Stereoselective uptake of the GABA-transaminase inhibitors gamma-vinyl gaba and gamma-acetylenic GABA into neurons and astrocytes

The cellular uptake of the GABA-transaminase inhibitors gamma-vinyl GABA (GVG) and gamma-acetylenic GABA (GAG) was studied in cultured neurons and astrocytes. By the use of the individual enantiomersR- andS-GVG andR- andS-GAG it could be shown that in both cell types only theS-enantiomers could be actively transported. Comparing neurons and astrocytes only neurons exhibited a high affinity uptake system forS-GVG (K _m 78.2±20.3 M;V _max 0.71±0.06 nmol · min^–1 · mg^–1 cell protein). In case ofS-GAG it could not be established with certainty whether the neuronal uptake was of the high affinity type. Both GVG and GAG were studied as inhibitors of GABA uptake into neurons and astrocytes.S-GVG andS-GAG were found to be weak inhibitors of GABA uptake suggesting thatS-GVG is not transported by the GABA carrier in neurons. The finding of a much more efficient uptake ofS-GVG into neurons than into astrocytes is in line with the previous observation that neuronal GABA-T is more sensitive than astrocytic GABA-T toS-GVG.     

Effect ofl-homocysteine and derivatives on the high-affinity uptake of taurine and GABA into synaptosomes and cultured neurons and astrocytes

The effect ofl-nomocysteine and selected derivatives on the high-affinity uptake of the inhibitory neuroeffectors, GABA and taurine, was investigated in synaptosomes, and in cultured neurons and astrocytes. High-affinity uptake of taurine into synaptosomes was inhibited most effectively byl-homocysteine,Dl-homocysteine and homocystine whereas neuronal uptake was unaffected by any of the compounds tested. The high affinity uptake of taurine into astrocytes was markedly inhibited byl-homocysteine,l-homocysteic acid andl-homocystine. High-affinity GABA uptake into astrocytes was notably inhibited byl-homocystine, none of the other compounds tested causing appreciable inhibition below a concentration of 5 mM. Neuronal and synaptosomal high-affinity uptake of GABA was not significantly affected by any of the test compounds at concentrations below 5 mM. The implication of these results to the study of the mechanism of homocysteine-induced seizures and their relevance to the genetic disorder homocystinuria is discussed.     

Induction by Hydrocortisone of Glutamine Synthetase in Mouse Primary Astrocyte Cultures

Glutamine synthetase activity was investigated in developing primary astroglial cultures established from newborn mouse cerebral hemispheres. Between the 2nd and 4th week of culture there was little change in activity under our standard culturing conditions; however, when hydrocortisone (10 microM) was added to the cultures for 48 h, the enzyme activity increased two- to fourfold, depending upon the age of the culture, with maximum response in 2-week-old cultures. The addition of dibutyryl cyclic AMP (dBcAMP) to the culture medium caused morphological differentiation of the astroglial cells but eliminated the response of the cells to hydrocortisone. Culturing in elevated serum levels, which delays morphological differentiation and inhibits astroglial cytodifferentiation after exposure to dBcAMP, shifted the time of maximal response to hydrocortisone from 2 to 3 weeks and prevented the abolishment of glutamine synthetase induction by dBcAMP. The induction of glutamine synthetase by hydrocortisone was prevented by actinomycin D (0.5 microgram/ml), indicating its dependence upon RNA and protein synthesis. The present work thus confirms reports in the literature that hydrocortisone induces glutamine synthetase in neural tissues, but differs from the findings of Moscona and co-workers in the chick retina that intact tissues are required for the induction to occur.     

Metabolism and Release of Glutamate in Cerebellar Granule Cells Cocultured with Astrocytes from Cerebellum or Cerebral Cortex

Cerebellar granule cells were cocultured with astrocytes from either cerebral cortex or cerebellum in two different systems. In one system the cells were plated next to each other only sharing the culture medium (separated cocultures) and in the other system the granule cells were plated on top of a preformed layer of astrocytes (sandwich cocultures). Using astrocytes from cerebellum, granule cells developed morphologically and functionally showing a characteristic high activity of the glutamate synthesizing enzyme aspartate aminotransferase (AAT) as well as a high stimulus-coupled transmitter release regardless of the culture system, i.e., granule cells could grow on top of cerebellar astrocytes as well as next to these cells. In the case of cerebral cortex astrocytes it was found that cerebellar granule cells did not develop (11% survival) when seeded on top of these astrocytes. This was indicated by the morphological appearance of the cultures as well as by a negligible difference between the AAT activity in sandwich cocultures and astrocytes cultured alone. On the other hand, granule cells in separated cocultures with cerebral cortex astrocytes exhibited a normal morphology and a high activity of AAT as well as a large stimulus-coupled transmitter release. Cerebellar and cortical astrocytes expressed the astrocyte specific enzyme glutamine synthetase in a glucocorticoid-inducible form regardless of the culture system. The results show that under conditions of direct contact between granule cells and astrocytes, regional specificity exists with regard to neuron-glia contacts. This specificity does not seem to involve soluble factors present in the culture medium because in separated cocultures the cerebellar granule cells developed normally regardless of the regional origin of the astrocytes.     

Stimulation of γ-[3H]Aminobutyric Acid Release from Cultured Mouse Cerebral Cortex Neurons by Sulphur-Containing Excitatory Amino Acid Transmitter Candidates: Receptor Activation Mediates Two Distinct Mechanisms of Release

In primary cultures of mouse cerebral cortex neurons, sulphur-containing excitatory amino acids (SAAs; namely, L-cysteine sulphinate, L-cysteate, L-homocysteine sulphinate, L-homocysteate, S-sulphocysteine) at concentrations ranging from 0.1 microM to 1 mM evoked a saturable release of gamma-[3H]aminobutyric acid ([3H]GABA) in the absence of any other depolarizing agent. All SAAs exhibited essentially similar potency (EC50, 100-150 microM) in releasing [3H]GABA although a variable profile of maximal stimulatory effect was observed when compared with basal release. The intracellular accumulation of the lipophilic cation, [3H]tetraphenylphosphonium, was significantly reduced in the presence of all SAAs, thus verifying a depolarization of the neuronal plasma membrane. SAA-stimulated release of [3H]GABA was shown to comprise two distinct components, calcium-dependent and calcium-independent, which occur after activation of N-methyl-D-aspartate (NMDA) and non-NMDA receptors. Thus, all SAA-evoked responses were antagonized by the selective, competitive NMDA-receptor antagonist, 3-[(+/-)-2-carboxypiperazin-4-yl]propyl-1-phosphonic acid (IC50 range, greater than 50 microM) and the non-NMDA-receptor antagonist, 6,7-dinitroquinoxalinedione (IC50 range, 5-50 microM). Removal of magnesium ions from the superfusion medium caused a significant potentiation of SAA-evoked responses without having any effect on basal levels of [3H]GABA efflux, a result consistent with an involvement of NMDA-receptor activation. Calcium-independent release (i.e., that release remaining in the presence of 1 mM cobalt ions) was a distinct component but of smaller magnitude. Using 500 microM excitatory amino acid agonist concentrations, this component of release was (1) markedly attenuated by 15 microM SKF-89976-A, a non-transportable inhibitor of the GABA carrier, and (2) abolished when choline ions replaced sodium ions in the superfusion medium or when in the presence of excitatory amino acid receptor antagonists. These observations are clearly consistent with a receptor-mediated, depolarization-induced reversal of the GABA carrier.     

Light and electron microscopic localization of GABAA-receptors on cultured cerebellar granule cells and astrocytes using immunohistochemical techniques

GABA_A-receptors were localized in explant cultures of rat cerebellum and in dissociated primary cultures of rat cerebellar granule cells and rat cerebellar astrocytes using the monoclonal antibody bd-17 directed against the -subunit of the GABA_A/benzodiazepine/chloride channel complex. At the light microscope level specific staining of GABA_A-receptors was localized in various types of neurones in explant cultures of rat cerebellum using the indirect peroxidase-antiperoxidase (PAP) technique, whereas no specific staining was found in astrocytes. At the electron microscope level labeling of GABA_A-receptors was observed in the plasma membrane of both the cell bodies and processes in dissociated primary cultures of cerebellar granule cells using an indirect preembedding immunogold staining technique which in contrast to the classical PAP technique allows quantitative estimations to be performed. Quantification of the labeling intensity revealed a higher concentration of GABA_A-receptors per m plasma membrane in the cell bodies than in the processes. In discrete areas an extremely high density of the GABA_A-receptors was observed. No specific labeling of GABA_A-receptors was observed in dissociated primary cultures of cerebellar astrocytes.Special issue dedicated to Dr. Eugene Roberts.     

Glutaminase in neurons and astrocytes cultured from mouse brain: Kinetic properties and effects of phosphate,glutamate, and ammonia

Phosphate activated glutaminase comprises two kinetically distinguishable enzyme forms in cultures of cerebellar granule cells, of cortical neurons and of astrocytes. Specific activity of glutaminase is higher in cultured neurons compared with astrocytes. Glutaminase is activated by phosphate in all cell types investigated, however, glutaminase in astrocytes reguires a much higher concentration of phosphate for half maximal activation. One of the products, glutamate, inhibits the enzyme strongly, whereas the other product ammonia has only a slight inhibitory action on the enzyme.     

Evidence for evoked release of adenosine and glutamate from cultured cerebellar granule cells

Evoked release of [³H]-D-aspartate which labels the neurotransmitter glutamate pool in cultured cerebellar granule cells was compared with evoked release of adenosine from similar cultures. It was found that both adenosine and [³H]-D-aspartate could be released from the neurons in a calcium dependent manner after depolarization of the cells with either 10–100 M glutamate or 50 mM KCl. Cultures of cerebellar granule cells treated with 50 M kainate to eliminate GABAergic neurons behaved in the same way. This together with the observation that cultured astrocytes did not exhibit a calcium dependent, potassium stimulated adenosine release strongly suggest that cerebellar granule cells release adenosine in a neurotransmitter-like fashion together with glutamate which is the classical neurotransmitter of these neurons. Studies of the metabolism of adenosine showed that in the granule cells adenosine is rapidly metabolized to ATP, ADP, and AMP, but in spite of this, adenosine was found to be released preferential to ATP.     

Correction to: Delineation of the Role of Astroglial GABA Transporters in Seizure Control

Neurochemical Research - The original version of this article unfortunately contained a mistake. In Fig. 1 two chemical structures are incorrect, namely exo-THPO and N-methyl-exo-THPO. The...