Abstract
Many neurons, including pyramidal cells of the cortex, express a slow afterhyperpolarization (sAHP) that regulates their firing. Although initial findings suggested that the current underlying the sAHP could be carried through SK(Ca) channels, recent work has uncovered anomalies that are not congruent with this idea. Here, we used overexpression and dominant-negative strategies to assess the involvement of SK(Ca) channels in mediating the current underlying the sAHP in pyramidal cells of the cerebral cortex. Pyramidal cells of layer V exhibit robust AHP currents composed of two kinetically and pharmacologically distinguishable currents known as the medium AHP current (I(mAHP)) and the slow AHP current (I(sAHP)). I(mAHP) is blocked by the SK(Ca) channel blockers apamin and bicuculline, whereas I(sAHP) is resistant to these agents but is inhibited by activation of muscarinic receptors. To test for a role for SK(Ca) channels, we overexpressed K(Ca)2.1 (SK1) and K(Ca)2.2 (SK2), the predominant SK(Ca) subunits expressed in the cortex, in pyramidal cells of cultured brain slices. Overexpression of K(Ca)2.1 and K(Ca)2.2 resulted in a fourfold to fivefold increase in the amplitude of I(mAHP) but had no detectable effect on I(sAHP). As an additional test, we examined I(sAHP) in a transgenic mouse expressing a truncated SK(Ca) subunit (SK3-1B) capable of acting as a dominant negative for the entire family of SK(Ca)-IK(Ca) channels. Expression of SK3-1B profoundly inhibited I(mAHP) but again had no discernable effect on I(sAHP). These results are inconsistent with the proposal that SK(Ca) channels mediate I(sAHP) in pyramidal cells and indicate that a different potassium channel mediates this current.