Effect of the antiepileptic drug sodium valproate on glutamine and glutamate metabolism in isolated human kidney tubules

We studied the effects of sodium valproate, a widely used antiepileptic drug and a hyperammonemic agent, on L-[1-14C]glutamine and L-[1-14C]glutamate metabolism in isolated human kidney-cortex tubules. Valproate markedly stimulated glutamine removal as well as the formation of ammonia, 14CO2, pyruvate, lactate and alanine, but it inhibited glucose synthesis; the increase in ammonia formation was explained by a stimulation by valproate mainly of flux through glutaminase (EC 3.5.1.2) and to a much lesser extent of flux through glutamate dehydrogenase (EC 1.4.1.3). By contrast, valproate did not stimulate glutamate removal or ammonia formation, suggesting that the increase in flux through glutamate dehydrogenase observed with glutamine as substrate was secondary to the increase in flux through glutaminase. Accumulation of pyruvate, alanine and lactate in the presence of valproate was less from glutamate than from glutamine. Inhibition by aminooxyacetate of accumulation of alanine from glutamine caused by valproate did not prevent the acceleration of glutamine utilization and the subsequent stimulation of ammonia formation. It is concluded from these data, which are the first concerning the in vitro metabolism of glutamine and glutamate in human kidney-cortex tubules, that the stimulatory effect of valproate is primarily exerted at the level of glutaminase in human renal cortex.     

Calcium-ion transport by intact synaptosomes. Intrasynaptosomal compartmentation and the role of the mitochondrial membrane potential.

1. The pathways and the fate of glutamate carbon and nitrogen were investigated in isolated guinea-pig kidney-cortex tubules. 2. At low glutamate concentration (1 mM), the glutamate carbon skeleton was either completely oxidized or converted into glutamine. At high glutamate concentration (5 mM), glucose, lactate and alanine were additional products of glutamate metabolism. 3. At neither concentration of glutamate was there accumulation of ammonia. 4. Nitrogen-balance calculations and the release of 14CO2 from L-[1-14C]glutamate (which gives an estimation of the flux of glutamate carbon skeleton through alpha-oxoglutarate dehydrogenase) clearly indicated that, despite the absence of ammonia accumulation, glutamate metabolism was initiated by the action of glutamate dehydrogenase and not by transamination reactions as suggested by Klahr, Schoolwerth & Bourgoignie [(1972) Am. J. Physiol. 222, 813-820] and Preuss [(1972) Am. J. Physiol. 222, 1395-1397]. Additional evidence for this was obtained by the use of (i) amino-oxyacetate, an inhibitor of transaminases, which did not decrease glutamate removal, or (ii) L-methionine DL-sulphoximine, an inhibitor of glutamine synthetase, which caused an accumulation of ammonia from glutamate. 5. Addition of NH4Cl plus glutamate caused an increase in both glutamate removal and glutamine synthesis, demonstrating that the supply of ammonia via glutamate dehydrogenase is the rate-limiting step in glutamine formation from glutamate. NH4Cl also inhibited the flux of glutamate through glutamate dehydrogenase and the formation of glucose, alanine and lactate. 6. The activities of enzymes possibly involved in the glutamate conversion into pyruvate were measured in guinea-pig renal cortex. 7. Renal arteriovenous-difference measurements revealed that in vivo the guinea-pig kidney adds glutamine and alanine to the circulating blood.     

Functional hepatocyte heterogeneity. Vascular 2-oxoglutarate is almost exclusively taken up by perivenous, glutamine-synthetase-containing hepatocytes

1. In isolated perfused rat liver maximal rates of 2-[1-14C]oxoglutarate uptake were about 0.4 mumol.g-1 .min-1; half-maximal rates of 2-[14C]oxoglutarate uptake were observed with influent concentrations of about 100 microM. 2-[14C]Oxoglutarate uptake by the liver was not affected by the direction of perfusion, but was decreased by about 80-90% when Na+ in the perfusion fluid was substituted by choline+, suggesting a Na+-dependence of hepatic 2-oxoglutarate uptake. In the absence of added ammonia, [14C]oxoglutarate uptake by the liver was about twice the net oxoglutarate uptake, indicating a simultaneous release of unlabeled oxoglutarate from perfused rat liver. 2. 14C-Labeled metabolites derived from [1-14C]oxoglutarate and recovered in the effluent perfusate were 14CO2 and 14C-labeled glutamate and glutamine; they accounted for 85-100% of the radiolabel taken up by the liver. 14CO2 was the major product (more than 70%) from [1-14C]oxoglutarate taken up the liver, provided glutamine synthesis was either inhibited by methionine sulfoximine or the endogenous rate of glutamine production was below 40 nmol.g-1.min-1. 3. Stimulation of glutamine synthesis by ammonia did not affect [14C]oxoglutarate uptake by the liver, but considerably increased net hepatic oxoglutarate uptake, indicating a decreased release of unlabeled oxoglutarate from the liver. Stepwise stimulation of hepatic glutamine synthesis led to a gradual decrease of 14CO2 production and radiolabel was recovered increasingly as [14C]glutamine in the effluent. At high rates of glutamine formation (i.e. about 0.6 mumol.g-1.min-1), about 60% of the [1-14C]oxoglutarate taken up by the liver was recovered in the effluent as [14C]glutamine. 14CO2 and [14C]glutamine production from added [1-14C]oxoglutarate were dependent on the rate of hepatic glutamine synthesis but not on the direction of perfusion. Extrapolation of 14C incorporation into glutamine to maximal rates of hepatic glutamine synthesis yielded an about 100% utilization of the [14C]oxoglutarate taken up by the liver for glutamine synthesis. This was again true for both the antegrade and the retrograde perfusion directions. On the other hand, addition of ammonia did not affect 14CO2 production from labeled oxoglutarate, when glutamine synthetase was inhibited by methionine sulfoximine. 4. The data suggest that vascular oxoglutarate is almost exclusively taken up by the small perivenous hepatocyte population containing glutamine synthetase, i.e. a cell population comprising only 6-7% of all hepatocytes. Thus, the findings demonstrate the existence of a, to date, uniquely zonally distributed oxoglutarate transport system which is probably Na+-dependent in the plasma membrane.(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.     

The conversion of alanine into glutamine in guinea-pig renal cortex. Essential role of pyruvate carboxylase.

1. The metabolism of L-alanine was studied in isolated guinea-pig kidney-cortex tubules. 2. In contrast with previous conclusions of Krebs [(1935) Biochem. J. 29, 1951-1969], glutamine was found to be the main carbon and nitrogenous product of the metabolism of alanine (at 1 and 5 mM). Glutamate and ammonia were only minor products. 3. At neither concentration of alanine was there accumulation of glucose, glycogen, pyruvate, lactate, aspartate or tricarboxylic acid-cycle intermediates. 4. Carbon-balance calculations and the release of 14CO2 from [U-14C]alanine indicate that oxidation of the alanine carbon skeleton occurred at both substrate concentrations. 5. A pathway involving alanine aminotransferase, glutamate dehydrogenase, glutamine synthetase, pyruvate dehydrogenase, pyruvate carboxylase and enzymes of the tricarboxylic acid cycle is proposed for the conversion of alanine into glutamine. 6. Strong evidence for this pathway was obtained by: (i) suppressing alanine removal by amino-oxyacetate, and inhibitor of transaminases, (ii) measuring the release of 14CO2 from [1-14C]alanine, (iii) the use of L-methionine DL-sulphoximine, an inhibitor of glutamine synthetase, which induced a large increase in ammonia release from alanine, and (iv) the use of fluoroacetate, an inhibitor of aconitase, which inhibited glutamine synthesis with concomitant accumulation of citrate from alanine. 7. In this pathway, the central role of pyruvate carboxylase, which explains the discrepancy between our results and those of Krebs (1935), was also demonstrated.     

Tricarboxylic acid-cycle metabolism in brain. Effect of fluoroacetate and fluorocitrate on the labelling of glutamate aspartate, glutamine and γ-amino butyrate

1. The effect of fluoroacetate and fluorocitrate on the compartmentation of the glutamate-glutamine system was studied in brain slices with l-[U-(14)C]glutamate, l-[U-(14)C]aspartate, [1-(14)C]acetate and gamma-amino[1-(14)C]butyrate as precursors and in homogenates of brain tissue with [1-(14)C]acetate. The effect of fluoroacetate was also studied in vivo in mouse brain with [1-(14)C]acetate as precursor. 2. Fluoroacetate and fluorocitrate inhibit the labelling of glutamine from all precursors but affect the labelling of glutamate to a much lesser extent. This effect is not due to inhibition of glutamine synthetase. It is interpreted as being due to selective inhibition of the metabolism of a small pool of glutamate that preferentially labels glutamine.     

Dibutyryl cyclic AMP decreases glutamine synthetase in cultured 3T3-L1 adipocytes

Glutamine synthetase specific activity increases greater than 100-fold during the insulin-mediated differentiation of confluent 3T3-L1 cells into adipocytes. Incubation of the adipocytes for 22 h with 0.5 mM dibutyryl cyclic AMP plus 0.5 mM theophylline, 0.2 mM 8-bromo-cyclic AMP, 10 micro M epinephrine, or 1 microgram of alpha 1-24 adrenocorticotropic hormone/ml decreased glutamine synthetase by greater than 60%. During the same incubation period, there was no effect of these compounds on protein or on the specific activities of glucose-6-P dehydrogenase or hexokinase. In the presence of 0.5 mM theophylline, the dibutyryl cyclic AMP-mediated decrease in glutamine synthetase activity was half-maximal at 50 micro M dibutyryl cyclic AMP. Furthermore, between 10 micro M and 5 mM dibutyryl cyclic AMP, the dibutyryl cyclic AMP-mediated decrease in glutamine synthetase was similar in the absence or presence of 1 microgram of insulin/ml. Immunotitration of glutamine synthetase activity from 3T3 adipocytes indicates that the dibutyryl cyclic AMP-mediated decrease in the activity is due to a decrease in the cellular content of glutamine synthetase molecules. We studied the effects of dibutyryl cyclic AMP on the synthesis and degradation of glutamine synthetase. Synthesis rate was estimated from the incorporation of L-[35S]methionine into glutamine synthetase during a 60-min incubation period. Degradation rate was estimated from the first order disappearance of radioactivity from glutamine synthetase in 3T3 adipocytes previously incubated with L-[35S]methionine. Glutamine synthetase was isolated by immunoprecipitation followed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Incubation of 3T3 adipocytes with dibutyrl cyclic AMP resulted in a rapid decline in the apparent synthesis rate of glutamine synthetase. In addition, dibutyryl cyclic AMP treatment increased the initial rate of glutamine synthetase degradation. The half-life of glutamine synthetase was 24.5 h in control cultures and 16 h in dibutyryl cyclic AMP-treated cultures. In contrast, dibutyryl cyclic AMP had little effect on the synthesis or degradation of soluble protein. Our data indicate that the dibutyryl cyclic AMP-mediated decrease in 3T3 adipocyte glutamine synthetase activity results from a decrease in the synthesis rate and an increase in the initial degradation rate of the enzyme.     

DL-7-azatryptophan and citrulline metabolism in the cyanobacterium Anabaena sp. strain 1F.

An alternative route for the primary assimilation of ammonia proceeds via glutamine synthetase-carbamyl phosphate synthetase and its inherent glutaminase activity in Anabaena sp. strain 1F, a marine filamentous, heterocystous cyanobacterium. Evidence for the presence of this possible alternative route to glutamate was provided by the use of amino acid analogs as specific enzyme inhibitors, enzymological studies, and radioistopic labeling experiments. The amino acid pool patterns of continuous cultures of Anabaena sp. strain 1F were markedly influenced by the nitrogen source. A relatively high concentration of glutamate was maintained in the amino acid pools of all cultures irrespective of the nitrogen source, reflecting the central role of glutamate in nitrogen metabolism. The addition of 1.0 microM azaserine increased the intracellular pools of glutamate and glutamine. All attempts to detect any enzymatic activity for glutamate synthase by measuring the formation of L-[14C]glutamate from 2-keto-[1-14C]glutarate and glutamine failed. The addition of 10 microM DL-7-azatryptophan caused a transient accumulation of intracellular citrulline and alanine which was not affected by the presence of chloramphenicol. The in vitro activity of carbamyl phosphate synthetase and glutaminase increased severalfold in the presence of azatryptophan. Results from radioisotopic labeling experiments with [14C]bicarbonate and L-[1-14C]ornithine also indicated that citrulline was formed via carbamyl phosphate synthetase and ornithine transcarbamylase. In addition to its effects on nitrogen metabolism, azatryptophan also affected carbon metabolism by inhibiting photosynthetic carbon assimilation and photosynthetic oxygen evolution.     

Inhibition of Astrocyte Glutamine Production by α-Ketoisocaproic Acid

Abstract: We have evaluated the effect of α-ketoisocaproic acid (KIC), the ketoacid of leucine, on the production of glutamine by cultured astrocytes. We used ¹⁵NH₄Cl as a metabolic tracer to measure the production of both [5-¹⁵N]glutamine, reflecting amidation of glutamate via glutamine synthetase, and [2-¹⁵N]glutamine, representing the reductive amination of 2-oxoglutarate via glutamate dehydrogenase and subsequent conversion of [¹⁵N]-glutamate to [2-¹⁵N]glutamine. Addition of KIC (1 mM) to the medium diminished the production of [5-¹⁵N]glutamine and stimulated the formation of [2-¹⁵N]glutamine with the overall result being a significant inhibition of net glutamine synthesis. An external KIC concentration as low as 0.06 mM inhibited synthesis of [5-¹⁵N]glutamine and a level as low as 0.13 mM enhanced labeling (atom% excess) of [2-¹⁵N]glutamine. Higher concentrations of KIC in the medium had correspondingly larger effects. The presence of KIC in the medium did not affect flux through glutaminase, which was measured using [2-¹⁵N]glutamine as a tracer. Nor did KIC inhibit the activity of glutamine synthetase that was purified from sheep brain. Addition of KIC to the medium caused no increased release of lactate dehydrogenase from the astrocytes, suggesting that the ketoacid was not toxic to the cells. KIC treatment was associated with an approximately twofold increase in the formation of ¹⁴CO₂ from [U-¹⁴C]glutamate, indicating that transamination of glutamate with KIC increases intraastrocytic α-ketoglutarate, which is oxidized in the tricarboxylic acid cycle. KIC inhibited glutamine synthesis more than any other ketoacid tested, with the exception of hydroxypyruvate. The data indicate that KIC diminishes flux through glutamine synthetase by lowering the intraastrocytic glutamate concentration below the K_m of glutamine synthetase for glutamate, which we determined to be ～7 mM.     

Hepatocyte heterogeneity in glutamate uptake by isolated perfused rat liver

Glutamate is simultaneously taken up and released by perfused rat liver, as shown by 14CO2 production from [1-14C]glutamate in the presence of a net glutamate release by the liver, turning to a net glutamate uptake at portal glutamate concentrations above 0.3 mM. 14CO2 production from portal [1-14C]glutamate is decreased by about 60% in the presence of ammonium ions. This effect is not observed during inhibition of glutamine synthetase by methionine sulfoximine. 14CO2 production from [1-14C]glutamate is not influenced by glutamine. Also, when glutamate accumulates intracellularly during the metabolism of glutamine (added at high concentrations, 5 mM), 14CO2 production from [1-14C]glutamate is not affected. If labeled glutamate is generated intracellularly from added [U-14C]proline, stimulation of glutamine synthesis by ammonium ions did not affect 14CO2 production from [U-14C]proline. After induction of a perivenous liver cell necrosis by CCL4, i.e. conditions associated with an almost complete loss of perivenous glutamine synthesis but no effect on periportal urea synthesis, 14CO2 production from [1-14C]glutamate is decreased by about 70%. The results are explained by hepatocyte heterogeneity in glutamate metabolism and indicate a predominant uptake of glutamate (that reaches the liver by the vena portae) by the small perivenous population of glutamine-synthesizing hepatocytes, whereas glutamate production from glutamine or proline is predominantly periportal. In view of the size of the glutamine synthetase-containing hepatocyte pool [Gebhardt, R. and Mecke, D. (1983) EMBO J. 2, 567-570], glutamate transport capacity of these hepatocytes would be about 20-fold higher as compared to other hepatocytes.     

Metabolic Fate of 14C-Labeled Glutamate in Astrocytes in Primary Cultures

The metabolic fate of L-[U-14C]- and L-[1-14C]glutamate was studied in primary cultures of mouse astrocytes. Conversion of the uniformly labeled compound to glutamine and aspartate was followed by determination of specific activities after dansylation with [3H]dansyl chloride and subsequent thin layer chromatography of the dansylated amino acids. Metabolic fluxes were calculated from the alterations of specific activities and the pool sizes, which were likewise measured by a dansylation method. Formation of 14CO2 from [1-14C]glutamate was determined by the trapping of CO2 in hyamine hydroxide in a gas-tight chamber, which is, in the known absence of glutamate decarboxylase activity in the cultured astrocytes, an unequivocal expression of the metabolic flux via alpha-ketoglutarate to CO2 and succinyl-CoA. The metabolic fluxes determined by these procedures amounted to 2.4 nmol/min/mg protein for glutamine synthesis, 1.1 nmol/min/mg protein for aspartate production, and 4.1 nmol/min/mg protein for formation and subsequent decarboxylation of alpha-ketoglutarate. The latter process was unaffected by virtually complete inhibition of glutamate-oxaloacetic transaminase with aminooxyacetic acid, indicating that the formation of alpha-ketoglutarate occurs as an oxidative deamination rather than as a transamination. This suggests that the formation of alpha-ketoglutarate from glutamate represents a net degradation, not an isotopic exchange.     

13N]Ammonia and L-[amide-13N]glutamine metabolism in glutaminase-sensitive and glutaminase-resistant murine tumors

The short-term metabolic fate of labeled nitrogen derived from [13N]ammonia or from L-[amide-13N]glutamine was determined in murine tumors known to be resistant (Ridgeway Osteogenic Sarcoma (ROS] or sensitive (Sarcoma-180 (S-180)) to glutaminase therapy. At 5 min after intraperitoneal injection of [13N]ammonia or of L-[amide-13N]glutamine, only about 0.7% of the label recovered in both tumors was in protein and nucleic acid. After [13N]ammonia administration, most of the label (over 80%) was in a metabolized form; a large portion of this metabolized label (50-57%) was in the urea fraction with a smaller amount in glutamine (37-42%). The major short-term fate of label derived from L-[amide-13N]glutamine was incorporation into components of the urea cycle with smaller amounts in the acidic metabolites and in acidic amino acids. No labeled urea was found during in vitro studies in which S-180 tumor slices were incubated with [13N]ammonia, suggesting that the [13N]urea formed in the tumor in the in vivo experiments was not due to de novo synthesis through carbamyl phosphate in the tumor. Both tumors exhibited very low glutamine synthetase activity. Following glutaminase treatment, glutamine synthetase and gamma-glutamyltransferase activities, while remaining low, increased in the resistant tumor but not in the sensitive tumor; this increase may be related to the insensitivity of the ROS tumor toward glutaminase treatment.     

Concomitant synthesis and degradation of glutamine in isolated rabbit kidney tubules

When rabbit kidney tubules were incubated with 1 mM [1-14C]glutamine as substrate, a release of 14CO2 together with a net production of glutamine were observed. That glutamine utilization was masked by higher rates of concomitant glutamine synthesis was demonstrated by: (i) inhibiting glutamine synthesis; and (ii) measuring the specific radioactivity of [1-14C]glutamine which fell during incubation.     

Alteration in Neuronal-Glial Metabolism of Glutamate by the Neurotoxin Kainic Acid

The effect of the excitotoxin kainic acid on glutamate and glutamine metabolism was studied in cerebellar slices incubated with D-[2-14C]glucose, [U-14C]gamma-aminobutyric acid, [3H]acetate, [U-14C]glutamate, and [U-14C]glutamine as precursors. Kainic acid (1 mM) strongly inhibited the labeling of glutamine relative to that of glutamate from all precursors except [2-14C]glucose and [U-14C]glutamine. Kainic acid did not inhibit glutamine synthetase directly. The data indicate that in the cerebellum kainic acid inhibits the synthesis of glutamine from the small pool of glutamate that is thought to be associated with glial cells. Kainic acid also markedly stimulated the efflux of glutamate from cerebellar slices and this release was not sensitive to tetrodotoxin. Kainic acid stimulated efflux of both glucose- and acetate-labeled glutamate. In contrast, veratridine released glucose-labeled glutamate preferentially via a tetrodotoxin-sensitive mechanism. Kainic acid did not release [U-14C]glutamate from synaptosomal fractions. These results suggest that the bulk of the glutamate released from cerebellar slices by kainic acid comes from nonsynaptic pools.     

Metabolic and secretory responses of parotid cells to cationic amino acids. Oxidation of the amino acids and interference with the oxidation of D-glucose or endogenous nutrients.

Cationic amino acids were recently found to stimulate amylase release from rat parotid cells. The possible relevance of their oxidative catabolism to such a secretory stimulation was investigated. D-Glucose, which was efficiently metabolized in parotid cells and which augmented O2 uptake above basal value, failed to affect basal or stimulated amylase release. L-Arginine, L-lysine and L-histidine failed to stimulate the oxidation of either exogenous D-[6-14C]glucose or endogenous nutrients in cells pre-labelled with [U-14C]palmitate or L-[U-14C]glutamine. The oxidation of L-[U-14C]arginine, L-[U-14C]ornithine, L-[U-14C]lysine and L-[U-14C]histidine, all tested at a 10 mM concentration, was much lower than that of D-[U-14C]glucose (5.6 mM). These findings argue against the view that the stimulation of amylase release by cationic amino acids would be related to their role as a source of energy in the parotid cells.     

Avian mitochondrial glutamine metabolism.

Intact avian liver mitochondria were shown to synthesize glutamine from glutamate in the absence of exogenous ATP and ammonia. With L-[U-14C]glutamate as the substrate, there was an approximate 1:1 stoichiometry between glutamate deaminated (as measured by the release of 14CO2 due to alpha-keto-[14C]glutarate oxidation) and glutamate amidated. With L-[15N]glutamate as the substrate, the isolated glutamine was shown by low and high resolution mass spectrometry of its phenylisothiocyanate derivative to contain 15N in both the alpha-amino and amide groups. Thus, for each mole of glutamate taken up, approximately 0.5 mol is deaminated and the other 0.5 mol serves as a substrate for glutamine synthetase previously localized in these mitochondria (Vorhaben, J. E., and Campbell, J. W. (1972) J. Biol. Chem. 247,2763). The permeability of L-glutamine to intact avian liver mitochondria was studied by a rapid centrifugation technique. Efflux as well as influx of L-glutamine were both rapid and appeared to occur by a passive, energy-independent process. These results indicate that the mitochondrial glutamine synthetase present in uricotelic species represents the primary ammonia detoxication reaction in that ammonia released intramitochondrially during amino acid catabolism is converted to glutamine for efflux to the cytosol where it may serve as a substrate for purine (uric acid) biosynthesis.     

Hepatocyte heterogeneity in glutamate metabolism and bidirectional transport in perfused rat liver

1. The metabolic fate of infused [1-14C]glutamate was studied in perfused rat liver. The 14C label taken up by the liver was recovered to 85 +/- 2% as 14CO2 and [14C]glutamine. Whereas 14CO2 production accounted for about 70% of the [1-14C]glutamate taken up under conditions of low endogenous rates of glutamine synthesis, stepwise stimulation of glutamine synthesis by NH4Cl increased 14C incorporation into glutamine at the expense of 14CO2 production. Extrapolation to maximal rates of hepatic glutamine synthesis yielded an about 100% utilization of vascular glutamate taken up by the liver for glutamine synthesis. This was observed in both, antegrade and retrograde perfusions and suggests an almost exclusive uptake of glutamate into perivenous glutamine-synthetase-containing hepatocytes. 2. Glutamate was simultaneously taken up and released from perfused rat liver. At a near-physiological influent glutamate concentration (0.1 mM), the rates of unidirectional glutamate influx and efflux were similar (about 100 and 120 nmol g-1 min-1, respectively). 3. During infusion of [1-14C]oxoglutarate (50 microM), addition of glutamate (2 mM) did not affect hepatic uptake of [1-14C]oxoglutarate. However, it increased labeled glutamate release from the liver about 10-fold (from 9 +/- 2 to 86 +/- 20 nmol g-1 min-1; n = 4), whereas 14CO2 production from labeled oxoglutarate decreased by about 40%. This suggests not only different mechanisms of oxoglutarate and glutamate transport across the plasma membrane, but also points to a glutamate/glutamate exchange. 4. Oxoglutarate was recently shown to be taken up almost exclusively by perivenous glutamine-synthetase-containing hepatocytes [Stoll, B & H?ussinger, D. (1989) Eur. J. Biochem. 181, 709-716] and [1-14C]oxoglutarate (9 microM) was used to label selectively the intracellular glutamate pool in this perivenous cell population. The specific radioactivity of this intracellular (perivenous) glutamate pool was assessed by measuring the specific radioactivity of newly synthesized glutamine which is continuously released from these cells into the perfusate. Comparison of the specific radioactivities of glutamine and glutamate released from perivenous cells indicates that about 60% of total glutamate release from the liver is derived from the perivenous glutamine-synthetase-containing cell population. Following addition of unlabeled glutamate (0.1 mM), unidirectional glutamate efflux from perivenous cells increased from about 30 to 80 nmol g-1 min-1, whereas glutamate efflux from non-perivenous (presumably periportal) hepatocytes remained largely unaltered (i.e. 20-30 nmol g-1 min-1). 5. It is concluded that, in the intact liver, vascular glutamate is almost exclusively taken up by the small perivenous hepatocyte population containing glutamine synthetase.     

Reversible reaction of cyanate with a reactive sulfhydryl group at the glutamine binding site of carbamyl phosphate synthetase.

Carbamyl phosphate synthetase from Escherichia coli reacts stoichiometrically (one to one) with [14C]cyanate to give a 14C-labeled complex which can be isolated by gel filtration. The formation of the complex is prevented if L-glutamine is present or if the enzyme is first reacted with 2-amino-4-oxo-5-chloropentanoic acid, a chloro ketone analog of glutamine which has been shown to react with a specific SH group in the glutamine binding site. The rate of complex formation is increased by ADP and decreased by ATP and HCO3-. The isolated complex is inactive with respect to glutamine-dependent synthetase activity. However, the reaction of cyanate with the enzyme is reversible. The rate of dissociation of the isolated complex is not affected by pH (over the pH range 6-10), is greatly increased by ATP and HCO3-, and is decreased by ADP. The allosteric effectors ornithine and UMP have no effect on either the rate of formation or the rate of dissociation of the complex; however, the apparent affinity of the enzyme for ATP is decreased by UMP and increased by ornithine. The site of reaction of cyanate with carbamyl phosphate synthetase, which is composed of a light and a heavy subunit, is with an SH group in the light subunit to give an S-carbamylcysteine residue. The binding of L-[14C]glutamine to the enzyme and the inhibition of glutamine-dependent synthetase activity by the chloroketone analog are both prevented by the presence of cyanate. The reaction with cyanate is considered to be with the same essential SH group which is located in the glutamine binding site and is alkylated by 2-amino-4-oxo-5-chloropentanoic acid. The bicarbonate-dependent effects of ATP suggest that formation of the activated carbon dioxide intermediate is accompanied by changes in the heavy subunit which functionally alter the properties of the glutamine binding site on the light subunit. The allosteric effects of ornithine and UMP are probably not related to this intersubunit interaction.     

Role of glucose in the regulation of glutamine metabolism in health and in type 1 insulin-dependent diabetes

To determine the effect of glucose availability on glutamine metabolism, glutamine kinetics were assessed under conditions of hyperglycemia resulting from 1) intravenous infusion of 7.5% dextrose in healthy adults and 2) insulin deficiency in young adults with insulin-dependent diabetes mellitus (IDDM). Eight healthy adults and five young adults with IDDM were studied in the postabsorptive state by use of a primed continuous infusion of D-[U-(14)C]glucose, L-[5,5,5-(2)H(3)]leucine, and L-[3, 4-(13)C]glutamine. Whether resulting from insulin deficiency or dextrose infusion, the rise in plasma glucose was associated with increased glucose turnover (23.5 +/- 0.7 vs. 12.9 +/- 0.3 micromol. kg(-1). min(-1), P < 0.01 and 20.9 +/- 2.5 vs. 12.8 +/- 0.4 micromol. kg(-1). min(-1), P = 0.03, in health and IDDM, respectively). In both cases, high blood glucose failed to alter glutamine appearance rate (R(a)) into plasma [298 +/- 9 vs. 312 +/- 14 micromol. kg(-1). h(-1), not significant (NS) and 309 +/- 23 vs 296 +/- 26 micromol. kg(-1). h(-1), NS, in health and IDDM, respectively] and the estimated fraction of glutamine R(a) arising from de novo synthesis (210 +/- 7 vs. 217 +/- 10 micromol. kg(-1). h(-1), NS and 210 +/- 16 vs. 207 +/- 21 micromol. kg(-1). h(-1), NS, in health and IDDM, respectively). When compared with the euglycemic day, the apparent contribution of glucose to glutamine carbon skeleton increased when high plasma glucose resulted from intravenous dextrose infusion in healthy volunteers (10 +/- 0.8 vs. 4.8 +/- 0.3%, P < 0.01) but failed to do so when hyperglycemia resulted from insulin deficiency in IDDM. We conclude that 1) the contribution of glucose to the estimated rate of glutamine de novo synthesis does not increase when elevation of plasma glucose results from insulin deficiency, and 2) the transfer of carbon from glucose to glutamine may depend on insulin availability.     

Regulation of enzyme turnover during tissue differentiation. Interactions of insulin, prolactin and cortisol in controlling the turnover of fatty acid synthetase in rabbit mammary gland in organ culture

1. Explants of mammary gland from mid-pregnant rabbits were cultured in Medium 199 containing combinations of insulin, prolactin and cortisol. With hormone combinations which included prolactin, a sustained increase in the apparent rate of synthesis and in the amount of fatty acid synthetase was measurable immunologically. Maximum increase was produced with insulin, prolactin and cortisol present together. 2. With prolactin present alone, synthetase activity in the explants decreased to undetectable values after 1 day in culture, whereas the incorporation of l-[U-(14)C]leucine into immunodetectable material increased. Prolactin may therefore direct the synthesis of immunologically cross-reactive precursors of fatty acid synthetase which are enzymically inactive. 3. Culture with dibutyryl cyclic AMP plus theophylline in the presence of insulin, prolactin and cortisol delayed the increase in the rate of synthesis and accumulation of the synthetase. These compounds may also prevent the apparent decrease in the rate of degradation of the synthetase which occurs on day 2 of culture. 4. A large decrease in the apparent rate of degradation of the synthetase on day 2 of culture occurs during culture with hormone combinations which include prolactin. The protein obtained by centrifugation of explant homogenates for 6min at 14000g(av.) is degraded continuously throughout the culture period. 5. This decrease in the apparent rate of degradation of the synthetase was measured by radio-immunological precipitation. It is probably part of a regulated programme of enzyme degradation and not a reflexion of the reutilization of radioactive amino acids for the following reasons. (a) The calculated increase in the amount of the synthetase in explants on day 2 of culture with insulin, prolactin and cortisol was approximately equal to the measured increase of the enzyme complex which accumulates in the explants. This suggests little or no enzyme degradation has occurred. (b) Explants were cultured for 24h with insulin, prolactin and cortisol. They were then incubated with l-[U-(14)C]leucine, washed and incubated again for up to 4(1/2)h. l-[U-(14)C]Leucine rapidly equilibrated with the intracellular amino acid pool. Within 10min of incubation after washing explants to remove endogenous l-[U-(14)C]leucine the previously linear incorporation of l-[U-(14)C]-leucine into total explant protein ceased. This suggests that protein is synthesized from an amino acid pool which rapidly equilibrates with amino acids in the culture medium. (c) Explants were cultured for 24h as described in (b) but after washing they were cultured with insulin, prolactin and cortisol for 24h. Approx. 90% of the radioactivity lost from the ;free' intracellular amino acid pool and from amino acids derived from the degradation of explant protein in this period was detected in the culture medium. This suggests that the ;free' intracellular amino acids and amino acids derived from protein degradation can equilibrate with amino acids in the medium. A residual ;free' radioactive amino acid pool was present in the tissue. (d) Casein represents approx. 20% of the protein synthesized after 1 day in culture with insulin, prolactin and cortisol. Histological evidence suggests that on day 2 of culture, casein is unlikely to be degraded in the tissue. No increase in the radioactivity incorporated into casein can be measured in the 23h after incubation of explants with l-[U-(14)C]leucine as described in (b). This suggests that the incorporation of radioactivity into proteins during culture after incubation with l-[U-(14)C]leucine is minimal. (e) Inhibition of protein synthesis in explants by cycloheximide after incubation with l-[U-(14)C]leucine does not reveal a latent continuous degradation of fatty acid synthetase on day 2 of culture which might have been masked by the high rates of protein synthesis and therefore the accumulation of the enzyme. 6. The conclusion is discussed that there is a real decrease (or even cessation) in the rate of degradation of fatty acid synthetase during the period when the enzyme accumulates in explants cultured with hormone combinations which contain prolactin.