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)

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.
Epilepsy Res Suppl 1996
PMID:Is there a mechanistic basis for rational polypharmacy? 929 30

Vigabatrin (gamma-vinyl GABA) is an antiepileptic drug and blocks GABA transaminase activity resulting in elevations in cellular GABA levels in the brain. Nipecotic acid (NPA) promotes release of GABA from neonatal optic nerve astrocytes, resulting in a bicuculline-sensitive depolarization of the optic nerve axons. The NPA-induced depolarization of vigabatrin-treated rats (100 mg/kg, i.p.) more than doubled, suggesting an elevation in free GABA levels; the GABA transporter inhibitor, NO-711 reduced the depolarization. These results are consistent with the known ability of vigabatrin to block the GABA degradation enzyme GABA-transaminase, suggesting that vigabatrin elevates astrocytic GABA levels, thereby favoring greater release of GABA through the GABA transporter.
Epilepsy Res 1998 Feb
PMID:Vigabatrin enhances promoted release of GABA in neonatal rat optic nerve. 955 81

Kindling is a chronic model of epilepsy characterized by a progressive increase in response to the same regularly applied electrical stimulus. The biological basis of the kindling phenomenon requires to be determined, but several studies indicate that impairment of GABAergic inhibition may be involved. In the present experiments, GABA turnover was determined in vivo by the GABA aminotransferase (GABA-T) inhibition method in 13 brain regions in three groups of rats: (1) a group which was kindled via electrical stimulation of intra-amygdala electrodes and was sacrificed 36 days after the last fully kindled seizure for neurochemical determinations; (2) a group of implanted but non-stimulated rats (sham control group) in which neurochemical measurements were done at the same time after electrode implantation as in the kindled group; and (3) a group of non-implanted, naive control rats. Regional GABA levels were determined after vehicle injection as well as 30 and 90 min after administration of aminooxyacetic acid (AOAA) at a dose which completely inhibits GABA-T. Compared to naive controls, prolonged electrode implantation in the amygdala induced a significant reduction of AOAA-induced GABA accumulation in amygdala, hippocampus, piriform cortex, olfactory bulb, frontal cortex, striatum, hypothalamus, tectum, and cerebellar cortex. In view of the GABA hypothesis of kindling, reduced GABA turnover in response to electrode implantation would suggest that the implantation per se exerts a pro-kindling effect, which was recently demonstrated in rats with intraamygdala electrodes. However, amygdala kindling itself appeared to antagonize the effect of electrode implantation in most regions. Thus, although, compared to naive controls, the predominant change in kindled rats was a decrease in GABA turnover, this decrease was less marked than in sham controls. In thalamus and brainstem kindling markedly increased GABA turnover above the levels determined in both naive and sham controls, possibly in response to impaired postsynaptic GABAergic function. The data indicate that both electrode implantation and kindling significantly alter regional GABA turnover, which might contribute to the pathophysiology of the kindling phenomenon. Furthermore, the data substantiate that the choice of adequate controls is critical in neurochemical and functional studies on the kindling phenomenon.
Epilepsy Res 1999 Nov
PMID:Effect of depth electrode implantation with or without subsequent kindling on GABA turnover in various rat brain regions. 1051 Sep 76

Vigabatrin (VGB) is a novel antiepileptic drug effective as adjunctive therapy in patients with partial seizures. In this study, the efficacy and tolerability of VGB as adjunctive therapy were evaluated in patients with refractory epilepsy. Adult patients with a definite diagnosis of complex partial seizures and/or partial seizures secondarily generalized were recruited from 10 Canadian centres. Patients were randomized to receive either active medication or placebo in a double- blind fashion and entered a 36-week titration and maintenance phase with regularly scheduled visits. Both efficacy parameters and safety assessments were monitored. Clinical laboratory, evoked potential studies, MRI, and neuropsychological tests were also performed. Forty-eight percent of VGB-treated patients vs. 26 percent of placebo-treated patients had a 50 percent or greater reduction in the frequency of complex partial seizures and partial seizures secondarily generalized. Vigabatrin was well tolerated by the majority of patients. Minor neurological side effects were observed in a number of patients in both treatment groups. No serious systemic toxicity was observed. No changes in evoked potential studies or MRI findings were noted. Vigabatrin was found to be an effective and well-tolerated antiepileptic drug when used as adjunctive therapy in patients with difficult to control complex partial seizures and for partial seizures secondarily generalized. Vigabatrin is a selective irreversible inhibitor of the GABA- degradating enzyme GABA transaminase and has shown efficacy in a number of clinical trials in patients with difficult to control partial seizures. Vigabatrin has been found most effective against complex partial and secondarily generalized tonic-clonic seizures in both adults and children. Vigabatrin has also been shown to reduce infantile spasms secondary to various aetiologies and is most effective in spasms associated with tuberous sclerosis. The aim of this study was to further extend the clinical experience with VGB as adjunctive therapy in the treatment of adult patients with difficult to control complex partial seizures and/or partial seizures secondarily generalized. In addition to the assessments of efficacy and tolerability to VGB, neuropsychological evaluations were also carried out.
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PMID:Vigabatrin as add-on therapy for adult complex partial seizures: a double-blind, placebo-controlled multicentre study. The Canadian Vigabatrin Study Group. 1077 31

Human neocortical temporal lobe tissue resected for treatment of pharmacoresistant epilepsy was investigated. In slices prepared from this tissue, epileptiform field potentials (EFP) were induced by omission of magnesium from the artificial cerebrospinal fluid (ACSF). The effects of the gamma-aminobutyric acid transaminase inhibitor vigabatrin on EFP were tested. Vigabatrin exerted a dose-dependent reduction of the repetition rate of EFP: after 3 h of administration of vigabatrin in concentrations of 100 and 200 micromol/l, the repetition rate of EFP was reduced to 35% and 18% of the initial values, respectively. This effect was not reversible. In control experiments with neocortical slices from rats, vigabatrin reduced EFP in a comparable range. The results demonstrate a strong antiepileptic effect of vigabatrin on EFP in tissues from pharmacoresistant epilepsy patients.
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PMID:Vigabatrin reduces epileptiform activity in brain slices from pharmacoresistant epilepsy patients. 1092 22

The mechanism of action of the antiepileptic drug lamotrigine has previously been investigated only in acute experiments and is thought to involve inhibition of voltage-dependent sodium channels. However, lamotrigine is effective against more forms of epilepsies than other antiepileptic drugs that also inhibit sodium channels. We investigated whether chronic lamotrigine treatment may affect cerebral amino acid levels. Rats received lamotrigine, 10 mg/kg/day, for 90 days. The hippocampal level of GABA increased 25%, and the activities of glutamate decarboxylase and succinic semialdehyde/GABA transaminase increased 12 and 21% (p< 0.05), respectively, indicating increased GABA turnover. The uptake of GABA and glutamate into proteoliposomes remained unaltered. The level of taurine increased 27% in the hippocampus and 16% in the frontal and parietal cortices. The activities of hexokinase and alpha-ketoglutarate dehydrogenase, remained at control values. Serum lamotrigine was 41.7+/-1.5 microM (mean+/-S.E.M.), which is within the range seen in epileptic patients. Acute experiments with 5, 20 or 100 mg lamotrigine/kg, caused no changes in brain amino acid levels. The results suggest that chronic lamotrigine treatment increases GABAergic activity in the hippocampus. The cerebral increase in taurine, which has neuromodulatory properties, may contribute to the antiepileptic effect of lamotrigine.
Epilepsy Res 2001 Feb
PMID:Chronic lamotrigine treatment increases rat hippocampal GABA shunt activity and elevates cerebral taurine levels. 1116 4

Gamma vinyl GABA (GVG), an irreversible GABA transaminase inhibitor, has anticonvulsant effects. GVG increases GABA levels in the brain by blocking its degradation, and is presumed to enhance GABAergic inhibition, however, in some cases it exacerbates seizures. We investigated the effects of GVG in vivo and in vitro on paired pulse inhibition (PPI) recorded in the rat dentate gyrus (DG) evoked by perforant path stimulation. At 2.5 h and 24 h after administration of GVG (1 g/kg, i.p.), there was a loss of PPI at both 15- and 25-ms interpulse intervals (IPI). Activation of presynaptic GABA(B) autoreceptors could explain this in vivo effect. We therefore further investigated the effects of co-application of GVG with the GABA(B) antagonists 2-OH saclofen (saclofen) or CGP 35348 (CGP) on PPI in hippocampal slices by in vitro study. Bath application of GVG (400 and 500 microM) not only resulted in a loss of perforant path evoked PPI at a 15-ms IPI, but produced facilitation of the second population spike relative to the first. Co-application of saclofen (250 microM) with GVG (500 microM) prevented facilitation of the second response of a paired-pulse. The facilitation of the second stimulation response produced by GVG (400 microM) was converted to inhibition by bath application of CGP 35348 (400 microM). These results suggest that activation of presynaptic GABA(B) receptors by increased extracellular GABA may be one of the contributing factors to the apparent paradoxical effect of GVG on PPI in the DG.
Epilepsy Res 2001 May
PMID:Gamma-vinyl GABA reduces paired pulse inhibition in the rat dentate gyrus in vivo and in vitro. 1132 67

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

gamma-Aminobutyric acid (GABA), the principal inhibitory neurotransmitter in the cerebral cortex, maintains the inhibitory tone that counterbalances neuronal excitation. When this balance is perturbed, seizures may ensue. GABA is formed within GABAergic axon terminals and released into the synapse, where it acts at one of two types of receptor: GABAA, which controls chloride entry into the cell, and GABAB, which increases potassium conductance, decreases calcium entry, and inhibits the presynaptic release of other transmitters. GABAA-receptor binding influences the early portion of the GABA-mediated inhibitory postsynaptic potential, whereas GABAB binding influences the late portion. GABA is rapidly removed by uptake into both glia and presynaptic nerve terminals and then catabolized by GABA transaminase. Experimental and clinical study evidence indicates that GABA has an important role in the mechanism and treatment of epilepsy: (a) Abnormalities of GABAergic function have been observed in genetic and acquired animal models of epilepsy; (b) Reductions of GABA-mediated inhibition, activity of glutamate decarboxylase, binding to GABAA and benzodiazepine sites, GABA in cerebrospinal fluid and brain tissue, and GABA detected during microdialysis studies have been reported in studies of human epileptic brain tissue; (c) GABA agonists suppress seizures, and GABA antagonists produce seizures; (d) Drugs that inhibit GABA synthesis cause seizures; and (e) Benzodiazepines and barbiturates work by enhancing GABA-mediated inhibition. Finally, drugs that increase synaptic GABA are potent anticonvulsants. Two recently developed antiepileptic drugs (AEDs), vigabatrin (VGB) and tiagabine (TGB), are examples of such agents. However, their mechanisms of action are quite different (VGB is an irreversible suicide inhibitor of GABA transaminase, whereas TGB blocks GABA reuptake into neurons and glia), which may account for observed differences in drug side-effect profile.
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PMID:GABAergic mechanisms in epilepsy. 1152 Mar 15

Gamma-aminobutyric acid (GABA), the major inhibitory neurotransmitter in CNS can elevate level of neuronal excitability by the mechanisms of hyperpolarization. Gabaergic hypothesis of epileptogenesis influenced development of a group of gabamimetic antiepileptic drugs (AEDs). Powerful conventional AEDs barbiturates and benzodiazepines can directly activate GABA-A receptor but their usefulness is limited by development of dependence and tolerance to antiseizure activity. The second generation AEDs have been achieved by a rationale synthesis of compounds that could mimic or augment the activity of endogenous GABA. Vigabatrin (VGB) irreversibly inhibits GABA-T activity, tiagabine (TGB) inhibits GABA-reuptake system (GAT-1) and gabapentin (GPT) enhances GABA turnover in CNS. New drugs with selective and specific influence on GABA neurotransmission are non-toxic and well-tolerated, but some side-effects (aggravation of seizures, visual field deficit and psychotic reactions) seems to be strictly connected with their pharmacodynamic properties. Absence and probably myoclonic seizures noted in about 10% of patients under VGB seems to be the result of disturbed GABA inhibition in thalamic interneurons and non-controlled hyperactivity of excitatory neocortex-thalamus-neocotrex circuits. Perimetric examination might reveal peripheral, persistent binasal visual field deficit in about 30% of patients treated with VGB. This is probably the effect of cytotoxic influence of enormous accumulation of GABA in retinal neurons. Barbiturates and benzodiazepines can exacerbate intellectual functioning and behaviour. Some emotional and reactive disturbances are more characteristic for newer drugs. Serious depressive reactions and psychoses were observed respectively in 12.5 and 2.5% epileptics under VGB and anecdotically after TGB or GPT therapy. Newer selective and specific gabamimetic AEDs play an essential role as add-on therapy of pharmaco-resistant epilepsy, but they did not bring significant qualitive change in the possibilities of pharmacotherapy.
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PMID:[Gabaergic hypothesis of epilepsy and clinical experience: controversial actions of the new generation gabamimetic antiepileptic drugs]. 1178 May 94


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