Evidence for Two Distinct Forms of Native Glutamic Acid Decarboxylase in Rat Brain Soluble Extract: An Immunoblotting Study

Immunoblots of the soluble proteins from a rat brain high-speed supernatant dissociated under reducing conditions showed two monomers (molecular weights, 59,000 and 62,000 +/- 2,000) immunolabeled by a glutamic acid decarboxylase (GAD) antiserum. In this extract, a GAD monoclonal antibody trapped the same two monomers, thus confirming that they are both constitutive subunits of GAD. Without treatment under reducing conditions, two additional bands were stained by immunoblotting. Their molecular weights were estimated to be 115,000 and 122,000 +/- 5,000. These results demonstrate the presence, in rat brain soluble extract, of two distinct forms of native GAD. They further support our previous hypothesis that each form is composed by the homodimeric association of each constitutive subunit through disulfide bridges.     

Brain Glutamate Decarboxylase: Properties of Its Calcium-Dependent Binding to Liposomes and Kinetics of the Bound and the Free Enzyme

Abstract: In the present work we describe several properties of the Ca²⁺-dependent binding of glutamate decarboxylase (GAD) to phosphatidylcholine-phosphatidylserine liposomes. The binding occurs very rapidly, is dependent on temperature in the range 23–37°C, is inhibited up to 35% by K⁺ in a concentration-dependent manner and is slightly increased when the dielectric constant of the medium is decreased by 3% ethanol. The association of GAD and liposomes is very firm, since EGTA displaces only 40% of the bound enzyme and Triton X-100 about 55%. Since apparently only part of the total GAD is able to bind to the liposomes and in a previous study two forms of GAD activity have been identified kinetically, we compared the activations by pyridoxal 5'-phosphate (PLP) of the soluble and the bound GAD, as well as their inhibition by PLP oxime- O -acetic acid. The bound GAD was activated 150–265% by 10⁻⁶ to 10⁻⁴ m -PLP, whereas the activation of GAD that remained soluble was only 65–110% in the same PLP concentration range. In the absence of PLP, the bound GAD was less inhibited by the PLP oxime- O -acetic acid than the soluble GAD, but the inhibition was similar when 0.1 m m -PLP was added. In contrast, activity of both the soluble and the bound GAD was totally blocked by aminooxyacetic acid. Endogenous PLP did not bind to liposomes under the experimental conditions inducing GAD binding. We conclude that the binding of GAD to negatively charged liposomes is primarily ionic. Furthermore, the GAD molecules that bind to the liposomes seem to be deficient in free PLP and therefore, are probably more susceptible to regulation by the coenzyme. These conclusions may be relevant to the hypothesis of a coupling between synthesis and release of GABA in inhibitory nerve endings.     

Characterization of Glutamic Acid Decarboxylase Activity in Cerebral Blood Vessels

Abstract: Glutamic acid decarboxylase activity associated with cerebral blood vessels appears to be part of a specific cerebrovascular system involving γ-aminobutyric acid. This activity was characterized kinetically and pharmacologically and compared with that in brain and several nonneuronal tissues. Formation of γ-aminobutyric acid from [¹⁴C]glutamate was measured in a soluble extract of pia-arachnoid blood vessels isolated from bovine brain. The vascular activity was like brain glutamate decarboxylase in that it required pyridoxal phosphate, was completely inhibited by aminooxyacetic acid, and had a similar affinity for glutamate. Cerebrovascular decarboxylase activity differed, however, from brain decarboxylase in that it was less sensitive to sulfhydryl reagents, was stimulated by 3-mercaptopropionic and cysteic acids, and was competitively inhibited by cysteine sulfinic acid. The glutamate decarboxylase activity of the cerebral vessels was similar to that in renal cortex and mesenteric blood vessels in its responses to sulfhydryl reagents and 3-mercaptopropionic acid. These findings are consistent with previous suggestions of a nonneuronal form of the enzyme and offer the possibility that synthesis of γ-aminobutyric acid in cerebral blood vessels can be manipulated independently from that in neuronal tissue.     

Multiple Forms of Glutamate Decarboxylase in Porcine Brain

Three forms of glutamate decarboxylase from hog brain (termed α-, ß-, and γ-GAD) were separated by hydrophobic interaction chromatography on phenyl-Sepharose, by isoelectric focusing, and by polyacryl-amide gel electrophoresis. When rechromatographed on phenyl-Sepharose, each form migrated as a single entity, indicating that the forms are not readily interconvertible. The three forms are not different-sized aggregates of one form, since all three have the same approximate molecular weight (100,000) as determined by Sephadex G-200 chromatography. The pIs of the three forms separated by phenyl-Sepharose were determined by isoelectric focusing. The values obtained (5.3, 5.5, and 5.8 for α-, ß-, and γ-GAD, respectively) were comparable to the pIs of the three peaks of activity observed upon focusing of enzyme that had been subjected to phenyl-Sepharose chromatography. These results indicate that phenyl-Sepharose chromatography and isoelectric focusing separate the same three components. When synaptosomal extracts were analyzed by phenyl-Sepharose chromatography without intervening purification steps, all three forms were present, but the proportion of ß-GAD was somewhat higher and that of γ-GAD somewhat lower than in the usual preparations.     

大鼠脑谷氨酸脱羧酶基因的cDNA克隆及序列分析

胰岛β－细胞自身抗原蛋白之一是脑中谷氨酸脱羧酶（Ｇｌｕｔａｍｉｃａｃｉｄｄｅｃａｒｂｏｘｙｌａｓｅ,ＧＡＤ,ＥＣ４．１．１．１５）同源物。以双链ｃＤＮＡ为模板,用ＰＣＲ方法快速克隆了Ｗｉｓｔａｒ大鼠脑ＧＡＤ基因的ｃＤＮＡ,将此包括编码５９３个氨基酸的全长ＤＮＡ片段重组入ｐＵＣ质粒并用双脱氧末端终止法测定了全部序列,证明其全长为１７７９ｂｐ．经比较发现Ｗｉｓｔａｒ大鼠脑与Ｒｕｓｓｅｌｌ报导的大鼠脑ＧＡＤ基因序列,有一处碱基的差别,但并不涉及氨基酸的改变。同时还对用ＰＣＲ扩增长片段ＤＮＡ进行了方法学上的探讨。     

Some Characteristics of Glutamic Acid Decarboxylase of Chick Ampullary Cristae

Abstract: In a previous study, it was demonstrated that enzyme-mediated γ-aminobutyric acid (GABA) synthesis occurs in the vestibule of the chick inner ear. As deeper knowledge of the properties of its synthesizing enzyme might contribute to the understanding of the role of GABA in inner ear function, some characteristics of glutamate decarboxylase (GAD) were studied in chick isolated ampullary cristae under conditions in which ¹⁴CO₂ release from [1-¹⁴C]glutamate and [¹⁴C]GABA formation from [U-¹⁴C]glutamate for estimating GAD activity were equal. It was found that K _m for glutamate is 5 m M and that the enzyme pH optimum is 7.3. These values fall within the range described for the corresponding enzyme in nervous tissue of other species. Pyridoxal phosphate (PLP) activates the enzyme and aminooxyacetic acid inhibits it, the same as these agents activate or inhibit GAD from several nervous tissue sources. 2-Mercaptoethanol shows some protection from inactivation of the PLP-de-pendent enzyme and Triton X-100 exerts some inhibition of vestibular GAD activity, as previously shown in other nervous tissue preparations. Although its cellular localization is at present uncertain, these results indicate that GAD of chick vestibular tissue possesses properties resembling those of the brain enzyme and might be controlled in a manner similar to that of GAD in brain, thus possibly participating in the regulation of inner ear function.     

Rat Brain Glutamic Acid Decarboxylase Sequence Deduced from a Cloned cDNA

A cDNA clone complementary to the rat brain glutamic acid decarboxylase mRNA was isolated from a rat brain cDNA expression library using an antibody specific to the enzyme. The cDNA insert has been shown to direct the synthesis of an active protein in Escherichia coli. In this study, the nucleotide sequence of this clone, which includes the complete coding region, is presented. The predicted protein is 593 amino acids in length. The first 557 residues display a 95% identity when compared with the corresponding cat sequence. However, the deduced amino acid sequence of the carboxy-terminal end of the rat protein, downstream of residue 557, is totally different from the cat, whereas it agrees with a published partial peptidic sequence of the rat protein.     

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)     

Phylogenesis of Brain Glutamic Acid Decarboxylase from Vertebrates: Immunochemical Studies

Brain high-speed supernatants from various lower and higher vertebrates were subjected to sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, electroblot on nitrocellulose membranes, and immunolabelling using an anti-glutamic acid decarboxylase (anti-GAD) antiserum prepared from rat antigen. Rat brain extracts showed two distinct immunolabelled bands (MW 59,000 and 62,000 daltons). The molecular weight of the native enzyme was 120,000 daltons. The immunoblot pattern was not affected by a 3-h incubation of the homogenate. In the substantia nigra, the decrease in the immunolabelling of both bands corresponded very closely to the decrease of GAD activity following lesioning of the striato-nigral pathway. Moreover, experiments with preadsorbed antiserum showed that both subunits have common antigenic determinants. The immunolabelling was consistently more intense over the lightest band. The autoradiography of immunoprecipitated rat brain GAD, iodinated prior to electrophoresis, revealed two radiolabelled bands corresponding to the two immunolabelled ones. Their radioactivity was found in a one-to-five ratio which closely paralleled their respective immunolabelling intensity. Thus, the two subunits recognized by the antiserum are not present in stoichiometric proportions in the rat brain high-speed supernatant. These findings suggest the existence of two homodimeric GAD with common antigenic determinants which are present in different amounts. Immunoprecipitation curves of brain GAD from rat, mouse, rabbit, monkey, human, quail, frog, and trout were similar, with a less than 10-fold maximum shift in affinity for GAD. GAD immunoblots from the various higher vertebrates showed a pattern similar to that obtained in rat.(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.     

Effects of Variations in Glutamic Acid Decarboxylase Activity on Acute Oxygen Poisoning

Abstract— A study was made to test the influence of rapid variations in glutamic acid decarboxylase (GAD) activity on the susceptibility of rats to hyperbaric oxygen (HBO). GAD was inhibited by the convulsant drug unsymmetrical dimethylhydrazine (UDMH) and reactivated by pyridoxine (PYR) after onset of convulsive activity. There was a relatively long induction period after UDMH injection until the onset of convulsions and the predictable interictal periods between successive periodic convulsions made it possible to study the impact of variations in GAD activity on survival rates, suspectibility to HBO and brain glycogen levels in a time sequence after UDMH administration. The experiments showed that UDMH interferes with aerobic metabolism in brain in such a way that profound alterations in resistance to acute oxygen poisoning resulted. An accumulation of substrate proximal to the enzyme block is assumed to develop during UDMH poisoning. The protective effect against HBO toxicity that was achieved after reactivation of GAD by PYR injection, as well as the rapid re-establishment of glycogen levels, is believed to speak in favour of this hypothesis.     

Glutamic Acid Decarboxylase in Sea Lamprey (Petromyzon marinus): Characterization, Localization, and Developmental Changes

Abstract: We have carried out assays for glutamic acid decarboxylase (GAD) in homogenates of brain and spinal cord from larval and adult sea lamprey ( Petromyzon marinus ). The enzyme had similar characteristics in both stages. Optimal pH was 6.8; optimal temperature was 27–30° C; K _m at 27°C was 5 mM. GAD activity was distributed uniformly along the length of the spinal cord. Specific activities for the larval cord and brain were 26 and 63 nm CO₂/mg protein/h. respectively. The specific activities for the adult cord and brain were 29 and 236 nm CO₂/mg protein/h, respectively. Thus, the activity of cord homogenates did not change significantly between larval and adult stages, but that of the brain increased about fourfold.     

Resolution and Brain Regional Distribution of Cysteine Sulfinate Decarboxylase Isoenzymes from Hog Brain

Abstract: Cysteine sulfinate decarboxylase (CSD; EC 4.1.1.29) activity from porcine brain was resolved into three peaks by hydroxylapatite chromatography. The first two peaks (I and II) did not decarboxylate and were not inhibited by glutamate. The third peak (III) cochromatographed with glutamate decarboxylase (GAD; EC 4.1.1.15) activity. The K_m values of cysteine sulfinate for peaks I, II, and III were 5.5 × 10⁻⁴ m , 1.3 × 10⁻⁴ m , and 4.5 × 10⁻³ m , respectively. The possibility that the same enzyme was responsible for peak III CSD and GAD activities was suggested by several findings: (1) Mutual competitive inhibition was observed between glutamate and cysteine sulfinate for these activities. (2) Similar first-order heat-inactivation curves were obtained for peak III CSD and GAD when incubated at 55xBOC. (3) Both activities were inhibited similarily by ATP and chloride ion. High concentrations of glutamate (0. l m ) inhibited peak III CSD activity more than 90% but had no effect on either peak I or II CSD activities. This difference in sensitivity of the isoenzymes to inhibition by glutamate was used to examine the relative regional distributions and the relative contributions to total activity of the glutamate-sensitive (peak III CSD, GAD) and glutamate-insensitive (peaks I and II CSD) isoenzymes. Glutamate-insensitive CSD activity contributed only part of the total activity in all brain regions tested (ranging from 23% in the superior colliculus to 64% in the pons). However, the specific activity of glutamate-insensitive CSD was more constant than the total or glutamate-sensitive specific activities among the brain regions tested. The results indicate that GAD is responsible for a significant proportion of the total CSD activity in porcine brain.     

Effect of Nucleotides and Other Inhibitors on the Inactivation of Glutamate Decarboxylase

Abstract: The effects of 17 nucleotides and nucleotide analogs and 11 other compounds on the glutamate-promoted inactivation of brain glutamate decarboxylase were examined. Among the nucleotides, the major determinant of potency was the polyphosphate chain, Glutamate-promoted inactivation was strongly enhanced by low concentrations (<100 μM) of adenosine tetraphosphate and all eight nucleoside triphosphates tested. Nucleoside diphosphates enhanced inactivation, but were much less effective than the nucleoside triphosphates; nucleoside monophosphates were not effective. Modification of the polyphosphate chain of the nucleoside triphosphates also affected potency; adenylylimidodiphosphate and α,β-methylene ATP were about as effective as nucleoside diphosphates, but α,β-methylene ATP was nearly as effective as ATP. The nucleoside base had only a small effect on potency; purine nucleotides were more potent than pyrimidine nucleotides, and one nucleotide with a tricyclic base, 1, N⁶-etheno ATP, was as effective as the purine nucleoside triphosphates. The 2'-hydroxyl group of ribose was unimportant, since deoxy ATP was as effective as ATP. Three nonnucleotide polyanions were strong promoters of inactivation; inositol hexasulfate and 5-phosphorylribose 1-pyrophosphate were at least as effective as ATP; inositol hexaphosphate (phytate) was as effective as the nucleoside diphosphates. These results suggest that a major determinant of potency was a strong negative charge on the molecule. Negative charge was not sufficient, however, since fructose 1,6-bisphosphate did not promote inactivation. Inactivation by all of these compounds was slow, requiring more than 20 min for full effect. Two competitive inhibitors, chloride and glutarate, acted immediately and also reduced rather than enhanced glutamate-promoted inactivation.     

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.     

Co-localization of Glutamic Acid Decarboxylase and Phosphate-activated Glutaminase in Neurons of Lateral Reticular Nucleus in Feline Thalamus

Immunohistochemical methods were used to label singly and/or in combination glutamic acid decarboxylase (GAD, the sole synthesizing enzyme for the inhibitory neurotransmitter γ-aminobutyric acid) and phosphate-activated glutaminase (GLN, a synthesizing enzyme for glutamate) in neurons of lateral reticular nucleus (LRN) of thalamus of adult cats. (1) GAD- and GLN-immunoreactivity (IR) exhibited matching regional patterns of organization within LRN. (2) GAD- and GLN-IR co-localized within most if not all LRN neuronal cell bodies as shown by light microscopy. (3) GAD- and GLN-IR had distinct subcellular localizations in LRN neurons as shown by correlative light/electron microscopy. LRN neurons are important conceptual models where strongly inhibitory cells receive predominant excitatory glutamatergic afferents (from neocortex). Consistent with known actions of intermediary astrocytes, LRN neurons demonstrate GLN enrichment synergistically coupled with glutamatergic innervation to supplement the glutamate pool for GABA synthesis (via GAD) and for metabolic utilization (via the GABA shunt/tricarboxylic acid cycle) but not, apparently, for excitatory neurotransmission. Special issue dedicated to John P. Blass.     

Distribution of γ-Aminobutyric Acid and Glutamate Decarboxylase in the Layers of Rat Oviduct

An enzymatic microassay method for glutamate decarboxylase (GAD) and gamma-aminobutyric acid (GABA) was improved to yield a high sensitivity and a low blank. The 20-microns thick freeze-dried sections (0.2-1.5 micrograms dry weight) were prepared from the oviduct and ovary of rat. The analysis of these microsamples by the improved method showed that, contrary to the previous observations, the rat ovary is devoid of GAD activity and contains a trace amount of GABA. Both are present abundantly in the oviduct. In the oviduct mucosa, significant GAD activity was found in the estrous phase, whereas the activity was nearly null during other phases of the estrous cycle. GABA concentration in the oviduct mucosa was 10-fold higher than in the cerebral cortex; its variation during the estrous cycle was not remarkable. In the muscle layer of oviduct, GAD activity had a low peak in the estrous phase and GABA concentration was almost constant during the estrous cycle. The denervation experiment showed that GAD is present in the nerve terminals innervating the oviduct.     

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.     

Sulfur Amino Acid Metabolism in the Developing Rhesus Monkey Brain: Subcellular Studies of Taurine, Cysteinesulfinic Acid Decarboxylase, γ-Aminobutyric Acid, and Glutamic Acid Decarboxylase

Abstract: Taurine, cysteinesulfinic acid decarboxylase (CSAD), glutamate, γ-aminobutyric acid (GABA), and glutamic acid decarboxylase (GAD) were measured in subcellular fractions prepared from occipital lobe of fetal and neonatal rhesus monkeys. In addition, the distribution of [³⁵S]taurine in subcellular fractions was determined after administration to the fetus via the mother, to the neonate via administration to the mother prior to birth, and directly to the neonate at various times after birth. CSAD, glutamate, GABA, and GAD all were found to be low or unmeasurable in early fetal life and to increase during late fetal and early neonatal life to reach values found in the mother. Taurine was present in large amounts in early fetal life and decreased slowly during neonatal life, arriving at amounts found in the mother not until after 150 days of age. Significant amounts of taurine, CSAD, GABA, and GAD were associated with nerve ending components with some indication that the proportion of brain taurine found in these organelles increases during development. All subcellular pools of taurine were rapidly labeled by exogenously administered [³⁵S]taurine. The subcellular distribution of all the components measured was compatible with the neurotransmitter or putative neuro-transmitter functions of glutamate, GABA, and taurine. The large amount of these three amino acids exceeds that required for such function. The excess of glutamate and GABA may be used as a source of energy. The function of the excess of taurine is still not clear, although circumstantial evidence favors an important role in the development and maturation of the CNS.