STUDIES ON THE REGULATION OF GABA SYNTHESIS: THE INTERACTION OF ADENINE NUCLEOTIDES AND GLUTAMATE WITH BRAIN GLUTAMATE DECARBOXYLASE

The effects of adenine nucleotides and glutamate on glutamate decarboxylase were studied in a dialyzed, high-speed supernatant of rat brain. When incubated with 10 μm -pyridoxal-P the enzyme was strongly inhibited by ATP, ADP and their Mg²⁺ complexes at concentrations which were well below tissue levels. The enzyme was not significantly inhibited by 15 mm -AMP or by 100 μM-3′-5’cyclic AMP or 3′-5’cyclic GMP. Inhibition by the nucleotides cannot be described in conventional steady-state kinetic terms. Addition of ATP in the presence of pyridoxal-P resulted in a slow, progressive decrease in the reaction rate which was similar to the inactivation observed when the enzyme was incubated in the absence of pyridoxal-P. The progressive inactivation in the presence of ATP was minimal at concentrations of glutamate which were well below K_m and became much more pronounced at higher glutamate concentrations. Addition of suprasaturating amounts of pyridoxal-P late in the incubation when the enzyme was almost completely inactivated resulted in an immediate and complete reactivation of the enzyme. Inhibition by ATP could be prevented by addition of saturating amounts of pyridoxal-P at the start of the reaction and was also relieved by addition of potassium phosphate buffer. The results suggest that inhibition by the nucleotides involves the prior formation of the inactive apoenzyme which results from the glutamate-promoted dissociation of pyridoxal-P. In the absence of the nucleotides, the enzyme is normally reactivated by the added pyridoxal-P. The nucleotides act to block this reassociation of pyridoxal-P with the apoenzyme thereby producing a progressive inactivation of the enzyme. The implications of these results for the regulation of GABA synthesis are discussed.     

EFFECTS OF DEPOLARIZATION ON COFACTOR REGULATION OF GLUTAMIC ACID DECARBOXYLASE IN SUBSTANTIA NIGRA SYNAPTOSOMES

Abstract— The level of saturation of glutamate decarboxylase (GAD) by cofactor, pyridoxal-5'-phosphate (pyridoxal-P), determined in synaptosomes prepared from substantia nigra tissue, was reduced from 45 to 28%; when ATP was included in the homogenizing medium to prevent nonspecific activation of GAD by endogenous pyridoxal-P. When the synaptosomes were incubated for 5–20 min at 37°C in Krebs-Ringer phosphate buffer (KRP), the level of saturation of GAD by cofactor decreased further, from 28 to 20%. Depolarization of the nigral synaptosomes by either high K⁺ (55 mM) or veratridine resulted in a significant increase in the level of GAD saturation by cofactor, to 32 and 41%. respectively. Omitting Ca²⁺ from the incubation medium blocked the depolarization-induced rise in the level of saturation. Depolarization with high K⁺ and veratridine also caused a significant decrease in the ATP concentration in the synaptosomes. No difference in ATP concentration was observed when the samples were incubated at 37°C for 5–20min or incubated in the absence of added Ca²⁺ with high K⁺. Results provide further evidence that in vivo brain GAD is largely unsaturated by cofactor and support the possibility that increased release and utilization of GABA may be associated with increases in the amount of pyridoxal-P endogenously bound to GAD in nerve terminals.     

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)     

STIMULATION BY PHOSPHATE OF THE ACTIVATION OF GLUTAMATE APODECARBOXYLASE BY PYRIDOXYL-5'-PHOSPHATE AND ITS IMPLICATIONS FOR THE CONTROL OF GABA SYNTHESIS

Abstract— Previous studies have shown that inorganic phosphate relieves the inhibition of brain glutamate decarboxylase by ATP. Since the evidence suggested that inhibition by ATP resulted in formation of the inactive apoenzyme, it was possible that P_i might relieve this inhibition by promoting activation of the apoenzyme by its cofactor, pyridoxal-5′-phosphate. We have investigated this possibility using apoenzyme from rat brain. In most experiments, apoenzyme was prepared by incubating glutamate decarboxylase with 20 μM-aminooxyacetate followed by exhaustive dialysis. Activation was studied by incubating the enzyme with pyridoxal-P under various conditions after which the amount of holoenzyme formed was measured by a 5 min enzyme assay. In the absence of P_i there was an initially rapid but incomplete activation by pyridoxal-P which stopped after 15-20 min. The amount of holoenzyme formed after 20 min increased without saturating as the concentration of pyridoxal-P was raised from 0.03 to 250 μm Addition of 1-10mm -P_i increased the initial rate of activation and the final degree of activation. P_i stimulated activation whether present initially or added after 15 min, indicating that incomplete activation in the absence of P_i was not attributable to destruction of pyridoxal-P or irreversible inactivation of the enzyme. P_i reduced the concentration of pyridoxal-P, giving half maximal activation from about 10 μm to about 0.07 μm . Pi also stimulated the residual enzyme activity in the apoenzyme preparation in the absence of added pyridoxal-P, suggesting that P_i may convert the holoenzyme to a more active form. P_i had very similar effects on glutamate apodecarboxylase from vitamin B₆-deficient rats and also stimulated the activation of apoenzyme which had been prepared by dissociation of the cofactor by treatment with glutamate, indicating that stimulation by P_i is unrelated to the method of preparing apoenzyme. Activation was also strongly stimulated by methylphosphonate and arsenate and weakly stimulated by sulfate. Trichloromethylphosphonate, cacodylate, pyrophosphate and AMP had little or no effect. The results suggest that P_i relieves the inhibition by ATP, at least in part, by promoting the activation of glutamate apodecarboxylase, and that P_i may be an important factor in the regulation of glutamate decarboxylase in vivo.     

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.     

Reactivation of substrate-inactivated brain glutamate decarboxylase

The effects of ATP and inorganic phosphate (Pi) on the reactivation of glutamate apodecarboxylase by its cofactor pyridoxal-5'-phosphate (pyridoxal-P) was studied. Apoenzyme was prepared by preincubation with glutamate. Apoenzyme prepared with glutamate alone was reactivated slowly and incompletely by adding a saturating concentration of pyridoxal-P (20 microM). Reactivation was slightly enhanced by 1-10 mM Pi. Reactivation by pyridoxal-P plus Pi was greatly enhanced by the presence of low concentrations (less than 100 microM) of ATP during the preparation of apoenzyme with glutamate. Reactivation was much lower if Pi was omitted. Enhancement of reactivation by ATP was due to its effect during apoenzyme formation, since ATP did not enhance reactivation if added only during reactivation and since the enhancing effect persisted after the removal of free ATP by chromatography on Sephadex G-25 after apoenzyme preparation and before reactivation. Reactivation was inhibited by high concentrations of ATP (greater than 100 microM), possibly by competition of ATP for the cofactor binding site. Four factors (glutamate, pyridoxal-P, ATP, and Pi) control a cycle of inactivation and reactivation that appears to be important in the regulation of brain glutamate decarboxylase.     

Motifs and structural fold of the cofactor binding site of human glutamate decarboxylase.

The pyridoxal-P binding sites of the two isoforms of human glutamate decarboxylase (GAD65 and GAD67) were modeled by using PROBE (a recently developed algorithm for multiple sequence alignment and database searching) to align the primary sequence of GAD with pyridoxal-P binding proteins of known structure. GAD's cofactor binding site is particularly interesting because GAD activity in the brain is controlled in part by a regulated interconversion of the apo- and holoenzymes. PROBE identified six motifs shared by the two GADs and four proteins of known structure: bacterial ornithine decarboxylase, dialkylglycine decarboxylase, aspartate aminotransferase, and tyrosine phenol-lyase. Five of the motifs corresponded to the alpha/beta elements and loops that form most of the conserved fold of the pyridoxal-P binding cleft of the four enzymes of known structure; the sixth motif corresponded to a helical element of the small domain that closes when the substrate binds. Eight residues that interact with pyridoxal-P and a ninth residue that lies at the interface of the large and small domains were also identified. Eleven additional conserved residues were identified and their functions were evaluated by examining the proteins of known structure. The key residues that interact directly with pyridoxal-P were identical in ornithine decarboxylase and the two GADs, thus allowing us to make a specific structural prediction of the cofactor binding site of GAD. The strong conservation of the cofactor binding site in GAD indicates that the highly regulated transition between apo- and holoGAD is accomplished by modifications in this basic fold rather than through a novel folding pattern.     

Pyridoxal phosphate protects against an irreversible temperature-dependent inactivation of hepatic delta-aminolevulinic acid synthase

The stability of hepatic delta-aminolevulinic acid synthase (ALAS), the first and rate-limiting enzyme of the heme biosynthetic pathway, was investigated. Incubation of the mitochondrial matrix fraction obtained from either control or allylisopropylacetamide-induced rats at 37 degrees C in Tris-Cl, pH 7.4, EDTA, and dithiothreitol resulted in a rapid decrease in ALAS activity such that 50-70% of the activity was lost after 30 min. Similar decreases in ALAS activity were observed when a cytosolic fraction from the induced animals was incubated at 37 degrees C. Addition of 0.1 mM pyridoxal-P, the cofactor of ALAS, to the preincubation medium completely prevented the observed loss of activity; however, dialysis of the inactive matrix fraction against several changes of buffer containing pyridoxal-P did not restore activity, suggesting that the inactivation was irreversible. These decreases in ALAS activity in the absence of pyridoxal-P were temperature dependent, as a 55% loss of ALAS activity was observed after a 60-min incubation at 30 degrees C, while the enzyme was completely stable when preincubated at 22 degrees C for 60 min. This inactivation of ALAS does not appear to involve proteolytic digestion, as addition of a wide spectrum of protease inhibitors to the preincubation medium in the absence of pyridoxal-P did not protect against the inactivation. The suggestion is made that the cofactor, pyridoxal-P, may dissociate from the enzyme during the preincubation and, consequently, the apoenzyme may be irreversibly inactivated at temperatures above 22 degrees C.     

Cofactor interactions and the regulation of glutamate decarboxylase activity

More than 50% of glutamate decarboxylase (GAD) in brain is present as apoenzyme. Recent work has opened the possibility that apoGAD can be studied in brain by labeling with radioactive cofactor. Such studies would be aided by a compound that inhibits specific binding. One possibility is 4-deoxy-pyridoxine 5-phosphate, a close structural analog of the cofactor pyridoxal 5-phosphate. The effects of deoxypyridoxine-P on the cyclic series of reactions that interconverts apo- and holoGAD was investigated and found to be consistent with simple competitive inhibition of the activation of apoGAD by pyridoxal-P. As expected from the cycle GAD was inactivated when incubated with glutamate and deoxypyridoxine-P even though cofactor was present, but no inactivation was observed with deoxypyridoxine-P in the absence of glutamate. Deoxypyridoxine-P also stabilized apoGAD against heat denaturation. These effects were quantitatively accounted for by a kinetic model of the apo-holoGAD cycle. Deoxypyridoxine-P inhibited the labeling by [³²P]pyridoxal-P of GAD isolated from rat brain. Hippocampal extracts were labeled with [³²P]pyridoxal-P and analyzed by SDS-polyacrylamide gel electrophoresis. Remarkably few bands were strongly labeled. The major labeled band (at 63 kDa) corresponded to one of the forms of GAD. Other strongly-labeled bands were observed at 65 kDa (corresponding to the higher molecular weight form of GAD) and at 69–72 kDa. Labeling of the 63- and 65-kDa bands was inhibited by deoxypyridoxine-P, but the 69–72 kDa bands were unaffected, suggesting that the latter were non-specifically labeled. The results suggest that the 63-kDa form of GAD makes up the majority of apoGAD in hippocampus.Special issue dedicated to Dr. Eugene Roberts.     

Structural features and regulatory properties of the brain glutamate decarboxylases

It is widely recognized that the two major forms of GAD present in adult vertebrate brains are each composed of two major sequence domains that differ in size and degree of similarity. The amino-terminal domain is smaller and shows little sequence identity between the two forms. This domain is thought to mediate the subcellular targeting of the two GADs. Substantial parts of the amino-terminal domain appear to be exposed and flexible, as shown by proteolysis experiments and the locations of posttranslational modifications. The carboxyl-terminal sequence domain contains the catalytic site and shows substantial sequence similarity between the forms. The interaction of GAD with its cofactor, pyridoxal-5' phosphate (pyridoxal-P), plays a key role in the regulation of GAD activity. Although GAD(65) and GAD(67) interact differently with pyridoxal-P, their cofactor-binding sites contain the same set of nine putative cofactor-binding residues and have the same basic structural fold. Thus the cofactor-binding differences cannot be attributed to fundamental structural differences between the GADs but must result from subtle modifications of the basic cofactor-binding fold. The presence of another conserved motif suggests that the carboxyl-terminal domain is composed of two functional domains: the cofactor-binding domain and a small domain that closes when the substrate binds. Finally, GAD is a dimeric enzyme and conserved features of GADs superfamily of pyridoxal-P proteins indicate the dimer-forming interactions are mediated mainly by the carboxyl-terminal domain.     

Cofactor and tryptophan accessibility and unfolding of brain glutamate decarboxylase

Cofactor and tryptophan accessibility of the 65-kDa form of rat brain glutamate decarboxylase (GAD) was investigated by fluorescence quenching measurements using acrylamide, I-, and Cs+ as the quenchers. Trp residues were partially exposed to solvent. I- was less able and Cs+ was more able to quench the fluorescence of Trp residues in the holoenzyme of GAD (holoGAD) than the apoenzyme (apoGAD). The fraction of exposed Trp residues were in the range of 30-49%. In contrast, pyridoxal-P bound to the active site of GAD was exposed to solvent. I- was more able and Cs+ was less able to quench the fluorescence of pyridoxal-P in holoGAD. The cofactor was present in a positively charged microenvironment, making it accessible for interactions with anions. A difference in the exposure of Trp residues and pyridoxal-P to these charged quenchers suggested that the exposed Trp residues were essentially located outside of the active site. Changes in the accessibility of Trp residues upon pyridoxal-P binding strongly supported a significant conformational change in GAD. Fluorescence intensity measurements were also carried out to investigate the unfolding of GAD using guanidine hydrochloride (GdnHCl) as the denaturant. At 0.8-1.5 M GdnHCl, an intermediate step was observed during the unfolding of GAD from the native to the denatured state, and was not found during the refolding of GAD from the denatured to native state, indicating that this intermediate step was not a reversible process. However, at >1.5 M GdnHCl for holoGAD and >2.0 M GdnHCl for apoGAD, the transition leading to the denatured state was reversible. It was suggested that the intermediate step involved the dissociation of native dimer of GAD into monomers and the change in the secondary structure of the protein. Circular dichroism revealed a decrease in the alpha-helix content of GAD from 36 to 28%. The unfolding pattern suggested that GAD may consist of at least two unfolding domains. Unfolding of the lower GdnHCl-resisting domain occurred at a similar concentration of denaturant for apoGAD and holoGAD, while unfolding of the higher GdnHCl-resisting domain occurred at a higher concentration of GdnHCl for apoGAD than holoGAD.     

Stability and Activation of Glutamate Apodecarboxylase from Pig Brain

The stability and activation of glutamate apodecarboxylase was studied with three forms of the enzyme from pig brain (referred to as the alpha, beta, and gamma forms). Apoenzyme was prepared by incubating the holoenzyme with aspartate followed by chromatography on Sephadex G-25. Apoenzyme was much less stable than holoenzyme to inactivation by heat (for beta-glutamate decarboxylase (beta-GAD) at 30 degrees C, t1/2 values of apo- and holoenzyme were 17 and greater than 100 min). ATP protected holoenzyme and apoenzyme against heat inactivation. The kinetics of reactivation of apoenzyme by pyridoxal-P was consistent with a two-step mechanism comprised of a rapid, reversible association of the cofactor with apoenzyme followed by a slow conversion of the complex to active holoenzyme. The reactivation rate constant (kr) and apparent dissociation constant (KD) for the binding of pyridoxal-P to apoenzyme differed substantially among the forms (for alpha-, beta-, and gamma-GAD, kr = 0.032, 0.17, and 0.27 min-1, and KD = 0.014, 0.018, and 0.04 microM). ATP was a strong competitive inhibitor of activation (Ki = 0.45, 0.18, and 0.39 microM for alpha-, beta-, and gamma-GAD). In contrast, Pi stimulated activation at 1-5 mM but inhibited at much higher concentrations. The results suggest that ATP is important in stabilizing the apoenzyme in brain and that ATP, Pi, and other compounds regulate its activation.     

Conformational alteration in serum albumin as a carrier for pyridoxal phosphate: a distinction from pyridoxal phosphate-dependent glutamate decarboxylase

The conformation of bovine serum albumin (BSA), a pyridoxal phosphate (pyridoxal-P) carrier, was investigated by using uv/visible spectrophotometry, fluorescence spectroscopy, circular dichroism, and differential scanning microcalorimetry. Upon interacting with pyridoxal-P, the uv/visible absorption spectrum of BSA exhibits peaks at 330 and 392 nm due to the formation of a Schiff base. Pyridoxal-P quenches the fluorescence emission intensity (excited at 295 or 280 nm) by 24% and enhances fluorescence steady-state polarization of BSA by 20%. These observations suggest a conformational change in BSA when it interacts with pyridoxal-P. However, this conformational change appears to be small since circular dichroism showed only a 2-4% decrease in the alpha-helical content of BSA and no change in the beta-sheet content, and differential scanning microcalorimetry yielded only a 10% change in the enthalpy of thermal unfolding of BSA. 2-Aminoethylisothiouronium bromide, an antioxidant, causes no effect on either uv/visible absorption spectrum or fluorescence emission intensity of BSA, suggesting that BSA lacks sensitive sulfhydryl groups. To help in understanding BSA as a carrier for pyridoxal-P, the results were compared with those for glutamate decarboxylase (GAD), a pyridoxal-P-dependent protein, which requires pyridoxal-P as the cofactor for activity. Although BSA and GAD exhibit comparable molecular weights (66430 versus 65300), numbers of amino acid residues (582 versus 585), and binding affinity (>10(6) M-1), distinct conformational alterations occur between the two proteins upon interacting with pyridoxal-P: a small conformational change for BSA versus a large conformational change for GAD. In contrast to the case of BSA, AET causes significant effects on both the uv/visible spectrum and fluorescence emission intensity of GAD, because GAD contains sensitive sulfhydryl groups. Factors such as disulfide bond and active site sequence were discussed to understand BAS as a carrier for pyridoxal-P and a pyridoxal-P-independent protein.     

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.     

The essential active-site lysines of clostridial glutamate dehydrogenase. A study with pyridoxal-5'-phosphate.

Glutamate dehydrogenase (GDH) of Clostridium symbiosum, like GDH from other species, is inactivated by pyridoxal 5'-phosphate (pyridoxal-P). This inactivation follows a similar pattern to that for beef liver GDH, in which a non-covalent GDH-pyridoxal-P complex reacts slowly to form a covalent complex in which pyridoxal-P is in a Schiff's-base linkage to lysine residues. [formula: see text] The equilibrium constant of this first-order reaction on the enzyme surface determines the final extent of inactivation observed [S. S. Chen and P. C. Engel (1975) Biochem. J. 147, 351-358]. For clostridial GDH, the maximal inactivation obtained was about 70%, reached after 10 min with 7 mM pyridoxal-P at pH 7. In keeping with the model, (a) inactivation became irreversible after reduction with NaBH4. (b) The NaBH4-reduced enzyme showed a new absorption peak at 325 nm. (c) Km values for NAD+ and glutamate were unaltered, although Vmax values were decreased by 70%. Kinetic analysis of the inactivation gave values of 0.81 +/- 0.34 min-1 for k3 and 3.61 +/- 0.95 mM for k2/k1. The linear plot of 1/(1-R) against 1/[pyridoxal-P], where R is the limiting residual activity reached in an inactivation reaction, gave a slightly higher value for k2/k1 of 4.8 +/- 0.47 mM and k4 of 0.16 +/- 0.01 min-1. NADH, NAD+, 2-oxoglutarate, glutarate and succinate separately gave partial protection against inactivation, the biggest effect being that of 40 mM succinate (68% activity compared with 33% in the control). Paired combinations of glutarate or 2-oxoglutarate and NAD+ gave slightly better protection than the separate components, but the most effective combination was 40 mM 2-oxoglutarate with 1 mM NADH (85% activity at equilibrium). 70% inactivated enzyme showed an incorporation of 0.7 mM pyridoxal-P/mol subunit, estimated spectrophotometrically after NaBH4 reduction, in keeping with the 1:1 stoichiometry for the inactivation. In a sample protected with 2-oxoglutarate and NADH, however, incorporation was 0.45 mol/mol, as against 0.15 mol/mol expected (85% active). Tryptic peptides of the enzyme, modified with and without protection, were purified by HPLC. Two major peaks containing phosphopyridoxyllysine were unique to the unprotected enzyme. These peaks yielded three peptide sequences clearly homologous to sequences of other GDH species. In each case, a gap at which no obvious phenylthiohydantoin-amino-acid was detected, matched a conserved lysine position. The gap was taken to indicate phosphopyridoxyllysine which had prevented tryptic cleavage.(ABSTRACT TRUNCATED AT 400 WORDS)     

The Inactivation of γ-Aminobutyric Acid Transaminase in Dissociated Neuronal Cultures from Spinal Cord

Abstract: It had previously been shown that dissociated cell cultures from chick embryo spinal cord have a high affinity uptake system for the neurotransmitter γ-aminobutyric acid (GABA) and make functional inhibitory synaptic contacts as determined by electrophysiology (Farb et al., 1979). It is shown here that these cultures can synthesize GABA from added glutamate in a glutamate decarboxylase-dependent reaction. Furthermore, these cultures have a functional GABA transaminase that degrades the neurotransmitter. This enzyme can be specifically and irreversibly blocked with gabaculine. A 15 min incubation with 10⁻⁶ M-gabaculine completely inactivates the enzyme. The inactivation of the enzyme leads to an increase in GABA levels. Long-term incubation (16 days) of gabaculine in the medium does not appear to alter high affinity GABA transport, suggesting that the drug is not toxic to cells capable of accumulating GABA.     

Purification and characterization of mouse hepatic enzyme that converts selenomethionine to methylselenol by its alpha,gamma-elimination

The objective of this study was to purify and characterize a mouse hepatic enzyme that directly generates CH3SeH from seleno-l-methionine (l-SeMet) by the alpha,gamma-elimination reaction. The l-SeMet alpha,gamma-elimination enzyme was ubiquitous in tissues from ICR mice and the activity was relatively high in the large intestine, brain, and muscle, as well as the liver. Aging and sex of the mice did not have any significant influence on the activity in the liver. The enzyme was purified from the mouse liver by ammonium sulfate precipitation and four kinds of column chromatography. These procedures yielded a homogeneous enzyme, which was purified approx 1000-fold relative to mouse liver extract. Overall recovery was approx 8%. The purified enzyme had a molecular mass of approx 160 kDa with four identical subunits. The Km value of the enzyme for the catalysis of l-SeMet was 15.5 mM, and the Vmax was 0.29 units/mg protein. Pyridoxal 5'-phosphate (pyridoxal-P) was required as a cofactor because the holoenzyme could be resolved to the apoenzyme by incubation with hydroxylamine and reconstituted by addition of pyridoxal-P. The enzyme showed the optimum activity at around pH 8.0 and the highest activity at 50 degrees C; it catalyzed the alpha,gamma-elimination reactions of several analogs such as d,l-homocysteine and l-homoserine in addition to l-SeMet. This enzyme also catalyzed the alpha,beta-elimination reaction of Se-methylseleno-l-cysteine. However, l-methionine was inert. Therefore, the purified enzyme was different from the bacterial l-methionine gamma-lyase that metabolizes l-SeMet to CH3SeH, in terms of the substrate specificity. These results were the first identification of a mammalian enzyme that specifically catalyzes the alpha,gamma-elimination reaction of l-SeMet and immediately converts it to CH3SeH, an important metabolite of Se.     

Studies on a sarcosine oxidase of bacterial origin

A "sarcosine oxidase" was prepared from a creatinine-decomposing strain of Pseudomonas aeruginosa. The enzyme is inactivated by drying, lyophilization, and dialysis against distilled water. No dialyzable cofactor was found. Optimal activity of the enzyme is reached at pH 7.8. Enzyme activity is directly proportional to enzyme concentration and also to substrate concentration up to the point of saturation of enzyme with substrate molecules. One molecule of enzyme combines with one molecule of substrate. Data concerning the effect of temperature and of a variety of chemical compounds on the enzyme are presented. Its inactivation by heat follows the course of a first order reaction, and the critical thermal increment between 48° and 52°C. was calculated to be 103,000 calories per mol. The relationship of enzyme concentration to heat inactivation rates is illustrated.     

Kinetics of the reaction between 5,5′-dithiobis[2-nitrobenzoic acid] and the sulphydryl group in Zn-dependent β-lactamase II

The kinetics of the reaction of the thiol residue in Zn²⁺-dependent β-lactamase II with 5,5′-dithiobis[2-nitrobenzoic acid], and the concomitant inactivation revealed that both events take place at the same rate. The inactivation could not be reverted by incubation with Zn²⁺ or by using a substrate concentration about eight times the K_m of the enzyme. EDTA incubation also produced inactivation of the enzyme, although it was reverted by increasing the substrate concentration in the assay. A dual role is proposed for Zn²⁺ in β-lactamase. The kinetic analysis of the thiol modification and the concomitant inactivation is in agreement with previous reports on the implication of the metal ion in catalysis. A role in stabilizing the native structure of the enzyme is also suggested.     

3(17)beta-Hydroxysteroid Dehydrogenase of Pseudomonas testosteroni. Ligand binding properties.

The binding of NAD and NADH to electrophoretically pure 3(17)beta-hydroxysteroid dehydrogenase of Pseudomonas testosteroni was determined by Fluorescence spectroscopy and gel filtration. Four moles of cofactor are bound/mol of tetrameric enzyme; the binding sites are equivalent and independent. The dissociation constants for NAD and NADH are 16 and 0.25 micronM, respectively. As measured by gel filtration in the absence of cofactor, 0.4 mol of estradiol-17 beta is bound/mol of tetrameric enzyme. Data obtained from isotope exchange at equilibrium indicate that the binding of the cofactor to the enzyme is favored over the binding of steroid, although each may bind in the absence of the other. The rates of cofactor dissociation from the ternary complexes are slower than the rates of steroid dissociation; cofactor dissociation is probably the rate-limiting step. Cofactor analogs modified in the pyridine moiety are cosubstrates, whereas modified adenine derivatives are not. The enzyme also utilized as substrate a number of potential steroid affinity labels; no enzyme inactivation by these compounds was observed.