Low-affinity excitatory amino acid uptake in hippocampal astrocytes: a possible role of Na+/dicarboxylate cotransporters.

The excitatory amino acid transporters (EAATs) underlie the so-called "high affinity" uptake of glutamate, which is well characterized. In contrast, the "low-affinity" uptake of glutamate remains poorly defined, and it has been discussed whether it may represent a mere in vitro artifact. Here we have visualized "low-affinity" excitatory amino acid uptake sites by incubating rat hippocampal slices with the glutamate analogue D-aspartate in the presence of PMB-TBOA, which blocks the EAATs. After fixation of the slices, D-aspartate taken up into the tissue was localized with the use of light microscopic immunoperoxidase and electron microscopic immunogold methods, exploiting highly specific antibodies against D-aspartate. PMB-TBOA blocked uptake of both low and high exogenous D-aspartate concentrations (0.01-1.0 mM) into nerve terminals, as well as the uptake of 0.01 mM D-aspartate into astrocytes. Interestingly, there was a residual PMB-TBOA insensitive uptake of D-aspartate in astrocytes at higher exogenous D-aspartate concentrations (0.05-1.0 mM), strongly suggesting that astrocytes have "low-affinity" uptake sites for excitatory amino acid. The PMB-TBOA insensitive D-aspartate uptake in astrocytes was sodium dependent and inhibited by succinate and to certain extent by homocysteate, but not by cystine or DIDS. We suggest that excitatory amino acid is transported into astrocytes in a "low-affinity" fashion by sodium/dicarboxylate transporters.

Glutamine as a precursor for transmitter glutamate, aspartate and GABA in the cerebellum: a role for phosphate-activated glutaminase.

Phosphate-activated glutaminase is present at high levels in the cerebellar mossy fiber terminals. The role of this enzyme for the production of glutamate from glutamine in the parallel-fiber terminals is unclear. In order to address this, we used light miroscopic immunoperoxidase and electron microscopic immunogold methods to study the localization of glutamate in rat cerbellar slices incubated with physiological K+ (3 mmol/L) and depolarizing K+ (40 mmol/L) concentrations, and during depolarizing conditions with the addition of glutamine and the glutaminase inhibitor 6-diazo-5-oxo-l-norleucine. During K+-induced depolarization glutamate labeling was redistributed from parallel-fiber terminals to glial cells. The nerve terminal content of glutamate was sustained when the slices were supplied with glutamine, which also reduced the accumulation of glutamate in glia. In spite of glutamine supplementation, the depolarized slices treated with 6-diazo-5-oxo-l-norleucine showed depletion of glutamate from parallel-fiber terminals and accumulation in glial cells. We conclude that cerebellar parallel-fiber terminals contain a glutaminase activity enabling them to synthesize glutamate from glutamine. Our results confirm that this is also true for the mossy fiber terminals. In addition, we show that, like for glutamate, the levels of aspartate in parallel-fiber terminals and GABA in Golgi fiber terminals can be maintained during depolarization if glutamine is present. This process is dependent on the activity of a glutaminase, as it can be inhibited by 6-diazo-5-oxo-l-norleucine, suggesting that the glutaminase reaction is important for glutamine to act as a precursor also for aspartate and GABA. The low levels of the kidney type of glutaminase that previously has been shown to be present in the parallel and Golgi fiber terminals could be sufficient to produce the transmitter amino acids. Alternatively, the amino acids could be produced from the liver type of glutaminase, which is not yet localized on the cellular level, or from an unknown glutminase.