The gdhA1 point mutation in Escherichia coli K12 CLR207 alters a key lysine residue of glutamate dehydrogenase

gdhA1 is a spontaneous mutant of Escherichia coli that causes complete loss of activity of the NADP-specific glutamate dehydrogenase (GDH) encoded by the gdhA gene. The gdhA1 mutational site has been identified by recombinational mapping, polymerase chain reaction (PCR) amplification and DNA sequencing, as an A to G transition at nucleotide 274 of the gdhA coding sequence, resulting in an amino acid change of lysine 92 to glutamic acid. The mutant enzyme forms hybrid hexamers with a wild-type GDH, providing a useful system for analysis of conformational integrity of mutational variants.     

Regulation of glutamate dehydrogenase activity in relation to carbon limitation and protein catabolism in carrot cell suspension cultures

Glutamate dehydrogenase (GDH) specific activity and function have been studied in cell suspension cultures of carrot (Daucus carota L. cv Chantenay) in response to carbon and nitrogen supply in the culture medium. The specific activity of GDH was derepressed in sucrose-starved cells concomitant with protein catabolism, ammonium excretion, and the accumulation of metabolically active amino acids. The addition of sucrose led to a rapid decrease in GDH specific activity, an uptake of ammonium from the medium, and a decrease in amino acid levels. The extent of GDH derepression was correlated positively with cellular glutamate concentration. These findings strengthen the view that the function of GDH is the catabolism of glutamate, which under conditions of carbon stress provides carbon skeletons for tricarboxylic acid cycle activity.     

The gdhA1 point mutation in Escherichia coli K12 CLR207 alters a key lysine residue of glutamate dehydrogenase

gdhA1 is a spontaneous mutant of Escherichia coli that causes complete loss of activity of the NADP-specific glutamate dehydrogenase (GDH) encoded by the gdhA gene. The gdhA1 mutational site has been identified by recombinational mapping, polymerase chain reaction (PCR) amplification and DNA sequencing, as an A to G transition at nucleotide 274 of the gdhA coding sequence, resulting in an amino acid change of lysine 92 to glutamic acid. The mutant enzyme forms hybrid hexamers with a wild-type GDH, providing a useful system for analysis of conformational integrity of mutational variants.     

Efficient approach for profiling photoaffinity labeled peptides with a cleavable biotinyl photoprobe

Based on the application of our recent biotinyl photoprobe with a cleavable N-acylsulfonamide, an efficient process has been developed for profiling photoaffinity labeled peptides among a large excess of unlabeled concomitants. N-acylsulfonamide group was found to be stable under the usual S-pyridylethylation condition of cysteine residues whereas the group was easily cleaved by N-alkylation with iodoacetic acid in acidic condition. The selective nature between two common protein alkylation reactions was evaluated with l-glutamate dehydrogenase (GDH) using an acidic amino acid photoprobe with biotinylated acylsulfonamide function. The labeled GDH was successfully subjected to S-pyridylethylation keeping the biotin tag intact, and then was easily released from streptavidin matrix with high purity via iodoacetic acid-mediated alkylation under mild condition at pH 5.0.     

The nucleotide sequence of the yeast ARG4 gene

The complete nucleotide sequence of a 2296-bp DNA fragment containing the yeast (Saccharomyces cerevisiae) ARG4 gene has been determined. This gene specifies the synthesis of the arginine biosynthetic enzyme, argininosuccinate lyase (EC 4.3.2.1). The sequence contains one major open reading frame of 463 codons, giving a calculated M_r of 52010 for the protein, in good agreement with the experimentally determined value of 53 000. The sequence upstream from the ARG4 gene shares structural features in common with other yeast genes subject to general amino acid control.     

Structural basis for leucine-induced allosteric activation of glutamate dehydrogenase

Glutamate dehydrogenase (GDH) catalyzes reversible conversion between glutamate and 2-oxoglutarate using NAD(P)(H) as a coenzyme. Although mammalian GDH is regulated by GTP through the antenna domain, little is known about the mechanism of allosteric activation by leucine. An extremely thermophilic bacterium, Thermus thermophilus, possesses GDH with a unique subunit configuration composed of two different subunits, GdhA (regulatory subunit) and GdhB (catalytic subunit). T. thermophilus GDH is unique in that the enzyme is subject to allosteric activation by leucine. To elucidate the structural basis for leucine-induced allosteric activation of GDH, we determined the crystal structures of the GdhB-Glu and GdhA-GdhB-Leu complexes at 2.1 and 2.6 Å resolution, respectively. The GdhB-Glu complex is a hexamer that binds 12 glutamate molecules: six molecules are bound at the substrate-binding sites, and the remaining six are bound at subunit interfaces, each composed of three subunits. The GdhA-GdhB-Leu complex is crystallized as a heterohexamer composed of four GdhA subunits and two GdhB subunits. In this complex, six leucine molecules are bound at subunit interfaces identified as glutamate-binding sites in the GdhB-Glu complex. Consistent with the structure, replacement of the amino acid residues of T. thermophilus GDH responsible for leucine binding made T. thermophilus GDH insensitive to leucine. Equivalent amino acid replacement caused a similar loss of sensitivity to leucine in human GDH2, suggesting that human GDH2 also uses the same allosteric site for regulation by leucine.     

Mechanism of Hyperinsulinism in Short-chain 3-Hydroxyacyl-CoA Dehydrogenase Deficiency Involves Activation of Glutamate Dehydrogenase

The mechanism of insulin dysregulation in children with hyperinsulinism associated with inactivating mutations of short-chain 3-hydroxyacyl-CoA dehydrogenase (SCHAD) was examined in mice with a knock-out of the hadh gene (hadh^−/−). The hadh^−/− mice had reduced levels of plasma glucose and elevated plasma insulin levels, similar to children with SCHAD deficiency. hadh^−/− mice were hypersensitive to oral amino acid with decrease of glucose level and elevation of insulin. Hypersensitivity to oral amino acid in hadh^−/− mice can be explained by abnormal insulin responses to a physiological mixture of amino acids and increased sensitivity to leucine stimulation in isolated perifused islets. Measurement of cytosolic calcium showed normal basal levels and abnormal responses to amino acids in hadh^−/− islets. Leucine, glutamine, and alanine are responsible for amino acid hypersensitivity in islets. hadh^−/− islets have lower intracellular glutamate and aspartate levels, and this decrease can be prevented by high glucose. hadh^−/− islets also have increased [U-¹⁴C]glutamine oxidation. In contrast, hadh^−/− mice have similar glucose tolerance and insulin sensitivity compared with controls. Perifused hadh^−/− islets showed no differences from controls in response to glucose-stimulated insulin secretion, even with addition of either a medium-chain fatty acid (octanoate) or a long-chain fatty acid (palmitate). Pull-down experiments with SCHAD, anti-SCHAD, or anti-GDH antibodies showed protein-protein interactions between SCHAD and GDH. GDH enzyme kinetics of hadh^−/− islets showed an increase in GDH affinity for its substrate, α-ketoglutarate. These studies indicate that SCHAD deficiency causes hyperinsulinism by activation of GDH via loss of inhibitory regulation of GDH by SCHAD.     

Amino acid pair- and triplet-wise groupings in the interior of α-helical segments in proteins

A statistical approach has been applied to analyse primary structure patterns at inner positions of α-helices in proteins. A systematic survey was carried out in a recent sample of non-redundant proteins selected from the Protein Data Bank, which were used to analyse α-helix structures for amino acid pairing patterns. Only residues more than three positions apart from both termini of the α-helix were considered as inner. Amino acid pairings i, i+k (k=1, 2, 3, 4, 5), were analysed and the corresponding 20×20 matrices of relative global propensities were constructed. An analysis of (i, i+4, i+8) and (i, i+3, i+4) triplet patterns was also performed. These analysis yielded information on a series of amino acid patterns (pairings and triplets) showing either high or low preference for α-helical motifs and suggested a novel approach to protein alphabet reduction. In addition, it has been shown that the individual amino acid propensities are not enough to define the statistical distribution of these patterns. Global pair propensities also depend on the type of pattern, its composition and orientation in the protein sequence. The data presented should prove useful to obtain and refine useful predictive rules which can further the development and fine-tuning of protein structure prediction algorithms and tools.     

Gamma-amino butyric acid, glutamate dehydrogenase and glutamate decarboxylase levels in phylogenetically divergent plants

Gamma-amino butyric acid (GABA) is a nonprotein amino acid found in a wide range of organisms including plants. Several studies have shown that GABA plays different roles in plant metabolism including carbon–nitrogen metabolism, energy balance, signaling and development. It has been suggested that the occurrence of GABA and the enzymes related to GABA biosynthesis in prokaryotes and eukaryotes may be important in evolution and diversification. However, studies of GABA biosynthesis and GABA levels in an evolutionary context are restricted to sequenced plant genomes. In this study we aimed to compare the activities of GDH and GAD enzymes and total nitrogen, and the contents of total soluble protein, succinate, glutamate, proline and GABA in plants from different phylogenetic levels including Ulva lactuca, Pseudevernia furfuracea, Nephrolepsis exaltata, Ginkgo biloba, Pinus pinea, Magnolia grandiflora, Nymphaea alba, Urtica dioica, Portulaca oleraceae, Malva sylvestris, Rosa canina, Lavandula stoechas, Washingtonia filifera, Avena barbata and Iris kaempferi. The activities of GAD and GDH enzymes differed according to the species and were not always parallel to GABA levels. The discrepancy in the contents of succinate and GABA between higher and primitive plants was also prominent. Glutamate levels were high with a few exceptions and proline contents were at similar low values as compared to other amino acids. Our results support the hypothesis that the GABA shunt plays a key role in carbon and nitrogen partitioning via linking amino acid metabolism and the tricarboxylic acid cycle which is essential for higher plant species.     

Amino acids response of glutamate dehydrogenase from light and dark treated roots and shoots of maize

Thein vitro activity of glutamate dehydrogenase (NADH-GDH), from dark-treated root segments of maize seedlings responded differently to amino acids threonine, glutamate and methionine than that from light-treated root segments, and to the amino acid methionine in dark- and light-treated shoot segments. In most cases amino acids inhibited GDH activity, the inhibition increased with amino acid concentration. However, methionine activated GDH from dark-treated roots and light-treated shoots, while aspartate had little effect on enzyme activity.     

Involvement of GDH3-encoded NADP+-dependent Glutamate Dehydrogenase in Yeast Cell Resistance to Stress-induced Apoptosis in Stationary Phase Cells

Glutamate metabolism is linked to a number of fundamental metabolic pathways such as amino acid metabolism, the TCA cycle, and glutathione (GSH) synthesis. In the yeast Saccharomyces cerevisiae, glutamate is synthesized from α-ketoglutarate by two NADP⁺-dependent glutamate dehydrogenases (NADP-GDH) encoded by GDH1 and GDH3. Here, we report the relationship between the function of the NADP-GDH and stress-induced apoptosis. Gdh3-null cells showed accelerated chronological aging and hypersusceptibility to thermal and oxidative stress during stationary phase. Upon exposure to oxidative stress, Gdh3-null strains displayed a rapid loss in viability associated with typical apoptotic hallmarks, i.e. reactive oxygen species accumulation, nuclear fragmentation, DNA breakage, and phosphatidylserine translocation. In addition, Gdh3-null cells, but not Gdh1-null cells, had a higher tendency toward GSH depletion and subsequent reactive oxygen species accumulation than did WT cells. GSH depletion was rescued by exogenous GSH or glutamate. The hypersusceptibility of stationary phase Gdh3-null cells to stress-induced apoptosis was suppressed by deletion of GDH2. Promoter swapping and site-directed mutagenesis of GDH1 and GDH3 indicated that the necessity of GDH3 for the resistance to stress-induced apoptosis and chronological aging is due to the stationary phase-specific expression of GDH3 and concurrent degradation of Gdh1 in which the Lys-426 residue plays an essential role.     

Glutamate Dehydrogenase Activity Can Be Transmitted Naturally to Lactococcus lactis Strains To Stimulate Amino Acid Conversion to Aroma Compounds

Amino acid conversion to aroma compounds by Lactococcus lactis is limited by the low production of α-ketoglutarate that is necessary for the first step of conversion. Recently, glutamate dehydrogenase (GDH) activity that catalyzes the reversible glutamate deamination to α-ketoglutarate was detected in L. lactis strains isolated from a vegetal source, and the gene responsible for the activity in L. lactis NCDO1867 was identified and characterized. The gene is located on a 70-kb plasmid also encoding cadmium resistance. In this study, gdh gene inactivation and overexpression confirmed the direct impact of GDH activity of L. lactis on amino acid catabolism in a reaction medium at pH 5.5, the pH of cheese. By using cadmium resistance as a selectable marker, the plasmid carrying gdh was naturally transmitted to another L. lactis strain by a mating procedure. The transfer conferred to the host strain GDH activity and the ability to catabolize amino acids in the presence of glutamate in the reaction medium. However, the plasmid appeared unstable in a strain also containing the protease lactose plasmid pLP712, indicating an incompatibility between these two plasmids.     

Distribution of glutamate dehydrogenase in the intestine of the earthworm (Lumbricus terrestris), and some physiological implications

• 1.1. Intestines of fresh and dehydrated-starved L. terrestris were compared to tissue and anterior-posterior distribution of glutamate dehydrogenase (GDH) and other mitochondrial or cytosol dehydrogenases.
• 2.2. For any dehydrogenase, including GDH, practically all the activity was in the gut epithelium. This distribution of GDH supports Tillinghast (1967, 1968) as to the excretory route for ammonia.
• 3.3. While the distributions of the marker dehydrogenases were reasonably uniform along the intestine, the GDH activity was predominantly (80–90% of the total activity) in the last third of the mid-intestine, indicating a true physiological differentiation of the midgut tube. The GDH activity of the typhlosole was about two times the activity in the peripheral epithelium. The GDH distribution was independent of the physiological state of the worm.
• 4.4. From the distribution of GDH it follows that the mid-intestine, immediately before the hindgut, is the main region both for amino acid uptake and catabolism. As regards amino acids, it typifies the primitive digestive tube by having both the absorptive and the liver functions.

     

Nitrogen metabolism of Frankia strain,Cc01, Mg+, At4 and Hr18

The composition and levels of amino acids in four Frankia strains isolated from different actinorhizal plants, were determined. Minor differences in the amino acid profiles were noted with GLN (GLU) being the major amino acid in all four strains. Enzyme actives of ammonia metabolism, GS (glutamine synthetase), GOGAT (glutamate synthetase), and GDH (glutamate dehydrogenase), were also measured. In strains At4 and Hr18, GS and GOGAT activity levels were elevated in N₂-grown cells but significant amounts of GDH activity were present in ammonia-grown cells. No GDH was detected in strain Cc01 and Mg⁺. The characters of heat-stable and heat-labile GSs were described. In N₂-fixing cells, the ATP and amino acid content was much lower, but ammonia content was higher than in NH _inf4 ^sup+ -grown cells.     

Sequence analysis of glutamate dehydrogenase (GDH) from the hyperthermophilic archaeon Pyrococcus sp. KOD1 and comparison of the enzymatic characteristics of native and recombinant GDHs

The gdhA gene encoding glutamate dehydrogenase (GDH) from the hyperthermophilic archaeon Pyrococcus sp. KOD1 was cloned and sequenced. Phylogenetic analysis was performed on an alignment of 25?GDH sequences including KOD1-GDH, and two protein families were distinguished, as previously reported. KOD1-GDH was classified as new member of the hexameric GDH Family II. The gdhA gene was expressed in Escherichia coli, and recombinant KOD1-GDH was purified. Its enzymatic characteristics were compared with those of the native KOD1-GDH. Both enzymes had a molecular mass of 47 300?Da and were shown to be functional in a hexameric form (284?kDa). The N-terminal amino acid sequences of native KOD1-GDH and the recombinant GDH were VEIDPFEMAV and MVEIDPFEMA, respectively, indicating that native KOD1-GDH does not retain the initial methionine at the N-terminus. The recombinant GDH displayed enzyme characteristics similar to those of the native GDH, except for a lower level of thermostability, with a half-life of 2?h at 100°?C, compared to 4?h for the native enzyme purified from KOD1. Kinetic studies suggested that the reaction is biased towards glutamate production. KOD1-GDH utilized both coenzymes NADH and NADPH, as do most eukaryal GDHs.     

L-Glutamate dehydrogenase from the antarctic fish Chaenocephalus aceratus. Primary structure, function and thermodynamic characterisation: relationship with cold adaptation

In order to study the molecular mechanisms of enzyme cold adaptation, direct amino acid sequence, catalytic features, thermal stability and thermodynamics of the reaction and of heat inactivation of L-glutamate dehydrogenase (GDH) from the liver of the Antarctic fish Chaenocephalus aceratus (suborder Notothenioidei, family Channichthyidae) were investigated. The enzyme shows dual coenzyme specificity, is inhibited by GTP and the forward reaction is activated by ADP and ATP. The complete primary structure of C. aceratus GDH has been established; it is the first amino acid sequence of a fish GDH to be described. In comparison with homologous mesophilic enzymes, the amino acid substitutions suggest a less compact molecular structure with a reduced number of salt bridges. Functional characterisation indicates efficient compensation of Q(10), achieved by increased k(cat) and modulation of S(0.5), which produce a catalytic efficiency at low temperature very similar to that of bovine GDH at its physiological temperature. The structural and functional characteristics are indicative of a high extent of protein flexibility. This property seems to find correspondence in the heat inactivation of Antarctic and bovine enzymes, which are inactivated at very similar temperature, but with different thermodynamics.