Ammonia production and pathways of glutamine utilization in rat kidney slices

Ammonia production from glutamine was studied in slices from non-acidotic and acidotic rat kidneys. Slices from non-acidotic kidneys made 53% as much ammonia from d-glutamine as from l-glutamine during the initial 15 min of incubation. Thereafter the production rate from the l-isomers accelerated while that from the d-isomers remained constant. The accelerated rate of ammonia production from l-glutamine was dependent upon tissue swelling since prevention of swelling reduced the production rate. Swelling activates the mitochondrial glutaminase I pathway as evidenced by the rise in ammonia produced per glutamine utilized ratio as well as by the accelerated rate of CO₂ production derived from the oxidative disposal of glutamine's carbon skeleton. Cortical slice swelling activates the mitochondrial pathway in a manner not unlike that seen in vivo during chronic acidosis and may reflect increased permeability to glutamine.Acidotic rat kidneys are not swollen in vivo while cortical slices initially produce 4-fold more ammonia than do non-acidotic slices. After 15 min, this 4-fold difference in total ammonia production drops to only a 2-fold difference due to the swelling-induced activation of the mitochondrial pathway. Consequently, slice swelling obliterates the important fact that ammonia production by the mitochondrial pathway is 15-fold greater in acidotic than in non-acidotic kidneys.     

Ammoniagenesis: d-glutamyltransferase as a source of ammonia in the rat kidney.

The contribution of D-glutamyltransferase (D-GT) (EC 2.3.2.1) to total renal ammonia production was determined by employing DL-methionine-DL-sulfoximine (MSO) as an inhibitor of D-GT. Rat kidney homogenates were assayed for NH3-liberating activity under optimal D-GT or gamma-glutamyltranspeptidase (gamma-GTP) (EC 2.3.2.2) conditions. MSO inhibits only D-GT activity. The contribution of D-GT to total renal ammonia production was then evaluated in the isolated perfused rat kidney employing identical substrate (5 mM L-glutamine) and inhibitor (15 mM MSO) concentrations as employed in the homogenate study. Under these conditions, MSO inhibits 70 percent of the total ammonia production by the normal kidney; in addition, the ratio of ammonia produced per glutamine taken up rose from 1.0 to 1.8. In kidneys from chronically acidotic rats, MSO reduced total ammonia production only 35 percent while the NH3/glutamine ratio rose from 1.0 to 1.8. D-GT appears to be the predominant source of NH3 production in the normal rat kidney; gamma-GTP does not contribute significantly. The rise in the NH3/glutamine ratio after D-GT inhibition is consistent with glutamine utilization via the activated mitochondrial glutaminase (EC 3.5.1.2)-glutamate dehydrogenase (EC 1.4.1.2) pathway.     

The purine nucleotide cycle and ammonia formation from glutamine by rat kidney slices.

To test the significance of the purine nucleotide cycle in renal ammoniagenesis, studies were conducted with rat kidney cortical slices using glutamate or glutamine labelled in the alpha-amino group with 15N. Glucose production by normal kidney slices with 2 mM-glutamine was equal to that with 3 mM-glutamate. With L-[15N]glutamate as sole substrate, one-third of the total ammonia produced by kidney slices was labelled, indicating significant deamination of glutamate or other amino acids from the cellular pool. Ammonia produced from the amino group of L-[alpha-15N]glutamine was 4-fold higher than from glutamate at similar glucose production rates. Glucose and ammonia formation from glutamine by kidney slices obtained from rats with chronic metabolic acidosis was found to be 70% higher than by normal kidney slices. The contribution of the amino group of glutamine to total ammonia production was similar in both types of kidneys. No 15N was found in the amino group of adenine nucleotides after incubation of kidney slices from normal or chronically acidotic rats with labelled glutamine. Addition of Pi, a strong inhibitor of AMP deaminase, had no effect on ammonia formation from glutamine. Likewise, fructose, which may induce a decrease in endogenous Pi, had no effect on ammonia formation. The data obtained suggest that the contribution of the purine nucleotide cycle to ammonia formation from glutamine in rat renal tissue is insignificant.     

The relationship of 4-aminobutyric acid metabolism to ammoniagenesis in renal cortex

Mitochondrial 4-aminobutyrate aminotransferase in rat kidney can utilize pyruvate as the acceptor for the amino group of 4-aminobutyrate. Renal 4-aminobutyrate aminotransferase activity at saturating equimolar concentration of 4-aminobutyrate and 5 mM pyruvate is 42.8 ± 2.5 μmol/g protein per h (mean ± S.E.M.) or 70% of 4-aminobutyrate aminotransferase activity with equimolar α-ketoglutarate. 4-Aminobutyrate aminotransferase in brain does not transaminate with pyruvate. Since pyruvate is an important mitochondrial metabolite in kidney, net disposal of glutamate via the 4-aminobutyrate pathway is possible. The renal 4-aminobutyrate pathway in the rat has other distinctive features when compared with the pathway in rat brain. Most inhibitors of rat neuronal glutamate decarboxylase were ineffective against the renal form of the enzyme, but 20 mM semicarbazide inhibited the latter form by 80% (P < 0.001) in vitro and reduced renal 4-aminobutyrate content by 75% (P < 0.001) in vivo. In the presence of 20 mM semicarbazide, ammoniagenesis by rat renal cortex slices incubated in 1 mM glutamine was inhibited 26% (P < 0.01). Semicarbazide was proportionately less effective (15% inhibition) when ammoniagenesis was stimulated (+243%) in slices prepared from chronically acidotic animals, and was no deterrant to ammoniagenesis when non-acidotic slices were incubated in supraphysiologic concentrations of 10 mM glutamine. We conclude that whereas integrity of the renal 4-aminobutyrate pathway may contribute to glutamate disposal and thus ammoniagenesis under physiologic conditions, the pathway is a passive participant in the overall process of ammoniagenesis.     

Acidotic alterations in oxidative metabolism influencing rat renal slice ammoniagenesis

We believe that two findings are interconnected and help to comprehend a major mechanism behind the regulation of renal ammonia production during acidosis. First, slices from acidotic compared to control and alkalotic rats produce more ammonia from glutamine. Second, inhibition of renal oxidative metabolism at various points by metabolic inhibitors augments slice ammoniagenesis. Based on this, our purpose was to determine whether enhanced renal ammoniagenesis during acidosis could occur through the same mechanism as the metabolic inhibitors. However, metabolic inhibitors (malonate; arsenite; 2,4-dinitrophenol) usually decrease while acidosis increases slice gluconeogenesis. There is one known exception. Fluorocitrate, which blocks citrate metabolism, simulates the acidotic condition by enhancing both ammonia and glucose production. Accordingly, a block of oxidative metabolism if located prior to citrate oxidation in the tricarboxylic acid cycle could theoretically augment ammoniagenesis during acidosis. Lactate, is a major renal fuel whose oxidative metabolism would be blocked by fluorocitrate. There, we concentrated on the effects of acidosis on lactate as well as glutamine metabolism. Lactate decarboxylation decreases in the face of increased glucose production during acidosis, and lactate inhibition of glutamine decarboxylation decreases in slices from acidotic rats. Also, we found lesser oxygen consumption in the presence of lactate by kidney slices from acidotic rats compared to control and alkalotic rats. We postulate that relatively less incorporation of lactate into the TCA cycle, causing decreased citrate formation and citrate oxidation during acidosis, contributes, at least in part, to acidotic adaptation of ammoniagenesis.     

Metabolism of glutamine and glutamic acid by isolated perfused kidneys of normal and acidotic rats

1. When isolated kidneys from fed rats were perfused with glutamine the rate of ammonia release at pH7.4 (110–360μmol/h per g dry wt.) was one to two times that of glutamine removal. Glucose formation from 5mm-glutamine was 16μmol/h per g. If kidneys were perfused with glutamine at pH7.1 (10–13mm-sodium bicarbonate) there was no increase in glutamine removal or in the formation of ammonia or glucose. 2. When isolated kidneys from fed rats were perfused with glutamate at pH7.4, glucose formation was 59μmol/h per g, glutamine formation was 182μmol/h per g and ammonia release was negligible. At pH7.1 glutamine synthesis was inhibited and formation of ammonia and glucose were increased. 3. In perfused kidneys from acidotic rats, which had received 1.5% (w/v) NH₄Cl to drink for 7–10 days, gluconeogenesis from glutamine was enhanced (101μmol/h per g). Glutamine removal and ammonia formation were also increased, compared with the rates in perfused kidney from normal rats. The extra glutamine consumed was equivalent to the extra glucose formed. 4. When the kidney from the 7–10-day-acidotic rat was perfused with glutamate gluconeogenesis was increased (113μmol/h per g). Synthesis of glutamine was decreased, and ammonia release was approximately equal to the rate of glutamate removal. 5. The time-course of these metabolic alterations was investigated after the rapid induction of acidosis by infusion of 0.25m-HCl into the right side of the heart. The increase in gluconeogenesis from glutamine developed gradually over several hours. When kidneys from 6h-acidotic rats were perfused with glutamate, formation of glucose and glutamine were both rapid. 6. In acidotic rat kidneys perfused with glutamine, tissue concentrations of glutamate and glucose 6-phosphate were increased compared with those in control perfused kidneys from non-acidotic rats. 7. The results are discussed in terms of control of the renal metabolism of glutamine. In particular, it is suggested that in acidotic rats glucose formation is the major fate of the carbon of the extra glutamine utilized by the kidney, and that inhibition of glutamine synthetase could contribute to the increase in intracellular ammonia concentration in the kidney.     

Renal glutamine utilization: glycylglycine stimulation of gamma-glutamyltransferase

Glycylglycine stimulation of renal glutamine utilization was studied on the homogenate, subcellular and purified enzyme level. The results clearly establish the existence of two glutamine utilizing pathways, the mitochondrial dependent L-glutamine amidohydrolase (PDG) and a second, extramitochondrial pathway. In contrast to the mitochondrial pathway which produces stoichiometric amounts of ammonia and glutamate, this second pathway hydrolyzes glutamine to produce ammonia and transfers the gamma-glutamyl moiety, producing gamma-glutamyl peptides. In the crude systems, containing cyclotransferase, the gamma-glutamyl moiety appears mainly as 5-oxoproline; however, in the enzyme preparation, purified 112-fold, gamma-glutamyl peptides (transpeptidation) and a small amount of glutamate (hydrolysis) appear. D-Glutamine was also hydrolyzed, in contrast to the stereospecific PDG, but at less than one-half the rate of the L-isomer. The molecular weight of this extramitochondrial D- and L-glutamine utilizing enzyme was estimated by gel filtration on a Sephadex G-200 column and found to be approximately 70 000. Based on product formation, molecular weight estimation and copurification with the activity responsible for p-nitroanilide release from gamma-glutamyl-p-nitroanilide, we conclude that this reaction is catalyzed by gamma-glutamyltranspeptidase. Glycylglycine stimulated this enzyme to produce more ammonia while decreasing the appearance of glutamate; in contrast, the mitochondrial glutaminase was unaffected by glycylglycine. This extramitochondrial glutamine utilizing pathway can make a significant contribution to in vivo renal ammoniagenesis.     

The transport and metabolism of glutamine by kidney-cortex mitochondria from normal and acidotic rats.

1. The oxidation of glutamine by kidney-cortex mitochondria from normal and acidotic rats was not inhibited by avenaciolide, which did inhibit glutamate uptake and oxidation. The oxidation of glutamine by these mitochondria was always greater than that of glutamate. Direct measurements of the metabolism of [1-14C]glutamine in the presence of glutamate, and of [1-14C]glutamate in the presence of glutamine, demonstrated that the uptake and metabolism of external glutamate is insufficient to account for the observed rate of glutamine uptake and metabolism. Thus the postulated glutamine/glutamate antiport does not play a quantitatively important role in the metabolism of glutamine by renal mitochondria. 2. Rapid swelling of these mitochondria was observed in iso-osmotic solutions of L-glutamine and L-glutamyl-gamma-monohydroxamate but not in D-glutamine or L-isoglutamine (1-amido-2-aminoglutaric acid). Thus a relatively specific glutamine uniport exists in these mitochondria. 3. The utilization of glutamine was increased about 3-fold in mitochondria from chronically acidotic rats. Thus mitochondrial adaptations play an important part in the renal response to metabolic acidosis.     

Renal extraction of glutamine from plasma and whole blood: studies in dogs and rats

The change in plasma and blood cell pools of L-glutamine during a single pass through the kidney was studied in dogs and rats. It was shown that the glutamine content of blood cells does not change following one passage through the renal vascular bed in normal or acidotic dogs. Furthermore, an infusion of L-glutamine elevating by 10-fold the plasma concentration of this amino acid only minimally changed the blood cells' glutamine content. Therefore within the time frame of acute experiments, the dog blood cells can be assumed to be impermeable to glutamine in vivo. Accordingly, renal glutamine extraction can be measured using either whole blood or plasma arteriovenous difference in this species. However, the latter value is larger and therefore can be measured more accurately. In normal rats, no net renal glutamine extraction is measured. In contrast, a considerable renal glutamine uptake occurs in acidotic rats, 23% of the extracted glutamine coming from the blood cell pool. A load of glutamine in vivo significantly elevates both the plasma and the blood cell concentration. It is concluded (i) that the renal extraction of glutamine is best estimated using plasma arteriovenous difference in the dog, especially when the renal extraction is small; (ii) that whole blood measurements should be obtained in the rat.     

Metabolism of glutamine and glutamate by rat renal tubules. Study with 15N and gas chromatography-mass spectrometry

Gas chromatography-mass spectrometry was utilized to study the metabolism of [15N]glutamate, [2-15N]glutamine, and [5-15N]glutamine in isolated renal tubules prepared from control and chronically acidotic rats. The main purpose was to determine the nitrogen sources utilized by the kidney in various acid-base states for ammoniagenesis. Incubations were performed in the presence of 2.5 mM 15N-labeled glutamine or glutamate. Experiments with [5-15N]glutamine showed that in control animals approximately 90% of ammonia nitrogen was derived from 5-N of glutamine versus 60% in renal tubules from acidotic rats. Experiments with [2-15N]glutamine or [15N]glutamate indicated that in chronic acidosis approximately 30% of ammonia nitrogen was derived either from 2-N of glutamine or glutamate-N by the activity of glutamate dehydrogenase. Flux through glutamate dehydrogenase was 6-fold higher in chronic acidosis versus control. No 15NH3 could be detected in renal tubules from control rats when [2-15N]glutamine was the substrate. The rates of 15N transfer to other amino acids and to the 6-amino groups of the adenine nucleotides were significantly higher in normal renal tubules versus those from chronically acidotic rats. In tubules from chronically acidotic rats, 15N abundance in 15NH3 and the rate of 15NH3 appearance were significantly higher than that of either the 6-amino group of adenine nucleotides or the 15N-amino acids studied. The data indicate that glutamate dehydrogenase activity rather than glutamate transamination is primarily responsible for augmented ammoniagenesis in chronic acidosis. The contribution of the purine nucleotide cycle to ammonia formation appears to be unimportant in renal tubules from chronically acidotic rats.     

The pathway of glutamate metabolism in rat brain mitochondria

1. The pathway of glutamate metabolism in non-synaptic rat brain mitochondria was investigated by measuring glutamate, aspartate and ammonia concentrations and oxygen uptakes in mitochondria metabolizing glutamate or glutamine under various conditions. 2. Brain mitochondria metabolizing 10mm-glutamate in the absence of malate produce aspartate at 15nmol/min per mg of protein, but no detectable ammonia. If amino-oxyacetate is added, the aspartate production is decreased by 80% and ammonia production is now observed at a rate of 6.3nmol/min per mg of protein. 3. Brain mitochondria metabolizing glutamate at various concentrations (0-10mm) in the presence of 2.5mm-malate produce aspartate at rates that are almost stoicheiometric with glutamate disappearance, with no detectable ammonia production. In the presence of amino-oxyacetate, although the rate of aspartate production is decreased by 75%, ammonia production is only just detectable (0.3nmol/min per mg of protein). 4. Brain mitochondria metabolizing 10mm-glutamine and 2.5mm-malate in States 3 and 4 were studied by using glutamine as a source of intramitochondrial glutamate without the involvement of mitochondrial translocases. The ammonia production due to the oxidative deamination of glutamate produced from the glutamine was estimated as 1nmol/min per mg of protein in State 3 and 3nmol/min per mg of protein in State 4. 5. Brain mitochondria metabolizing 10mm-glutamine in the presence of 1mm-amino-oxyacetate under State-3 conditions in the presence or absence of 2.5mm-malate showed no detectable aspartate production. In both cases, however, over the first 5min, ammonia production from the oxidative deamination of glutamate was 21-27nmol/min per mg of protein, but then decreased to approx. 1-1.5nmol/min per mg. 6. It is concluded that the oxidative deamination of glutamate by glutamate dehydrogenase is not a major route of metabolism of glutamate from either exogenous or endogenous (glutamine) sources in rat brain mitochondria.     

Ammonia formation from glutamine isomers by nonacidotic and acidotic perfused rat kidneys.

The following points summarize these findings: (i) there are 2 glutamine utilizing enzyme systems in the rat kidney; (ii) the cytoplasmic glutamyltransferase system hydrolyzes either glutamine isomer while the mitochondrial localized glutaminase 1 is specific for the L-isomer; (iii) the cytoplasmic pathway contributes 70% of the total renal ammonia production in the normal kidney; (iv) chronic metabolic acidosis results in a 20-fold activation of the mitochondrial glutaminase 1 pathway.     

Effects of Branched-Chain L-Amino Acids, L-Phenylalanine, and L-Methionine on the Transport of L-Glutamine in Rat Brain Cortex In Vitro. Influence of Cations

Abstract: Uptake of L-glutamine (2 mM) by rat brain cortex slices against a concentration gradient is markedly inhibited (40%) by branched-chain Lamino acids (1 mM), L-phenylalanine (1 mM), or L-methionine (1 mM); that of L-asparagine (2 mM) is much less affected by these amino acids. Other amino acids investigated have little or no effect on cerebral L-glutamine uptake. The suppressions of L-glutamine uptake by the inhibitory amino acids are apparently blocked by high [K⁺], which itself has little or no effect on glutamine uptake. This abolition of suppression is partly explained by high [K⁺] retention of endogenous glutamine; in the absence of Ca²⁺ such retention disappears. The inhibitory amino acids (1 mM) also enhance the release of endogenous glutamine, exogenous glutamine with which slices have been loaded, or glutamine synthesized in the slices from exogenous glutamate. The enhanced release of endogenous glutamine is diminished by high [K⁺]. The suppression of glutamine uptake by the branched-chain amino acids is independent of the concentration of glutamine at low concentrations (0.25–0.5 mM), indicating non-competition, but is reduced with high concentration of glutamine. The inhibition by L-phenylalanine is noncompetitive. L-Glutamine (2 mM) exerts no inhibition of the cerebral uptakes of the branched-chain L-amino acids or Lphenylalanine (0.25–2 mM). The inhibitory amino acids are as active in suppressing L-glutamine uptake with immature rat brain slices as with adult, although the uptake, against a gradient, of L-glutamine in the infant rat brain is about one-half that in the adult. They are also just as inhibitory on the concentrative uptake of L-glutamine by a crude synaptosomal preparation derived from rat brain cortex. Such a nerve ending preparation takes up L-glutamine (0.25 mM), against a gradient, at about ninefold the rate at which it is taken up by cortex slices (for equal amounts of protein), and the uptake process is markedly suppressed by high [K⁺] in contrast to the effects of high [K⁺] with slices. The possible physiological and pathological consequences of the suppression of glutamine uptake are discussed.     

Arteriovenous differences for amino acids and lactate across kidneys of normal and acidotic rats.

1. Arteriovenous differences fro amino acids across kidneys of normal and chronically acidotic rats were measured. Glutamine was the only amino acid extracted in increased amounts in acidosis. There was a considerable production of serine by kidneys from both normal and acidotic rats. 2. The arterial blood concentration of glutamine was significantly decreased in acidotic animals. 3. The glutamine extracted by kidneys of acidotic rats was largely and probably exclusively derived from the plasma. 4. The blood lactate concentration was unchanged in acidosis, as was the uptake of lactate by the kidney.     

Role of hippurate in acidosis induced adaptation in renal gamma-glutamyltransferase

Metabolic acidosis results in an adaptation in renal γ-glutamyltransferase (γ-GT) and a doubling of hippurate excretion. The greater rate of γ-glutamohydroxamate, γ-GHA, formation from L-glutamine, but not from glutathione, by acidotic kidney homogenates suggest an increased γ-glutamyl-enzyme complex formation and a preference for glutamine as the γ-glutamyl donor in acidosis. Hippurate added $\text{in}$$\text{vitro}$ to cortical homogenates or microsomes mimics the affect of acidosis upon γ-GHA formation from glutamine. Acid extracts of urine stimulated ammonia formation from glutamine using cortical microsomes in agreement with the measured hippurate levels. Administering an exogenous hippurate load to fasting nonacidotic rats doubled ammonia excretion and the rate of γ-GHA formation by cortical homogenates. These results are consistent with the acidosis induced adaptation in renal γ-GT governed by hippurate.     

The purine nucleotide cycle and ammoniagenesis in rat kidney tubules

The contribution of the purine nucleotide cycle to renal ammoniagenesis was examined in cortical tubule suspensions prepared from acidotic rats and incubated with [alpha-15N]glutamine, [15N]glutamate, or [15N]aspartate. Labeling of ammonia and adenine nucleotides was determined after enzymatic transformations designed to circumvent the technical problem that 15NH3 and H2O have the same nominal mass. Labeling of the adenine nucleotide was undetectable (less than 10%) even after 1 h of incubation. From the measured concentrations of adenine nucleotides and ammonia and the labeling of the ammonia, the flux through the purine nucleotide cycle was calculated to account for less than 1% of the deamination of alpha-amino groups from all three substrates. The glutamate dehydrogenase reaction is therefore the likely pathway for deamination. The rate of 15NH3 production from [alpha-15N]glutamine was two or three times greater than from added [15N]glutamate, indicating a preference for intracellularly generated glutamate. 15NH3 production from added [15N]aspartate was similar to and perhaps slightly greater than that from added [15N]glutamate.     

Organic mercurial diuresis: inhibition of glutamine utilization in the acidotic rat.

Organic mercurials inhibit mitochondrial glutamine metabolism in vitro while metabolic acidosis, a condition in which the predominant renal fuel is glutamine, potentiates mercurial diuresis. The following studies were undertaken to determine whether potentiation of diuresis reflects mercurial inhibition of glutamine utilization. (1) All three mercurials employed (mersalyl, chlormerodrin, and p-chloromercuribenzoate) are diuretics in the rat and this effect was potentiated by NH4Cl. (2) Despite reabsorbing less sodium, mercurial-treated rats had lower kidney ATP content (4.35 +/- 0.26 and 3.84 +/- 0.43 mumol/g dry weight (mercurial plus NH4Cl) than did controls (4.95 +/- 0.31 and 4.87 +/- 0.39 mumol/g dry weight (NH4Cl). (3) Isolated kidneys from NH4Cl and NH4Cl plus mercurial treated rats were perfused with 1 mM L-[U-14C]glutamine to determine rates of extraction and oxidation. Mercurial-treated acidotic rat kidneys had a reduced rate of glutamine uptake (40.8 +/- 7.4 vs. 64.8 +/- 5.8 mumol/h per kidney), a diminished rate of glutamine conversion to CO2 (14.8 +/- 3.6 vs. 26.4 +/- 5.2 mumol/h per kidney), and a reduction in glucose production (16 +/- 5 vs. 27 +/- 4 mumol/h per kidney). These results are consistent with an effect of organic mercurials upon glutamine utilization, limiting ATP availability, and thereby reducing tubular active sodium reabsorption.     

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

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

A 15N-n.m.r. study of cerebral, hepatic and renal nitrogen metabolism in hyperammonaemic rats.

1. Rats were infused with 15NH4+ or L-[15N]alanine to induce hyperammonaemia, a potential cause of hepatic encephalopathy. HClO4 extracts of freeze-clamped brain, liver and kidney were analysed by 15N-n.m.r. spectroscopy in combination with biochemical assays to investigate the effects of hyperammonaemia on tissue concentrations of ammonia, glutamine, glutamate and urea. 2. 15NH4+ infusion resulted in a 36-fold increase in the concentration of blood ammonia. Cerebral glutamine concentration increased, with 15NH4+ incorporated predominantly into the gamma-nitrogen atom of glutamine. Incorporation into glutamate was very low. Cerebral ammonia concentration increased 5-10-fold. The results suggest that the capacity of glutamine synthetase for ammonia detoxification was saturated. 3. Pretreatment with the glutamine synthetase inhibitor L-methionine DL-sulphoximine resulted in 84% inhibition of [gamma-15N]glutamine synthesis, but incorporation of 15N into other metabolites was not observed. The result suggests that no major alternative pathway for ammonia detoxification, other than glutamine synthetase, exists in rat brain. 4. In the liver 15NH4+ was incorporated into urea, glutamine, glutamate and alanine. The specific activity of 15N was higher in the gamma-nitrogen atom of glutamine than in urea. A similar pattern was observed when [15N]alanine was infused. The results are discussed in terms of the near-equilibrium states of the reactions involved in glutamate and alanine formation, heterogeneous distribution in the liver lobules of the enzymes involved in ammonia removal and their different affinities for ammonia. 5. Synthesis of glutamine, glutamate and hippurate de novo was observed in kidney. Hippurate, as well as 15NH4+, was contributed by co-extracted urine. 6. The potential utility and limitations of 15N n.m.r. for studies of mammalian metabolism in vivo are discussed.     

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.