Regulation of Na+ channel inactivation by the DIII and DIV voltage-sensing domains

Eric J. Hsu; Wandi Zhu; Angela R. Schubert; Taylor Voelker; Zoltan Varga; Jonathan R. Silva

doi:10.1085/jgp.201611678

Regulation of Na⁺ channel inactivation by the DIII and DIV voltage-sensing domains

Eric J. Hsu, Wandi Zhu, Angela R. Schubert, Taylor Voelker, Zoltan Varga, Jonathan R. Silva

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

Functional eukaryotic voltage-gated Na⁺ (Na_V ) channels comprise four domains (DI–DIV), each containing six membrane-spanning segments (S1–S6). Voltage sensing is accomplished by the first four membrane-spanning segments (S1–S4), which together form a voltage-sensing domain (VSD). A critical Na_V channel gating process, inactivation, has previously been linked to activation of the VSDs in DIII and DIV. Here, we probe this interaction by using voltage-clamp fluorometry to observe VSD kinetics in the presence of mutations at locations that have been shown to impair Na_V channel inactivation. These locations include the DIII–DIV linker, the DIII S4–S5 linker, and the DIV S4-S5 linker. Our results show that, within the 10-ms timeframe of fast inactivation, the DIV-VSD is the primary regulator of inactivation. However, after longer 100-ms pulses, the DIII–DIV linker slows DIII-VSD deactivation, and the rate of DIII deactivation correlates strongly with the rate of recovery from inac-tivation. Our results imply that, over the course of an action potential, DIV-VSDs regulate the onset of fast in-activation while DIII-VSDs determine its recovery.

Original language	English
Pages (from-to)	389-403
Number of pages	15
Journal	Journal of General Physiology
Volume	149
Issue number	3
DOIs	https://doi.org/10.1085/jgp.201611678
State	Published - 2017

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10.1085/jgp.201611678

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@article{3ce2a61c3f9344fea9aef6ed071702f7,

title = "Regulation of Na+ channel inactivation by the DIII and DIV voltage-sensing domains",

abstract = "Functional eukaryotic voltage-gated Na+ (NaV ) channels comprise four domains (DI–DIV), each containing six membrane-spanning segments (S1–S6). Voltage sensing is accomplished by the first four membrane-spanning segments (S1–S4), which together form a voltage-sensing domain (VSD). A critical NaV channel gating process, inactivation, has previously been linked to activation of the VSDs in DIII and DIV. Here, we probe this interaction by using voltage-clamp fluorometry to observe VSD kinetics in the presence of mutations at locations that have been shown to impair NaV channel inactivation. These locations include the DIII–DIV linker, the DIII S4–S5 linker, and the DIV S4-S5 linker. Our results show that, within the 10-ms timeframe of fast inactivation, the DIV-VSD is the primary regulator of inactivation. However, after longer 100-ms pulses, the DIII–DIV linker slows DIII-VSD deactivation, and the rate of DIII deactivation correlates strongly with the rate of recovery from inac-tivation. Our results imply that, over the course of an action potential, DIV-VSDs regulate the onset of fast in-activation while DIII-VSDs determine its recovery.",

author = "Hsu, {Eric J.} and Wandi Zhu and Schubert, {Angela R.} and Taylor Voelker and Zoltan Varga and Silva, {Jonathan R.}",

note = "Funding Information: This work was supported by a Howard Hughes Medical Institutes Summer Undergraduate Research Fellowship (to E.J. Hsu), American Heart Association Fellowship (15PRE25080073 to W. Zhu), a Burroughs Wellcome Fund Career Award at the Scientific Interface (1010299) and American Heart Association grant (16GRNT31200025; both to J.R. Silva), and a Hungarian Academy of Sciences grant (KTIA_NAP_13-2-2015-0009) and a Bolyai Fellowship (to Z. Varga). The authors declare no competing financial interests. Kenton J. Swartz served as editor. Publisher Copyright: {\textcopyright} 2017 Hsu et al.",

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doi = "10.1085/jgp.201611678",

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T1 - Regulation of Na+ channel inactivation by the DIII and DIV voltage-sensing domains

AU - Hsu, Eric J.

AU - Zhu, Wandi

AU - Schubert, Angela R.

AU - Voelker, Taylor

AU - Varga, Zoltan

AU - Silva, Jonathan R.

N1 - Funding Information: This work was supported by a Howard Hughes Medical Institutes Summer Undergraduate Research Fellowship (to E.J. Hsu), American Heart Association Fellowship (15PRE25080073 to W. Zhu), a Burroughs Wellcome Fund Career Award at the Scientific Interface (1010299) and American Heart Association grant (16GRNT31200025; both to J.R. Silva), and a Hungarian Academy of Sciences grant (KTIA_NAP_13-2-2015-0009) and a Bolyai Fellowship (to Z. Varga). The authors declare no competing financial interests. Kenton J. Swartz served as editor. Publisher Copyright: © 2017 Hsu et al.

PY - 2017

Y1 - 2017

N2 - Functional eukaryotic voltage-gated Na+ (NaV ) channels comprise four domains (DI–DIV), each containing six membrane-spanning segments (S1–S6). Voltage sensing is accomplished by the first four membrane-spanning segments (S1–S4), which together form a voltage-sensing domain (VSD). A critical NaV channel gating process, inactivation, has previously been linked to activation of the VSDs in DIII and DIV. Here, we probe this interaction by using voltage-clamp fluorometry to observe VSD kinetics in the presence of mutations at locations that have been shown to impair NaV channel inactivation. These locations include the DIII–DIV linker, the DIII S4–S5 linker, and the DIV S4-S5 linker. Our results show that, within the 10-ms timeframe of fast inactivation, the DIV-VSD is the primary regulator of inactivation. However, after longer 100-ms pulses, the DIII–DIV linker slows DIII-VSD deactivation, and the rate of DIII deactivation correlates strongly with the rate of recovery from inac-tivation. Our results imply that, over the course of an action potential, DIV-VSDs regulate the onset of fast in-activation while DIII-VSDs determine its recovery.

AB - Functional eukaryotic voltage-gated Na+ (NaV ) channels comprise four domains (DI–DIV), each containing six membrane-spanning segments (S1–S6). Voltage sensing is accomplished by the first four membrane-spanning segments (S1–S4), which together form a voltage-sensing domain (VSD). A critical NaV channel gating process, inactivation, has previously been linked to activation of the VSDs in DIII and DIV. Here, we probe this interaction by using voltage-clamp fluorometry to observe VSD kinetics in the presence of mutations at locations that have been shown to impair NaV channel inactivation. These locations include the DIII–DIV linker, the DIII S4–S5 linker, and the DIV S4-S5 linker. Our results show that, within the 10-ms timeframe of fast inactivation, the DIV-VSD is the primary regulator of inactivation. However, after longer 100-ms pulses, the DIII–DIV linker slows DIII-VSD deactivation, and the rate of DIII deactivation correlates strongly with the rate of recovery from inac-tivation. Our results imply that, over the course of an action potential, DIV-VSDs regulate the onset of fast in-activation while DIII-VSDs determine its recovery.

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Regulation of Na⁺ channel inactivation by the DIII and DIV voltage-sensing domains

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