Uterine uptake of amino acids and placental glutamine--glutamate balance in the pregnant ewe

The uterine uptake of amino acids was studied in 10 pregnant sheep with gestational ages of 114-146 days. After recovery from surgery, arterial and uterine venous samples were drawn simultaneously via indwelling catheters and analysed for amino acid and oxygen content. In seven ewes, amino acid concentrations were measured by a chromatographic technique. In four ewes, glutamate and glutamine arterio-venous differences across the uterine and umbilical circulations were measured by an enzymatic method. The uptake of neutral and basic amino acids was 66 mumol/mmol O2 and 17.3 mumol/mmol O2, respectively. Comparison of uterine and umbilical uptake shows that the bulk of the neutral and basic amino acids taken up by the pregnant uterus are transferred to the fetus. there was no significant uptake of acidic amino acids (i.e. glutamate, aspartate and taurine). glutamate was delivered from the fetus to the placenta but excretion of glutamate into the uterine circulation was negligible. Glutamine and asparagine were delivered to the fetus in amount which were two to three times larger than the placental uptake of glutamate and aspartate. Therefore placental conversion of exogenous glutamate and aspartate to glutamine and asparagine cannot account entirely for the fetal uptake of these amino acids.     

The glutamine/amino acid transporter (ASCT2) reconstituted in liposomes: transport mechanism, regulation by ATP and characterization of the glutamine/glutamate antiport

The glutamine/amino acid transporter solubilized from rat renal apical plasma membrane (brush-border membrane) with C12E8 and reconstituted into liposomes has been previously identified as the ASCT2 transporter. The reconstituted transporter catalyses an antiport reaction in which external glutamine and Na+ are cotransported in exchange with internal glutamine (or other amino acids). The glutamine-Na+ cotransport occurred with a 1:1 stoichiometry. The concentration of Na+ did not influence the Km for glutamine and vice versa. Experimental data obtained by a bi-substrate analysis of the glutamine-Na+ cotransport, together with previous report on the glutamine(ex)/glutamine(in) pseudo bi-reactant analysis, indicated that the transporter catalyses a three-substrate transport reaction with a random simultaneous mechanism. The presence of ATP in the internal compartment of the proteoliposomes led to an increase of the Vmax of the transport and to a decrease of the Km of the transporter for external Na+. The reconstituted glutamine/amino acid transporter was inhibited by glutamate; the inhibition was more pronounced at acidic pH. A kinetic analysis revealed that the inhibition was competitive with respect to glutamine. Glutamate was also transported in exchange with glutamine. The external Km of the transporter for glutamate (13.3 mM) was slightly higher than the internal one (8.3 mM). At acidic pH the external but not the internal Km decreased. According with the Km values, glutamate should be transported preferentially from inside to outside in exchange for external glutamine and Na+.     

Glutamine transport by the blood-brain barrier: a possible mechanism for nitrogen removal

Glutamine and glutamate transport activities were measuredin isolated luminal and abluminal plasma membrane vesiclesderived from bovine brain endothelial cells. Facilitativesystems for glutamine and glutamate were almost exclusivelylocated in luminal-enriched membranes. The facilitativeglutamine carrier was neither sensitive to2-aminobicyclo(2,2,1)heptane-2-carboxylic acid inhibition nor did itparticipate in accelerated amino acid exchange; it therefore appearedto be distinct from the neutral amino acid transport system L1. TwoNa-dependent glutamine transporters were found in abluminal-enrichedmembranes: systems A and N. System N accounted for ~80% ofNa-dependent glutamine transport at 100 µM. Abluminal-enriched membranes showed Na-dependent glutamate transport activity. The presence of 1) Na-dependent carrierscapable of pumping glutamine and glutamate from brain into endothelialcells, 2) glutaminase withinendothelial cells to hydrolyze glutamine to glutamate and ammonia, and3) facilitative carriers forglutamine and glutamate at the luminal membrane may provide a mechanismfor removing nitrogen and nitrogen-rich amino acids from brain.

     

Glutamine synthesis in the developing porcine placenta

Glutamine plays a vital role in fetal carbon and nitrogen metabolism and exhibits the highest fetal:maternal plasma ratio among all amino acids in pigs. Such disparate glutamine levels between mother and fetus suggest that glutamine may be actively synthesized and released into the fetal circulation by the porcine placenta. We hypothesized that branched-chain amino acid (BCAA) metabolism in the placenta plays an important role in placental glutamine synthesis. This hypothesis was tested by studying conceptuses from gilts on Days 20, 30, 35, 40, 45, 50, 60, 90, or 110 of gestation (n = 6 per day). Placental tissue was analyzed for amino acid concentrations, BCAA transport, BCAA degradation, and glutamine synthesis as well as the activities of related enzymes (including BCAA transaminase, branched-chain alpha-ketoacid dehydrogenase, glutamine synthetase, glutamate-pyruvate transaminase, and glutaminase). On all days of gestation, rates of BCAA transamination were much greater than rates of branched-chain alpha-ketoacid decarboxylation. The glutamate generated from BCAA transamination was primarily directed to glutamine synthesis and, to a much lesser extent, alanine production. Placental BCAA transport, BCAA transamination, glutamine synthesis, and activities of related enzymes increased markedly between Days 20 and 40 of gestation, as did glutamine in fetal allantoic fluid. Accordingly, placental BCAA levels decreased after Day 20 of gestation in association with a marked increase in BCAA catabolism and concentrations of glutamine. There was no detectable catabolism of glutamine in pig placenta throughout pregnancy, which would ensure maximum output of glutamine by this tissue. These novel results demonstrate glutamine synthesis from BCAAs in pig placentae, aid in explaining the abundance of glutamine in the fetus, and provide valuable insight into the dynamic role of the placenta in fetal metabolism and nutrition.     

The glutamine/amino acid transporter (ASCT2) reconstituted in liposomes: Transport mechanism, regulation by ATP and characterization of the glutamine/glutamate antiport

The glutamine/amino acid transporter solubilized from rat renal apical plasma membrane (brush-border membrane) with C₁₂E₈ and reconstituted into liposomes has been previously identified as the ASCT2 transporter. The reconstituted transporter catalyses an antiport reaction in which external glutamine and Na⁺ are cotransported in exchange with internal glutamine (or other amino acids). The glutamine-Na⁺ cotransport occurred with a 1:1 stoichiometry. The concentration of Na⁺ did not influence the Km for glutamine and vice versa. Experimental data obtained by a bi-substrate analysis of the glutamine-Na⁺ cotransport, together with previous report on the glutamine_ex/glutamine_in pseudo bi-reactant analysis, indicated that the transporter catalyses a three-substrate transport reaction with a random simultaneous mechanism. The presence of ATP in the internal compartment of the proteoliposomes led to an increase of the Vmax of the transport and to a decrease of the Km of the transporter for external Na⁺. The reconstituted glutamine/amino acid transporter was inhibited by glutamate; the inhibition was more pronounced at acidic pH. A kinetic analysis revealed that the inhibition was competitive with respect to glutamine. Glutamate was also transported in exchange with glutamine. The external Km of the transporter for glutamate (13.3 mM) was slightly higher than the internal one (8.3 mM). At acidic pH the external but not the internal Km decreased. According with the Km values, glutamate should be transported preferentially from inside to outside in exchange for external glutamine and Na⁺.     

Plasma amino acid concentrations in pregnant rats and in 21-day foetuses.

Plasma amino acid concentrations were determined in virgin female rats, in pregnant rats (12 and 21 days after impregnation) and in 21-day foetuses. The total amino acid concentration in plasma decreases significantly with pregnancy, being lower at 12 than at 21 days. Alanine, glutamine+glutamate and other 'gluconeogenic' amino acids decrease dramatically by mid-term, but regain their original concentrations at the end of the pregnancy. With most other amino acids, mainly the essential ones, the trend is towards lower concentrations which are maintained throughout pregnancy. These data agree with known nitrogen-conservation schemes in pregnancy and with the important demands on amino acids provoked by foetal growth. In the 21-day foetuses, concentrations of individual amino acids are considerably higher than in their mothers, with high plasma foetal/maternal concentration ratios, especially for lysine, phenylalanine and hydroxy-proline, suggesting active protein biosynthesis and turnover. All other amino acids also have high concentration ratios, presumably owing to their requirement by the foetuses for growth. Alanine, glutamine+glutamate, asparagine+aspartate, glycine, serine and threonine form a lower proportion of the total amino acids in foetuses than in the virgin controls or pregnant rats, probably owing to their role primarily in energy metabolism in the adults. The results indicate that at this phase of foetal growth, the placental amino acid uptake is considerable and seems to be higher than immediately before birth.     

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

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

Regulation of Transmitter γ-Aminobutyric Acid (GABA) Synthesis and Metabolism Illustrated by the Effect of γ-Vinyl GABA and Hypoglycemia

The effect of different treatments on amino acid levels in neostriatum was studied to throw some light on the synthesis and metabolism of gamma-aminobutyric acid (GABA). Irreversible inhibition of GABA transaminase by microinjection of gamma-vinyl GABA (GVG) led to a decrease in aspartate, glutamate, and glutamine levels and an increase in the GABA level, such that the nitrogen pool remained constant. The results indicate that a large part of brain glutamine is derived from GABA. Hypoglycemia led to an increase in the aspartate level and a decrease in glutamate, glutamine, and GABA levels. The total amino acid pool was decreased compared with amino acid levels in normoglycemic rats. GVG treatment of hypoglycemic rats led to a decrease in the aspartate level and a further reduction in glutamate and glutamine levels. In this case, GABA accumulation continued, although the glutamine pool was almost depleted. The GABA level increased postmortem, but there were no detectable changes in levels of the other amino acids. Pretreatment of the rats with hypoglycemia reduced both glutamate and glutamine levels with a subsequent decreased postmortem GABA accumulation. The half-maximal GABA synthesis rate was obtained when the glutamate level was reduced by 50% and the glutamine level was reduced by 80%.     

Methionine-Induced Changes in Glutamate, Aspartate, Glutamine, and γ-Aminobutyrate Levels in Brain Tissue

Intramuscular administration of methionine to mice resulted in changes in the levels of aspartate, glutamate, glutamine, and gamma-aminobutyrate in both nerve endings (synaptosomes) and "non-nerve-ending" tissue in the brain. However, the amino acid changes in the two locations differed considerably, not only in the time to onset of the changes, but also in the direction of the changes and in their duration. The results provide additional support for a glutamate-glutamine cycle between neurons and glia, and suggest that the decreases in amino acid levels in the nerve endings are due to an insufficient supply of glutamine from glia or other cellular structures, possibly compounded by an impairment in the uptake of glutamine into the nerve terminals. The primary cause of the glutamine deficiency is unknown because methionine did not affect the enzymes of glutamate and glutamine metabolism. Treatment of mice with methionine also resulted in an anticonvulsant action, but no correlation was observed between the latter phenomenon and the glutamate content of nerve endings.     

Phloem Loading and Metabolism of Xylem-Borne Amino Compounds in Fruiting Shoots of a Legume

Cut, fruiting shoots of Lupinus albus L. supplied with ¹⁴C-and ¹⁵N-labelled L-asparagine, L-glutamine, L-aspartic acid,or L-glutamic acid through the transpiration stream readilytransferred the labelled carbon and nitrogen of each compoundto pods and seeds of fruits. A time course of labelling of phloemsap collected from petioles and fruit tips following feedingof labelled asparagine indicated that xylem to phloem exchangein leaflets was an immediate and effective route of transferof the amide to fruits and that this and the loading onto phloemof additional asparagine from unlabelled pools of the amidein stems furnished a major source of the nitrogen for fruitfilling. Xylem to phloem exchange of nitrogen was accomplishedin different ways for each amino acid. The amide nitrogen ofasparagine was transferred mainly in the unmetabolized compound,the nitrogen of aspartate and glutamate largely in a wide rangeof amino acids synthesized in the leaf, and the amide nitrogenof glutamine was transferred in a manner intermediate betweenthese extremes. Glutamine and asparagine were the principalphloem solutes labelled with nitrogen from any of the suppliedcompounds, but the photosynthetically produced amino acids,glutamate, aspartate, serine, alanine, and valine also became¹⁵N-labelled in phloem. The main pathway for glutamine synthesisin vegetative parts of the shoot appeared to be by amidationof glutamate, but asparagine was not considered to be derivedsimilarly from aspartate. Leaflets metabolized glutamine morereadily than asparagine, but in each case the amide nitrogenwas used for synthesis of a variety of amino acids and the carbonwas recovered largely in non-amino compounds.     

Characterization of amino acid pools in the vacuolar compartment of Saccharomyces cerevisiae

Intact vacuoles are released from spheroplasts of Saccharomyces cerevisiae by means of a gentle mechanical disintegration method. They are purified by centrifugation in isotonic density gradients (flotation and subsequent sedimentation), and analyzed for their soluble amino acid content. The results indicate that about 60% of the total amino acid pool of spheroplasts is contained in the vacuoles. This may be an underestimate, as it presupposes no loss of amino acids from the vacuoles during the purification procedure. The amino acid concentration in the vecuoles is calculated to be approximately 5 times that in the cytoplasm if the total volumes of the two compartments are used for the calculation. The vacuolar amino acid pool is rich in basic amino acids, and in citrulline and glutamine, but contains a remarkably small amount of glutamate. Radioactive labeling experiments with spheroplasts indicate that the vacuolar amino acids are separated from the metabolically active pools located in the cytoplasm. This is particularly evident for the basic amino acids and glutamine; in contrast, the neutral amino acids and glutamate appear to exchange more rapidly between the cytoplasmic and the vacuolar compartments of the cells.     

GLUTAMINE UPTAKE AND METABOLISM BY THE ISOLATED TOAD BRAIN: EVIDENCE PERTAINING TO ITS PROPOSED ROLE AS A TRANSMITTER PRECURSOR

Abstract— Hemisections of toad brains, when incubated in a physiological medium containing no glutamine. released considerable amounts of this amino acid into the medium. When glutamine was included in the medium at a concentration of 0.2 mm the net efflux from the tissue was reduced but not totally prevented. Although there was no net uptake of glutamine, the tissue did accumulate [U-¹⁴C]glu-tamine and some of this labelled glutamine was rapidly metabolized to glutamate, GABA and aspartate. The precursor-product relationship for the metabolism of glutamine to glutamate differed from the classic single compartment model in that the specific radioactivity of glutamate rose very quickly to approx one-tenth that of glutamine, but increased slowly thereafter. These data suggest that the [¹⁴C]glutamine was taken up into two metabolically distinct compartments and/or that some of the [¹⁴C]glutamine was converted to [¹⁴C]glutamate during the uptake process. The uptake of [¹⁴C]glutamine was diminished when the tissue was incubated in a non-oxygenated medium or when Na⁺ was omitted (substituted with sucrose) and K⁺ was concomitantly elevated. However, on a relative basis, the incorporation of radioactivity into glutamate and GABA was increased by these incubation conditions. The metabolism of glutamine to aspartate was greatly depressed when the tissue was not oxygenated. The glutamate formed from [U-¹⁴C]glutamine taken up by the tissue was converted to GABA at a faster rate than was glutamate derived from [U-¹⁴C]glucose. [U-¹⁴C]gly-cerol or exogenous [U-¹⁴C]glutamate. This suggests that glutamine was metabolized to GABA selectively; i.e. on a relative basis, glutamine served as a better source of carbon for the synthesis of GABA than did glucose, glycerol or exogenous glutamate. When the brain hemisections were incubated in the normal physiological medium with or without glutamine. there was very little efflux of glutamate, GABA or aspartate from the tissue. However when NaCl was omitted from the medium (substituted with sucrose) and K⁺ was elevated to 29 miu. a marked efflux of these three amino acids into the medium did occur, and over a period of 160min, the content of each amino acid in the tissue was depleted considerably. When glutamine (0.2 mm ) was included in the Na⁺ deficient-high K.⁺ medium, the average amount of glutamate, GABA and aspartate in the tissue plus the medium was greater than when glutamine was not included in the medium. Such data indicate that CNS tissues can utilize glutamine for a net synthesis of glutamate, GABA and aspartate. The results of this study provide further evidence in support of the concept that the functional (transmitter) pools of glutamate and GABA are maintained and regulated in part via biosynthesis from glutamine. One specific mechanism instrumental in regulating the content of glutamate in nerve terminals may be a process of glutamine uptake coupled to deamidation.     

Ketogenic diet, brain glutamate metabolism and seizure control

We do not know the mode of action of the ketogenic diet in controlling epilepsy. One possibility is that the diet alters brain handling of glutamate, the major excitatory neurotransmitter and a probable factor in evoking and perpetuating a convulsion. We have found that brain metabolism of ketone bodies can furnish as much as 30% of glutamate and glutamine carbon. Ketone body metabolism also provides acetyl-CoA to the citrate synthetase reaction, in the process consuming oxaloacetate and thereby diminishing the transamination of glutamate to aspartate, a pathway in which oxaloacetate is a reactant. Relatively more glutamate then is available to the glutamate decarboxylase reaction, which increases brain [GABA]. Ketosis also increases brain [GABA] by increasing brain metabolism of acetate, which glia convert to glutamine. GABA-ergic neurons readily take up the latter amino acid and use it as a precursor to GABA. Ketosis also may be associated with altered amino acid transport at the blood-brain barrier. Specifically, ketosis may favor the release from brain of glutamine, which transporters at the blood-brain barrier exchange for blood leucine. Since brain glutamine is formed in astrocytes from glutamate, the overall effect will be to favor the release of glutamate from the nervous system.     

Cerebral Cortex Ammonia and Glutamine Metabolism During Liver Insufficiency-Induced Hyperammonemia in the Rat

Hyperammonemia has been suggested to induce enhanced cerebral cortex ammonia uptake, subsequent glutamine synthesis and accumulation, and finally net glutamine release into the blood stream, but this has never been confirmed in liver insufficiency models. Therefore, cerebral cortex ammonia- and glutamine-related metabolism was studied during liver insufficiency-induced hyperammonemia by measuring plasma flow and venous-arterial concentration differences of ammonia and amino acids across the cerebral cortex (enabling estimation of net metabolite exchange), 1 day after portacaval shunting and 2, 4, and 6 h after hepatic artery ligation (or in controls). The intra-organ effects were investigated by measuring cerebral cortex tissue ammonia and amino acids 6 h after liver ischemia induction or in controls. Arterial ammonia and glutamine increased in portacaval-shunted rats versus controls, and further increased during liver ischemia. Cerebral cortex net ammonia uptake, observed in portacaval-shunted rats, increased progressively during liver ischemia, but net glutamine release was only observed after 6 h of liver ischemia. Cerebral cortex tissue glutamine, gamma-aminobutyric acid, most other amino acids, and ammonia levels were increased during liver ischemia. Glutamate was equally decreased in portacaval-shunted and liver-ischemia rats. The observed net cerebral cortex ammonia uptake, cerebral cortex tissue ammonia and glutamine accumulation, and finally glutamine release into the blood suggest that the rat cerebral cortex initially contributes to net ammonia removal from the blood during liver insufficiency-induced hyperammonemia by augmenting tissue glutamine and ammonia pools, and later by net glutamine release into the blood. The changes in cerebral cortex glutamate and gamma-aminobutyric acid could be related to altered ammonia metabolism.     

A novel function of glutamine in cell culture: utilization of glutamine for the uptake of cystine in human fibroblasts

Transport and metabolism of glutamine has been investigated in human diploid fibroblasts, IMR-90. Glutamine was taken up via System ASC (Na+-dependent amino acid transport system especially reactive with short or polar side chain amino acids). In the routine culture medium the cells contained a large quantity of glutamate; its major source was shown to be glutamine in the medium. Previously we described a transport system that mediates the entrance of cystine in exchange for the exit of glutamate (Bannai, 1986). Since the cystine taken up is reduced to cysteine and the cysteine readily exits to the medium where it is oxidized to cystine, a cystine-cysteine cycle across the plasma membrane has been postulated. When the cells were cultured in glutamate/glutamine-free medium, intracellular glutamate decreased, depending on the amount of cystine in the medium; in the absence of cystine, glutamate decreased very slowly. When the cells were cultured in ordinary medium, glutamine in the medium decreased, and glutamate in the medium increased. Both changes were well correlated with cystine concentration in the medium. These results are consistent with the view that the intracellular glutamate, of which the source is glutamine in the medium, is released from the cells into the medium in order to take up cystine and thereby to rotate the cystine-cysteine cycle. In the routine culture one-third to one-half of the total consumption of glutamine seems to be used for the uptake of cystine.     

Role of Branched-Chain Aminotransferase Isoenzymes and Gabapentin in Neurotransmitter Metabolism

Abstract: Because it is well known that excess branched-chain amino acids (BCAAs) have a profound influence on neurological function, studies were conducted to determine the impact of BCAAs on neuronal and astrocytic metabolism and on trafficking between neurons and astrocytes. The first step in the metabolism of BCAAs is transamination with α-ketoglutarate to form the branched-chain α-keto acids (BCKAs). The brain is unique in that it expresses two separate branched-chain aminotransferase (BCAT) isoenzymes. One is the common peripheral form [mitochondrial (BCATm)], and the other [cytosolic (BCATc)] is unique to cerebral tissue, placenta, and ovaries. Therefore, attempts were made to define the isoenzymes' spatial distribution and whether they might play separate metabolic roles. Studies were conducted on primary rat brain cell cultures enriched in either astroglia or neurons. The data show that over time BCATm becomes the predominant isoenzyme in astrocyte cultures and that BCATc is prominent in early neuronal cultures. The data also show that gabapentin, a structural analogue of leucine with anticonvulsant properties, is a competitive inhibitor of BCATc but that it does not inhibit BCATm. Metabolic studies indicated that BCAAs promote the efflux of glutamine from astrocytes and that gabapentin can replace leucine as an exchange substrate. Studying astrocyte-enriched cultures in the presence of [U-¹⁴C]glutamate we found that BCKAs, but not BCAAs, stimulate glutamate transamination to α-ketoglutarate and thus irreversible decarboxylation of glutamate to pyruvate and lactate, thereby promoting glutamate oxidative breakdown. Oxidation of glutamate appeared to be largely dependent on the presence of an α-keto acid acceptor for transamination in astrocyte cultures and independent of astrocytic glutamate dehydrogenase activity. The data are discussed in terms of a putative BCAA/BCKA shuttle, where BCATs and BCAAs provide the amino group for glutamate synthesis from α-ketoglutarate via BCATm in astrocytes and thereby promote glutamine transfer to neurons, whereas BCATc reaminates the amino acids in neurons for another cycle.     

The differential transport of amino acids into the phloem of Ricinus communis L. seedlings as shown by the analysis of sieve-tube sap

The cotyledons of castor bean (Ricinus communis L.) act as absorption organs for amino acids, which are supplied to the medium. The analysis of the sieve-tube sap, which exudes from the cut hypocotyl, demonstrated the ability of the cotyledons to load particular amino acids into the phloem and to reject the loading of others. The sieve-tube sap of cotyledons, which were embedded in the endosperm, contained 150 mM amino acids, with 50 mM glutamine as the major amino acid, and 10–15 mM each of valine, isoleucine, lysine and arginine. Removal of the endosperm led to a drastic decline in the amino-acid content of sieve-tube sap down to 16 mM. Addition of single amino acid species to the medium increased the amino acid concentration in the sieve-tube sap in specific manner: glutamine caused the largest increase (up to 140 mM in exudate), glutamate and alanine smaller increases (up to 60 mM), and arginine the smallest. In addition, the amino acid composition of the sieve-tube sap changed, for instance, glutamine or alanine readily appeared in the sieve-tube sap upon incubation in glutamine or alanine, respectively, whereas glutamate was hardly discernible even in the case of incubation with glutamate; arginine was loaded into the sieve tubes only reluctantly. In general, glutamine and alanine accumulated four- to tenfold in the sieve tubes. The uptake of amino acids and of sucrose into the sieve tubes was interdependent: the loading of sucrose strongly reduced the amino acid concentration in the sieve-tube exudate and loading of amino acids decreased the sucrose concentration. Comparison of the concentrations of various amino acids on their way from the endosperm via the cotyledon-endosperm interface, through the cotyledons and into the sieve tubes showed that glutamine, valine, isoleucine and lysine are accumulated on this pathway, whereas glutamate and arginine are more concentrated in the cotyledons than in the sieve tubes. Obviously the phloem-loading system has a transport specificity different from that of the amino acid uptake system of the cotyledon in general and it strongly discriminates between amino acids within the cotyledons.     

Analysis of glutamate homeostasis by overexpression of Fd-GOGAT gene in Arabidopsis thaliana

Glutamate plays a central role in nitrogen flow and serves as a nitrogen donor for the production of amino acids. In plants, some amino acids work as buffers: during photorespiration, ammonium derived from the conversion of glycine to serine is promptly reassimilated into glutamate by the glutamine synthetase (GS-2)/ferredoxin-dependent glutamate synthase (Fd-GOGAT) cycle. The glutamate concentration is relatively stable compared with those of other amino acids under environmental changes. The few studies dealing with glutamate homeostasis have but all used knockouts or mutants of these enzymes. Here, we generated Fd-GOGAT (GLU1)-overexpressing Arabidopsis plants to analyze changes in the amino acid pool caused by glutamate overproduction under different ammonium conditions controlled by CO₂ concentration, light intensity and nitrate concentration. Under photorespiratory conditions with sufficient ammonium supply, aspartate increased and glutamine and glycine decreased, but glutamate barely changed. Under non-photorespiratory conditions, however, glutamate and most other amino acids increased. These results suggest that the synthesized glutamate is promptly converted into other amino acids, especially aspartate. In addition, ammonium supply by photorespiration does not limit glutamate biosynthesis, but glutamine and glycine are important. This study will contribute to the understanding of glutamate homeostasis in plants.     

Glutamine requirement for aerial mycelium growth in Neurospora crassa

Five amino acids are accumulated during vegetative growth of Neurospora crassa, particularly.during the prestationary growth phase. Alanine, glutamine, glutamate, arginine and ornithine.comprised over 80% of the total amino acid pool in the mycelium. Amino acid pools of different amino acid auxotrophs were followed during the partial transformation of a mycelial mat into an aerial mycelium. The mycelial mat under starvation and in direct contact with air rapidly formed aerial mycelium, which produced thereafter a burst of conidia. During this process,glutamine and alanine in the mycelial mat were consumed more rapidly than other amino acids;in the growing aerial mycelium, glutamate and glutamine were particularly accumulated. Of the amino acids that were initially accumulated in the mycelial mat, only a high glutamine pool was required for aerial mycelium growth induced by starvation. This requirement for glutamine could not be satisfied by a mixture of the amino compounds that are synthesized via glutamine amidotransferase reactions. It is proposed that glutamine serves as a nitrogen carrier from the mycelial mat to the growing aerial mycelium.     

Ammonia assimilation by Aspergillus nidulans: [15N]ammonia study

15N kinetic labelling studies were done on liquid cultures of wild-type Aspergillus nidulans. The labelling pattern of major amino acids under 'steady state' conditions suggests that glutamate and glutamine-amide are the early products of ammonia assimilation in A. nidulans. In the presence of phosphinothricin, an inhibitor or glutamine synthetase, 15N labelling of glutamate, alanine and aspartate was maintained whereas the labelling of glutamine was low. This pattern of labelling is consistent with ammonia assimilation into glutamate via the glutamate dehydrogenase pathway. In the presence of azaserine, an inhibitor of glutamate synthase, glutamate was initially more highly labelled than any other amino acid, whereas its concentration declined. Isotope also accumulated in glutamine. Observations with these two inhibitors suggest that ammonia assimilation can occur concurrently via the glutamine synthetase/glutamate synthase and the glutamate dehydrogenase pathways in low-ammonia-grown A. nidulans. From a simple model it was estimated that about half of the glutamate was synthesized via the glutamate dehydrogenase pathway; the other half was formed from glutamine via the glutamate synthase pathway. The transfer coefficients of nine other amino acids were also determined.