4.5 Article

SHAPING OF ACTION POTENTIALS BY TYPE I AND TYPE II LARGE-CONDUCTANCE Ca2+-ACTIVATED K+ CHANNELS

Journal

NEUROSCIENCE
Volume 192, Issue -, Pages 205-218

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.neuroscience.2011.06.028

Keywords

modeling; neuron; dentate gyrus; granule cell; potassium channel; patch clamp

Categories

Funding

  1. NIH [NS052574]
  2. AHA [BGIA2390030]
  3. San Antonio Life Sciences Institute (SALSI)

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The BK channel is a Ca2+ and voltage-gated conductance responsible for shaping action potential waveforms in many types of neurons. Type II BK channels are differentiated from type I channels by their pharmacology and slow gating kinetics. The beta 4 accessory subunit confers type II properties on BK alpha subunits. Empirically derived properties of BK channels, with and without the (beta 4 accessory subunit, were obtained using a heterologous expression system under physiological ionic conditions. These data were then used to study how BK channels alone (type I) and with the accessory beta 4 subunit (type II) modulate action potential properties in biophysical neuron models. Overall, the models support the hypothesis that it is the slower kinetics provided by the beta 4 subunit that endows the BK channel with type II properties, which leads to broadening of action potentials and, secondarily, to greater recruitment of SK channels reducing neuronal excitability. Two regions of parameter space distinguished type II and type I effects; one where the range of BK-activating Ca2+ was high (>20 mu M) and the other where BK-activating Ca2+ was low (similar to 0.4-1.2 mu M). The latter required an elevated BK channel density, possibly beyond a likely physiological range. BK-mediated sharpening of the spike waveform associated with the lack of the beta 4 subunit was sensitive to the properties of voltage-gated Ca2+ channels due to electrogenic effects on spike duration. We also found that depending on Ca2+ dynamics, type II BK channels may have the ability to contribute to the medium AHP, a property not generally ascribed to BK channels, influencing the frequency-current relationship. Finally, we show how the broadening of action potentials conferred by type II BK channels can also indirectly increase the recruitment of SK-type channels decreasing the excitability of the neuron. (C) 2011 IBRO. Published by Elsevier Ltd. All rights reserved.

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