The effect of prolonged depolarization on synaptic transfer in the stellate ganglion of the squid
- 1 July 1971
- journal article
- Published by Wiley in The Journal of Physiology
- Vol. 216 (2) , 503-512
- https://doi.org/10.1113/jphysiol.1971.sp009537
Abstract
1. Depolarization of the giant axon terminal of the squid causes local calcium influx which gives rise to transmitter release and post‐synaptic response, and which under certain experimental conditions leads to a regenerative action potential in the presynaptic terminal itself.2. There has been conflicting evidence in the literature on the question whether the calcium permeability change in the terminal is rapidly inactivated, or whether it can persist with little diminution for hundreds of milliseconds during a depolarizing voltage step.3. Results are presented which show that there is little ‘calcium inactivation’, even when very large depolarizing steps are imposed on the terminal and maintained for periods of 1‐2 sec.4. Contrary indications are examined and found to be attributable to an increase of potassium conductance, rather than direct inactivation of calcium conductance.This publication has 7 references indexed in Scilit:
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- Tetrodotoxin‐resistant electric activity in presynaptic terminalsThe Journal of Physiology, 1969
- Influence of ionic environment on the relationship between pre- and postsynaptic potentialsJournal of Neurobiology, 1969
- Correlation of Transmitter Release with Membrane Properties of the Presynaptic Fiber of the Squid Giant SynapseThe Journal of general physiology, 1967
- A study of synaptic transmission in the absence of nerve impulsesThe Journal of Physiology, 1967
- Spontaneous synaptic potentials and quantal release of transmitter in the stellate ganglion of the squidThe Journal of Physiology, 1967
- Transmission across the squid giant synapse in the presence of tetrodotoxin.1967