Structural model of the Ca(V)1.2 pore.

Anna Weinzinger; H. Robert Guy; Yinon Shafrir; Steffen Hering; Karl Peter Wolschann

Structural model of the Ca(V)1.2 pore.

Anna Weinzinger
, H. Robert Guy
, Yinon Shafrir
, Steffen Hering
, Karl Peter Wolschann

Department of Theoretical Chemistry

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Understanding the structure and functional mechanisms of voltage-gated calcium channels remains a major task in membrane biophysics. In the absence of three dimensional structures, homology modeling techniques are the method of choice, to address questions concerning the structure of these channels. We have developed models of the open Ca(V)1.2 pore, based on the crystal structure of the mammalian voltage-gated potassium channel K(V)1.2 and a model of the bacterial sodium channel NaChBac. Our models are developed to be consistent with experimental data and modeling criteria. The models highlight major differences between voltage-gated potassium and calcium channels in the P segments, as well as the inner pore helices. Molecular dynamics simulations support the hypothesis of a clockwise domain arrangement and experimental observations of asymmetric calcium channel behavior. In the accompanying paper these models were used to study structural effects of a channelopathy mutation.

Original language	English
Pages (from-to)	210-215
Number of pages	6
Journal	Channels (Austin)
Volume	2
Issue number	3
Publication status	Published - 2008

Austrian Fields of Science 2012

301207 Pharmaceutical chemistry
106005 Bioinformatics
104022 Theoretical chemistry

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@article{5551b60531e04ee6909a342abf2a1401,

title = "Structural model of the Ca(V)1.2 pore.",

abstract = "Understanding the structure and functional mechanisms of voltage-gated calcium channels remains a major task in membrane biophysics. In the absence of three dimensional structures, homology modeling techniques are the method of choice, to address questions concerning the structure of these channels. We have developed models of the open Ca(V)1.2 pore, based on the crystal structure of the mammalian voltage-gated potassium channel K(V)1.2 and a model of the bacterial sodium channel NaChBac. Our models are developed to be consistent with experimental data and modeling criteria. The models highlight major differences between voltage-gated potassium and calcium channels in the P segments, as well as the inner pore helices. Molecular dynamics simulations support the hypothesis of a clockwise domain arrangement and experimental observations of asymmetric calcium channel behavior. In the accompanying paper these models were used to study structural effects of a channelopathy mutation.",

author = "Anna Weinzinger and Guy, \{H. Robert\} and Yinon Shafrir and Steffen Hering and Wolschann, \{Karl Peter\}",

note = "09.02.2010: Datenanforderung UNIVIS-DATEN-DAT.RA-2 (Import Sachbearbeiter)",

year = "2008",

language = "English",

volume = "2",

pages = "210--215",

journal = "Channels (Austin)",

issn = "1933-6950",

number = "3",

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TY - JOUR

T1 - Structural model of the Ca(V)1.2 pore.

AU - Weinzinger, Anna

AU - Guy, H. Robert

AU - Shafrir, Yinon

AU - Hering, Steffen

AU - Wolschann, Karl Peter

N1 - 09.02.2010: Datenanforderung UNIVIS-DATEN-DAT.RA-2 (Import Sachbearbeiter)

PY - 2008

Y1 - 2008

N2 - Understanding the structure and functional mechanisms of voltage-gated calcium channels remains a major task in membrane biophysics. In the absence of three dimensional structures, homology modeling techniques are the method of choice, to address questions concerning the structure of these channels. We have developed models of the open Ca(V)1.2 pore, based on the crystal structure of the mammalian voltage-gated potassium channel K(V)1.2 and a model of the bacterial sodium channel NaChBac. Our models are developed to be consistent with experimental data and modeling criteria. The models highlight major differences between voltage-gated potassium and calcium channels in the P segments, as well as the inner pore helices. Molecular dynamics simulations support the hypothesis of a clockwise domain arrangement and experimental observations of asymmetric calcium channel behavior. In the accompanying paper these models were used to study structural effects of a channelopathy mutation.

AB - Understanding the structure and functional mechanisms of voltage-gated calcium channels remains a major task in membrane biophysics. In the absence of three dimensional structures, homology modeling techniques are the method of choice, to address questions concerning the structure of these channels. We have developed models of the open Ca(V)1.2 pore, based on the crystal structure of the mammalian voltage-gated potassium channel K(V)1.2 and a model of the bacterial sodium channel NaChBac. Our models are developed to be consistent with experimental data and modeling criteria. The models highlight major differences between voltage-gated potassium and calcium channels in the P segments, as well as the inner pore helices. Molecular dynamics simulations support the hypothesis of a clockwise domain arrangement and experimental observations of asymmetric calcium channel behavior. In the accompanying paper these models were used to study structural effects of a channelopathy mutation.

M3 - Article

SN - 1933-6950

VL - 2

SP - 210

EP - 215

JO - Channels (Austin)

JF - Channels (Austin)

IS - 3

ER -

Structural model of the Ca(V)1.2 pore.

Abstract

Austrian Fields of Science 2012

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