Regulation of γ-Aminobutyric Acid Synthesis in the Brain

Abstract: γ-Aminobutyric acid (GABA) is synthesized in brain in at least two compartments, commonly called the transmitter and metabolic compartments, and because reglatory processes must serve the physiologic function of each compartment, the regulation of GABA synthesis presents a complex problem. Brain contains at least two molecular forms of glutamate decarboxylase (GAD), the principal synthetic enzyme for GABA. Two forms, termed GAD₆₅ and GAD₆₇, are the products of two genes and differ in sequence, molecular weight, interaction with the cofactor, pyridoxal 5′-phosphate (pyridoxal-P), and level of expression among brain regions. GAD₆₅ appears to be localized in nerve terminals to a greater degree than GAD₆₇, which appears to be more uniformly distributed throughout the cell. The interaction of GAD with pyridoxal-P is a major factor in the short-term regulation of GAD activity. At least 50% of GAD is present in brain as apoenzyme (GAD without bound cofactor; apoGAD), which serves as a reservoir of inactive GAD that can be drawn on when additional GABA synthesis is needed. A substantial majority of apoGAD in brain is accounted for by GAD₆₅, but GAD₆₇ also contributes to the pool of apoGAD. The apparent localization of GAD₆₅ in nerve terminals and the large reserve of apo-GAD₆₅ suggest that GAD₆₅ is specialized to respond to short-term changes in demand for transmitter GABA. The levels of apoGAD and the holoenzyme of GAD (holoGAD) are controlled by a cycle of reactions that is regulated by physiologically relevant concentrations of ATP and other polyanions and by inorganic phosphate, and it appears possible that GAD activity is linked to neuronal activity through energy metabolism. GAD is not saturated by glutamate in synaptosomes or cortical slices, but there is no evidence that GABA synthesis in vivo is regulated physiologically by the availability of glutamate. GABA competitively inhibits GAD and converts holo- to apoGAD, but it is not clear if intracellular GABA levels are high enough to regulate GAD. There is no evidence of short-term regulation by second messengers. The syntheses of GAD₆₅ and GAD₆₇ proteins are regulated separately. GAD₆₇ regulation is complex; it not only is present as apoGAD₆₇, but the expression of GAD₆₇ protein is regulated by two mechanisms: (a) by control of mRNA levels and (b) at the level of translation or protein stability. The latter mechanism appears to be mediated by intracellular GABA levels.     

Rapid Inactivation of Brain Glutamate Decarboxylase by Aspartate

In the absence of its cofactor, pyridoxal 5'-phosphate (pyridoxal-P), glutamate decarboxylase is rapidly inactivated by aspartate. Inactivation is a first-order process and the apparent rate constant is a simple saturation function of the concentration of aspartate. For the beta-form of the enzyme, the concentration of aspartate giving the half-maximal rate of inactivation is 6.1 +/- 1.3 mM and the maximal apparent rate constant is 1.02 +/- 0.09 min-1, which corresponds to a half-time of inactivation of 41 s. The rate of inactivation by aspartate is about 25 times faster than inactivation by glutamate or gamma-aminobutyric acid (GABA). Inactivation is accompanied by a rapid conversion of holoenzyme to apoenzyme and is opposed by pyridoxal-P, suggesting that inactivation results from an alternative transamination of aspartate catalyzed by the enzyme, as previously observed with glutamate and GABA. Consistent with this mechanism pyridoxamine 5'-phosphate, an expected transamination product, was formed when the enzyme was incubated with aspartate and pyridoxal-P. The rate of transamination relative to the rate of decarboxylation was much greater for aspartate than for glutamate. Apoenzyme formed by transamination of aspartate was reactivated with pyridoxal-P. In view of the high rate of inactivation, aspartate may affect the level of apoenzyme in brain.     

Activation of Glutamate Apodecarboxylase by Succinic Semialdehyde and Pyridoxamine 5''-Phosphate

Glutamate apodecarboxylase was activated by incubation with succinic semialdehyde and pyridoxamine 5'-phosphate. Activation required both compounds and was highly selective for succinic semialdehyde. Of 18 analogs tested, only glyoxylate, pyruvate, oxaloacetate, and 2-oxoglutarate activated the apoenzyme significantly, but much higher concentrations of these compounds than of succinic semialdehyde were required. In the presence of pyridoxamine 5'-phosphate, the concentration of succinic semialdehyde giving half-maximal activation of apoenzyme was 7 microM. In contrast, the Ki for succinic semialdehyde as a competitive inhibitor of glutamate decarboxylation was 1.2 mM, indicating that apoenzyme with bound pyridoxamine 5'-phosphate has a much higher affinity for succinic semialdehyde than does holoenzyme. The concentration of pyridoxamine 5'-phosphate giving half-maximal activation was 17 microM, which is more than an order of magnitude greater than the corresponding value for pyridoxal 5'-phosphate.     

Glutamate-Dependent Active-Site Labeling of Brain Glutamate Decarboxylase

A major regulatory feature of brain glutamate decarboxylase (GAD) is a cyclic reaction that controls the relative amounts of holoenzyme and apoenzyme [active and inactive GAD with and without bound pyridoxal 5'-phosphate (pyridoxal-P, the cofactor), respectively]. Previous studies have indicated that progression of the enzyme around the cycle should be stimulated strongly by the substrate, glutamate. To test this prediction, the effect of glutamate on the incorporation of pyridoxal-P into rat-brain GAD was studied by incubating GAD with [32P]pyridoxal-P, followed by reduction with NaBH4 to link irreversibly the cofactor to the enzyme. Adding glutamate to the reaction mixture strongly stimulated labeling of GAD, as expected. 4-Deoxypyridoxine 5'-phosphate (deoxypyridoxine-P), a close structural analogue of pyridoxal-P, was a competitive inhibitor of the activation of glutamate apodecarboxylase by pyridoxal-P (Ki = 0.27 microM) and strongly inhibited glutamate-dependent labeling of GAD. Analysis of labeled GAD by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis showed two labeled proteins with apparent molecular masses of 59 and 63 kDa. Both proteins could be purified by immunoaffinity chromatography on a column prepared with a monoclonal antibody to GAD, and both were labeled in a glutamate-dependent, deoxypyridoxine-P-sensitive manner, indicating that both were GAD. Three peaks of GAD activity (termed peaks I, II, and III) were separated by chromatography on phenyl-Sepharose, labeled with [32P]pyridoxal-P, purified by immunoaffinity chromatography, and analyzed by SDS-polyacrylamide gel electrophoresis. Peak I contained only the 59-kDa labeled protein. Peaks II and III contained the both the 59- and 63-kDa proteins, but in differing proportions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alteration of Amino Acid Metabolism in Epileptogenic Mice by Elevation of Brain Pyridoxal Phosphate

A single intraperitoneal injection of pyridoxal-5'-phosphate (PLP) in a species of mouse, DBA/2J, that is normally susceptible to sound-induced convulsion exacerbated its epileptic condition. The effect of injection was most pronounced about 30 min after the administration and subsided gradually within the following 4 h. Correlated with this increased seizure susceptibility were enhanced levels of synaptosomal aspartate and glutamate, and a diminished gamma-aminobutyric acid (GABA) level. The concentrations of nonneuroactive amino acids remained unchanged. When stimulated with veratrine, synaptosomes prepared from PLP-injected mice showed an increased release of aspartate and glutamate and a decreased release of GABA compared to those prepared from control mice. The activity of glutamate decarboxylase in the brains of PLP-treated mice was lowered, whereas the activity of GABA-transaminase was enhanced. Finally, the epileptic condition of DBA mice could be ameliorated by maintenance on a diet composed of vitamin B6-deficient feed and cellulose.     

Two Forms of the γ-Aminobutyric Acid Synthetic Enzyme Glutamate Decarboxylase Have Distinct Intraneuronal Distributions and Cofactor Interactions

Glutamate decarboxylase (GAD) catalyzes the production of gamma-aminobutyric acid (GABA), a major inhibitory neurotransmitter. The mammalian brain contains two forms of GAD, with Mrs of 67,000 and 65,000 (GAD67 and GAD65). Using a new antiserum specific for GAD67 and a monoclonal antibody specific for GAD65, we show that the two forms of GAD differ in their intraneuronal distributions: GAD67 is widely distributed throughout the neuron, whereas GAD65 lies primarily in axon terminals. In brain extracts, almost all GAD67 is in an active holoenzyme form, saturated with its cofactor, pyridoxal phosphate. In contrast, only about half of GAD65 (which is found in synaptic terminals) exists as active holoenzyme. We suggest that the relative levels of apo-GAD65 and holo-GAD65 in synaptic terminals may couple GABA production to neuronal activity.     

Essential Active-Site Lysine of Brain Glutamate Dehydrogenase Isoproteins

Abstract: Two soluble forms of bovine brain glutamate dehydrogenase (GDH) isoproteins were inactivated by pyridoxal 5'-phosphate. Spectral evidence is presented to indicate that the inactivation proceeds through Schiff's base formation with amino groups of the enzyme. Sodium borohydride reduction of the pyridoxal 5'-phosphate-inactivated GDH isoproteins produced a stable pyridoxyl enzyme derivative that could not be reactivated by dialysis. The pyridoxyl enzyme was studied through fluorescence spectroscopy. No substrates or coenzymes separately gave complete protection against pyridoxal 5'-phosphate. A combination of 10 m M 2-oxoglutarate with 2 m M NADH, however, gave complete protection against the inactivation. Tryptic peptides of the isoproteins, modified with and without protection, resulted in a selective modification of one lysine. In both GDH isoproteins, the sequences of the peptide containing the phosphopyridoxyllysine were clearly identical to sequences of other GDH species.     

Comparative Characterization of Glutamate Decarboxylase in Crude Homogenates of Oviduct, Ovary, and Hypothalamus

Some biochemical characteristics of L-glutamate decarboxylase (GAD) were compared using crude homogenates of the rat oviduct, ovary, and hypothalamus. As estimated by the measurement of CO2 production, the specific activities of oviductal and ovarian GAD were about 10 and 3% of the hypothalamic value, respectively. Stoichiometric formation of gamma-aminobutyric acid (GABA) and CO2 from L-glutamate could be observed in oviduct and hypothalamus, while in ovarian homogenates the production of CO2 was more than nine times that of GABA. Hypothalamic and tubal GAD showed similar time course, temperature dependence, and pH dependence. The dependence on protein concentration and on exogenous cofactor supply was also similar in these two tissues. The kinetic constant for L-glutamate as a substrate was nearly the same in oviduct (1.30 mM) and hypothalamus (1.64 mM). The responsiveness of tubal and hypothalamic GAD to various inhibitors was also similar. The present findings indicate that the oviductal and the hypothalamic GAD may be identical, and they suggest a possible GABAergic innervation of the Fallopian tube.     

Increased Intracellular γ-Aminobutyric Acid Selectively Lowers the Level of the Larger of Two Glutamate Decarboxylase Proteins in Cultured GABAergic Neurons from Rat Cerebral Cortex

The regulation of glutamate decarboxylase (GAD; EC 4.1.1.15) was studied by using cultures of cerebral cortical neurons from rat brain grown in serum-free medium. About 50% of the neurons in the cultures were gamma-aminobutyric acid (GABA)ergic as determined by two double-staining procedures. Immunoblotting experiments with four anti-GAD sera that recognize the two forms to varying degrees, demonstrated that the cultures contained the two forms of GAD that are present in rat brain (apparent molecular masses = 63 and 66 kDa). GAD activity was reduced by 60-70% when intracellular GABA levels were increased by incubating the cultures with the GABA-transaminase inhibitor gamma-vinyl-GABA for greater than 5-10 h or with 1 mM GABA itself. Neither baclofen nor muscimol (100 microM) affected GAD activity. Immunoblotting experiments showed that only the larger of the two forms of GAD (66 kDa) was decreased by elevated GABA levels. These results, together with previous results indicating that the smaller form of GAD is more strongly regulated by pyridoxal 5'-phosphate (the cofactor for GAD), suggest that the two forms of GAD are regulated by different mechanisms.     

Higher GABA Concentrations in Fallopian Tube Than in Brain of the Rat

Abstract: The GABA content was determined simultaneously in two peripheral organs, i.e., ovary and Fallopian tube. Moreover, the effects of inhibitors of glutamate decarboxylase or γ-aminobutyrate transaminase (GABA-T) on the GABA concentrations of the two organs were examined, to point out similarities and differences between central and peripheral pathways of GABA biosynthesis and degradation. In ovary, GABA concentration was found to be about 30% of that in total brain tissue. Furthermore, isoniazid and thiosemicarbazide caused significant reduction of GABA levels in peripheral organs. In contrast to the CNS, aminooxyacetic acid failed to increase, but even produced a significant diminution in peripheral GABA content. Gabaculine did not change GABA levels. In conclusion, it has been demonstrated for the first time that a peripheral organ, i.e. fallopian tube, contained higher GABA concentrations than the CNS. On the other hand, in the organs examined GABA seemed to be synthesized similarly, but metabolized by a pathway different from that in the brian.     

Inhibition of Brain Glutamate Decarboxylase Activity Is Related to Febrile Seizures in Rat Pups

Because previous work showed that in the newborn brain, but not in the adult brain, glutamate decarboxylase (GAD) is notably susceptible to heat, we have studied the possible involvement of GAD inhibition in febrile convulsions and the related changes in gamma-aminobutyric acid (GABA) content. Rats of different ages were subjected to hyperthermia, and GAD activity was determined in brain homogenates by measuring the release of 14CO2 from labeled glutamate and by measuring the formation of GABA. The latter method gave considerably lower values than the former in the youngest rats, and was considered more reliable. With this method, we found a 37-48% inhibition of GAD activity in rat pups 2-5 days old, which showed febrile seizures at progressively higher body temperatures, whereas in 10- and 15-day-old animals, which did not show convulsions, GAD activity was not affected by hyperthermia. Whole-brain GABA levels, however, did not change at any age. In contrast to GAD, choline acetyltransferase and lactic dehydrogenase activities were not altered by hyperthermia at any of the ages studied. These results suggest that a decreased efficiency of the inhibitory neurotransmission mediated by GABA, consequent to the inhibition of GAD activity, may be a factor related to febrile convulsions.     

Effects of Lead In Vivo and In Vitro on GABAergic Neurochemistry

Abstract: Alterations in aspects of neurotransmission utilizing -γ-aminobutyric acid (GABA) are associated with in vivo exposure of rats to lead at doses that do not produce convulsions, but sensitize animals to convulsant agents. These effects are observed regionally and include: decreased GABA levels in cerebellum; increased activity of glutamate decarboxylase (GAD) in caudate; and decreased GABA release (both resting and K⁺-stimulated) in cortex, caudate, cerebellum and substantia nigra. Sodium-dependent uptake of GABA by synaptosomes of cerebellum, substantia nigra and caudate was also affected: in these regions, affinity (K_m) was increased and maximal velocity (V_max) was reduced. Sodium-independent binding of GABA to synaptic membranes was increased in cerebellum, but was observed only when tissue was Tritonized and prepared without freezing and washing. No effects on GAD or on GABA uptake, release, or binding were observed when lead was added to brain tissue in vitro in concentrations as high as 100 μM. The results suggest that lead may produce chronic inhibition of presynaptic GABAergic function, notably in the cerebellum, which is associated with supersensitivity of postsynaptic GABA receptors. Failure of lead to affect GABAergic function in vitro may indicate that these effects are secondary to another neurotoxic action of lead in the CNS or are consequent to a nonneuronal metabolic action of lead.     

Glutamate Decarboxylases in Nonneural Cells of Rat Testis and Oviduct: Differential Expression of GAD65 and GAD67

gamma-Aminobutyric acid (GABA) and its synthetic enzyme, glutamate decarboxylase (GAD), are not limited to the nervous system but are also found in nonneural tissues. The mammalian brain contains at least two forms of GAD (GAD67 and GAD65), which differ from each other in size, sequence, immunoreactivity, and their interaction with the cofactor pyridoxal 5'-phosphate (PLP). We used cDNAs and antibodies specific to GAD65 and GAD67 to study the molecular identity of GADs in peripheral tissues. We detected GAD and GAD mRNAs in rat oviduct and testis. In oviduct, the size of GAD, its response to PLP, its immunoreactivity, and its hybridization to specific RNA and DNA probes all indicate the specific expression of the GAD65 gene. In contrast, rat testis expresses the GAD67 gene. The GAD in these two reproductive tissues is not in neurons but in nonneural cells. The localization of brain GAD and GAD mRNAs in the mucosal epithelial cells of the oviduct and in spermatocytes and spermatids of the testis shows that GAD is not limited to neurons and that GABA may have functions other than neurotransmission.     

Anticonvulsant Activity of Muscimol and γ-Aminobutyric Acid Against Pyridoxal Phosphate-Induced Epileptic Seizures

The intracerebroventricular injection of pyridoxal phosphate (PLP, 0.125-1.25 μmol/rat) causes epileptic seizures (4 min → 1 min) that are preventable or reversible by GABA (1 μmol/rat), by muscimol (O.025 μmol/rat), or by diazepam (1.75 μmol/rat). At the peak of PLP-induced convulsions, the activities of GAD and GABA-T in 14 regions of rat brain remained unaltered, whereas the concentrations of PLP remained elevated. The PLP-induced convulsion was blocked by DABA (10 μmol/rat) but was not altered by β-alanine (50 μmol/rat). The previous in vitro studies have shown that PLP increases the uptake of [³H]GABA into synaptosomes and inhibits the binding of [³H]GABA to synaptic membranes. These data suggest that PLP-induced convulsion is due to reduced availability of GABA to its recognition sites, rather than to alteration in the activity of GABA metabolizing enzymes, or unavailability of PLP as a coenzyme for GAD and GABA-T. Since the duration of PLP-induced epileptic seizures is short and can be prevented by GABA agonists, PLP may be used as a tool to study the nature of GABA-mediated neuroinhibition and the properties of GABA receptor sites.     

Presence of γ-Aminobutyric Acid in Rat Ovary

Abstract: As γ-aminobutyric acid (GABA) was first discovered as the free acid in the mammalian central nervous system, it has been assumed that GABA is generally to be found in significant amounts only in the brain, in spite of reports of its presence in a number of non-neuronal tissues. In this study, GABA was detected amongst the free amino acids in most rat tissues that were examined. The highest concentration outside the brain was in the ovary (0.59 μmol/g fresh tissue). It is concluded that the synthesis of the GABA is intragonadal and probably of metabolic importance.     

γ-Aminobutyric Acid System in Developing and Degenerating Mouse Retina

Freeze-dried sections (14 microns thick) of retinal layers were prepared from mice with retinal degeneration (C3H strain) and control mice (C57BL strain). The weighed sections (2-30 ng dry weight) were analyzed using our microassay methods. In the control retina, gamma-aminobutyric acid (GABA) concentration and glutamate decarboxylase (GAD) activity, on a dry weight basis, increased from birth to 9 weeks of age and decreased slightly at 20 weeks. In the degenerated retina, the levels of GABA and GAD activity were higher at birth than in the control retina, and continued to increase until 20 weeks of age, at which time the GAD activity reached a markedly high level. This increase was found when the total GABA and GAD levels per retina were determined. In the normal retinal layers, GABA and GAD were confined primarily to the inner plexiform layer. In the degenerated retina, GAD activity gradually increased in the inner layers during postnatal development, but by 20 weeks the increase was most prominent in the inner part of inner nuclear layer and in the outer part of inner plexiform layer. GABA transaminase activity and its distribution were not much different in both normal and degenerated retinas during development.     

Stimulation of Synaptosomal γ-Aminobutyric Acid Synthesis by Glutamate and Glutamine

gamma-Aminobutyric acid (GABA) synthesis was studied in rat brain synaptosomes by measuring the increase of GABA level in the presence of the GABA-transaminase inhibitor gabaculine. The basal rate of synaptosomal GABA synthesis in glucose-containing medium (25.9 nmol/h/mg of protein) was only 3% of the maximal activity of glutamate decarboxylase (GAD; 804 +/- 83 nmol/h/mg of protein), a result indicating that synaptosomal GAD operates at only a small fraction of its catalytic capacity. Synaptosomal GABA synthesis was stimulated more than threefold by adding 500 microM glutamine. Glutamate also stimulated GABA synthesis, but the effect was smaller (1.5-fold). These results indicate that synaptosomal GAD is not saturated by endogenous levels of its substrate, glutamate, and account for part of the unused catalytic capacity. The greater stimulation of GABA synthesis by glutamine indicates that the GAD-containing compartment is more accessible to extrasynaptosomal glutamine than glutamate. The strong stimulation by glutamine also shows that the rates of uptake of glutamine and its conversion to glutamate can be sufficiently rapid to support GABA synthesis in nerve terminals. Synaptosomes carried out a slow net synthesis of aspartate in glucose-containing medium (7.7 nmol/h/mg of protein). Aspartate synthesis was strongly stimulated by glutamate and glutamine, but in this case the stimulation by glutamate was greater. Thus, the larger part of synaptosomal aspartate synthesis occurs in a different compartment than does GABA synthesis.     

Preloading In Vivo: A Rapid and Reliable Method for Measuring γ-Aminobutyric Acid and Glutamate Fluxes by Microdialysis

In vivo microdialysis was used in conjunction with a novel dual-label preloading method, to monitor changes in extracellular levels of gamma-aminobutyric acid (GABA) and glutamate in the striatum of conscious, unrestrained rats. [3H]GABA and [14C]glutamate were applied in the dialysis stream for a preloading period of 30 min, after which dialysis perfusion was continued for up to 6 h, and dialysate samples were collected for scintillation counting. Veratridine (Vtd: 100 microM in the dialysate) caused significant rises in both 3H and 14C content measured in the dialysates, the majority of which remained associated with the preload GABA and glutamate, respectively. The Vtd-stimulated release of GABA and glutamate measured in this way was blocked by tetrodotoxin and was Ca2+ dependent. Thus, by reproducing results obtained using other techniques, we have shown that the preloading method provides a quick and reliable method for measuring the effects of drugs on the release of neurotransmitter GABA and glutamate in vivo by dyalisis. It should enable sample times as low as 1 min to be used, thus allowing resolution of transient stimulated responses taking place over a time course of minutes.     

Effects of Increased γ-Aminobutyric Acid Levels on GAD67 Protein and mRNA Levels in Rat Cerebral Cortex

Abstract: Rats were injected with saline or the γ-aminobutyric acid (GABA) transaminase inhibitor γ-vinyl-GABA for 7 days and the effects on GABA content and glutamic acid decarboxylase (GAD) activity, and the protein and mRNA levels of the two forms of GAD (GAD₆₇ and GAD₆₅) in the cerebral cortex were studied. γ-Vinyl-GABA induced a 2.3-fold increase in GABA content, whereas total GAD activity decreased by 30%. Quantitative immunoblotting showed that the decline in GAD activity was attributable to a 75–80% decrease in GAD₆₇ levels, whereas the levels of GAD₆₅ remained unchanged. RNA slot-blotting with a ³²P-labeled GAD₆₇ cDNA probe demonstrated that the change in GAD₆₇ protein content was not associated with a change in GAD₆₇ mRNA levels. Our results suggest that GABA specifically controls the level of GAD₆₇ protein. This effect may be mediated by a decreased translation of the GAD₆₇ mRNA and/or a change in the stability of the GAD₆₇ protein.     

In Vivo Release of Endogenous Amino Acids from the Rat Striatum: Further Evidence for a Role of Glutamate and Aspartate in Corticostriatal Neurotransmission

By means of the push-pull cannula method, the outflow of endogenous amino acids was studied in the striatum of halothane-anesthetized rats. Addition of K+ ions (30 mM for 4 min) to the superfusion fluid increased the release of aspartate (+116%), glutamate (+217%), taurine (+109%), and gamma-aminobutyric acid (GABA) (+429%) whereas a prolonged decrease in the outflow of glutamine (-28%) and a delayed reduction in the efflux of tyrosine (-25%) were observed. In the absence of Ca2+, the K+-induced release of aspartate, glutamate, and GABA was blocked whereas the K+-induced release of taurine was still present. Under these conditions, the decrease in glutamine efflux was reduced and that of tyrosine was abolished. Local application of tetrodotoxin (5 microM) decreased only the outflow of glutamate (-25%). One week following lesion of the ipsilateral sensorimotor cortex the spontaneous outflow of glutamine and of tyrosine was enhanced. Despite the lack of change in their spontaneous outflow, the K+-evoked release of aspartate and glutamate was less pronounced in lesioned than in control animals, whereas the K+-evoked changes in GABA and glutamine efflux were not modified. Our data indicate that the push-pull cannula method is a reliable approach for the study of the in vivo release of endogenous amino acids. In addition, they provide further evidence for a role for glutamate and aspartate as neurotransmitters of corticostriatal neurons.