Molecular motions within the pore of voltage-dependent sodium channels

Jean Pierre Bénitah; Ravi Ranjan; Toshio Yamagishi; Maria Janecki; Gordon F. Tomaselli; Eduardo Marban

Molecular motions within the pore of voltage-dependent sodium channels

Jean Pierre Bénitah, Ravi Ranjan, Toshio Yamagishi, Maria Janecki, Gordon F. Tomaselli, Eduardo Marban

School of Medicine

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

57 Scopus citations

Abstract

The pores of ion channel proteins are often modeled as static structures. In this view, selectivity reflects rigidly constrained backbone orientations. Such a picture is at variance with the generalization that biological proteins are flexible, capable of major internal motions on biologically relevant time scales. We tested for motions in the sodium channel pore by systematically introducing pairs of cysteine residues throughout the pore-lining segments. Two distinct pairs of residues spontaneously formed disulfide bonds bridging domains I and II. Nine other permutations, involving all four domains, were capable of disulfide bonding in the presence of a redox catalyst. The results are inconsistent with a single fixed backbone structure for the pore; instead, the segments that line the permeation pathway appear capable of sizable motions.

Original language	English (US)
Pages (from-to)	603-613
Number of pages	11
Journal	Biophysical Journal
Volume	73
Issue number	2
State	Published - Aug 1997

ASJC Scopus subject areas

Biophysics

Cite this

@article{92b08f18ab84467c99f169afcef2bff0,

title = "Molecular motions within the pore of voltage-dependent sodium channels",

abstract = "The pores of ion channel proteins are often modeled as static structures. In this view, selectivity reflects rigidly constrained backbone orientations. Such a picture is at variance with the generalization that biological proteins are flexible, capable of major internal motions on biologically relevant time scales. We tested for motions in the sodium channel pore by systematically introducing pairs of cysteine residues throughout the pore-lining segments. Two distinct pairs of residues spontaneously formed disulfide bonds bridging domains I and II. Nine other permutations, involving all four domains, were capable of disulfide bonding in the presence of a redox catalyst. The results are inconsistent with a single fixed backbone structure for the pore; instead, the segments that line the permeation pathway appear capable of sizable motions.",

author = "B{\'e}nitah, {Jean Pierre} and Ravi Ranjan and Toshio Yamagishi and Maria Janecki and Tomaselli, {Gordon F.} and Eduardo Marban",

year = "1997",

month = aug,

language = "English (US)",

volume = "73",

pages = "603--613",

journal = "Biophysical Journal",

issn = "0006-3495",

publisher = "Biophysical Society",

number = "2",

}

TY - JOUR

T1 - Molecular motions within the pore of voltage-dependent sodium channels

AU - Bénitah, Jean Pierre

AU - Ranjan, Ravi

AU - Yamagishi, Toshio

AU - Janecki, Maria

AU - Tomaselli, Gordon F.

AU - Marban, Eduardo

PY - 1997/8

Y1 - 1997/8

N2 - The pores of ion channel proteins are often modeled as static structures. In this view, selectivity reflects rigidly constrained backbone orientations. Such a picture is at variance with the generalization that biological proteins are flexible, capable of major internal motions on biologically relevant time scales. We tested for motions in the sodium channel pore by systematically introducing pairs of cysteine residues throughout the pore-lining segments. Two distinct pairs of residues spontaneously formed disulfide bonds bridging domains I and II. Nine other permutations, involving all four domains, were capable of disulfide bonding in the presence of a redox catalyst. The results are inconsistent with a single fixed backbone structure for the pore; instead, the segments that line the permeation pathway appear capable of sizable motions.

AB - The pores of ion channel proteins are often modeled as static structures. In this view, selectivity reflects rigidly constrained backbone orientations. Such a picture is at variance with the generalization that biological proteins are flexible, capable of major internal motions on biologically relevant time scales. We tested for motions in the sodium channel pore by systematically introducing pairs of cysteine residues throughout the pore-lining segments. Two distinct pairs of residues spontaneously formed disulfide bonds bridging domains I and II. Nine other permutations, involving all four domains, were capable of disulfide bonding in the presence of a redox catalyst. The results are inconsistent with a single fixed backbone structure for the pore; instead, the segments that line the permeation pathway appear capable of sizable motions.

UR - http://www.scopus.com/inward/record.url?scp=0342276134&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0342276134&partnerID=8YFLogxK

M3 - Article

C2 - 9251780

AN - SCOPUS:0342276134

SN - 0006-3495

VL - 73

SP - 603

EP - 613

JO - Biophysical Journal

JF - Biophysical Journal

IS - 2

ER -

Molecular motions within the pore of voltage-dependent sodium channels

Abstract

ASJC Scopus subject areas

Other files and links

Fingerprint

Cite this