K(+)-induced reversal of astrocyte glutamate uptake is limited by compensatory changes in intracellular Na+.

Glutamate uptake is coupled to counter-transport of K+, and high external K+ concentrations can induce reversal of glutamate uptake in whole-cell patch-clamp and isolated membrane preparations. However, high external K+ causes little or no reversal of glutamate uptake in intact astrocytes, suggesting a regulatory mechanism not evident in membrane preparations. One mechanism by which intact cells could limit the effects of altered extracellular ion concentrations on glutamate transport is by compensatory changes in intracellular Na+ concentrations. This possibility was examined using astrocyte cultures treated in two ways to reduce the driving force for glutamate uptake: incubation in high K+ (with reciprocal reduction in Na+), and incubation with metabolic inhibitors to induce ATP depletion. ATP depletion produced a rise in intracellular Na+, a collapse of the membrane sodium gradient and a massive reversal of glutamate uptake. By contrast, incubation in high K+/low Na+ medium did not significantly alter the sodium gradient and did not induce glutamate uptake reversal. The sodium gradient was shown to be maintained under these conditions by compensatory reductions in intracellular Na+ that approximately matched the reductions in extracellular Na+. These findings suggest a mechanism by which astrocytes may limit reversal of glutamate uptake under high K+/low Na+ conditions, and further suggest a general mechanism by which Na(+)-dependent transport processes could be shielded from fluctuating extracellular ion concentrations.

Net glutamate release from astrocytes is not induced by extracellular potassium concentrations attainable in brain.

Elevated extracellular potassium concentration ([K+]e) has been shown to induce reversal of glial Na+-dependent glutamate uptake in whole-cell patch clamp preparations. It is uncertain, however, whether elevated [K+]e similarly induces a net glutamate efflux from intact cells with a physiological intracellular milieu. To answer this question, astrocyte cultures prepared from rat and mouse cortices were incubated in medium with elevated [K+]e (by equimolar substitution of K+ for Na+), and glutamate accumulation was measured by HPLC. With [K+]e elevations to 60 mM, medium glutamate concentrations did not increase during incubation periods of 5-120 min. By contrast, 45 min of combined inhibition of glycolytic and oxidative ATP production increased medium glutamate concentrations 50-100-fold. Similar results were obtained in both rat and mouse cultures. Studies were also performed using astrocytes loaded with the nonmetabolized glutamate tracer D-aspartate, and parallel results were obtained; no increase in medium D-aspartate content resulted from [K+]e elevation up to 90 mM, whereas a large increase occurred during inhibition of energy metabolism. These results suggest that a net efflux of glutamate from intact astrocytes is not induced by any [K+]e attainable in brain.

Neuronal regulation of glutamate transporter subtype expression in astrocytes.

GLT-1, GLAST, and EAAC1 are high-affinity, Na(+)-dependent glutamate transporters identified in rat forebrain. The expression of these transporter subtypes was characterized in three preparations: undifferentiated rat cortical astrocyte cultures, astrocytes cocultured with cortical neurons, and astrocyte cultures differentiated with dibutyryl cyclic AMP (dBcAMP). The undifferentiated astrocyte monocultures expressed only the GLAST subtype. Astrocytes cocultured with neurons developed a stellate morphology and expressed both GLAST and GLT-1; neurons expressed only the EAAC1 transporter, and rare microglia in these cultures expressed GLT-1. Treatment of astrocyte cultures with dBcAMP induced expression of GLT-1 and increased expression of GLAST. These effects of dBcAMP on transporter expression were qualitatively similar to those resulting from coculture with neurons, but immunocytochemistry showed the pattern of transporter expression to be more complex in the coculture preparations. Compared with astrocytes expressing only GLAST, the dBcAMP-treated cultures expressing both GLAST and GLT-1 showed an increase in glutamate uptake Vmax, but no change in the glutamate K(m) and no increased sensitivity to inhibition by dihydrokainate. Pyrrolidine-2,4-dicarboxylic acid and threo-beta-hydroxyaspartic acid caused relatively less inhibition of transport in cultures expressing both GLAST and GLT-1, suggesting a weaker effect at GLT-1 than at GLAST. These studies show that astrocyte expression of glutamate transporter subtypes is influenced by neurons, and that dBcAMP can partially mimic this influence. Manipulation of transporter expression in astrocyte cultures may permit identification of factors regulating the expression and function of GLAST and GLT-1 in their native cell type.

MK-801 reduces uptake and stimulates efflux of excitatory amino acids via membrane depolarization.

MK-801 and related compounds reduce excitotoxic neuronal injury by blocking N-methyl-D-aspartate (NMDA) receptorgated ion channels. These agents also cause neuronal vacuolization and block glutamate-induced astrocyte swelling, effects that may be unrelated to actions at the NMDA receptor. In the present study, high concentrations of MK-801 (100-1,000 microM) caused uncompetitive inhibition of glutamate uptake in astrocyte and neuronal cultures and stimulated D-aspartate efflux from astrocytes. MK-801 (500 microM) reduced the maximal velocity for glutamate uptake in astrocytes from 31 to 17 nmol.mg protein-1.min-1, whereas competitive NMDA receptor antagonists did not affect glutamate uptake. MK-801 also inhibited uptake of gamma-aminobutyric acid (GABA). Because both GABA uptake and glutamate uptake are electrogenic, one mechanism by which MK-801 could inhibit uptake is by membrane depolarization. Whole cell patch-clamp recording confirmed that MK-801 in the range of 100-1,000 microM caused dose-dependent and reversible depolarization. These concentrations are far higher than necessary to block NMDA receptors, and the findings suggest that actions at sites other than NMDA receptors could contribute to the effects of high doses of MK-801 in some experimental and clinical settings.

Excitatory amino acid release from astrocytes during energy failure by reversal of sodium-dependent uptake.

Non-synaptic release may be the major route of excitatory amino acid (EAA) efflux during cerebral ischemia. Possible routes of non-synaptic release include non-specific anion channels, reversal of Na(+)-, Cl(-)-, or Ca(2+)-dependent uptake, and cell lysis. In the present study we employ a novel approach to show reversal of Na(+)-dependent uptake as a major route of EAA efflux from astrocyte cultures under conditions of energy failure. Primary rat astrocyte cultures were subjected to combined blockade of glycolytic and oxidative metabolism after incubation with [3H]-D-aspartate (D-ASP). Energy failure produced an efflux of D-ASP that was maximal by 90 minutes. The efflux over this period was reduced by more than 50% in cells that had been pre-loaded with PDC (L-transpyrrolidine-2,4-dicarboxylic acid) or TBHA (threo-beta-hydroxyaspartic acid), compounds that are competitive inhibitors of Na(+)-dependent glutamate uptake. The effect of pre-loading with the inhibitors was concentration dependent. No effect was seen if the inhibitors were added after induction of energy failure, suggesting that the attenuation of D-ASP efflux resulted from binding of the inhibitors to an intracellular site. These results provide strong evidence that EAA efflux from astrocytes under conditions of energy failure occurs largely through reversal of Na(+)-dependent uptake.

Glycolysis can prevent non-synaptic excitatory amino acid release during hypoxia.

Release of excitatory amino acids (EAAs) contributes to neuronal death during cerebral ischemia. EAA release occurs by both synaptic and non-synaptic mechanisms. However, studies in vivo yield conflicting estimates of their relative importance. This disparity may reflect differing degrees of substrate deprivation produced by various in vivo models. We used primary rat astrocyte cultures to establish the relationship between substrate deprivation, energy failure, and non-synaptic EAA release. Combined hypoxia and glycolytic blockade produced severe ATP depletion and EAA release (10-fold). In contrast, hypoxia alone caused only a moderate reduction in ATP and did not induce EAA release. These findings suggest that glycolytic metabolism may be an important factor affecting the magnitude of non-synaptic EAA release during ischemia.

Intracellular tetanic calcium signals are reduced in fatigue of whole skeletal muscle.

Force and intracellular calcium signals were monitored in whole bullfrog semitendinosus muscles during fatigue produced by intermittent tetanic stimulation. Intracellular calcium signals were monitored using the fluorescent calcium-sensitive indicator indo-1 from the ratio of fluorescence intensities (R) at 400 and 470 nm. Fatiguing stimulation caused 1) proportional decreases of tetanic force and R, suggesting a component of the decreased force during fatigue of whole muscle may be due to insufficient calcium to activate contraction; 2) a progressive slowing of the relaxation of both force and R, suggesting slowed force relaxation may be mediated by slowed calcium removal from the myoplasm; 3) an increase of resting level R, suggesting impaired calcium removal from, or increased leakage to the cytosol; 4) prolongation of the twitch contraction, which was paralleled by changes in R. These findings are consistent with previous single fiber studies and suggest that changes in whole muscle contractility with fatigue may be partially mediated by changes in calcium handling by the cell.