Ion channel gating: Insights via molecular simulations

Oliver Beckstein; Philip C. Biggin; Peter Bond; Joanne N. Bright; Carmen Domene; Alessandro Grottesi; John Holyoake; Mark S.P. Sansom

doi:10.1016/S0014-5793(03)01151-7

Ion channel gating: Insights via molecular simulations

Oliver Beckstein, Philip C. Biggin, Peter Bond, Joanne N. Bright, Carmen Domene, Alessandro Grottesi, John Holyoake, Mark S.P. Sansom^*

^*Corresponding author for this work

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

116 Citations (Scopus)

Abstract

Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecular dynamics simulations may be used to study the conformational dynamics of ion channels and of simple channel models. Simulations on model nanopores reveal that a narrow (<4 Å) hydrophobic region can form a functionally closed gate in the channel and can be opened by either a small (∼1 Å) increase in pore radius or an increase in polarity. Modelling and simulation studies confirm the importance of hydrophobic gating in K channels, and support a model in which hinge-bending of the pore-lining M2 (or S6 in Kv channels) helices underlies channel gating. Simulations of a simple outer membrane protein, OmpA, indicate that a gate may also be formed by interactions of charged side chains within a pore, as is also the case in ClC channels.

Original language	English
Pages (from-to)	85-90
Number of pages	6
Journal	FEBS Letters
Volume	555
Issue number	1
DOIs	https://doi.org/10.1016/S0014-5793(03)01151-7
Publication status	Published - 27 Nov 2003

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title = "Ion channel gating: Insights via molecular simulations",

abstract = "Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecular dynamics simulations may be used to study the conformational dynamics of ion channels and of simple channel models. Simulations on model nanopores reveal that a narrow (<4 {\AA}) hydrophobic region can form a functionally closed gate in the channel and can be opened by either a small (∼1 {\AA}) increase in pore radius or an increase in polarity. Modelling and simulation studies confirm the importance of hydrophobic gating in K channels, and support a model in which hinge-bending of the pore-lining M2 (or S6 in Kv channels) helices underlies channel gating. Simulations of a simple outer membrane protein, OmpA, indicate that a gate may also be formed by interactions of charged side chains within a pore, as is also the case in ClC channels.",

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T2 - Insights via molecular simulations

AU - Beckstein, Oliver

AU - Biggin, Philip C.

AU - Bond, Peter

AU - Bright, Joanne N.

AU - Domene, Carmen

AU - Grottesi, Alessandro

AU - Holyoake, John

AU - Sansom, Mark S.P.

PY - 2003/11/27

Y1 - 2003/11/27

N2 - Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecular dynamics simulations may be used to study the conformational dynamics of ion channels and of simple channel models. Simulations on model nanopores reveal that a narrow (<4 Å) hydrophobic region can form a functionally closed gate in the channel and can be opened by either a small (∼1 Å) increase in pore radius or an increase in polarity. Modelling and simulation studies confirm the importance of hydrophobic gating in K channels, and support a model in which hinge-bending of the pore-lining M2 (or S6 in Kv channels) helices underlies channel gating. Simulations of a simple outer membrane protein, OmpA, indicate that a gate may also be formed by interactions of charged side chains within a pore, as is also the case in ClC channels.

AB - Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecular dynamics simulations may be used to study the conformational dynamics of ion channels and of simple channel models. Simulations on model nanopores reveal that a narrow (<4 Å) hydrophobic region can form a functionally closed gate in the channel and can be opened by either a small (∼1 Å) increase in pore radius or an increase in polarity. Modelling and simulation studies confirm the importance of hydrophobic gating in K channels, and support a model in which hinge-bending of the pore-lining M2 (or S6 in Kv channels) helices underlies channel gating. Simulations of a simple outer membrane protein, OmpA, indicate that a gate may also be formed by interactions of charged side chains within a pore, as is also the case in ClC channels.

KW - Gating

KW - Ion channel

KW - Molecolar dynamics

KW - Nanopore

KW - Outer membrane protein

KW - Pore

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Ion channel gating: Insights via molecular simulations

Abstract

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