Slow non-cholinergic excitatory potentials in neurones of the guinea-pig coeliac ganglia.

Abstract

Intracellular recordings were made from neurons of the celiac ganglia of the guinea pig in vitro. In addition to the fast excitatory post-synaptic potentials (e.p.s.p.) repetitive stimulation (10-20 Hz, 1-2 s) of the left greater splanchnic nerves elicited a slow depolarization in .apprx. 70% of the neurons examined. This depolarization lasted for minutes and was resistant to nicotinic and muscarinic antagonists; it was abolished reversibly in a low-Ca2+, high-Mg2+ solution. The response is termed non-cholinergic e.p.s.p. In .apprx. 10% of the neurons, the non-cholinergic e.p.s.p. exhibited a biphasic pattern. The fast as well as the non-cholinergic e.p.s.p. could be effectively induced by stimulation of any of the several nerve trunks that enter the ganglion. Simultaneous stimulation of 2 separate nerves resulted in a much larger non-cholinergic e.p.s.p. than could be achieved by stimulation of a single nerve. When the membrane potential was manually clamped, the non-cholinergic e.p.s.p. was associated with an increase of membrane resistance in the large majority of cells tested. Membrane hyperpolarization generally caused an increase in the amplitude of the non-cholinergic e.p.s.p.; a decrease was observed in only a few cells. Subthreshold depolarizations induced by direct intracellular stimulation as well as fast e.p.s.p. elicited by heterosynaptic nerve stimulation were facilitated during the course of a non-cholinergic e.p.s.p., often resulting in spike discharges. A potentiation of lesser magnitude occurred when the membrane potential was manually clamped during the course of the slow response, indicating that the facilitation may be attributed to both membrane depolarization and increased membrane resistance. The non-cholinergic e.p.s.p. evidently constitutes an integral part of synaptic transmission in celiac ganglia. Its function may be to provide a mechanism for increasing the responsiveness of sympathetic neurons to incoming fast e.p.s.p.