| Abstract: | 1. Evidence is presented that synaptic interactions within and between the statocyst and visual pathways of Hermissenda are eliminated after 0.5-4 min exposure to 20-40 mM Co2+. 2. Synaptic blockade was also produced by perfusion with low Ca2+ (5mM) plus 10-20 mM Co2+. 3. Depolarization of hair cells by impulses of type A photoreceptors remains after the same exposure to Co2+, or low Ca2+ plus Co2+. 4. The increased resistance previously observed during this depolarization of hair cells cannot be observed after exposure to Co2+. 5. The depolarization which remains after exposure to Co2+ did not change with different levels of membrane potential from -20 mV below to +10 mV above the resting level. 6. The time course of potassium accumulation, monitored by the amplitude of the type A impulse afterpotential, closely followed the time course of hair cell depolarization and also of changes in the amplitude of the hair cell afterpotential. 7. The depolarization of hair cells by type A impulses decreased with increased extracellular potassium, but was only slightly reduced by lowered extracellular potassium. 8. The amount of potassium accumulation following a type A impulse train could be estimated from the effects of changes in extracellular potassium in the perfusate on the type A impulse afterpotential. From this extimated increase of extracellular potassium it was possible to predict with some accuracy, the observed hair cell depolarization. 9. Although type A cells are not electrically coupled to ipsilateral hair cells, firing of these hair cells slightly depolarized the type A photoreceptor which excites them. 10. Strophanthidin (10-4 M) did not block the depolarization of hair cells by type A impulses. 11. The data are evidence for nonsynaptic excitation of hair cells by type A photoreceptor impulses. The data are also consistent with the interpretation that the excitation arises from potassium accumulation around the type A and hair cell axonal membranes. |
