Guang Jian Wang scite author profile

To identify glutamate transporters expressed in forebrain neurons, we prepared a cDNA library from rat forebrain neuronal cultures, previously shown to transport glutamate with high affinity and capacity. Using this library, we cloned two forms, varying in the C terminus, of the glutamate transporter GLT1. This transporter was previously found to be localized exclusively in astrocytes in the normal mature brain. Specific antibodies against the C-terminal peptides were used to show that forebrain neurons in culture express both GLT1a and GLT1b proteins. The pharmacological properties of glutamate transport mediated by GLT1a and GLT1b expressed in COS-7 cells and in neuronal cultures were indistinguishable. Both GLT1a and GLT1b were upregulated in astrocyte cultures by exposure to dibutyryl cAMP. We next investigated the expression of GLT1b in vivo. Northern blot analysis of forebrain RNA revealed two transcripts of ϳ3 and 11 kb that became more plentiful with developmental age. Immunoblot analysis showed high levels of expression in the cortex, hippocampus, striatum, thalamus, and midbrain. Pre-embedding electron microscopic immunocytochemistry with silver-enhanced immunogold detection was used to localize GLT1b in vivo. In the rat somatosensory cortex, GLT1b was clearly expressed in neurons in presynaptic terminals and dendritic shafts, as well as in astrocytes. The presence of GLT1b in neurons may offer a partial explanation for the observed uptake of glutamate by presynaptic terminals, for the preservation of input specificity at excitatory synapses, and may play a role in the pathophysiology of excitotoxicity.

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High Affinity Glutamate Transport in Rat Cortical Neurons in Culture

Wang

Chung

Schnuer

et al. 1998

Mol Pharmacol

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We assayed glutamate transport activity in cultures of rat cortical neurons containing < 0.2% astrocytes. Using [3H]L-glutamate as the tracer, sodium-dependent high affinity glutamate transport was demonstrated [K(m) = 17.2 +/- 2.4 microM; Vmax = 3.3 +/- 0.32 nmol/mg of protein/min (n = 5)]. Dihydrokainate (1 mM) inhibited uptake of radioactivity by 88 +/- 3% and had a Ki value of 65 +/- 7 microM. L-alpha-Aminoadipate (1 mM) inhibited uptake by only 25 +/- 4%. L-trans-2,4-Pyrrolidine dicarboxylate, L-serine-O-sulfate, and kainate potently inhibited transport activity with Ki values of 5.1 +/- 0.3, 56 +/- 6, and 103 +/- 9 microM, respectively (n = 3). Voltage-clamp studies of GLT1-expressing oocytes showed that, as in cortical neurons, glutamate transport was not inhibited by L-alpha-aminoadipate. Dihydrokainate was a potent inhibitor (Ki = 8 +/- 1 microM), and L-serine-O-sulfate produced a GLT1-mediated current with a K(m) value of 312 +/- 33 microM. Immunoblot analysis showed that neuronal cultures express excitatory amino acid carrier 1 (EAAC1), shown previously to be relatively insensitive to dihydrokainate, plus a trace amount of GLT1, but no GLAST. These studies establish that a major component of the glutamate transport activity of cortical neurons is dihydrokainate sensitive and distinct from the previously recognized neuronal transporter excitatory amino acid carrier 1.

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Neuronal degeneration in rat forebrain resulting from d-amphetamine-induced convulsions is dependent on seizure severity and age

Bowyer¹,

Peterson²,

Rountree³

et al. 1998

Brain Research

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Dihydrokainate‐sensitive neuronal glutamate transport is required for protection of rat cortical neurons in culture against synaptically released glutamate

Wang

Chung

Schnuer

et al. 1998

Eur J of Neuroscience

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Glutamate transport in nearly pure rat cortical neurons in culture (less than 0.2% astrocytes) is potently inhibited by dihydrokainate, l-serine-O-sulphate, but not by l-alpha-amino-adipate. This system allows for a test of the hypothesis that glutamate transport is important for protecting neurons against the toxicity of endogenous synaptically released glutamate. In support of this hypothesis, a 20-24 h exposure to 1 mm dihydrokainate reduced cell survival to only 14.8 +/- 9.8% in neuronal cultures (P < 0.001; n = 3), although it had no effect on neuronal survival in astrocyte-rich cultures (P > 0.05; n = 3). Dihydrokainate also significantly caused accumulation of glutamate in the extracellular medium of cortical neuronal cultures (6.6 +/- 4.9 micrometer, compared to 1.2 +/- 0.3 micrometer in control, n = 14, P < 0.01). The neurotoxicity of dihydrokainate was blocked by 10 micrometer MK-801, 10 micrometer tetrodotoxin, and an enzyme system that degrades extracellular glutamate. The latter two also abolished the accumulation of glutamate in the extracellular medium. Dihydrokainate (1 mm) inhibited the 45calcium uptake stimulated by 30 micrometer N-methyl-d-aspartate (NMDA), but not by higher concentrations consistent with a weak antagonist action of dihydrokainate at the NMDA receptor. Whole cell recordings showed that 1 mm dihydrokainate produced approximately 25% inhibition of 30 micrometer NMDA-induced current in cortical neurons. Dihydrokainate (1 mm) alone generated a small current (17% of the current produced by 30 micrometer NMDA) that was blocked by 30 micrometer 5,7-dichlorokynurenate and only weakly by 10 micrometer cyano-7-nitroquinoxaline-2,3-dione (CNQX). These results suggest that the toxicity of dihydrokainate in neuronal cultures is due to its ability to block glutamate transport in these cultures, and that dihydrokainate-sensitive neuronal glutamate transport may be important in protecting neurons against the toxicity of synaptically released glutamate.

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Guang Jian Wang

Expression of a Variant Form of the Glutamate Transporter GLT1 in Neuronal Cultures and in Neurons and Astrocytes in the Rat Brain

High Affinity Glutamate Transport in Rat Cortical Neurons in Culture

Neuronal degeneration in rat forebrain resulting from d-amphetamine-induced convulsions is dependent on seizure severity and age

Dihydrokainate‐sensitive neuronal glutamate transport is required for protection of rat cortical neurons in culture against synaptically released glutamate

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