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

Characteristics of 3H-GABA binding to rat brain synaptic membranes in vitro have been investigated. The specific binding of 3H-GABA displays saturation kinetics. Only one single population of receptor sites was found (Km = 31.3 nM) with a concentration of 2.09 pmol/mg protein. Only GABA agonists show inhibitory effect on the binding, whereas GABA antagonists, GABA-uptake inhibitors, and inhibitors of GAD and GABA-T are without effect. The order of potencies for GABA agonists are: Muscimol greater than GABA greater than or equal to 4,5-dihydromuscimol greater than 3-aminoproprane sulphonic acid greater than isoguvacine greater than THIP greater than 3-hydroxy-GABA greater than imidazol-4-acetic acid. Agonists and antagonists from other neurone systems as well as neuroleptics and benzodiazepines had no or only a very slight potency in the binding test.
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PMID:Characterization of 3H-GABA receptor binding to rat brain synaptosomal membranes: effect of non GABAergic compounds. 22 5

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

Experimental procedures are described which are believed to yield results that reflect, within certain limits, the in vivo changes of the size of the GABA pool in nerve endings in comparison with those of all other GABA pools. Two irreversible GABA-T inhibitors, vinyl GABA and acetylenic GABA, two GAD inhibitors, 3-mercaptopropionic acid and pyridoxal phosphate glutamyl-gamma-hydrazone, and di-n propylacetate, a clinically useful anticonvulsant, have been studied to determine their effects on GABA compartmentalization in mouse brain cortex. The changes elicited by these drugs in subcellular fractions of brain cortex homogenates support the notion that measurement of amino acid concentrations in crude synaptosomal fractions and in supernatant fractions under controlled conditions allow one to draw conclusions about relative changes of pool sizes in vivo. In particular this work showed that a specific increase in the concentration of GABA within the nerve endings is more important than a large increase of total brain GABA as a means of decreasing susceptibility to a variety of chemically or physically induced seizures.
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PMID:Metabolic inhibitors and subcellular distribution of GABA. 39 22

In young chicks the effects of 3 min stroboscope stimulation on GABA and free glutamic acid content and on GAD and GABA-T activity in optic lobes were studied. A significant depletion in GABA and glutamic acid levels was found to occur. In addition a sustained increase in GABA-T and GAD activity was observed. In conclusion present experiments are in favour of an inhibitory role played by GABA in chick optic tectum during stroboscope stimulation.
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PMID:Light-evoked changes in chick optic lobe GABA system. 45 34

In chicks with cannulae chronically implanted into the III cerebral ventricle, the effects of a single dose (10 micrograms) of beta-endorphin on GABA and free glutamic acid content, GAD and GABA-T activities in the diencephalon, brain-stem and brain hemispheres were studied at the time of maximal behavioural stuporous state and analgesia. A significant decrease in GABA concentration both in the diencephalon and brain-stem, accompanied by a significant increase in GABA-T activity in the same areas, was shown to occur. No changes were observed in GAD activity and in glutamic acid content in the studied areas of the brain. In conclusion, present experiments suggest that some central effects of a beta-endorphin may be due to an interference with GABA-ergic transmission.
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PMID:Effects of intraventricular beta-endorphin on GABA system in some areas of chick brain. 52 83

GABA, its derivative -- gamma-hydroxybuturic acid and metabolite --succinic acid have a pronounced dilatatory activity on cerebral circulation in various brain parts. GABA increases cerebral circulation by 25.3%, gamma-hydroxybutyric acid by 35.9% and sucinic acid by 20.4%. In ischaemia of the brain a relationship has been established between cerebral circulation, changes in the GABA system in brain and in the walls of cerebral arteries. The content of GABA increases following enhancement of GAD activity and inhibition of GABA-T. The increase of endogenous GABA level in brain during hypoxia of the brain brings to an improvement of blood circulation through increasing collateral vessels. Experiments with GABA-T inhibition by aminooxyacetic acid give direct evidence about the role of the GABA system in cerebral blood circulation. This mechanism is evaluated by us as an example of an autoregulatory system that is realized by a feed-back mechanism providing the adaptability and compensatory function of cerebral haemodynamics to changing conditions.
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PMID:[Role of GABA and its derivatives in regulating cerebral circulation]. 57 37

Chronically alcoholized intoxication (1.5--2 months) induces adaptation of cerebral neurones to changing equilibrium states of biochemical processes by altering the activity of enzymes of GABA metabolism, reduction of alanine and aspartate transaminase activity and increase of LDH and succinate dehydrogenase activity. In the cerebellum and cerebral hemispheres during alcohol abstinacy the activity of GABA-T, succinate dehydrogenase and aspartate transaminase was reduced while that of LDH and alanine transaminase was increased. The administration of fusarinic acid (100 mg/kg i. p.) to control animals induced a sharp increase of GAD activity in both structures of the brain. The stimulatory effects of fusarinic acid were not observed when it was administered to animals receiving alcohol chronically. Motor activity or rats was markedly reduced during chronical alcoholism and the first days of alcohol abstinacy (24--48 h), as well as following injection fusarinic acid and homopantothenic acid. The increase of locomotion and the vertical component of motor activity was observed only following one week or one month after alcohol abstinacy.
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PMID:[Adaptive changes in brain metabolism during chronic alcoholic intoxication]. 57 38

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

The knowledge that GABA is an inhibitory neurotransmitter substance in brain has spurred a prodigious research effort to implicate GABA in the etiology of seizures. Such an involvement for GABA can occur theoretically at either of two levels, at the level of its metabolism or at the level of its functioning. Convulsant agents such as picrotoxin and bicuculline appear to act by impairing the functioning of GABA at the postsynaptic receptor site, but virtually nothing is known about the attendant molecular events although a major expansion of knowledge in this area may be expected within the next decade. In contrast, a vast amount of data has accumulated with respect to changes in GABA metabolism induced by convulsant agents such as the hydrazines, hydrazides, and hyperbaric oxygen. The problem in this case lies in the interpretation of the data. Are the changes in GABA metabolism the cause of the seizures? There is clearly no simple relationship between seizure activity and any single parameter of GABA metabolism, be it the GABA content of the brain, or the rate of uptake of GABA by cellular components, or the activity of the GABA-synthesizing and degrading enzyme systems, GAD and GABA-T respectively. This finding may, however, be illusory since the parameters of GABA metabolism were in most cases measured using preparations from intact brain tissue. Observed changes in the parameters may not accurately reflect events at a critical subcellular location such as the synaptic cleft. Thus there may well be a simple relationship between the concentration of GABA in the synaptic cleft and seizure activity. Unfortunately the limitations of current technology preclude the testing of this possibility. The author has, however, developed an equation on an empirical basis which provides an excellent relationship between the excitable state of the brain and a function of GABA metabolism which incorporates both changes in GABA level and changes in GAD activity. This equation has been used successfully to explain and rationalize previously anomalous results with respect to changes in GABA metabolism associated with the action of both convulsant and anticonvulsant agents. The concept embodied in the equation is that the excitable state of brain is determined primarily by the rate of synthesis of GABA but that reflects changes in the concentration of GABA in the synaptic cleft has been suggested.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The role of gamma-aminobutyric acid in the mechanism of seizures. 83 81


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