Molecular mapping of a site for Cd<sup>2+</sup>‐induced modification of human <i>ether‐à‐go‐go</i>‐related gene (hERG) channel activation

C., David J. Fernández; Ghanta, Azad; Kinard, Krista; Sanguinetti, Michael C.

doi:10.1113/jphysiol.2005.089094

Cited by 26 publications

(58 citation statements)

References 52 publications

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“…These specific interactions were supported by the recently solved crystal structure of Kv1.2, demonstrating a salt bridge between R303 and E226 (corresponding to R531 and D456 in hERG1, respectively) in the open conformation [21]. Moreover, D456, D460 and D509 in hERG1 form a coordination site for external Cd 2+ implying that these residues are located close to one another [42]. A homology model of hERG1 based on the Kv1.2 crystal structure illustrates the proximity of R531 to this negatively charged pocket in the open state (Fig.…”

Section: Discussionmentioning

confidence: 53%

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Piper

Rupp

Sachse

et al. 2008

Cell Physiol Biochem

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HERG1 K⁺ channels are critical for modulating the duration of the cardiac action potential. The role of hERG1 channels in maintaining electrical stability in the heart derives from their unusual gating properties: slow activation and fast inactivation. HERG1 channel inactivation is intrinsically voltage sensitive and is not coupled to activation in the same way as in the Shaker family of K⁺ channels. We recently proposed that the S4 transmembrane domain functions as the primary voltage sensor for hERG1 activation and inactivation and that distinct regions of S4 contribute to each gating process. In this study, we tested the hypothesis that S4 rearrangements underlying activation and inactivation gating may be associated with distinct cooperative interactions between a key residue in the S4 domain (R531) and acidic residues in neighboring regions (S1 – S3 domains) of the voltage sensing module. Using double-mutant cycle analysis, we found that R531 was energetically coupled to all acidic residues in S1-S3 during activation, but was coupled only to acidic residues near the extracellular portion of S2 and S3 (D456, D460 and D509) during inactivation. We propose that hERG1 activation involves a cooperative conformational change involving the entire voltage sensing module, while inactivation may involve a more limited interaction between R531 and D456, D460 and D509.

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Section: Discussionmentioning

confidence: 53%

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Piper

Rupp

Sachse

et al. 2008

Cell Physiol Biochem

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“…Mutagenic neutralization of these charges in mammalian Eag, Elk and Erg channels depolarizes the voltage-activation curve (Fernandez et al, 2005;Silverman et al, 2000;Zhang et al, 2009). Furthermore, voltage activation of EAG channels is universally depolarized by extracellular protons through neutralization of the EAG acidic charges (Kazmierczak et al, 2013).…”

Section: Research Articlementioning

confidence: 99%

“…We examined the pH and divalent cation sensitivity of NvErg1 activation because voltage activation of human Erg1 is also inhibited by binding of protons and Ca 2+ and Mg 2+ to the EAG-specific voltage sensor site (Fernandez et al, 2005;Jo et al, 1999;Kazmierczak et al, 2013). The pH sensitivity of human Erg is extremely low at physiological concentrations of Ca 2+ , but increases dramatically if Ca 2+ is reduced to micromolar levels (Kazmierczak et al, 2013).…”

Section: Research Articlementioning

confidence: 99%

“…Mg 2+ sensitivity of Eag channels is primarily conferred by acidic residues in the voltage sensor (Silverman et al, 2000) that are unique to the EAG family of K + channels, but are shared with hyperpolarizationgated cation channels (HCNs) and cyclic-nucleotide-gated cation channels (CNGs). Erg channel kinetics are sensitive to both Mg 2+ and Ca 2+ (Fernandez et al, 2005;Jo et al, 1999), whereas Elk channels are insensitive to these ions, but are inhibited by Zn 2+ (Zhang et al, 2009). Protons inhibit voltage-dependent activation of all EAG family channels examined so far through protonation of these same EAG family acidic residues (Kazmierczak et al, 2013) and compete with divalent cations for the binding site (Kazmierczak et al, 2013;Terlau et al, 1996).…”

Section: Introductionmentioning

confidence: 99%

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Ether-à-go-go family voltage-gated K+ channels evolved in an ancestral metazoan and functionally diversified in a cnidarian–bilaterian ancestor

Martinson

Layden

et al. 2015

Journal of Experimental Biology

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We examined the evolutionary origins of the ether-à-go-go (EAG) family of voltage-gated K + channels, which have a strong influence on the excitability of neurons. The bilaterian EAG family comprises three gene subfamilies (Eag, Erg and Elk) distinguished by sequence conservation and functional properties. Searches of genome sequence indicate that EAG channels are metazoan specific, appearing first in ctenophores. However, phylogenetic analysis including two EAG family channels from the ctenophore Mnemiopsis leidyi indicates that the diversification of the Eag, Erg and Elk gene subfamilies occurred in a cnidarian/bilaterian ancestor after divergence from ctenophores. Erg channel function is highly conserved between cnidarians and mammals. Here we show that Eag and Elk channels from the sea anemone Nematostella vectensis (NvEag and NvElk) also share high functional conservation with mammalian channels. NvEag, like bilaterian Eag channels, has rapid kinetics, whereas NvElk activates at extremely hyperpolarized voltages, which is characteristic of Elk channels. Potent inhibition of voltage activation by extracellular protons is conserved between mammalian and Nematostella EAG channels. However, characteristic inhibition of voltage activation by Mg 2+ in Eag channels and Ca 2+ in Erg channels is reduced in Nematostella because of mutation of a highly conserved aspartate residue in the voltage sensor. This mutation may preserve sub-threshold activation of Nematostella Eag and Erg channels in a high divalent cation environment. mRNA in situ hybridization of EAG channels in Nematostella suggests that they are differentially expressed in distinct cell types. Most notable is the expression of NvEag in cnidocytes, a cnidarian-specific stinging cell thought to be a neuronal subtype.

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“…Guided by our rescue experiments, we surveyed a series of mutations in the transmembrane domain of hERG (S1-S6) that replaced negatively charged glutamate or aspartate residues with alanine, because we considered negatively charged amino acid residues putative interaction partners for positively charged pentamidine. Mutations in the S1-S4 voltage sensor domain included hERG 4EC, which removes not one but four glutamate residues in the extracellular S1-S2 linker (Fernandez et al, 2005), hERG D456A, D460A, D466A, D509A, E518A, E519A, D540A, and E544A. In the inner pore region (S5-S6), we tested three additional negative charge replacements, hERG E575A, D580A, and D591A.…”

Section: Pentamidine Inhibits Herg Forward Traffickingmentioning

confidence: 99%

Molecular Determinants of Pentamidine-Induced hERG Trafficking Inhibition

Dennis¹,

Wang²,

Wan³

et al. 2011

Mol Pharmacol

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Pentamidine is an antiprotozoal compound that clinically causes acquired long QT syndrome (acLQTS), which is associated with prolonged QT intervals, tachycardias, and sudden cardiac arrest. Pentamidine delays terminal repolarization in human heart by acutely blocking cardiac inward rectifier currents. At the same time, pentamidine reduces surface expression of the cardiac potassium channel I Kr /human ether à -gogo-related gene (hERG). This is unusual in that acLQTS is caused most often by direct block of the cardiac potassium current I Kr /hERG. The present study was designed to provide a more complete picture of how hERG surface expression is disrupted by pentamidine at the cellular and molecular levels. Using biochemical and electrophysiological methods, we found that pentamidine exclusively inhibits hERG export from the endoplasmic reticulum to the cell surface in a heterologous expression system as well as in cardiomyocytes. hERG trafficking inhibition could be rescued in the presence of the pharmacological chaperone astemizole. We used rescue experiments in combination with an extensive mutational analysis to locate an interaction site for pentamidine at phenylalanine 656, a crucial residue in the canonical drug binding site of terminally folded hERG. Our data suggest that pentamidine binding to a folding intermediate of hERG arrests channel maturation in a conformational state that cannot be exported from the endoplasmic reticulum. We propose that pentamidine is the founding member of a novel pharmacological entity whose members act as small molecule antichaperones.

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Molecular mapping of a site for Cd²⁺‐induced modification of human ether‐à‐go‐go‐related gene (hERG) channel activation

Cited by 26 publications

References 52 publications

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Ether-à-go-go family voltage-gated K+ channels evolved in an ancestral metazoan and functionally diversified in a cnidarian–bilaterian ancestor

Molecular Determinants of Pentamidine-Induced hERG Trafficking Inhibition

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Molecular mapping of a site for Cd2+‐induced modification of human ether‐à‐go‐go‐related gene (hERG) channel activation

Cited by 26 publications

References 52 publications

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Cooperative Interactions Between R531 and Acidic Residues in the Voltage Sensing Module of hERG1 Channels

Ether-à-go-go family voltage-gated K+ channels evolved in an ancestral metazoan and functionally diversified in a cnidarian–bilaterian ancestor

Molecular Determinants of Pentamidine-Induced hERG Trafficking Inhibition

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Molecular mapping of a site for Cd²⁺‐induced modification of human ether‐à‐go‐go‐related gene (hERG) channel activation