The slow calcium-dependent potassium current in a myenteric neurone of the guinea-pig ileum

Abstract

Experiments were performed in current-clamped and voltage-clamped after-hyperpolarizing (AH) neurones of the guinea-pig myenteric plexus to examine the properties of the potassium conductance (gK, Ca) underlying the slow calcium-activated after-hyperpolarization (VK, Ca). The action potential plateau lengthened by the addition of tetraethylammonium chloride (TEA) to the bathing medium was compared to VK, Ca. Results were consistent with enhanced calcium entry causing an increase of VK, Ca. 4-Aminopyridine (4-AP) directly reduced VK, Ca. Voltage-clamp data of gK, Ca were well fitted by a process with a delay (approximately equal to 60 ms) followed by exponential activation (time constant approximately equal to 300 ms) and inactivation (time constant approximately equal to 2 s). The presence of a small, much slower inactivating process was noted. Values for time constants were similar to those reported by Morita, North & Tokimasa (1982) and North & Tokimasa (1983) where gK, Ca was measured during VK, Ca subsequent to action potential stimulation. The relation between gK, Ca (or the calcium-activated potassium current IK, Ca) and estimated calcium influx resulting from short-duration calcium currents elicited at various voltages was compared. Both the integral of the calcium current and gK, Ca showed a similar dependence on the depolarizations used to elicit IK, Ca except there was a positive shift of about 4 mV for the gK, Ca curve. This shift was attributed to a requirement for calcium ions to prime the gK, Ca mechanism. An inward ion charge movement of about 8 pC was required before significant activation of gK, Ca occurred. After the 'priming' condition had been established, the sensitivity of gK, Ca to inward calcium current measured at the resting potential was about 500 pS/pC of inward charge. Large calcium entry obtained by prolonged calcium currents caused saturation of the peak amplitude of IK, Ca and initiated currents with slower time to peak amplitude and longer duration. Increasing the calcium concentration of the external solution provided proportionally larger IK, Ca currents before saturation. The saturation amplitude of IK, Ca (namely gK, Ca) was relatively unaffected.