Two types of potassium currents seen in isolated Necturus enterocytes with the single‐electrode voltage‐clamp technique.

1. The ionic permeability of Necturus maculosus small intestine epithelial cells was investigated using intracellular microelectrodes to measure membrane potential in intact tissue or by the single‐electrode voltage‐clamp technique in isolated cells. 2. The basolateral membrane of enterocytes appears to be K+ selective as demonstrated by the dependence of membrane potential and fractional serosal resistance measured in the intact epithelium on serosal K+ concentration. 3. Isolated cells had membrane potentials similar to those measured in the intact tissue. Voltage‐clamp experiments in a physiological Ringer solution showed the presence of both large outward and inward currents. 4. Removal of Cl‐ from the bathing medium, linear subtraction or the use of a Cl‐ channel blocker revealed outwardly rectifying currents. The quasi‐linear component was also revealed following K+ channel inhibition; it reversed near ECl, suggesting that the charge carrier was Cl‐. 5. Outwardly rectifying currents could be kinetically resolved into two components. A fast component (tau for activation < 4 ms) accounted for 60‐80% of the total current at positive potentials. A slowly activating component appeared at voltages positive to 50 mV with tau for activation of > 25 ms. 6. The slow outward current showed strong voltage dependence of both activation and relaxation, which were faster at more depolarized potentials. 7. Both fast and slow outward currents seem to be carried by K+ as they were blocked by Ba2+ and tetraethylammonium (TEA). Tail current analysis of the slow component indicated a reversal potential very similar to EK. 8. Fast outward currents were half‐activated at about ‐40 mV whereas slow outward currents were only apparent at more positive potentials. It is proposed that the fast outward K+ current plays a role, together with Cl‐ currents, in determining the resting membrane potential of Necturus enterocytes.