GABA对小鼠大脑皮质中GABA受体胚胎发育的调节

本文用ＧＡＢＡ及其受体激动剂和拮抗剂处理培养的胚胎小鼠大脑皮层神经细胞以及精确计时的妊娠小鼠,用放射配体结合法检测ＧＡＢＡＡ及ＧＡＢＡＢ的结合位点数目,研究了ＧＡＢＡ对小鼠大脑皮层ＧＡＢＡ受体胚胎发育的调节作用,结果表明：①ＧＡＢＡ可使培养１５—１７天妊龄的胚胎小鼠大脑皮层神经细胞及出生第１天的仔鼠大脑皮层中的ＧＡＢＡＡ及ＧＡＢＡＢ受体数目增加,这种作用可被蝇蕈醇（Ｍｕｓ）及巴氯芬（Ｂａｃ）分别模拟,对ＧＡＢＡＡ受体的作用可为荷包牡丹碱（Ｂｉｃ）所阻断;②用ＧＡＢＡ处理妊娠７—１３天的小鼠,仔鼠出生第１天其大脑皮层的ＧＡＢＡＡ及ＧＡＢＡＢ受体数目均无变化;③用ＧＡＢＡ处理妊娠１４—１９天的小鼠,仔鼠出生的第１天其大脑皮层中的ＧＡＢＡＡ受体数目增加而ＧＡＢＡＢ受体数目不变;④用ＧＡＢＡ处理妊娠７－１９天的小鼠,仔鼠出生第１天其大脑皮层中ＧＡＢＡＡ及ＧＡＢＡＢ受体数目增加。这说明在胚胎发育的特定时期内,ＧＡＢＡ可诱导其受体数目的增加,这个作用是由ＧＡＢＡ受体调节的。     

Amino acid uptake by neurones and glial cells from embryonic cockroach brain growing in vitro

Insect neuronal cultures and glial-enriched cultures derived from the brains of embryonic cockroaches have been used to investigate the uptake of putative amino acid neurotransmitters. Some neurones and all of the glia in these cultures possess uptake systems for [³H]l-glutamate and [³H]GABA. The neuronal and glial uptake of l-glutamate is reduced by d-aspartate. Neuronal accumulation of [³H]GABA is reduced by nipecotic acid but is not inhibited by β-alanine and DABA, whereas DABA is the most potent inhibitor of GABA accumulation by glia. The cockroach glial cells did not accumulate taurine, glycine, d-aspartate or leucine but there was some neuronal uptake of both taurine and glycine although this was insensitive to sodium ions.     

Development of a high-affinity GABA uptake system in embryonic amphibian spinal neurons

High-affinity uptake systems for amino acid neurotransmitter precursors have been highly correlated with the use of the particular amino acid or its derivative as a transmitter. We have found interneurons in the Xenopus embryo spinal cord which accumulate GABA by a high-affinity uptake system. They originate near the end of gastrulation and their ability to accumulate GABA first appears at the early tail bud stage. By position and appearance they are comparable to some of the embryonic interneurons described by A. Roberts and J. D. W. Clarke (1982, Phil. Trans. R. Soc. London Ser. B 296, 195-212). GABA-accumulating neurons also develop in dissociated cell cultures made from the presumptive spinal cord of neural plate stage Xenopus embryos. GABA accumulation in cultured neurons, as in cells in vivo, occurs via a high-affinity uptake system; GABA-accumulating cells have the same time of origin as the cells in vivo, and the ability to accumulate GABA in the population of cultured neurons appears at a time equivalent to that observed in intact sibling embryos. Thus it seems likely that the population of GABA-accumulating neurons developing in cell culture corresponds to the GABA-accumulating interneurons in vivo. The development of these neurons in dissociated cell cultures permits perturbation experiments that would be difficult to perform in vivo. We have examined the development of high-affinity GABA uptake in conditions that permit no electrical impulse activity in the cultures. The onset and extent of development of GABA accumulation in the neuronal population are normal under these conditions.     

Developmental change of an enzyme activity oxidizing γ-aminobutyraldehyde to γ-aminobutyric acid in the chick embryonic brain

An enzyme activity oxidizing -aminobutyraldehyde (ABAL) to GABA reflecting an alternative pathway for GABA synthesis was assayed in the developing chick embryonic brain and was compared with glutamate decarboxylase (GAD) activity. An enzyme activity oxidizing ABAL to GABA showed almost constant level during development in the chick embryonic brain, and was present at low levels compared with GAD activity. The results indicate that GABA synthesis via an alternative pathway is always much less than synthesis via the GAD-dependent pathway in the developing chick embryonic brain.     

Presence of gamma-aminobutyric acid in embryonic palates of AJ and SWV mouse strains

The presence of gamma-aminobutyric acid (GABA) in the embryonic palate was sought as a criterion for its role in regulating palate development. GABA was measured by a gas chromatographic-mass spectrometric (GC-MS) method using the heptafluorobutyryl (HFB)-cyclohexyl-GABA derivative, which gave the necessary sensitivity and specificity to measure low levels of GABA in the presence of contaminating substances. GABA was measured in dissected embryonic palates at various times of development in the AJ mouse strain. GABA levels were lower in day 14 AJ palates (0.19 +/- 0.01 nmol/mg protein) than at days 13 (0.28 +/- 0.03) and 15 (0.30 +/- 0.04). Comparable levels were observed in fore- and hindlimbs at day 14, whereas levels were lower in embryonic tongue and higher, as was expected, in embryonic brain. To confirm the presence of GABA in the palate, it was analyzed in growing palate mesenchymal cells in primary and secondary cultures as well as in serum-free medium. In addition, GABA levels were compared in the SWV mouse strain; this strain exhibits a more efficient active uptake mechanism and diazepam produces a higher frequency of cleft palate in this strain than in AJ. SWV contained one and one-half to three times higher concentrations of GABA in excised palates and cultured palate cells than the AJ strain. Furthermore, when GABA levels in skin fibroblasts of the two strains were measured, SWV cells contained 2.7-fold greater GABA than AJ cells. The present results provide additional evidence for the role of GABA in palate development.     

GABA signalling during development: new data and old questions

In addition to being the major inhibitory neurotransmitter, gamma-aminobutyric acid (GABA) is thought to play a morphogenetic role in embryonic development. During the last decade, considerable progress has been made in elucidating the molecular mechanisms involved in GABA synthesis and biological action. The present review is an attempt to summarise recent results on the ontogeny of the different components of embryonic GABA signalling with an emphasis on the synthesis of GABA by different molecular forms of glutamic acid decarboxylase (GAD).     

EFFECT OF DIAZEPAM AND PENTOBARBITAL ON AMINOOXYACETIC ACID-INDUCED ACCUMULATION OF GABA

Abstract— The effect of diazepam and pentobarbital on γ-aminobutyric acid (GABA) levels, the aminooxyacetic acid (AOAA)-induced accumulation of GABA, and the in vitro activity of l -glutamate 1-carboxyl-lyase (EC 4.1.1.15) [GAD] were studied in various regions of rat brain. Diazepam increased GABA levels in the substantia nigra, diminished the AOAA-induced accumulation of GABA in the caudate nucleus, cingulate, parietal and entorhinal cortex and had no effect on GABA accumulation in the pyriform and cerebellar cortex. After pentobarbital, GABA levels were elevated in the caudate nucleus but decreased in the parietal and pyriform cortex; the AOAA-induced accumulation of GABA also diminished in all cortical regions studied. No correlation was found between the apparent changes in GABA synthesis, as estimated by accumulation after inhibition of 4-aminobutyrate-2-oxoglu-tarate (EC 2.6.1.19) [GABA-T] with AOAA, and the changes in GABA levels induced by these drugs. The reduction in AOAA-induced GABA accumulation after diazepam and pentobarbital treatment was most pronounced in regions which showed the greatest accumulation of GABA after AOAA administration. Neither diazepam nor pentobarbital administration affected the activity of GAD in homogenates of cingulate cortex. Chlorpromazine, at a dose which decreased spontaneous activity, enhanced the AOAA-induced GABA accumulation in the cingulate cortex, suggesting that drug-induced sedation is not necessarily associated with decreased GABA synthesis. While regional differences were observed in the effects of diazepam and pentobarbital on GABA synthesis, both agents appear to inhibit GABA synthesis in vivo and both do so, in at least some brain areas, at subsedative doses.     

Gamma-aminobutyrate: defense against invertebrate pests?

Gamma-aminobutyrate (GABA) is a ubiquitous four-carbon, non-protein amino acid. In plants, stress-induced GABA accumulation is well documented. However, the role(s) of GABA accumulation is contentious. In this Opinion article, we argue that wounding due to herbivory and crawling by insect larvae causes rapid GABA accumulation via the disruption of cellular compartmentation and the release of the acidic vacuolar contents to the cytosol. The activity of glutamate decarboxylase, the cytosolic enzyme responsible for GABA synthesis, has an acidic pH optimum. Subsequent GABA ingestion has a plant defense function by directly acting on GABA-regulated invertebrate neuromuscular junctions. Plants with an enhanced GABA-producing capacity reduce herbivory by invertebrate pests. These findings suggest that GABA accumulation is a rapidly deployed, local resistance mechanism that constitutes a first line of defense in deterring herbivory.     

Higher accumulation of gamma-aminobutyric acid induced by salt stress through stimulating the activity of diamine oxidases in Glycine max (L.) Merr. roots.

Polyamines (PAs) are assumed to perform their functions through their oxidative product such as gamma-aminobutyric acid (GABA) formation. However, there is only limited information on the interrelation between PA degradation and GABA accumulation under salt stress. In order to reveal a quantitative correlation between PA oxidation and GABA accumulation, the effects of treatments with different NaCl concentrations, along with aminoguanidine (AG, a specific inhibitor of diamine oxidases (DAO; EC: 1.4.3.6)) and a recovery test from salt stress on endogenous free PAs, gamma-aminobutyric acid (GABA) accumulation and DAO activity were determined in roots of soybean [Glycine max (L.) Merr.] cultivar Suxie-1. The results showed that the levels of putrescine (Put), cadaverine (Cad), and spermidine (Spd) decreased significantly with increasing salt concentrations. This occurred because salt stress strongly promoted DAO activity to stimulate PA degradation. GABA accumulation increased with growing NaCl concentrations, about an 11- to 17-fold increase as compared with the control plants. AG treatment increased the accumulation of endogenous free PAs as a result of a strong retardation of DAO activity, but decreased GABA accumulation. The recovery for 6 days in 1/2 Hoagland solution from 100mM NaCl stress resulted in a decrease in DAO activity, a rebound of PA levels and a simultaneous reduction of GABA content. A close correlation was observed between the changes in DAO activity and GABA accumulation. The results indicated that higher GABA accumulation (about 39%) induced by salt stress could come from PA degradation, suggesting that PAs might perform their functions through GABA formation under salt stress.     

Intracerebral injection of gamma vinyl GABA: Method for measuring rates of GABA synthesis in specific brain regions invivo

In order to obtain an index of the rate of GABA synthesis in different rat brain regions, we examined the rate of accumulation of GABA after irreversible inhibition of GABA-transaminase. Gamma-vinyl-GABA (GVG), a catalytic inhibitor of GABA-transaminase, was microinjected directly into each of four brain areas: superior colliculus (SC), substantia nigra (SN), frontal cortex (CTX) and caudate-putamen (CP). The subsequent rate of GABA accumulation was linear for at least 90 min in all regions, and was found to be 2–3 times higher in the SC and SN than in the CTX and CP. The nerve terminal contribution to the initial rate of GABA accumulation after GVG was determined by comparing values obtained in the intact SN with those obtained in the SN in which the GABAergic afferent terminals had been destroyed. The initial rate of GABA accumulation in the denervated SN was less than one-half of that measured in the intact SN, indicating that, under normal conditions, both nerve-terminal and non-nerve-terminal (perikarya, glia) compartments contribute to the rate of GABA accumulation after GABA-transaminase inhibition. Our results indicate that the intracerebral injection of GVG is a sensitive and reliable method for studying $\text{in}\text{vivo}$ GABA synthesis in brain. Although the rate of GABA accumulation after GVG is sensitive to changes in the nerve terminal compartment, other GABA compartments may also influence these measurements.     

GABA accumulation causes cell elongation defects and a decrease in expression of genes encoding secreted and cell wall-related proteins in Arabidopsis thaliana

GABA (γ-aminobutyric acid), a non-protein amino acid, is a signaling factor in many organisms. In plants, GABA is known to accumulate under a variety of stresses. However, the consequence of GABA accumulation, especially in vegetative tissues, remains poorly understood. Moreover, gene expression changes as a consequence of GABA accumulation in plants are largely unknown. The pop2 mutant, which is defective in GABA catabolism and accumulates GABA, is a good model to examine the effects of GABA accumulation on plant development. Here, we show that the pop2 mutants have pollen tube elongation defects in the transmitting tract of pistils. Additionally, we observed growth inhibition of primary root and dark-grown hypocotyl, at least in part due to cell elongation defects, upon exposure to exogenous GABA. Microarray analysis of pop2-1 seedlings grown in GABA-supplemented medium revealed that 60% of genes whose expression decreased encode secreted proteins. Besides, functional classification of genes with decreased expression in the pop2-1 mutant showed that cell wall-related genes were significantly enriched in the microarray data set, consistent with the cell elongation defects observed in pop2 mutants. Our study identifies cell elongation defects caused by GABA accumulation in both reproductive and vegetative tissues. Additionally, our results show that genes that encode secreted and cell wall-related proteins may mediate some of the effects of GABA accumulation. The potential function of GABA as a growth control factor under stressful conditions is discussed.     

Gamma Aminobutyric Acid (GABA) and Plant Responses to Stress

4-aminobutyrate (GABA) is a non-protein amino acid that is widely distributed throughout the biological world. In animals, GABA functions as the predominant inhibitory neurotransmitter in the central nervous system by acting through the GABA receptors. The neuromuscular system enables animals to escape from environmental stresses. Being nonmotile, plants have evolved chemical responses to mitigate stress. Mechanisms by which GABA may facilitate these responses are discussed in this review. Environmental stresses increase GABA accumulation through two different mechanisms. Stresses causing metabolic and/or mechanical disruptions, resulting in cytosolic acidification, induce an acidic pH-dependent activation of glutamate decarboxylase and GABA synthesis. Extremely marked declines in cytosolic pH occur under oxygen deprivation, which is the primary stress factor in flooded soils, and this stress induces the greatest accumulation of GABA. Other stresses, including cold, heat, salt, and mild or transient environmental factors, such as touch, wind, rain, etc. rapidly increase cellular levels of Ca²⁺. Increased cytosolic Ca²⁺ stimulates calmodulin-dependent glutamate decarboxylase activity and GABA synthesis. A review of the kinetics of GABA accumulation in plants reveals a stress-specific pattern of accumulation that is consistent with a physiological role for GABA in stress mitigation. Recent physiological and genetic evidence indicates that plants may possess GAB A-like receptors that have features in common with the animal receptors. The mechanism of action of animal GABA receptors suggests a model for rapid amplification of ion-mediated signals and GABA accumulation in response to stress. Metabolic pathways that link GABA to stress-related metabolism and plant hormones are identified. The survival value of stress-related metabolism is dependent on metabolic changes occurring before stress causes irreversible damage to plant tissue. Rapid accumulation of GABA in stressed tissue may provide a critical link in the chain of events leading from perception of environmental stresses to timely physiological responses.     

Importance of Glutamine for γ-Aminobutyric Acid Synthesis in Rat Neostriatum In Vivo

This work was carried out to evaluate the importance of glial cells in providing precursors for the in vivo synthesis of gamma-aminobutyric acid (GABA). Fluorocitrate, which selectively inhibits the tricarboxylic acid cycle in glial cells, was administered locally in rat neostriatum. Inhibition of the glial cell tricarboxylic acid cycle led to a decrease both in glutamine level and in gamma-vinyl GABA (GVG)-induced GABA accumulation, an observation indicating reduced GABA synthesis. The role of glutamine, which is synthesized in glial cells as a precursor for GABA, was further investigated by inhibition of glutamine synthetase with intrastriatally administered methionine sulfoximine. In this case, the glutamine level was reduced to near zero values, and the GVG-induced GABA accumulation was only half that of normal. The results show that glutamine is an important precursor for GABA synthesis, but it cannot be the sole precursor because it was not possible to depress the GVG-induced GABA accumulation completely.     

Kinetic analysis of the accumulation of γ-aminobutyric acid by particulate fractions of rat brain:

Kinetic analyses indicate that nipecotic acid and cis-3-aminocyclohexane-1-carboxylic acid (cis-3-ACHC) inhibit GABA accumulation by similar mechanisms of action. Both amino acids are competitive inhibitors of particulate GABA accumulation when GABA and the inhibitor are added simultaneously to tissue fractions. However, preincubating the tissue with either amino acid produces noncompetitive inhibition of GABA accumulation at low concentrations of inhibitor and mixed inhibition at higher concentrations. The possible roles of intrasynaptosomal mechanisms and of astroglia in producing these effects are discussed. The most notable difference between cis-3-ACHC and the other amino acid inhibitors of GABA accumulation, such as nipecotic acid, cis-4-OH-nipecotic acid, guvacine, beta-proline, homo-beta-proline, and 2,4-diaminobutyric acid (DABA), is that cis-3-ACHC is approximately 3.5 times more potent as an inhibitor following preincubation. Thus, while cis-3-ACHC does inhibit GABA transport, its major site of action in the synaptosome may be intracellular.     

POST-MORTEM AND AMINOOXYACETIC ACID-INDUCED ACCUMULATION OF GABA: EFFECT OF GAMMA-BUTYROLACTONE AND PICROTOXIN

Abstract— The effects of γ-butyrolactone (GBL) and picrotoxin on both the post-mortem and amino-oxyacetic acid (AOAA) induced accumulations of γ-aminobutyric acid (GABA) were examined in rats. GBL produced a marked dose-dependent decrease in AOAA-induced GABA accumulation in caudate. globus pallidus, cerebellar and cerebral cortices. The cingulate cortex showed the greatest response to GBL treatment; subanesthetic doses completely blocked the effect of AOAA. Picrotoxin increased the AOAA-induced accumulation of GABA in parietal, entorhinal and cerebellar cortices, and had no significant effect in pyriform or cingulate cortices. Neither drug significantly altered the post-mortem accumulation of GABA. Results suggest that picrotoxin, a GABA antagonist and convulsant drug, causes an increase in GABA synthesis in vivo. The apparent decrease in GABA synthesis following GBL treatment was greater than that observed with anesthetic doses of chloral hydrate and was not blocked by picrotoxin. Alterations in the activity of GABA neurons, cerebral glucose metabolism and GAD activity may contribute to the apparent decrease in in vivo GABA synthesis caused by GBL.     

Accumulation of gamma-aminobutyric acid in the halotolerant cyanobacterium <Emphasis Type="Italic">Aphanothece halophytica</Emphasis> under salt and acid stress

γ-Aminobutyric acid (GABA) is known as an inhibitory neurotransmitter in human, while in plants, GABA is an intermediate for amino acid metabolism and also is accumulated in response to a wide range of environmental stress. In the present study, GABA accumulation in Aphanothece halophytica was increased 2-fold in mid-log phase cells grown under salt stress (2.0 M NaCl). When mid-log phase cells were subjected to changes in NaCl concentrations and pH for 4 h, the highest GABA accumulation was observed in cells adapted in medium that contained 2.0 M NaCl and that was adjusted to pH 4.0, respectively. The increase of GABA accumulation was accompanied by an increased glutamate decarboxylase activity. Addition of glutamate to growth medium stimulated GABA accumulation under acid stress but had no effect under salt stress. However, the highest GABA accumulation was detected in cells exposed to both high salt and acid stresses combined with the 5 mM glutamate supplementation with an approximately 3-fold increase as compared to the control. The unicellular A. halophytica showed a similarly high content of GABA to that of a filamentous Arthrospira platensis suggesting the possibility of genetic manipulation of the genes of A. halophytica involved in GABA synthesis to increase GABA yield.     

Acute and long-lasting effects of peripheral injection of caerulein and CCK-8 on the central GABAergic system in mice

Acute and long-lasting effects of peripheral injection of caerulein (CLN) and cholecystokinin octapeptide (CCK-8) on the gamma-aminobutylic acid (GABA) content and the GABA accumulation by aminooxyacetic acid (AOAA) in the discrete brain regions of mice were examined. The content and accumulation of GABA in the striatum, hypothalamus, and frontal cortex was measured with high performance liquid chromatography with electrochemical detection (HPLC-ECD). The GABA content slightly decreased in the striatum 60 min after CLN and CCK-8 were administered, whereas it slightly increased in the hypothalamus and frontal cortex. Moreover, with CLN and CCK-8, the GABA accumulation after AOAA treatment decreased in the striatum and hypothalamus 30 min after injection. Meanwhile, when administering CLN, the GABA content as well as the GABA accumulation after AOAA treatment increased in the striatum and frontal cortex 1 day after injection, and continued to increase the second and third day in the striatum. These results showed that peripheral injection of CLN and CCK-8 had effects on the central GABAergic system with local specific actions, and also the long-lasting and time-dependent biphasic effects of CLN.     

The use of 3H-gamma-aminobutyric acid for transport studies with isolated nerve-terminals from rat brain

Isolated synaptosomes were used to study the problem of net accumulation of neurotransmitters. The time-course and the kinetics of exogenous and endogenous GABA transport were studied by liquid-scintillation counting and HPLC-amino acid analysis respectively. Different pools of GABA were suggested by a 6-fold difference in tissue-to-medium-ratio of endogenous vs. exogenous GABA. Net accumulation, exchange and net efflux of GABA was found to be a function of the GABA concentration in the incubation medium. The Kms for net accumulation and for 3H-GABA accumulation were 2.68 +/- 1.16 and 6.19 +/- 1.26 microM respectively, whereas the Vmaxs were 5.9 +/- 4.9 and 134 +/- 13 pmol/mg w.w. min respectively. This means that the transport studies which use exogenous substances (e.g. 3H-GABA) considerably overestimate the transport by overlooking the magnitude of the counter transport.     

The Use of Inhibitors of GABA-Transaminase for the Determination of GABA Turnover in Mouse Brain Regions: An Evaluation of Aminooxyacetic Acid and Gabaculine

Abstract: The accumulation of γ -aminobutyric acid (GABA) after inhibition of GABA-T (4-aminobutyrate: 2-oxoglutamate aminotransferase, EC 2.6.1.19) by various doses of aminooxyacetic acid (AOAA) and gabaculine was studied in four different regions of the mouse brain. The dose-response curve for GABA accumulation after treatment with AOAA was linear up to 10 mg/kg i.p., and then leveled off. The increase in GABA accumulation after gabaculine treatment was linear up to 100 mg/kg i.p. No further increase was observed with doses up to 300 mg/kg i.p. The selectivity of both GABA-T inhibitors was assessed by measuring their effects on the content of free amino acids in mouse brain. Apart from the substantial increase in the GABA concentration, there were significant decreases in the content of glutamic acid, aspartic acid, alanine and glutamine, and an increase in ornithine content after administration of gabaculine. The same changes in amino acid content were observed after treatment with AOAA, but the level of lysine was also increased and the change in alanine level was biphasic. All these changes, however, were very small compared with the large increase in GABA level. A method for estimating the rate of the GABA turnover in vivo by measuring the initial rate of GABA accumulation after administration of AOAA or gabaculine is proposed, and the validity of the two techniques is discussed. The effect of diazepam on GABA levels and on the gabaculine-induced accumulation of GABA was studied. The results obtained with diazepam show that this method can provide valuable insight into the effects of drugs on GABAergic mechanisms in vivo.