Amino acid uptake by neurones and glial cells from embryonic cockroach brain growing in vitro

Insect neuronal cultures and glial-enriched cultures derived from the brains of embryonic cockroaches have been used to investigate the uptake of putative amino acid neurotransmitters. Some neurones and all of the glia in these cultures possess uptake systems for [³H]l-glutamate and [³H]GABA. The neuronal and glial uptake of l-glutamate is reduced by d-aspartate. Neuronal accumulation of [³H]GABA is reduced by nipecotic acid but is not inhibited by β-alanine and DABA, whereas DABA is the most potent inhibitor of GABA accumulation by glia. The cockroach glial cells did not accumulate taurine, glycine, d-aspartate or leucine but there was some neuronal uptake of both taurine and glycine although this was insensitive to sodium ions.     

Effects of amino acids on calcium uptake by glial and neuroblastoma cells

The uptake of [⁴⁵Ca] has been studied in clonal glial and neuronal cells. It was somewhat more efficient in the neuroblastoma clone M₁ compared to glial clones. In all cases [⁴⁵Ca] uptake was shown to depend on the phosphate concentration in the incubation medium. It was decreased by the ionophore A 23187 at 200 μM concentration in both neuronal and glial clones. The influence of amino acids some of which are putative neurotransmitters was investigated; the interactions between [⁴⁵Ca] uptake and these amino acids were related to their concentration and the type of cells used (neuronal or glial). L-aspartate and taurine for example had two opposite effects on [⁴⁵Ca] uptake by the glial clone NN at two different concentrations; they could therefore play a role in the control of calcium level in the synaptic cleft.     

Changes in the Uptake of GABA and Taurine During Neuronal and Glial Maturation

Abstract: The influence of the time of culture on GABA and taurine uptake was investigated in spontaneously matured cultures of glial and neuronal origins and in cultures treated with cyclic nucleotides. In the spontaneously matured cultures the capacity of the high-affinity neuronal GABA transport system increased with time in culture. Essentially opposite results were found for the uptake of GABA by glial cultures. In contrast with the neuronal uptake of GABA, the capacity of the taurine transport system was significantly decreased. Uptake of taurine into glia, however, exhibited a progressive increase with the period of culture. The values of Km, for the high-affinity systems were always found to range around 10 μM. It is suggested that, in mature cells, neuronal uptake sites are of prime importance for GABA transport, while taurine uptake may be more specifically directed towards glial cells. When cultures were treated with cyclic nucleotide derivatives, a morphological differentiation was induced, which could not be linked to a stimulation of GABA or taurine uptake systems as compared with the non-treated cultures.     

Effects of amino acids on calcium uptake by glial and neuroblastoma cells.

The uptake of [45Ca] has been studied in clonal glial and neuronal cells. It was somewhat more efficient in the neuroblastoma clone M1 compared to glial clones. In all cases [45Ca] uptake was shown to depend on the phosphate concentration in the incubation medium. It was decreased by the ionophore A 23187 at 200 microM concentration in both neuronal and glial clones. The influence of amino acids some of which are putative neurotransmitters was investigated; the interactions between [45Ca] uptake and these amino acids were related to their concentration and the type of cells used (neuronal or glial). L-aspartate and taurine for example had two opposite effects on [45Ca] uptake by the glial clone NN at two different concentrations; they could therefore play a role in the control of calcium level in the synaptic cleft.     

Glial uptake system of GABA distinct from that of taurine in the bullfrog sympathetic ganglia

The kinetics and specificity of GABA and taurine uptake were studied in the bullfrog sympathetic ganglia. GABA uptake system consisted of simple saturable component and taurine uptake system consisted of two saturable components exclusive of non-saturable influx. Taurine unaffected GABA uptake while GABA inhibited taurine uptake competitively with theK _i/K_m ratio of 38. GABA (5.14 M) uptake was inhibited by -aminovaleric acid and slightly by 2,4-diaminobutyric acid (5 mM, each) among ten structural analogs. Taurine uptake under high-affinity conditions was most strongly suppressed by hypotaurine and -alanine competitively with theK _i/K_m ratio of 1.0 and 1.9, respectively. Autoradiography showed that glial cells were heavily labeled by both [³H]GABA and [³H]taurine. These results suggest that GABA is transported by a highly specific carrier system distinct from the taurine carrier and that taurine, hypotaurine, and -alanine may share the same high-affinity carrier system in the glial cells of the bullfrog sympathetic ganglia.     

Uptake of taurine into subcellular fractions of C-6 glioma cells.

Subcellular fractions from cultured C-6 glioma cells prepared by methods similar to those for crude synaptosomal fractions of rat cerebral cortex accumulated [³⁵S]taurine as did intact glioma cells. Thus, the accumulation of taurine was dependent on temperature and sodium concentration and sensitive to osmotic shock. The kinetic properties of this uptake are characterized by an apparent K_m, of about 25 μm, The properties of taurine uptake into subcellular fractions from C-6 glioma cells were compared with those of crude synaptosomal fractions and differences could be observed in temperature sensitivity and with metabolic inhibitors, which were less potent in the glioma preparation. Equilibrium density gradient centrifugation of subcellular fractions from glioma cells revealed that particles containing [³⁵S]taurine sediment to a lower buoyant density than mitochondria. But on co-sedimentation of subcellular fractions from glioma cells with synaptosomal fractions derived from cerebral cortex, differences in the buoyant density between these two preparations could be found. The findings support the possibility of a contamination of synaptosomal fractions with subcellular fractions derived from glial origin.     

Estrogen regulation and ion dependence of taurine uptake by MCF-7 human breast cancer cells

It has been reported that estrogen receptor-positive MCF-7 cells express TauT, a Na⁺-dependent taurine transporter. However, there is a paucity of information relating to the characteristics of taurine transport in this human breast cancer cell line. Therefore, we have examined the characteristics and regulation of taurine uptake by MCF-7 cells. Taurine uptake by MCF-7 cells showed an absolute dependence upon extracellular Na⁺. Although taurine uptake was reduced in Cl^- free medium a significant portion of taurine uptake persisted in the presence of NO₃ ^-. Taurine uptake by MCF-7 cells was inhibited by extracellular β-alanine but not by L-alanine or L-leucine. 17β-estadiol increased taurine uptake by MCF-7 cells: the V_max of influx was increased without affecting the K_m. The effect of 17β-estradiol on taurine uptake by MCF-7 cells was dependent upon the presence of extracellular Na⁺. In contrast, 17β-estradiol had no significant effect on the kinetic parameters of taurine uptake by estrogen receptor-negative MDA-MB-231 cells. It appears that estrogen regulates taurine uptake by MCF-7 cells via TauT. In addition, Na⁺-dependent taurine uptake may not be strictly dependent upon extracellular Cl^-.     

NEURONAL AND GLIAL SYSTEMS FOR γ-AMINOBUTYRIC ACID TRANSPORT

—The uptake of [2,3-³H]γ-aminobutyric acid (GABA) by bulk prepared neuronal perikarya, nerve endings and glial cells has been studied in an in vitro-system. The uptake in the different fractions had a similar dependence for sodium, potassium and magnesium. Calcium stimulated the synaptosomal GABA uptake at concentrations which inhibited the glial uptake. Bicuculline strongly inhibited the uptake in all fractions. Picrotoxin and strychnine had little effect on the neuronal uptake whereas glial uptake was stimulated. l -2,4-di-aminobutyric acid and chlorpromazine inhibited GABA uptake in all fractions. The effect of cyclic AMP was not significant.     

GABA and taurine sensitivity of cockroach giant interneurone synapses: Indirect evidence for the existence of a GABA uptake mechanism

The effects of exogenous GABA and taurine were studied on the cercal afferent-giant interneurone synapses (G.I. 2) located in the neuropile of the sixth abdominal ganglion of the cockroach, Periplaneta americana L. The decrease in excitatory synaptic potentials and the increase in postsynaptic membrane conductance due to GABA were enhanced by lowering the temperature of the saline, by using Na⁺ pump inhibitors, Na⁺ free salines or by agents blocking GABA uptake. The action of temperature was studied for taurine. Implications of these results for the identification of a metabolically dependent GABA uptake mechanism into glial cells are discussed.     

Uptake and metabolism of l-[3H]pyroglutamic acid in neuronal and glial cells in culture

The presence of an efficient uptake system for l-pyroglutamate was demonstrated in cultured glial cells originating from newborn rats. This compound is also transported by a high affinity uptake mechanism in neurons cultured from rat embryos cerebral hemispheres, but the V_max is 6 times lower than for glial cells. It is shown that l-pyroglutamate like l-glutamate is preferentially transported by glial cells, but with a V_max 40 to 60 times lower than for glutamate. The metabolism of l-pyroglutamate was also studied in cultured rat neuronal and glial cells, using l-[³H]pyroglutamate. Pyroglutamate, its metabolites and the various amino acids were separated by thin-layer electrophoresis. [³H]Pyroglutamate is more actively metabolised in glial cells than in neurons and glutamate is the main metabolite. Glutamate maximal specific activity is 4 times higher in glial than in neuronal cultures. It should also be noted that some [³H]pyroglutamate is transformed in [³H]GABA after longer incubation periods, but only in neurons. These results show the importance of glial cells for pyroglutamate uptake and metabolism in nervous tissue. They also suggest that pyroglutamate may interfere with glutamate neurotransmission in vivo.     

Cysteine sulfinic acid uptake in cultured neuronal and glial cells

The presence of an efficient high affinity uptake system for L-CSA has been demonstrated in cultured neuronal and glial cells of various types. In neurons and most glial cells L-CSA uptake is inhibited by acidic amino acids,L-glutamate andL-aspartate and requires sodium ions; however the sodium dependence varies from one cell type to the other. The characteristics of the uptake system change during cell maturation, especially in astroblasts. The predominance of CSA uptake in glial cells as compared to neurons, the similarity of the kinetic parameters and of the structural specficity ofL-glutamate uptake suggest that both excitatory amino acids are transported by a common system. In view of accumulating evidence, the present results are in agreement with a role of CSA as a neurotransmitter and as a precursor for taurine biosynthesis in the central nervous system.     

PHOSPHOLTPID METABOLISM IN ISOLATED NEURONAL AND GLIAL CELLS FROM BRAINS OF 17-DAY OLD RATS1

Neuronal and glial cells were isolated from the brains of 17-day old rats and incubated for 5 h with either radioactive inorganic phosphate, palmitate, serine, choline or ethanolamine in a tissue culture medium. A comparison of the results suggests that both neuronal and glial cells exhibit effective de novo, phospholipid synthesis and that the observed differences in the uptake are due more to quantitative rather than qualitative differences in phospholipid metabolism of both cell types. Incubations of the combined neuronal and glial fractions with ³²PO₄ and [³H]palmitate result in incorporations up to 100% higher than calculated from incubations of the separate fractions, suggesting that phospholipid metabolism of neuronal and glial cells may exhibit cooperativity.     

RESPIRATION BY CULTIVATED ASTROCYTES AND NEURONS FROM THE CEREBRAL HEMISPHERES

-Rates of oxygen uptake were measured in chick and/or rat astrocytes and neuronal cells cultivated for 2–4 weeks in Falcon flasks or Rose chambers. All the preparations were found to have respiratory rates between 0.4 and 0.8 × 10^?5μl/h O₂ per cell. Based upon measurements of cell diameters these values were recalculated to about 570 μmol/g wet wt. for the neuronal cells and 130 μmol/g wet wt. for the glial cells. The results are compared with previous data of oxygen uptake by neurons and glial cells separated by other procedures.     

Effects of phorbol ester on immunoreactive protein kinase C,insulin binding,and glucose uptake in astrocytic glial and neuronal cells from the brain

Phorbol esters, potent stimulators of protein kinase C (PKC), stimulate [³H]2-deoxy-d-glucose (dGlc) uptake and [¹²⁵I] insulin binding in cultured glial cells but not neuronal cells from neonatal rat brains. Using an antibody to the and forms of PKC we have demonstrated that both neuronal and glial cells contain an immunoactive PKC of Mr 80 kD, although the PKC level in neurons is greater than 4-fold that in glia. The majority of immunoactive PKC (63%) is cytosolic in glial cells although the reverse is true in neuronal cells, in which 88% of the PKC is membrane-bound in the basal state. The most potent phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), stimulates a redistribution of this enzyme in neuronal and glial cells. The TPA-stimulated translocation of PKC from cytosol to membrane precedes TPA's effecs of [³H]dGlc uptake and insulin binding in glial cells.     

Autoradiographic localization of 3H-histamine accumulation by the visual system of the locust

Summary The uptake of [³H]-histamine into the retina and optic lobe of the locust, Schistocerca americana gregaria was studied by means of autoradiography at the light- and electron-microscopic levels. Light-microscopic autoradiography showed a significant accumulation of [³H]-histamine in several regions of the optic lobe. Dense accumulations of silver grains were concentrated along the medial border of the medullary neuropil and around the entire periphery of the lobula. No significant accumulations of grains were present within the retina or the neuropil zones of the lamina, medulla or lobula.Electron-microscopic autoradiography showed histamine-accumulating cells along the border of the medulla to exhibit electron density and morphology typical of glial cells. Labelled histamine was present within both glial cell bodies and their processes. In the region surrounding the neuropil of the lobula, [³H]-histamine was concentrated within fine glial processes wrapped around neuronal cell bodies and their axons. No neuronal cell bodies or axons showed accumulation of silver grains above background.These results are consistent with previous studies showing the glial uptake of amino acid and biogenic amine putative neurotransmitters. However, the lack of a demonstration of a specific uptake of histamine in neuropil zones makes it difficult to assess the role of histamine uptake in the inactivation of neurally released histamine in the locust visual system.     

Modulation of taurine uptake in the goldfish retina and axonal transport to the tectum¶Effect of crushing the optic nerve or axotomy

Summary. Although there are a great number of studies concerning the uptake of taurine in several tissues, the regulation of taurine transport has not been studied in the retina after lesioning the optic nerve. In the present study, isolated retinal cells of the goldfish retina were used either immediatly after cell suspension or in culture. The high-affinity transport system of [³H]taurine in these cells was sodium-, temperature- and energy-dependent, and was inhibited by hypotaurine and β-alanine, but not by γ-aminobutyric acid. There was a decrease in the maximal velocity (V_max) without modifications in the substrate affinity (K_m) after optic axotomy. These changes were mantained for up to 15 days after the lesion. The results might be the summation of mechanisms for providing extracellular taurine to be taken up by other retinal cells or eye structures, or regulation by the substrate taurine, which increases after lesioning the optic nerve. The in vivo accumulation of [³H]taurine in the retina after intraocular injection of [³H]taurine was affected by crushing the optic nerve or by axotomy. A progressive retinal decrease in taurine transport was observed after crushing the optic nerve, starting at 7 hours after surgery on the nerve. The uptake of [³H]taurine by the tectum was compensated in the animals that were subjected to crushing of the optic nerve, since the concentration of [³H]taurine was only different from the control value 24 hours after the lesion, indicating an efficient transport by the remaining axons. On the contrary, the low levels of [³H]taurine in the tectum after axotomy might be an index of the non-axonal origin of taurine in the tectum. Axonal transport was illustrated by the differential presence of [³H]taurine in the intact or crushed optic nerve. The uptake of [³H]taurine into retinal cells in culture in the absence or in the presence of taurine might indicate the existence of an adaptive regulation of taurine transport in this tissue, however taurine transport probably differentially occurs in specific populations of retinal cells. The use of a purified preparation of cells might be useful for future studies on the modulation of taurine transport by taurine in the retina and its role during regeneration. Received June 11, 1999/Accepted August 31, 1999     

Net taurine transport and its inhibition by a taurine antagonist

P₂-fractions were isolated from rat brain, and used to study net taurine transport. The fractions were incubated in increasing concentrations of [³H]taurine and the intraterminal concentration measured by liquid scintillation and amino acid analysis. The membrane potential of the isolated fractions was estimated using⁸⁶Rb⁺ as a marker for intracellular K⁺. Taurine was synthesized in the P₂-fraction when incubated in taurine free medium. At external taurine concentrations below 370 M a significant amount of the endogenous taurine was released to the incubation medium. Net taurine uptake into the P₂-fraction was achieved at external taurine concentrations exceeding 370 M. The taurine antagonist 6-aminomethyl-3-methyl-4H, 1, 2, 4-benzothiadiazine-1, 1-dioxide (TAG) competitively inhibited taurine and [³H]taurine transport into the P₂-fraction. As the external concentration of taurine was increased, the accumulation of⁸⁶Rb⁺ into the P₂-fraction was facilitated. This indicated an increasing hyperpolarization of the neuronal membrane as taurine transport shifted from release towards uptake. TAG reduced the hyperpolarization that paralleled taurine accumulation, in a dose dependent manner. Our results indicate that relatively low transmembranal gradients of taurine may be maintained by an electrogenic taurine transporter having a large transport capacity. Such a transporter may well serve the needs of osmotic regulation, i.e. to transport large amounts of taurine in any direction across the neuronal membrane.     

Taurine in the developing cat: Uptake and release in different brain areas

Taurine is an important modulator of neuronal activity in the immature brain. In kittens, taurine deficiency causes serious dysfunction in the cerebellar and cerebral visual cortex. The processes of taurine transport in vitro were now studied for the first time in different brain areas in developing and adult cats. The uptake of taurine consisted initially of two saturable components, high- and low-affinity, in synaptosomal preparations from the developing cerebral cortex and cerebellum, but the high-affinity uptake component completely disappeared during maturation. The release of both endogenous and preloaded labeled taurine from brain slices measured in a superfusion system was severalfold stimulated with a slow onset by depolarizing K⁺ (50 mM) concentrations. K⁺ stimulation released markedly more taurine from the cerebral cortex, cerebellum and brain stem in kittens than in adult cats. The responses were largest in the cerebellum. Both uptake and release of taurine are thus highly efficient in the brain of kittens and may be of significance in view of the vulnerability of cats to taurine deficiency.     

Taurine and hypotaurine transport in neuroblastoma cells: effects of cations

The cation requirements of [³H]taurine and [³⁵S]hypotaurine uptake by cultured neuroblastoma C1300 cells were compared in Krebs-Ringer-Hepes-glucose medium. The uptakes were strictly sodium-dependent at both low and high taurine and hypotaurine concentrations. The omission of Ca²⁺ or Mg²⁺ ions affected uptakes only marginally. The optimal K⁺ concentration was equal to the physiological concentration, whereas abnormally high K⁺ levels inhibited similarly taurine and hypotaurine uptake. The sodium dependence curves of both uptakes were sigmoidal in character at low and high taurine and hypotaurine concentrations. Hill plots suggest that two Na⁺ ions are coupled with the transfer of one taurine or hypotaurine molecule into neuroblastoma cells. With respect to cation requirements taurine and hypotaurine transports are similar in cultured neuroblastoma cells and display features considered typical of the uptake of a neurotransmitter amino acid.     

Stimulation of amino acid accumulation in neuroblastoma and astrocytoma cells byl-histidine

Uptake of amino acids by cultured neuroblastoma and astrocytoma cells was studied in the presence and absence ofl-histidine. Intracellularly accumulated histidine was assumed to induce accumulation of radioactively labeled amino acids from medium by means of exchange transport. Neuroblastoma cells accumulated more histidine than astrocytoma cells and were more sensitive to the enhancement of the uptake of other large neutral amino acids by histidine. Histidine also increased glutamic acid uptake in astrocytoma cells, but reduced it in neuroblastoma cells. The greatest differences between the cell lines in amino acid uptake without histidine were found with acidic amino acids (astrocytoma cells accumulated them more than neuroblastoma cells) and with taurine (the reverse was found). The uptake and exchange mechanisms for some neutral and acidic amino acids may thus be dissimilar in the plasma membranes of cultured cells of neuronal and glial origin.