Characterization of a Ca 2+ ‐activated K + current in insulin‐secreting murine βTC‐3 cells

1 The whole‐cell perforated‐patch recording mode was used to record a Ca 2+ ‐dependent K + current ( I K(Ca) ) in mouse βTC‐3 insulin‐secreting cells. 2 Depolarizing voltage steps (to potentials where Ca 2+ currents are activated) evoked a slowly activating, outward current, which exhibited a slow deactivation (in seconds) upon subsequent hyperpolarization. 3 This current was shown to increase with progressively longer depolarizing voltage steps. It could be reversibly abolished by the removal of Ca 2+ from the external medium or by application of Ca 2+ channel blockers, such as Cd 2+ and nifedipine. It was concluded that the depolarization‐evoked current was activated by Ca 2+ . 4 Variations in external K + concentration led to shifts in the reversal potential of the Ca 2+ ‐dependent current as predicted by the Nernst equation for a K + ‐selective current. 5 The Ca 2+ ‐activated K + current was insensitive to external TEA (10 mM), a concentration sufficient to block the large‐conductance Ca 2+ ‐dependent (maxi‐K Ca ) channel in β‐cells. It was also insensitive to apamin, tubocurarine and scyllatoxin (leiurotoxin I), specific blockers of small‐conductance K Ca channels. 6 The current was blocked by quinine, a non‐specific K Ca channel blocker and, surprisingly, by charybdotoxin (ChTX; 100 nM) but not iberiotoxin, a charybdotoxin analogue, which blocks the maxi‐K Ca channel. It was sensitive to block by clotrimazole and could be potently and reversibly potentiated by micromolar concentrations of niflumic acid. Thus, the current exhibited unique pharmacological characteristics, not conforming to the known K Ca channel classes. 7 The ChTX‐sensitive K Ca channel was permeable to Tl + , K + , Rb + and NH 4 + but not Cs + ions. 8 The ChTX‐sensitive I K(Ca) could be activated by the muscarinic agonists in the presence or absence of external Ca 2+ , presumably by releasing Ca 2+ from internal stores. 9 Acutely isolated porcine islet cells also exhibited a slow I K(Ca) resembling that described in βTC‐3 cells in kinetic properties, insensitivity to TEA (5 mM) and sensitivity to quinidine, an analogue of quinine. The porcine I K(Ca) , however, was not sensitive to block by 100‐200 nM ChTX. It is likely, that species differences account for pharmacological differences between the mouse and porcine slow I K(Ca) .