Mechanism of conversion of aspartate into glutamate in cerebral-cortex slices

1. When slices of guinea-pig cerebral-cortex slices are incubated with [U-¹⁴C]-aspartate and non-radioactive glucose as substrates, the specific radioactivities of the citric acid-cycle intermediates are lower than that of the glutamate isolated from the same vessels. 2. Glutamate was significantly labelled when [1-¹⁴C]-aspartate and glucose were present in the incubation medium. These results would not be expected on the basis of simple conversion of aspartate into glutamate through the citric acid cycle, since the C-1 position of oxaloacetate is decarboxylated in the conversion of isocitrate into α-oxoglutarate. 3. It appears that aspartate is converted into glutamate by citric acid-cycle mechanisms; however, the carbon `skeleton' is not immediately condensed with acetyl-CoA to form citrate but first follows the cycle in a reverse direction to fumarate or succinate and then proceeds in the forward direction. 4. The conversion of aspartate into glutamate appears to be compartmentalized.     

Compartmentation of citric acid cycle metabolism in brain: effect of aminooxyacetic acid, ouabain and Ca2+ on the labelling of glutamate, glutamine, aspartate and gaba by [1-14C]acetate, [U-14C]glutamate and [U-14C]asparate

—(1) The effects of aminooxyacetic acid, ouabain and Ca²⁺ on the compartmentation of amino acid metabolism have been studied in slices of brain incubated with sodium-[1-¹⁴C]acetate, l-[U-¹⁴C]glutamate and l-[U-¹⁴C]aspartate as tracer metabolites. (2) Aminooxyacetic acid (10^-3 m) inhibited the labelling of aspartate from [¹⁴C]acetate and [¹⁴C]glutamate, as well as the incorporation of label from [¹⁴C]aspartate into glutamate and glutamine. It also inhibited the labelling of GABA from all three radioactive precursors, as would be anticipated if there was inhibition of several transaminases as well as glutamate decarboxylase. The RSA of glutamine labelled from [1-¹⁴C]acetate was increased. This finding indicated that the glutamate pool which is utilized for glutamine formation is associated with glutamate dehydrogenase, and this enzyme appears to be related to the ‘synthetic tricarboxylic acid cycle’. AOAA exerted its major inhibitory effects on the citric acid‘energy cycle’with which transaminases are associated. (3) Ouabain (10^-5 m) inhibited the labelling of glutamine to a much greater extent than the labelling of glutamate from [1-¹⁴C]acetate. It also caused leakage of amino acids from the tissue into the medium. Its effect on the glutamate–glutamine system was interpreted to be a selective inhibition of the 'synthetic’citric acid cycle. (4) The omission of Ca²⁺ from the incubation medium was associated with formation of glutamine with RSA less than 1·0 when labelled from [U-¹⁴C]glutamate, [U-¹⁴C]aspartate and lower than normal when labelled from [1-¹⁴C]acetate.     

ÈVIDENCE FOR THE COMPARTMENTATION OF GLUTAMATE METABOLISM IN ISOLATED RAT RETINA

—Glucose is a major precursor of glutamate and related amino acids in the retina of adult rats. ¹⁴C from labelled glucose appears to gain access to a large glutamate pool, and the resulting specific activity of glutamate labelled from glucose is always higher than that of glutamine or the other amino acids. Radioactive acetate appeared to label a small glutamate pool. The specific activity of glutamine labelled from acetate relative to that of glutamate was always greater than 1.0. Other precursors of the small glutamate pool were found to include glutamate, aspartate, GABA, serine, leucine and sodium bicarbonate. The level of radioactivity present in retinae incubated with [U-¹⁴C]glucose or [1-¹⁴C]sodium acetate was reduced in the presence of 10^?5m -ouabain. Under these conditions, the relative specific activity of glutamine labelled from [1-¹⁴C]sodium acetate was lowered, but it was raised when [U-¹⁴C]glucose was used as substrate. Ouabain also considerably reduced the synthesis of GABA from [1-¹⁴C]sodium acetate. In all cases ouabain caused a fall in the tissue levels of the amino acids. Aminooxyacetic acid (10^?4m ) almost completely abolished the labelling of GABA from both [U-¹⁴C]glucose and [1-¹⁴C]sodium acetate, while the RSA of glutamine labelled from the latter substrate was significantly increased. Aminooxyacetic acid raised the tissue concentration of glutamate, but caused a fall in the tissue concentrations of glutamine, aspartate and GABA. The results suggest that there are separate compartments for the metabolism of glutamate in retina and that these can be modified in different ways by different drugs.     

The operation of the γ-aminobutyrate bypath of the tricarboxylic acid cycle in brain tissue in vitro

1. Cerebral-cortex slices prelabelled with gamma-amino[1-(14)C]butyrate (GABA) were incubated in a glucose-saline medium. After the initial rapid uptake there was no appreciable re-entry of (14)C into the GABA pool, either from the medium or from labelled metabolites formed in the tissue. The kinetic constants of GABA metabolism were determined by computer simulation of the experimental results by using mathematical procedures. The GABA flux was estimated to be 0.03mumol per min/g, or about 8% of the total flux through the tricarboxylic acid cycle. It was found that the assumption of compartmentation did not greatly affect the estimates of the GABA flux. 2. The time-course of incorporation of (14)C into amino acids associated with the tricarboxylic acid cycle was followed with [1-(14)C]GABA and [U-(14)C]-glucose as labelled substrates. The results were consistent with the utilization of GABA via succinate. This was confirmed by determining the position of (14)C in the carbon skeletons of aspartate and glutamate formed after the oxidation of [1-(14)C]GABA. These results also indicated that under the experimental conditions the reversal of reactions catalysed by alpha-oxoglutarate dehydrogenase and glutamate decarboxylase respectively was negligible. The conversion of [(14)C]GABA into gamma-hydroxybutyrate was probably also of minor importance, but decarboxylation of oxaloacetate did occur at a relatively slow rate. 3. When [1-(14)C]GABA was the labelled substrate there was evidence of a metabolic compartmentation of glutamate since, even before the peak of the incorporation of (14)C into glutamate had been reached, the glutamine/glutamate specific-radioactivity ratio was greater than unity. When [U-(14)C]glucose was oxidized this ratio was less than unity. The heterogeneity of the glutamate pool was indicated also by the relatively high specific radioactivity of GABA, which was comparable with that of aspartate during the whole incubation time (40min). The rates of equilibration of labelled amino acids between slice and medium gave evidence that the permeability properties of the glutamate compartments labelled as a result of oxidation of [1-(14)C]GABA were different from those labelled by the metabolism of [(14)C]glucose. The results showed therefore that in brain tissue incubated under the conditions used, the organization underlying metabolic compartmentation was preserved. The observed concentration ratios of amino acids between tissue and medium were also similar to those obtaining in vivo. These ratios decreased in the order: GABA>acidic acids>neutral amino acids>glutamine. 4. The approximate pool sizes of the amino acids in the different metabolic compartments were calculated. The glutamate content of the pool responsible for most of the labelling of glutamine during oxidation of [1-(14)C]GABA was estimated to be not more than 30% of the total tissue glutamate. The GABA content of the ;transmitter pool' was estimated to be 25-30% of the total GABA in the tissue. The structural correlates of metabolic compartmentation were considered.     

Amino acid oxidation and alanine production in rat hemidiaphragm in vitro. Effects of dichloroacetate.

Dichloroacetate (an activator of pyruvate dehydrogenase) stimulates 14CO2 production from [U-14C]glucose, but not from [U-14C]glutamate, [U-14C]aspartate, [U-14C]- and [1-14C]-valine and [U-14C]- and [1-14C]-leucine. It is concluded (1) that pyruvate dehydrogenase is not rate-limiting in the oxidation to CO2 of amino acids that are metabolized to tricarboxylic acid-cycle intermediates, and (2) that carbohydrate (and not amino acids) is the main carbon precursor in alanine formation in muscle.     

Quantification of carbon fluxes through the tricarboxylic acid cycle in early germinating lettuce embryos

A method involving labeling to isotopic steady state and modeling of the tricarboxylic acid cycle has been used to identify the respiratory substrates in lettuce embryos during the early steps of germination. We have compared the specific radioactivities of aspartate and glutamate and of glutamate C-1 and C-5 after labeling with different substrates. Labeling with [U-14C]acetate and 14CO2 was used to verify the validity of the model for this study; the relative labeling of aspartate and glutamate was that expected from the normal operation of the tricarboxylic acid cycle. After labeling with 14CO2, the label distribution in the glutamate molecule (95% of the label at glutamate C-1) was consistent with an input of carbon via the phosphoenolpyruvate carboxylase reaction, and the relative specific radioactivities of aspartate and glutamate permitted the quantification of the apparent rate of the fumarase reaction. CO2 and intermediates related to the tricarboxylic acid cycle were labeled with [U-14C]acetate, [1-14C] hexanoate, or [U-14C]palmitic acid. The ratios of specific radioactivities of asparate to glutamate and of glutamate C-1 to C-5 indicated that the fatty acids were degraded to acetyl units, suggesting the operation of beta-oxidation, and that the acety-CoA was incorporated directly into citrate. Short-term labeling with [1-14C]hexanoate showed that citrate and glutamate were labeled earlier than malate and aspartate, showing that this fatty acid was metabolized through the tricarboxylic acid cycle rather than the glyoxylate cycle. This was in agreement with the flux into gluconeogenesis compared to efflux as respiratory CO2. The fraction of labeled substrate incorporated into carbohydrates was only about 5% of that converted to CO2; the carbon flux into gluconeogenesis was determined after labeling with 14CO2 and [1-14C]hexanoate from the specific radioactivity of aspartate C-1 and the amount of label incorporated into the carbohydrate fraction. It was only 7.4% of the efflux of respiratory CO2. The labeling of alanine indicates a low activity of either a malic enzyme or the sequence phosphoenolpyruvate carboxykinase/pyruvate kinase. After labeling with [U-14C]glucose, the ratios of specific radioactivities indicated that the labeled carbohydrates contributed less than 10% to the flux of acetyl-CoA. The model indicated that the glycolytic flux is partitioned one-third to pyruvate and two-thirds to oxalacetate and is therefore mainly anaplerotic. The possible role of fatty acids as the main source of acetyl-CoA for respiration is discussed.     

Purification and characterization of cytosolic aldolase from carrot storage root.

The time courses of incorporation of 13C from 13C-labelled glucose or acetate into cerebral amino acids (glutamate, glutamine and 4-aminobutyrate) and lactate were monitored by using 13C-n.m.r. spectroscopy. When [1-13C]glucose was used as precursor the C-2 of 4-aminobutyrate was more highly labelled than the analogous C-4 of glutamate, whereas no label was observed in glutamine. A similar pattern was observed with [2-13C]glucose: the C-1 of 4-aminobutyrate was more highly labelled than the analogous C-5 of glutamate. Again, no labelling of glutamine was detected. In contrast, [2-13C]acetate labelled the C-4 of glutamine and the C-2 of 4-aminobutyrate more highly than the C-4 of glutamate; [1-13C]acetate also labelled the C-1 and C-5 positions of glutamine more than the analogous positions of glutamate. These results are consistent with earlier patterns reported from the use of 14C-labelled precursors that led to the concept of compartmentation of neuronal and glial metabolism and now provide the possibility of distinguishing differential effects of metabolic perturbations on the two pools simultaneously. An unexpected observation was that citrate is more highly labelled from acetate than from glucose.     

DECARBOXYLATION STUDIES OF GLUTAMATE, GLUTAMINE, AND ASPARTATE FROM BRAIN LABELLED WITH [1-14C] ACETATE, l-[U-14C]-ASPARTATE, AND l-[U-14C]GLUTAMATE

Studies in vivo and in vitro of the distribution of label in C-1 of glutamate and glutamine and C-4 of aspartate in the free amino acids of brain were carried out. [1-¹⁴C]-Acetate was used both in vivo and in vitro and l -[U-¹⁴C]aspartate and l -[U-¹⁴C]glutamate were used in vitro.

• 1 The results obtained with labelled acetate and aspartate suggest that CO₂ and a 3-carbon acid may exchange at different rates on a CO_a-fixing enzyme.
• 2 The apparent cycling times of both glutamate and glutamine show fast components measured in minutes and slow components measured in hours.
• 3 With [1-¹⁴C]acetate in vitro glutamine is more rapidly labelled in C-1 than is glutamate at early time points; the curves cross over at about 7 min.
• 4 The results support and extend the concept of metabolic compartmentation of amino acid metabolism in brain.

     

GLUCOSE AND AMINO ACID METABOLISM IN SOME INVERTEBRATE NERVOUS SYSTEMS

(1) The in vitro metabolism of [U-¹⁴C]glucose and [U-¹⁴C]glutamate was compared in snail, octopus and locust ganglia, and in rat cerebral cortex. (2) The metabolic patterns are quantitatively similar. The major labelled metabolites formed from glucose or glutamate by rat cortex and the invertebrate systems were CO₂, aspartate, glutamate, glutamine and alanine. γ-Aminobutyric acid (GABA) was formed in substantial amounts only by locust and rat. (3) A much larger proportion of labelled glucose and glutamate was converted to alanine by the invertebrates compared with rat cortex, although ¹⁴CO₂ production was lower. (4) The effect of glucose in reducing aspartate formation and stimulating glutamine formation from [U-¹⁴C]glutamate in mammalian cortex was observed in the locust but not in the molluscs. (5) Labelled citric acid cycle intermediates were formed in substantial quantities from glucose and glutamate only by snail and locust.     

The tricarboxylic acid cycle in Dictyostelium discoideum. Metabolite concentrations, oxygen uptake and 14c-labelled amino acid labelling patterns.

Some aspects of tricarboxylic acid-cycle activity during differentiation and aging in Dictyostelium discoideum were examined. The concentrations of glutamate, aspartate, alanine, citrate, 2-oxoglutarate, succinate, fumarate, malate, oxaloacetate, pyruvate and acetyl-CoA were determined at four stages over the course of differentiation. The rate of O2 utilization was also determined over differentiation. In addition, experiments are described in which the specific radioactivities of citrate, 2-oxoglutarate, succinate, fumarate and malate were determined during a 30 min labelling of cells from the preculmination stage of development with [14C]glutamate, [14C]aspartate or [14C]alanine. A similar experiment was also performed with cells from the aggregation stage of development using [14C]glutamate.     

EFFECTS OF SODIUM FLUOROACETATE ON THE METABOLISM OF N-ACETYLASPARTATE AND ASPARTATE IN MOUSE BRAIN

A subconvulsant dose of sodium fluoroacetate inhibited the metabolic utilization of intracerebrally-administered N-acetyl-l -[U-¹⁴C]asparticacid and the labelling of glutamine from this precursor in mouse brain, but not the labelling of glutamate or aspartate. A convulsant dose also inhibited the utilization of l -[U-¹⁴C]aspartic acid. When intraperitoneal injection of a convulsant dose of sodium fluoroacetate was followed by intracerebral injection of N-acetyl-l -[U-¹⁴C]asparticacid, the levels of N-acetylaspartate, aspartate and glutamate in brain were lowered, while the glutamine content was increased. The specific radioactivity of glutamine relative to that of glutamate was much lower when these compounds were labelled from l -[U-¹⁴C]aspartic acid than when N-acetyl-l -[U-¹⁴C]aspartic acid was used as the precursor. Intracerebral injection of tracer amounts of l -[U-¹⁴C]aspartic acid reduced the content of N-acetylaspartate in brain and raised the glutamine content. Sodium fluoroacetate had no additional effect on the relative specific radioactivity of glutamine or the content of N-acetylaspartate, aspartate, glutamate or glutamine when l -[U-¹⁴C]aspartic acid was the precursor. We consider the results to be consistent with a selective inhibition both by sodium fluoroacetate and by exogenous aspartic acid of the tricarboxylic acid cycle in brain associated with the biosynthesis of glutamine. We suggest that the activity of this pathway may regulate the metabolism of N-acetylaspartate and aspartate.     

Glutamate racemization and catabolism in Fusobacterium varium

The pathways of glutamate catabolism in the anaerobic bacterium Fusobacterium varium, grown on complex, undefined medium and chemically defined, minimal medium, were investigated using specifically labelled (13)C-glutamate. The metabolic end-products acetate and butyrate were isolated from culture fluids and derivatized for analysis by nuclear magnetic resonance and mass spectrometry. On complex medium, labels from L-[1-(13)C]glutamate and L-[4-(13)C]glutamate were incorporated into C1 of acetate and equally into C1/C3 of butyrate, while label derived from L-[5-(13)C]glutamate was not incorporated. The isotopic incorporation results and the detection of glutamate mutase and 3-methylaspartate ammonia lyase in cell extracts are most consistent with the methylaspartate pathway, the best known route of glutamate catabolism in Clostridium species. When F. varium was grown on defined medium, label from L-[4-(13)C]glutamate was incorporated mainly into C4 of butyrate, demonstrating a major role for the hydroxyglutarate pathway. Upon addition of coenzyme B(12) or cobalt ion to the defined medium in replicate experiments, isotope was located equally at C1/C3 of butyrate in accord with the methylaspartate pathway. Racemization of D-glutamate and subsequent degradation of L-glutamate via the methylaspartate pathway are supported by incorporation of label into C2 of acetate and equally into C2/C4 of butyrate from D-[3-(13)C]glutamate and the detection of a cofactor-independent glutamate racemase in cell extracts. Together the results demonstrate a major role for the methylaspartate pathway of glutamate catabolism in F. varium and substantial participation of the hydroxyglutarate pathway when coenzyme B(12) is not available.     

Pyruvate carboxylation as an anaplerotic mechanism in the isolated perfused rat heart.

1. The role of pyruvate carboxylation in the net synthesis of tricarboxylic acid-cycle intermediates during acetate metabolism was studied in isolated rat hearts perfused with [1-14C]pyruvate. 2. The incorporation of the 14C label from [1-14C]pyruvate into the tricarboxylic acid-cycle intermediates points to a carbon input from pyruvate via enzymes in addition to pyruvate dehydrogenase and citrate synthase. 3. On addition of acetate, the specific radioactivity of citrate showed an initial maximum at 2 min, with a subsequent decline in labelling. The C-6 of citrate (which is removed in the isocitrate dehydrogenase reaction) and the remainder of the molecule showed differential labelling kinetics, the specific radioactivity of C-6 declining more rapidly. Since this carbon is lost in the isocitrate dehydrogenase reaction, the results are consistent with a rapid inactivation of pyruvate dehydrogenase after the addition of acetate, which was confirmed by measuring the 14CO2 production from [1-14C]pyruvate. 4. The results can be interpreted to show that carboxylation of pyruvate to the C4 compounds of the tricarboxylic acid cycle occurs under conditions necessitating anaplerosis in rat myocardium, although the results do not identify the enzyme involved. 5. The specific radioactivity of tissue lactate was too low to allow it to be used as an indicator of the specific radioactivity of the intracellular pyruvate pool. The specific radioactivity of alanine was three times that of lactate. When the hearts were perfused with [1-14C]lactate, the specific radioactivity of alanine was 70% of that of pyruvate. The results suggest that a subcompartmentation of lactate and pyruvate occurs in the cytosol.     

Distribution of isotopic label after the oral administration of free and bound 14C-labelled glucosamine in rats

The metabolic fate of [1-(14)C]glucosamine, of N-acetyl[1-(14)C]glucosamine and of glycoproteins labelled with [1-(14)C]glucosamine was studied in rats for a period of 24hr. after these materials were given orally or injected. When [1-(14)C]glucosamine was injected 26.3% of the label was excreted in the urine, 19.7% was expired as carbon dioxide and 12.7% was incorporated into plasma proteins. When the same compound was given orally, 49.2% of the label was expired as carbon dioxide, with little appearing in the urine or in the plasma. When N-acetyl[1-(14)C]glucosamine was injected, 51.3% of the label was excreted in the urine with 12.3% appearing in carbon dioxide, but there was little incorporation into plasma protein. When this compound was given orally, 46.5% of the label was expired as carbon dioxide, 7.4% was recovered in the urine and 1.7% was incorporated into plasma protein. After the injection of (14)C-labelled glycoprotein 21.0% of the label was expired as carbon dioxide, whereas when it was given orally 49.8% of the label was recovered in carbon dioxide. The differences observed between the metabolic fate of the amino sugars when they were given orally and their fate when injected could not be accounted for by the action of the intestinal microflora or by the rate of administration of the material. It is concluded that amino sugars undergo metabolic alteration or degradation during absorption.     

Glycine formation during growth of Pseudomonas AM1 on methanol and succinate

1. The mechanism of regeneration of glycine during the growth of Pseudomonas AM1 on C(1) compounds has been investigated by brief incubation of bacterial suspensions with [2,3-(14)C(2)]succinate and observing the incorporation of radioactivity into various metabolites. 2. With the wild-type organism growing on methanol, radioactivity appeared rapidly in glycine and tricarboxylic acid-cycle intermediates, but there was a relatively slow labelling of serine and phosphorylated compounds. Serine became labelled predominantly in the C-2 position. 3. The proportion of radioactivity incorporated into glycine at earliest times was greatly diminished when succinate-grown cells were used. 4. Radioactivity was also incorporated from [2,3-(14)C(2)]succinate into glycine and serine by methanol-grown mutant 20S, which lacks phosphoserine phosphohydrolase. Both the glycine and serine were labelled mainly in C-2. 5. The formation of predominantly [2-(14)C]serine from [2,3-(14)C(2)]succinate in wild-type Pseudomonas AM1, and of [2-(14)C]serine and [2-(14)C]glycine in the mutant lacking the phosphorylated pathway from succinate to serine, is taken as strong evidence for a mechanism of glycine regeneration involving cleavage of a C(4) skeleton between C-2 and C-3, rather than by a direct combination of two C(1) units derived from the growth substrate. 6. The cleavage mechanism is quantitatively more significant during growth on methanol than on succinate.     

Compartmentation of glutamate metabolism in brain. Evidence for the existence of two different tricarboxylic acid cycles in brain

1. (14)C from [1-(14)C]glucose injected intraperitoneally into mice is incorporated into glutamate, aspartate and glutamine in the brain to a much greater extent than (14)C from [2-(14)C]glucose. This difference for [1-(14)C]glucose and [2-(14)C]glucose increases with time. The amount of (14)C in C-1 of glutamate increases steadily with time with both precursors. It is suggested that a large part of the glutamate and aspartate pools in brain are in close contact with intermediates of a fast-turning tricarboxylic acid cycle. 2. (14)C from [1-(14)C]acetate and [2-(14)C]acetate is incorporated to a much larger extent into glutamine than into glutamate. An examination of the time-course of (14)C incorporated into glutamine and glutamate reveals that glutamine is not formed from the glutamate pool, labelled extensively by glucose, but from a small glutamate pool. This small glutamate pool is not derived from an intermediate of a fast-turning tricarboxylic acid cycle. 3. It is proposed that two different tricarboxylic acid cycles exist in brain.     

Adrenergic inhibition of branched-chain 2-oxo acid dehydrogenase in rat diaphragm muscle in vitro.

In theory, the complete oxidation to CO2 of amino acids that are metabolized by conversion into tricarboxylic acid-cycle intermediates may proceed via their conversion into acetyl-CoA. The possible adrenergic modulation of this oxidative pathway was investigated in isolated hemidiaphragms from 40 h-starved rats. Adrenaline (5.5 microM), phenylephrine (0.49 mM) and dibutyryl cyclic AMP (10 microM) inhibited 14CO2 production from 3 mM-[U-14C]valine by 35%, 28% and 19% respectively. At the same time, these agents stimulated glycogen mobilization (measured as a decrease in glycogen content) and glycolysis (measured as lactate release). Adrenaline, phenylephrine and dibutyryl cyclic AMP did not inhibit 14CO2 production from 3 mM-[U-14C]aspartate or 3 mM-[U-14C]glutamate, although, as in the presence of valine, the agents stimulated glycogen mobilization and glycolysis. The rate of proteolysis (measured as tyrosine release in the presence of cycloheximide) was not changed by adrenaline. The data indicate that the adrenergic inhibition of 14CO2 production from [U-14C]valine was not a consequence of radiolabel dilution. Inhibition was apparently specific for branched-chain amino acid metabolism in that the adrenergic agonists also inhibited 14CO2 production from [1-14C]valine, [1-14C]leucine and [U-14C]isoleucine. Since 14CO2 production from the 1-14C-labelled substrates is a specific measure of decarboxylation in the reaction catalysed by the branched-chain 2-oxo acid dehydrogenase complex, it is at this site that the adrenergic agents are concluded to act.     

An NMR study of alterations in [1-13C]glucose metabolism in C6 glioma cells by gliotoxic amino acids

A series of glutamate analogues, known as gliotoxins, are toxic to astrocytes in culture, and are inhibitors or substrates of high affinity sodium-dependent glutamate transporters. The mechanisms by which these gliotoxins cause toxicity are not fully understood. The effects of a series of gliotoxic amino acids (L-alpha-aminoadipate, L-serine-O-sulphate, D-aspartate and L-cysteate) on metabolism of [1-13C]glucose were examined in C6 glioma cells using 13C nuclear magnetic resonance (NMR) spectroscopy. The cells were preincubated in the presence of sub toxic concentrations of each gliotoxin (400 micromol/l) for 20 h. This was followed by incubation (4 h) with [1-13C]glucose (5.5 mmol/l) in the presence and absence of each gliotoxin. The incorporation of 13C label into the observed metabolites was analysed. Following preincubation with L-alpha-aminoadipate, D-aspartate, and L-serine-O-sulphate there was a significant decrease in the incorporation of 13C label into glutamate, alanine and lactate from [1-13C]glucose. In the presence of L-cysteate production of labelled glutamate was decreased, while there was no significant effect on the concentrations of labelled lactate and alanine. There was no change in the quantity of LDH released into the medium after incubation of the cells with any of the gliotoxins. Overall these results indicate that the presence of gliotoxins profoundly alters the flux of glucose to lactate, alanine, aspartate and glutamate.     

A sex difference in hepatic glutathione S-transferase B and the effect of hypophysectomy.

[2-14C]Methyl cyanide (acetonitrile) is metabolized to citrate, succinate, fumarate, malate, glutamate, pyrrolidonecarboxylic acid and aspartate. Non-radioactive acetamide and acetate compete with 14C from methyl cyanide, and [2-14C]acetate and [2-14C]methyl cyanide are metabolized at similar rates, giving identical products. This evidence, combined with the inhibitory effect of fluoroacetate and arsenite on methyl cyanide metabolism, indicates that the pathway is: methyl cyanide leads to acetamide leads to acetate leads to tricarboxylic acid-cycle intermediates. The pathway was investigated in a species of Pseudomonas (group III; N.C.I.B. 10477), but comparison of labelling patterns suggests that it also exists in several higher plants.     

The effect of cosubstrates on tricarboxylic acid cycle dynamics during pyruvate oxidation: the formation of alpha-ketoglutarate and utilization of glutamate by mitochondria from rabbit brain.

—Data comparing tricarboxylic acid cycle dynamics in mitochondria from rabbit brain using [2- or 3-¹⁴C]pyruvate with and without cosubstrates (malate, α-ketoglutarate, glutamate) are reported. With a physiological concentration of an unlabelled cosubstrate, from 90-99% of the isotope remained in cycle intermediates. However, the liberation of ¹⁴CO₂ and the presence of ¹⁴C in the C-1 position of α-ketoglutarate indicated that multiple turns of the cycle occurred. Entry of pyruvate into the cycle was greater with malate than with either α-ketoglutarate or glutamate as cosubstrate. With malate as cosubstrate for [¹⁴C]pyruvate the amount of [¹⁴C]citrate which accumulated averaged 30nmol/ml or 23% of the pyruvate utilized while α-ketoglutarate averaged 45 nmol/ml or 35% of the pyruvate utilized. With α-ketoglutarate as cosubstrate for [¹⁴C]pyruvate, the average amount of [¹⁴C]citrate which accumulated decreased to 8 nmol/ml or 10% of the pyruvate utilized while [¹⁴C]α-ketoglutarate increased slightly to 52 nmol/ml or an increase to 62%, largely due to a decrease in pyruvate utilization. The percentage of ¹⁴C found in α-ketoglutarate was always greater than that found in malate, irrespective of whether α-ketoglutarate or malate was the cosubstrate for either [2- or 3-¹⁴C]pyruvate. The fraction of ¹⁴CO₂ produced was slightly greater with α-ketoglutarate as cosubstrate than with malate. This observation and the fact that malate had a higher specific activity than did α-ketoglutarate when α-ketoglutarate was the cosubstrate, indicated a preferential utilization of α-ketoglutarate formed within the mitochondria. When l -glutamate was a cosubstrate for [¹⁴C]pyruvate the principal radioactive product was glutamate, formed by isotopic exchange of glutamate with [¹⁴C] α-ketoglutarate. If malate was also added, [¹⁴C]citrate accumulated although pyruvate entry did not increase. Due to retention of isotope in glutamate, little [¹⁴C]succinate, malate or aspartate accumulated. When [U-¹⁴C]l -glutamate was used in conjunction with unlabelled pyruvate more ¹⁴C entered the cycle than when unlabelled glutamate was used with [¹⁴C]pyruvate and led to α-ketoglutarate, succinate and aspartate as the major isotopic products. When in addition, unlabelled malate was added, total and isotopic α-ketoglutarate increased while [¹⁴C]aspartate decreased. The increase in [¹⁴C]succinate when [¹⁴C] glutamate was used indicated an increase in the flux through α-ketoglutarate dehydrogenase and was accompanied by a decrease of pyruvate utilization as compared to experiments when either α-ketoglutarate or glutamate were present at low concentration. It is concluded that the tricarboxylic acid cycle in brain mitochondria operates in at least three open segments, (1) pyruvate plus malate (oxaloacetate) to citrate; (2) citrate to α-ketoglutarate and; (3) α-ketoglutarate to malate, and that at any given time, the relative rates of these segments depend upon the substrate composition of the environment of the mitochondria. These data suggest an approach to a steady state consistent with the kinetic properties of the tricarboxylic acid cycle within the mitochondria.