Relative contribution of carbon dioxide fixation and acetyl-coA pathways in two nervous tissues

Measurements of the anaplerotic rate in the human cerebral cortex using 13C magnetic resonance spectroscopy and [1-13C] and [2-13C] glucose

Recent studies in rodent and human cerebral cortex have shown that glutamate-glutamine neurotransmitter cycling is rapid and the major pathway of neuronal glutamate repletion. The rate of the cycle remains controversial in humans, because glutamine may come either from cycling or from anaplerosis via glial pyruvate carboxylase. Most studies have determined cycling from isotopic labeling of glutamine and glutamate using a [1-(13)C]glucose tracer, which provides label through neuronal and glial pyruvate dehydrogenase or via glial pyruvate carboxylase. To measure the anaplerotic contribution, we measured (13)C incorporation into glutamate and glutamine in the occipital-parietal region of awake humans while infusing [2-(13)C]glucose, which labels the C2 and C3 positions of glutamine and glutamate exclusively via pyruvate carboxylase. Relative to [1-(13)C]glucose, [2-(13)C]glucose provided little label to C2 and C3 glutamine and glutamate. Metabolic modeling of the labeling data indicated that pyruvate carboxylase accounts for 6 +/- 4% of the rate of glutamine synthesis, or 0.02 micromol/g/min. Comparison with estimates of human brain glutamine efflux suggests that the majority of the pyruvate carboxylase flux is used for replacing glutamate lost due to glial oxidation and therefore can be considered to support neurotransmitter trafficking. These results are consistent with observations made with arterial-venous differences and radiotracer methods.

Cerebral pyruvate carboxylase flux is unaltered during bicuculline-seizures

Glutamine synthesis in the astroglia reflects the sum of neurotransmitter cycling (glutamate and gamma-aminobutyric acid [GABA]) and de novo synthesis (anaplerosis), the latter catalyzed by pyruvate carboxylase. Previous studies have shown that the glutamate plus GABA cycling flux is correlated strongly with neuronal activity; however, the relationship between pyruvate carboxylase flux and neuronal activity is not known. In this study, pyruvate carboxylase flux was assessed during intravenous infusion of [2-(13)C]glucose using localized (1)H-[(13)C] NMR spectroscopy at 7 Tesla in vivo in halothane-anesthetized and ventilated adult Wistar rats during 85 min of bicuculline-induced seizures (1 mg/kg, intravenously) and in nontreated controls. During seizures, concentrations of lactate, alanine, glutamine, GABA, and succinate increased whereas glutamate and aspartate decreased such that the decrease in glutamate plus aspartate equaled the increase in glutamine plus GABA. Pyruvate carboxylase flux was assessed by the sum of [2-(13)C] and [3-(13)C] of glutamine and glutamate (Glx(2+3)) labeling during [2-(13)C]glucose infusion. During seizures the initial rate of Glx(2+3) synthesis (0.069 +/- 0.013 micromol/g/min) was not significantly different (P = 0.68) from that of the controls (0.059 +/- 0.010 micromol/g/min), indicating that anaplerotic flow through pyruvate carboxylase was unaltered. Intense neuronal activation of seizures did not seem to increase anaplerosis through pyruvate carboxylase, despite the substantial increase in neuronal activity and glutamate/glutamine cycling shown in a previous study (Patel et al., 2004b).

Energy contribution of octanoate to intact rat brain metabolism measured by 13C nuclear magnetic resonance spectroscopy

Glucose is the dominant oxidative fuel for brain, but studies have indicated that fatty acids are used by brain as well. We postulated that fatty acid oxidation in brain could contribute significantly to overall energy usage and account for non-glucose-derived energy production. [2,4,6,8-13C4]octanoate oxidation in intact rats was determined by nuclear magnetic resonance spectroscopy. We found that oxidation of 13C-octanoate in brain is avid and contributes approximately 20% to total brain oxidative energy production. Labeling patterns of glutamate and glutamine were distinct, and analysis of these metabolites indicated compartmentalized oxidation of octanoate in brain. Examination of liver and blood spectra revealed that label from 13C-octanoate was incorporated into glucose and ketones, which enabled calculation of its overall energy contribution to brain metabolism: glucose (predominantly unlabeled) and 13C-labeled octanoate can account for the entire oxidative metabolism of brain. Additionally, flux through anaplerotic pathways relative to tricarboxylic acid cycle flux (Y) was calculated to be 0.08 +/- 0.039 in brain, indicating that anaplerotic flux is significant and should be considered when assessing brain metabolism. Y was associated with the glutamine synthesis compartment, consistent with the view that anaplerotic flux occurs primarily in astrocytes.

In vivo (13)C NMR measurement of neurotransmitter glutamate cycling, anaplerosis and TCA cycle flux in rat brain during

The aims of this study were twofold: (i) to determine quantitatively the contribution of glutamate/glutamine cycling to total astrocyte/neuron substrate trafficking for the replenishment of neurotransmitter glutamate; and (ii) to determine the relative contributions of anaplerotic flux and glutamate/glutamine cycling to total glutamine synthesis. In this work in vivo and in vitro (13)C NMR spectroscopy were used, with a [2-(13)C]glucose or [5-(13)C]glucose infusion, to determine the rates of glutamate/glutamine cycling, de novo glutamine synthesis via anaplerosis, and the neuronal and astrocytic tricarboxylic acid cycles in the rat cerebral cortex. The rate of glutamate/glutamine cycling measured in this study is compared with that determined from re-analysis of (13)C NMR data acquired during a [1-(13)C]glucose infusion. The excellent agreement between these rates supports the hypothesis that glutamate/glutamine cycling is a major metabolic flux ( approximately 0.20 micromol/min/g) in the cerebral cortex of anesthetized rats and the predominant pathway of astrocyte/neuron trafficking of neurotransmitter glutamate precursors. Under normoammonemic conditions anaplerosis was found to comprise 19-26% of the total glutamine synthesis, whilst this fraction increased significantly during hyperammonemia ( approximately 32%). These findings indicate that anaplerotic glutamine synthesis is coupled to nitrogen removal from the brain (ammonia detoxification) under hyperammonemic conditions.

The entry of [1-13C]glucose into biochemical pathways reveals a complex compartmentation and metabolite trafficking between glia and neurons: a study by 13C-NMR spectroscopy

Glial-neuronal interactions were investigated in rats injected intraperitoneally with [1-13C]glucose and killed after 15, 30, 45, or 60 min. Brain extracts were analyzed by 13C-NMR spectroscopy and the fractional 13C-enrichment at individual carbon positions was measured for amino acids, lactate, and N-acetyl-aspartate. [1-13C]Glucose was shown to be metabolized by both neurons and glia, with the anaplerotic pathway through pyruvate carboxylase (PC) accounting for 10% of total cerebral glucose metabolism. The PC-mediated pathway accounted for 39% of the glutamine synthesis, and for 8, 6, 14% of glutamate, GABA, and aspartate synthesis, respectively. These results reflect a compartmentation of the cerebral amino acids synthesis within glial and neuronal cells. The appearance of the 13C-label in C5 of glutamate and glutamine, C1 of GABA and C2 of lactate, is suggestive of pyruvate, formation from TCA cycle intermediates and provides evidence of metabolite trafficking between astrocytes and neurons.

Measurement of amino acid metabolism derived from [1-13C]glucose in the rat brain using 13C magnetic resonance spectroscopy

To clarify the unique characteristics of amino acid metabolism derived from glucose in the central nervous system (CNS), we injected [1-13C]glucose intraperitoneally to the rat, and extracted the free amino acids from several kinds of tissues and measured the amount of incorporation of 13C derived from [1-13C]glucose into each amino acid using 13C-magnetic resonance spectroscopy (NMR). In the adult rat brain, the intensities of resonances from 13C-amino acids were observed in the following order: glutamate, glutamine, aspartate, gamma-aminobutyrate (GABA) and alanine. There seemed no regional difference on this labeling pattern in the brain. However, only in the striatum and thalamus, the intensities of resonances from [2-13C]GABA were larger than that from [2,3-13C]aspartate. In the other tissues, such as heart, kidney, liver, spleen, muscle, lung and small intestine, the resonances from GABA were not detected and every intensity of resonances from 13C-amino acids, except 13C-alanine, was much smaller than those in the brain and spinal cord. In the serum, 13C-amino acid was not detected at all. When the rats were decapitated, in the brain, the resonances from [1-13C]glucose greatly reduced and the intensities of resonances from [3-13C]lactate, [3-13C]alanine, [2, 3, 4-13C]GABA and [2-13C]glutamine became larger as compared with those in the case that the rats were sacrificed with microwave. In other tissues, the resonances from [1-13C]glucose were clearly detected even after the decapitation. In the glioma induced by nitrosoethylurea in the spinal cord, the large resonances from glutamine and alanine were observed; however, the intensities of resonances from glutamate were considerably reduced and the resonances from GABA and aspartate were not detected. These results show that the pattern of 13C label incorporation into amino acids is unique in the central nervous tissues and also suggest that the metabolic compartmentalization could exist in the CNS through the metabolic trafficking between neurons and astroglia.

Cerebral metabolic compartmentation as revealed by nuclear magnetic resonance analysis of D-[1-13C]glucose metabolism

Nuclear magnetic resonance (NMR) was used to study the metabolic pathways involved in the conversion of glucose to glutamate, gamma-aminobutyrate (GABA), glutamine, and aspartate. D-[1-13C]Glucose was administered to rats intraperitoneally, and 6, 15, 30, or 45 min later the rats were killed and extracts from the forebrain were prepared for 13C-NMR analysis and amino acid analysis. The absolute amount of 13C present within each carbonatom pool was determined for C-2, C-3, and C-4 of glutamate, glutamine, and GABA, for C-2 and C-3 of aspartate, and for C-3 of lactate. The natural abundance 13C present in extracts from control rats was also determined for each of these compounds and for N-acetylaspartate and taurine. The pattern of labeling within glutamate and GABA indicates that these amino acids were synthesized primarily within compartments in which glucose was metabolized to pyruvate, followed by decarboxylation to acetyl-CoA for entry into the tricarboxylic acid cycle. In contrast, the labeling pattern for glutamine and aspartate indicates that appreciable amounts of these amino acids were synthesized within a compartment in which glucose was metabolized to pyruvate, followed by carboxylation to oxaloacetate. These results are consistent with the concept that pyruvate carboxylase and glutamine synthetase are glia-specific enzymes, and that this partially accounts for the unusual metabolic compartmentation in CNS tissues. The results of our study also support the concept that there are several pools of glutamate, with different metabolic turnover rates.(ABSTRACT TRUNCATED AT 250 WORDS)

13C nuclear magnetic resonance evidence for gamma-aminobutyric acid formation via pyruvate carboxylase in rat brain: a metabolic basis for compartmentation

The compartmentation of amino acid metabolism is an active and important area of brain research. 13C labeling and 13C nuclear magnetic resonance (NMR) are powerful tools for studying metabolic pathways, because information about the metabolic histories of metabolites can be determined from the appearance and position of the label in products. We have used 13C labeling and 13C NMR in order to investigate the metabolic history of gamma-aminobutyric acid (GABA) and glutamate in rat brain. [1-13C]Glucose was infused into anesthetized rats and the 13C labeling patterns in GABA and glutamate examined in brain tissue extracts obtained at various times after infusion of the label. Five minutes after infusion, most of the 13C label in glutamate appeared at the C4 position; at later times, label was also present at C2 and C3. This 13C labeling pattern occurs when [1-13C]glucose is metabolized to pyruvate by glycolysis and enters the pool of tricarboxylic acid (TCA) intermediates via pyruvate dehydrogenase. The label exchanges into glutamate from the TCA cycle pool through glutamate transaminases or dehydrogenase. After 30 min of infusion, approximately 10% of the total 13C in brain extracts appeared in GABA, primarily (greater than 80%) at the amino carbon (C4), indicating that the GABA detected is labeled through pyruvate carboxylase. The different labeling patterns observed for glutamate and GABA show that the large detectable glutamate pool does not serve as the precursor to GABA. Our NMR data support previous experiments suggesting compartmentation of metabolism in brain, and further demonstrate that GABA is formed from a pool of TCA cycle intermediates derived from an anaplerotic pathway involving pyruvate carboxylase.

Alpha-ketoglutarate and malate uptake and metabolism by synaptosomes: further evidence for an astrocyte-to-neuron metabolic shuttle

This study was undertaken to provide further evidence relevant to the hypothesis that astrocytes supply one or more citric acid cycle intermediates to synaptic terminals, thereby serving an anaplerotic function necessitated by the synthesis and release of amino acid neurotransmitters. In our experiments, two populations of synaptosomes obtained from the brain of rats were separated from myelin and mitochondria by using Percoll to generate continuous density gradients. Both synaptosomal populations readily accumulated 14C-labelled alpha-ketoglutarate and L-malate by high-affinity transport systems. Hofstee plots of uptake velocity as a function of substrate concentration were highly nonlinear, indicating that uptake was mediated by two or more carriers, or was subject to negative cooperativity. At least one carrier was selective for alpha-ketoglutarate and another for malate, whereas a third carrier appeared to be present which transported both substrates. At low concentrations (approximately 1 microM), alpha-ketoglutarate transport was almost totally Na+-dependent, whereas malate uptake exhibited little Na+-dependency. The transport of alpha-ketoglutarate was associated with a net influx, and therefore was not due to a homoexchange process. alpha-Ketoglutarate and malate were metabolized rapidly to glutamate and aspartate, respectively, by both synaptosomal preparations; however, in all cases, label accumulated in gamma-aminobutyric acid rather slowly. The incorporation of label into glutamine from alpha-ketoglutarate was much greater in the high-density synaptosomes that in low-density synaptosomes, an indication that the former contained a higher proportion of astrogliasomes.(ABSTRACT TRUNCATED AT 250 WORDS)

Glutamine and alpha-ketoglutarate uptake and metabolism by nerve terminal enriched material from mouse cerebellum

In order to provide evidence relevant to the hypothesis that nonsynaptically derived alpha-ketoglutarate serves as a metabolic precursor of the neurotransmitter pools of glutamate and GABA the uptake and metabolism of alpha-ketoglutarate by nerve terminal enriched material was studied and compared to corresponding data for glutamine. Both alpha-ketoglutarate and glutamine were transported across the cell membrane by high affinity and low affinity carriers. Under conditions prevailing in vivo alpha-ketoglutarate probably is transported primarily by its high affinity carrier, whereas gluatmine should be transported primarily by one or more low affinity carriers. Based upon reciprocal uptake inhibition experiments glutamine appeared to be transported by the alanine preferring system, and to a lesser extent by the basic amino acid and large neutral amino acid carriers. A comparison of the rate of uptake by different cellular preparations enriched in either nerve terminals or cell bodies indicated that alpha-ketoglutarate is transported selectively by nerve terminals. Both substrates were rapidly converted to glutamate; however, glutamine was more readily metabolized to GABA. The results of our study are consistent with the concept that both glutamine and alpha-ketoglutarate derived from extra-neuronal sources are taken up by nerve terminals and utilized to replenish the neurotransmitter pools of glutamate and GABA.

Role of carbon dioxide fixation, blood aspartate and glutamate in the adaptation of amphibian brain tissues to a hyperosmotic internal environment

Mechanisms have been examined by which hyperosmotic blood plasma might elevate the levels of aspartate and glutamate in the brain of the toad Bufo boreas. CO2 fixation was assessed by two in vivo methods using [2-14 C]glucose injected intracisternally. Thirty minutes after injection, the 14C labeling of glutamate and aspartate was more than 100 times greater in brain than in liver. In brain tissues, 40 + % of 14C atoms appeared to be incorporated into aspartate via the pyruvate carboxylase pathway. Brain tissues of control toads and toads adapting or adapted to hyperosmotic plasma osmolality revealed no differences in the rate of CO2 fixation as related to glucose utilization or tissue pool sizes of glutamate and aspartate. Elevated levels of these amino acids in blood plasma preceded increases in brain tissues. Carbon atoms required during hyperosmotic adaptation for expansion of amino acid pools in brain tissues may, in part, originate from amino acids in blood but apparently not from CO2 fixation in brain.

Origin of the acetyl moiety of acetylcholine synthesized in rat striatal synaptosomes

The subcellular localization of the AcCoA compartment supplying the cytoplasmic choline acetyltransferase (ChAc, EC 2.3.1.6) was investigated using a purified preparation of rat striatal synaptosomes (B fraction). It was first demonstrated that the SRA of the [14C]ACh synthesized during a 10 min incubation period was equal to the SRA of the [2-14C] and the [3-14C]pyruvate added to the isolated nerve terminal suspension. The experimental results can be summarised as follows: (i) No modification in the amount of [14C]ACh synthesized from [2-14C]pyruvatetion in the amount of [14C]ACh synthesized from [2-13C]pyruvate could be detected after the addition of high concentrations of either carnitine, acetylcarnitine or acetyl phosphate to the synaptosomal suspension. (ii) Under experimental conditions in which the amount of [1,5-14C]citrate taken up by passive diffusion into the cholinergic nerve endings would allow detection of the possible formation of the labelled ester, no [14C]ACh could be recovered. (iii) The SRA's of the individual carbon atoms of the Krebs cycle intermediary compounds when the cycle is fed with [2-14C] and [3-14C]pyruvate were calculated as a function of the STA's of each of these two precursors (a and a' respectively), of the number of 14CO2 dpm produced in the Krebs cycle from each of these two labelled compounds (D2 and D3 respectively), and as the function of the rate y of exchanges of molecules between the tricarboxylic acid cycle and other metabolic compartments. The experimental value obtained from a 10 min incubation, after the nerve endings had reached a steady metabolic activity, indicate that if the acetyl moiety of ACh was derived from some Krebs cycle intermediary compounds, its SRA could never exceed 55 per cent that of the [2-14C]pyruvate from which it is produced, (iv) No correlation could be found between the rate of [14C]ACh formation and changes in the Krebs cycle activity induced by sodium cyanide, 2-4 dinitrophenol and Ca2+ free medium. (v) The lack of significant [14C]ACh synthesis from [1-14C]acetate in striatal synaptosomes is consistent with the failure of fluoroacetate to modify the amounts of 14CO2 as well as of [14C]ACh formed from [2-14C]pyruvate. These results were interpreted as a confirmation of the presence of a low AcCoA synthetase activity in the nerve terminals. To reconcile all these data, it is proposed that pyruvate is transformed into AcCoA outside the mitochondria by the action of some cytoplasmic pyruvate dehydrogenase-like enzyme.

Electron microscope histochemical evidence for a partial or total block of the tricarboxylic acid cycle in the mitochondria of presynaptic axon terminals

Respiration-linked, massive accumulation of Sr(2+) is used to reveal the coupled oxidation of pyruvate, alpha-oxoglutarate, succinate, and malate by in situ mitochondria. All of these substrates were actively oxidized in the dendritic and perikaryal mitochondria, but no alpha-oxoglutarate or succinate utilization could be demonstrated in the mitochondria of the presynaptic axon terminals. A block at an early step of alpha-oxoglutarate and succinate oxidation is proposed to account for the negative histochemical results, since the positive reaction with pyruvate and malate proves that these mitochondria possess an intact respiratory chain and energy-coupling mechanism essential for Sr(2+) accumulation. This indicates that the mitochondria in the axon terminals would be able to generate energy for synaptic function with at least some of the respiratory substrates. With regard to the block in the tricarboxylic acid cycle, the oxaloacetate necessary for citrate formation is suggested to be provided by fixation of CO(2) into some of the pyruvate.

A study on the tricarboxylic acid cycle and the synthesis of acetylcholine in the lobster nerve

1. The pattern of metabolism of (14)C-labelled substrates in the lobster nerve suggested a normal tricarboxylic acid cycle with a slow turnover. 2. Acetylcholine was synthesized from [2-(14)C]acetate, [2-(14)C]pyruvate and [1,5-(14)C]citrate, implying the presence of acetate thiokinase, choline acetylase and citrate-cleavage enzyme. 3. [2-(14)C]Acetate was the best precursor. 4. The formation of acetyl-CoA from citrate was limited, probably by the citrate-cleavage enzyme, although the magnitude of the reversed reactions of the tricarboxylic acid cycle was large when compared with that of the forward reactions. 5. The relative magnitude of the two pathways (acetyl-CoA and carbon dioxide fixation) in pyruvate utilization was nearly equal. 6. The probable presence of metabolic compartments in the lobster nerve is discussed.