Ion channels

Influence of the N terminus on the biophysical properties and pharmacology of TREK1 potassium channels.

Molecular pharmacology 85:5 (2014) 671-681

Authors:

Emma L Veale, Ehab Al-Moubarak, Naina Bajaria, Kiyoyuki Omoto, Lishuang Cao, Stephen J Tucker, Edward B Stevens, Alistair Mathie

Abstract:

TWIK-related K(+) 1 (TREK1) potassium channels are members of the two-pore domain potassium channel family and contribute to background potassium conductances in many cell types, where their activity can be regulated by a variety of physiologic and pharmacologic mediators. Fenamates such as FFA (flufenamic acid; 2-{[3-(trifluoromethyl)phenyl]amino}benzoic acid), MFA [mefenamic acid; 2-(2,3-dimethylphenyl)aminobenzoic acid], NFA [niflumic acid; 2-{[3-(trifluoromethyl)phenyl]amino}nicotinic acid], and diclofenac [2-(2-(2,6-dichlorophenylamino)phenyl)acetic acid] and the related experimental drug BL-1249 [(5,6,7,8-tetrahydro-naphthalen-1-yl)-[2-(1H-tetrazol-5-yl)-phenyl]-amine] enhance the activity of TREK1 currents, and we show that BL-1249 is the most potent of these compounds. Alternative translation initiation produces a shorter, N terminus truncated form of TREK1 with a much reduced open probability and a proposed increased permeability to sodium compared with the longer form. We show that both forms of TREK1 can be activated by fenamates and that a number of mutations that affect TREK1 channel gating occlude the action of fenamates but only in the longer form of TREK1. Furthermore, fenamates produce a marked enhancement of current through the shorter, truncated form of TREK1 and reveal a K(+)-selective channel, like the long form. These results provide insight into the mechanism of TREK1 channel activation by fenamates, and, given the role of TREK1 channels in pain, they suggest a novel analgesic mechanism for these compounds.

Structural and Thermodynamic Characterization of the Gating Pathway in a K+ Channel

BIOPHYSICAL JOURNAL 106:2 (2014) 155A-155A

Authors:

Murali K Bollepalli, Philip W Fowler, Markus Rapedius, Lijun Shang, Mark SP Sansom, Stephen J Tucker, Thomas Baukrowitz

Control of KirBac3.1 potassium channel gating at the interface between cytoplasmic domains.

J Biol Chem 289:1 (2014) 143-151

Authors:

Lejla Zubcevic, Vassiliy N Bavro, Joao RC Muniz, Matthias R Schmidt, Shizhen Wang, Rita De Zorzi, Catherine Venien-Bryan, Mark SP Sansom, Colin G Nichols, Stephen J Tucker

Abstract:

KirBac channels are prokaryotic homologs of mammalian inwardly rectifying potassium (Kir) channels, and recent structures of KirBac3.1 have provided important insights into the structural basis of gating in Kir channels. In this study, we demonstrate that KirBac3.1 channel activity is strongly pH-dependent, and we used x-ray crystallography to determine the structural changes that arise from an activatory mutation (S205L) located in the cytoplasmic domain (CTD). This mutation stabilizes a novel energetically favorable open conformation in which changes at the intersubunit interface in the CTD also alter the electrostatic potential of the inner cytoplasmic cavity. These results provide a structural explanation for the activatory effect of this mutation and provide a greater insight into the role of the CTD in Kir channel gating.

A Novel Mechanism of Voltage Sensing and Gating in K2P Potassium Channels

Biophysical Journal Elsevier 106:2 (2014) 746a

Authors:

Marcus Schewe, Markus Rapedius, Ehsan Nematian-Ardestani, Thomas Linke, Klaus Benndorf, Stephen J Tucker, Thomas Baukrowitz

Insights into the structural nature of the transition state in the Kir channel gating pathway.

Channels (Austin, Tex.) 8:6 (2014) 551-555

Authors:

Philip W Fowler, Murali K Bollepalli, Markus Rapedius, Ehsan Nematian-Ardestani, Lijun Shang, Mark Sp Sansom, Stephen J Tucker, Thomas Baukrowitz

Abstract:

In a previous study we identified an extensive gating network within the inwardly rectifying Kir1.1 (ROMK) channel by combining systematic scanning mutagenesis and functional analysis with structural models of the channel in the closed, pre-open and open states. This extensive network appeared to stabilize the open and pre-open states, but the network fragmented upon channel closure. In this study we have analyzed the gating kinetics of different mutations within key parts of this gating network. These results suggest that the structure of the transition state (TS), which connects the pre-open and closed states of the channel, more closely resembles the structure of the pre-open state. Furthermore, the G-loop, which occurs at the center of this extensive gating network, appears to become unstructured in the TS because mutations within this region have a 'catalytic' effect upon the channel gating kinetics.