Small conductance Ca2+-activated K+ channels and calmodulin

Small conductance Ca²⁺-activated K⁺ channels (SK channels) contribute to the long lasting afterhyperpolarization (AHP) that follows an action potential in many central neurones. The biophysical and pharmacological attributes of cloned SK channels strongly suggest that one or more of them underlie the medium component of the AHP that regulates interspike interval and plays an important role in setting tonic firing frequency. The cloned SK channels comprise a distinct subfamily of K⁺ channels. Heterologously expressed SK channels recapitulate the biophysical and pharmacological hallmarks of native SK channels, being gated solely by intracellular Ca²⁺ ions with no voltage dependence to their gating, small unitary conductance values and sensitivity to the bee venom peptide toxin, apamin. Molecular, biochemical and electrophysiological studies have revealed that Ca²⁺ gating in SK channels is due to heteromeric assembly of the SK α pore-forming subunits with calmodulin (CaM). Ca²⁺ binding to the N-terminal E–F hands of CaM is responsible for SK channel gating. Crystallographic studies suggest that SK channels gate as a dimer-of-dimers, and that the physical gate of SK channels resides at or near the selectivity filter of the channels. In addition, Ca²⁺-independent interactions between the SK channel α subunits and CaM are necessary for proper membrane trafficking.     

A novel O2-sensing mechanism in rat glossopharyngeal neurones mediated by a halothane-inhibitable background K+ conductance

Modulation of K⁺ channels by hypoxia is a common O₂-sensing mechanism in specialised cells. More recently, acid-sensitive TASK-like background K⁺ channels, which play a key role in setting the resting membrane potential, have been implicated in O₂-sensing in certain cell types. Here, we report a novel O₂ sensitivity mediated by a weakly pH-sensitive background K⁺ conductance in nitric oxide synthase (NOS)-positive neurones of the glossopharyngeal nerve (GPN). This conductance was insensitive to 30 m m TEA, 5 m m 4-aminopyridine (4-AP) and 200 μ m Cd²⁺, but was reversibly inhibited by hypoxia (O₂ tension ( P _O2) = 15 mmHg), 2–5 m m halothane, 10 m m barium and 1 m m quinidine. Notably, the presence of halothane occluded the inhibitory effect of hypoxia. Under current clamp, these agents depolarised GPN neurones. In contrast, arachidonic acid (5–10 μ m ) caused membrane hyperpolarisation and potentiation of the background K⁺ current. This pharmacological profile suggests the O₂-sensitive conductance in GPN neurones is mediated by a class of background K⁺ channels different from the TASK family; it appears more closely related to the THIK (tandem pore domain halothane-inhibited K⁺) subfamily, or may represent a new member of the background K⁺ family. Since GPN neurones are thought to provide NO-mediated efferent inhibition of the carotid body (CB), these channels may contribute to the regulation of breathing during hypoxia via negative feedback control of CB function, as well as to the inhibitory effect of volatile anaesthetics (e.g. halothane) on respiration.     

Glucagon activates Ca2+ and Cl− channels in rat hepatocytes

Glucagon is one of the major hormonal regulators of glucose metabolism, counteracting the hepatic effects of insulin when the concentration of glucose in the bloodstream falls below a certain level. Glucagon also regulates bile flow, hepatocellular volume and membrane potential of hepatocytes. It is clear that changes in cell volume and membrane potential cannot occur without significant ion fluxes across the plasma membrane. The effects of glucagon on membrane currents in hepatocytes, however, are not well understood. Here we show, by patch-clamping of rat hepatocytes, that glucagon activates two types of currents: a small inwardly rectifying Ca²⁺ current with characteristics similar to those of the store-operated Ca²⁺ current and a larger outwardly rectifying Cl⁻ current similar to that activated by cell swelling. We show that the mechanism of glucagon action on membrane conductance involves phospholipase C and adenylyl cyclase. Contribution of the adenylyl cyclase-dependent pathway to activation of the currents depended on Epac (exchange protein directly activated by cAMP), but not on protein kinase A. The activation of Ca²⁺ and Cl⁻ channels is likely to play a key role in the mechanisms by which glucagon regulates hepatocyte metabolism and volume.