Post-translational processing of Neisseria meningitidis gamma-glutamyl aminopeptidase and its association with inner membrane facing to the cytoplasmic space

We previously demonstrated that gamma-glutamyl aminopeptidase (also called gamma-glutamyl transpeptidase) (GGT) of Neisseria meningitidis is involved in the bacterial multiplication in cerebrospinal fluid. To further understand the function of meningococcal GGT, the biochemical properties were investigated in this study. The deduced amino acid sequence in N. meningitidis GGT was 37% identical to that of Escherichia coli GGT and that of Helicobacter pylori GGT, respectively, while a typical signal sequence was not found at the N-terminus of meningococcal GGT. Western blotting using rabbit antiserum against recombinant meningococcal GGT protein demonstrated that the meningococcal GGT is processed into two subunits in N. meningitidis at the conserved amino acid, threonine 427. The experiments on subcellular fractionation suggested that the majority of meningococcal GGT is associated with inner membrane facing to the cytoplasmic side. This cell localization might be unique for N. meningitidis compared to other GGTs.     

Identification and Function of Octopamine and Tyramine Conjugates in the Limulus Visual System

Major metabolites of octopamine and tyramine in the Limulus nervous system are identified here as gamma-glutamyl octopamine and gamma-glutamyl tyramine. We show that these conjugates are normal products of amine metabolism in Limulus, and that they are normally present in octopamine-rich Limulus tissues. The synthesis of these conjugates is not restricted to nervous tissue, but the highest activity of gamma-glutamyl amine synthetase was measured in the CNS. Our interest in these molecules stems from our previous observations which showed that they were synthesized and stored in, and released from, the efferent fibers to Limulus eyes which modulate the sensitivity of the eyes to light. Here we provide direct evidence for the release of the conjugates from Limulus eyes in response to depolarization, and that gamma-glutamyl octopamine can increase the sensitivity of the lateral eye to light. Our observations lend support to the hypothesis that gamma-glutamyl octopamine may serve as an intercellular messenger in the Limulus visual system.     

A Micromethod for the Isolation of Large and Small Microvessels from Frozen Autopsied Human Brain

Microvessels were isolated from autopsied human brain using a simple procedure involving disruption, sieving, and centrifugation on a sucrose density gradient. The present procedure is characterized by isolation, from frozen autopsied brain, of materials either from the cerebral cortex or white matter, and subsequent separation of the capillary fraction from the large vessel fraction. The preparation appears highly purified under phase-contrast microscopic examination. The purity was also established by the enrichment of gamma-glutamyl transpeptidase activity and by the nearly negligible cerebroside content in the vessel fractions as compared to the brain homogenate.     

Utilization of glutathione as an exogenous sulfur source is independent of gamma-glutamyl transpeptidase in the yeast Saccharomyces cerevisiae: evidence for an alternative gluathione degradation pathway

gamma-Glutamyl transpeptidase (gamma-GT) is the only enzyme known to be responsible for glutathione degradation in living cells. In the present study we provide evidence that the utilization of glutathione can occur in the absence of gamma-GT. When disruptions in the CIS2 gene encoding gamma-GT were created in met15Delta strains, which require organic sulfur sources for growth, the cells were able to grow well with glutathione as the sole sulfur source suggesting that a gamma-GT-independent pathway for glutathione degradation exists in yeast cells. The CIS2 gene was strongly repressed by ammonium and derepressed in glutamate medium, and was found to be regulated by the nitrogen regulatory circuit. The utilization of glutathione as a sulfur source was, however, independent of the nitrogen source in the medium, further underlining that the two degradatory pathways were distinct.     

The Occurrence of γ-Aminobutyrylcholine in Mammalian Brain—Fact or Artefact?

Abstract: γ-Aminobutyrylcholine (GABACh) has been reported to exist in mammalian brain tissue, but not, as yet, given a specific physiological role in the CNS. In order to investigate further its occurrence and function in the CNS, two new methods have been developed for its isolation and determination at the picomole level. Its isolation has been achieved by ammonium Reineckate precipitation or by cation-exchange followed by HPLC determination of the dansyl and O -phthaldialdehyde derivatives. Using these methods, no free endogenous GABACh (<80 pmol/g) was found in rat, guinea pig, cat, pig, marmoset, or human brain tissue. No evidence was obtained, either in vitro or in vivo , for the incorporation of [¹⁴C]choline or [¹⁴C]γ-aminobutyric acid into GABACh. GABACh was hydrolysed at a low rate (maximum of 45 nmol/h/g of brain tissue) after incubation with rat, guinea pig, or cat brain minces and homogenates. These results fail to confirm the data of other investigators, and the possible reasons for this are discussed.     

An evaluation of gamma-glutamyl dipeptide derivatives as antagonists of amino acid-induced Na+ fluxes in rat striatum slices

Abstract: Various γ-glutamyl dipeptide derivatives of the l and d configuration were tested as antagonists of excitatory amino acid-induced [²²Na⁺] efflux from rat striatum slices. The N -methyl- d -aspartate- and kainic acid-induced responses were much more affected by the presence of these peptides than were the l -glutamate-, l -aspartate-, and quisqualate-induced responses. The dipeptides produced different patterns of antagonism of the responses to N- methyl- d -aspartate and kainic acid, indicating that these latter excitants interact with distinct receptors.     

beta-N-gamma-glutamyl diaminopropionic acid, a convulsant and an inhibitor of brain glutamate decarboxylase

The different isomers of the dipeptide beta-N-gamma-glutamyl diaminopropionate inhibit L-glutamate-1-carboxylyase (GAD, EC-4.1.1.15) activity in mouse brain homogenates. The L-D isomer is the most effective as an inhibitor, while the D-D isomer is least inhibitory. The different isomers are neurotoxic to mice and the chick, the L-D isomer being the most toxic. The neurotoxicity of the isomers in mice was also associated with a significant lowering in GAD activity in the brains of convulsing mice.     

Culture and Characterization of Epithelial Cells from Bovine Choroid Plexus

Epithelial cells were isolated from choroid plexus, which plays a major role in cerebrospinal fluid production and regulation. Incubation of bovine choroid plexuses with pronase released cells which attached to plastic dishes with a plating efficiency of 5%. The cells were predominantly polygonal as judged by phase-contrast microscopy. These polygonal cells undergo limited cell division and survive for 1-2 weeks in culture before being overgrown by fibroblasts. The fibroblastic cells could be selectively removed from the cultures but the addition of 100 microgram/ml cis-hydroxyproline to the medium for several days. The specific activities of three membrane-bound enzymes, gamma-glutamyl transpeptidase, alkaline phosphatase, and leucine aminopeptidase were compared in selective cultures of polygonal cells and fibroblasts. Polygonal cells were found to have 4-5 times the gamma-glutamyl transpeptidase of fibroblasts, whereas fibroblasts have 2-3 times the alkaline phosphatase of polygonal cells. Leucine aminopeptidase levels in the two cultures were roughly equivalent. The polygonal cells rapidly lost gamma-glutamyl transpeptidase activity over a 4-day period in culture but acquired increased levels of leucine aminopeptidase. Alkaline phosphatase remained roughly constant. Under similar conditions fibroblasts showed a 3- to 4-fold increase in the specific activities of all three enzymes; these changes coincided with a substantial increase in cell density. Based on morphology, resistance to cis-hydroxyproline, absence of antihemophilic factor antigen, and enzymatic characteristics, we believe the polygonal cells to be of epithelial origin.     

Determination of Glutathione and ATP in Ganglia and Individual Neurons of Aplysia californica

The levels of two gamma-glutamyl cycle substrates, glutathione and ATP, were determined in single identified nerve cell bodies from the CNS of Aplysia californica. The glutathione content of single cells averaged 30 +/- 4.9 mumol/g protein. Glutathione levels were similar in identified cholinergic, serotonergic, and histaminergic cells, as well as in neurons whose transmitters are not yet identified. The abdominal rostral white cells, which are enriched in glycine, a component amino acid of glutathione, did not possess distinctively higher glutathione concentrations. The ATP content of single Aplysia nerve cell bodies averaged 15.0 +/- 1.5 mumol/g protein. Despite the vast chemical, anatomical, and functional heterogeneity between Aplysia central neurons, no cells were found that contained unusually high or low ATP levels.     

γ-Glutamyl Transpeptidase Activity in Brain Microvessels Exhibits Regional Heterogeneity

Brain microvessels form a tight blood-tissue permeability barrier and express high levels of specific enzymes, including gamma-glutamyl transpeptidase (GGTP). This differentiation is thought to be induced by perivascular astrocytes. By using histochemical methods, we found that the percentage of GGTP-positive vessels varied considerably in different areas of rat brain. Enzyme activity was not found in the pineal gland or the median eminence, where the blood-brain barrier is not expressed. In areas where the blood-brain barrier is expressed, the percentage of GGTP-positive vessels varied from 8% in the optic nerve to 100% in the anterior commissure. The neocortex showed a lower percentage of GGTP-positive vessels (2-15%) than anterior olfactory nucleus (42%), subiculum (70%), hippocampus (48%), and striatum (50-58%). Alkaline phosphatase, another brain microvessel-enriched enzyme, did not show these marked regional differences. The morphometric histochemical results were verified by enzymatic assays in homogenates of different regions from rat and bovine brain and in microvessel preparations of bovine putamen and neocortex. During the postnatal development of rat brain, the difference between neocortex and striatum appeared after day 20. The regional heterogeneity of brain microvessels may be caused by astrocytic heterogeneity and reflect regional heterogeneity in microvascular function.     

Isolation and Identification of α-(γ-Aminobutyryl)-Hypusine

A new dipeptide, alpha-(gamma-aminobutyryl)-hypusine, was identified in bovine brain. This compound was isolated from trichloroacetic acid-soluble fraction of bovine brain with five steps of ion-exchange chromatography. Its structure was postulated by routine chemical analyses and determined by synthesis. The amount of the compound isolated from 1.2 kg of bovine brain was 870 nmol.     

In Vitro Synthesis of Dopamine and Noradrenaline in the Isolated Rat Pineal Gland: Day-Night Variations and Effects of Electrical Stimulation

Isolated rat pineal glands were incubated in vitro in a medium containing [14C]dopamine or [14C]tyrosine, and the tissue contents of 14C-labelled and total dopamine and noradrenaline were determined by HPLC followed by electrochemical detection and scintillation spectrometry. During incubation with [14C]dopamine, the labelled amine accumulated in pineal glands and was partially converted into [14C]noradrenaline. Nomifensine, a neuronal amine uptake blocker, largely inhibited the accumulation of [14C]dopamine and the formation of [14C]noradrenaline. These experiments demonstrated dopamine beta-hydroxylase activity in the sympathetic nerves of the pineal gland. During incubation with [14C]tyrosine, formation of [14C]dopamine and [14C]noradrenaline was observed in the pineal tissue, indicating that noradrenaline can also be synthesized from dopamine, endogenously formed in the gland. Electrical stimulation of the stalk region of the pineal gland during incubation with [14C]dopamine enhanced the accumulation of [14C]dopamine and synthesis of [14C]noradrenaline. Electrical stimulation also enhanced the formation of [14C]dopamine during incubation with [14C]tyrosine. Compared to that at midday, the tissue content of endogenous noradrenaline at midnight was enhanced by 50% and that of dopamine by 450%. The in vitro accumulation of [14C]dopamine, as well as the synthesis of [14C]dopamine and [14C]noradrenaline, was also increased at midnight. In conclusion, sympathetic nerves in the rat pineal gland contain tyrosine hydroxylase and dopamine beta-hydroxylase, the two enzymes required for the synthesis of noradrenaline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human γγ-Enolase: Two-Site Immunoradiometric Assay with a Single Monoclonal Antibody

Abstract: A monoclonal antibody (mAb), termed BBS/NC/VI-H14 (H14), that reacts with the human enzyme γγ-enolase was prepared. It was directed against the γ-subunit and did not cross-react with the α- or β-subunit. The mAb H14 can be used for quantitative determination of γγ-enolase in a two-site immunoradiometric assay (two-site IRMA). It is also suitable for immunostaining formalin-fixed tissues. The specific identification of γγ-enolase provided by the two-site IRMA with H14 is discussed in relation to the cellular distribution of this protein.     

Tocopherol metabolism, oxidation and recycling under high light stress in Arabidopsis

SUMMARY: Tocopherols are synthesized and accumulated by all plants and many cyanobacteria. The quenching and scavenging of reactive oxygen species and lipid peroxy radicals by tocopherols can result in the formation of various tocopherol oxidation compounds. A targeted GC/MS profiling method was developed to quantify all tocopherols and pathway intermediates, and 23 potential alpha- and gamma-tocopherol oxidation products. This method was used to study the response of wild-type Arabidopsis (Col) and the tocopherol biosynthetic mutants vte1, vte2 and vte4 during 12 h low- and high-light treatments (LL and HL, 90 and 1500 mumol photon m(-2) sec(-1), respectively) and a subsequent 12 h dark recovery period. All tocopherols and pathway intermediates exhibited HL-dependent increases except 2,3-dimethyl-6-phytyl-1,4-benzoquinone (DMPBQ) in vte1 and beta-tocopherol in Col. Profiling of potential tocopherol oxidation products during HL treatment indicated the presence of only alpha-tocopherolquinol (alpha-TQH(2)) in Col and only gamma-tocopherolquinol (gamma-TQH(2)) in vte4, both of which accumulated to similar levels and with similar kinetics the two genotypes. However, during dark recovery, the level of alpha-TQH(2) in Col decreased several times faster than that of gamma-TQH(2) in vte4, suggesting the presence of biochemical processes with higher specificity for alpha-TQH(2). (14)C-labeled alpha-tocopherolquinone (alpha-TQ) applied to isolated Col chloroplasts was converted to (14)C-alpha-tocopherol, demonstrating the existence of a plastid-based system for recycling oxidized alpha-tocopherol. The accumulation of (14)C-trimethylphytylbenzoquinone (TMPBQ) by isolated vte1 plastids treated with (14)C-labeled alpha-TQ is consistent with the tocopherolquinone-recycling pathway utilizing a yet to be identified plastid-localized dehydratase that converts tocopherolquinone to TMPBQ.     

Increase of Catecholamines in Mouse Brain by Systemic Administration of γ-Glutamyl L-3,4-Dihydroxyphenylalanine

We investigated the effect of systemic administration of gamma-glutamyl L-3,4-dihydroxyphenylalanine (gamma-Glu-DOPA) on catecholamine contents in the brain. gamma-Glu-DOPA was transformed to dopamine (DA) in vitro with brain homogenate by the sequential action of gamma-glutamyl transpeptidase and aromatic L-amino acid decarboxylase. Intraperitoneal injection of gamma-Glu-DOPA to mice increased DA markedly and noradrenaline (NA) moderately in the brain. The increase of endogenous DA was followed by elevation of the main DA metabolites (3,4-dihydroxyphenyl-acetic acid and homovanillic acid). These increases were in a dose-dependent manner. The maximal elevation of DA was observed within 30 min after administration of gamma-Glu-DOPA, but a substantial increase of NA was observed 2 h after the administration. These results suggest that gamma-Glu-DOPA may be applicable to the treatment of Parkinson's disease.     

αγ-Enolase in the Rat: Ontogeny and Tissue Distribution

Abstract: The rat brain enolases are dimers composed of α and γ subunits. At pH 8.6 αγ-enolase seemed to be stable, and no evidence was found for the possible formation of αγ-enolase from αα-enolase and γγ-enolase in the course of rat brain homogenization. During ontogeny of the rat forebrain, αγ-enolase was formed before γγ-enolase. The half-maximal specific concentrations were reached at postnatal days 14 and 23, respectively. The distribution of αγ- and γγ-enolase in various rat brain areas was also investigated. In all areas both forms were present. In neuroendocrine tissues αγ-enolase was present at a much higher concentration than γγ-enolase. The ratio between γγ-enolase and αγ-enolase may be indicative of the degree of neuronal maturation, a conclusion further substantiated by the high ratio observed in cerebellum and the low ratio observed in olfactory bulbs, both compared with the ratio in forebrain.     

γ-Aminobutyric Acid-Activated 36Cl- Influx: A Functional In Vitro Assay for CNS γ-Aminobutyric Acid Receptors of Insects

The effects of gamma-aminobutyric acid (GABA) on the uptake of 36Cl- into a membrane microsac preparation from isolated nerve cords of the cockroach Periplaneta americana was studied. On addition of 1 microM GABA (after 4-s incubation, then rapid quenching) the influx of 36Cl- was stimulated to a level 75% above that of the control value. This stimulation was reduced by picrotoxin (100 microM), but was not significantly affected by bicuculline (100 microM). Results of 36Cl- influx experiments are in agreement with data obtained from radiolabelled ligand binding assays and electrophysiological investigations on the same tissue. The method described represents a functional in vitro assay for CNS GABA receptors of insects.     

Dipeptide Antagonists of Amino Acid-Induced and Synaptic Excitation in the Frog Spinal Cord

Abstract: The dipeptide γ-d -glutamylglycine (γDGG) antagonizes amino acidinduced depolarization and synaptic excitation in the isolated hemisected spinal cord of the frog. In general, the effects of this compound resembled those of the structurally similar d -α-aminosuberate (DαAS) in being more effective against N-methyl-d -aspartate (NMDA)-induced responses than against responses induced by other excitatory amino acids. However γDGG appeared to be more effective than DαAS in depressing kainate-induced responses. Similar, though weaker, effects were produced by the L isomer of the dipeptide (αLGG), a natural brain constituent.     

1,25-Dihydroxyvitamin D3 Regulates the Synthesis of γ-Glutamyl Transpeptidase and Glutathione Levels in Rat Primary Astrocytes

Astrocytes play a pivotal role in CNS detoxification pathways, where glutathione (GSH) is involved in the elimination of oxygen and nitrogen reactive species such as nitric oxide. We have previously demonstrated that the specific activity of gamma-glutamyl transpeptidase (gamma-GT), an enzyme of central significance in GSH metabolism, is regulated in vivo in astrocytes by 1,25-dihydroxyvitamin D3 (1,25-D3). The aim of the present work was to investigate, in primary cultures of newborn rat astrocytes, the effects of this hormone on gamma-GT synthesis and on GSH and nitrite levels after lipopolysaccharide (LPS) treatment. This study demonstrates that both gamma-GT gene expression and specific activity, induced by LPS, are potentiated by 1,25-D3. In contrast, 1,25-D3 does not regulate the expression of other enzymes involved in astrocyte detoxification processes, such as superoxide dismutase or GSH peroxidase. In parallel, 1,25-D3 enhanced intracellular GSH pools and significantly reduced nitrite production induced by LPS. Taken together, these results suggest that gamma-GT, GSH, and 1,25-D3 play a fundamental role in astrocyte detoxification pathways.