Amino Acid Neurotransmitters in Nucleus Tractus Solitarius: An In Vivo Microdialysis Study

Amino acid neurotransmitters in the nucleus tractus solitarius (NTS) are thought to play a key role in the mediation of visceral reflexes and glutamate has been proposed as the neurotransmitter of visceral afferent nerves projecting to this region. The present studies sought to characterize the use of in vivo microdialysis to examine extracellular fluid levels of amino acids in the NTS of anesthetized rats. Using a microdialysis probe that was 450 μm in length and a sensitive HPLC assay for amino acids, amino acids could be measured in dialysate samples collected from the NTS. Perfusion of the microdialysis probe with 60 mM K^±, to elicit depolarization of nerve terminals in the vicinity of the probe, resulted in increased dialysate fluid levels of aspartate, glutamate, glycine, taurine, and GABA. In contrast, glutamine and tyrosine were decreased and other amino acids were not significantly affected. Prior removal of the ipsilateral nodose ganglion did not alter the K^±-evoked changes in dialysate levels of any of these amino acids. Electrical stimulation of the vagus nerves, using a variety of stimulus parameters, did not significantly alter dialysate levels of glutamate or any of the other amino acids that were measured. Blockade of glutamate uptake with dihydrokainate increased dialysate levels of glutamate, aspartate, and GABA, but in the presence of dihydrokainate vagal stimulation did not alter dialysate levels of these amino acids. The results show that in vivo microdialysis can be used to examine amino acid efflux in the rat NTS and provide further evidence for amino acidergic neural transmission in the NTS. However, these studies fail to support the hypothesis that vagal afferents release glutamate or aspartate.     

Extracellular Glutamate During Focal Cerebral Ischaemia in Rats: Time Course and Calcium Dependency

Abstract: The time course of changes in extracellular glutamic acid levels and their Ca²⁺ dependency were studied in the rat striatum during focal cerebral ischaemia, using microdialysis. Ischaemia-induced changes were compared with those produced by high K⁺-evoked local depolarization. To optimize time resolution, glutamate was analysed continuously as the dialysate emerged from the microdialysis probe by either enzyme fluorimetry or biosensor. The Ca²⁺ dependency of glutamate changes was examined by perfusing the probe with Ca²⁺-free medium. With normal artificial CSF, ischaemia produced a biphasic increase in extracellular glutamate, which started from the onset of ischaemia. During the first phase lasting ～10 min, dialysate glutamate level increased from 5.8 ± 0.9 µM· min^?1 to 35.8 ± 6.2 µM where it stabilized for ～3 min. During the second phase dialysate glutamate increased progressively to its maximum (82 ± 8 µM), reached after 55 min of ischaemia, where it remained for as long as it was recorded (3 h). The overall changes in extracellular glutamate were similar when Ca²⁺ was omitted from the perfusion medium, except that the first phase was no longer detectable and, early in ischaemia, extracellular glutamate increased at a significantly slower rate than in the control group (2.2 ± 1 µM· min^?1; p < 0.05). On the basis of these data, we propose that most of the glutamate released in the extracellular space in severe ischaemia is of metabolic origin, probably originating from both neurons and glia, and caused by altered glutamate uptake mechanisms. Comparison with high K⁺-induced glutamate release did not suggest that glutamate “exocytosis,” early after middle cerebral artery occlusion, was markedly limited by deficient ATP levels.     

Interrelationships of Leucine and Glutamate Metabolism in Cultured Astrocytes

Abstract: The aim was to study the extent to which leu-cine furnishes α-NH₂ groups for glutamate synthesis via branched-chain amino acid aminotransferase. The transfer of N from leucine to glutamate was determined by incubating astrocytes in a medium containing [¹⁵N]leucine and 15 unlabeled amino acids; isotopic abundance was measured with gas chromatography-mass spectrometry. The ratio of labeling in both [¹⁵N]glutamate/[¹⁵N]leucine and [2-¹⁵N]glutamine/[¹⁵N]leucine suggested that at least one-fifth of all glutamate N had been derived from leucine nitrogen. At the same time, enrichment in [¹⁵N]leucine declined, reflecting dilution of the ¹⁶N label by the unlabeled amino acids that were in the medium. Isotopic abundance in [¹⁶N]-isoleucine increased very quickly, suggesting the rapidity of transamination between these amino acids. The appearance of ¹⁵N in valine was more gradual. Measurement of branched-chain amino acid transaminase showed that the reaction from leucine to glutamate was approximately six times more active than from glutamate to leucine (8.72 vs. 1.46 nmol/min/mg of protein). However, when the medium was supplemented with α-ketoisocaproate (1 mM), the ketoacid of leucine, the reaction readily ran in the “reverse” direction and intraastrocytic [glutamate] was reduced by ～50% in only 5 min. Extracellular concentrations of α-ketoisocaproate as low as 0.05 mM significantly lowered intracellular [glutamate]. The relative efficiency of branched-chain amino acid transamination was studied by incubating astrocytes with 15 unlabeled amino acids (0.1 mM each) and [¹⁵N]glutamate. After 45 min, the most highly labeled amino acid was [¹⁵N]alanine, which was closely followed by [¹⁵N]leucine and [¹⁵N]isoleucine. Relatively little ¹⁵N was detected in any other amino acids, except for [¹⁵N]serine. The transamination of leucine was ～17 times greater than the rate of [1-¹⁴C]leucine oxidation. These data indicate that leucine is a major source of glutamate nitrogen. Conversely, reamination of a-ketoisocaproate, the ketoacid of leucine, affords a mechanism for the temporary “buffering” of intracellular glutamate.     

Neuronal Metabolism of Branched-Chain Amino Acids: Flux Through the Aminotransferase Pathway in Synaptosomes

Abstract: The metabolism of branched-chain amino acids (BCAAs) was studied in cortical synaptosomes. With [¹⁵N]leucine (1 mM) as precursor, the cumulative appearance of ¹⁵N in [¹⁵N]glutamate and [¹⁵N]aspartate was 0.2 nmol/min/mg of protein without supplemental α-ketoglutarate and 0.3 nmol/min/mg of protein in the presence of α-ketoglutarate (0.5 mM). The BCAA aminotransferase reaction also proceeded in the “reverse” direction [α-ketoisocaproate (KIC) + glutamate → leucine + α-ketoglutarate]. This was documented by incubating synaptosomes with [¹⁵N]glutamate and measuring the formation of [¹⁵N]leucine. Without KIC in the medium, the rate of [¹⁵N]leucine production was 0.13 nmol/min/mg of protein. In the presence of 25 µM KIC the rate was 0.79 nmol/min/mg of protein and even greater (1.0 nmol/min/mg of protein) in the presence of 500 µM KIC. The reamination of KIC was two- to threefold faster with [2-¹⁵N]glutamine as precursor compared with [¹⁵N]glutamate. The ketoacid of valine, α-ketoisovalerate (KIV), was reaminated to [¹⁵N]valine at a rate comparable to that observed with respect to KIC. The BCAA transaminase mediated not only the bidirectional transfer of amino groups between leucine or valine and glutamate, but also the direct transfer of nitrogen between leucine and valine. This was ascertained in studies in which the incubation medium was supplemented with either [¹⁵N]leucine and KIV or [¹⁵N]valine and KIC (amino acids at 1 mM and ketoacids at 25 or 500 µM). The rate was faster in the direction of leucine formation at both the lower (6.1-fold) and higher (1.7-fold) KIC concentration. It is suggested that in synaptosomes the BCAA transaminase (a) functions predominantly in the direction of leucine formation and (b) maintains a constant ratio of BCAAs and ketoacids to one other.     

GLUCOSE AND AMINO ACID METABOLISM IN ISOLATED NEURONAL AND GLIAL CELL FRACTIONS IN VITRO

Abstract—

• 1 The metabolism of three substrates, [U-¹⁴C]glucose, [U-¹⁴C]pyruvate and [U-¹⁴C]glutamate has been studied in vitro in neuronal and glial cell fractions obtained from rat cerebral cortex by a density gradient technique.
• 2 The mixed cell suspension, after washing, metabolized glucose and glutamate in a manner essentially similar to the tissue slice. Exceptions were a reduced ability to generate lactate from glucose and alanine from glutamate, and a lowered effect of added glucose in suppressing the production of aspartate from glutamate.
• 3 After 2 hr incubation with [U-¹⁴C]glucose, the concentration of the amino acids glutamate, glutamine, GABA, aspartate and alanine were raised in the neuronal, compared to the glial fraction to 234 per cent, 176 per cent, 202 per cent, 167 per cent and 230 per cent respectively although both were lower than in the tissue slice. Incorporation of radio-activity was absolutely lower in the neuronal fraction, however, and the specific activities of the amino acids were: glutamate 12 per cent, GABA 18 per cent, aspartate 34 per cent, and alanine 33 per cent of those in the glial fraction.
• 4 After the incubation with [U-¹⁴C]pyruvate, the pool size of the amino acids were higher than after incubation with glucose, except for GABA, which was reduced to one-third. The concentrations of the amino acids glutamate, glutamine, GABA, aspartate, and alanine in the neuronal fraction were respectively 46 per cent, 143 per cent, 105 per cent, 97 per cent, and 57 per cent of those in the glial. Thus, with the exception of alanine, the specific activity of the neuronal amino acids compared to the glial was little increased when pyruvate replaced glucose as substrate.
• 5 After 2 hr incubation with [U-¹⁴C]glutamate in the presence of non-radioactive glucose, the pool sizes of all the amino acids were increased in both neuronal and glial fractions, with the exception of neuronal alanine and glial glutamine. The concentrations of the amino acids glutamine, GABA, aspartate and alanine were raised in the neuronal fraction, compared to the glial, to 425 per cent, 187 per cent, 222 per cent, and 133 per cent respectively. The specific activities of all the amino acids were higher than with glucose alone with the exception of alanine, and neuronal GABA. Neuronal glutamine and aspartate had specific activities respectively 102 per cent and 84 per cent of glial.
• 6 An unidentified amino acid, with R_F comparable to that of alanine and specific activity close to that of glutamate, was also present after incubation. It was relatively concentrated in the neuronal fraction.
• 7 The distribution of the enzymes glutamate dehydrogenase, aspartate aminotransferase, glutamate decarboxylase and glutamine synthetase between the cell fractions was studied. With the exception of glutamine synthetase, none of the enzymes was lost from the cell fractions during their preparation. Only 14 per cent of the glutamine synthetase, compared with 75 per cent of total protein, was recovered in the fractions. Of the enzymes, glutamate dehydrogenase activity was 406 per cent, and glutamate synthetase activity 177 per cent in the neuronal fraction compared to the glial in the absence of detergent. In the presence of detergent, glutamate dehydrogenase control was 261 per cent, aspartate aminotransferase activity 237 per cent is the neuronal as compared to the glial fraction.
• 8 Incorporation of radioactivity into acid-insoluble material from either glutamate or pyruvate was twice as high into the neuronal as the glial fraction.
• 9 The extent to which these differences may be extrapolated back to the intact tissue is considered, and certain correction factors calculated. The significance of the observations for an understanding of the compartmentation of amino acid pools and metabolism in the brain, and the possible identification of such compartments, is discussed.

     

Mivazerol, a Novel α2-Agonist and Potential Anti-Ischemic Drug, Inhibits KCl-Stimulated Neurotransmitter Release in Rat Nervous Tissue Preparations

Abstract: In this study, we have investigated the effect of mivazerol, [3-(1H-imidazol-4-yl)methyl-1]-2-hydroxy-benzamide hydrochloride, a new α₂-agonist lacking hypotensive properties and a potential anti-ischemic drug, on the evoked release of norepinephrine, aspartate, and glutamate in tissue preparations from hippocampus, spinal cord T1–T5 section, rostrolateral ventricular medulla, and nucleus tractus solitarii of the brainstem of rat. A simple and efficient in vitro procedure to study pharmacologically the release of norepinephrine and glutamate is described. Tissues were chopped into (0.3 × 0.2 × 0.2 mm³) sections and the resulting minces were used for this study. Exposure to KCl (10–75 mM) for 5 min served as a stimulus for the release response. One, S (for aspartate and for glutamate release), or two such stimuli, S₁ and S₂ (for norepinephrine release) were conducted. The release of norepinephrine (+150% above baseline) was inhibited in a dose-dependent manner by mivazerol in hippocampus (IC₅₀ = 1.5 × 10^?8M), spinal cord (IC₅₀ = 5 × 10^?8M), rostrolateral ventricular medulla (IC₅₀ = 10^?7M), and nucleus tractus solitarii (IC₅₀ = 7.5 × 10^?8M), and by clonidine in hippocampus (IC₅₀ = 5 × 10^?8M), spinal cord (IC₅₀ = 4.5 × 10^?8M), rostrolateral ventricular medulla (IC₅₀ = 2.5 × 10^?7M), and nucleus tractus solitarii (IC₅₀ = 10^?7M). This effect was counteracted by the selective α₂-antagonists yohimbine and rauwolscine. A significant glutamate and aspartate release response was also induced by KCl (35 mmol/L) in hippocampus (+250 and +135%, respectively) and spinal cord (+120 and +55%, respectively), in vitro. However, neither mivazerol nor clonidine, at doses up to 10 µM, had any significant effect on KCl-induced glutamate release in spinal cord, whereas mivazerol blocked completely the release of both amino acids in hippocampus and only the release of aspartate in spinal cord. On the other hand, clonidine (1 µM) was only effective in reducing by 40% the release of aspartate in hippocampus. These data indicate that (1) inhibition of KCl-induced norepinephrine release by mivazerol is mediated by its action on α₂-adrenergic receptors; (2) at concentrations selective for α₂-adrenergic receptors, only mivazerol was effective in blocking the KCl-induced glutamate release in hippocampal tissue; and (3) at the same concentrations, both mivazerol and clonidine were unable to inhibit glutamate release in the spinal cord. These data suggest that prevention of hyperadrenergic activity by mivazerol in perioperative patients may be mediated through its effect on the release of norepinephrine and/or the release of glutamate and aspartate in regions of the CNS that are involved in the control of cardiovascular homeostasis.     

Glutamate Uptake and Metabolism in C-6 Glioma Cells: Alterations by Potassium Ion and Dibutyryl cAMP

Abstract: Uptake and metabolism of glutamate was studied in the C-6 glioma cell line grown in the absence or presence of dibutyryl cyclic AMP (dbcAMP). Glutamate and aspartate uptake were competitive in cells grown under both conditions. Increased [K⁺] in the medium caused a significant decrease in the uptake of both amino acids. A small part of this decrease (<25%) was due to an enhanced efflux of tissue amino acid. The effects of increased [K⁺] were observed whether or not the [Na⁺] in the medium was concomitantly decreased. In cells grown in the presence of 1 mM dbcAMP for 48 h, glutamate uptake and metabolism were altered. Tissue levels of glutamate, aspartate, glutamine, GABA, and alanine were generally less in treated than in naive cells. When incubated with 50 μM [U-¹⁴C]glutamate, there was significantly less incorporation of radioactivity into treated cells with time, resulting in greatly lowered specific radioactivities of glutamate, aspartate, and GABA. However, the rate of labeling of glutamine was greatly increased; this was consistent with the previously observed doubling in glutamine synthetase activity in dbcAMP-treated C-6 cells. Tissue glutamate decarboxylase activity was halved in treated cells, accounting for the large decrease in GABA labeling. The metabolic data suggested a decreased uptake of exogenous glutamate; in studies on initial rates of uptake, the V_max of high-affinity glutamate uptake was decreased by 40%. This decrease was of the same order of magnitude as that observed in the metabolic experiments. Thus, in this glial model, both rapid, acute changes and slower, long-term changes in neuroactive amino acid metabolism were observed. Each of these conditions mimics a stimulus of neuronal origin, and the resulting changes could modulate extrasynaptic activity of neuroactive amino acids.     

LABELLING OF BRAIN PROTEINS AT EARLY PERIODS AFTER SUBCUTANEOUS INJECTION OF A MIXTURE OF [U-14C]GLUCOSE AND [3H]GLUTAMATE

To obtain evidence of the site of conversion of [U-¹⁴C]glucose into glutamate and related amino acids of the brain, a mixture of [U-¹⁴C]glucose and [³H]glutamate was injected subcutaneously into rats. [³H]Glutamate gave rise to several ³H-labelled amino acids in rat liver and blood; only ³H-labelled glutamate, glutamine or γ-aminobutyrate were found in the brain. The specific radioactivity of [³H]glutamine in the brain was higher than that of [³H]glutamate indicating the entry of [³H]glutamate mainly in the ‘small glutamate compartment’. The ¹⁴C-labelling pattern of amino acids in the brain and liver after injection of [U-¹⁴C]glucose was similar to that previously reported (Gaitonde et al., 1965). The specific radioactivity of [¹⁴C]glutamine in the blood and liver after injection of both precursors was greater than that of glutamate between 10 and 60 min after the injection of the precursors. The extent of labelling of alanine and aspartate was greater than that of other amino acids in the blood after injection of [U-¹⁴C]glucose. There was no labelling of brain protein with [³H]glutamate during the 10 min period, but significant label was found at 30 and 60 min. The highest relative incorporation of [¹⁴C]glutamate and [¹⁴C]aspartate in rat brain protein was observed at 5 min after the injection of [U-¹⁴C]glucose. The results have been discussed in the context of transport of glutamine synthesized in the brain and the site of metabolism of [U-¹⁴C]glucose in the brain.     

Accumulation of Extracellular Glutamate by Inhibition of Its Uptake Is Not Sufficient for Inducing Neuronal Damage: An In Vivo Microdialysis Study

Abstract: It is well documented that neurons exposed to high concentrations of excitatory amino acids, such as glutamate and aspartate, degenerate and die. The clearance of these amino acids from the synaptic cleft depends mainly on their transport by high-affinity sodium-dependent carriers. Using microdialysis in vivo and HPLC analysis, we have studied the effect of the administration of inhibitors of the glutamate transporter (l -trans-pyrrolidine-2,4-dicarboxylate and dihydrokainate) on the extracellular concentration of endogenous amino acids in the rat striatum. In addition, we have analyzed whether the changes observed in the concentration of glutamate and aspartate were injurious to striatal cells. Neuronal damage was assessed by biochemical determination of choline acetyltransferase and glutamate decarboxylase activities, 7 days after the microdialysis procedure. In other experiments, pyrrolidine dicarboxylate and dihydrokainate, as well as two other inhibitors of the glutamate carrier, dl -threo-β-hydroxyaspartate and l -aspartate-β-hydroxamate, were microinjected into the striatum, and neuronal damage was assessed, both biochemically and histologically, 7 or 14 days after the injection. Dihydrokainate and pyrrolidine dicarboxylate produced a similar remarkable increase in the concentration of extracellular aspartate and glutamate. However, the former induced also notable elevations in the concentration of other amino acids. Clear neuronal damage was observed only after dihydrokainate administration, which was partially prevented by intraperitoneal injection of (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate or by intrastriatal coinjection of 2,3-dihydroxy-6-nitro-7-sulfamoylbenzo(f)quinoxaline. No cell damage was observed with the other three glutamate carrier inhibitors used. It is concluded that an increased extracellular glutamate level in vivo due to dysfunction of its transporter is not sufficient for inducing neuronal damage. The neurotoxic effects of dihydrokainate could be explained by direct activation of glutamate postsynaptic receptors, an effect not shared by the other inhibitors used.     

Adenosine and Glutamate Modulate Each Other's Release from Rat Hippocampal Synaptosomes

Abstract: In rat hippocampal synaptosomes, adenosine decreased the K⁺ (15 mM) or the kainate (1 mM) evoked release of glutamate and aspartate. An even more pronounced effect was observed in the presence of the stable adenosine analogue, R-phenylisopropyladenosine. All these effects were reversed by the selective adenosine A₁ receptor antagonist 8-cyclo-pentyltheophylline. In the same synaptosomal preparation, K⁺ (30 mM) strongly stimulated the release of the preloaded [³H]adenosine in a partially Ca²⁺-dependent and tetrodotoxin (TTX)-sensitive manner. Moreover, in the same experimental conditions, both l -glutamate and l -aspartate enhanced the release of [³H]adenosine derivatives ([³H]ADD). The gluta-mate-evoked release was dose dependent and appeared to be Ca²⁺ independent and tetrodotoxin insensitive. This effect was not due to metabolism because even the nonmetabolizable isomers d -glutamate and d -aspartate were able to stimulate [³H]ADD release. In contrast, the specific glutamate agonists N-methyl-d -aspartate, kainate, and quisqualate failed to stimulate [³H]ADD release, suggesting that glutamate and aspartate effects were not mediated by known excitatory amino acid receptors. Moreover, NMDA was also ineffective in the absence of Mg²⁺ and l -glutamate-evoked release was not inhibited by adding the specific antagonists 2-amino-5-phosphonovaleric acid or 6–7-dinitroquinoxaline-2, 3-dione. The stimulatory effect did not appear specific for only excitatory amino acids, as γ-anunobutyric acid stimulated [³H]ADD release in a dose-related manner. These results suggest that, at least in synaptosomal preparations from rat hippocampus, adenosine and glutamate modulate each other's release. The exact mechanism of such interplay, although still, unknown, could help in the understanding of excitatory amino acid neurotoxicity.     

Oryza sativa Lysine‐Histidine‐type Transporter 1 functions in root uptake and root‐to‐shoot allocation of amino acids in rice

In agricultural soils, amino acids can represent vital nitrogen (N) sources for crop growth and yield. However, the molecular mechanisms underlying amino acid uptake and allocation are poorly understood in crop plants. This study shows that rice (Oryza sativa L.) roots can acquire aspartate at soil concentration, and that japonica subspecies take up this acidic amino acid 1.5‐fold more efficiently than indica subspecies. Genetic association analyses with 68 representative japonica or indica germplasms identified rice Lysine‐Histidine‐type Transporter 1 (OsLHT1) as a candidate gene associated with the aspartate uptake trait. When expressed in yeast, OsLHT1 supported cell growth on a broad spectrum of amino acids, and effectively transported aspartate, asparagine and glutamate. OsLHT1 is localized throughout the rice root, including root hairs, epidermis, cortex and stele, and to the leaf vasculature. Knockout of OsLHT1 in japonica resulted in reduced root uptake of amino acids. Furthermore, in ¹⁵N‐amino acid‐fed mutants versus wild‐type, a higher percentage of ¹⁵N remained in roots instead of being allocated to the shoot. ¹⁵N‐ammonium uptake and subsequently the delivery of root‐synthesized amino acids to Oslht1 shoots were also significantly decreased, which was accompanied by reduced shoot growth. These results together provide evidence that OsLHT1 functions in both root uptake and root to shoot allocation of a broad spectrum of amino acids in rice.     

Studies on Amino Acid Metabolism in the Brain Using 15N-Labeled Precursors

The transfer of label from ¹⁵N-alanine and ¹⁵N-glutamate into amino acids in incubated brain slices has been followed using gas chromatography/mass spectrometry (GC/MS). ¹⁵N from alanine appeared in both amino and amide groups of glutamine more rapidly than into aspartate, glutamate and GABA, which were all labeled at similar rates. Maximum labelling of approx. 50% enrichment of these three metabolites was achieved in 3 hr. The ¹⁵N present in doubly-labeled glutamine exceeded that in the singly-labelled after 30 min. ¹⁵N from glutamate was rapidly transferred to aspartate and to alanine, with slower incorporation into glutamine and GABA. As was seen with labeling from alanine, doubly-labeled glutamine was higher than the singly-labeled species, also reaching some 50% enrichment in 3 hr. Depolarisation with 40 mM extracellular K⁺ caused a considerable reversal of the ratio of doubly- to singly-labeled glutamine species from both alanine and glutamate. The results are discussed in terms of the effects of depolarization on the glutamate/glutamine cycle.     

Interstitial Concentrations of Amino Acids in the Rat Striatum During Global Forebrain Ischemia and Potassium-Evoked Spreading Depression

The early detection and appropriate treatment of brain ischemia is of paramount importance. The interstitial concentrations of neurotransmitter amino acids are often used as an index of neuronal injury. However, monitoring of non-neurotransmitter amino acids may be equally important. We have studied the behavior of 10 amino acids during K⁺-induced spreading depression (application of 70 mM KCl during 40 min) and global forebrain ischemia (two-vessel occlusion with hypotension during 20 min). The concentrations of glutamate, aspartate, taurine, GABA, glycine, and alanine, measured in the rat striatum by microdialysis, increased during both ischemia and spreading depression, whereas glutamine concentrations decreased in both cases. Only ischemia, but not spreading depression, led to enhanced release of serine, threonine, and asparagine. We thus conclude that an elevation in the interstitial concentrations of non-neurotransmitter amino acids is specific to deep ischemic injury to nervous tissue. We propose the monitoring of serine, asparagine, and threonine, together with excitatory amino acids, as an index of the degree of ischemic brain injury.     

BACLOFEN: EFFECTS ON AMINO ACID RELEASE AND METABOLISM IN SLICES OF GUINEA PIG CEREBRAL CORTEX

Slices of guinea-pig cerebral cortex were used to investigate the effects of the antispastic drug β-(p-chlorophenyl)-γ-aminobutyrate (Baclofen, Lioresal) on the release and metabolism of several amino acids. Electrical stimulation of slices evoked (1) a relatively large release, probably from nerve terminals, of ¹⁴C-labelled tissue glumate, aspartate and γ-aminobutyrate (GABA) synthesized via metabolism of D-[U-¹⁴C]glucose and (2) a relatively small release, probably not from nerve terminals, of ¹⁴C-labelled tissue alanine and threonine-serine-glutamine and of exogenous radiolabeled glutamate, aspartate, GABA and α-aminoisobutyrate that had been taken up from the medium. Baclofen (4μM) preferentially inhibited the release of ¹⁴C-labelled tissue glutamate and aspartate. It had no effect on the concentrations and specific radio-activities of most of the labelled tissue amino acids in the slices. However, it increased the turnover of ¹⁴C-labelled tissue glycine approx 4-fold and elevated the specific radio activity of tissue alanine by 40%. It was concluded that Baclofen affects transmission not by modulating the release of the inhibitory amino acid GABA, but by selectively suppressing the release of the excitatory amino acids glutamate and aspartate from nerve terminals. Provided that this action obtains in the spinal cord, it may at least partly underlie the antispastic action of Baclofen as glutamate and aspartate are presumed to be the transmitters released from terminals of non-nociceptive primary afferent fibers and excitatory interneurons, respectively. The Baclofen-induced increase in glycine turnover suggests an additional effect on inhibitory glycinergic interneurons in the spinal cord.     

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.

     

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 toadBufo boreas. CO₂ fixation was assessed by two in vivo methods using [2-¹⁴C]glucose injected intracisternally. Thirty minutes after injection, the¹⁴C labeling of glutamate and aspartate was more than 100 times greater in brain than in liver. In brain tissues, 40+% of¹⁴C 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.     

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.     

Cardiac outflow of amino acids and purines during myocardial ischemia and reperfusion.

A novel application of microdialysis was studied, in which myocardial outflow of amino acids and purines was monitored by intravasal microdialysis in the myocardial venous outflow during ischemia and reperfusion. Microdialysis catheters were introduced into the great cardiac vein, pulmonary artery, and external jugular vein in 20 anesthetized pigs. The left anterior descending artery was occluded in four groups of pigs for 0, 10, 15, and 60 min. Ischemia was followed by 120 min of reperfusion. Microdialysis samples were analyzed for taurine, aspartate, glutamate, hypoxanthine, inosine, and guanosine. Myocardial infarction developed when ischemia exceeded 10 min. Taurine, aspartate, inosine, and guanosine increased early in the great cardiac vein during ischemia. We found the outflow patterns of amino acids and purines to be graded in response to different lengths of ischemia. In this study we have demonstrated a graded outflow of amino acids and purines in response to ischemia and a positive correlation between infarct size and myocardial outflow of amino acids and purines. This could be of value in a clinical setting to quantify the extent of myocardial damage.     

EFFECTS OF TETRODOTOXIN, CALCIUM AND MAGNESIUM ON THE RELEASE OF AMINO ACIDS FROM SLICES OF GUINEA-PIG CEREBRAL CORTEX

Abstract— Tetrodotoxin, Ca²⁺-deprivation and high-Mg²⁺ were used in an effort to identify the portion of the evoked release of endogenous amino acids, labelled via metabolism of [¹⁴C]-glucose, and several exogenous labelled amino acids, that came from nerve terminals when slices of guinea pig cerebral cortex were superfused with glucose-free solutions and stimulated electrically. With some exceptions, spontaneous release of labelled amino acids was decreased by 2 μm -tetrodotoxin but increased in Ca²⁺-free medium and in solutions containing an extra 24 mm -MgCl₂. Tetrodotoxin suppressed 85–90% of the stimulated release of almost all labelled amino acids, but had a smaller effect on the release of endogenous ¹⁴C-labelled threonine-serine-glutamine (unseparated). In Ca²⁺-free solution, the stimulated release of endogenous ¹⁴C-labelled glutamate, aspartate and GABA was suppressed by 80–90%, but that of endogenous ¹⁴C-labelled threonine-serine-glutamine was unaffected as was most of the release of the other labelled amino acids. In medium containing an extra 24mM-MgCl₂, the stimulated release of endogenous ¹⁴C-labelled glutamate, aspartate and GABA was suppressed by 75-85%, that of exogenous labelled aspartate and GABA by 50–65%, but the release of the other labelled amino acids was unaffected. The control stimulated releases of endogenous ¹⁴C-labelled glutamate, aspartate and GABA were much larger than those of other labelled amino acids but were reduced by tetrodotoxin, Ca²⁺-deprivation and high-Mg²⁺ to a level similar to that of the control stimulated releases of the other labelled amino acids. These results suggest that almost all of the stimulated release of endogenous ¹⁴C-labelled glutamate, aspartate and GABA came from nerve terminals while those of the other labelled amino acids came from other tissue elements. In addition, they are in accord with a transmitter role for glutamate, aspartate and GABA in cerebral cortex.     

Effects of Prostaglandin E2 and Capsaicin on Behavior and Cerebrospinal Fluid Amino Acid Concentrations of Unanesthetized Rats: A Microdialysis Study

Abstract: Prostaglandin E₂ (PGE₂) delivered to the spinal cord produces an increased sensitivity to noxious (hyperalgesia) and innocuous (allodynia) stimuli. The mechanisms that underlie this effect remain unknown, but a PGE₂-evoked enhancement of spinal neurotransmitter release may be involved. To address this hypothesis, we examined the effect of PGE₂ on CSF concentrations of amino acids and also the modulatory effect of PGE₂ on capsaicin-evoked changes of spinal amino acid concentrations using a microdialysis probe placed in the lumbar subarachnoid space. Amino acids were quantified using HPLC with fluorescence detection. Addition of 1 mM, but not 10 or 100 µM, PGE₂ to the perfusate for a 10-min period (flow rate, 5 µl/min) evoked an immediate increase (80–100%) in glutamate (Glu), aspartate (Asp), taurine (Tau), glycine (Gly), and γ-aminobutyric acid (GABA) concentrations. Similarly, capsaicin infusion (0.1–10 µM) induced a dose-dependent increase in Glu, Asp, Tau, Gly, GABA, and ethanolamine levels. Significant increases in amino acid levels evoked by PGE₂ or capsaicin were associated with a touch-evoked allodynia. The combination of PGE₂ (10 µM) and capsaicin (0.1 or 1.0 µM) at concentrations that individually had no effect together evoked a significant increase (60–100%) in Glu, Asp, Tau, Gly, and GABA concentrations and produced tactile allodynia. These data demonstrate that spinally delivered PGE₂ or capsaicin substantially elevates CSF concentrations of both excitatory and inhibitory amino acids. The capacity of PGE₂ to enhance and prolong capsaicin-evoked amino acid concentrations may be one of the mechanisms by which spinal PGE₂ produces hyperalgesia and allodynia.