Sarah E. H. Bowden scite author profile

In hippocampal neurons, the firing of a train of action potentials is terminated by generation of the slow afterhyperpolarization (AHP). Recordings from hippocampal slices have shown that the slow AHP likely results from the activation of small-conductance calcium-activated potassium (SK) channels by calcium (Ca(2+)) entry through L-type Ca(2+) channels. However, the relative localization of these two channel subtypes is not known. The cloning and characterization of three subtypes of SK channel has suggested that SK1 may underlie generation of the slow AHP. Using a novel antibody directed against rat SK1 (rSK1), it has been determined that the rSK1 channel is primarily in the soma of hippocampal CA1 neurons. In conjunction with antibodies directed against C (Ca(v)1.2) and D (Ca(v)1.3) class L-type Ca(2+) channel alpha1 subunits, it was observed that rSK1 channels were selectively colocalized with D class L-type channels. This colocalization supports the functional coupling of L-type and SK channels previously observed in cell-attached patches from hippocampal neurons. However, it appears contrary to the slow rise and decay of the slow AHP. Induction of delayed facilitation of L-type Ca(2+) channels in cell-attached patches from hippocampal neurons evoked delayed opening of coupled SK channels. Generation of ensemble currents produced waveforms identical to the ionic current underlying the slow AHP (I(sAHP)). Therefore, these data indicate that the slow AHP is somatic in origin, resulting from delayed facilitation of D class L-type Ca(2+) channels colocalized with rSK1 channels.

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High-Threshold Mechanosensitive Ion Channels Blocked by a Novel Conopeptide Mediate Pressure-Evoked Pain

Drew

Rugiero

Cesare

et al. 2007

PLoS ONE

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Little is known about the molecular basis of somatosensory mechanotransduction in mammals. We screened a library of peptide toxins for effects on mechanically activated currents in cultured dorsal root ganglion neurons. One conopeptide analogue, termed NMB-1 for noxious mechanosensation blocker 1, selectively inhibits (IC50 1 µM) sustained mechanically activated currents in a subset of sensory neurons. Biotinylated NMB-1 retains activity and binds selectively to peripherin-positive nociceptive sensory neurons. The selectivity of NMB-1 was confirmed by the fact that it has no inhibitory effects on voltage-gated sodium and calcium channels, or ligand-gated channels such as acid-sensing ion channels or TRPA1 channels. Conversely, the tarantula toxin, GsMTx-4, which inhibits stretch-activated ion channels, had no effects on mechanically activated currents in sensory neurons. In behavioral assays, NMB-1 inhibits responses only to high intensity, painful mechanical stimulation and has no effects on low intensity mechanical stimulation or thermosensation. Unexpectedly, NMB-1 was found to also be an inhibitor of rapid FM1-43 loading (a measure of mechanotransduction) in cochlear hair cells. These data demonstrate that pharmacologically distinct channels respond to distinct types of mechanical stimuli and suggest that mechanically activated sustained currents underlie noxious mechanosensation. NMB-1 thus provides a novel diagnostic tool for the molecular definition of channels involved in hearing and pressure-evoked pain.

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False interaction of syntaxin 1A with a Ca2+-activated K+ channel revealed by co-immunoprecipitation and pull-down assays: implications for identification of protein–protein interactions

2003

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Modulation of Single Channels Underlying Hippocampal L-Type Current Enhancement by Agonists Depends on the Permeant Ion

Tavalin

Shepherd

Cloues

et al. 2004

Journal of Neurophysiology

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The influx of calcium (Ca(2+)) ions through L-type channels underlies many cellular processes, ranging from initiation of gene transcription to activation of Ca(2+)-activated potassium channels. L-type channels possess a diagnostic pharmacology, being enhanced by the dihydropyridine BAY K 8644 and benzoylpyrrole FPL 64176. It is assumed that the action of these compounds is independent of the ion conducted through the channel. In contrast to this assumption, modulation of L-type channel activity in acutely dissociated rat CA1 hippocampal neurons depended on the divalent ion identity. BAY K 8644 and FPL 64176 substantially increased single-channel open time only when barium (Ba(2+)) was the permeant ion. BAY K 8644 increased single-channel conductance when either Ba(2+) or Ca(2+) ions were the charge carrier, an effect not observed with FPL 64176. BAY K 8644 enhanced the whole cell L-type channel Ca(2+)- or Ba(2+)-carried current without a change in deactivation tail kinetics. In contrast, enhancement by FPL 64176 was associated with a dramatic slowing of deactivation kinetics only when Ba(2+) and not Ca(2+) was the charge carrier. Current activation was slowed by FPL 64176 with either charge carrier, an effect arising from a clustering of agonist-modified long-duration openings toward the end of the voltage step. These data indicate that agonists enhanced L-type current by distinct mechanisms dependent on the permeant ion, indicating that care must be considered when used as diagnostic tools.

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Sarah E. H. Bowden

Somatic Colocalization of Rat SK1 and D class (Ca_v 1.2) L-type Calcium Channels in Rat CA1 Hippocampal Pyramidal Neurons

High-Threshold Mechanosensitive Ion Channels Blocked by a Novel Conopeptide Mediate Pressure-Evoked Pain

False interaction of syntaxin 1A with a Ca2+-activated K+ channel revealed by co-immunoprecipitation and pull-down assays: implications for identification of protein–protein interactions

Modulation of Single Channels Underlying Hippocampal L-Type Current Enhancement by Agonists Depends on the Permeant Ion

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Sarah E. H. Bowden

Somatic Colocalization of Rat SK1 and D class (Cav 1.2) L-type Calcium Channels in Rat CA1 Hippocampal Pyramidal Neurons

High-Threshold Mechanosensitive Ion Channels Blocked by a Novel Conopeptide Mediate Pressure-Evoked Pain

False interaction of syntaxin 1A with a Ca2+-activated K+ channel revealed by co-immunoprecipitation and pull-down assays: implications for identification of protein–protein interactions

Modulation of Single Channels Underlying Hippocampal L-Type Current Enhancement by Agonists Depends on the Permeant Ion

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Product

Resources

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Somatic Colocalization of Rat SK1 and D class (Ca_v 1.2) L-type Calcium Channels in Rat CA1 Hippocampal Pyramidal Neurons