Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P80404 (GABA transaminase)
786 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Our efforts have been directed towards characterizing amino acid uptake, metabolism and release in bulk-isolated glia and neuronal perikarya studied in parallel with nerve-endings, especially as it concerns the transmitter amino acids and the participation of glia in the clearing of the synpatic space during impulse conduction. A possible neuromodulator role for the glia at the synapse is also suggested by K+-stimulated release. Our most definitive conclusions have been based so far on studies with GABA, although we are also beginning to accumulate data for glutamate related to glutamate-glutamine compartmentation. Glia preferentially accumulate potassium and amino acids compared to neuronal perikarya, have higher Na+/K+-ATPase activity, possess high-affinity, sodium-dependent uptake systems for GABA and glutamate similar to the ones in synaptosomes, and release amino acid in response to a potassium pulse by a calcium-independent process. Low neuronal uptake could be due to loss of dendrites. Unidirectional GABA-flux from the synaptosomal to glial compartment is supported by high GAD in nerve endings compared to high GABA-T in glia. Glutamine may be a transmitter glutamate-precursor in nerve-endings since glutaminase activity is high in nerve-endings, but low in glia where glutamine is presumably made. Glutamine uptake in both glia and synaptosomes obeys low-affinity kinetics in contrast to glutamate, consistent with the inability of glutamine to excite the neuronal membrane. The studies with GABA, which are considerably more extensive, are supported by related work using glia in tissue-culture and autoradiography. There appears to be a suggested difference in the behavior of amines which were poorly taken up by the glial system. Glia, synaptosomes and neuronal perikarya, in general behaved similarly with respect to requirements for uptake and release, except in the case of Ca++, which exerted opposite effects on glial and synaptosomal uptake of GABA. We believe that work along these lines tends to firmly establish a direct role for glial cells as modulators of neuronal excitability and represents a convergence between transmitter amino acid neuropharmacology and cellular biochemistry. This not only deepens and enlarges the vocabulary of synaptic biochemistry but also undoubtedly will have major clinical applications in the fields of epilepsy and behavior.
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PMID:Amino acid transport in isolated neurons and glia. 0 26

Kojic amine (KA; 2-aminomethyl-5-hydroxy-4H-pyran-4-one), a compound which shares some structural features with gamma-aminobutyric acid (GABA) and muscimol, has been examined in a variety of test systems for GABAmimetic activity. In several in vitro central nervous system receptor binding assays employing rat brain membrane preparations, KA exhibited selective activity to displace 3H-muscimol but with a relatively high IC50 of 4.4 muM. KA did not alter the binding of 3H-diazepam. Iontophoretically applied KA exerted a pronounced (comparable to GABA on the basis of ejection currents)i inhibition of the firing of cerebellar Purkinje cells and spontaneously active or glutamate-activated neurons in the cerebral cortex. The inhibitory effects of KA, which were longer lasting than those of GABA, were antagonized by bicuculline and enhanced in the presence of 2,4-diaminobutyric acid. On the isolated amphibian (Bufo marinus) spinal cord, KA was less than 1/3 as potent as GABA in depolarizing primary afferent terminals. In this preparation KA caused a marked decrease in the dorsal and ventral root potentials evoked by electrical stimulation of an adjacent or corresponding dorsal root. KA is a poor substrate for GABA uptake systems into rat brain synaptosomes, has no effect on GABA release in vitro, and does not inhibit GABA transaminase activity. Altogether, these data suggest that KA does have some GABAmimetic actions (which are perhaps restricted to hyperpolarizing post-synaptic GABA receptors) but also exerts other pharmacological effects as well.
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PMID:The neuropharmacology of a novel gamma-aminobutyric acid analog, kojic amine. 11 13

The uptake of the inhibitory transmitter substance gamma-aminobutyric acid (GABA) into the adult rat pineal gland was studied autoradiographically using both light and electron microscopy. The sites of GABA uptake were shown to be exclusively present in the gliocyte cells of the gland following both in vitro incubation with tritiated GABA and after in vivo administration of the amino acid by intra-arterial injection. Both the pinealocyte cells and the numerous sympathetic axons in the gland were devoid of silver grains. Preliminary biochemical studies indicated that the gliocyte uptake process for GABA resembles that in the satellite glia of the sensory ganglia but differed from that in slices of the cerebral cortex. Evidence is also presented which shows the pineal gland to contain endogenous GABA and the enzymes directly associated with its in vivo metabolism, L-glutamate-1-carboxylase (EC 4.1.1.15) (GAD) and GABA-2-oxoglutarate aminotransferase (EC 2.6.1.19) (GABA-T). Furthermore, a 3-fold rise in endogenous GABA occurred in the pineal after inhibition of GABA-catabolism as would be expected if the GABA-shunt pathway was functionally active in the oxidative metabolism of the pineal gland.
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PMID:On GABA metabolism in the gliocyte cells of the rat pineal gland. 23 81

A synaptic vesicle fraction was prepared from calf brain cortex, containing 10 identified amino acids and two unidentified ninhydrin-positive compounds, one of which is apparently a peptide. The most plentiful amino acids were taurine (1.8 nmol/g original tissue), glutamic acid (1.8), serine (0.9), aspartic acid (0.8) and GABA (0.8); the others identified were cysteic acid (or cysteinesulphinic acid), glutamine, alanine, glycine and lysine. The unknown peptide occurred in a high concentration (about 16 alanine equivalents/g), and contained mainly aspartic acid and serine. Cysteic acid (or cysteinesulphinic acid) also occurred in relatively high amounts, but its peak contained acid-labile impurities. The influx of [14C]glutamate into the vesicles took place by means of non-saturable migration, while two saturable systems having very similar properties were dominant only at low glutamate concentrations. Influx constants for these quantitatively low uptake systems were Km, 34 and 92 micrometer, and Vmax, 33 and 49 nmol/min/g obtained by v versus v/S plot. Almost the same values were also obtained by a 1/v versus 1/S plot. GAD and GABA-T activities in the vesicles were only 1/200th of those in the synaptosomes.
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PMID:Amino acids in the synaptic vesicle fraction from calf brain: content, uptake and metabolism. 58 77

In the belief that homocysteine-induced convulsions might be related to alterations in brain gamma-aminobutyric acid metabolism, we have studied the action of this amino acid on the activity of glutamic decarboxylase (GAD, EC 4.1.1.15) and gamma-aminobutyrate aminotransferase (EC 2.6.1.19) of mouse brain in vitro DL-homocysteine competitively inhibited GAD with respect to both L-glutamate and pyridoxal 5'-phosphate. The respective Ki's were 3.8 mM and 0.3 mM. The activity of GABA-T also was altered in the presence of DL-homocysteine. A competitive inhibition (Ki = 6 mM) was observed with gamma-aminobutyric acid, and an uncompetitive inhibition with respect to pyridoxal 5'-phosphate and alpha-ketoglutarate. These results are explained in terms of a dual action of homocysteine on each of the enzymes: one involving a competition for substrate binding site and the other involving the formation of an inactive inhibitor-cofactor complex. The significance of the inhibition of these enzymes of gamma-aminobutyric acid metabolism is discussed in relation to the convulsant action of homocysteine.
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PMID:The mode of action of homocysteine on mouse brain glutamic decarboxylase and gamma-aminobutyrate aminotransferase. 90 1

The regional distribution of 9 amino acids, including glutamate and GABA and their metabolising enzymes, has been determined in 5 regions of the frog CNS. Glycine was relatively concentrated in the spinal cord whereas the highest concentration of each of the other amino acids was found in the midbrain. There was a good correlation between the activity of l-glutamate-1-carboxylase (GAD) and the level of GABA in all regions examined and both were concentrated in the midbrain. There was little regional variation in the distribution of 4-aminobutyrate-2-oxoglutarate transaminase (GABA-T).
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PMID:Glutamic acid, GABA and their metabolising enzymes in the frog central nervous system. 107 86

Quantitative histochemistry (scanning microphotometry) was used to determine the activities of the mitochondrial enzymes NAD-linked isocitrate dehydrogenase (EC 1.1.1.41), L-glutamate dehydrogenase (EC 1.4.1.3) and GABA transaminase (EC 2.6.1.19) in various layers of the hippocampus (middle one third) of young (3-4 months old) and memory-impaired aged rats (28-30 months old). For comparison, determinations of cytochrome c oxidase (EC 1.9.3.1) as a marker for mitochondria and energy metabolism were also performed. The study showed that there was a layered reaction pattern in the hippocampus and that the cellular distribution and the levels of enzyme activity were different. However, the activities of the different enzymes (excepting GABA transaminase and cytochrome c oxidase) were significantly correlated in the hippocampus in both age groups. Age-dependent changes were only observed for NAD-linked isocitrate dehydrogenase and GABA transaminase (significant increases of activities in some layers of the hippocampus, preferentially in the terminal field of the perforant path). From the present study it is concluded that, 1. the enzymatic complement of mitochondria in neurons and glia depends upon layer specific metabolic processes of the hippocampus (also with respect to glutamatergic and GABAergic terminal fields) indicating a layer specific interaction of the enzymes studied to produce or catabolize glutamate and GABA, and 2. the age dependent changes of the studied enzymes are very restricted.
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PMID:Mitochondrial enzymes related to glutamate and GABA metabolism in the hippocampus of young and aged rats: a quantitative histochemical study. 134 64

An isocratic high-performance liquid chromatographic technique was developed to measure levels of gamma-aminobutyric acid (GABA), glutamate, and taurine in the brain and pituitary of goldfish. Accuracy of this procedure for quantification of these compounds was established by evaluating anesthetic and postmortem effects and by selectively manipulating GABA concentrations by intraperitoneal administration of the glutamic acid decarboxylase (GAD) inhibitor 3-mercaptopropionic acid or the GABA transaminase inhibitor gamma-vinyl GABA. The technique provided a simple, rapid, and reliable method for evaluating the concentrations of these amino acids without the use of complex gradient chromatographic systems. To investigate the relationship between neurotransmitter amino acids and the control of pituitary secretion of gonadotropin, the effects of injection of taurine, GABA, or monosodium glutamate on GABA, glutamate, taurine, and, in some instances, monoamine concentrations in the brain and pituitary were evaluated and related to serum gonadotropin levels. Injection of taurine caused an elevation in serum gonadotropin concentrations. In addition, injection of the taurine precursor hypotaurine but not the taurine catabolite isethionic acid elevated serum gonadotropin levels. Intracerebroventricular injection of either GABA or taurine also elevated serum gonadotropin concentrations. Pretreatment of recrudescent fish with alpha-methyl-p-tyrosine reduced pituitary dopamine concentrations and also potentiated the serum gonadotropin response to taurine. Injection of monosodium glutamate caused an increase of glutamate content in the pituitary at 24 h; this was followed by a decrease at 72 h after administration. Pituitary GABA, taurine, and dopamine concentrations underwent a transient depletion after monosodium glutamate administration, and this was associated with an elevation of serum gonadotropin content.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Amino acid neurotransmitters and dopamine in brain and pituitary of the goldfish: involvement in the regulation of gonadotropin secretion. 134 46

A study was made of the effect of X-rays (4,5 Gy) and pyridoxal phosphate (3 mg/kg, v/v) on the activity of pyridoxal enzymes of GABA metabolism (e.g. glutamate decarboxylase, E.C. 4.1.1.15) and aminobutyrate aminotransferase (GABA-T, E.C. 2.6.1.19), as well as on GABA and glutamate content of the hemisphere cortex, brain stem and cerebellum of rabbits 6 and 10 days following irradiation and injection of a coenzyme. The height of the radiation sickness in rabbits was characterized by the manifest changes in glutamate decarboxylase and GABA-T activity, as well as in GABA and glutamate content of various brain parts differing in the structural and functional functions. The administration of pyridoxal phosphate produced pronounced activation of glutamate decarboxylase, particularly 6 days after irradiation and administration of the co-enzyme, and, to a lesser extent, influenced GABA-T function. Pyridoxal phosphate favored maintaining the GABA level above the control level in the hemisphere cortex and brain stem 6 and 10 days after exposure. The injection of pyridoxal phosphate did not normalize the glutamate content of the brain parts 6 days after exposure, but favored the normalization of GABA-T activity on day 10.
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PMID:[Effect of pyridoxal phosphate on gamma-aminobutyric acid metabolism in different sections of the brain in irradiated animals]. 167 11

Seizure susceptibility and GABA metabolism were altered in the substantia nigra [SN] of adult male Sprague Dawley rats when these animals were acclimating to an altered plasma osmolality. Changes in GABA metabolism were measured in vivo in SN of the freely moving rat. Suitable precautions were taken to avoid any post-mortem flux of glutamate to GABA and to correct for the underestimation of GABA build up in SN due to the finite diffusion rate of gamma-vinyl GABA [GVG] after stereotaxic injection of small amounts into one side of the brain. Control experiments provided evidence that changes in osmolality, within a normal physiological range, did not affect significantly gamma-aminobutyric acid transaminase [GABA-T]. Also kindling via the medial septum [MS], in the absence of electrical stimulation did not alter GABA metabolism in SN, thus providing a stable baseline for studies of osmotic effects. Hyperosmolality was associated with a rise in seizure thresholds, with a marked reduction of the rate of GABA synthesis in SN, and with a substantial increase in turnover time of the GABA pool. Hypoosmolality, of a degree known to be associated with mild cerebral edema and swelling localized to astrocytes, markedly reduced seizure threshold, and reduced GABA pool size in SN, but did not alter the rate of GABA synthesis significantly. These results demonstrate by new and independent means the relationship between GABA metabolism in the SN and seizure susceptibility in vivo.
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PMID:Alterations of GABA metabolism and seizure susceptibility in the substantia nigra of the kindled rat acclimating to changes in osmotic state. 178 28


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