Suppression of the enzymes of glutamate metabolism in cortical synaptosomes in methionine sulfoximine toxicity

Enzymes of glutamate metabolism were studied in synaptosomes prepared from normal rats and those treated with acute (300 mg/kg) and subacute (150 mg/kg) doses of the convulsant methionine sulfoximine (MSO). The activities of glutamine synthetase, glutamate dehydrogenase and aspartate aminotransferase were inhibited in the synaptosomes of drug treated animals. It is suggested that MSO would suppress the formation of glutamine and glutamate and consequently the releasable pool of glutamate, aspartate and GABA. These neurotransmitters would be depleted irom the nerve endings. It is also indicated that the ammonia accumulated would affect the cerebral functioning by interfering with the maintenance of ionic gradients.     

Cerebral Aspartate Utilization: Near-Equilibrium Relationships in Aspartate Aminotransferase Reaction

Abstract: The pathways of nitrogen transfer from 50 μM [¹⁵N]aspartate were studied in rat brain synaptosomes and cultured primary rat astrocytes by using gas chromatography-mass spectrometry technique. Aspartate was taken up rapidly by both preparations, but the rates of transport were faster in astrocytes than in synaptosomes. In synaptosomes, ¹⁵N was incorporated predominantly into glutamate, whereas in glial cells, glutamine and other ¹⁵N-amino acids were also produced. In both preparations, the initial rate of N transfer from aspartate to glutamate was within a factor of 2-3 of that in the opposite direction. The rates of transamination were greater in synaptosomes than in astrocytes. Omission of glucose increased the formation of [¹⁵N]-glutamate in synaptosomes, but not in astrocytes. Rotenone substantially decreased the rate of transamination. There was no detectable incorporation of ¹⁵N from labeled aspartate to 6-amino-¹⁵N-labeled adenine nucleotides during 60-min incubation of synaptosomes under a variety of conditions; however, such activity could be demonstrated in glial cells. The formation of ¹⁵N-labeled adenine nucleotides was marginally increased by the presence of 1 mM aminooxyacetate, but was unaffected by pretreatment with 1 mM 5-amino-4-imidazolecarboxamide ribose. It is concluded that (1) aspartate aminotransferase is near equilibrium in both synaptosomes and astrocytes under cellular conditions, but the rates of transamination are faster in the nerve endings; (2) in the absence of glucose, use of amino acids for the purpose of energy production increases in synaptosomes, but may not do so in glial cells because the latter possess larger glycogen stores; and (3) nerve endings have a very limited capacity for salvage of the adenine nucleotides via the purine nucleotide cycle.     

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.     

Acidosis and astrocyte amino acid metabolism

The relationship between acidosis and the metabolism of glutamine and glutamate was studied in cultured astrocytes. Acidification of the incubation medium was associated with an increased formation of aspartate from glutamate and glutamine. The rise of the intracellular content of aspartate was accompanied by a significant decline in the extracellular concentration of both lactate and citrate. Studies with either [2-(15)N]glutamine or [15N]glutamate indicated that there occurred in acidosis an increased transamination of glutamate to aspartate. Studies with L-[2,3,3,4,4-(2)H5]glutamine indicated that in acidosis glutamate carbon was more rapidly converted to aspartate via the tricarboxylic acid cycle. Acidosis appears to result in increased availability of oxaloacetate to the aspartate aminotransferase reaction and, consequently, increased transamination of glutamate. The expansion of the available pool of oxaloacetate probably reflects a combination of: (a) Restricted flux through glycolysis and less production from pyruvate of acetyl-CoA, which condenses with oxaloacetate in the citrate synthetase reaction; and (b) Increased oxidation of glutamate and glutamine through a portion of the tricarboxylic acid cycle and enhanced production of oxaloacetate from glutamate and glutamine carbon. The data point to the interplay of the metabolism of glucose and that of glutamate in these cells.     

NEURONAL-GLIAL CONTRIBUTIONS TO TRANSMITTER AMINO ACID METABOLISM: STUDIES WITH KAINIC ACID-INDUCED LESIONS OF RAT STRIATUM

Abstract– Various aspects of amino acid metabolism were studied in striatum of rats with unilateral, kainic acid-induced lesions. Tissue slices were prepared from the lesioned and the contralateral, unlesioned, striatum. The preparations were incubated with a mixture of d -[2-¹⁴C]glucose and [³H]acetate in a Krebs-Ringer bicarbonate medium to evaluate oxidative metabolism. Glutamate and aspartate levels were decreased in the slices prepared from the lesioned striata by 35-40% and that of GABA by 75% compared to the levels found in the slices from the contralateral striata; glutamine levels were not different in the two preparations. Glucose utilization was decreased 60% in the slices from the lesioned striatum; this was caused not only by decreased levels of glutamate, aspartate and GABA but also by a decreased rate of labelling of glutamate and aspartate. On the other hand, the metabolism of [³H]acetate was greatly increased. The specific activities of glutamate and aspartate were 4-5-fold higher in the slices from kainic acid-lesioned striata; those of glutamine and GABA were unchanged. Thus, there was a 6-7-fold increase in the ratio of ³H to ¹⁴C in the specific activities of glutamate, aspartate and GABA with no change in this ratio in glutamine. The labelling of glutamine relative to that of glutamate, especially from [³H]acetate, suggested that the compartmentation of the glutamate-glutamine system was greatly altered in the kainate-lesioned striatum which now more closely resembled a single compartment system. The activities of lactate dehydrogenase, glutamate dehydrogenase, GABA transaminase and ‘cytoplasmic’ aspartate aminotransferase were decreased in homogenates of lesioned striatum. Succinate dehydrogenase, glutaminase (phosphate-activated) and ‘mitochondrial’ aspartate aminotransferase activities were unchanged whilst that of glutamine synthetase was increased. The results are consistent with hypotheses concerning the assignment of labelled acetate metabolism to glial cells as well as the distribution of the above enzymes between glia, neurones and nerve endings.     

Cerebral Alanine Transport and Alanine Aminotransferase Reaction: Alanine as a Source of Neuronal Glutamate

Abstract: Alanine transport and the role of alanine amino-transferase in the synthesis and consumption of glutamate were investigated in the preparation of rat brain synaptosomes. Alanine was accumulated rapidly via both the high-and low-affinity uptake systems. The high-affinity transport was dependent on the sodium concentration gradient and membrane electrical potential, which suggests a cotransport with Na⁺. Rapid accumulation of the Na⁺-alanine complex by synaptosomes stimulated activity of the Na⁺/K⁺ pump and increased energy utilization; this, in turn, activated the ATP-producing pathways, glycolysis and oxidative phosphorylation. Accumulation of Na⁺ also caused a small depolarization of the plasma membrane, a rise in [Ca²⁺]₁, and a release of glutamate. Intra-synaptosomal metabolism of alanine via alanine aminotransferase, as estimated from measurements of N fluxes from labeled precursors, was much slower than the rate of alanine uptake, even in the presence of added oxoacids. The velocity of [¹⁵N]alanine formation from [¹⁵N]glutamine was seven to eight times higher than the rate of [¹⁵N]glutamate generation from [¹⁵N]alanine. It is concluded that (a) overloading of nerve endings with alanine could be deleterious to neuronal function because it increases release of glutamate; (b) the activity of synaptosomal alanine aminotransferase is much slower than that of glutaminase and hence unlikely to play a major role in maintaining [glutamate] during neuronal activity; and (c) alanine aminotransferase might serve as a source of glutamate during recovery from ischemia/hypoxia when the alanine concentration rises and that of glutamate falls.     

Combined Effects of a Metabolic Inhibitor (Gabaculine) and an Uptake Inhibitor (Ketamine) on the γ-Aminobutyrate System in Mouse Brain

Abstract: The intramuscular administration of a γ-aminobutyrate-α-oxoglutarate aminotransferase (GABA-T) inhibitor, gabaculine, to mice resulted in significant increases in GABA content and decreases in the content of aspartate, glutamate, and glutamine in the nerve endings (synaptosomes). These effects were ameliorated by the concurrent administration of the GABA uptake inhibitor ketamine. A major cause of these effects was the gabaculine-induced inhibition of GABA-T activity and the lessening of this inhibition by ketamine. The latter phenomenon was not due to a direct action of ketamine on the enzyme, nor to an interaction between gabaculine and ketamine. Rather, it appeared that ketamine might be interfering with the transport of gabaculine into the cellular structures. The anticonvulsant action of the GABA-T inhibitor and the GABA uptake inhibitor together was little different from that of the GABA-T inhibitor alone.     

Interactions in the Metabolism of Glutamate and the Branched-Chain Amino Acids and Ketoacids in the CNS

Glutamatergic neurotransmission entails a tonic loss of glutamate from nerve endings into the synapse. Replacement of neuronal glutamate is essential in order to avoid depletion of the internal pool. In brain this occurs primarily via the glutamate-glutamine cycle, which invokes astrocytic synthesis of glutamine and hydrolysis of this amino acid via neuronal phosphate-dependent glutaminase. This cycle maintains constancy of internal pools, but it does not provide a mechanism for inevitable losses of glutamate N from brain. Import of glutamine or glutamate from blood does not occur to any appreciable extent. However, the branched-chain amino acids (BCAA) cross the blood–brain barrier swiftly. The brain possesses abundant branched-chain amino acid transaminase activity which replenishes brain glutamate and also generates branched-chain ketoacids. It seems probable that the branched-chain amino acids and ketoacids participate in a “glutamate-BCAA cycle” which involves shuttling of branched-chain amino acids and ketoacids between astrocytes and neurons. This mechanism not only supports the synthesis of glutamate, it also may constitute a mechanism by which high (and potentially toxic) concentrations of glutamate can be avoided by the re-amination of branched-chain ketoacids.     

Effect of 8-bromo-cAMP and dexamethasone on glutamate metabolism in rat astrocytes

Glutamine synthetase (GS) activity in cultured rat astrocytes was measured in extracts and compared to the intracellular rate of glutamine synthesis by intact control astrocytes or astrocytes exposed to 1 mM 8-bromo-cAMP (8Br-cAMP)+1 M dexamethasone (DEX) for 4 days. GS activity in extracts of astrocytes treated with 8Br-cAMP+DEX was 7.5 times greater than the activity in extracts of control astrocytes. In contrast, the intracellular rate of glutamine synthesis by intact cells increased only 2-fold, suggesting that additional intracellular effectors regulate the expression of GS activity inside the intact cell. The rate of glutamine synthesis by astrocytes was 4.3 times greater in MEM than in HEPES buffered Hank's salts. Synthesis of glutamine by intact astrocytes cultured in MEM was independent of the external glutamine or ammonia concentrations but was increased by higher extracellular glutamate concentrations. In studies with intact astrocytes 80% of the original [U-¹⁴C]glutamate was recovered in the medium as radioactive glutamine, 2–3% as aspartate, and 7% as glutamate after 2 hours for both control and treated astrocytes. The results suggest: (1) astrocytes are highly efficient in the conversion of glutamate to glutamine; (2) induction of GS activity increases the rate of glutamate conversion to glutamine by astrocytes and the rate of glutamine release into the medium; (3) endogenous intracellular regulators of GS activity control the flux of glutamate through this enzymatic reaction; and, (4) the composition of the medium alters the rate of glutamine synthesis from external glutamate.     

Distinct changes in neuronal and astrocytic amino acid neurotransmitter metabolism in mice with reduced numbers of synaptic vesicles

The relations between glutamate and GABA concentrations and synaptic vesicle density in nerve terminals were examined in an animal model with 40–50% reduction in synaptic vesicle numbers caused by inactivation of the genes encoding synapsin I and II. Concentrations and synthesis of amino acids were measured in extracts from cerebrum and a crude synaptosomal fraction by HPLC and ¹³C nuclear magnetic resonance spectroscopy (NMRS), respectively. Analysis of cerebrum extracts, comprising both neurotransmitter and metabolic pools, showed decreased concentration of GABA, increased concentration of glutamine and unchanged concentration of glutamate in synapsin I and II double knockout (DKO) mice. In contrast, both glutamate and GABA concentrations were decreased in crude synaptosomes isolated from synapsin DKO mice, suggesting that the large metabolic pool of glutamate in the cerebral extracts may overshadow minor changes in the transmitter pool. ¹³C NMRS studies showed that the changes in amino acid concentrations in the synapsin DKO mice were caused by decreased synthesis of GABA (20–24%) in cerebral neurons and increased synthesis of glutamine (36%) in astrocytes. In a crude synaptosomal fraction, the glutamate synthesis was reduced (24%), but this reduction could not be detected in cerebrum extracts. We suggest that lack of synaptic vesicles causes down-regulation of neuronal GABA and glutamate synthesis, with a concomitant increase in astrocytic synthesis of glutamine, in order to maintain normal neurotransmitter concentrations in the nerve terminal cytosol.     

Differential effects of ammonia and β-methylene-dl-aspartate on metabolism of glutamate and related amino acids by astrocytes and neurons in primary culture

The effects of ammonium chloride (3 mM) and -methylene-dl-aspartate (BMA; 5 mM) (an inhibitor of aspartate aminotransferase, a key enzyme of the malate-aspartate shuttle (MAS)) on the metabolism of glutamate and related amino acids were studied in primary cultures of astrocytes and neurons. Both ammonia and BMA inhibited¹⁴CO₂ production from [U-¹⁴C]-and [1-¹⁴C]glutamate by astrocytes and neurons and their effects were partially additive. Acute treatment of astrocytes with ammonia (but not BMA) increased astrocytic glutamine. Acute treatment of astrocytes with ammonia or BMA decreased astrocytic glutamate and aspartate (both are key components of the MAS). Acute treatment of neurons with ammonia decreased neuronal aspartate and glutamine and did not apparently affect the efflux of aspartate from neurons. However, acute BMA treatment of neurons led to decreased neuronal glutamate and glutamine and apparently reduced the efflux of aspartate and glutamine from neurons. The data are consistent with the notion that both ammonia and BMA may inhibit the MAS although BMA may also directly inhibit cellular glutamate uptake. Additionally, these results also suggest that ammonia and BMA exert differential effects on astroglial and neuronal glutamate metabolism.This paper is dedicated to Professor E. Kvamme. Dr. Kvamme has conducted numerous pioneering studies on the regulation of the metabolism of glutamine, glutamate and ammonia in nervous and other tissues (see Refs. 1 and 3 for a complete discussion and citation of his many papers). Many important ideas in this exciting field of research have emerged from the work carried out in his laboratory.     

Role of Pyruvate Carboxylase in Facilitation of Synthesis of Glutamate and Glutamine in Cultured Astrocytes

Abstract: CO₂ fixation was measured in cultured astrocytes isolated from neonatal rat brain to test the hypothesis that the activity of pyruvate carboxylase influences the rate of de novo glutamate and glutamine synthesis in astrocytes. Astrocytes were incubated with ¹⁴CO₂ and the incorporation of ¹⁴C into medium or cell extract products was determined. After chromatographic separation of ¹⁴C-labelled products, the fractions of ¹⁴C cycled back to pyruvate, incorporated into citric acid cycle intermediates, and converted to the amino acids glutamate and glutamine were determined as a function of increasing pyruvate carboxylase flux. The consequences of increasing pyruvate, bicarbonate, and ammonia were investigated. Increasing extracellular pyruvate from 0 to 5 mM increased pyruvate carboxylase flux as observed by increases in the ¹⁴C incorporated into pyruvate and citric acid cycle intermediates, but incorporation into glutamate and glutamine, although relatively high at low pyruvate levels, did not increase as pyruvate carboxylase flux increased. Increasing added bicarbonate from 15 to 25 mM almost doubled CO₂ fixation. When 25 mM bicarbonate plus 0.5 mM pyruvate increased pyruvate carboxylase flux to approximately the same extent as 15 mM bicarbonate plus 5 mM pyruvate, the rate of appearance of [¹⁴C]glutamate and glutamine was higher with the lower level of pyruvate. The conclusion was drawn that, in addition to stimulating pyruvate carboxylase, added pyruvate (but not added bicarbonate) increases alanine aminotransferase flux in the direction of glutamate utilization, thereby decreasing glutamate as pyruvate + glutamate →α-ketoglutarate + alanine. In contrast to previous in vivo studies, the addition of ammonia (0.1 and 5 mM) had no effect on net ¹⁴CO₂ fixation, but did alter the distribution of ¹⁴C-labelled products by decreasing glutamate and increasing glutamine. Rather unexpectedly, ammonia did not increase the sum of glutamate plus glutamine (mass amounts or ¹⁴C incorporation). Low rates of conversion of α-[¹⁴C]ketoglutarate to [¹⁴C]glutamate, even in the presence of excess added ammonia, suggested that reductive amination of α-ketoglutarate is inactive under conditions studied in these cultured astrocytes. We conclude that pyruvate carboxylase is required for de novo synthesis of glutamate plus glutamine, but that conversion of α-ketoglutarate to glutamate may frequently be the rate-limiting step in this process of glutamate synthesis.     

Activities of glutamine synthetase,glutaminase and arginase in kainic acid lesioned rat brain corpus striatum

Intrastriatal kainic acid (2 μg/μl) administration gave rise to significant increase in activities of glutamine synthetase and arginase along with a significant decrease in the activity of glutaminase in the lesioned striatal tissue 7 days after the administration of kainic acid. The increase in the activity of glutamine synthetase was attributed to the gliosis occurring in such lesions. The decrease in the activity of glutaminase was thought to be due to the loss of GABAergic neurons. The increase in arginase activity might be occurring in glial cells or in nerve endings. Although the earlier results indicated a low specific activity of arginase in glial cells, the observed increase in its activity might be partly due to its increase in proliferating glial cells, liberating ornithine for the formation of polyamines. However, it was also thought that a substantial increase may be occurring in the arginase present in the intact glutamatergic (corticostriate pathway) nerve endings, since it was earlier found that the synaptosomes of the rat brain had appreciably high activity of arginase. These results were discussed in relation to the probable roles of arginine and glutamine as the precursors for neurotransmitter pools of glutamate in striatum.     

Down-expressed GLT-1 in PSD astrocytes inhibits synaptic formation of NSC-derived neurons in vitro

Little is known about the effect of astroglial GLT-1 of post-stroke depression (PSD) rat model on the function of neural stem cells (NSCs). This study aimed to investigate whether astroglial GLT-1 of PSD rats affect differentiation of NSCs from neonatal rat hippocampus and synaptic formation of NSC-derived neurons. Astrocytes were isolated from the left hippocampus of normal adult SD rats and PSD rats. A lentiviral vector was used to silence the expression of GLT-1 in astrocytes of PSD rats. NSCs were respectively co-cultured with normal (control), PSD, and GLT-1 silenced astrocytes for 7 days. GLT-1, GFAP, MAP2, Synaptophysin (SYN), glutamate (Glu) and glutamine (Gln) were respectively measured by qRT-PCR, western blot, immunofluorescence and efficient mass spectrometry (MS). PSD astrocytes increased the number of NSC-derived astrocytes, but inhibited the expression of GLT-1 of NSC-derived astrocytes and synapses of NSC-derived neurons. On the basis of the low expression of GLT-1 in PSD astrocytes, we further silenced GLT-1 in PSD astrocytes. Interestingly, GLT-1 silenced PSD astrocytes more obviously inhibited synapses of NSC-derived neurons, but increased the number of NSC-derived neurons and reversed the expression of GLT-1 in NSC-derived astrocytes. At the same time, concentration of glutamate in the medium elevated, and glutamine in the medium gradually reduced. In NSC-derived neurons and astrocytes, glutamate metabolism was also affected by changed GLT-1. Down-expressed GLT-1 in PSD astrocytes stimulated NSCs differentiating into astrocytes, but inhibiting the formation of functional synapses by influencing glutamate metabolism in vitro.     

Elevation of transamination of branched chain amino acids in brain in acute ammonia toxicity

The activity levels of leucine, isoleucine and valine aminotransferases were determined in various cerebral regions, liver and muscle of rats injected with a large dose of ammonium acetate and were compared with those of normal animals. In brain the activity levels of both leucine and isoleucine aminotransferases were elevated in both preconvulsive and convulsive states. Valine aminotransferase activity was suppressed in brain stem and corpus striatum and was elevated in cerebellum and hippocampus in preconvulsive states. During convulsions its activity was suppressed in cerebral cortex and hippocampus. Under these conditions, there was a suppression of both leucine and valine aminotransferases in muscle. In liver, however, the activities of these enzymes were elevated. The results suggested that the glutamate required for glutamine formation in hyperammonaemic states in brain might be obtained from branched chain amino acids, especially leucine and isoleucine.     

Inhibition of glutamine synthesis induces glutamate dehydrogenase-dependent ammonia fixation into alanine in co-cultures of astrocytes and neurons

It has been previously demonstrated that ammonia exposure of neurons and astrocytes in co-culture leads to net synthesis not only of glutamine but also of alanine. The latter process involves the concerted action of glutamate dehydrogenase (GDH) and alanine aminotransferase (ALAT). In the present study it was investigated if the glutamine synthetase (GS) inhibitor methionine sulfoximine (MSO) would enhance alanine synthesis by blocking the GS-dependent ammonia scavenging process. Hence, co-cultures of neurons and astrocytes were incubated for 2.5 h with [U-¹³C]glucose to monitor de novo synthesis of alanine and glutamine in the absence and presence of 5.0 mM NH₄Cl and 10 mM MSO. Ammonia exposure led to increased incorporation of label but not to a significant increase in the amount of these amino acids. However, in the presence of MSO, glutamine synthesis was blocked and synthesis of alanine increased leading to an elevated content intra- as well as extracellularly of this amino acid. Treatment with MSO led to a dramatic decrease in glutamine content and increased the intracellular contents of glutamate and aspartate. The large increase in alanine during exposure to MSO underlines the importance of the GDH and ALAT biosynthetic pathway for ammonia fixation, and it points to the use of a GS inhibitor to ameliorate the brain toxicity and edema induced by hyperammonemia, events likely related to glutamine synthesis.     

The metabolic role of isoleucine in detoxification of ammonia in cultured mouse neurons and astrocytes

Cerebral hyperammonemia is a hallmark of hepatic encephalopathy, a debilitating condition arising secondary to liver disease. Pyruvate oxidation including tricarboxylic acid (TCA) cycle metabolism has been suggested to be inhibited by hyperammonemia at the pyruvate and -ketoglutarate dehydrogenase steps. Catabolism of the branched-chain amino acid isoleucine provides both acetyl-CoA and succinyl-CoA, thus by-passing both the pyruvate dehydrogenase and the -ketoglutarate dehydrogenase steps. Potentially, this will enable the TCA cycle to work in the face of ammonium-induced inhibition. In addition, this will provide the -ketoglutarate carbon skeleton for glutamate and glutamine synthesis by glutamate dehydrogenase and glutamine synthetase (astrocytes only), respectively, both reactions fixing ammonium. Cultured cerebellar neurons (primarily glutamatergic) or astrocytes were incubated in the presence of either [U-¹³C]glucose (2.5 mM) and isoleucine (1 mM) or [U-¹³C]isoleucine and glucose. Cell cultures were treated with an acute ammonium chloride load of 2 (astrocytes) or 5 mM (neurons and astrocytes) and incorporation of ¹³C-label into glutamate, aspartate, glutamine and alanine was determined employing mass spectrometry. Labeling from [U-¹³C]glucose in glutamate and aspartate increased as a result of ammonium-treatment in both neurons and astrocytes, suggesting that the TCA cycle was not inhibited. Labeling in alanine increased in neurons but not in astrocytes, indicating elevated glycolysis in neurons. For both neurons and astrocytes, labeling from [U-¹³C]isoleucine entered glutamate and aspartate albeit to a lower extent than from [U-¹³C]glucose. Labeling in glutamate and aspartate from [U-¹³C]isoleucine was decreased by ammonium treatment in neurons but not in astrocytes, the former probably reflecting increased metabolism of unlabeled glucose. In astrocytes, ammonia treatment resulted in glutamine production and release to the medium, partially supported by catabolism of [U-¹³C]isoleucine. In conclusion, i) neuronal and astrocytic TCA cycle metabolism was not inhibited by ammonium and ii) isoleucine may provide the carbon skeleton for synthesis of glutamate/glutamine in the detoxification of ammonium.     

Effect of pH on Glutamine Content Derived from Exogenous Glutamate in Astrocytes

Abstract: A shift in pH from 7.4 to 7.8 in the incubation solution caused a 3.4-fold increase in the free glutamine content of mouse cerebral astrocytes that were incubated with glutamate (100 μ M ) and ammonium (100 μ M ). This large and reversible steady-state increase in glutamine content was accompanied by smaller transient increases in the following: (a) net formation of glutamine; (b) clearance of glutamate from the incubation solution; and (c) glutamate content. The content of glutamine was reduced markedly by omission of either glutamate or ammonium from the incubation solution, or by inhibition of glutamine synthetase activity with methionine sulfoximine. The rate at which glutamine was exported from the astrocytes was unaffected by the pH change. The effects of pH on the concentration of free ammonia or on glutamate uptake do not appear to mediate the increase in glutamine content. Uptake of exogenous glutamine was little affected by the pH change. Therefore, possible mediation of the effect by an increase in intracellular pH must be considered. The response to altered pH described here may provide a cellular basis for the increased level of brain glutamine observed in hyperammonemia.     

Exogenous Glutamate Concentration Regulates the Metabolic Fate of Glutamate in Astrocytes

Abstract: The metabolic fate of glutamate in astrocytes has been controversial since several studies reported >80% of glutamate was metabolized to glutamine; however, other studies have shown that half of the glutamate was metabolized via the tricarboxylic acid (TCA) cycle and half converted to glutamine. Studies were initiated to determine the metabolic fate of increasing concentrations of [U-¹³C]glutamate in primary cultures of cerebral cortical astrocytes from rat brain. When astrocytes from rat brain were incubated with 0.1 m M [U-¹³C]glutamate 85% of the ¹³C metabolized was converted to glutamine. The formation of [1,2,3-¹³C₃]glutamate demonstrated metabolism of the labeled glutamate via the TCA cycle. When astrocytes were incubated with 0.2–0.5 m M glutamate, ¹³C from glutamate was also incorporated into intracellular aspartate and into lactate that was released into the media. The amount of [¹³C]lactate was essentially unchanged within the range of 0.2–0.5 m M glutamate, whereas the amount of [¹³C]aspartate continued to increase in parallel with the increase in glutamate concentration. The amount of glutamate metabolized via the TCA cycle progressively increased from 15.3 to 42.7% as the extracellular glutamate concentration increased from 0.1 to 0.5 m M , suggesting that the concentration of glutamate is a major factor determining the metabolic fate of glutamate in astrocytes. Previous studies using glutamate concentrations from 0.01 to 0.5 m M and astrocytes from both rat and mouse brain are consistent with these findings.     

Excess Extracellular and Low Intracellular Glutamate in Poorly Differentiating Wobbler Astrocytes and Astrocyte Recovery in Glutamine-Depleted Culture Medium

Abstract: The wobbler mouse develops an inherited motoneuronal degeneration of unknown origin in the spinal cord. Primary cultures of adult wobbler spinal cord astrocytes display abnormal morphological characteristics with fewer processes and paucity of cell-cell contacts. We have searched for a possible involvement of glutamate and glutamine intra- and extracellular accumulations in vitro in the abnormal differentiation of mutant astrocytes. We have found significantly higher glutamate and glutamine concentrations in the culture media of mutant astrocytes over a 3-day period compared with normal control astrocytes. Moreover, intracellular glutamate concentrations decreased substantially in mutant astrocytes, but intracellular glutamine concentrations remained unchanged. Furthermore, decreasing initial glutamine concentrations in the culture medium (glutamine-depleted medium) led to the recovery of normal extra- and intracellular concentrations of glutamate and recovery of quasi-normal morphological differentiation and increased cell-cell contacts, leading to an essentially normal looking astrocyte network after 3 days of culture. Under these conditions, which lead to recovery, the only remaining abnormality was the higher glutamine extracellular concentration attained in the originally depleted glutamine media. These findings suggest that mechanisms regulating glutamate/glutamine synthesis and/or influx/efflux are defective in wobbler astrocytes, leading to metabolic imbalance and possible cytotoxic effects characterized by disturbed intercellular networks and poor differentiation.