Effect of aminooxyacetic acid on the release of preloaded [3H]GABA and radioactive metabolites from slices of developing mouse brain

The release of [³H]-aminobutyric acid (GABA) and its radioactive metabolites from slices of the cerebral cortex, cerebellum, striatum and brain stem of developing and adult mice was studied. The slices were incubated and superfused in the absence and presence of the GABA aminotransferase (GABA-T) inhibitor aminooxyacetic acid (AOAA). Exposure to 100 M AOAA totally inhibited GABA-T and all radioactivity released from slices was in authentic GABA. In studies on developing brain the 10-M concentration was also effective enough, except in cerebellar slices. In the absence of AOAA the major part of radioactivity spontaneously released from slices of adult cerebral cortex and cerebellum was tritiated water and still about one third part in the presence of 10 M AOAA. Potassium stimulation induced only the release of radioactive GABA but not labeled metabolites in both presence and absence of AOAA. AOAA reduced the stimulation-induced release of GABA. It is recommended that the use of GABA-T inhibitors should be discontinued in release experiments. Then labeled GABA must be separated in the effluents from its radioactive breakdown products.     

Depolarization elicits,while hyperpolarization blocks uptake of endogenous glutamate by retinal horizontal cells of the turtle

We have employed an immunoreaction against glutamate to qualitatively demonstrate varying levels of glutamate in retinal horizontal cells of the turtle. Glutamate-like immunoreactivity (GLI) in horizontal cells could be demonstrated after glutamate decarboxylase was inhibited by aminooxy acetic acid (AOAA) and its degradation to GABA was blocked. Depolarization of horizontal cells by kainic acid (KA) induces strong glutamate immunoreactivity in these cells, whereas hyperpolarization by 2,3-cis piperidine dicarboxylate (PDA) abolishes glutamate-like immunoreactivity in horizontal cells. When glutamate release from cones and bipolar cells is blocked in the absence of calcium, or when glutamate uptake is blocked by DL-threo -hydroxy aspartate, KA/AOAA treatment of the retina does not induce GLI in horizontal cells. Our data show that horizontal cells are capable of taking up glutamate from the endogenous retinal pool in an activity dependent way. Our interpretation of these findings is that retinal horizontal cells are capable of regulating glutamate levels in the extracellular space of the cone pedicle complex by an activity-dependent uptake system. We suggest that inhibition of glutamate uptake upon hyperpolarization rather than inhibition of GABA release may evoke the antagonistic surround response of retinal bipolar cells.     

Evidence for net uptake of GABA into mouse astrocytes in primary cultures—Its sodium dependence and potassium independence

Content of GABA was measured in cultured, normal astrocytes (from the brain cortex of newborn mice) together with the effect of nonradioactive GABA on the efflux of labeled GABA from cells previously loaded with [¹⁴C]GABA. An increase of external GABA concentration from 0 to 25 M evoked a rise of the GABA content in the cells to a level which was approximately 50 times that of the incubation medium. Neither 200 nor 2000 M nonradioactive GABA had any effect on the rate of release of radioactivity from cells loaded with [¹⁴C]GABA. Both the high tissue/medium ratio and the lack of a GABA-induced enhancement of the release of radioactivity indicate that the previously observed high-affinity uptake of GABA in cultured astrocytes represents a net uptake and not a homoexchange with endogenous GABA. This uptake is sodium dependent but was found to be unaffected in potassium-free media; the quantitative correlation between GABA transport and sodium transport differed from that reported for synaptosomes.     

The proliferation of adrenal medullary cells in newborn and adult mice

Summary The proliferative activity of newborn and adult mouse adrenal medullary cells was determined with light and electron microscopic autoradiography. The H³ thymidine labelling index of 2 weeks old mice adrenal medullary cells was about 9.4 % and declined to less than 1 % in adult mice. In electron microscopic autoradiography labelled norepinephrine as well as epinephrine cells could be seen. Only in 1 and 2 weeks old mice some morphologically undifferentiated cells were visible. In formaldehyde induced fluorescence combined with light microscopic autoradiography the fluorescence intensities of labelled and unlabelled medullary cells were measured. On average the fluorescence intensity of labelled cells was lower than that of unlabelled cells. The differences could be explained by a higher number of autoradiographic silver grains laying on the cytoplasm of labelled cells. These results give evidence that fully differentiated adrenal medullary cells are capable of division.This study was supported by Jubiläumsfonds der Österreichischen Nationalbank grant No. 818     

Immunohistochemical and histochemical evidence for the presence of noradrenaline,serotonin and gamma-aminobutyric acid in chief cells of the mouse carotid body

The immunohistochemical study revealed tyrosine hydroxylase (TH), dopamine -hydroxylase (DBH), phenylethanolamine N-methyltransferase (PNMT), serotonin, glutamate decarboxylase (GAD) and -aminobutyric acid (GABA) immunoreactivities in the mouse carotid body. TH and DBH immunoreactivities were found in almost all chief cells and a few ganglion cells, and in relatively numerous varicose nerve fibers of the carotid body. The histofluorescence microscopy showed catecholamine fluorescence in almost all chief cells. However, no PNMT immunoreactivity was observed in the carotid body. Serotonin, GAD and GABA immunoreactivities were also seen in almost all chief cells of the carotid body. From combined immunohistochemistry and fluorescence histochemistry, catecholamine and serotonin or catecholamine and GABA were colocalized in almost all chief cells. Thus, these findings suggest that noradrenaline, serotonin and GABA may be synthesized and co-exist in almost all chief cells of the mouse carotid body and may play roles in chemoreceptive functions.     

Morphological and functional changes in the tight junctions of the bile canaliculi induced by bile duct ligation

Summary Thin sections after bile duct ligation showed that the depth of tight junctions appeared to increase and that the distance between individual punctate contacts appeared to become irregular and wider than in controls. The freeze fracture replicas clearly demonstrated these changes in the tight junction morphology. Changes were noted most conspicuously in the tight junction three weeks after ligation. Measurements of the junctional morphology in control and ligated specimens showed that the junctional depth had increased two fold in the latter, whereas the number of strands had scarcely changed. Lanthanum tracer experiments showed that the tight junctions did not permit the passage of the tracer in normal nor ligated rats. It was concluded that the mechanism of obstructive jaundice could not be related to changes in junctional morphology causing increased junctional permeability.Tight junction depth in this paper is synonymously used with Tight junction width or Tight junction thickness     

Use of Inhibitors of γ-Aminobutyric Acid (GABA) Transaminase for the Estimation of GABA Turnover in Various Brain Regions of Rats: A Reevaluation of Aminooxyacetic Acid

The technique of estimating gamma-aminobutyric acid (GABA) turnover by inhibiting its major degrading enzyme GABA-T (4-aminobutyrate:2-oxoglutarate aminotransferase; EC 2.6.1.19) and measuring GABA accumulation has been used repeatedly, but, at least in rats, its usefulness has been limited by several difficulties, including marked differences in the degree of GABA-T inhibition in different brain regions after systemic injection of GABA-T inhibitors. In an attempt to improve this type of approach for measuring GABA turnover, the time course of GABA-T inhibition and accumulation of GABA in 12 regions of rat brain has been studied after systemic administration of aminooxyacetic acid (AOAA), injected at various doses and with different routes of administration. A total and rapidly occurring inhibition of GABA-T in all regions was obtained with intraperitoneal injection of 100 mg/kg AOAA, whereas after lower doses, marked regional differences in the degree of GABA-T inhibition were found, thus leading to underestimation of GABA synthesis rates, e.g., in substantia nigra. The activity of the GABA-synthesizing enzyme GAD (L-glutamate-1-decarboxylase; EC 4.1.1.15) was not reduced significantly at any time after intraperitoneal injection of AOAA, except for a small decrease in olfactory bulbs. Even the highest dose of AOAA tested (100 mg/kg) was not associated with toxicity in rats, but induced motor impairment, which was obviously related to the marked GABA accumulation found with this dose. The increase in GABA concentrations induced with intraperitoneal injection of 100 mg/kg AOAA was rapid in onset, allowing one to estimate GABA turnover rates from the initial rate of GABA accumulation, i.e., during the first 30 min after AOAA injection. GABA turnover rates thus determined were correlated in a highly significant fashion with the GAD activities determined in brain regions, with highest turnover rates measured in substantia nigra, hypothalamus, olfactory bulb, and tectum. Pretreatment of rats with diazepam, 5 mg/kg i.p., 5-30 min prior to AOAA, reduced the AOAA-induced GABA accumulation in all 12 regions examined, most probably as a result of potentiation of postsynaptic GABA function. The data indicate that AOAA is a valuable tool for regional GABA turnover studies in rats, provided the GABA-T inhibitor is administered in sufficiently high doses to obtain complete inhibition of GABA degradation.     

THE EFFECT OF AMINO-OXYACETIC ACID ON BRAIN CATECHOLAMINES

Abstract— —Administration of amino-oxyacetic acid (AOAA) to rats induced a pronounced decrease of midbrain norepinephrine (NE) and adrenal epinephrine (E) after 30 min, at which time the GABA level of midbrain had increased to 117 per cent of the initial value. The concentrations of NE in the pons-medulla and of dopamine (DA) in the cerebral hemispheres were not changed.
Further increases in brain GABA were accompanied by a rise of NE in midbrain and pons-medulla beginning 1 hr after AOAA administration. A rise of cerebral DA level was observed only after 4 hr. Six hours after AOAA administration the levels of both NE and DA in brain were reduced.
From the results of these and other studies, where administration of small amounts of GABA were shown to affect brain NE and serotonin levels, it is suggested that monoamines may be involved in the physiological action of GABA in the brain.     

EFFECTS OF METABOLIC INHIBITORS ON AMINO ACID METABOLISM IN RAT RETINA: A COMPARISON OF AMINO-OXYACETIC ACID AND ETHANOLAMINE-O-SULPHATE

Abstract— The abilities of AOAA and EOS to modify the utilisation of radioactively labelled glucose, acetate, glutamine and GABA were studied in isolated rat retina. AOAA inhibited the activities of GAD and GABA-T, while EOS inhibited GABA-T but not GAD. AOAA lowered the free amino acid contents of incubated retinae and suppressed the outflow of amino acids into the incubation medium, while EOS had no effect on either parameter. AOAA strongly inhibited the incorporation of ¹⁴C from labelled glucose, acetate and glutamine into GABA, and also suppressed the labelling of glutamate, aspartate and glutamine. These effects were qualitatively similar but quantitatively smaller with EOS. Both compounds markedly decreased the syntheses of aspartate and glutamate from exogenous GABA, while the passage of carbon from GABA to glutamine was much less affected. It is suggested that AOAA and EOS may act predominantly on neurones. It appears that inhibition of GABA-T alone does not cause a profound disturbance of the metabolism of other amino acids. Other metabolic inhibitors such as ouabain, malonate and fluoroacetate did not greatly affect the metabolism of GABA in rat retina.     

Cellular compartments of GABA in brain and their relationship to anticonvulsant activity

Summary The effects of GABA-elevating agents were examined with respect to the cellular compartments in which GABA increases occurred and the brain region(s) that mediate the anticonvulsant activity of these compounds. Changes in GABA occurring in the presence and absence of GABAergic nerve terminals were estimated in vivo using rats in which the GABA projection to the substantia nigra (SN) was destroyed on one side of the brain. One week post-operatively, the GABA concentration in the denervated SN was 10–20% of control. The net increase in GABA content of the denervated SN was compared to that of the intact SN after intraperitoneal injection of amino-oxacetic acid (AOAA), di-n-propylacetate (DPA) and -vinyl GABA (GVG). In the intact SN, all drugs produced significant increases in GABA. In the denervated SN, both AOAA and GVG produced marked increases in GABA (nearly equivalent to those obtained in the intact SN) whereas DPA was without effect. It therefore appears that the DPA-induced elevation of GABA depends upon the presence of GABAergic nerve terminals whereas AOAA and GVG primarily elevate GABA in non-nerve terminal compartments. An increase in GABA associated with nerve terminals was obtained with GVG only after a latency of more than 12 h following a single injection. The time course of elevation of nerve terminal-associated GABA coincided with the time course of anticonvulsant action of GVG; both effects were maximal at 60 h after a single injection. Taken together, our results indicate that the ability of DPA, AOAA and GVG to protect against chemically- and electrically-induced seizures is directly correlated with increases in nerve terminal GABA and not related to increases in other GABA compartments.Localization of the anatomical site that mediates anticonvulsant activity was examined using intracerebral injections of GVG into fore-, mid-and hindbrain areas. Blockade of tonic hindlimb extension in the maximal electroshock test and blockade of tonic and clonic seizures produced by pentylenetetrazol and bicuculline was obtained by microinjection of GVG (10 µg) into the ventral tegmental area of the midbrain. Injections of GVG (10–40 µg) into forebrain areas (striatum, thalamus) or into hindbrain (pontine tegmentum) were without anticonvulsant activity. Anticonvulsant effects of midbrain GVG were correlated with GABA elevation (3–4 fold) within a 1.5 mm radius of the injection site; these effects were obtained within 6 h and lasted three to four days after a single treatment. After four days seizure activity returned to control. No changes in spontaneous motor activity or reflexes accompanied the GVG injections. Similar but shorter lasting anticonvulsant effects were obtained with the direct GABA receptor agonist muscimol (50 ng) injected into the midbrain site. On the other hand, doses of muscimol up to 500 ng placed in the rostral pontine tegmentum were without anticonvulsant effect, despite the appearance of marked sedation.The time to peak anticonvulsant activity after midbrain microinjection of GVG (6 h) was considerably more rapid than that after intraperitoneal injection (60 h). Compartmental analysis revealed that nerve terminal associated GABA was elevated by 6 h after GVG when the direct microinjection route was used. These results suggest that GABAergic synapses in the midbrain may be critically involved in the control of seizure propagation.     

High-affinity binding of proline to mouse brain synaptic membranes

There is evidence suggestive of the possible neuromodulatory role forl-proline in the mammalian brain. The binding of proline to whole mouse brain synaptic membranes has been partially characterized. Several binding sites for this imino acid have been identified; one in the nanomolar range and at least two in the submicromolar range. The binding of proline is inhibited by NaCl. Pipecolic acid (40 M), ornithine, aminooxyacetic acid (AOAA), glycine, GABA, and glutamate were capable of significantly inhibiting proline binding. Although detailed pharmacological and functional studies are needed, these results are consistent with a brain-specific function for this imino acid, as well as, with the presence of specific binding site(s) for proline.     

GABA-gated chloride ion influx in brains of epileptic El mice

GABA-gated chloride ion influx was measured in brain microsac preparations of epileptic El mice. There was significantly greater sensitivity to GABA in stimulated El mice (which had 14–18 convulsions induced at weekly intervals) than in unstimulated El mice (which had not experienced convulsions) or ddY mice. GABA-gated chloride ion influx was significantly decreased 20 min after a single convulsion, and returned to the preconvulsion level 60 min after a convulsion. These findings suggest that the functional state of GABA-gated chloride channel in El mice is changed secondarily by single or repeated convulsions.     

Regional distributions of γ-aminobutyric acid (GABA), glutamate decarboxylase (GAD), and γ-aminobutyrate transaminase (GABA-T) in the central nervous brains of C57/BR,C3H/He,and F1 hybrid mice

The distributions of -aminobutyric acid (GABA), glutamate decarboxylase (GAD), and -aminobutyrate transaminase (GABA-T) have been studied in various brain areas of mice. These neurochemical markers, which are related to inhibitory neurotransmission, were investigated in different inbred strains of mice (C3H/He, C57/BR, and their F₁ hybrids). The regional distributions of GABA, GAD activity, and GABA-T activity in adult mice of these three strains were quite similar. No significant differences were found in any brain area for GAD or GABA-T activity. However, significant differences in GABA level were found in several brain areas among these strains of mice, especially in hypothalamus, hippcampus, olfactory bulb, and occipital cortex. These results provide further information to the possible influence of the GABAergic system in these brain areas.     

THE ROLE OF GABA METABOLISM IN THE CONVULSANT AND ANTICONVULSANT ACTIONS OF AMINOOXYACETIC ACID

Abstract— At high dosage levels AOAA acted as a convulsant agent in mice and rats but in lower amounts it was an effective anticonvulsant agent against INH-induced seizures, by tripling the time to the onset of the convulsions. AOAA elevated brain GABA levels as a result of a preferential inhibition of the GABA-T enzyme system but, contrary to previous reports, the activity of the GAD enzyme system was also inhibited, even by relatively low dosage levels of AOAA. The state of excitability of the brain following the administration of AOAA was related, within the limits of the present study, to changes in GAD activity and GABA levels, but additional data are required before the relationship can be properly evaluated.     

Inhibitors of crayfish glutamic acid decarboxylase

Crayfish glutamic acid decarboxylase (GAD), like the homologous enzymes from other species, is inhibited by carbonyl-trapping agents (e.g. aminooxyacetic acid; AOAA) and sulfhydryl reagents (e.g. 5,5-dithiobis-(2-nitrobenzoic acid); DTNB). It also is inhibited by the product GABA, many anions (e.g. SCN^– and Cl^–), and some cations (e.g. Zn⁺²). The inhibition by AOAA, but not that by DTNB, was prevented by increasing the concentration of the pyridoxal phosphate (PLP) coenzyme. GABA blocked the effects of PLP on enzyme activity. The inhibition by AOAA, DTNB, GABA, and chloride all were competitive with substrate. The effect of GABA occurs at physiological concentrations and may contribute to the regulation of GAD activity in vivo. The quantitative effect of anions is dependent on the cation with which they are administered. ATP stimulated GAD activity in homogenates prepared with potassium phosphate or Tris-acetate buffer, even when no exogenous PLP was provided.     

Modification of chloride flux across brain membranes by inhibitory amino acids in developing and adult mice

The influx of³⁶Cl^– was studied in membrane vesicles prepared from different brain regions from 3-day-old and adult mice. In both age groups the influx was enhanced about threefold by -aminobutyric acid (GABA), which effect was blocked by bicuculline and picrotoxin but not by baclofen, characteristic of a GABA_A receptor-mediated event. In samples from the adult brain stem the GABA stimulation was smaller than in samples from the other brain regions. Most of the compounds studied apparently act at the same receptor site with the following order of efficacy: muscimol > GABA > -alanine > hypotaurine > taurine. A number of anticonvulsant taurine derivatives were not effective and glycine only in the brain stem. The weak modulatory effects of taurine could be of significance in vivo since depolarizing stimuli release massive amounts of taurine in developing brain tissue.     

Comparative study of cholinergic cells in retinas of various mouse strains

We examined cholinergic cells in the retinas of BALB/C albino, C57BL/6J black, and 129/SvJ light chinchilla mice by using immunocytochemistry with specific antisera against choline acetyltransferase (ChAT). Two types of ChAT-immunoreactive amacrine cell bodies were found in the inner nuclear layer (INL) and ganglion cell layer in the retinas of all three mouse strains. They were distributed with mirror-image symmetry and their processes ramified in strata 2 and 4 of the inner plexiform layer. A distinct type of ChAT-immunoreactive cell was found only in C57BL/6J mouse retina. The somata of this third type of ChAT-immunoreactive cell were located in the outermost part of the INL, with their processes extending toward the outer plexiform layer. Double-labeling experiments demonstrated that these were not horizontal cells and that they were GABA-immunoreactive. The results suggested that these cells were probably misplaced cholinergic amacrine cells showing GABA immunoreactivity. This feature of the C57BL/6J mouse retina should be taken into account in studies of mutant mice having a mixed genetic background with a C57BL/6J contribution.Tae-Hoon Kang, Young-Han Ryu and In-Beom Kim contributed equally to this study.This work was supported by Neurobiology Support Grant (M1-0108-00-0059) of the Ministry of Science and Technology, Korea     

The effect of kainate on protein kinase C,GABA, and the uptake of serotonin in the rabbit retina in vivo

The purpose of this study was to investigate the effect of kainate on protein kinase C (PKC), -aminobutyrate (GABA) and serotonin uptake in the rabbit retina. Kainate when injected into the vitreous humour produces a change in the GABA immunoreactivity within 6 hours. After 3 days, remnants of the normal GABA immunoreactivity still persist and additionally astrocyte and microglia-like elements stain positively for GABA. After 7 days exposure to kainate none of the normal GABA immunoreactivity is apparent, instead a number of round-shaped elements which may be reactive astrocytes and/or microglia stain positively for GABA. During these stages kainate does not affect the PKC immunoreactivity associated with the on-bipolar cells. Six hours following kainate treatment the ability of certain GABA amacrine cells to take up exogenous serotonin is unaffected. After three days only a few of these cells can still take up exogenous serotonin and then not avidly. After seven days the GABA/serotonin amacrine cells cannot take up exogenous serotonin suggesting that all of these neurons are irreversibly damaged. One hour after treatment with kainate both calcium-dependent and-independent PKC species are translocated from the cytosolic to membrane compartments. After 5 hours and 7 days there was also evidence from the enzyme assay experiments that kainate caused the calcium-dependent and-independent PKC enzymes to be translocated but because the total enzyme activity was reduced due perhaps to down-regulation of the enzyme this was difficult to assess precisely. However, the electrophoresis/blotting experiments of tissues exposed for 5 hours (but not one hour) to kainate established clearly that , , and PKC are translocated from cytosolic and membrane compartments.     

Regional excitatory and inhibitory amino acid levels in epileptic El mouse brain

Inbred mutant El mice are highly susceptible to convulsive seizures upon tossing stimulation. The levels of excitatory (e.g. glutamate and aspartate) and inhibitory amino acids [e.g. -aminobutyrate (GABA)] were examined in discrete regions of stimulated El mice [El(+)] non-stimulated El mice [El(-)] and ddY mice, which do not have convulsive disposition. In comparison with ddY, a general increased levels of aspartate, glutamate, glutamine, and taurine were detected in brain regions of El(-). The levels of GABA and glycine were almost the same in ddY and El(-). Compared to El(+), the levels of aspartate, glutamate, glutamine, and GABA in El(-) were either the same or higher. In the case of taurine and glycine, the levels in El(-) were either the same or lower than El(+). Alanine is special in that El(-) have a higher level than El(+) in hippocampus but lower in cerebellum. Furthermore, while marked changes were registered in several brain regions, none of the amino acids investigated showed any significant differences in the hypothalamus of three different groups of mice.     

Endogenous zinc can be a modulator of glycinergic signaling pathway in the rat retina

Summary Zinc is a modulator of glutamatergic inputs in the hippocampus. In the retina, however, we previously reported that endogenous zinc is present in the non-glutamatergic neural processes and earlier electrophysiological studies suggest that zinc is a modulator of inhibitory signaling pathways, which are mediated by glycine and GABA. AII amacrine cells, a subpopulation of glycinergic amacrine cells, are identified by selective immunoreactivity for parvalbumin in the rat retina. In the present study, therefore, we focused on whether zinc is present in AII amacrine cells using silver amplification combined with immunohistochemistry in the rat retina. We also examined whether zinc modulate glycine response in the rat retina by the patch clamp technique. Association of silver precipitates with the parvalbumin-immunoreactive neural processes was observed at the ultrastructural level. We also found that zinc existed in the neural processes which were not parvalbumin-immunoreactive. Glycine-induced responses were augmented when the concentration of Zn²⁺ was below 10 M, but inhibited at Zn²⁺ concentrations of 50 M or more. Our results suggest the notion that zinc in neural processes of retinal neurons modulates the inhibitory signaling pathway, particularly that mediated by glycine receptors in AII amacrine cells.