UMLS:C0017638 - FACTA Search

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Query: UMLS:C0017638 (glioma)
30,880 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A "recptor unit" for gamma-aminobutyric acid (GABA), which includes brainlike receptor binding sites for tritium-labeled GABA and benzodiazepines (diazepam, clonazepam, and flunitrazepam) and a thermostable endogenous protein (GABA modulin) that inhibits both GABA and benzodiazepine binding, has been demonstrated in membranes prepared from NB2a neuroblastoma and C6 glioma clonal cell lines. In these cells, as in brain, diazepam (1 micromolar) prevents the effect of GABA modulin, and in turn GABA (0.oma and, to a lesser extent, the glioma cells represent a suitable model to study the interactions and the sequence of membrane and intracellular events triggered by the stimulation of benzodiazepine and GABA receptors.
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PMID:GABA receptors in clonal cell lines: a model for study of benzodiazepine action at molecular level. 46 92

The metabolism of putrescine in neuroblastoma and glioma cells was analyzed during culture. In the former cells the formation of gamma-aminobutyric acid from putrescine was low and constant during the logarithmic phase and increased dramatically during the stationary phase or in cultures with low serum concentrations, while in the latter cells it was low and constant throughout culture. The formation of spermidine from putrescine in both cell lines was active at days 1-2 of culture and decreased gradually during culture. These findings indicate that spermidine formation is closely related to proliferation of the cells, and gamma-aminobutyric acid formation to differentiation or maturation of the neuroblastoma cells.
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PMID:Metabolism of putrescine in neuroblastoma and glioma cells during culture. 92 85

The C6-2B glioma cell line, rich in mitochondrial receptors that bind with high affinity to benzodiazepines, imidazopyridines, and isoquinolinecarboxamides (previously called peripheral-type benzodiazepine receptors), was investigated as a model to study the significance of the polypeptide diazepam binding inhibitor (DBI) and the putative DBI processing products on mitochondrial receptor-regulated steroidogenesis. DBI and its naturally occurring fragments have been found to be present in high concentrations in C6-2B glioma cells, to compete against specific isoquinolinecarboxamide or 4'-chlorodiazepam binding to mitochondrial recognition sites with high affinity, and to stimulate mitochondrial pregnenolone formation. These data suggest that this cell type may express both the receptor and the putative agonist ligand to regulate steroidogenesis. Therefore, we propose to term this mitochondrial receptor MDR (mitochondrial DBI receptor) to indicate its responsiveness to DBI in steroid biosynthesis. In the present work, we show that mitochondria of C6-2B cells convert (22R)-22-hydroxycholesterol to pregnenolone by a mechanism blocked by aminoglutethimide. Immunoblotting confirmed the presence of relatively high levels of cytochrome P-450 cholesterol side-chain-cleavage enzyme in C6-2B cell mitochondria. Furthermore, isoquinolinecarboxamide binding sites associated with the 18-kDa mitochondrial polypeptide subunit of the MDR are abundant in C6-2B glioma cell mitochondria (Bmax approximately 30 pmol/mg protein) and are coupled to the regulation of steroid biosynthesis. Occupancy of MDRs with nanomolar concentrations of the naturally occurring polypeptide, DBI, as well as its naturally occurring processing product tetratriacontaneuropeptide [DBI-(17-50)] increases pregnenolone formation. Clonazepam and octadecaneuropeptide [DBI-(33-50)], which exhibit a higher affinity for gamma-aminobutyric acid type A receptors but a low affinity for MDR, were ineffective in stimulating pregnenolone synthesis. These findings provide evidence that C6-2B cells exhibit a significant steroidogenic activity which resembles that found in peripheral endocrine organs and they suggest that MDRs and DBI are involved in the regulation of glial cell steroidogenesis.
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PMID:Pregnenolone biosynthesis in C6-2B glioma cell mitochondria: regulation by a mitochondrial diazepam binding inhibitor receptor. 131 81

1. The M-like current IK(M,ng) in differentiated NG108-15 mouse neuroblastoma x rat glioma hybrid cells has been studied using tight-seal, whole-cell patch-clamp recording. 2. When calculated from steady-state current-voltage curves, the conductance underlying IK(M,ng) showed a Boltzmann dependence on voltage with half-activation voltage Vo = -44 mV (in 3 mM [K+]) and slope factor (a) = 8.1 mV/e-fold increase in conductance. In 12 mM [K+] Vo = -38 mV and a = 6.9 mV. The deactivation reciprocal time constant accelerated with hyperpolarization with slope factor 17 mV/e-fold voltage change. 3. The reversal potential for deactivation tail currents varied with external [K+] as if PNa/PK were 0.005. 4. Steady-state current was increased on removing external Ca2+. In the presence of external Ca2+, reactivation of IK(M, ng) after a hyperpolarizing step was delayed. This delay was preceded by an inward Ca2+ current, and coincided with an increase in intracellular [Ca2+] as measured with Indo-1 fluorescence. Elevation of intracellular [Ca2+] with caffeine also reduced IK(M, ng). 5. IK(M, ng) was inhibited by external divalent cations in decreasing order of potency (mM IC50 in parentheses): Zn2+ (0.011) greater than Cu2+ (0.018) greater than Cd2+ (0.070) greater than Ni2+ (0.44) greater than Ba2+ (0.47) greater than Fe2+ (0.69) greater than Mn2+ (0.86) greater than Co2+ (0.92) greater than Ca2+ (5.6) greater than Mg2+ (16) greater than Sr2+ (33). This was not secondary to inhibition of ICa since: (i) inhibition persisted in Ca(2+)-free solution; (ii) La3+ did not inhibit IK(M, ng) at concentrations which inhibited ICa; and (iii) organic Ca2+ channel blockers were ineffective. Inhibition comprised both depression of the maximum conductance and a positive shift of the activation curve. Addition of Ca2+ (10 microM free [Ca2+]) or Ba2+ (1 mM total [Ba2+]) to the pipette solution did not significantly change IK(M, ng). 6. IK(M, ng) was reduced by 9-amino-1,2,3,4-tetrahydroacridine (IC50 8 microM) and quinine (30 microM) but was insensitive to tetraethylammonium (IC50 greater than 30 mM), 4-aminopyridine (greater than 10 mM), apamin (greater than 3 microM) or dendrotoxin (greater than 100 nM). 7. IK(M, ng) was inhibited by bradykinin (1-10 microM) or angiotensin II (1-10 microM), but not by the following other receptor agonists: acetylcholine (10 mM), muscarine (10 microM), noradrenaline (100 microM), adrenaline (100 microM), dopamine (100 microM), histamine (100 microM), 5-hydroxytryptamine (10 microM), Met-enkephalin (1 microM), glycine (100 microM), gamma-aminobutyric acid (100 microM) or baclofen (500 microM).(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Kinetic and pharmacological properties of the M-current in rodent neuroblastoma x glioma hybrid cells. 140 9

In neuronal cells, opioid peptides and opiates inhibit neurotransmitter release, which is a calcium-dependent process. They also inhibit adenylyl cyclase, presumably via the membrane signal-transducing component, Gi, a guanine nucleotide-binding protein (G-protein). No causal relationship between these two events has yet been demonstrated. Besides Gi, membranes of neuronal tissues contain large amounts of Go, a G-protein with unknown function. Both G-proteins are heterotrimers consisting of alpha-, beta- and gamma-subunits; the alpha-subunits can be ADP-ribosylated by an exotoxin from Bordetella pertussis (PT), which modification inhibits receptor-mediated activation of the G-protein. It was recently shown that noradrenaline, dopamine and gamma-aminobutyric acid (GABA) inhibit the voltage-dependent calcium channels in dorsal root and sympathetic ganglia; this inhibition is mimicked by intracellular application of guanine nucleotides and blocked by PT, suggesting the involvement of a G-protein. Here we report an inhibitory effect of the opioid D-Ala2, D-Leu5-enkephalin (DADLE) on the calcium current (ICa) in neuroblastoma X glioma hybrid cells (N X G cells). Pretreatment with PT almost completely abolishes the DADLE effect. The effect is restored by intracellular application of Gi and Go. As the alpha-subunit of Go (with or without beta-gamma complex) is 10 times more potent than Gi, we propose that Go is involved in the functional coupling of opiate receptors to neuronal voltage-dependent calcium channels.
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PMID:The GTP-binding protein, Go, regulates neuronal calcium channels. 243 90

Glioma C6 cells were incubated with [14C]arachidonate to label membrane phospholipids. Muscimol, a selective gamma-aminobutyric acid A receptor agonist, but not (-)-baclofen, a selective gamma-aminobutyric acid B receptor agonist, stimulates [14C]arachidonate release from C6 cells as a result of hydrolysis of a small pool of phosphatidylcholine and phosphatidylethanolamine by phospholipase A2. This release is facilitated by diazepam and a number of other benzodiazepines such as flunitrazepam, medazepam and midazolam (but very little by clonazepam), although these benzodiazepines per se are inactive in causing the release. In addition to increasing the release of [14C]arachidonate, diazepam in the presence of muscimol promotes the release of [14C] prostaglandin D2. Bicuculline inhibits the action of muscimol and facilitation by diazepam. "Peripheral" benzodiazepine ligand, RO 5-4864 (4'-chlordiazepam) antagonizes the action of diazepam, whereas "central" ligand, RO 15-1788, is inactive. The release of arachidonate metabolites stimulated by muscimol and diazepam is unaffected by Cl- channel blockers, picrotoxin and pentylenetetrazol. Based on these results we propose that in glioma C6 cells (and presumably in normal glia) peripheral benzodiazepine receptor interacts functionally with gamma-aminobutyric acid A type of receptor, which appears not to be linked to picrotoxin sensitive Cl- channel, and may be linked to phospholipase A2.
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PMID:Benzodiazepines enhance the muscimol-dependent activation of phospholipase A2 in glioma C6 cells. 285 84

The in vivo uptake and metabolism of radiolabeled putrescine was examined in two glioma models: (a) the T9 gliosarcoma in the CD Fischer rat and (b) the U-87 MG human glioblastoma in the athymic (nude) mouse. Autoradiography after parenteral administration of [14C]putrescine revealed rapid and selective uptake by both tumors compared with normal brain. Polyamine analysis of the rat gliosarcoma demonstrated minimal conversion of labeled putrescine to its metabolites, spermidine and spermine, at 5 and 30 minutes after intravenous injection. The human glioblastoma also exhibited minimal polyamine conversion at 5 minutes, although there was a trend toward significant metabolism at longer time periods (30 and 45 minutes). In addition, the human glioblastoma produced nonpolyamine metabolites that suggest an alternative pathway of putrescine metabolism via gamma-aminobutyric acid. These in vivo findings are discussed in relation to the usefulness of putrescine as a marker for positron emission tomography of human gliomas.
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PMID:In vivo metabolism of radiolabeled putrescine in gliomas: implications for positron emission tomography of brain tumors. 326 87

The activity of ornithine decarboxylase (EC 4.1.1.17) increased in confluent cultures of glioma C6BU-1 cells 3 h after adding a complete serum-containing medium, and was maximal 5 h later. The activity of S-adenoxyl-L-methionine decarboxylase (EC 4.1.1.50) increased soon after addition of the complete medium to the cells, and reached its peak after 11 h. The activity of diamine oxidase (EC 1.4.3.6) also increased soon after adding complete medium and was maximal 8h later, when the activity of ornithine decarboxylase reached its peak. The increase in the activity of S-adenosyl-L-methionine decarboxylase was accompanied by changes in cellular spermidine and spermine concentrations, whereas the increase in the activity of diamine oxidase was followed by the accumulation of gamma-aminobutyric acid, which was detected both in the cells and in the medium. Asparagine enhanced the utilization of radioactive putrescine by glioma cells suspended in buffered-salt/glucose solution and increased intracellular and extracellular gamma-aminobutyric acid concentrations. Radioactive putrescine was converted into spermidine and spermine by glioma cells after addition of a serum-containing medium, but not after adding buffered--salt/glucose solutions, in the presence or absence of asparagine. The kinetics of ornithine decarboxylase 'induction' and the half-life of the enzyme differed in cells incubated with buffered asparagine solutions and serum-containing media.
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PMID:Metabolism of polyamines by cultured glioma cells. Effect of asparagine on gamma-aminobutyric acid concentrations. 677 65

Isogabaculine (3-amino-1,3-cyclohexadienyl carboxylic acid; RMI 71,932), an irreversible inhibitor of GABA transaminase, when added to mouse neuroblastoma cells in spinner culture at the time of induction of cell proliferation, increased ornithine decarboxylase (ODC) activity threefold above that of normal control cells and twofold above that of GABA (gamma-aminobutyric acid)-treated cells. Isogabaculine did not affect ODC activity of rat glioma (C6) or rat hepatoma (HTC) cells. As determined by half-life measurements of ODC and intracellular GABA concentrations, isogabaculine apparently has a direct stabilizing effect on ODC in neuroblastoma cells that is unrelated to the accumulation of GABA due to GABA transaminase inhibition. Putrescine metabolism to GABA or spermidine was determined in C6, HTC, and neuroblastoma cells in the presence or absence of isogabaculine and/or GABA. Neither GABA nor isogabaculine treatment dramatically altered the metabolism of putrescine to GABA or spermidine in neuroblastoma, C6 glioma, or HTC cells. However, the appreciable amount of labeled GABA formed from putrescine indicated that this metabolic route may be more important than was previously thought.
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PMID:Effect of GABA and isogabaculine on ornithine decarboxylase and putrescine metabolism. 709 60

To clarify the unique characteristics of amino acid metabolism derived from glucose in the central nervous system (CNS), we injected [1-13C]glucose intraperitoneally to the rat, and extracted the free amino acids from several kinds of tissues and measured the amount of incorporation of 13C derived from [1-13C]glucose into each amino acid using 13C-magnetic resonance spectroscopy (NMR). In the adult rat brain, the intensities of resonances from 13C-amino acids were observed in the following order: glutamate, glutamine, aspartate, gamma-aminobutyrate (GABA) and alanine. There seemed no regional difference on this labeling pattern in the brain. However, only in the striatum and thalamus, the intensities of resonances from [2-13C]GABA were larger than that from [2,3-13C]aspartate. In the other tissues, such as heart, kidney, liver, spleen, muscle, lung and small intestine, the resonances from GABA were not detected and every intensity of resonances from 13C-amino acids, except 13C-alanine, was much smaller than those in the brain and spinal cord. In the serum, 13C-amino acid was not detected at all. When the rats were decapitated, in the brain, the resonances from [1-13C]glucose greatly reduced and the intensities of resonances from [3-13C]lactate, [3-13C]alanine, [2, 3, 4-13C]GABA and [2-13C]glutamine became larger as compared with those in the case that the rats were sacrificed with microwave. In other tissues, the resonances from [1-13C]glucose were clearly detected even after the decapitation. In the glioma induced by nitrosoethylurea in the spinal cord, the large resonances from glutamine and alanine were observed; however, the intensities of resonances from glutamate were considerably reduced and the resonances from GABA and aspartate were not detected. These results show that the pattern of 13C label incorporation into amino acids is unique in the central nervous tissues and also suggest that the metabolic compartmentalization could exist in the CNS through the metabolic trafficking between neurons and astroglia.
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PMID:Measurement of amino acid metabolism derived from [1-13C]glucose in the rat brain using 13C magnetic resonance spectroscopy. 806 17

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