Radioisotope assay for glutamine synthetase using thinlayer chromatography

Ammonium metabolism enzymes aid Helicobacter pylori acid resistance

The gastric pathogen Helicobacter pylori possesses a highly active urease to support acid tolerance. Urea hydrolysis occurs inside the cytoplasm, resulting in the production of NH3 that is immediately protonated to form NH4 (+). This ammonium must be metabolized or effluxed because its presence within the cell is counterproductive to the goal of raising pH while maintaining a viable proton motive force (PMF). Two compatible hypotheses for mitigating intracellular ammonium toxicity include (i) the exit of protonated ammonium outward via the UreI permease, which was shown to facilitate diffusion of both urea and ammonium, and/or (ii) the assimilation of this ammonium, which is supported by evidence that H. pylori assimilates urea nitrogen into its amino acid pools. We investigated the second hypothesis by constructing strains with altered expression of the ammonium-assimilating enzymes glutamine synthetase (GS) and glutamate dehydrogenase (GDH) and the ammonium-evolving periplasmic enzymes glutaminase (Ggt) and asparaginase (AsnB). H. pylori strains expressing elevated levels of either GS or GDH are more acid tolerant than the wild type, exhibit enhanced ammonium production, and are able to alkalize the medium faster than the wild type. Strains lacking the genes for either Ggt or AsnB are acid sensitive, have 8-fold-lower urea-dependent ammonium production, and are more acid sensitive than the parent. Additionally, we found that purified H. pylori GS produces glutamine in the presence of Mg(2+) at a rate similar to that of unadenylated Escherichia coli GS. These data reveal that all four enzymes contribute to whole-cell acid resistance in H. pylori and are likely important for assimilation and/or efflux of urea-derived ammonium.

Differential Effects of Tetanus Toxin on Inhibitory and Excitatory Neurotransmitter Release from Mammalian Spinal Cord Cells in Culture

The effect of tetanus toxin on depolarization-evoked and spontaneous synaptic release of inhibitory and excitatory neurotransmitters was examined in murine spinal cord cell cultures. Toxin action on the release of radiolabeled glycine and glutamate was followed over time intervals corresponding to the early phase of convulsant activity through the later phase of electrical quiescence. Tetanus toxin inhibited potassium-evoked release of [3H]glycine and [3H]glutamate in a time- and dose-dependent manner. Ninety minutes after the application of toxin (6 x 10(-10) M), the stimulated release of [3H]glycine was blocked completely, whereas stimulated release of [3H]glutamate was not blocked completely until 150-210 min after toxin application. Fragment C, the binding portion of the tetanus toxin molecule, had no effect on stimulated release of either transmitter. The spontaneous synaptic release of [3H]glycine was blocked totally within 90 min of toxin exposure. In contrast, the spontaneous release of [3H]glutamate, in toxin-exposed cultures, was elevated to nearly twice that of control cultures at this time. Thus, toxin-induced convulsant activity is characterized by a reduction in the spontaneous synaptic release of inhibitory neurotransmitter with a concomitant increase in the release of excitatory neurotransmitter, as well as the more rapid onset of blockade of depolarization-evoked release of inhibitory versus excitatory neurotransmitter.

Calcium-dependent release of N-acetylaspartylglutamate from retinal neurons upon depolarization

N-Acetylaspartylglutamate (NAAG) is present in high concentrations specifically in the nervous system. Its neuronal distribution, presence in synaptic vesicles and its excitatory actions support the hypothesis that this dipeptide participates in communication between neurons. Following the incorporation of [3H]glutamate by frog retinal cells in vivo, the release of radiolabeled glutamate, GABA and NAAG was studied during acute incubation of the retina in vitro. Release of the radiolabeled amino acids and dipeptide was stimulated by elevated extracellular potassium. The release required the presence of extracellular calcium. These data are the first which demonstrate the release of NAAG following biosynthesis from a radiolabeled precursor and are consistent with synaptic release of this dipeptide.

Bovine retinal glutamine synthetase 2. Regulation and properties on the basis of glutamine synthetase and glutamyl transferase reactions

Glutamine, the end product formed by the glutamine synthetase (GS) reaction, inhibits retinal GS activity in the presence of Mn2+, but not in the presence of Mg2+. In the presence of Mg2+, Mn2+ itself inhibits retinal GS activity. Other compounds which inhibit retinal GS activity significantly are methionine sulfoximine, D-alanine and carbamyl phosphate. Amino acids, such as L-alanine, L-serine and glycine, do not affect the enzyme activity. These amino acids, however, significantly inhibit the enzyme activity when measured on the basis of the glutamyl transferase (GT) reaction. GS isolated from neuronal tissues is regulated differently from that previously reported by others for non-neuronal tissues. The enzyme activity, as measured by GS activity, shows three-fold higher activity with Mg2+ over Mn2+ or Co2+ and on the basis of GT activity, shows about three-fold higher activity with Mn2+ over Mg2+ or Co2+. The optimum pH for the GS reaction lies in the range of 7.2-7.8 and for the GT reaction is 6.4-7.0. Both the GS and GT activities of the enzyme show similar heat stabilities.