There is controversy over the extent to which glutamate released at one synapse can escape from the synaptic cleft and affect receptors at other synapses nearby, thereby compromising the synapse-specificity of information transmission. Here we show that the glial glutamate transporters GLAST and GLT-1 limit the activation of Purkinje cell AMPA receptors produced by glutamate diffusion between parallel fibre synapses in the cerebellar cortex of juvenile mice. For a single stimulus to the cerebellar molecular layer of wild-type mice, increasing the number of activated parallel fibres prolonged the parallel fibre EPSC, demonstrating an interaction between different synapses. Knocking out GLAST, or blocking GLT-1 in the absence of GLAST, prolonged the EPSC when many parallel fibres were stimulated but not when few were stimulated. When spatially separated parallel fibres were activated by granular layer stimulation, the EPSC prolongation produced by stimulating more fibres or reducing glutamate transport was greatly reduced. Thus, GLAST and GLT-1 curtail the EPSC produced by a single stimulus only when many nearby fibres are simultaneously activated. However when trains of stimuli were applied, even to a small number of parallel fibres, knocking out GLAST or blocking GLT-1 in the absence of GLAST greatly prolonged and enhanced the AMPA receptor-mediated current. These results show that glial cell glutamate transporters allow neighbouring synapses to operate more independently, and control the postsynaptic response to high frequency bursts of action potentials.
Transporters are thought to assist in the termination of synaptic transmission at some synapses by removing neurotransmitter from the synapse. To investigate the role of glutamate transport in shaping the time course of excitatory transmission at the mossy fiber-granule cell synapse, the effects of transport impairment were studied using whole-cell voltage-and currentclamp recordings in slices of rat cerebellum. Impairment of transport by L-trans-pyrrolidine-2,4-dicarboxylate (PDC) produced a prolongation of the decay of the AMPA receptormediated current after a repetitive stimulus, as well as prolongation of single stimulus-evoked EPSCs when AMPA receptor desensitization was blocked. PDC also produced a prolongation of both single and repetitive-evoked NMDA receptormediated EPSCs. Enzymatic degradation of extracellular glutamate did not reverse the PDC-induced prolongation of AMPA receptor-mediated current after a repetitive stimulus, suggesting that transporter binding sites participate in limiting glutamate spillover. In current-clamp recordings, PDC dramatically increased the total area of the EPSP and the burst duration evoked by single and repetitive stimuli. These data indicate that glutamate transporters play a significant role in sculpting the time course of synaptic transmission at granule cell synapses, most likely by limiting the extent of glutamate spillover. The contribution of transporters is particularly striking during repetitive stimulus trains at physiologically relevant frequencies. Hence, the structural arrangement of the glomerulus may enhance the contribution of transporters to information processing by limiting the extent of glutamate spillover between adjacent synapses.
G q protein-coupled receptors (G q PCRs) are widely distributed in the CNS and play fundamental roles in a variety of neuronal processes. Their activation results in PIP 2 hydrolysis and Ca 2+ release from intracellular stores via the PLC-IP 3 signaling pathway. Since early G q PCR signaling events occur at the plasma membrane of neurons, they might be influenced by changes in membrane potential. In this study we use combined patch-clamp and imaging methods to investigate whether membrane potential changes can modulate G q PCR signaling in neurons. Our results demonstrate that G q PCR signaling in the human neuronal cell line SH-SY5Y and in rat cerebellar granule neurons is directly sensitive to changes in membrane potential, even in the absence of extracellular Ca 2+ . Depolarization has a bi-directional effect on G q PCR signaling, potentiating thapsigargin-sensitive Ca 2+ responses to muscarinic receptor activation but attenuating those mediated by bradykinin receptors. The depolarization-evoked potentiation of the muscarinic signaling is graded, bipolar, non-inactivating and with no apparent upper limit, ruling out traditional voltage-gated ion channels as the primary voltage sensors. Flash photolysis of caged IP 3 /GPIP 2 places the voltage-sensor before the level of the Ca 2+ store and measurements using the fluorescent bioprobe eGFP-PH PLCδ directly demonstrate that voltage affects muscarinic signaling at the level of the IP 3 production pathway. The sensitivity of G q PCR IP 3 signaling in neurons to voltage itself may represent a fundamental mechanism by which ionotropic signals can shape metabotropic receptor activity in neurons and influence processes such as synaptic plasticity in which the detection of coincident signals is crucial.
Glutamate released from synapses during excitatory neurotransmission must be rapidly recycled to maintain neuronal communication. This review evaluates data from physiological experiments at hippocampal CA3 to CA1 synapses and the calyx of Held synapse in the brainstem to analyze quantitatively the rates of release and resupply of glutamate required to sustain neurotransmission. We calculate that, without efficient recycling, the presynaptic glutamate supply will be exhausted within about a minute of normal synaptic activity. We also discuss replenishment of the presynaptic pool by diffusion from the soma, direct uptake of glutamate back into the presynaptic terminal, and uptake of glutamate precursor molecules. Diffusion of glutamate from the soma is calculated to be fast enough to resupply presynaptic glutamate in the hippocampus but not at the calyx of Held. However, because the somatic cytoplasm will also quickly run out of glutamate and synapses can function continually even if the presynaptic axon is severed, mechanisms other than diffusion must be present to resupply glutamate for release. Direct presynaptic uptake of glutamate is not present at the calyx of Held but may play a role in glutamate recycling in the hippocampus. Alternatively, glutamine or tricarboxylic acid cycle intermediates released from glia can serve as a precursor for glutamate in synaptic terminals, and we calculate that the magnitude of presynaptic glutamine uptake is sufficient to supply enough glutamate to sustain neurotransmission. The nature of these mechanisms, their relative abundance, and the co-ordination between them remain areas of intensive investigation.
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