Cumulative hydropathic topology of a voltage-gated sodium channel at atomic resolution

Markos N. Xenakis; Dimos Kapetis; Yang Yang; Jordi Heijman; Stephen G. Waxman; Giuseppe Lauria; Catharina G. Faber; Hubert J. Smeets; Ronald L. Westra; Patrick J. Lindsey

doi:10.1002/prot.25951

Cumulative hydropathic topology of a voltage-gated sodium channel at atomic resolution

Markos N. Xenakis^*, Dimos Kapetis, Yang Yang, Jordi Heijman, Stephen G. Waxman, Giuseppe Lauria, Catharina G. Faber, Hubert J. Smeets, Ronald L. Westra, Patrick J. Lindsey

^*Corresponding author for this work

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

Abstract

Voltage-gated sodium channels (NavChs) are biological pores that control the flow of sodium ions through the cell membrane. In humans, mutations in genes encoding NavChs can disrupt physiological cellular activity thus leading to a wide spectrum of diseases. Here, we present a topological connection between the functional architecture of a NavAb bacterial channel and accumulation of atomic hydropathicity around its pore. This connection is established via a scaling analysis methodology that elucidates how intrachannel hydropathic density variations translate into hydropathic dipole field configurations along the pore. Our findings suggest the existence of a nonrandom cumulative hydropathic topology that is organized parallel to the membrane surface so that pore's stability, as well as, gating behavior are guaranteed. Given the biophysical significance of the hydropathic effect, our study seeks to provide a computational framework for studying cumulative hydropathic topological properties of NavChs and pore-forming proteins in general.

Original language	English
Pages (from-to)	1319-1328
Number of pages	10
Journal	Proteins-structure Function and Bioinformatics
Volume	88
Issue number	10
DOIs	https://doi.org/10.1002/prot.25951
Publication status	Published - Oct 2020

Keywords

ALPHA-SUBUNIT
ERYTHERMALGIA
ERYTHROMELALGIA
EXTREME PAIN DISORDER
HYDROPHOBIC MOMENTS
NA(V)1.7
NavAb
OF-FUNCTION MUTATION
SCN9A MUTATIONS
STATE
WATER
cumulative hydropathic effects
hydrophobic gating
scaling
topology
voltage-gated sodium channels

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Cite this

@article{0cfd6d7a08da40128c947975b216f128,

title = "Cumulative hydropathic topology of a voltage-gated sodium channel at atomic resolution",

abstract = "Voltage-gated sodium channels (NavChs) are biological pores that control the flow of sodium ions through the cell membrane. In humans, mutations in genes encoding NavChs can disrupt physiological cellular activity thus leading to a wide spectrum of diseases. Here, we present a topological connection between the functional architecture of a NavAb bacterial channel and accumulation of atomic hydropathicity around its pore. This connection is established via a scaling analysis methodology that elucidates how intrachannel hydropathic density variations translate into hydropathic dipole field configurations along the pore. Our findings suggest the existence of a nonrandom cumulative hydropathic topology that is organized parallel to the membrane surface so that pore's stability, as well as, gating behavior are guaranteed. Given the biophysical significance of the hydropathic effect, our study seeks to provide a computational framework for studying cumulative hydropathic topological properties of NavChs and pore-forming proteins in general.",

keywords = "ALPHA-SUBUNIT, ERYTHERMALGIA, ERYTHROMELALGIA, EXTREME PAIN DISORDER, HYDROPHOBIC MOMENTS, NA(V)1.7, NavAb, OF-FUNCTION MUTATION, SCN9A MUTATIONS, STATE, WATER, cumulative hydropathic effects, hydrophobic gating, scaling, topology, voltage-gated sodium channels",

author = "Xenakis, {Markos N.} and Dimos Kapetis and Yang Yang and Jordi Heijman and Waxman, {Stephen G.} and Giuseppe Lauria and Faber, {Catharina G.} and Smeets, {Hubert J.} and Westra, {Ronald L.} and Lindsey, {Patrick J.}",

note = "Funding Information: Seventh Framework Programme, Grant/Award Number: grant n602273; European Union 7th Framework Programme Funding information Publisher Copyright: {\textcopyright} 2020 The Authors. Proteins: Structure, Function, and Bioinformatics published by Wiley Periodicals, LLC.",

year = "2020",

month = oct,

doi = "10.1002/prot.25951",

language = "English",

volume = "88",

pages = "1319--1328",

journal = "Proteins-structure Function and Bioinformatics",

issn = "0887-3585",

publisher = "Wiley-Liss Inc.",

number = "10",

}

TY - JOUR

T1 - Cumulative hydropathic topology of a voltage-gated sodium channel at atomic resolution

AU - Xenakis, Markos N.

AU - Kapetis, Dimos

AU - Yang, Yang

AU - Heijman, Jordi

AU - Waxman, Stephen G.

AU - Lauria, Giuseppe

AU - Faber, Catharina G.

AU - Smeets, Hubert J.

AU - Westra, Ronald L.

AU - Lindsey, Patrick J.

N1 - Funding Information: Seventh Framework Programme, Grant/Award Number: grant n602273; European Union 7th Framework Programme Funding information Publisher Copyright: © 2020 The Authors. Proteins: Structure, Function, and Bioinformatics published by Wiley Periodicals, LLC.

PY - 2020/10

Y1 - 2020/10

N2 - Voltage-gated sodium channels (NavChs) are biological pores that control the flow of sodium ions through the cell membrane. In humans, mutations in genes encoding NavChs can disrupt physiological cellular activity thus leading to a wide spectrum of diseases. Here, we present a topological connection between the functional architecture of a NavAb bacterial channel and accumulation of atomic hydropathicity around its pore. This connection is established via a scaling analysis methodology that elucidates how intrachannel hydropathic density variations translate into hydropathic dipole field configurations along the pore. Our findings suggest the existence of a nonrandom cumulative hydropathic topology that is organized parallel to the membrane surface so that pore's stability, as well as, gating behavior are guaranteed. Given the biophysical significance of the hydropathic effect, our study seeks to provide a computational framework for studying cumulative hydropathic topological properties of NavChs and pore-forming proteins in general.

AB - Voltage-gated sodium channels (NavChs) are biological pores that control the flow of sodium ions through the cell membrane. In humans, mutations in genes encoding NavChs can disrupt physiological cellular activity thus leading to a wide spectrum of diseases. Here, we present a topological connection between the functional architecture of a NavAb bacterial channel and accumulation of atomic hydropathicity around its pore. This connection is established via a scaling analysis methodology that elucidates how intrachannel hydropathic density variations translate into hydropathic dipole field configurations along the pore. Our findings suggest the existence of a nonrandom cumulative hydropathic topology that is organized parallel to the membrane surface so that pore's stability, as well as, gating behavior are guaranteed. Given the biophysical significance of the hydropathic effect, our study seeks to provide a computational framework for studying cumulative hydropathic topological properties of NavChs and pore-forming proteins in general.

KW - ALPHA-SUBUNIT

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KW - HYDROPHOBIC MOMENTS

KW - NA(V)1.7

KW - NavAb

KW - OF-FUNCTION MUTATION

KW - SCN9A MUTATIONS

KW - STATE

KW - WATER

KW - cumulative hydropathic effects

KW - hydrophobic gating

KW - scaling

KW - topology

KW - voltage-gated sodium channels

U2 - 10.1002/prot.25951

DO - 10.1002/prot.25951

M3 - Article

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SN - 0887-3585

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SP - 1319

EP - 1328

JO - Proteins-structure Function and Bioinformatics

JF - Proteins-structure Function and Bioinformatics

IS - 10

ER -