Prolonged presence of glutamate during excitatory synaptic transmission to cerebellar Purkinje cells
B Barbour, BU Keller, I Llano, A Marty - Neuron, 1994 - cell.com
B Barbour, BU Keller, I Llano, A Marty
Neuron, 1994•cell.comIn the molecular layer of the cerebellar cortex, Purkinje ceils and interneurons receive a
common excitatory input from parallel fibers. The AMPA/kainate receptormediated parallel
fiber excitatory postsynaptic current (EPSC) recorded in Purkinje cells decays much more
slowly than that recorded in interneurons. We show that this slowness of decay does not
result from dendritic filtering and that it is unlikely to reflect the deactivation kinetics of the
postsynaptic receptors. Agents blocking glutamate uptake prolong the EPSC in Purkinje …
common excitatory input from parallel fibers. The AMPA/kainate receptormediated parallel
fiber excitatory postsynaptic current (EPSC) recorded in Purkinje cells decays much more
slowly than that recorded in interneurons. We show that this slowness of decay does not
result from dendritic filtering and that it is unlikely to reflect the deactivation kinetics of the
postsynaptic receptors. Agents blocking glutamate uptake prolong the EPSC in Purkinje …
Summary
In the molecular layer of the cerebellar cortex, Purkinje ceils and interneurons receive a common excitatory input from parallel fibers. The AMPA/kainate receptormediated parallel fiber excitatory postsynaptic current (EPSC) recorded in Purkinje cells decays much more slowly than that recorded in interneurons. We show that this slowness of decay does not result from dendritic filtering and that it is unlikely to reflect the deactivation kinetics of the postsynaptic receptors. Agents blocking glutamate uptake prolong the EPSC in Purkinje cells. We conclude that the slow EPSC decay results from the continued presence of transmitter glutamate. This may be due to retarded transmitter diffusion around spines or to cross-talk between neighboring active synapses.
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