The relationship between apamin binding and channel block in KCa2 potassium channels.

Small conductance calcium-activated potassium channels (KCa2.1,2.2,2.3) are widely distributed throughout the body and are involved in diverse physiological processes including the regulation of neuronal firing and smooth muscle contraction. They are also potential targets in the treatment of cardiac arrhythmia. The KCa2.2 and 2.3 members of the family are blocked by the peptide toxin apamin at low concentrations, however, the mechanism of block by apamin is unclear. In electrophysiological experiments apamin has been reported to block Kca2.2 and 2.3 with IC50 ~100 pM and ~1nM respectively. In contrast, in ligand binding experiments using [125I]-mono-iodoapamin it has been found that apamin does not discriminate between Kca2.2 and 2.3 and that it binds with significantly higher affinity ( ~5pM). This discrepancy has led to the suggestion that, rather than acting as a classical pore blocker, apamin exerts its action by an allosteric mechanism. It is notable that the ligand binding studies reported so far have been conducted with isolated cell membranes in non-physiological solution with low ionic strength. We have investigated this discrepancy between results from ligand binding and electrophysiological studies by comparing binding of [125I]-mono-iodoapamin and inhibition of KCa2 current in intact HEK 293 cells using identical physiological solutions. In these conditions we found that apamin bound to KCa2.1 and KCa 2.3 with KL 60 and 606 pM, close to values of IC50 from electrophysiological experiments. We also compared the ability of some known SK channel blockers, UCL 1848, UCL 1684, gallamine and dequalinium, to displace labelled apamin and inhibit KCa2 current. With these compounds we found a good correlation between K¬i and IC50. These findings suggest that the discrepancy between binding and block might arise from differences in the experimental protocols used. To examine this we examined apamin block of KCa2 current in low ionic strength solutions in which NaCl was iso-osmotically replaced by sucrose. In these conditions 100 pM apamin caused 92 ± 0.1 % block as against 51 ± 5 % block in physiological ionic strength. We conclude that binding data obtained from membrane preparations must be interpreted with care when making comparisons with data from functional experiments and that this has implications for current views on the mechanism of action of apamin as an SK channel blocke

Nanoscale-targeted patch-clamp recordings of functional presynaptic ion channels

Important modulatory roles have been attributed to presynaptic NMDA receptors (NMDARs) located on cerebellar interneuron terminals. Evidence supporting a presynaptic location includes an increase in the frequency of mini events following the application of NMDA and gold particle-labelled NMDA receptor antibody localisation. However, more recent work, using calcium indicators, casts doubt on the idea of presynaptic NMDARs because basket cell varicosities did not show the expected calcium rise following either the local iontophoresis of L-aspartate or the two-photon uncaging of glutamate. (In theory such calcium imaging is sensitive enough to detect the calcium rise from even a single activated receptor.) It has therefore been suggested that the effects of NMDA are mediated via the activation of somatodendritic channels, which subsequently cause a subthreshold depolarization of the axon. Here we report results from a vibrodissociated preparation of cerebellar Purkinje cells, in which the interneuron cell bodies are no longer connected but many of their terminal varicosities remain attached and functional. This preparation can retain both inhibitory and excitatory inputs. We find that the application of NMDA increases the frequency of both types of synaptic event. The characteristics of these events suggest they can originate from interneuron, parallel fiber and even climbing fiber terminals. Interestingly, retrograde signalling seems to activate only the inhibitory terminals. Finally, antibody staining of these cells shows NMDAR-like immunoreactivity co-localised with synaptic markers. Since the Purkinje cells show no evidence of postsynaptic NMDAR-mediated currents, we conclude that functional NMDA receptors are located on presynaptic terminals

A functional role for small-conductance calcium-activated potassium channels in sensory pathways including nociceptive processes

We investigated the role of small-conductance calcium-activated potassium (SK) and intermediate-conductance calcium-activated potassium channels in modulating sensory transmission from peripheral afferents into the rat spinal cord. Subunit-specific antibodies reveal high levels of SK3 immunoreactivity in laminas I, II, and III of the spinal cord. Among dorsal root ganglion neurons, both peripherin-positive (C-type) and peripherin-negative (A-type) cells show intense SK3 immunoreactivity. Furthermore, dorsal root-stimulated sensory responses recorded in vitro are inhibited when SK channel activity is increased with 1-ethyl-2-benzimidazolinone (1-EBIO). In vivo electrophysiological recordings show that neuronal responses to naturally evoked nociceptive and nonnociceptive stimuli increase after application of the selective SK channel blocker 8,14-diaza-1,7( 1,4)-diquinolinacyclotetradecaphanedium ditrifluoroacetate (UCL 1848), indicating that SK channels are normally active in moderating afferent input. Conversely, neuronal responses evoked by mechanical stimuli are inhibited when SK channel activity is increased with 1-EBIO. These effects are reversed by the subsequent application of UCL 1848. Our data demonstrate that SK channels have an important role in controlling sensory input into the spinal cord

A Nanosensor Toolbox for Rapid, Label-Free Measurement of Airway Surface Liquid and Epithelial Cell Function

Ciliated lung epithelial cells and the airway surface liquid (ASL) comprise one of the body's most important protective systems. This system is finely tuned, and perturbations to ASL rheology, ASL depth, ASL pH, the transepithelial potential, and the cilia beat frequency are all associated with disease pathology. Further, these apparently distinct properties interact with each other in a complex manner. For example, changes in ASL rheology can result from altered mucin secretion, changes in ASL pH, or changes in ASL depth. Thus, one of the great challenges in trying to understand airway pathology is that the properties of the ASL/epithelial cell system need to be assessed near-simultaneously and without perturbing the sample. Here, we show that nanosensor probes mounted on a scanning ion conductance microscope make this possible for the first time, without any need for labeling. We also demonstrate that ASL from senescence-retarded human bronchial epithelial cells retains its native properties. Our results demonstrate that by using a nanosensor approach, it is possible to pursue faster, more accurate, more coherent, and more informative studies of ASL and airway epithelia in health and disease