Common Principles of Voltage-Dependent Gating for Hv and Kv Channels

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Common Principles of Voltage-Dependent Gating for Hv and Kv Channels Jeet Kalia, Kenton J. Swartz Neuron Volume 77, Issue 2, Pages 214-216 (January 2013) DOI: 10.1016/j.neuron.2013.01.001 Copyright © 2013 Elsevier Inc. Terms and Conditions

Figure 1 Architecture of Voltage-Activated Cation Channels (A) Architecture of classical voltage-activated channels. Kv channels are tetramers, with each subunit containing six segments spanning the membrane (gray slab). S1–S4 from each subunit form a voltage-sensing domain in the tetrameric channel (only one is depicted). S5–S6 from four subunits form the central pore domain. The S4 Arg residues (blue) drive motions of that helix in response to voltage changes. A well-conserved Phe in S2 (green) is the likely charge-transfer center. Acidic residues stabilizing Arg residues within the membrane are not shown. Both Nav and Cav channels contain four repeating S1-S6 segments within a subunit (pseudotetramers). (B) Architecture of dimeric Hv channels. Each subunit contains four transmembrane segments corresponding to the S1–S4 in Kv channels. Hv1 channels do not contain separate pore domains, and the permeation pathway for protons is contained within S1–S4. Dimerization interfaces exist between S1 helices and in the C-terminal coiled-coil. The S1 helix acidic residue studied by Qiu et al. (2013) is shown in red. (C) Chemical structures of an Arg side chain and the Hv1 inhibitor 2GBI described by Hong et al. (2013), with guanidine groups (blue). Neuron 2013 77, 214-216DOI: (10.1016/j.neuron.2013.01.001) Copyright © 2013 Elsevier Inc. Terms and Conditions