Metabolism of absorbed aspartate,asparagine, and arginine by rat small intestine in vivo

l-[U-¹⁴C]aspartate, l-[U-¹⁴C]asparagine, and l-[U-¹⁴C]arginine were administered luminally into isolated segments of rat jejunum in situ, and the radioactive products appearing in venous blood from the segment were identified and quantified, in a continuation of similar studies with l-glutamate and l-glutamine (Windmueller H.G. and Spaeth, A. E. (1975) Arch. Biochem. Biophys. 171, 662–672). Aspartate, administered alone (6 mm) or with 18 other amino acids plus glucose, was absorbed more rapidly than glutamate, but, as with glutamate, less than 1% was recovered intact in intestinal venous blood. More than 50% of aspartate carbon was recovered in CO₂, 24% in organic acids, mostly lactate, 12% in other amino acids (alanine, glutamate, proline, ornithine, and citrulline), and 10% in glucose, apparently the first demonstration of gluconeogenesis by intestine in vivo. In contrast to aspartate and glutamine, nearly all asparagine was absorbed intact, less than 1% being catabolized. About 4% of the absorbed dose was incorporated into the acid-insoluble fraction of intestine, as was the case with all the amino acids studied. In conventional or germ-free rats, only 60% of arginine was absorbed intact, while 33% was hydrolyzed to ornithine and urea. The urea and 38% of the ornithine were released into the blood; the remaining ornithine was metabolized further by intestine to citrulline, proline, glutamate, organic acids, and CO₂. Catabolism of several amino acids from the lumen plus glutamine from arterial blood may provide an important energy source in small intestine.     

Nitrogen Assimilation in Mycorrhizas : Ammonium Assimilation in the N-Starved Ectomycorrhizal Fungus Cenococcum graniforme

Ammonium assimilation was followed in N-starved mycelia from the ectomycorrhizal Ascomycete Cenococcum graniforme. The evaluation of free amino acid pool levels after the addition of 5 millimolar NH₄⁺ indicated that the absorbed ammonium was assimilated rapidly. Post-feeding nitrogen content of amino acids was very different from the initial values. After 8 hours of NH₄⁺ feeding, glutamine accounted for the largest percentage of free amino acid nitrogen (43%). The addition of 5 millimolar methionine sulfoximine (MSX) to NH₄⁺-fed mycelia caused an inhibition of glutamine accumulation with a corresponding increase in glutamate and alanine levels.

Using ¹⁵N as a tracer, it was found that the greatest initial labeling was into glutamine and glutamate followed by aspartate, alanine, and ornithine. On inhibiting glutamine synthetase using MSX, ¹⁵N enrichment of glutamate, alanine, aspartate, and ornithine continued although labeling of glutamine was quite low. Moreover, the incorporation of ¹⁵N label in insoluble nitrogenous compounds was lower in the presence of MSX. From the composition of free amino acid pools, the ¹⁵N labeling pattern and effects of MSX, NH₄⁺ assimilation in C. graniforme mycelia appears to proceed via glutamate dehydrogenase pathway. This study also demonstrates that glutamine synthesis is an important reaction of ammonia utilization.

     

Glutamine limited fed-batch culture reduces the overflow metabolism of amino acids in myeloma cells

The murine myeloma cell line Sp 2/0-Ag 14 was cultured in an ordinary batch culture and in a glutamine limited fed-batch culture. In batch culture, the overflow metabolism of glutamine ends in excess production of ammonium and the amino acids alanine, proline, ornithine, asparagine, glutamate, serine and glycine. This pattern was dramatically changed in the fed-batch culture. Glutamine limitation halved the cellular ammonium production and reduced the ratio of NH₄ ⁺/glutamine. The excess production of alanine, proline and ornithine was reduced by a factor of 2–6 while asparagine was not produced at all. In contrary to the other amino acids glycine production was increased. These results are discussed in view of the different nature of glutamine metabolism in the mitochondrial compartment vs. the cytosolic. Furthermore, essential amino acids were used more efficiently in the fed-batch as judged by the increase in the cellular yield coefficients in the range of 1.3–2.6 times for seven of the 11 consumed ones. In all, this leads to a more efficient use of the energy sources glucose and glutamine as revealed by an increase in the cellular yield coefficient for glucose by 70% and for glutamine by 61%.     

Amino Acid Metabolism of Lemna minor L. : I. Responses to Methionine Sulfoximine

When Lemna minor L. is supplied with the potent inhibitor of glutamine synthetase, methionine sulfoximine, rapid changes in free amino acid levels occur. Glutamine, glutamate, asparagine, aspartate, alanine, and serine levels decline concomitantly with ammonia accumulation. However, not all free amino acid pools deplete in response to this inhibitor. Several free amino acids including proline, valine, leucine, isoleucine, threonine, lysine, phenylalanine, tyrosine, histidine, and methionine exhibit severalfold accumulations within 24 hours of methionine sulfoximine treatment. To investigate whether these latter amino acid accumulations result from de novo synthesis via a methionine sulfoximine insensitive pathway of ammonia assimilation (e.g. glutamate dehydrogenase) or from protein turnover, fronds of Lemna minor were prelabeled with [¹⁵N]H₄⁺ prior to supplying the inhibitor. Analyses of the ¹⁵N abundance of free amino acids suggest that protein turnover is the major source of these methionine sulfoximine induced amino acid accumulations. Thus, the pools of valine, leucine, isoleucine, proline, and threonine accumulated in response to the inhibitor in the presence of [¹⁵N]H₄⁺, are ¹⁴N enriched and are not apparently derived from ¹⁵N-labeled precursors. To account for the selective accumulation of amino acids, such as valine, leucine, isoleucine, proline, and threonine, it is necessary to envisage that these free amino acids are relatively poorly catabolized in vivo. The amino acids which deplete in response to methionine sulfoximine (i.e. glutamate, glutamine, alanine, aspartate, asparagine, and serine) are all presumably rapidly catabolized to ammonia, either in the photorespiratory pathway or by alternative routes.     

Metabolic changes associated with adaptation of plant cells to water stress

Suspension cultured cells of tomato (Lycopersicon esculentum Mill. cv VFNT Cherry) adapted to water stress induced with polyethylene glycol 6000 (PEG), exhibit marked alterations in free amino acid pools (Handa et al. 1983 Plant Physiol 73: 834-843). Using computer simulation models the in vivo rates of synthesis and utilization and compartmentation of free amino acid pools were determined from ¹⁵N labeling kinetics after substituting [¹⁵N]ammonium and [¹⁵N]nitrate for the ¹⁴N salts in the culture medium of cell lines adapted to 0% and 25% PEG. The 300-fold elevated proline pool in 25% PEG adapted cells is primarily the consequence of a 10-fold elevated rate of proline synthesis via the glutamate pathway. Ornithine was insufficiently labeled to serve as a major precursor for proline. Our calculations suggest that the rate of proline synthesis only slightly exceeds the rate required to sustain both protein synthesis and proline pool maintenance with growth. Mechanisms must operate to restrict proline oxidation in adapted cells. The kinetics of labeling of proline in 25% PEG adapted cells are consistent with a single, greatly enlarged metabolic pool of proline. The depletion of glutamine in adapted cells appears to be a consequence of a selective depletion of a large, metabolically inactive storage pool present in unadapted cultures. The labeling kinetics of the amino nitrogen groups of glutamine and glutamate are consistent with the operation of the glutamine synthetase-glutamate synthase cycle in both cell lines. However, we could not conclusively discriminate between the exclusive operation of the glutamine synthetase-glutamate synthase cycle and a 10 to 20% contribution of the glutamate dehydrogenase pathway of ammonia assimilation. Adaptation to water stress leads to increased nitrogen flux from glutamate into alanine and γ-aminobutyrate, suggesting increased pyruvate availability and increased rates of glutamate decarboxylation. Both alanine and γ-aminobutyrate are synthesized at rates greatly in excess of those simply required to maintain the free pools with growth, indicating that these amino acids are rapidly turned over. Thus, both synthesis and utilization rates for alanine and γ-aminobutyrate are increased in adapted cells. Adaptation to stress leads to increased rates of synthesis of valine and leucine apparently at the expense of isoleucine. Remarkably low ¹⁵N flux via the aspartate family amino acids was observed in these experiments. The rate of synthesis of threonine appeared too low to account for threonine utilization in protein synthesis, pool maintenance, and isoleucine biosynthesis. It is possible that isoleucine may be deriving carbon skeletons from sources other than threonine. Tentative models of the nitrogen flux of these two contrasting cell lines are discussed in relation to carbon metabolism, osmoregulation, and nitrogenous solute compartmentation.     

Studies on Amino Acid Metabolism in the Brain Using 15N-Labeled Precursors

The transfer of label from ¹⁵N-alanine and ¹⁵N-glutamate into amino acids in incubated brain slices has been followed using gas chromatography/mass spectrometry (GC/MS). ¹⁵N from alanine appeared in both amino and amide groups of glutamine more rapidly than into aspartate, glutamate and GABA, which were all labeled at similar rates. Maximum labelling of approx. 50% enrichment of these three metabolites was achieved in 3 hr. The ¹⁵N present in doubly-labeled glutamine exceeded that in the singly-labelled after 30 min. ¹⁵N from glutamate was rapidly transferred to aspartate and to alanine, with slower incorporation into glutamine and GABA. As was seen with labeling from alanine, doubly-labeled glutamine was higher than the singly-labeled species, also reaching some 50% enrichment in 3 hr. Depolarisation with 40 mM extracellular K⁺ caused a considerable reversal of the ratio of doubly- to singly-labeled glutamine species from both alanine and glutamate. The results are discussed in terms of the effects of depolarization on the glutamate/glutamine cycle.     

Intestinal metabolism of glutamine and glutamate from the lumen as compared to glutamine from blood.

Only a small fraction of the l-[U-¹⁴C]glutamate (2%) and the l-[U-¹⁴C]glutamine (34%) administered at a 6 mm concentration into the lumen of rat jejunal segments in situ was recovered unchanged in venous blood collected from the segments. The remaining ¹⁴C of both amino acids was recovered in the blood as CO₂ (60%), proline (5%), citrulline (4%), alanine (3%), ornithine (2%), and organic acids, mostly lactate (19%). The amide nitrogen of glutamine was recovered mostly as ammonia and the amino nitrogen of both amino acids predominantly in alanine. A nearly identical distribution of products was seen in previously published experiments in which rat intestine took up l-[U-¹⁴C]glutamine from arterial blood (Windmueller, H. G., and Spaeth, A. E. (1974) J. Biol. Chem., 249, 5070–5079). The results are therefore consistent with a single metabolic pool within mucosal cells for blood-derived and lumen-derived glutamine. When 6 mm glutamine was continuously perfused through the lumen, jejunal segments metabolized arterial and luminal glutamine at approximately equal rates (130–190 nmol min^?1 (g of tissue)^?1). The total combined rate was 1.7 times the rate of utilization of arterial glutamine alone in jejunal segments not absorbing glutamine. These results provide the first quantitative data on comparative metabolism by the intestine of substrates from the lumen and from blood. Rat intestine apparently metabolizes nearly all absorbed dietary glutamate and most glutamine in addition to circulating glutamine derived from other tissues.     

Changes in Amino Acid Content and the Metabolism of γ-Aminobutyrate in Cucurbita moschata Seedlings

Ungerminated pumpkin (Cucurbita moschata Poir.) cotyledons contained 30 % of their dry weight as lipid and 26 % as protein, of which 93 % was globulin. There was a rapid degradation of these reserves 4 to 8 days after planting when the cotyledons had their maximum metabolic activity. About half of the mole percent of amino acids found in the globulin reserve was in arginine, glutamate, aspartate, and their amides. The cotyledons had a large soluble pool of arginine, glutamine, glutamate, and leucine. Most amino acids increased steadily in amount in the cotyledons during germination, except glutamine, ornithine, alanine, serine, glycine, and γ-aminobutyrate and these appeared in large amounts in the translocation stream to the axis tissue. Little arginine or proline was translocated. By 10 days, when translocation had decreased, amino acids accumulated. Ornithine, γ-aminobutyrate, and aspartate were rapidly utilized in the hypocotyl, while glutamine, glycine, and alanine accumulated there. Cysteine and methionine levels were low in the reserve, trans-location stream and soluble fractions. γ-Aminobutyrate-U^?14C injected into cotyledons or incubated with hypocotyls was utilized in a similar fashion. The label appeared in citric acid cycle acids and in the amino acids closely related to this cycle, but the bulk of the label appeared in CO₂. The labeling pattern suggests that γ-aminobutyrate was utilized via succinate, and thus entered the citric acid cycle. A close relationship between arginine, ornithine, glutamate, and γ-aminobutyrate exists in the cotyledon with all but arginine being translocated rapidly to the axis tissue where these amino acids are rapidly metabolized.     

Incorporation of nitrate nitrogen in rice seedlings transferred to anaerobic conditions

Summary Incorporation of¹⁵NO₃- into amino acids was studied in 3-day-old aerobic rice seedlings (with coleoptile and root) subjected for 24h to anaerobic conditions. The incorporation of¹⁵N into glutamate, glutamine and alanine accounted for 89% and 84% of total incorporation in coleoptile and root, respectively. These findings indicate that, after the primary incorporation of¹⁵N into glutamate and glutamine, the main fate of nitrate nitrogen in rice seedlings subjected to anoxia is alanine.     

Changes in plasma amino acid concentrations with increasing age in patients with propionic acidemia

The objective of the study is to analyze plasma amino acid concentrations in propionic acidemia (PA) for the purpose of elucidating possible correlations between propionyl-CoA carboxylase deficiency and distinct amino acid behavior. Plasma concentrations of 19 amino acids were measured in 240 random samples from 11 patients (6 families) with enzymatically and/or genetically proven propionic acidemia (sampling period, January 2001–December 2007). They were compared with reference values from the literature and correlated with age using the Pearson correlation coefficient test. Decreased plasma concentrations were observed for glutamine, histidine, threonine, valine, isoleucine, leucine, phenylalanine and arginine. Levels of glycine, alanine and aspartate were elevated, while values of serine, asparagine, ornithine and glutamate were normal. For lysine, proline and methionine a clear association was not possible. Significant correlations with age were observed for 13 amino acids (positive correlation: asparagine, glutamine, proline, alanine, histidine, threonine, methionine, arginine; negative correlation: leucine, phenylalanine, ornithine, glutamate and aspartate). This study gives new insight over long-term changes in plasma amino acid concentrations and may provide options for future therapies (e.g., substitution of anaplerotic substances) in PA patients.     

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

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

Asparagine biosynthesis by Oryza sativa seedlings

l-Aspartate-[U-¹⁴C] was quickly metabolized in rice seedlings into amino acids, organic acids and sugars. On feeding simultaneously with ammonium for 2 hr, about 1% of the total soluble radioactivity was recovered as asparagine. Major amino acids labelled were aspartate, glutamate, glutamine and alanine in both shoots and roots. On the other hand, on feeding l-aspartate-[U-¹⁴C] to rice seedlings precultured in an ammonium medium, asparagine accounted for 35% of the total soluble radioactivity in the roots. Different labelling patterns in amino acids from those of non-precultured tissues were observed, and the main amino acids labelled in this case were asparagine and γ-aminobutyrate in the roots; glutamate, asparagine and glutamine in the shoots. It was observed in the roots that this increase of asparagine labelling was associated with a decrease of label in glutamate.     

Analysis of energetic amino acid metabolism in Acyrthosiphon pisum: A multidimensional approach to amino acid metabolism in aphids

Aphids are highly specialized insects that feed on the phloem-sap of plants, the amino acid composition of which is very unbalanced. Amino acid metabolism is thus crucial in aphids, and we describe a novel investigation method based on the use of ¹⁴C-labeled amino acids added in an artificial diet. A metabolism cage for aphids was constructed, allowing for the collection and analysis of the radioactivity incorporated into the aphid body, expired as CO₂, and rejected in the honeydew and exuviae. This method was applied to the study of the metabolism of eight energetic amino acids (aspartate, glutamate, glutamine, glycine, serine, alanine, proline, and threonine) in the pea aphid, Acyrthosiphon pisum. All these amino acids except threonine were subject to substantial catabolism as measured by high ¹⁴CO₂ production. The highest turnover was displayed by aspartate, with 60% of its carbons expired as CO₂. For the first time in an aphid, we directly demonstrated the synthesis of three essential amino acids (threonine, isoleucine, and lysine) from carbons of common amino acids. The synthesis of these three compounds was only observed from amino acids that were previously converted into glutamate. This conversion was important for aspartate, and lower for alanine and proline. To explain the quantitative results of interconversion between amino acids, we propose a compartmentation model with the intervention of bacterial endosymbiotes for the synthesis of essential amino acids and with glutamate as the only amino acid supplied by the insect to the symbiotes. Moreover, proline exhibited partial conversion into arginine, and it is suggested that proline is probably indirectly involved in excretory nitrogen metabolism. © 1995 Wiley-Liss, Inc.     

Differential ammonia metabolism in Aedes aegypti fat body and midgut tissues

In order to understand at the tissue level how Aedes aegypti copes with toxic ammonia concentrations that result from the rapid metabolism of blood meal proteins, we investigated the incorporation of ¹⁵N from ¹⁵NH₄Cl into amino acids using an in vitro tissue culture system. Fat body or midgut tissues from female mosquitoes were incubated in an Aedes saline solution supplemented with glucose and ¹⁵NH₄Cl for 10-40 min. The media were then mixed with deuterium-labeled amino acids, dried and derivatized. The ¹⁵N-labeled and unlabeled amino acids in each sample were quantified by mass spectrometry techniques. The results demonstrate that both tissues efficiently incorporate ammonia into amino acids, however, the specific metabolic pathways are distinct. In the fat body, the ¹⁵N from ¹⁵NH₄Cl is first incorporated into the amide side chain of Gln and then into the amino group of Gln, Glu, Ala and Pro. This process mainly occurs via the glutamine synthetase (GS) and glutamate synthase (GltS) pathway. In contrast, ¹⁵N in midgut is first incorporated into the amino group of Glu and Ala, and then into the amide side chain of Gln. Interestingly, our data show that the GS/GltS pathway is not functional in the midgut. Instead, midgut cells detoxify ammonia by glutamate dehydrogenase, alanine aminotransferase and GS. These data provide new insights into ammonia metabolism in A. aegypti mosquitoes.     

Incorporation of nitrate nitrogen into amino acids during the anaerobic germination of rice

Summary Incorporation of¹⁵NO₃-into amino acids was studied during the anaerobic germination of rice seeds. In treated coleoptiles, the label was incorporated into glutamine, glutamate, alanine,-aminobutyric acid (Gaba), arginine, aspartate and methionine. These findings are consistent with a primary incorporation of nitrate nitrogen into glutamine, glutamate and aspartate, and their further conversion to alanine, Gaba, arginine and methionine.     

Exogenous ornithine is an effective precursor and the δ-ornithine amino transferase pathway contributes to proline accumulation under high N recycling in salt-stressed cashew leaves

The role of the δ-ornithine amino transferase (OAT) pathway in proline synthesis is still controversial and was assessed in leaves of cashew plants subjected to salinity. The activities of enzymes and the concentrations of metabolites involved in proline synthesis were examined in parallel with the capacity of exogenous ornithine and glutamate to induce proline accumulation. Proline accumulation was best correlated with OAT activity, which increased 4-fold and was paralleled by NADH oxidation coupled to the activities of OAT and Δ¹-pyrroline-5-carboxylate reductase (P5CR), demonstrating the potential of proline synthesis via OAT/P5C. Overall, the activities of GS, GOGAT and aminating GDH remained practically unchanged under salinity. The activity of P5CR did not respond to NaCl whereas Δ¹-pyrroline-5-carboxylate dehydrogenase was sharply repressed by salinity. We suggest that if the export of P5C from the mitochondria to the cytosol is possible, its subsequent conversion to proline by P5CR may be important. In a time-course experiment, proline accumulation was associated with disturbances in amino acid metabolism as indicated by large increases in the concentrations of ammonia, free amino acids, glutamine, arginine and ornithine. Conversely, glutamate concentrations increased moderately and only within the first 24 h. Exogenous feeding of ornithine as a precursor was very effective in inducing proline accumulation in intact plants and leaf discs, in which proline concentrations were several times higher than glutamate-fed or salt-treated plants. Our data suggest that proline accumulation might be a consequence of salt-induced increase in N recycling, resulting in increased levels of ornithine and other metabolites involved with proline synthesis and OAT activity. Under these metabolic circumstances the OAT pathway might contribute significantly to proline accumulation in salt-stressed cashew leaves.     

Metabolic effects of hydrocortisone in mouse brain

The effect of intramuscular administration of hydrocortisone (10 mg/day per animal) for 5 days has been studied on the content of the amino acids belonging to the glutamate family, in the different regions of the mouse brain, along with the activities of glutamine synthetase, glutamate dehydrogenase, and aspartate, alanine, tyrosine, and ornithine aminotransferases. Further, since proline too is related to glutamate metabolism, the activity of proline oxidase was also studied in these regions. As hydrocortisone is known to influence the ionic fluxes in different tissues and the nitrogen metabolism, the activities of Na⁺,K⁺-ATPase together with the content of RNA and protein have also been estimated. A fall in the amino acids of the glutamate family in all three regions was observed with an increase in glutamate dehydrogenase activity in cerebral cortex. A significant fall in the protein content was also observed, mainly in the brain stem. A universal increase in Na⁺,K⁺-ATPase activity was observed in all three regions, with the highest in the cerebral cortex. The results indicate that hydrocortisone triggers increased utilization of glutamate in brain as an alternative to glucose, thereby shifting the nitrogen metabolism toward catabolism. The increased activity of Na⁺,K⁺-ATPase under these conditions would further aggravate the same and may lead to membrane stabilization.     

Regeneration in alfalfa tissue culture: stimulation of somatic embryo production by amino acids and N-15 NMR determination of nitrogen utilization

The production of somatic embryos in alfalfa (Medicago sativa L., cv Regen S) is increased 5- to 10-fold by alanine and proline. However, utilization of nitrogen for synthesis of protein from alanine, proline, glutamate, and glycine is not qualitatively different, even though the latter two amino acids do not increase somatic embryo formation. These determinations were made by ¹⁵N labeling with detection by nuclear magnetic resonance. Overall metabolism of the nitrogen of proline, alanine, glutamate, and glycine is also similar in two regenerating and nonregenerating genotypes with similar germplasm, except that the levels of free amino acids are consistently higher in the nonregenerating line. In addition, when regeneration is suppressed in either of the two regenerating lines, the level of intracellular free amino acids increases. This increased level of metabolites is the only direct evidence provided by analysis of nitrogen metabolism of differences between the regenerating and nonregenerating states in alfalfa.     

Refixation of photorespiratory ammonia and the role of alanine in photorespiration: Studies with15N

Summary Labelling experiments with¹⁵N glutamate and¹⁵N alanine were conducted using slices from oat leaves to investigate photorespiratory nitrogen metabolism. It is concluded from the labelling kinetics of glutamine that the refixation of photorespiratory ammonia primarily occurs by glutamine synthetase in the chloroplast. The labelling kinetics of glutamine with¹⁵N glutamate indicate that the chloroplastic and cytoplasmic glutamate pools do not exchange easily in oat leaf cells. Alanine was shown to be an important amino donor for photorespiratory glycine formation. This result is discussed with regard to a possible role of alanine in photorespiration. A modification to the scheme of photorespiratory nitrogen metabolism is proposed.     

Interrelationships of Leucine and Glutamate Metabolism in Cultured Astrocytes

Abstract: The aim was to study the extent to which leu-cine furnishes α-NH₂ groups for glutamate synthesis via branched-chain amino acid aminotransferase. The transfer of N from leucine to glutamate was determined by incubating astrocytes in a medium containing [¹⁵N]leucine and 15 unlabeled amino acids; isotopic abundance was measured with gas chromatography-mass spectrometry. The ratio of labeling in both [¹⁵N]glutamate/[¹⁵N]leucine and [2-¹⁵N]glutamine/[¹⁵N]leucine suggested that at least one-fifth of all glutamate N had been derived from leucine nitrogen. At the same time, enrichment in [¹⁵N]leucine declined, reflecting dilution of the ¹⁶N label by the unlabeled amino acids that were in the medium. Isotopic abundance in [¹⁶N]-isoleucine increased very quickly, suggesting the rapidity of transamination between these amino acids. The appearance of ¹⁵N in valine was more gradual. Measurement of branched-chain amino acid transaminase showed that the reaction from leucine to glutamate was approximately six times more active than from glutamate to leucine (8.72 vs. 1.46 nmol/min/mg of protein). However, when the medium was supplemented with α-ketoisocaproate (1 mM), the ketoacid of leucine, the reaction readily ran in the “reverse” direction and intraastrocytic [glutamate] was reduced by ～50% in only 5 min. Extracellular concentrations of α-ketoisocaproate as low as 0.05 mM significantly lowered intracellular [glutamate]. The relative efficiency of branched-chain amino acid transamination was studied by incubating astrocytes with 15 unlabeled amino acids (0.1 mM each) and [¹⁵N]glutamate. After 45 min, the most highly labeled amino acid was [¹⁵N]alanine, which was closely followed by [¹⁵N]leucine and [¹⁵N]isoleucine. Relatively little ¹⁵N was detected in any other amino acids, except for [¹⁵N]serine. The transamination of leucine was ～17 times greater than the rate of [1-¹⁴C]leucine oxidation. These data indicate that leucine is a major source of glutamate nitrogen. Conversely, reamination of a-ketoisocaproate, the ketoacid of leucine, affords a mechanism for the temporary “buffering” of intracellular glutamate.