Peculiarities of synaptic transmission between photoreceptors and horizontal cells

Abstract

A previously advanced hypothesis, according to which the transmitter which depolarizes the membrane of horizontal cells is continually liberated in the dark, and ceases to be liberated in the light, is tested experimentally. The data presented show that a current acting on presynatic receptor endings evokes a depolarizing response in horizontal cells to short current impulses passing through the retina (anode on receptor surface, cathode in vitreous body). These receptor endings are depolarized, which evidently leads to liberation of the transmitter from the receptors. Experiments with electrical stimulation of the retina have shown that treatment of the retina with potassium cyanide disrupts synaptic transmission between the receptor and horizontal cell. A potential equal to their membrane potential is established in horizontal cells in bright light; this potential is evidently the true rest potential of these cells. The relative stability of the membrane potential of horizontal cells in light with change in temperature is evidence in support of this assumption. In the dark, the membrane potential increases considerably with increase in temperature; this effect is possibly due to a rise in the rate of decomposition of the depolarizing transmitter. Evidence in support of this hypothesis is the rise in steepness of the falling phase of the response of the horizontal cells to electrical stimulation observed on elevation of the temperature.