Synaptic transmission in the hippocampus: Critical role for glial cells

The importance of glial cells in controlling the neuronal microenvironment has been increasingly recognized. We now demonstrate that glial cells play an integral role in hippocampal synaptic transmission by using the glial‐specific metabolic blocker fluoroacetate (FAC) to selectively inhibit glial cell function. FAC inhibits evoked intracellular postsynaptic potentials (PSPs; IC50 = 39 μM) as well as population PSPs (IC50 = 65 μM) in field CA1 of the guinea pig hippocampal slice. Spontaneous synaptic transmission is concurrently decreased. These effects are time and dose dependent. ATP concentrations in glial but not neuronal elements are also significantly reduced with FAC treatment. Simultaneous application of the metabolic substrate isocitrate with FAC prevents both the reduction in glial ATP concentrations and the decrease in evoked PSPs. Given that isocitrate is selectively taken up by glia, these data further support a glial specific metabolic action of FAC. Additionally, FAC has no postsynaptic effects as peak responses to iontophoretically applied glutamate are unchanged. However, the decay of both iontophoretic and evoked PSPs are prolonged following FAC treatment suggesting inhibition of glutamate uptake may contribute to the FAC‐induced depression of synaptic potentials. These results show, for the first time, that glial cells are critical for maintenance of synaptic transmission and suggest a role for glial cells in the modulation of synaptic efficacy. © 1994 Wiley‐Liss, Inc.

[1]  F. Fonnum Regulation of the synthesis of the transmitter glutamate pool. , 1993, Progress in biophysics and molecular biology.

[2]  G. Westbrook,et al.  The time course of glutamate in the synaptic cleft. , 1992, Science.

[3]  I. Kass,et al.  The barbiturate thiopental reduces ATP levels during anoxia but improves electrophysiological recovery and ionic homeostasis in the rat hippocampal slice , 1992, Neuroscience.

[4]  B. Gähwiler,et al.  Effects of the GABA uptake inhibitor tiagabine on inhibitory synaptic potentials in rat hippocampal slice cultures. , 1992, Journal of neurophysiology.

[5]  S. Finkbeiner Calcium waves in astrocytes-filling in the gaps , 1992, Neuron.

[6]  F. Fonnum,et al.  Selective inhibition of glial cell metabolism in vivo by fluorocitrate , 1992, Brain Research.

[7]  L. Noble,et al.  Morphologic changes in cultured astrocytes after exposure to glutamate. , 1992, Journal of neurotrauma.

[8]  D. L. Martin,et al.  Synthesis and release of neuroactive substances by glial cells , 1992, Glia.

[9]  B. Barres,et al.  New roles for glia , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[10]  M. Krug,et al.  The influence of long-term potentiation on the spatial relationship between astrocyte processes and potentiated synapses in the dentate gyrus neuropil of rat brain , 1991, Brain Research.

[11]  K. Tipton,et al.  The inhibition of glutamine synthetase in rat corpus striatum in vitro by methionine sulfoximine increases the neurotoxic effects of kainate and N-methyl-d-aspartate , 1991, Neuroscience Letters.

[12]  I. Silver,et al.  Relations between intracellular ions and energy metabolism: a study with monensin in synaptosomes, neurons, and C6 glioma cells , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[13]  B. Ballyk,et al.  Osmotic effects on the CA1 neuronal population in hippocampal slices with special reference to glucose. , 1991, Journal of neurophysiology.

[14]  J. LaManna,et al.  Regional Cerebral Metabolites, Blood Flow, Plasma Volume, and Mean Transit Time in Total Cerebral Ischemia in the Rat , 1991, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[15]  S. Finkbeiner,et al.  Ca2+ waves in astrocytes. , 1991, Cell calcium.

[16]  L. Toral-Barza,et al.  Cytosolic free calcium and ATP in synaptosomes after ischemia. , 1991, Life sciences.

[17]  I. Silver,et al.  Metabolism and role of glutamate in mammalian brain , 1990, Progress in Neurobiology.

[18]  M. Hatten,et al.  Riding the glial monorail: A common mechanism for glialguided neuronal migration in different regions of the developing mammalian brain , 1990, Trends in Neurosciences.

[19]  S. Finkbeiner,et al.  Glutamate induces calcium waves in cultured astrocytes: long-range glial signaling. , 1990, Science.

[20]  Stephen J. Smith,et al.  The excitatory neurotransmitter glutamate causes filopodia formation in cultured hippocampal astrocytes , 1990, Glia.

[21]  W. Walz Role of glial cells in the regulation of the brain ion microenvironment , 1989, Progress in Neurobiology.

[22]  F. Fonnum,et al.  Role of Glial Cells for the Basal and Ca2+‐Dependent K+‐Evoked Release of Transmitter Amino Acids Investigated by Microdialysis , 1989, Journal of neurochemistry.

[23]  J. LaManna,et al.  Manipulating the intracellular environment of hippocampal slices: pH and high-energy phosphates , 1989, Journal of Neuroscience Methods.

[24]  T. Pellmar Peroxide alters neuronal excitability in the CA1 region of guinea-pig hippocampus in vitro , 1987, Neuroscience.

[25]  S. Murphy,et al.  Functional receptors for neurotransmitters on astroglial cells , 1987, Neuroscience.

[26]  F. Fonnum,et al.  An In Vivo Model for Studying Function of Brain Tissue Temporarily Devoid of Glial Cell Metabolism: The Use of Fluorocitrate , 1987, Journal of neurochemistry.

[27]  J. Szerb,et al.  Increase in the stimulation-induced overflow of glutamate by fluoroacetate, a selective inhibitor of the glial tricarboxylic cycle , 1987, Brain Research.

[28]  D. Muir,et al.  Acetate and fluoroacetate as possible markers for glial metabolism in vivo , 1986, Brain Research.

[29]  J. Hallenbeck,et al.  Effects of pressure on uptake and release of calcium by brain synaptosomes. , 1986, Journal of applied physiology.

[30]  I. Silver,et al.  The role of glial cells in regulation of neurotransmitter amino acids in the external environment. II. Mechanism of aspartate transport , 1986, Brain Research.

[31]  R. Murison,et al.  Effect of central noradrenaline depletion on corticosterone levels and gastric ulcerations in rats , 1986, Brain Research.

[32]  R. Dingledine,et al.  Inhibition of GABA uptake in the rat hippocampal slice , 1986, Brain Research.

[33]  F. Fonnum Determination of Transmitter Amino Acid Turnover , 1985 .

[34]  J. Szerb,et al.  Glutamine enhances glutamate release in preference to gamma-aminobutyrate release in hippocampal slices. , 1984, Canadian journal of physiology and pharmacology.

[35]  G. Moonen,et al.  Plasminogen activator–plasmin system and neuronal migration , 1982, Nature.

[36]  J. Hardy,et al.  A rapid method for preparing synaptosomes: Comparison, with alternative procedures , 1981, Brain Research.

[37]  N. Seeds,et al.  Plasminogen activator release at the neuronal growth cone. , 1981, Science.

[38]  A. Schousboe,et al.  UPTAKE AND METABOLISM OF GLUTAMATE IN ASTROCYTES CULTURED FROM DISSOCIATED MOUSE BRAIN HEMISPHERES , 1977, Journal of neurochemistry.

[39]  W. Nicklas,et al.  Tricarboxylic acid-cycle metabolism in brain. Effect of fluoroacetate and fluorocitrate on the labelling of glutamate aspartate, glutamine and γ-amino butyrate , 1970 .

[40]  R. O'Neal,et al.  PRECURSORS IN VIVO OF GLUTAMATE, ASPARTATE AND THEIR DERIVATIVES OF RAT BRAIN , 1966, Journal of neurochemistry.