Glutamate Dehydrogenase Reaction Research Articles

The real-time resolution of proton-related transient-state steps in an enzymatic reaction. The early steps in the oxidative deamination reaction of bovine liver glutamate dehydrogenase.

We introduce a novel transient-state kinetic approach which can resolve proton and product time courses into a series of individual steps that comprise the reaction path. We have applied this approach to the oxidative deamination reaction catalyzed by bovine liver glutamate dehydrogenase, measuring both the product (NADPH) and proton time courses at various pH values. The global treatment (over all pH values) resolves the very early portion of this reaction quantitatively and provides a continuous time course for each of the six protonic species. We propose the following mechanism: L-glutamate binds to an open conformation of the enzyme-NADP complex, forming salt bridges between its alpha- and gamma-carboxyl groups and the protonated forms of enzyme lysine residues 114 and 90, respectively. In this position, the alpha-H atom of the substrate is too far from the nicotinamide ring for hydride transfer to occur. In the next step, three events occur in a concerted manner: lysine 126 loses a proton and acquires a single water molecule; the active site cleft closes; bulk water is expelled; the substrate and coenzyme are forced closer together and remain in a nonaqueous environment during the ensuing chemical events, returning to an open conformation only in time to allow the product release steps to occur. Thus, substrate binding accomplishes a number of important tasks which are themselves an integral part of the catalytic mechanism. Combining the novel transient state approach developed here with steady-state kinetic information can produce a detailed mechanistic resolution of otherwise hidden steps.

Role of glutamate dehydrogenase reaction in the control of citrate pool in yeast

1.1. Role of NADP-glutamate dehydrogenase in the depletion of citrate was analyzed using permeabilized yeast cells.2.2. Citrate was converted to 2-oxoglutarate, which was then metabolized to glutamate by NADP-glutamate dehydrogenase in the presence of ammonium ion.3.3. Formation of 2-oxoglutarate plus glutamate was in good agreement with the concentration of citrate decreased. Glutamate formation can be a good indicator of the depletion of citrate, because 70% of the citrate decreased was converted to glutamate.4.4. Glycolytic activity was closely correlated with the decrease in citrate under the in situ conditions.5.5. NADP-glutamate dehydrogenase increased in anaerobically grown yeast cells.6.6. An effective depletion of citrate by increased synthesis of NADP-glutamate dehydrogenase can explain the lowered mechanism of citrate causing glycolytic stimulation under the anaerobic growth conditions of yeast.

Electrical control of the glutamate dehydrogenase reaction in polypyrrole membranes

The immobilization of enzymes is a key technology for constructing bioreactor and biosensor systems. Among a large variety of methods developed for the immobilization of enzymes, the electrochemical polymerization of pyrroles in the presence of enzymes is particularly interesting [l-4]: the electroconductivity of enzyme-containing polypyrrole membranes facilitates electron transfer between the immobilized redox enzyme and the polymer [5,6]. We have reported the preparation of enzyme-immobilized polypyrrole membranes [5,7-91 and its application to biosensors [8,9]. Both the amount of electrical charge on the conducting polymer membrane and its electroconductivity change when the potential applied to the membrane is varied. Consequently, the number of ions penetrating the membrane also changes 1101. Thus we can control the rate of enzymatic reaction in the polymer membrane which involves ionic substrates. In this study, we report the electrical control of the glutamate dehydrogenase reaction in a polypyrrole ,membrane.

Electrical control of the glutamate dehydrogenase reaction in polypyrrole membranes

The immobilization of enzymes is a key technology for constructing bioreactor and biosensor systems. Among a large variety of methods developed for the immobilization of enzymes, the electrochemical polymerization of pyrroles in the presence of enzymes is particularly interesting [l-4]: the electroconductivity of enzyme-containing polypyrrole membranes facilitates electron transfer between the immobilized redox enzyme and the polymer [5,6]. We have reported the preparation of enzyme-immobilized polypyrrole membranes [5,7-91 and its application to biosensors [8,9]. Both the amount of electrical charge on the conducting polymer membrane and its electroconductivity change when the potential applied to the membrane is varied. Consequently, the number of ions penetrating the membrane also changes 1101. Thus we can control the rate of enzymatic reaction in the polymer membrane which involves ionic substrates. In this study, we report the electrical control of the glutamate dehydrogenase reaction in a polypyrrole ,membrane.

Dual-enzyme fiber-optic biosensor for glutamate based on reduced nicotinamide adenine dinucleotide luminescence.

Response characteristics are presented for a dual-enzyme fiber-optic biosensor for glutamate. An enzyme layer composed of glutamate dehydrogenase (GDH) and glutamate-pyruvate transaminase (GPT) is used to produce reduced nicotinamide adenine dinucleotide (NADH) at the tip of a fiber-optic probe. NADH luminescence is monitored through this probe and the measured fluorescence intensity is related to the concentration of glutamate. GDH catalyzes the formation of NADH, and GPT drives the GDH reaction by removing a reaction product and regenerating glutamate. Optimal response is obtained in a pH 7.4 Tris-HCl buffer maintained at 25 degrees C in the presence of 4 mM NAD+ and 10 mM L-alanine. The temperature profile reveals a strong negative temperature effect which is attributed to the temperature dependency of NADH luminescence. Under optimal conditions, the sensor sensitivity is 0.127 nA/microM over the 1-10 microM concentration range, the detection limit is 0.13 microM, and response times range from 4 to 8 min. The sensor response is stable for 12 days when stored at 4 degrees C. Selectivity for glutamate is excellent over most of the common amino acids as well as ascorbic acid, uric acid, taurine, and GABA. Only slight responses were observed for glutamine and lysine. The effect of ammonia on the glutamate response was found to be minimal at total ammonia nitrogen concentrations as high as 200 microM.

Malate: A Possible Source of Error in the NAD Glutamate Dehydrogenase Assay

The effects of externally induced metabolic perturbations are often studied through changes of the enzyme activity patterns in crude plant extracts. From glutamate dehydrogenase (GDH) it is reported that environmental changes not only influence the amount of the enzymatic activity, but also the ratio of the aminating to the deaminating activities (NADH/NAD + ratio). Using crude cell extracts of suspension cultures of wheat (Triticum aestivum L. cv. Heines Koga II) we find evidence that the pretreatment of the homogenate directly influences this ratio. Dialysis of these crude cell extracts resulted in a 70% loss of the NAD+ activity, while the NADH activity remained unchanged. The deaminating activity in the dialysed extract could be completely restored upon addition of a dialysable factor which was identified to be malate. The interference of malate with the glutamate dehydrogenase reaction is caused through the action of malate dehydrogenase and glutamate oxaloacetate transaminase which are both present in high activities in the extracts. Only in exhaustively dialysed cell extracts can the proper deaminating GDH activity be determined. The results are discussed in the light of the controversial reports on the variable ratio of the NADH/NAD+activity of GDH.

Transduction of enzyme-ligand binding energy into catalytic driving force

We propose a testable general mechanism by which ligand binding energy can be used to drive a catalytic step in an enzyme catalyzed reaction or to do other forms of work involving protein molecules. This energy transduction theory is based on our finding of the widespread occurrence of ligand binding-induced protein macrostate interconversions each having a large invariant Δ H° accompanied by a small but highly variable Δ G°. This phenomenon, which can be recognized by the large Δ Cp°'s it generates, can provide the necessary energy input step but is not in itself sufficient to constitute a workable transduction mechanism. A viable mechanism requires the additional presence of an ‘energy transmission step’ which is terminated to trigger the ‘power’ stroke at a precise location on the reaction coordinate, followed by an energetically inexpensive ‘return’ step to restore the machine to its initial conditions. In the model we propose here, these additional steps are provided by the existence of ligand inducible 2-state transitions in the free enzyme and in each of the enzyme complexes that occur along the reaction coordinate, and by the selective blocking of certain of these interconversions by high energetic barriers. We provide direct experimental evidence supporting the facts that these additional mechanistic components do exist and that the liver glutamate dehydrogenase reaction is indeed driven by just such machinery. We describe some aspects of the chemical nature of these transitions, and evidence for their occurrence in other systems.

Glutamate Dehydrogenase Reaction as a Source of Glutamic Acid in Synaptosomes

The role of the glutamate dehydrogenase reaction as a pathway of glutamate synthesis was studied by incubating synaptosomes with 5 mM 15NH4Cl and then utilizing gas chromatography-mass spectrometry to measure isotopic enrichment in glutamate and aspartate. The rate of formation of [15N]glutamate and [15N]aspartate from 5 mM 15NH4Cl was approximately 0.2 nmol/min/mg of protein, a value much less than flux through glutaminase (4.8 nmol/min/mg of protein) but greater than flux through glutamine synthetase (0.045 nmol/min/mg of protein). Addition of 1 mM 2-oxoglutarate to the medium did not affect the rate of [15N]glutamate formation. O2 consumption and lactate formation were increased in the presence of 5 mM NH3, whereas the intrasynaptosomal concentrations of glutamate and aspartate were unaffected. Treatment of synaptosomes with veratridine stimulated reductive amination of 2-oxoglutarate during the early time points. The production of ([15N]glutamate + [15N]aspartate) was enhanced about twofold in the presence of 5 mM beta-(+/-)-2-aminobicyclo [2.2.1]heptane-2-carboxylic acid, a known effector of glutamate dehydrogenase. Supplementation of the incubation medium with a mixture of unlabelled amino acids at concentrations similar to those present in the extracellular fluid of the brain had little effect on the intrasynaptosomal [glutamate] and [aspartate]. However, the enrichment in these amino acids was consistently greater in the presence of supplementary amino acids, which appeared to stimulate modestly the reductive amination of 2-oxoglutarate. It is concluded: (a) compared with the phosphate-dependent glutaminase reaction, reductive amination is a relatively minor pathway of synaptosomal glutamate synthesis in both the basal state and during depolarization; (b) NH3 toxicity, at least in synaptosomes, is not referable to energy failure caused by a depletion of 2-oxoglutarate in the glutamate dehydrogenase reaction; and (c) transamination is not a major mechanism of glutamate nitrogen production in nerve endings.

Tissue distribution and subcellular localization of glutamate dehydrogenase in a freshwater air-breathing teleost, Heteropneustes fossilis

The nucleotide dependence, tissue distribution and subcellular localization of glutamate dehydrogenase (GDH) (both reductive amination and oxidative deamination) were studied in a freshwater air-breathing teleost, Heteropneustes fossilis. The oxidative deamination reaction of GDH was absolutely dependent on ADP and the reductive amination reaction was independent of ADP. ADP acted as a positive modulator for the latter reaction. Both NADH and NADPH served equally well as coenzymes for reductive amination reaction whereas in the oxidative deamination reaction only NAD+ and not NADP+ acted as the coenzyme. GDH activity was found to be more stable in phosphate buffer than in Tris buffer. The enzyme activities were found to be at a maximum in liver followed by kidney, gill, muscle and brain. GDH activity was found to be mitochondrial in all the tissues studied. A three to four times higher reductive amination reaction than oxidative deamination reaction suggested an important role of GDH in ammonia detoxification in various tissues of H. fossilis.

Failure of glutamate dehydrogenase system to predict oxygenation state of human skeletal muscle

In a recent study, the total tissue contents of glutamate (Glu), ammonium (NH+4), and 2-oxoglutarate (2-OG) were used to estimate changes in the mitochondrial redox state ([NAD+]/[NADH]) of contracting skeletal muscle with intact circulation [Am. J. Physiol. 253 (Cell Physiol. 22): C263-C268, 1987]. These metabolites participate in the glutamate dehydrogenase (GDH) reaction, which, based on a number of assumptions, theoretically enables calculation of the mitochondrial redox state as follows (brackets indicate concentrations): [NAD+]/[NADH] = ([NH+4] [2-OG])/[( Glu]Kapp), where Kapp is the apparent equilibrium constant for GDH. The purpose of this study was to determine whether changes in the total tissue contents of Glu, NH+4, and 2-OG could be used to predict a reduction of the mitochondrial redox state in anoxic skeletal muscle. Anoxia was induced in the quadriceps femoris muscle by 10 min of circulatory occlusion (low metabolic rate) and isometric contraction to fatigue (high metabolic rate). The mean (+/- SE) value for the metabolite ratio ([NH+4][2-OG]/[Glu]) at rest was 6 +/- 3 mmol/kg dry wt (x 10(-4]. No significant change occurred after circulatory occlusion (4 +/- 2 x 10(-4); P greater than 0.05), whereas an almost 60-fold increase was observed after isometric contraction (P less than 0.05). Because the muscle was anoxic under both conditions, a significant decrease in the metabolite ratio should have occurred. These data demonstrate that changes in total tissue contents of Glu, NH+4, and 2-OG cannot be used to estimate changes in the redox and oxygenation state of mitochondria in intact human skeletal muscle.

Flow‐Injection Analysis of Amino Acids and Their Metabolites by Immobilized Vitamin B6‐Dependent Enzymes

Sensitive flow-injection analyses of aspartate, glutamate, 2-oxoglutarate, and oxaloacetate were developed. The analytes were enzymatically coupled with NADH which was monitored by light emission from immobilized bacterial bioluminescence enzymes. Aspartate (or oxaloacetate) was assayed on the basis of NADH consumption by introducing the sample through a coimmobilized aspartate aminotransferase-malate dehydrogenase column. The assay responded linearly from 100 pmoles to 5 nmoles per assay. Glutamate (2-oxoglutarate) was determined by formation of NADH in the glutamate dehydrogenase reaction. The measuring range for glutamate was from 10 pmoles to 100 nmoles per assay. The precision of the flow-injection method was generally excellent, and the sensitivities of the described assays were 100-1000-fold higher than with spectrophotometric methods. The immobilized enzyme preparations were stable for several months in storage, and the enzyme columns could be used for 600-800 analyses. Flow-injection analyses of amino acids and related compounds by NADH/bioluminescence-coupled reactions provide a sensitive, fast, and inexpensive assay method for a wide variety of purposes.

One-step and two-step fluorometric assay methods for general aminotransferases using glutamate dehydrogenase

One-step and two-step assay methods were developed for general aminotransferases (ATs) utilizing Glu and α-ketoglutarate (α-KG) as the donor and acceptor of the amino group, by coupling a glutamate dehydrogenase (GDH) reaction with the AT reactions. For instance, α-KG formed from Glu by AspAT is reduced and aminated back to Glu by GDH, which oxidizes NADPH corresponding to the amount of α-KG formed. In the reverse reaction, Glu formed from α-KG is oxidized and deaminated back to α-KG by GDH, which reduces NADP + corresponding to the amount of Glu formed. In the one-step assay, both AT and GDH reactions are simultaneously carried out, and the decrease or increase in NADPH fluorescence is directly monitored in 1.0 ml of the reaction mixture for both forward and reverse reactions. In the two-step assay, an AT reaction is carried out and stopped once at the first step. Next, the α-KG or Glu formed is determined fluorometrically in a GDH reaction. In order to analyze partially purified or crude samples, the one-step assay is convenient for surveying the relative activities. The two-step assay is useful for analyzing the properties of enzymes and measuring activities under conditions approaching the optimum. AspAT can be replaced by other general ATs using enzyme-specific substrates in place of oxalacetate and Asp in the assay mixture. The present methods were successfully applied to four enzymes (Asp, alanine, γ-aminobutyrate, and ornithine ATs) in tissue homogenates and a mitochondrial extract.

Transport of glutamine by Streptococcus bovis and conversion of glutamine to pyroglutamic acid and ammonia.

Streptococcus bovis JB1 cells energized with glucose transported glutamine at a rate of 7 nmol/mg of protein per min at a pH of 5.0 to 7.5; sodium had little effect on the transport rate. Because valinomycin-treated cells loaded with K and diluted into Na (pH 6.5) to create an artificial delta psi took up little glutamine, it appeared that transport was driven by phosphate-bond energy rather than proton motive force. The kinetics of glutamine transport by glucose-energized cells were biphasic, and it appeared that facilitated diffusion was also involved, particularly at high glutamine concentrations. Glucose-depleted cultures took up glutamine and produced ammonia, but the rate of transport per unit of glutamine (V/S) by nonenergized cells was at least 1,000-fold less than the V/S by glucose-energized cells. Glutamine was converted to pyroglutamate and ammonia by a pathway that did not involve a glutaminase reaction or glutamate production. No ammonia production from pyroglutamate was detected. S. bovis was unable to take up glutamate, but intracellular glutamate concentrations were as high as 7 mM. Glutamate was produced from ammonia via a glutamate dehydrogenase reaction. Cells contained high concentrations of 2-oxoglutarate and NADPH that inhibited glutamate deamination and favored glutamate formation. Since the carbon skeleton of glutamine was lost as pyroglutamate, glutamate formation occurred at the expense of glucose. Arginine deamination is often used as a taxonomic tool in classifying streptococci, and it had generally been assumed that other amino acids could not be fermented. To our knowledge, this is the first report of glutamine conversion to pyroglutamate and ammonia in streptococci.

Enantioselective synthesis of various D-amino acids by a multi-enzyme system

We have developed an effective method for the synthesis of various D-amino acids from the corresponding α-keto acids and ammonia by coupling four enzyme reactions catalyzed by D-amino acid aminotransferase, glutamate racemase, glutamate dehydrogenase, and formate dehydrogenase. In this system, D-glutamate is continuously regenerated from α-ketoglutarate, ammonia and NADH by the coupled reaction of glutamate dehydrogenase and glutamate racemase, and used as an amino donor for the enantioselective D-amino acid synthesis by the D-amino acid aminotransferase reaction. The unidirectional formate dehydrogenase reaction is also coupled to regenerate NADH consumed. Under the optimum conditions, D-enantiomers of valine, alanine, α-keto analogues with a molar yield higher than 80%.

Mechanism of formation of bound alpha-iminoglutarate from alpha-ketoglutarate in the glutamate dehydrogenase reaction. A chemical basis for ammonia recognition.

Two mechanisms have been postulated for the formation of bound alpha-iminoglutarate intermediate during the glutamate dehydrogenase-catalyzed reductive amination of alpha-ketoglutarate; one involves the nucleophilic attack of ammonia on a covalently bound Schiff base in the enzyme-NADPH-alpha-ketoglutarate complex, and the other involves the reaction of ammonia with the carbonyl group of alpha-ketoglutarate in the ternary complex. We have measured the rates of carbonyl oxygen exchange in the complex to unambiguously distinguish between these two mechanisms. We find that the loss of label in the carbonyl oxygen-labeled ternary complex is at least 10(5) times slower than the rate of the reductive amination reaction. Therefore, the former mechanism cannot be operative. We also find that (i) the carbonyl oxygen exchange in free alpha-ketoglutarate proceeds without any significant catalysis by its gamma-carboxylate group; (ii) this exchange reaction has energy parameters which are comparable to those observed for the hydration of simple aliphatic ketones; and (iii) the carbonyl oxygen exchange in bound alpha-ketoglutarate is slower than that in the free keto acid over a wide pH range. We conclude that the oxygen exchange in the free and bound alpha-ketoglutarate must occur via a gem-diol intermediate. The observation that the enzyme inhibits the reaction of water with alpha-ketoglutarate while it catalyzes the reaction of ammonia with the same keto acid points to an extraordinary recognition of ammonia by the enzyme. We interpret this observation by assuming that the enzyme-NADPH-alpha-ketoglutarate complex exists in two forms, a predominant form which is produced rapidly upon mixing the components together and an unstable form which is produced in trace amounts from the predominant form via a gem-diol intermediate. These two forms are presumed to differ in the spatial relationship of the carbonyl group to the enzyme functional groups. The carbonyl group in the unstable form is assumed to be surrounded by the same enzyme groups as the iminium ion is in the bound iminoglutarate complex. We ascribe the remarkable catalysis of the ammonia reaction and the inhibition of the water reaction by the enzyme to the opposing interactions of the iminium and carbonyl groups with these surrounding enzyme groups.

Short-term metabolic fate of [13N]ammonia in rat liver in vivo.

The short-term metabolic fate of [13N]ammonia in the livers of adult male, anesthetized rats was determined. Following a bolus injection of tracer quantities of [13N]ammonia into the portal vein, the single pass extraction was approximately 93%, in good agreement with the portal-hepatic vein difference of approximately 90%. High performance liquid chromatographic analysis of deproteinized liver samples indicated that labeled nitrogen is exchanged rapidly among components of: mitochondrial aspartate aminotransferase and glutamate dehydrogenase reactions and cytoplasmic aspartate aminotransferase and alanine aminotransferase reactions (t1/2 for the exchange of label toward equilibrium is on the order of seconds). Comparison of specific activities of glutamate and ammonia suggests that at 5 s most labeled glutamate was mitochondrial, whereas at 60 s approximately 93% was cytosolic; this change is presumably brought about by the combined action of the mitochondrial and cytosolic aspartate aminotransferases and the aspartate carrier of the malate-aspartate shuttle. Specific activity measurements of glutamate, alanine, and aspartate are in accord with the proposal by Williamson et al. (Williamson, D.H., Lopes-Vieira, O., and Walker, B. (1967) Biochem. J. 104, 497-502) that the components of the aspartate aminotransferase reaction are in thermodynamic equilibrium, whereas the components of the alanine aminotransferase reaction are in equilibrium but compartmented in the rat liver. Despite considerable label in citrulline at early time points, no radioactivity (less than or equal to 0.25% of the total) was detected in carbamyl phosphate, suggesting very efficient conversion to citrulline with little free carbamyl phosphate accumulating in the mitochondria. Our data also show that some portal vein-derived ammonia is metabolized to glutamine in the rat liver, but the amount is small (approximately 7% of that metabolized to urea) in part because liver glutamine synthetase is located in a small population of perivenous cells "downstream" from the urea cycle-containing periportal cells. Finally, no tracer evidence could be found for the participation of the purine nucleotide cycle in ammonia production from aspartate. The present work continues to emphasize the usefulness of [13N]ammonia for short-term metabolic studies under truly tracer conditions, particularly when turnover times are on the order of seconds.

Metabolic Alterations Associated with Proliferation of Mitogen-Activated Lymphocytes and of Lymphoblastoid Cell Lines: Evaluation of Glucose and Glutamine Metabolism

In vitro resting, short-term mitogen stimulated, and proliferating rat thymocytes as well as established human T and B lymphoblastoid cell lines were compared in their capacity to metabolize glucose and glutamine as energy source. Furthermore, the pathways of glutamine metabolism in these cells were studied. Compared with resting thyrnocytes, glucose metabolism of proliferating thymocytes was 36-fold increased during the incubation; 92 % of the amount of glucose utilized was converted into trioses mainly lactate, whereas resting cells metabolized only 38 % to trioses. However, the latter oxidized 19 % of glucose to CO 2, as opposed to 1.1 % by the proliferating cells. Rates of glucose uptake and degradation to products by the malignant T lymphoblastoid cell line (jurkat) were nearly identical with those observed with proliferating rat thyrnocytes, whereas the benign B lymphoblastoid cell lines (DHg-B-1 and LV-B-1) showed significantly higher rates of glucose metabolism. All three transformed lymphoblastoid cell lines, however, metabolized glucose almost completely to lactate as did the proliferating rat thymocytes. Lymphocytes are able to utilize glutamine with glutamate, aspartate and ammonia being the major end-products. A complete recovery of glutamine carbon in the products was obtained with all cells. Glutamine utilization by incubated proliferating rat thymocytes was 8-fold increased as compared to the resting cells. Again the human T lymphoblastoid cell line showed the same rates of glutamine uptake and conversion into products as did the proliferating rat thymocytes, whereas both B lymphoblastoid cell lines had about 2.5-fold enhanced rates as compared to the T cell line. The results indicate that during lymphocyte proliferation caused by mitogen stimulation as well as by permanent transformation into lymphoblastoid cell lines glucose metabolism is altered not only quantitatively but also qualitatively by changing from partly aerobic to almost complete anaerobic glucose breakdown. Glutamine has been found to be a suitable energy source for lymphocytes. About 75 % of the amount of glutamate derived from glutamine entered into the citric acid cycle via the aspartate aminotransferase, and the remaining 25% via the glutamate dehydrogenase reaction. The changes in metabolic rates observed in proliferating as well as in transformed or leukemic lymphocytes appear to be reliable parameters to characterize the state of lymphocyte activation or to evaluate the efficacy of lymphokines.

The purine nucleotide cycle and ammoniagenesis in rat kidney tubules.

The contribution of the purine nucleotide cycle to renal ammoniagenesis was examined in cortical tubule suspensions prepared from acidotic rats and incubated with [alpha-15N]glutamine, [15N]glutamate, or [15N]aspartate. Labeling of ammonia and adenine nucleotides was determined after enzymatic transformations designed to circumvent the technical problem that 15NH3 and H2O have the same nominal mass. Labeling of the adenine nucleotide was undetectable (less than 10%) even after 1 h of incubation. From the measured concentrations of adenine nucleotides and ammonia and the labeling of the ammonia, the flux through the purine nucleotide cycle was calculated to account for less than 1% of the deamination of alpha-amino groups from all three substrates. The glutamate dehydrogenase reaction is therefore the likely pathway for deamination. The rate of 15NH3 production from [alpha-15N]glutamine was two or three times greater than from added [15N]glutamate, indicating a preference for intracellularly generated glutamate. 15NH3 production from added [15N]aspartate was similar to and perhaps slightly greater than that from added [15N]glutamate.

Histochemical demonstration of sodium-dependent glutamate uptake in brain tissues by glutamate dehydrogenase reaction

Using a special tetrazolium salt technique, a striking correlation was observed between Na+ concentration of the incubation medium and the formation of formazan catalyzed by glutamate dehydrogenase (GDH) in glutamatergic neuropil areas of the hippocampal formation, cerebellum, and other brain regions. Na+ concentrations of 130-150 mmol/l caused maximal formazan production. The GDH catalyzed sodium-dependent increase in formazan production is suggested to be a consequence of the sodium dependence of glutamate uptake in glutamatergic brain structures supplying the enzyme with substrate.

Histophotometric evaluation of glutamate dehydrogenase activity of the rat hippocampal formation during postnatal development, with special reference to the glutamate transmitter metabolism.

Transmitter glutamate/aspartate synthesis is known to proceed along different metabolic pathways. In this light, the functional relevance of glutamate dehydrogenase in postnatally maturing glutamatergic/aspartatergic structures was studied by means of quantitative enzyme histochemistry. The basic requirements concerning the kinetics and calibration of the histochemical glutamate dehydrogenase reaction used were proved to be met in order to obtain valid quantitative data. The histochemically demonstrable activity of glutamate dehydrogenase (EC 1.4.1.3) in the hippocampal formation of the rat increased markedly during postnatal development. On day 30, the distribution pattern observed was similar to that in adult animals. While the enzyme activity rose within cell body layers from day 0 to day 30 by 240-285%, the increase in neuropil layers was found to be up to 830%. Maximum values were seen in the stratum lacunosum-moleculare of CA1 and CA3 and the stratum moleculare of the dentate fascia on day 30. Since the hippocampal neuropil is supposed to be copiously provided with glutamatergic (and aspartatergic?) structures which become functional in rats during the first weeks of postnatal life, the increase in enzyme activity is discussed to be primarily a consequence of maturing synaptic systems using glutamate and/or aspartate as transmitters.