UNIPROT:P80404 - FACTA Search

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)

Depending on their mechanism of action, anticonvulsant drugs in clinical use may be divided into three groups: those drugs which facilitate gamma-aminobutryic acid (GABA)ergic neurotransmission; those which block neuronal ion channels; and those whose mechanism of action is unresolved. The compounds acting on GABAergic systems may be further subdivided into those which modulate transmission through chloride channels, e.g. the barbiturates and the benzodiazepines; those compounds, in particular vigabatrin, which reduce the degradation of GABA by blocking GABA transaminase; and those which inhibit the re-uptake of GABA into the presynaptic terminal. The other group of compounds whose mechanism of action is known are those which block neuronal ion channels. Blockage of voltage-operated sodium channels by lamotrigine, phenytoin or carbamazepine leads to decreased electrical activity and, probably, a subsequent reduction in glutamate release. Conversely, ethosuximide, blocks voltage-operated calcium channels, especially those which mediate calcium currents in thalamic neurones. Of those drugs in which the mechanism of action is unknown, sodium valproate is the prime example. An antagonistic action at the N-methyl-D-aspartate (NMDA) subtype of glutamate receptor might also be a possibility, which could be the case with some of the newer compounds currently undergoing evaluation.
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PMID:Mechanisms of action of antiepileptic drugs. 871 18

Established antiepileptic drugs (AEDs) decrease membrane excitability by interacting with neurotransmitter receptors or ion channels. AEDs developed before 1980 appear to act on sodium channels, gamma-aminobutyric acid type A (GABAA) receptors, or calcium channels. Benzodiazepines and barbiturates enhance GABAA receptor-mediated inhibition. Phenytoin (PHT), carbamazepine (CBZ), and possibly valproate (VPA) decrease high-frequency repetitive firing of action potentials by enhancing sodium-channel inactivation. Ethosuximide (ESM) and VPA reduce a low threshold (T-type) calcium-channel current. The mechanisms of action of the new AEDs are not fully established. Gabapentin (GBP) binds to a high-affinity site on neuronal membranes in a restricted regional distribution of the central nervous system. This binding site may be related to a possible active transport process of GBP into neurons; however, this has not been proven, and the mechanism of action of GBP remains uncertain. Lamotrigine (LTG) decreases sustained high-frequency repetitive firing of voltage-dependent sodium action potentials that may result in a preferential decreased release of presynaptic glutamate. The mechanism of action of oxcarbazepine (OCBZ) is not known; however, its similarity in structure and clinical efficacy to CBZ suggests that its mechanism of action may involve inhibition of sustained high-frequency repetitive firing of voltage-dependent sodium action potentials. Vigabatrin (VGB) irreversibly inhibits GABA transaminase, the enzyme that degrades GABA, thereby producing greater available pools of presynaptic GABA for release in central synapses. Increased activity of GABA at postsynaptic receptors may underline the clinical efficacy of VGB.
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PMID:Antiepileptic drug mechanisms of action. 878 10

Great progress has been made in the development of antiepileptic drugs (AEDs) from their early empirical stage until the current scientifically-founded advancement based on our greater understanding of the genesis of epilepsy. Available AEDs decrease neuronal membrane excitability, acting on ion channels or synaptic receptors. The classic AEDs act on sodium channels (phenytoin and carbamazepine); increase GABA-A receptor-mediated inhibition (benzodiazepines and barbiturates); and on T-type Ca2+ channels (sodium valproate and ethosuximide). Many patients are resistant to these AEDs. The introduction of new drugs whose mechanisms of action are not well established has improved therapeutic prospects. Four promising new AEDs are now available in many countries. Vigabatrin is an irreversible inhibitor of GABA transaminase. Lamotrigine blocks Na+ channels, thereby inhibiting the presynaptic release of excitatory neurotransmitters. Gabapentin increases GABAergic inhibition and Felbamate acts on the NMDA receptor and Na+ channels. New techniques in molecular biology are likely to facilitate the design of better AEDs.
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PMID:[Antiepileptic drugs: mechanism of action]. 905 61

Established antiepileptic drugs (AEDs) decrease membrane excitability by interacting with neurotransmitter receptors or ion channels. AEDs developed prior to 1980 appear to act on sodium channels. gamma-amino butyric acid type A (GABAA) receptors (GABARs) or calcium channels. Benzodiazepines and barbiturates enhance GABAR-mediated inhibition. Phenytion, carbamazepine and possibly sodium valproate decrease high-frequency repetitive firing of action potentials by enhancing sodium channel inactivation. Ethosuximide and sodium valproate reduce a low threshold (T-type) calcium channel current. The mechanisms of action of the new AEDs are not fully established. Gabapentin binds to a high affinity site on neuronal membranes in a restricted regional distribution of the central nervous system. This binding site may be related to a possible active transport process of gabapentin into neurons; however, this has not been proven and the mechanism of action of gabapentin remains uncertain. Lamotrigine decreases sustained high-frequency repetitive firing of voltage-dependent sodium actin potentials that may result in a preferential decreased release of presynaptic glutamate. Oxcarbazepine's mechanism of action is not known; however, its similarity in structure and clinical efficacy to that of carbamazepine suggests that its mechanism of action may involve inhibition of sustained high-frequency repetitive firing of voltage-dependent sodium action potentials. Vigabatrin irreversibly inhibits GABA transaminase, the enzyme that degrades GABA, thereby producing greater available pools of presynaptic GABA for release in central synapses. Increased activity of GABA at postsynaptic receptors may underlie the clinical efficacy of vigabatrin. The potential mechanistic bases for rational polypharmacy are reviewed.
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PMID:Is there a mechanistic basis for rational polypharmacy? 929 30

1. The effects of 2, 8 and 21 day oral treatment with the specific gamma-aminobutyric acid transaminase (GABA-T) inhibitors gamma-vinyl GABA (GVG) and ethanolamine O-sulphate (EOS) on brain GABA levels, GABA-T activity, and basal and stimulated GABA release from rat cross-chopped brain hippocampal slices was investigated. 2. Treatment with GABA-T inhibitors lead to a reduction in brain GABA-T activity by 65-80% compared with control values, with a concomitant increase in brain GABA content of 40-100%. 3. Basal hippocampal GABA release was increased to 250-450% of control levels following inhibition of GABA-T activity. No Ca2+ dependence was observed in either control or treated tissues. 4. GVG and EOS administration led to a significant elevation in the potassium stimulated release of GABA from cross-chopped hippocampal slices compared with that of controls. Although stimulated GABA release from control tissues was decreased in the presence of a low Ca2+ medium, GVG and EOS treatment abolished this Ca2+ dependency. 5. GABA compartmentalization, Na+ and Cl- coupled GABA uptake carriers and glial release may provide explanations for the loss of the Ca2+ dependency of stimulated GABA release observed following GVG and EOS treatment. 6. Administration of GABA-T inhibitors led to increases in both basal and stimulated hippocampal GABA release. However, it is not clear which is the most important factor in the anticonvulsant activity of these drugs, the increased GABA content 'leaking' out of neurones and glia leading to widespread inhibition, or the increase in stimulated GABA release which may occur following depolarization caused by an epileptic discharge.
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PMID:Effect of chronic treatment with the GABA transaminase inhibitors gamma-vinyl GABA and ethanolamine O-sulphate on the in vitro GABA release from rat hippocampus. 935 12

Gamma-aminobutyric acid (GABA), a four-carbon non-protein amino acid, is a significant component of the free amino acid pool in most prokaryotic and eukaryotic organisms. In plants, stress initiates a signal-transduction pathway, in which increased cytosolic Ca2+ activates Ca2+/calmodulin-dependent glutamate decarboxylase activity and GABA synthesis. Elevated H+ and substrate levels can also stimulate glutamate decarboxylase activity. GABA accumulation probably is mediated primarily by glutamate decarboxylase. However, more information is needed concerning the control of the catabolic mitochondrial enzymes (GABA transaminase and succinic semialdehyde dehydrogenase) and the intracellular and intercellular transport of GABA. Experimental evidence supports the involvement of GABA synthesis in pH regulation, nitrogen storage, plant development and defence, as well as a compatible osmolyte and an alternative pathway for glutamate utilization. There is a need to identify the genes of enzymes involved in GABA metabolism, and to generate mutants with which to elucidate the physiological function(s) of GABA in plants.
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PMID:Metabolism and functions of gamma-aminobutyric acid. 1052 26

gamma-Aminobutyric acid (GABA) belongs to main inhibitory neurotransmitters in the central nervous system and activates three types of specific receptors--GABAA, GABAB i GABAC. At present, little is known about GABAC-mediated events. GABAB receptors are metabotropic, whilst stimulation of ionotropic GABAA receptors results in opening the chloride channel, followed by influx of chloride ions and hyperpolarization. The GABAA receptor possesses also binding sites for benzodiazepines and barbiturates which, via these sites, enhance GABAA-mediated events. Another antiepileptic drug potentiating GABA-ergic inhibition is valproate, which increases synthesis of GABA and reduces its metabolism. Among new antiepileptic drugs associated with the GABA-ergic system are tiagabine, vigabatrin, and to a certain degree--gabapentin. Tiagabine blocks neuronal and glial uptake of GABA whilst vigabatrin increases the synaptic concentration of GABA by inhibition of GABA aminotransferase. Gabapentin, probably through the activation of glutamic acid decarboxylase, leads to the increase in synaptic GABA. However, this antiepileptic drugs is also binds to specific sites within voltage-dependent calcium channels, which results in the reduced intraneuronal concentration of calcium ions. Presumably, tiagabine and vigabatrin possess only one mechanism of action, associated with the increased GABA-ergic inhibition. Although topiramate and felbamate were shown to enhance GABA-mediated events, they have additional mechanisms of action, including blockade of voltage-dependent sodium channels and inhibition of glutamatergic neurotransmission.
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PMID:[GABA-ergic system and antiepileptic drugs]. 1076 41

gamma-Aminobutyric acid (GABA) belongs to the main inhibitory neurotransmitters in the central nervous system and activates three types of specific receptors--GABAA, GABAB i GABAC. At present, little is known about GABAC-mediated events. GABAB receptors are metabotropic, whilst stimulation of ionotropic GABAA receptors results in opening the chloride channel, followed by influx of chloride ions and hyperpolarization. The GABAA receptor possesses also binding sites for benzodiazepines and barbiturates which, via these sites, enhance GABAA-mediated events. Another antiepileptic drug potentiating GABA-ergic inhibition is valproate, which increases synthesis of GABA and reduces its metabolism. Among new antiepileptic drugs associated with the GABA-ergic system are tiagabine, vigabatrin, and to a certain degree--gabapentin. Tiagabine blocks neuronal and glial uptake of GABA whilst vigabatrin increases the synaptic concentration of GABA by inhibition of GABA aminotransferase. Gabapentin, probably through the activation of glutamic acid decarboxylase, leads to the increase in synaptic GABA. However, this antiepileptic drug also binds to specific sites within voltage-dependent calcium channels, which results in reduced intraneuronal concentration of calcium ions. Presumably, tiagabine and vigabatrin possess only one mechanism of action, associated with increased GABA-ergic inhibition. Although topiramate and felbamate were shown to enhance GABA-mediated events, they have additional mechanisms of action, including blockade of voltage-dependent sodium channels and inhibition of glutamatergic neurotransmission.
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PMID:[GABA-ergic system and antiepileptic drugs]. 1079 Oct 39

The GABA transporter can reverse with depolarization, causing nonvesicular GABA release. However, this is thought to occur only under pathological conditions. Patch-clamp recordings were made from rat hippocampal neurons in primary cell cultures. Inhibition of GABA transaminase with the anticonvulsant gamma-vinyl GABA (vigabatrin; 0.05-100 microm) resulted in a large leak current that was blocked by bicuculline (50 microm). This leak current occurred in the absence of extracellular calcium and was blocked by the GABA transporter antagonist SKF-89976a (5 microm). These results indicate that vigabatrin induces spontaneous GABA efflux from neighboring cells via reversal of GABA transporters, subsequently leading to the stimulation of GABA(A) receptors on the recorded neuron. The leak current increased slowly over 4 d of treatment with 100 microm vigabatrin, at which time it reached an equivalent conductance of 9.0 +/- 4.9 nS. Blockade of glutamic acid decarboxylase with semicarbazide (2 mm) decreased the leak current that was induced by vigabatrin by 47%. In untreated cells, carrier-mediated GABA efflux did not occur spontaneously but was induced by an increase in [K(+)](o) from 3 to as little as 6 mm. Vigabatrin enhanced this depolarization-evoked nonvesicular GABA release and also enhanced the heteroexchange release of GABA induced by nipecotate. Thus, the GABA transporter normally operates near its equilibrium and can be easily induced to reverse by an increase in cytosolic [GABA] or mild depolarization. We propose that this transporter-mediated nonvesicular GABA release plays an important role in neuronal inhibition under both physiological and pathophysiological conditions and is the target of some anticonvulsants.
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PMID:GABA transaminase inhibition induces spontaneous and enhances depolarization-evoked GABA efflux via reversal of the GABA transporter. 1130 16

gamma-Aminobutyric acid (GABA) is considered to be the major inhibitory neurotransmitter in the brain and loss of GABA inhibition has been clearly implicated in epileptogenesis. GABA interacts with 3 types of receptor: GABAA, GABAB and GABAC. The GABAA receptor has provided an excellent target for the development of drugs with an anticonvulsant action. Some clinically useful anticonvulsants, such as the benzodiazepines and barbiturates and possibly valproic acid (sodium valproate), act at this receptor. In recent years 4 new anticonvulsants, namely vigabatrin, tiagabine, gabapentin and topiramate, with a mechanism of action considered to be primarily via an effect on GABA, have been licensed. Vigabatrin elevates brain GABA levels by inhibiting the enzyme GABA transaminase which is responsible for intracellular GABA catabolism. In contrast, tiagabine elevates synaptic GABA levels by inhibiting the GABA uptake transporter, GAT1, and preventing the uptake of GABA into neurons and glia. Gabapentin, a cyclic analogue of GABA, acts by enhancing GABA synthesis and also by decreasing neuronal calcium influx via a specific subunit of voltage-dependent calcium channels. Topiramate acts, in part, via an action on a novel site of the GABAA receptor. Although these drugs are useful in some patients, overall, they have proven to be disappointing as they have had little impact on the prognosis of patients with intractable epilepsy. Despite this, additional GABA enhancing anticonvulsants are presently under development. Ganaxolone, retigabine and pregabalin may prove to have a more advantageous therapeutic profile than the presently licensed GABA enhancing drugs. This anticipation is based on 2 characteristics. First, they act by hitherto unique mechanisms of action in enhancing GABA-induced neuronal inhibition. Secondly, they act on additional antiepileptogenic mechanisms. Finally, CGP 36742, a GABAB receptor antagonist, may prove to be particularly useful in the management of primary generalised absence seizures. The exact impact of these new GABA-enhancing drugs in the treatment of epilepsy will have to await their licensing and a period of postmarketing surveillance. As to clarification of their role in the management of epilepsy, this will have to await further clinical trials, particularly direct comparative trials with other anticonvulsants.
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PMID:The new generation of GABA enhancers. Potential in the treatment of epilepsy. 1147 40

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