Differential effects of homologous S4 mutations in human skeletal muscle sodium channels on deactivation gating from open and inactivated states

Groome, James R.; Fujimoto, E.; George, Alfred L.; Ruben, Peter C.

doi:10.1111/j.1469-7793.1999.0687u.x

Cited by 36 publications

(40 citation statements)

References 35 publications

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“…A charge-neutralizing arginine-to-cysteine substitution at the same position in hSkM1 (R669C) caused only a modest depolarizing shift of the G-V relationship of 5-7 mV (Mitrovic et al, 1998;Groome et al, 1999), similar to the small 3 mV rightward shift reported here. In the human cardiac Na channel isoform hH1, mutation of the outermost arginine in IIS4 to histidine caused a similar modest depolarizing shift in the conductance-voltage relationship and no change in the voltage dependence of inactivation (Chen et al, 1996).…”

Section: Role Of Iis4 In Nasupporting

confidence: 62%

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

Struyk

Scoggan²,

Bulman

et al. 2000

J. Neurosci.

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Missense mutations of the human skeletal muscle voltage-gated Na channel (hSkM1) underlie a variety of diseases, including hyperkalemic periodic paralysis (HyperPP), paramyotonia congenita, and potassium-aggravated myotonia. Another disorder of sarcolemmal excitability, hypokalemic periodic paralysis (HypoPP), which is usually caused by missense mutations of the S4 voltage sensors of the L-type Ca channel, was associated recently in one family with a mutation in the outermost arginine of the IIS4 voltage sensor (R669H) of hSkM1 (Bulman et al., 1999). Intriguingly, an arginine-to-histidine mutation at the homologous position in the L-type Ca 2ϩ channel (R528H) is a common cause of HypoPP. We have studied the gating properties of the hSkM1-R669H mutant Na channel experimentally in human embryonic kidney cells and found that it has no significant effects on activation or fast inactivation but does cause an enhancement of slow inactivation. R669H channels exhibit an ϳ10 mV hyperpolarized shift in the voltage dependence of slow inactivation and a twofold to fivefold prolongation of recovery after prolonged depolarization. In contrast, slow inactivation is often disrupted in HyperPP-associated Na channel mutants. These results demonstrate that, in R669H-associated HypoPP, enhanced slow inactivation does not preclude, and may contribute to, prolonged attacks of weakness and add support to previous evidence implicating the IIS4 voltage sensor in slow-inactivation gating.

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Section: Role Of Iis4 In Nasupporting

confidence: 62%

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

Struyk

Scoggan²,

Bulman

et al. 2000

J. Neurosci.

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“…Mutation of this positively charged arginine results in the general set of biophysical defects associated with paramyotonia congenita mutants, including slowed whole-cell current inactivation, reduced voltage-dependence of inactivation, enhanced rate of the recovery from inactivation and increased tetrodotoxin (TTX)-sensitive persistent (late) I Na . [7][8][9][10][11][12] These features lead to enhanced Na + entry into the cell causing depolarization of the resting membrane potential and sustained action potential firing which results in hyperexcitability (myotonia) or inexcitability (paralysis). 10,13,14 Current therapies for patients with…”

Section: Introductionmentioning

confidence: 99%

Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants

El-Bizri¹,

Kahlig²,

Shyrock³

et al. 2011

Channels

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“…Since the position of the S4 gating charge is biased towards the cytosolic side, the outermost charges may contribute to the initial gating charge transfer across the transmembrane electric field upon membrane depolarization. [32][33][34][35] When the outermost charge of a sensor is removed, e.g., R663C in domain-2, the initial activation of this sensor (outward movement) should be less voltage-dependent. If this initial movement of the voltage sensor already weakens the stability of the MrVIA-channel interaction, neutralization of the outermost charged residue is expected to have a strong impact on the kinetics with which MrVIA is repelled from the channel.…”

Section: Discussionmentioning

confidence: 99%

µO-Conotoxins Inhibit Na_VChannels by Interfering with their Voltage Sensors in Domain-2

Leipold¹,

DeBie²,

Zorn³

et al. 2007

Channels

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ACKNOWLEDGEMENTSThis work was supported by the Deutsche Forschungsgemeinschaft (HE 2993/5-2 to Stefan H. Heinemann), FONACIT CNPq (PI 20040000385 to Adolfo Borges), and NIH (GM48677 to Baldomero M. Olivera). We thank Dr. J. Trimmer for providing the clone for rNa V 1.4 and the MzB SW seminar group for helpful discussions. ABSTRACTThe µO-conotoxins MrVIA and MrVIB are 31-residue peptides from Conus marmoreus, belonging to the O-superfamily of conotoxins with three disulfide bridges. They have attracted attention because they are inhibitors of tetrodotoxin-insensitive voltage-gated sodium channels (Na V 1.8) and could therefore serve as lead structure for novel analgesics. The aim of this study was to elucidate the molecular mechanism by which µO-conotoxins affect Na V channels. Rat Na V 1.4 channels and mutants thereof were expressed in mammalian cells and were assayed with the whole-cell patch-clamp method. Unlike for the M-superfamily µ-conotoxin GIIIA from Conus geographus, channel block by MrVIA was strongly diminished after activating the Na V channels by depolarizing voltage steps. Searching for the source of this voltage dependence, the gating charges in all four-voltage sensors were reduced by site-directed mutagenesis showing that alterations of the voltage sensor in domain-2 have the strongest impact on MrVIA action. These results, together with previous findings that the effect of MrVIA depends on the structure of the pore-loop in domain-3, suggest a functional similarity with scorpion b-toxins. In fact, MrVIA functionally competed with the scorpion b-toxin Ts1 from Tityus serrulatus, while it did not show competition with µ-GIIIA. Ts1 and µ-GIIIA did not compete either. Thus, similar to scorpion b-toxins, µO-conotoxins are voltage-sensor toxins targeting receptor site-4 on Na V channels. They "block" Na + flow most likely by hindering the voltage sensor in domain-2 from activating and, hence, the channel from opening.

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Differential effects of homologous S4 mutations in human skeletal muscle sodium channels on deactivation gating from open and inactivated states

Cited by 36 publications

References 35 publications

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants

µO-Conotoxins Inhibit Na_VChannels by Interfering with their Voltage Sensors in Domain-2

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Differential effects of homologous S4 mutations in human skeletal muscle sodium channels on deactivation gating from open and inactivated states

Cited by 36 publications

References 35 publications

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

The Human Skeletal Muscle Na Channel Mutation R669H Associated with Hypokalemic Periodic Paralysis Enhances Slow Inactivation

Ranolazine block of human Nav1.4 sodium channels and paramyotonia congenita mutants

µO-Conotoxins Inhibit NaVChannels by Interfering with their Voltage Sensors in Domain-2

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Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants

µO-Conotoxins Inhibit Na_VChannels by Interfering with their Voltage Sensors in Domain-2