Ion channels

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.

Novel phenotype associated with a mutation in the KCNA1(Kv1.1) gene.

Frontiers in physiology 5 (2014) 525

Authors:

Maria C D'Adamo, Constanze Gallenmüller, Ilenio Servettini, Elisabeth Hartl, Stephen J Tucker, Larissa Arning, Saskia Biskup, Alessandro Grottesi, Luca Guglielmi, Paola Imbrici, Pia Bernasconi, Giuseppe Di Giovanni, Fabio Franciolini, Luigi Catacuzzeno, Mauro Pessia, Thomas Klopstock

Abstract:

Episodic ataxia type 1 (EA1) is an autosomal dominant K(+) channelopathy which manifests with short attacks of cerebellar ataxia and dysarthria, and may also show interictal myokymia. Episodes can be triggered by emotional or physical stress, startle response, sudden postural change or fever. Here we describe a 31-year-old man displaying markedly atypical symptoms, including long-lasting attacks of jerking muscle contractions associated with hyperthermia, severe migraine, and a relatively short-sleep phenotype. A single nucleotide change in KCNA1 (c.555C>G) was identified that changes a highly conserved residue (p.C185W) in the first transmembrane segment of the voltage-gated K(+) channel Kv1.1. The patient is heterozygous and the mutation was inherited from his asymptomatic mother. Next generation sequencing revealed no variations in the CACNA1A, CACNB4, KCNC3, KCNJ10, PRRT2 or SCN8A genes of either the patient or mother, except for a benign variant in SLC1A3. Functional analysis of the p.C185W mutation in KCNA1 demonstrated a deleterious dominant-negative phenotype where the remaining current displayed slower activation kinetics, subtle changes in voltage-dependence and faster recovery from slow inactivation. Structural modeling also predicts the C185W mutation to be functionally deleterious. This description of novel clinical features, associated with a Kv1.1 mutation highlights a possibly unrecognized relationship between K(+) channel dysfunction, hyperthermia and migraine in EA1, and suggests that thorough assessments for these symptoms should be carefully considered for all patients affected by EA1.

A novel mechanism of voltage sensing and gating in K2P potassium channels

ACTA PHYSIOLOGICA 210 (2014) 62-62

Authors:

M Rapedius, M Schewe, E Nematian-Ardestani, T Linke, K Benndorf, SJ Tucker, T Baukrowitz

A novel mechanism of voltage sensing and gating in K2P potassium channels

ACTA PHYSIOLOGICA 210 (2014) 220-222

Authors:

M Schewe, M Rapedius, E Nematian-Ardestani, T Linke, K Benndorf, SJ Tucker, T Baukrowitz

Simulation-based prediction of phosphatidylinositol 4,5-bisphosphate binding to an ion channel.

Biochemistry 52:2 (2013) 279-281

Authors:

Matthias R Schmidt, Phillip J Stansfeld, Stephen J Tucker, Mark SP Sansom

Abstract:

Protein-lipid interactions regulate many membrane protein functions. Using a multiscale approach that combines coarse-grained and atomistic molecular dynamics simulations, we have predicted the binding site for the anionic phospholipid phosphatidylinositol 4,5-bisphosphate (PIP(2)) on the Kir2.2 inwardly rectifying (Kir) potassium channel. Comparison of the predicted binding site to that observed in the recent PIP(2)-bound crystal structure of Kir2.2 reveals good agreement between simulation and experiment. In addition to providing insight into the mechanism by which PIP(2) binds to Kir2.2, these results help to establish the validity of this multiscale simulation approach and its future application in the examination of novel membrane protein-lipid interactions in the increasing number of high-resolution membrane protein structures that are now available.