The Occurrence of γ-Aminobutyrylcholine in Mammalian Brain—Fact or Artefact?

Abstract: γ-Aminobutyrylcholine (GABACh) has been reported to exist in mammalian brain tissue, but not, as yet, given a specific physiological role in the CNS. In order to investigate further its occurrence and function in the CNS, two new methods have been developed for its isolation and determination at the picomole level. Its isolation has been achieved by ammonium Reineckate precipitation or by cation-exchange followed by HPLC determination of the dansyl and O -phthaldialdehyde derivatives. Using these methods, no free endogenous GABACh (<80 pmol/g) was found in rat, guinea pig, cat, pig, marmoset, or human brain tissue. No evidence was obtained, either in vitro or in vivo , for the incorporation of [¹⁴C]choline or [¹⁴C]γ-aminobutyric acid into GABACh. GABACh was hydrolysed at a low rate (maximum of 45 nmol/h/g of brain tissue) after incubation with rat, guinea pig, or cat brain minces and homogenates. These results fail to confirm the data of other investigators, and the possible reasons for this are discussed.     

ALTERATIONS IN GABA METABOLISM AND MET-ENKEPHALIN CONTENT IN RAT BRAIN FOLLOWING REPEATED ELECTROCONVULSIVE SHOCKS

The effects of electroconvulsive shock (ECS; 120 V for 1 s through ear-clip electrodes) or sub-convulsive shocks (70 V for 1 s) on rat brain GABA and met-enkephalin concentration and GABA turnover has been examined 24 h after a single treatment (×1) or once daily for 10 days (×10). ECS × 10 increased GABA concentrations in the N. caudatus and N. accumbens and decreased the synthesis rate of GABA by 40% and 50% respectively in these regions. Sub-convulsive shocks (× 10 × 10) or ECS × 1 had no effect. No consistent changes were seen in the substantia nigra. Met-enkephalin concentrations increased by 50% in the N. caudatus after ECS × 10 but were unchanged in the cortex and pons/medulla. No other shock regimen had any effect on the concentration of this peptide. The results are discussed in relation to the enhanced monoamine-induced responses seen only after ECS × 10.     

Multi-Regional Investigation of the Relationship between Functional MRI Blood Oxygenation Level Dependent (BOLD) Activation and GABA Concentration

Several recent studies have reported an inter-individual correlation between regional GABA concentration, as measured by MRS, and the amplitude of the functional blood oxygenation level dependent (BOLD) response in the same region. In this study, we set out to investigate whether this coupling generalizes across cortex. In 18 healthy participants, we performed edited MRS measurements of GABA and BOLD-fMRI experiments using regionally related activation paradigms. Regions and tasks were the: occipital cortex with a visual grating stimulus; auditory cortex with a white noise stimulus; sensorimotor cortex with a finger-tapping task; frontal eye field with a saccade task; and dorsolateral prefrontal cortex with a working memory task. In contrast to the prior literature, no correlation between GABA concentration and BOLD activation was detected in any region. The origin of this discrepancy is not clear. Subtle differences in study design or insufficient power may cause differing results; these and other potential reasons for the discrepant results are discussed. This negative result, although it should be interpreted with caution, has a larger sample size than prior positive results, and suggests that the relationship between GABA and the BOLD response may be more complex than previously thought.     

In Vivo Changes in γ-Aminobutyric Acid Output from the Cerebral Cortex Induced by Inhibitors of γ-Aminobutyric Acid Uptake and Metabolism

Abstract: The effects of inhibitors of γ-aminobutyric acid (GABA) metabolism or uptake on GABA output from the cerebral cortex was studied by means of a collecting cup placed on the exposed cortex of rats anaesthetized with urethane. GABA was identified and quantified by a mass-fragmentographic method. Ethanolamine-O-sulphate (10⁻² M ) applied directly on the cerebral cortex caused a long-lasting twofold increase in GABA output, whereas dl -2, 4-diaminobutyric acid (5 × 10⁻³ M ) caused a sevenfold increase and β -alanine was inactive. The results indicate that glial uptake has little effect on GABA inactivation in the cerebral cortex. The inhibition of neuronal uptake seems a more effective tool to increase GABA concentration in the synaptic cleft, and consequently also in GABA output, than the inhibition of GABA metabolism.     

Effect of propyl-2-pentene-2-oic acid on GABA levels in different regions of mouse brain]

An elevation in cerebral GABA level (65%) is observed after administration of an anticonvulsant, sodium propyl 2-pentene-2 oate, a branched chain fatty acid, comformationally restricted GABA analogue, competitive inhibitor of GABA-T in regard to GABA. The concentration of GABA increases in some regions i.e. substantia nigra, frontal and temporal cortex, cerebellum and olfactory bulbs. The GABA level remains unchanged in caudate nucleus, hippocampus and occipital cortex. Results are discussed comparatively to the effect of sodium n-dipropylacetate.     

A search for endogenous modulators of the GABA receptor in different regions of the rat CNS

The possible existence of endogenous substances other than γ-aminobutyric acid (GABA), that can also bind to rat brain GABA receptors, has been investigated in synaptic membranes derived from whole rat brain, or from cerebral cortex; as well as in isolated synaptic vesicles obtained from cerebral cortex, striatum, hypothalamus, cerebellum and spinal cord and in the superfusion fluid of electrically stimulated brain cortex slices, where a GABA-like substance is released by a calcium-dependent process. The detector used to study the presence of such presumed non-GABA endogenous ligands, were frozen and thawed rat brain synaptic membranes, that had been treated with 0.05% Triton X-100 and thoroughly washed. With this highly sensitive preparation, at least 5 pmol of GABA/ml could be detected. The extracts of the different preparations where these hypothetical ligands were looked for, were analyzed by means of gel filtration on Sephadez G-10, paper chromatography and high voltage electrophoresis. In a very great number of experiments performed, the only endogenous ligand detected was GABA itself.The possible influence of a number of peptides on binding of GABA to its receptor, was also looked for. No significant effect was found for substance P, neurotensin, cholecystokinin octapeptide sulfated, somatostatin, thyrotropin releasing hormone, luteinizing hormone releasing hormone, methionine enkephalin (all 10^?5 M), angiotensin II (10^?4 M), ACTH (3 × 10^?7M), poly-l-lysine (30 μg/ml) or poly-l-glutamate (30 μg/ml).     

INHIBITION OF GABA TRANSAMINASE ACTIVITY BY 4-AMINOTETROLIC ACID

Abstract— The influence of the following acetylenic analogues of GABA on GABA-metabolizing enzymes was studied in vitro : 4-amino-, 4-morpholino-, 4-piperazino-, 4-piperidino- and 4-pyrrolidinotetrolic acid. 4-Aminotetrolic acid was a linear competitive inhibitor of GABA transaminase activity in extracts of rat cerebral mitochondria and a linear noncompetitive inhibitor of this enzyme activity in extracts of P. fluorescens when activity was measured with GABA as the variable substrate. From these results it was calculated that the dissociation constants for the binding of 4-aminotetrolic acid to the pyridoxal form of these enzymes are approx. 1 mM. The other substituted tetrolic acids did not influence either transaminase activity under the conditions studied. None of the substituted tetrolic acids influenced the L-glutamic acid decarboxylase activity in extracts of rat cerebral cortex and of E. coli .     

Increased brain uptake and brain to blood efflux transport of 14C-GABA in spontaneously hypertensive rats

The brain uptake and brain to blood efflux transport of (14)C-GABA were studied in spontaneously hypertensive rats (SHR) and normotensive Wistar Kyoto (WKY) rats using 20 min bilateral in situ brain perfusion in rats anesthetized using urethane. The volume of distribution (Vd) of (14)C-GABA into cerebrospinal fluid (CSF) and brain regions (cortex, diencephalon, cerebellum, and brain stem) was significantly greater in SHR than in the corresponding regions in WKY rats (p<0.05). The estimated Vd value of (14)C-GABA in CSF of SHR was 3.4 fold greater than that in WKY. Also compared to WKY, the Vd of (14)C-GABA into cerebellum and cortex of SHR was 15.3 fold and 19.4 fold greater, respectively. Although the study of blood-brain barrier (BBB) integrity using (3)H-mannitol revealed increased paracellular permeability at the brain capillaries of SHR when compared to WKY rats, this was found to be only partially responsible for the increased (14)C-GABA uptake. The study of brain to blood efflux transport of (14)C-GABA (after loading of brain with (14)C-GABA by vascular perfusion) revealed that the half-time of elimination was significantly shorter in SHR (5.35+/-0.66 min) than in WKY rats (14.83+/-1.94 min), (p<0.001). HPLC analysis revealed that GABA concentrations in brain extracts and CSF of SHR were similar to those in WKY rats (p>0.05). The faster efflux in SHR might be, at least partially, responsible to compensate for increased uptake of this neurotransmitter and to preserve the protective function of BBB towards GABA. The protective function of the BCSFB towards GABA appears to be also preserved, since systemic infusion of GABA within a wide range of administered doses (0.004-5.00 mg/kg) produced an increase in GABA CSF concentration from around 0.5 microM to only 11 microM, and the obtained pattern of CSF GABA concentrations under these conditions did not differ between SHR and WKY rats, as revealed by HPLC.     

REDUCTION OF γ-AMINOBUTYRIC ACID LEVEL IN THE CAT CEREBRAL CORTEX BY AFFERENT ELECTRICAL STIMULATION

—Electrical stimulation for 30 s of one brachial plexus in cat (afferent electrical stimulation = AES) produced a 20% decrease in GABA level of the stimulated (contralateral) cerebral cortex as compared to the non-stimulated (ipsilateral) cortex in the same animal. This change in GABA was reversed within a few seconds after cessation of stimulation. Inhibition of GABA catabolism by aminooxyacetic acid elevated considerably the cortical level of GABA but failed to prevent lowering GABA by AES. When AES was performed in preconvulsive condition induced by administration of picrotoxin, the decrease in GABA was negligible, while similar treatment with pentylenetetrazol had no influence on the decrease in GABA produced by AES. The observed lowering cortical GABA by AES is interpreted as being associated with some mechanism of the inhibitory transmitter inactivation.     

Focal neurometabolic alterations in mice deficient for succinate semialdehyde dehydrogenase

Metabolite profiling in succinate semialdehyde dehydrogenase (SSADH; Aldh5a1-/-) deficient mice previously revealed elevated gamma-hydroxybutyrate (GHB) and total GABA in urine and total brain and liver extracts. In this study, we extend our metabolic characterization of these mutant mice by documenting elevated GHB and total GABA in homogenates of mutant kidney, pancreas and heart. We quantified beta-alanine (a GABA homolog and putative neurotransmitter) to address its potential role in pathophysiology. We found normal levels of beta-alanine in urine and total homogenates of mutant brain, heart and pancreas, but elevated concentrations in mutant kidney and liver extracts. Amino acid analysis in mutant total brain homogenates revealed no abnormalities except for significantly decreased glutamine, which was normal in mutant liver and kidney extracts. Regional amino acid analysis (frontal cortex, parietal cortex, hippocampus and cerebellum) in mutant mice confirmed glutamine results. Glutamine synthetase protein and mRNA levels in homogenates of mutant mouse brain were normal. We profiled organic acid patterns in mutant brain homogenates to assess brain oxidative metabolism and found normal concentrations of Kreb's cycle intermediates but increased 4,5-dihydroxyhexanoic acid (a postulated derivative of succinic semialdehyde) levels. We conclude that SSADH-deficient mice represent a valid metabolic model of human SSADH deficiency, manifesting focal neurometabolic abnormalities which could provide key insights into pathophysiologic mechanisms.     

POSTNATAL CHANGES IN THE POTASSIUM-STIMULATED, CALCIUM-DEPENDENT RELEASE OF RADIOACTIVE GABA AND GLYCINE FROM SLICES OF RAT CENTRAL NERVOUS TISSUE

—Using a simple apparatus designed to perfuse nervous tissue mini-slices retained on glass fibre filter discs, slices of adult (13 week) rat cerebral cortex and spinal cord were shown to release radioactive GABA and glycine, but not 2-amino-isobutyric acid, in response to increased potassium ion concentration of the perfusing medium. A major portion of this potassium-stimulated release was dependent upon the presence of calcium ions in the perfusing medium. Slices of cerebral cortex and spinal cord from rats of 1 day and 10 days postnatal age showed potassium-stimulated, calcium-dependent release of radioactive GABA and glycine respectively. These findings are consistent with other evidence that GABA and glycine are functioning as inhibitory transmitters in rats at least as soon as 1 day after birth.     

Rapid method for the assay of 4-aminobutyric acid (GABA), glutamic acid and aspartic acid in brain tissue and subcellular fractions

The thin-layer electrophoretic separation at pH 4.8 of brain extracts and a procedure for fluorescent staining of the plates with fluorescamine are described for the rapid routine determination of 4-aminobutyric acid (GABA), glutamic acid and aspartic acid in brain extracts and in particulate fractions of brain tissue. Automated sample application, electrophoretic separation using two chambers, and quantitation by in situ fluorescence scanning allows the assay of 280 samples within three working days. The method is reproducible (S.D. <8% of the mean) within the range of 0.2–2 nmole per spot. The staining procedure can be applied to a variety of related analytical problems. The method has proved useful for the determination of the specific radioactivities of GABA, glutamic acid and aspartic acid in metabolic studies.     

Uptake of [14C]GABA by rat brain slices; the effect of Ca2+

The [14C]GABA uptake by slices (0.3 mm thick) of Wistar rat brain cortex was studied for its dependence on the GABA concentration in the medium, time of incubation and the presence of Ca2+. This process is characterized by the absence of saturation; the uptake by slices increases sharply when the concentration of exogenous [14C]GABA reaches 200 microM. Bicucullin (10(-4) M), an antagonist of GABA, inhibits the accumulation of GABA in the concentration of 0.2 microM by 60%, that evidences for a considerable contribution of the receptor binding to this process. The [14C]GABA uptake when Ca2+ is absent in the incubation medium and when its concentration is 10(-3) M is practically the same and comparatively low concentrations of Ca2+ (10(-6)-10(-4] decrease the GABA uptake.     

Glutamate as a precursor of GABA in rat brain and peripheral tissues

Summary The formation of GABA from L-glutamate was investigated in homogenates of rat brain, liver, and kidney, using highly purified [¹⁴C]-L-glutamic acid as substrate and a thin-layer chromatographic separation of products. In agreement with other workers, liberation of [¹⁴C]-CO₂ was found to be stoichiometric with GABA formation in brain homogenates, but not in liver or kidney extracts. Subcellular fractionation and dialysis experiments suggested that most of the GABA synthesis in these peripheral tissues, unlike brain, does not occur via a direct decarboxylation of glutamate and requires one or more cofactors other than pyridoxal phosphate. NAD stimulated GABA formation in dialyzed extracts, and inhibition of GABA-transaminase, bothin vitro andin vivo, caused marked inhibition of GABA formation from glutamate in peripheral extracts. Although a very low GAD activity in liver and kidney cannot be excluded, these experiments suggest a major pathway from glutamate to GABA in these homogenates which includes (1) conversion of glutamate to -ketoglutarate by glutamate dehydrogenase or transaminases, (2) conversion of -ketoglutarate to succinic semialdehyde, and (3) formation of GABA from succinic semialdehyde and glutamate by GABA-transaminase.     

Uptake of γ-Aminobutyric Acid by Brain Tissue Preparations: A Reevaluation

The kinetic constants Km and Vmax for the uptake of gamma-aminobutyric acid (GABA) by various preparations from rat cerebral cortex were determined by means of Eadie-Hofstee plots and computer analysis. The Km values were much greater in 0.1-mm slices than in synaptosomal preparations, and the Km value increased further with the thickness of the slices. The apparent high Km values in slices were probably due to depletion of the GABA concentration in the extracellular fluid as the exogenous GABA ran the gauntlet of competing uptake sites on its way to sites deep within the slice, thereby bringing about a requirement for higher GABA concentrations in the incubation medium in order to maintain the internal GABA levels at the "Km level." Evidence was obtained for three GABA uptake systems with Km values (in synaptosomes) of 1.1 microM, 43 microM, and 3.9 mM, respectively. In contrast, only two uptake systems for D-aspartate were detected, with Km values of 1.8 microM and 1.8 mM, respectively. The implications of the findings in the study with respect to previous data in the literature are discussed.     

The Synthesis and Activity of cis-and trans-2-(Aminomethyl) cyclopropanecarboxylic Acid as Conformationally Restricted Analogues of GABA

Abstract: The synthesis of cis -2-(aminomethyl) cyclopropanecarboxylic acid, a new analogue of GABA in a folded conformation, is described, as is also an improved preparation of trans -2-(aminomethyl) cyclopropanecarboxylic acid. When adminstered microelectrophoretically the trans isomer was more potent than GABA as a bicuculline-sensitive depressant of the firing of cat spinal neurons in vivo , whereas the cis-isomer was less potent than GABA and its effects appeared not to be sensitive to bicuculline methochloride. Trans -2-(aminomethyl) cyclopropanecarboxylic acid was a weak inhibitor of the sodium-dependent uptake of GABA by mini slices of rat cerebral cortex and a substrate for the GABA: 2-oxoglutarate aminotransferase activity in extracts of rat brain mitochondria. The cis isomer did not influence GABA uptake or aminotransferase activity and neither isomer reduced glutamate decar-boxylase activity in rat brain homogenates. Both cyclopropane isomers inhibited the sodium-independent binding of GABA to synaptic membranes from rat brain and their relative potencies together with those found for the stereochemically related unsaturated derivatives, cis -and trans -4-aminocrotonic acid, were broadly consistent with the activity observed for these compounds in vivo on cat spinal neurons. These studies reinforce the evidence that extended rather than folded conformations of GABA are active at most GABA recognition sites within the mammalian central nervous system.     

Effect of a benzodiazepine (chlordiazepoxide) on a GABAA receptor from rat brain. Requirement of only one bound GABA molecule for channel opening.

Chlordiazepoxide (CDPX) enhanced the rate of chloride exchange mediated by the major GABAA receptor found on sealed native membrane vesicles from rat cerebral cortex. The initial rate constant for chloride exchange for this receptor, (JA), a measure of open channel, was determined from the progress of GABA-mediated influx of 36Cl-. The dependence of JA on GABA concentration was hyperbolic in the presence of CDPX (150 microM, sufficient to give maximum enhancement of chloride exchange rate) but sigmoid in its absence. Enhancement of channel opening (10-fold at 0.3 microM GABA) decreased with increasing GABA concentration. The maximal response, above 1,000 microM GABA, was unaltered. The half-response concentration was reduced from 80 microM to 50 microM. CDPX alone caused no measurable 36Cl- exchange. In the presence of CDPX, channel opening occurred with only one bound GABA molecule, whereas in its absence, channel opening with two bound GABA molecules was much more favorable. This could not be direct allosteric modulation of the channel opening conformational change by binding of CDPX at effector sites, but could be explained by an additional change of the receptor on binding CDPX to give a closed state which gave channel opening mediated by a single GABA binding site. Another possibility is that CDPX could act at one of the channel opening binding sites without a postulated, second closed conformational state.     

Determination of GAB A Levels by a [3H]Muscimol Radioreceptor Assay

Abstract: A [³H]muscimol radioreceptor assay was used to measure the levels of GAB A in mouse brain. The method is based on the competitive inhibition of [³H]muscimol binding to the GABA receptor by GABA extracted from tissue. The specificity and accuracy of the method was established by comparative measurements of GABA levels by gas chromatography. GABA levels obtained by radioreceptor assay (R) and gas chromatography (GC) in different areas of mouse brain were (in μmol/g tissue ± S.E.M.): cerebral cortex 1.41 ± 0.06 (R), 1.50 ± 0.03 (GC); corpus striatum 1.70 ± 0.05 (R), 1.66 ± 0.01 (GC); cerebellum 1.15 ± 0.04 (R), 1.11 ± 0.07 (GC); hippocampus 1.35 ± 0.04 (R), 1.43 ± 0.04 (GC). The sensitivity of the assay was 5 pmol of GABA, which is sufficient to measure GABA levels in brain. The technique described is simple and rapid and it can be used for unpurified tissue extracts.     

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

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

EFFECTS OF AMINOOXYACETIC ACID AND l-GLUTAMIC ACID-γ-HYDRAZIDE ON GABA METABOLISM IN SPECIFIC BRAIN REGIONS

Abstract— Aminooxyacetic acid (AOAA) administration produced an increase in γ-aminobutyric acid (GABA) levels in regions of cerebral cortex, subcortex and cerebellum. In some cortical areas studied, the maximal effect was observed with 25 mg/kg AOAA; in other regions GABA levels were increased further with 50 and 75 mg/kg AOAA. Pretreatment with 25 mg/kg AOAA effectively inhibited GABA:2-oxoglutarate aminotransferase (GABA-T) and partially inhibited glutamic acid decarboxylase (GAD) activity in regions of cerebral cortex. However, this dose did not affect GAD activity in substantia nigra while GABA-T in the nigra and in the cerebellum was only partially inhibited. In both cortical and subcortical areas, the increase in GABA produced by 25 mg/kg of AOAA was linear. In contrast, l -glutamic acid-hydrazide (GAH) had no effect in the pyriform and cingulate cortex for the first 60 min after injection, and produced a biphasic GABA increase in caudate and substantia nigra over a 4 h period. Results suggest that GAH and AOAA affect regional GABA metabolism differentially and that there are several problems associated with estimating absolute GABA synthesis rates by measuring the rate or GABA accumulation after inhibition of GABA catabolism with these agents. This approach, however, may provide an easily obtainable indication of whether drugs or other manipulations are altering GABA synthesis in a given region.