Effects of Sodium, Potassium, and Calcium Ions on Slow and Spike Potentials in Single Photoreceptor Cells

doi:10.1085/jgp.53.5.541

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ARTICLE

Effects of Sodium, Potassium, and Calcium Ions on Slow and Spike Potentials in Single Photoreceptor Cells

Bernard Fulpius ¹ and Fritz Baumann ¹

¹ From the Institute of Physiology, University of Geneva, Geneva, Switzerland.

Dr. Fulpius' present address is The Rockefeller University, New York 10021

The influence of changes in the ionic composition of the bathingmedium on responses of the retinula cell of the honeybee droneto light was examined by means of intracellular microelectrodes.The resting potential of the cell was influenced mainly by theconcentration of K. The peak of the receptor potential (thetransient), which in a normal solution and with strong lightapproaches zero membrane potential, overshot this level in aK-rich solution. An increase in the concentration of K alsoraised the level of the steady-state phase of the receptor potential(the plateau). The amplitude of the receptor potential was decreasedand the spike potential rapidly abolished when Na was replacedby either sucrose, choline, or Tris. In a Ca-free solution theamplitude of the response and especially that of the plateau,was increased. An increase in Ca had the opposite effects. Allthese changes were reversible. An attempt was made to interpretthe receptor and spike potentials in terms of passive movementsof Na and K across the membrane of the retinula cell. The majordifficulty encountered was to find an explanation for the persistenceof an appreciable fraction of the transient and the plateauin preparations kept up to 12 hr in a solution in which allthe Na had been replaced by choline, Tris, or sucrose.

Submitted on November 12, 1968

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