External protons destabilize the activated voltage sensor in hERG channels

Shi, Yu; Cheng, Yen May; Slyke, Aaron C. Van; Claydon, Tom W.

doi:10.1007/s00249-013-0940-y

Cited by 12 publications

(32 citation statements)

References 43 publications

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“…Double mutant cyclic analysis revealed energetic coupling between R531 and D456, D460, and D509 during activation and with D411 and D466 through a cooperative ionic-pairing interaction mechanism (Piper et al, 2008). Accessibility studies have also revealed that D460 and D509 stabilize the activated state (Liu et al, 2003), which is consistent with observations that neutralization of any of the acidic charges accelerates deactivation kinetics, likely by disrupting electrostatic interactions with S4 basic residues (Liu et al, 2003;Fernandez et al, 2005;Piper et al, 2008;Shi et al, 2014). Interestingly, disruption of the electrostatic pairing involving D509, either by protonation or alanine substitution, destabilizes the relaxed state of the voltage sensor leading to the loss of hysteresis and accelerated deactivation (Shi et al, 2019).…”

Section: The Voltage Sensor Domain (S1-s4)supporting

confidence: 76%

“…The Relaxed State of the Voltage Sensor Is Destabilized by Extracellular Protons hERG channel deactivation kinetics are sensitive to changes in the extracellular proton concentration and numerous studies have shown that acidosis accelerates deactivation rate (Anumonwo et al, 1999;Bérubé et al, 1999;Jiang et al, 1999;Terai et al, 2000;Bett and Rasmusson, 2003;Du et al, 2010;Zhou and Bett, 2010;Du et al, 2011;Van Slyke et al, 2012;Shi et al, 2014;Shi et al, 2019). pH reductions within the physiological range (as low as pH 6.5) accelerated both the fast and the slow components of deactivation with a pKa of~6.8 (Bett and Rasmusson, 2003;Shi et al, 2019) with little effect channel conductance, and other voltage-dependent gating parameters (Jiang et al, 1999;Bett and Rasmusson, 2003;Shi et al, 2019).…”

Section: Targeted Modulation Of Herg Voltage Sensor Relaxationmentioning

confidence: 99%

“…A key site of action for this effect of external protons may be three acidic residues, D456, D460, and D509, which form a cation binding pocket that coordinates Zn 2+ , Mg 2+ , Ca 2+ , Cd 2+ , as well as H + (Ho et al, 1998;Jo et al, 1999;Fernandez et al, 2005;Lin and Papazian, 2007;Abbruzzese et al, 2010;Kazmierczak et al, 2013;Shi et al, 2014;Shi et al, 2019). These sites may also interact with positive S4 gating charges as discussed in an earlier section.…”

Section: Targeted Modulation Of Herg Voltage Sensor Relaxationmentioning

confidence: 99%

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Modulation of hERG K+ Channel Deactivation by Voltage Sensor Relaxation

2020

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The hERG (human-ether-à-go-go-related gene) channel underlies the rapid delayed rectifier current, I kr , in the heart, which is essential for normal cardiac electrical activity and rhythm. Slow deactivation is one of the hallmark features of the unusual gating characteristics of hERG channels, and plays a crucial role in providing a robust current that aids repolarization of the cardiac action potential. As such, there is significant interest in elucidating the underlying mechanistic determinants of slow hERG channel deactivation. Recent work has shown that the hERG channel S4 voltage sensor is stabilized following activation in a process termed relaxation. Voltage sensor relaxation results in energetic separation of the activation and deactivation pathways, producing a hysteresis, which modulates the kinetics of deactivation gating. Despite widespread observation of relaxation behaviour in other voltage-gated K + channels, such as Shaker, Kv1.2 and Kv3.1, as well as the voltage-sensing phosphatase Ci-VSP, the relationship between stabilization of the activated voltage sensor by the open pore and voltage sensor relaxation in the control of deactivation has only recently begun to be explored. In this review, we discuss present knowledge and questions raised related to the voltage sensor relaxation mechanism in hERG channels and compare structure-function aspects of relaxation with those observed in related ion channels. We focus discussion, in particular, on the mechanism of coupling between voltage sensor relaxation and deactivation gating to highlight the insight that these studies provide into the control of hERG channel deactivation gating during their physiological functioning.

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Section: The Voltage Sensor Domain (S1-s4)supporting

confidence: 76%

Section: Targeted Modulation Of Herg Voltage Sensor Relaxationmentioning

confidence: 99%

Section: Targeted Modulation Of Herg Voltage Sensor Relaxationmentioning

confidence: 99%

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Modulation of hERG K+ Channel Deactivation by Voltage Sensor Relaxation

2020

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“…The effects of protons on gating have been thoroughly studied in Nav1.5 [25]. Although the identity of the residues involved in pH-dependent changes in gating have not been fully determined, structural studies in bacterial sodium channels and potassium channels suggest that acidic residues play a role [21,39]. Interactions of protons at the individual domains typically depolarizes the voltage-dependence, presumably via electrostatic interactions which hinder the outward movement of S4 voltage-sensors.…”

Section: Discussionmentioning

confidence: 99%

“…The presence of extracellular protons can modulate both the VSD and the PD, depolarizing the voltagedependence of activation and blocking ionic current, respectively [18,19]. Acidification decreases peak sodium conductance by protonating the outer vestibule carboxylates [19,20], and likely by binding to negative charges in the VSDs, which destabilizes the outward conformation of the voltage-sensors [21,22].…”

Section: Introductionmentioning

confidence: 99%

Effects of acidosis on neuronal voltage-gated sodium channels: Nav1.1 and Nav1.3

2018

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Voltage-gated sodium channels are key contributors to membrane excitability. These channels are expressed in a tissue-specific manner. Mutations and modulation of these channels underlie various physiological and pathophysiological manifestations. The effects of changes in extracellular pH on channel gating have been studied on several sodium channel subtypes. Among these, Nav1.5 is the most pH-sensitive channel, with Nav1.2 and Nav1.4 being mostly pH-resistant channels. However, pH effects have not been characterized on other sodium channel subtypes. In this study, we sought to determine whether Nav1.1 and Nav1.3 display resistance or sensitivity to changes in extracellular pH. These two sodium channel subtypes are predominantly found in inhibitory neurons. The expression of these channels highly depends on age and the developmental stage of neurons, with Nav1.3 being found mostly in neonatal neurons, and Nav1.1 being found in adult neurons. Our present results indicate that, during extracellular acidosis, both channels show a depolarization in the voltage-dependence of activation and moderate reduction in current density. Voltage-dependence of steady-state fast inactivation and recovery from fast inactivation were unchanged. We conclude that Nav1.1 and Nav1.3 have similar pH-sensitivities.

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pH Modulation of Voltage-Gated Sodium Channels

Peters

Ghovanloo

Gershome

et al. 2018

Handbook of Experimental Pharmacology

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Changes in blood and tissue pH accompany physiological and pathophysiological conditions including exercise, cardiac ischemia, ischemic stroke, and cocaine ingestion. These conditions are known to trigger the symptoms of electrical diseases in patients carrying sodium channel mutations. Protons cause a diverse set of changes to sodium channel gating, which generally lead to decreases in the amplitude of the transient sodium current and increases in the fraction of non-inactivating channels that pass persistent currents. These effects are shared with disease-causing mutants in neuronal, skeletal muscle, and cardiac tissue and may be compounded in mutants that impart greater proton sensitivity to sodium channels, suggesting a role of protons in triggering acute symptoms of electrical disease.In this chapter, we review the mechanisms of proton block of the sodium channel pore and a suggested mode of action by which protons alter channel gating. We discuss the available data on isoform specificity of proton effects and tissue level effects. Finally, we review the role that protons play in disease and our own recent studies on proton-sensitizing mutants in cardiac and skeletal muscle sodium channels.

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External protons destabilize the activated voltage sensor in hERG channels

Cited by 12 publications

References 43 publications

Modulation of hERG K+ Channel Deactivation by Voltage Sensor Relaxation

Modulation of hERG K+ Channel Deactivation by Voltage Sensor Relaxation

Effects of acidosis on neuronal voltage-gated sodium channels: Nav1.1 and Nav1.3

pH Modulation of Voltage-Gated Sodium Channels

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