SYNAPTIC INHIBITION IN AN ISOLATED NERVE CELL

doi:10.1085/jgp.39.1.155

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ARTICLE

SYNAPTIC INHIBITION IN AN ISOLATED NERVE CELL

Stephen W. Kuffler ¹ and Carlos Eyzaguirre ¹

¹ From the Wilmer Institute, Johns Hopkins Hospital and University, Baltimore

Following the preceding studies on the mechanisms of excitationin stretch receptor cells of crayfish, this investigation analyzesinhibitory activity in the synapses formed by two neurons. Thecell body of the receptor neuron is located in the peripheryand sends dendrites into a fine muscle strand. The dendritesreceive innervation through an accessory nerve fiber which hasnow been established to be inhibitory. There exists a directperipheral inhibitory control mechanism which can modulate theactivity of the stretch receptor. The receptor cell which canbe studied in isolation was stimulated by stretch deformationof its dendrites or by antidromic excitation and the effectof inhibitory impulses on its activity was analyzed. Recordingwas done mainly with intracellular leads inserted into the cellbody.

1. Stimulation of the relatively slowly conducting inhibitorynerve fiber either decreases the afferent discharge rate orstops impulses altogether in stretched receptor cells. The inhibitoryaction is confined to the dendrites and acts on the generatormechanism which is set up by stretch deformation. By restrictingdepolarization of the dendrites above a certain level, inhibitionprevents the generator potential from attaining the "firinglevel" of the cell.

2. The same inhibitory impulse may set upa postsynaptic polarization or a depolarization, depending onthe resting potential level of the cell. The membrane potentialat which the inhibitory synaptic potential reverses its polarity,the equilibrium level, may vary in different preparations. Theinhibitory potentials increase as the resting potential is displacedin any direction from the inhibitory equilibrium.

3. The inhibitorypotentials usually rise to a peak in about 2 msec. and decayin about 30 msec. After repetitive inhibitory stimulation adelayed secondary polarization phase has frequently been seen,prolonging the inhibitory action. Repetitive inhibitory excitationmay also be followed by a period of facilitation. Some examplesof "direct" excitation by the depolarizing action of inhibitoryimpulses are described.

4. The interaction between antidromicand inhibitory impulses was studied. The results support previousconclusions (a) that during stretch the dendrites provide apersisting "drive" for the more central portions of the receptorcell, and (b) that antidromic all-or-none impulses do not penetrateinto the distal portions of stretch-depolarized dendrites. The"after-potentials" of antidromic impulses are modified by inhibition.

5.Evidence is presented that inhibitory synaptic activity increasesthe conductance of the dendrites. This effect may occur in theabsence of inhibitory potential changes.

Submitted on June 14, 1955

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