Modulation of Activity of One Neuron by Subthreshold Slow Potentials in Another in Lobster Cardiac Ganglion

doi:10.1085/jgp.43.6.1031

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Modulation of Activity of One Neuron by Subthreshold Slow Potentials in Another in Lobster Cardiac Ganglion

Akira Watanabe ¹ and Theodore H. Bullock ¹

¹ From the Department of Zoology, University of California, Los Angeles

A direct demonstration is given of interaction between specificneurons without impulses, via graded slow potentials electrotonicallyspread from one cell to another. Repetitive polarizing or depolarizingcurrent pulses of 50 to 200 msec. and subthreshold intensitywere passed through an intracellular electrode in the soma ofa follower cell of the isolated ganglion. When the frequencyis near the natural rhythm of impulse bursts corresponding toheart beats and arising in a pacemaker cell 5 to 10 mm. posteriorly,the bursts rapidly become synchronized with the pulses. Theeffect disappears upon withdrawing the intracellular electrode.Brief pulses or full spikes in the follower are not effective.Hyperpolarizing long pulses attract the burst to a fixed periodafter the end of the pulse, depolarizations after the beginningof the pulse. The natural rhythm promptly reappears when thepulses are stopped and occasionally breaks through during weakrepetitive pulses. Current pulses in postsynaptic cells alsoalter the threshold of a presynaptic neuron to externally appliedstimuli. Some kind of direct, low resistance pathway for electrotonicspread, discriminating against spikes because of their brevity,is inferred, providing a basis for subthreshold interactionwhich is specific and not by way of a field effect. Due to thesensitivity of modulation of ongoing rhythms, electrotonic currentscan be effective even after decrementing over several millimeters.

Submitted on November 4, 1959

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