Jeroo D. Sinor scite author profile

Some data suggest that the sodium-dependent, high-affinity L-glutamate (Glu) transport sites in forebrain are different from those in cerebellum. In the present study, sodium-dependent transport of L-[3H]Glu was characterized in cerebellum and cortex. In both cerebellar and cortical tissue, activity was enriched in synaptosomes. Approximately 100 excitatory amino acid analogues were tested as potential inhibitors of transport activity. Many of the compounds tested inhibited transport activity by < 65% at 1 mM and were not studied further. One group of compounds exhibited inhibition conforming to theoretical curves with Hill coefficients of 1 and were < 10-fold selective as inhibitors of transport activity. These included three of the putative endogenous substrates for transport: L-Glu, L-aspartate, and L-cysteate. Four of the compounds exhibited inhibition conforming to theoretical curves with Hill coefficients of 1 and were > 10-fold selective as inhibitors. These included beta-N-oxalyl-L-alpha,beta-diaminopropionate, alpha-methyl-DL-glutamate, (2S,1'S,2'S)-2-(carboxycyclopropyl)glycine, and (2S,1'S,2'S,3'S)-2-(2-carboxy-3-methoxymethylcyclopropyl)glycine. Data obtained with a few of the inhibitors were consistent with two sites in one or both of the brain regions. (2S,1'R,2'R)-2-(Carboxycyclopropyl)glycine (L-CCG-II) was identified as the most potent (IC50 = 5.5 microM) and selective (60-100-fold) inhibitor of transport activity in cerebellum. One of the potential endogenous substrates, L-homocysteate, was also a selective inhibitor of cerebellar transport activity. The data for inhibition of transport activity in cortex by both L-CCG-II and L-homocysteate were best fit to two sites. Kainate was equipotent as an inhibitor of transport activity, and in both brain regions the data for inhibition were best fit to two sites. The possibility that there are four subtypes of excitatory amino acid transport is discussed. Altering sodium and potassium levels affects cerebellar and cortical transport activity differently, suggesting that the differences extend to other recognition sites on these transporters.

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Pharmacology of Sodium‐Dependent High‐Affinity l‐[³H]Glutamate Transport in Glial Cultures

Garlin

Sinor

et al. 1995

Journal of Neurochemistry

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Pharmacological and molecular biological studies provide evidence for subtypes of sodium‐dependent high‐affinity glutamate (Glu) transport in the mammalian CNS. At least some of these transporters appear to be selectively expressed in different brain regions or by different cell types. In the present study, the properties of l‐[3H]Glu transport were characterized using astrocyte‐enriched cultures prepared from cerebellum and cortex. In both brain regions, the kinetic data for sodium‐dependent transport were consistent with a single site with Km values of 91 ± 17 µM in cortical glial cells and 66 ± 23 µM in cerebellar glial cells. The capacities were 6.1 ± 1.6 nmol/mg of protein/min in cortical glial cells and 8.4 ± 0.9 nmol/mg of protein/min in cerebellar glial cells. The potencies of ∼40 excitatory amino acid analogues for inhibition of sodium‐dependent transport into glial cells prepared from cortex and cerebellum were examined, including compounds that are selective inhibitors of transport in synaptosomes prepared from either cerebellum or cortex. Of the analogues tested, 14 inhibited transport activity by >50% at 1 mM concentrations. Unlike l‐[3H]Glu transport in synaptosomes prepared from cerebellum or cortex, there were no large differences between the potencies of compounds for inhibition of transport measured in glial cells prepared from these two brain regions. With the exception of (2S,1′R,2′R)‐2‐(carboxycyclopropyl)glycine and l‐α‐aminoadipate, all of the compounds examined were ∼10–200‐fold less potent as inhibitors of l‐[3H]Glu transport measured in glial cells than as inhibitors of transport measured in synaptosomes prepared from their respective brain regions. The pharmacology of transport measured in these glial cells differs from the reported pharmacology of the cloned Glu transporters, suggesting the existence of additional uncloned Glu transporters or Glu transporter subunits.

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Jeroo D. Sinor

Pharmacologically distinct sodium-dependentl-[3H]glutamate transport processes in rat brain

Subtypes of Sodium‐Dependent High‐Affinity L‐[³H]Glutamate Transport Activity: Pharmacologic Specificity and Regulation by Sodium and Potassium

Pharmacology of Sodium‐Dependent High‐Affinity l‐[³H]Glutamate Transport in Glial Cultures

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Jeroo D. Sinor

Pharmacologically distinct sodium-dependentl-[3H]glutamate transport processes in rat brain

Subtypes of Sodium‐Dependent High‐Affinity L‐[3H]Glutamate Transport Activity: Pharmacologic Specificity and Regulation by Sodium and Potassium

Pharmacology of Sodium‐Dependent High‐Affinity l‐[3H]Glutamate Transport in Glial Cultures

Contact Info

Product

Resources

About

Subtypes of Sodium‐Dependent High‐Affinity L‐[³H]Glutamate Transport Activity: Pharmacologic Specificity and Regulation by Sodium and Potassium

Pharmacology of Sodium‐Dependent High‐Affinity l‐[³H]Glutamate Transport in Glial Cultures