Discovery of a heme-binding domain in a neuronal voltage-gated potassium channel.

The EAG () family of voltage-gated K channels are important regulators of neuronal and cardiac action potential firing (excitability) and have major roles in human diseases such as epilepsy, schizophrenia, cancer, and sudden cardiac death. A defining feature of EAG (Kv10-12) channels is a highly conserved domain on the N terminus, known as the eag domain, consisting of a Per-ARNT-Sim (PAS) domain capped by a short sequence containing an amphipathic helix (Cap domain). The PAS and Cap domains are both vital for the normal function of EAG channels.

Author Correction: A mechanism for CO regulation of ion channels.

The originally published version of this article contained an error in the subheading 'Heme is required for CO-dependent channel activation', which was incorrectly given as 'Hame is required for CO-dependent channel activation'. This has now been corrected in both the PDF and HTML versions of the Article.

A Novel Mechanism for Calmodulin-Dependent Inactivation of Transient Receptor Potential Vanilloid 6.

The paralogues TRPV5 and TRPV6 belong to the vanilloid subfamily of the transient receptor potential (TRP) superfamily of ion channels, and both play an important role in overall Ca homeostasis. The functioning of the channels centers on a tightly controlled Ca-dependent feedback mechanism in which the direct binding of the universal Ca-binding protein calmodulin (CaM) to the channel's C-terminal tail is required for channel inactivation. We have investigated this interaction at the atomic level and propose that under basal cellular Ca concentrations CaM is constitutively bound to the channel's C-tail via CaM C-lobe only contacts.

A mechanism for CO regulation of ion channels.

Despite being highly toxic, carbon monoxide (CO) is also an essential intracellular signalling molecule. The mechanisms of CO-dependent cell signalling are poorly defined, but are likely to involve interactions with heme proteins. One such role for CO is in ion channel regulation.

Calmodulin Regulates Human Ether à Go-Go 1 (hEAG1) Potassium Channels through Interactions of the Eag Domain with the Cyclic Nucleotide Binding Homology Domain.

The ether à go-go family of voltage-gated potassium channels is structurally distinct. The N terminus contains an eag domain (eagD) that contains a Per-Arnt-Sim (PAS) domain that is preceded by a conserved sequence of 25-27 amino acids known as the PAS-cap. The C terminus contains a region with homology to cyclic nucleotide binding domains (cNBHD), which is directly linked to the channel pore.

A heme-binding domain controls regulation of ATP-dependent potassium channels.

Heme iron has many and varied roles in biology. Most commonly it binds as a prosthetic group to proteins, and it has been widely supposed and amply demonstrated that subtle variations in the protein structure around the heme, including the heme ligands, are used to control the reactivity of the metal ion. However, the role of heme in biology now appears to also include a regulatory responsibility in the cell; this includes regulation of ion channel function.

hERG potassium channel blockade by the HCN channel inhibitor bradycardic agent ivabradine.

Background: Ivabradine is a specific bradycardic agent used in coronary artery disease and heart failure, lowering heart rate through inhibition of sinoatrial nodal HCN-channels. This study investigated the propensity of ivabradine to interact with KCNH2-encoded human Ether-à-go-go-Related Gene (hERG) potassium channels, which strongly influence ventricular repolarization and susceptibility to torsades de pointes arrhythmia.

Methods And Results: Patch clamp recordings of hERG current (IhERG) were made from hERG expressing cells at 37°C.

New pyrimido-indole compound CD-160130 preferentially inhibits the KV11.1B isoform and produces antileukemic effects without cardiotoxicity.

KV11.1 (hERG1) channels are often overexpressed in human cancers. In leukemias, KV11.

Long-term channel block is required to inhibit cellular transformation by human ether-à-go-go-related gene (hERG1) potassium channels.

Both human ether-à-go-go-related gene (hERG1) and the closely related human ether-à-go-go (hEAG1) channel are aberrantly expressed in a large proportion of human cancers. In the present study, we demonstrate that transfection of hERG1 into mouse fibroblasts is sufficient to induce many features characteristic of malignant transformation. An important finding of this work is that this transformation could be reversed by chronic incubation (for 2-3 weeks) with the hERG channel blocker dofetilide (100 nM), whereas more acute applications (for 1-2 days) were ineffective.

Computational design and discovery of "minimally structured" hERG blockers.

Molecular knowledge of hERG blocking liability can offer the possibility of optimizing lead compounds in a way that eliminates potentially lethal side effects. In this study, we computationally designed, synthesized, and tested a small series of "minimally structured" molecules. Some of these compounds were remarkably potent against hERG (6, IC(50) = 2.

Mechanistic insight into human ether-à-go-go-related gene (hERG) K+ channel deactivation gating from the solution structure of the EAG domain.

Human ether-à-go-go-related gene (hERG) K(+) channels have a critical role in cardiac repolarization. hERG channels close (deactivate) very slowly, and this is vital for regulating the time course and amplitude of repolarizing current during the cardiac action potential. Accelerated deactivation is one mechanism by which inherited mutations cause long QT syndrome and potentially lethal arrhythmias.

Resonance assignment and secondary structure prediction of the N-terminal domain of hERG (Kv11.1).

The hERG (human ether-à-go-go related gene) channel is a member of the eag voltage-gated K(+) channel family. In common with other members of this family, it has a subunit topology of six trans-membrane helices that tetramerise to form a functional ion-channel. In addition, hERG has an N-terminal PAS (Per, Arnt and Sim) domain and a C-terminal cyclic nucleotide binding domain (cNBD).

Revealing the structural basis of action of hERG potassium channel activators and blockers.

Human ether-á-go-go related gene (hERG) potassium (K(+)) channels play a critical role in cardiac action potential repolarization. This is due, in large part, to the unique gating properties of these channels, which are characterized by relatively slow activation and an unusually fast and voltage-dependent inactivation. A large number of structurally diverse compounds bind to hERG and carry an unacceptably high risk of causing arrhythmias.

hERG potassium channels and the structural basis of drug-induced arrhythmias.

hERG potassium channels have a critical role in the normal electrical activity of the heart. The block of hERG channels can cause the drug-induced form of long QT syndrome, a cardiac disorder that carries an increased risk of cardiac arrhythmias and sudden death. hERG channels are extraordinarily sensitive to block by large numbers of structurally diverse drugs.

Activation gating of hERG potassium channels: S6 glycines are not required as gating hinges.

The opening of ion channels is proposed to arise from bending of the pore inner helices that enables them to pivot away from the central axis creating a cytosolic opening for ion diffusion. The flexibility of the inner helices is suggested to occur either at a conserved glycine located adjacent to the selectivity filter (glycine gating hinge) and/or at a second site occupied by glycine or proline containing motifs. Sequence alignment with other K+ channels shows that hERG possesses glycine residues (Gly648 and Gly657) at each of these putative hinge sites.

Drug block of the hERG potassium channel: insight from modeling.

Many commonly used, structurally diverse, drugs block the human ether-a-go-go-related gene (hERG) K(+) channel to cause acquired long QT syndrome, which can lead to sudden death via lethal cardiac arrhythmias. This undesirable side effect is a major hurdle in the development of safe drugs. To gain insight about the structure of hERG and the nature of drug block we have produced structural models of the channel pore domain, into each of which we have docked a set of 20 hERG blockers.

Molecular mechanisms for drug interactions with hERG that cause long QT syndrome.

The human ether-a-go-go-related gene (hERG) encodes the pore-forming alpha-subunit of a voltage-gated potassium (K(+)) channel. A variety of unrelated compounds reduce K(+ )current in the heart by blocking the pore or disrupting trafficking of the hERG channel to the membrane surface. This induces a syndrome known as long QT, which arises from abnormalities in action potential repolarisation and can degenerate into lethal cardiac arrhythmias.

Molecular determinants of HERG channel block.

Drug-induced block of cardiac hERG K+ channels causes acquired long QT syndrome. Here, we characterized the molecular mechanism of hERG block by two low-potency drugs (Nifekalant and bepridil) and two high-potency drugs 1-[2-(6-methyl-2pyridyl)ethyl]-4-(4-methylsulfonyl aminobenzoyl)piperidine (E-4031) and dofetilide). Channels were expressed in Xenopus laevis oocytes, and currents were measured using the two-microelectrode voltage-clamp technique.

Drug binding interactions in the inner cavity of HERG channels: molecular insights from structure-activity relationships of clofilium and ibutilide analogs.

Block of human ether-a-go-go related gene (hERG) K(+) channels by otherwise useful drugs is the most common cause of long QT syndrome, a disorder of cardiac repolarization that predisposes patients to potentially fatal arrhythmias. This undesirable long QT side effect has been a major reason for the withdrawal of medications from the pharmaceutical market. Understanding the molecular basis of hERG block is therefore essential to facilitate the design of safe drugs.

Physicochemical basis for binding and voltage-dependent block of hERG channels by structurally diverse drugs.

Blockade of hERG K+ channels in the heart is an unintentional side effect of many drugs and can induce cardiac arrhythmia and sudden death. For this reason, most pharmaceutical companies screen compounds for hERG channel activity early in the drug discovery/development process. A detailed understanding of the drug binding site(s) on the hERG channel could enable rational design of future medications devoid of this unwanted side effect.