogen in this system.     

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.     

Pentylenetetrazole inhibits glutamate dehydrogenase and aspartate aminotransferase, and stimulates GABA aminotransferase in homogenates from rat cerebral cortex

The mechanism by which pentylenetetrazole provokes convulsions in animals has been investigated by measuring its influence in vitro on the activities of several enzymes of glutamate metabolism in rat brain homogenates. Pentylenetetrazole does not affect the specific activities of glutamine synthetase, glutaminase, or glutamate decarboxylase; it inhibits those of glutamate dehydrogenase and aspartate aminotransferase, and stimulates that of gamma-aminobutyric acid (GABA) aminotransferase. The overall consequence of the action of pentylenetetrazole on the activities of these enzymes should be an increase in the concentration of glutamate and a decrease in that of GABA. This modulation of glutamate and GABA metabolism by pentylenetetrazole could contribute to the triggering of convulsions.     

Amino acid sequence of the trypsin-generated C3d fragment from human complement factor C3.

Energy metabolism in proliferating cultured rat thymocytes was compared with that of freshly prepared non-proliferating resting cells. Cultured rat thymocytes enter a proliferative cycle after stimulation by concanavalin A and Lymphocult T (interleukin-2), with maximal rates of DNA synthesis at 60 h. Compared with incubated resting thymocytes, glucose metabolism by incubated proliferating thymocytes was 53-fold increased; 90% of the amount of glucose utilized was converted into lactate, whereas resting cells metabolized only 56% to lactate. However, the latter oxidized 27% of glucose to CO2, as opposed to 1.1% by the proliferating cells. Activities of hexokinase, 6-phosphofructokinase, pyruvate kinase and aldolase in proliferating thymocytes were increased 12-, 17-, 30- and 24-fold respectively, whereas the rate of pyruvate oxidation was enhanced only 3-fold. The relatively low capacity of pyruvate degradation in proliferating thymocytes might be the reason for almost complete conversion of glucose into lactate by these cells. Glutamine utilization by rat thymocytes was 8-fold increased during proliferation. The major end products of glutamine metabolism are glutamate, aspartate, CO2 and ammonia. A complete recovery of glutamine carbon and nitrogen in the products was obtained. The amount of glutamate formed by phosphate-dependent glutaminase which entered the citric acid cycle was enhanced 5-fold in the proliferating cells: 76% was converted into 2-oxoglutarate by aspartate aminotransferase, present in high activity, and the remaining 24% by glutamate dehydrogenase. With resting cells the same percentages were obtained (75 and 25). Maximal activities of glutaminase, glutamate dehydrogenase and aspartate aminotransferase were increased 3-, 12- and 6-fold respectively in proliferating cells; 32% of the glutamate metabolized in the citric acid cycle was recovered in CO2 and 61% in aspartate. In resting cells this proportion was 41% and 59% and in mitogen-stimulated cells 39% and 65% respectively. Addition of glucose (4 mM) or malate (2 mM) strongly decreased the rates of glutamine utilization and glutamate conversion into 2-oxoglutarate by proliferating thymocytes and also affected the pathways of further glutamate metabolism. Addition of 2 mM-pyruvate did not alter the rate of glutamine utilization by proliferating thymocytes, but decreased the rate of metabolism beyond the stage of glutamate significantly. Formation of acetyl-CoA in the presence of pyruvate might explain the relatively enhanced oxidation of glutamate to CO2 (56%) by proliferating thymocytes.     

The formation of ornithine from proline in animal tissues

1. Homogenates of liver or kidney from rat, mouse, dog and guinea pig formed ornithine from proline but not from glutamate. Rat kidney was most active in this reaction and was used for further studies. 2. The overall reaction was found to be catalysed by proline oxidase to yield glutamic gamma-semialdehyde, followed by transamination of this product with glutamate as catalysed by ornithine-keto acid aminotransferase. 3. The unfavourable equilibrium of the ornithine-keto acid aminotransferase reaction was overcome chiefly by glutamate dehydrogenase in the tissue, which removed the alpha-oxoglutarate produced, by reduction with endogenous ammonia and NADH. 4. Aspartate aminotransferase in these preparations also aided in the removal of alpha-oxoglutarate. In this case the overall reaction was driven also by the rapid decarboxylation of oxaloacetate. 5. No evidence could be found for a pathway of ornithine synthesis involving acylated intermediates as has been observed in some micro-organisms. 6. The rate of ornithine synthesis in homogenates of several rat tissues paralleled the activity of ornithine-keto acid aminotransferase in these tissues, indicating that this enzyme was rate-determining for the synthesis. 7. The possible influence of these reactions on urea synthesis is discussed.