Effects of thiopental on transport and metabolism of glutamate in cultured cerebellar granule neurons

This study was performed to analyze the effects of the barbiturate thiopental on neuronal glutamate uptake, release and metabolism. Since barbiturates are known to bind to the GABA(A) receptor, some experiments were carried out in the presence of GABA. Cerebellar granule neurons were incubated for 2 h in medium containing 0.25 mM [U-(13)C]glutamate, 3 mM glucose, 50 microM GABA and 0.1 or 1 mM thiopental when indicated. When analyzing cell extracts, it was surprisingly found that in addition to glutamate, aspartate and glutathione, GABA was also labeled. In the medium, label was observed in glutamate, aspartate and lactate. Glutamate exhibited different labeling patterns, indicating metabolism in the tricarboxylic acid cycle, and subsequent release. A net uptake of [U-(13)C]glutamate and unlabeled glucose was seen under all conditions. The amounts of most metabolites synthesized from [U-(13)C]glutamate were unchanged in the presence of GABA with or without 0.1 mM thiopental. In the presence of 1 mM thiopental, regardless of the presence of GABA, decreased amounts of [1,2, 3-(13)C]glutamate and [U-(13)C]aspartate were found in the medium. In the cell extracts increased [U-(13)C]glutamate, [1,2, 3-(13)C]glutamate, labeled glutathione and [U-(13)C]aspartate were observed in the 1 mM thiopental groups. Glutamate efflux and uptake were studied using [(3)H]D-aspartate. While efflux was substantially reduced in the presence of 1 mM thiopental, this barbiturate only marginally inhibited uptake even at 3 mM. These results may suggest that the previously demonstrated neuroprotective action of thiopental could be related to its ability to reduce excessive glutamate outflow. Additionally, thiopental decreased the oxidative metabolism of [U-(13)C]glutamate but at the same time increased the detectable metabolites derived from the TCA cycle. These latter effects were also exerted by GABA.     

Role of glutamine and neuronal glutamate uptake in glutamate homeostasis and synthesis during vesicular release in cultured glutamatergic neurons

Glutamate exists in a vesicular as well as a cytoplasmic pool and is metabolically closely related to the tricarboxylic acid (TCA) cycle. Glutamate released during neuronal activity is most likely to a large extent accumulated by astrocytes surrounding the synapse. A compensatory flux from astrocytes to neurons of suitable precursors is obligatory as neurons are incapable of performing a net synthesis of glutamate from glucose. Glutamine appears to play a major role in this context. Employing cultured cerebellar granule cells, as a model system for glutamatergic neurons, details of the biosynthetic machinery have been investigated during depolarizing conditions inducing vesicular release. [U-13C]Glucose and [U-13C]glutamine were used as labeled precursors for monitoring metabolic pathways by nuclear magnetic resonance (NMR) spectroscopy and liquid chromatography-mass spectrometry (LC-MS) technologies. To characterize release mechanisms and influence of glutamate transporters on maintenance of homeostasis in the glutamatergic synapse, a quantification was performed by HPLC analysis of the amounts of glutamate and aspartate released in response to depolarization by potassium (55 mM) in the absence and presence of DL-threo-beta-benzyloxyaspartate (TBOA) and in response to L-trans-pyrrolidine-2,4-dicarboxylate (t-2,4-PDC), a substrate for the glutamate transporter. Based on labeling patterns of glutamate the biosynthesis of the intracellular pool of glutamate from glutamine was found to involve the TCA cycle to a considerable extent (approximately 50%). Due to the mitochondrial localization of PAG this is unlikely only to reflect amino acid exchange via the cytosolic aspartate aminotransferase reaction. The involvement of the TCA cycle was significantly lower in the synthesis of the released vesicular pool of glutamate. However, in the presence of TBOA, inhibiting glutamate uptake, the difference between the intracellular and the vesicular pool with regard to the extent of involvement of the TCA cycle in glutamate synthesis from glutamine was eliminated. Surprisingly, the intracellular pool of glutamate was decreased after repetitive release from the vesicular pool in the presence of TBOA indicating that neuronal reuptake of released glutamate is involved in the maintenance of the neurotransmitter pool and that 0.5 mM glutamine exogenously supplied is inadequate to sustain this pool.     

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.     

The NMR study of succinate formation from exogenous precursors in anaerobic rat heart mitochondria

Succinate formation during incubation of isolated rat heart mitochondria with exogenous precursors, malate, alpha-ketoglutarate, oxaloacetate and L-glutamate was studied in the absence of aeration. The formation of succinate, the end product of the tricarboxylic acid cycle, occurs via two pathways: through reduction of oxaloacetate or malate and via oxiation of alpha-ketoglutarate. The highest rate of succinate synthesis was observed when mitochondria were incubated with a mixture of 5 mM L-glutamate and 10 mM oxaloacetate, i.e., when both routes were used simultaneously. The [U-13C]succinate/succinate and aspartate/succinate ratios were equal to 2, when mitochondria were incubated with 5 mM [U-13C]glutamate and 10 mM oxaloacetate. Therefore, the amount of succinate formed from [13C]alpha-ketoglutarate via transamination of [13C]glutamate with oxaloacetate exceeds twice succinate production from oxialoacetate. These data suggest that GTP formation in the succinic thiokinase reaction should exceed twice the ATP yield coupled with NADH-dependent reduction of fumarate.     

Metabolic Compartmentation in Cortical Synaptosomes: Influence of Glucose and Preferential Incorporation of Endogenous Glutamate into GABA

Metabolism of glutamine was determined under a variety of conditions to study compartmentation in cortical synaptosomes. The combined intracellular and extracellular amounts of [U-¹³C]GABA, [U-¹³C]glutamate and [U-¹³C]glutamine were the same in synaptosomes incubated with [U-¹³C]glutamine in the presence and absence of glucose. However, the concentration of these amino acids was decreased in the latter group, demonstrating the requirement for glucose to maintain the size of neurotransmitter pools. In hypoglycemic synaptosomes more [U-¹³C]glutamine was converted to [U-¹³C]aspartate, and less glutamate was re-synthesized from the tricarboxylic acid (TCA) cycle, suggesting use of the partial TCA cycle from -ketoglutarate to oxaloacetate for energy. Compartmentation was studied in synaptosomes incubated with glucose plus labeled and unlabeled glutamine and glutamate. Incubation with [U-¹³C]glutamine plus unlabeled glutamate gave rise to [U-¹³C]GABA but not labeled aspartate; however, incubation with [U-¹³C]glutamate plus unlabeled glutamine gave rise to [U-¹³C]aspartate, but not labeled GABA. Thus the endogenous glutamate formed via glutaminase in synaptic terminals is preferentially used for GABA synthesis, and is metabolized differently than glutamate taken up from the extracellular milieu.     

Breath [13CO2] recovery from an oral glucose load during exercise: comparison between [U-13C] and [1,2-13C]glucose.

The purpose of the present experiment was to compare 13CO2 recovery at the mouth, and the corresponding exogenous glucose oxidation computed, during a 100-min exercise at 63 +/- 3% maximal O2 uptake with ingestion of glucose (1.75 g/kg) in six active male subjects, by use of [U-13C] and [1,2-13C]glucose. We hypothesized that 13C recovery and exogenous glucose oxidation could be lower with [1,2-13C] than [U-13C]glucose because both tracers provide [13C]acetate, with possible loss of 13C in the tricarboxylic acid (TCA) cycle, but decarboxylation of pyruvate from [U-13C]glucose also provides 13CO2, which is entirely recovered at the mouth during exercise. The recovery of 13C (25.8 +/- 2.3 and 27.4 +/- 1.2% over the exercise period) and the amounts of exogenous glucose oxidized computed were not significantly different with [1,2-13C] and [U-13C]glucose (28.9 +/- 2.6 and 30.7 +/- 1.3 g, between minutes 40 and 100), suggesting that no significant loss of 13C occurred in the TCA cycle. This stems from the fact that, during exercise, the rate of exogenous glucose oxidation is probably much larger than the flux of the metabolic pathways fueled from TCA cycle intermediates. It is thus unlikely that a significant portion of the 13C entering the TCA cycle could be diverted to these pathways. From a methodological standpoint, this result indicates that when a large amount of [13C]glucose is ingested and oxidized during exercise, 13CO2 production at the mouth accurately reflects the rate of glucose entry in the TCA cycle and that no correction factor is needed to compute the oxidative flux of exogenous glucose.     

A 1H NMR study of succinate synthesis from exogenous precursors in oxygen-deprived rat heart mitochondria

Succinate synthesis from exogenous malate, alpha-ketoglutarate, oxaloacetate and L-glutamate in isolated oxygen-deprived rat heart mitochondria was studied using 1H NMR. The highest rate of succinate synthesis was observed during incubation of mitochondria with a mixture of L-glutamate and oxaloacetate. When mitochondria were incubated with [U-13C] glutamate and oxaloacetate the [U-13C] succinate/succinate and aspartate/succinate ratios were equal to 2. This suggests that the succinate produced from [U-13C] alpha-keto-glutarate formed via transamination of [U-13C] glutamate with oxaloacetate by aspartate aminotransferase exceeds twofold that synthesized via oxaloacetate reduction. It may thus be expected that GTP yield in a reaction catalyzed by the succinic thiokinase will be 2 times higher that of ATP production coupled with NADH-dependent fumarate reduction.     

Effect of methylmercury on glutamate metabolism in cerebellar astrocytes in culture

The effect of methylmercury (MeHg) on [U-13C]glutamate metabolism was studied in cerebellar astrocytes using 13C nuclear magnetic resonance spectroscopy. The cells were preincubated in medium containing 25 or 50 microM MeHg and 10% fetal calf serum for 4h and then in medium with [U-13C]glutamate (0.5mM) for 2h. Labeled glutamate, glutamine and aspartate were observed both in the cell extracts and media, labeled glutathione in the cell extracts and labeled lactate and alanine in the media. The amount of glutamate removed from the media was decreased in the 50 microM MeHg group, furthermore, the levels of both labeled and unlabeled glutamine were decreased. This might indicate a decreased synthesis and/or increased degradation. An increase was observed for glutathione in the 25 microM group, which might be due to an upregulated synthesis of glutathione in response to the toxic effects of MeHg. The percentage of [U-13C]glutamate used for the synthesis of metabolites via the tricarboxylic acid cycle was increased in the presence of 50 microM MeHg. However, the percentage used for energy production was decreased in both groups, indicating selective mitochondrial vulnerability due to the inhibitory effect of MeHg.     

Compartmentation of TCA cycle metabolism in cultured neocortical neurons revealed by 13C MR spectroscopy

Cultured neocortical neurons were incubated in medium containing [U-13C]glucose (0.5 mM) and in some cases unlabeled glutamine (0.5 mM). Subsequently the cells were "superfused" for investigation of the effect of depolarization by 55 mM K+. Cell extracts were analyzed by 13C magnetic resonance spectroscopy and gas chromatography/mass spectrometry to determine incorporation of 13C in glutamate, GABA, aspartate and fumarate. The importance of the tricarboxylic acid (TCA) cycle for conversion of the carbon skeleton of glutamine to GABA was evident from the effect of glutamine on the labeling pattern of GABA and glutamate. Moreover, analysis of the labeling patterns of glutamate in particular indicated a depolarization induced increased oxidative metabolism. This effect was only observed in glutamate and not in neurotransmitter GABA. Based on this a hypothesis of mitochondrial compartmentation may be proposed in which mitochondria associated with neurotransmitter synthesis are distinct from those aimed at energy production and influenced by depolarization. The hypothesis of mitochondrial compartmentation was further supported by the finding that the total percent labeling of fumarate and aspartate differed significantly from each other. This can only be explained by the existence of multiple TCA cycles with different turnover rates.     

Pyruvate decarboxylation in astrocytes and in neurons in primary cultures in the presence and the absence of ammonia

Oxidative decarboxylation of [1-¹⁴C]pyruvate was studied in primary cultures of neurons and of astrocytes. The rate of this process, which is a measure of carbon flow into the tricarboxylic acid (TCA) cycle and which is inhibited by its end product, acetyl CoA, was determined under conditions which would either elevate or reduce the components of the malate-aspartate shuttle (MAS). Addition of aspartate (1 mM) was found to stimulate pyruvate decarboxylation in astrocytes whereas addition of glutamate (or glutamine) had no effect. Since aspartate is a precursor for extramitochondrial malate, and thus intramitochondrial oxaloacetate, whereas glutamate and glutamine are not, this suggests that an increase in oxaloacetate level stimulates TCA cycle activity. Conversely, a reduction of the glutamate content by 3 mM ammonia, which might reduce exchange between glutamate and aspartate across the mitochondrial membrane, suppressed pyruvate decarboxylation. This effect was abolished by addition of glutamate or glutamine or exposure to methionine sulfoximine (MSO). These findings suggest that impairment of MAS activity by removal of MAS constituents decreases TCA cycle activity whereas replenishment of these compounds restores the activity of the TCA cycle. No corresponding effects were observed in neurons.     

13C nuclear magnetic resonance and gas chromatography-mass spectrometry studies of carbon metabolism in the actinomycin D producer Streptomyces parvulus by use of 13C-labeled precursors.

Fructose and glutamate metabolism was monitored in cell suspensions of streptomyces parvulus by 13C nuclear magnetic resonance. The experiments were performed for cells grown with various 13C sources in a growth medium containing D-[U-13C]fructose, L-[13C]glutamate, or L-[U-13C]aspartate and with nonlabeled precursors to compare intracellular pools in S. parvulus cells at different periods of the cell life cycle. The transport of fructose into the cells was biphasic in nature; during rapid transport, mannitol, fructose, and glucose 6-phosphate were accumulated intracellularly, whereas during the passive diffusion of fructose, the intracellular carbohydrate pool comprised mainly trehalose (1,1'-alpha-alpha-D-glucose). The regulation of fructokinase activity by the intracellular intermediates may play an important role in fructose catabolism in S. parvulus. Transaldolase activity in S. parvulus was determined from the 13C nuclear magnetic resonance labeling pattern of trehalose carbons obtained from cells grown in medium containing either L-[U-13C]aspartate or L-[U-13C]glutamate. Only carbons 4, 5, and 6 of the disaccharide were labeled. Isotopomer analysis of the trehalose carbons led us to conclude that the flux through the reverse glycolytic pathway, condensation of glyceraldehyde 3-phosphate with dihydroxyacetone phosphate, makes at best a minor contribution to the 13C-labeled glucose units observed in trehalose. The pentose pathway and transaldolase activity can explain the labeling pattern of 4,5,6-13C3 of trehalose. Moreover, the transfer of the 13C label of L-[U-13C]aspartate into the different isotopomers of trehalose C4, C5, and C6 by the transaldolase activity allowed us to calculate the relative fluxes from oxaloacetate via gluconeogenesis and through the tricarboxylic acid cycle. The ratio of the two fluxes is approximately 1. However, the main carbon source for trehalose synthesis in S. parvulus is fructose and not glutamate or aspartate. The 13C enrichment and isotopomer population, measured by nuclear magnetic resonance and gas chromatography-mass spectrometry, of the actinomycin D peptide ring enabled us to specify the origins of the five amino acids of actinomycin D. Threonine and proline exhibited isotopomer populations similar to that of the extracellular L-[13C]glutamate, indicating that protein catabolism is the origin of their 13C label, whereas the isotopomer populations of sarcosine and N-methylvaline were similar to those of the new intracellular pool of S. parvulus that originated from D-[U-13C]fructose during the production of actinomycin D.     

Metabolism of [U-<Superscript>13</Superscript>C]Glutamine and [U-<Superscript>13</Superscript>C]Glutamate in Isolated Rat Brain Mitochondria Suggests Functional Phosphate-Activated Glutaminase Activity in Matrix

One of the forms of phosphate activated glutaminase (PAG) is associated with the inner mitochondrial membrane. It has been debated whether glutamate formed from glutamine in the reaction catalyzed by PAG has direct access to mitochondrial or cytosolic metabolism. In this study, metabolism of [U-¹³C]glutamine (3 mM) or [U-¹³C]glutamate (10 mM) was investigated in isolated rat brain mitochondria. The presence of a functional tricarboxylic (TCA) cycle in the mitochondria was tested using [U-¹³C]succinate as substrate and extensive labeling in aspartate was seen. Accumulation of glutamine into the mitochondrial matrix was inhibited by histidine (15 mM). Extracts of mitochondria were analyzed for labeling in glutamine, glutamate and aspartate using liquid chromatography-mass spectrometry. Formation of [U-¹³C]glutamate from exogenous [U-¹³C]glutamine was decreased about 50% (P < 0.001) in the presence of histidine. In addition, the ¹³C-labeled skeleton of [U-¹³C]glutamine was metabolized more vividly in the tricarboxylic acid (TCA) cycle than that from [U-¹³C]glutamate, even though glutamate was labeled to a higher extent in the latter condition. Collectively the results show that transport of glutamine into the mitochondrial matrix may be a prerequisite for deamidation by PAG. Special issue article in honor of Dr. Frode Fonnum. Lasse K. Bak and Elżbieta Ziemińska contributed equally to the experimental work described in this paper.     

Metabolism of [1,6-13C]Glucose and [U-13C]Glutamine and Depolarization Induced GABA Release in Superfused Mouse Cerebral Cortical Mini-slices

Mouse cerebral cortical mini-slices were used in a superfusion system to monitor depolarization-induced (55 mM K⁺) release of preloaded [2,3-³H]GABA and to investigate the biosynthesis of glutamate, GABA and aspartate during physiological and depolarizing (55 mM K⁺) conditions from either [1,6-¹³C]glucose or [U-¹³C]glutamine. Depolarization-induced GABA release could be reduced (50%) by the GABA transport inhibitor tiagabine (25 μM) or by replacing Ca²⁺ with Co²⁺. In the presence of both tiagabine and Co²⁺ (1 mM), release was abolished completely. The release observed in the presence of 25 μM tiagabine thus represents vesicular release. Superfusion in the presence of [1,6-¹³C]glucose led to considerable labeling in the three amino acids, the labeling in glutamate and aspartate being increased after depolarization. This condition had no effect on GABA labeling. For all three amino acids, the distribution of label in the different carbon atoms revealed on increased tricarboxylic acid (TCA) activity during depolarization. When [U-¹³C]glutamine was used as substrate, labeling in glutamate was higher than that in GABA and aspartate and the fraction of glutamate and aspartate being synthesized by participation of the TCA cycle was increased by depolarization, an effect not seen for GABA. However, GABA synthesis reflected TCA cycle involvement to a much higher extent than for glutamate and aspartate. The results show that this preparation of brain tissue with intact cellular networks is well suited to study metabolism and release of neurotransmitter amino acids under conditions mimicking neural activity. Special issue article in honor of Dr. Ricardo Tapia.     

Isotopomer profiling of Leishmania mexicana promastigotes reveals important roles for succinate fermentation and aspartate uptake in tricarboxylic acid cycle (TCA) anaplerosis, glutamate synthesis, and growth

Leishmania parasites proliferate within nutritionally complex niches in their sandfly vector and mammalian hosts. However, the extent to which these parasites utilize different carbon sources remains poorly defined. In this study, we have followed the incorporation of various (13)C-labeled carbon sources into the intracellular and secreted metabolites of Leishmania mexicana promastigotes using gas chromatography-mass spectrometry and (13)C NMR. [U-(13)C]Glucose was rapidly incorporated into intermediates in glycolysis, the pentose phosphate pathway, and the cytoplasmic carbohydrate reserve material, mannogen. Enzymes involved in the upper glycolytic pathway are sequestered within glycosomes, and the ATP and NAD(+) consumed by these reactions were primarily regenerated by the fermentation of phosphoenolpyruvate to succinate (glycosomal succinate fermentation). The initiating enzyme in this pathway, phosphoenolpyruvate carboxykinase, was exclusively localized to the glycosome. Although some of the glycosomal succinate was secreted, most of the C4 dicarboxylic acids generated during succinate fermentation were further catabolized in the TCA cycle. A high rate of TCA cycle anaplerosis was further suggested by measurement of [U-(13)C]aspartate and [U-(13)C]alanine uptake and catabolism. TCA cycle anaplerosis is apparently needed to sustain glutamate production under standard culture conditions. Specifically, inhibition of mitochondrial aconitase with sodium fluoroacetate resulted in the rapid depletion of intracellular glutamate pools and growth arrest. Addition of high concentrations of exogenous glutamate alleviated this growth arrest. These findings suggest that glycosomal and mitochondrial metabolism in Leishmania promastigotes is tightly coupled and that, in contrast to the situation in some other trypanosomatid parasites, the TCA cycle has crucial anabolic functions.     

The role of glia in neuronal recovery following anoxia: In vitro evidence of neuronal adaptation

We investigated the effects of 3h of anoxia on metabolism of neurons and astrocytes, using a robust cell-based model system that mimics closely the living tissue milieu, i.e., in 3D neural aggregates cultured in bioreactors. Cells were incubated simultaneously with [1-(13)C]glucose and [1,2-(13)C]acetate; and, the gliotoxin fluorocitrate (FC) was used for glial tricarboxylic acid (TCA) cycle inhibition to assess the role of astrocytes for neuronal metabolism after oxygen deprivation. Results show that culture viability was not compromised by exposure to anoxia with and without FC. Interaction between astrocytes and glutamatergic neurons was altered due to anoxia: labeling in glutamine from [1-(13)C]glucose was decreased, whereas that in glutamate from [1,2-(13)C]acetate was increased. In contrast, GABA labeling was not affected by anoxia. It was shown that anoxia did not affect astrocytic capacity to synthesize glutamine in the reoxygenation period. The selective action of FC on astrocytes was confirmed. However, the presence of small amounts of glutamate and GABA labeled from acetate indicated residual activity of the glial TCA cycle. Although major metabolic changes were found due to FC-treatment, the intracellular pool of GABA was kept unchanged. Overall, our data clearly confirm that the glutamate-glutamine cycle depends on astrocytic TCA cycle activity and that mitochondrial impairment of astrocytes will ultimately stop metabolic trafficking between astrocytes and glutamatergic neurons. Additionally, our data suggest a metabolic independence of GABAergic neurons from astrocytes even after situations of complete oxygen depletion.     

C-NMR spectroscopic evaluation of the citric acid cycle flux in conditions of high aspartate transaminase activity in glucose-perfused rat hearts

A new mathematical model, based on the observation of ¹³C-NMR spectra of two principal metabolites (glutamate and aspartate), was constructed to determine the citric acid cycle flux in the case of high aspartate transaminase activity leading to the formation of large amounts of labeled aspartate and glutamate. In this model, the labeling of glutamate and aspartate carbons by chemical and isotopic exchange with the citric acid cycle are considered to be interdependent. With [U-¹³C]Glc or [1,2-¹³C]acetate as a substrate, all glutamate and aspartate carbons can be labeled. The isotopic transformations of 32 glutamate isotopomers into 16 aspartate isotopomers or vice versa were studied using matrix operations; the results were compiled in two matrices. We showed how the flux constants of the citric acid cycle and the ¹³C-enrichment of acetyl-CoA can be deduced from ¹³C-NMR spectra of glutamate and/or aspartate. The citric acid cycle flux in beating Wistar rat hearts, aerobically perfused with [U-¹³C]glucose in the absence of insulin, was investigated by ¹³C-NMR spectroscopy. Surprisingly, aspartate instead of glutamate was found to be the most abundantly-labeled metabolite, indicating that aspartate transaminase (which catalyses the reversible reaction: (glutamate + oxaloacetate ↔ 2-oxoglutarate + aspartate) is highly active in the absence of insulin. The amount of aspartate was about two times larger than glutamate. The quantities of glutamate (G_o) or aspartate (A_O) were approximately the same for all hearts and remained constant during perfusion: G₀ = (0.74 ±0.03) μmol/g; A₀ = (1.49±0.05) μmol/g. The flux constants, i.e., the fraction of glutamate and aspartate in exchange with the citric acid cycle, were about 1.45 min⁻¹ and 0.72 min⁻¹, respectively; the flux of this cycle is about (1.07±0.02) μmol min^-1 g^-1. Excellent agreement between the computed and experimental data was obtained, showing that: i) in the absence of insulin, only 41% of acetyl-CoA is formed from glucose while the rest is derived from endogenous substrates; and ii) the exchange between aspartate and oxaloacetate or between glutamate and 2-oxoglutarate is fast in comparison with the biological transformation of intermediate compounds by the citric acid cycle.     

Real-time detection of 13C NMR labeling kinetics in perfused EMT6 mouse mammary tumor cells and betaHC9 mouse insulinomas

A method was developed for obtaining high signal-to-noise 13C NMR spectra of intracellular compounds in metabolically active cultured cells. The method allows TCA cycle labeling kinetics to be determined in real time without significant oxygen transport limitations. Cells were immobilized on the surface of nonporous microcarriers that were either uncoated or coated with polypeptides and used in a 12-cm3 packed bed. The methods were tested with two EMT6 mouse mammary tumor cell lines, one strongly adherent and the other moderately adherent, and a weakly adherent mouse insulinoma line (betaHC9). For both EMT6 lines, NTP and oxygen consumption measurements indicated that the number of cells in the spectrometer ranged from 6 x 10(8) to 1 x 10(9). During infusion of [1-13C]glucose, labeling in C-4 glutamate (indicative of flux into the first half of the TCA cycle) could be detected with 15-min resolution. However, labeling for C-3 and C-2 glutamate (indicative of complete TCA cycle activity) was fivefold lower and difficult to quantify. To increase TCA cycle labeling, cells were infused with medium containing [1,6-13C2]glucose. A 2.5-fold increase was observed in C-4 glutamate labeling and C-3 and C-2 glutamate labeling could be monitored with 30-min resolution. Citrate synthase activity was indirectly detected in real time, as [3,4-13C2]glutamate was formed from [2-13C]oxaloacetate and [2-13C]acetate (of acetyl-CoA). Cell mass levels observed with betaHC9 cells were somewhat lower. However, the 13C S/N was sufficient to allow real-time monitoring of the response of intracellular metabolite labeling to a step change in glucose and a combined glutamine/serum pulse.     

α-Ketoisocaproate Alters the Production of Both Lactate and Aspartate from [U-13C]Glutamate in Astrocytes: A 13C NMR Study

Abstract: The present study determined the metabolic fate of [U-¹³C]glutamate in primary cultures of cerebral cortical astrocytes from rat brain and also in cultures incubated in the presence of 1 or 5 mMα-ketoisocaproate (α-KIC). When astrocytes were incubated with 0.2 mM [U-¹³C]glutamate, 64.1% of the ¹³C metabolized was converted to glutamine, and the remainder was metabolized via the tricarboxylic acid (TCA) cycle. The formation of [1,2,3-¹³C₃]glutamate demonstrated metabolism of the labeled glutamate via the TCA cycle. In control astrocytes, 8.0% of the [¹³C]glutamate metabolized was incorporated into intracellular aspartate, and 17.2% was incorporated into lactate that was released into the medium. In contrast, there was no detectable incorporation of [¹³C]glutamate into aspartate in astrocytes incubated in the presence of α-KIC. In addition, the intracellular aspartate concentration was decreased 50% in these cells. However, there was increased incorporation of [¹³C]glutamate into the 1,2,3-¹³C₃-isotopomer of lactate in cells incubated in the presence of α-KIC versus controls, with formation of lactate accounting for 34.8% of the glutamate metabolized in astrocytes incubated in the presence of α-KIC. Altogether more of the [¹³C]glutamate was metabolized via the TCA cycle, and less was converted to glutamine in astrocytes incubated in the presence of α-KIC than in control cells. Overall, the results demonstrate that the presence of α-KIC profoundly influences the metabolic disposition of glutamate by astrocytes and leads to altered concentrations of other metabolites, including aspartate, lactate, and leucine. The decrease in formation of aspartate from glutamate and in total concentration of aspartate may impair the activity of the malate-aspartate shuttle and the ability of astrocytes to transfer reducing equivalents into the mitochondria and thus compromise overall energy metabolism in astrocytes.     

IGF-I promotes a shift in metabolic flux in vascular smooth muscle cells

13C-nuclear magnetic resonance (NMR) spectroscopy was used to test our hypothesis that insulin-like growth factor I (IGF-I) stimulates glucose flux into both nonoxidative and oxidative pathways in vascular smooth muscle cells (VSMC). Rat VSMC were exposed to uniformly labeled [13C]glucose ([U-13C]glucose; 5.5 mM) and [3-13C]pyruvate (1 mM) in the presence and absence of IGF-I (100 ng/ml). IGF-I increased glucose flux through glycolysis and the tricarboxylic acid (TCA) cycle as well as total anaplerotic flux into the TCA cycle. Previous work in our laboratory identified an increase in GLUT1 content and glucose metabolism in neointimal VSMC that was sufficient to promote proliferation and inhibit apoptosis. To test whether IGF-I could potentiate the GLUT1-induced increased flux in the neointima, we utilized VSMC harboring constitutive overexpression of GLUT1. Indeed, IGF-I markedly potentiated the GLUT1-induced increase in glucose flux through glycolysis and the TCA cycle. Taken together, these findings demonstrate that upregulation of glucose transport through either IGF-I or increased GLUT1 content stimulates glucose flux through both nonoxidative and oxidative pathways in VSMC.     

Pentylenetetrazole decreases metabolic glutamate turnover in rat brain

Seizures were induced in rats by intraperitoneal injection of pentylenetetrazole (PTZ, 70 mg/kg), followed, 30 min later, by injection of [1-13C]glucose and [1,2-13C]acetate. Analyses of extracts from cortex, subcortex and cerebellum were performed using 13C magnetic resonance spectroscopy and HPLC. It could be shown that PTZ affected different brain regions differently. The total amounts of glutamate, glutamine, GABA, aspartate and taurine were decreased in the cerebellum and unchanged in the other brain regions. GABAergic neurones in the cortex and subcortex were not affected, whereas those in the cerebellum showed a pronounced decrease of GABA synthesis. However, glutamatergic neurones in all brain regions showed a decrease in glutamate labelling and in addition a decreased turnover in cerebellum. It could be shown that this decrease was in the metabolic pool of glutamate whereas release of glutamate was unaffected since glutamine labelling from glutamate was unchanged. Aspartate turnover was also decreased in all brain regions. Changes in astrocyte metabolism were not detected, indicating that PTZ had no effect on astrocyte metabolism in the early postictal stage.