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PDBsum entry 1a11
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Acetylcholine receptor
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PDB id
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1a11
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DOI no:
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Nat Struct Biol
6:374-379
(1999)
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PubMed id:
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Structures of the M2 channel-lining segments from nicotinic acetylcholine and NMDA receptors by NMR spectroscopy.
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S.J.Opella,
F.M.Marassi,
J.J.Gesell,
A.P.Valente,
Y.Kim,
M.Oblatt-Montal,
M.Montal.
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ABSTRACT
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The structures of functional peptides corresponding to the predicted
channel-lining M2 segments of the nicotinic acetylcholine receptor (AChR) and of
a glutamate receptor of the NMDA subtype (NMDAR) were determined using solution
NMR experiments on micelle samples, and solid-state NMR experiments on bilayer
samples. Both M2 segments form straight transmembrane alpha-helices with no
kinks. The AChR M2 peptide inserts in the lipid bilayer at an angle of 12
degrees relative to the bilayer normal, with a rotation about the helix long
axis such that the polar residues face the N-terminal side of the membrane,
which is assigned to be intracellular. A model built from these solid-state NMR
data, and assuming a symmetric pentameric arrangement of M2 helices, results in
a funnel-like architecture for the channel, with the wide opening on the
N-terminal intracellular side.
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Selected figure(s)
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Figure 1.
Figure 1. a−h, Single-channel recordings from recombinant M2
peptides in lipid bilayers. The currents were recorded at
constant voltage in symmetric 500 mM NaCl or KCl supplemented
with 1 mM CaCl[2], 5 mM HEPES pH 7.4. The currents of closed (C)
and open (O) states are indicated by the solid lines. Dotted
lines define the range set to discriminate the transitions
between states, based on signal-to-noise measurements. The AChR
M2 traces show bursts of channel activity with single-channel
conductances of 37  2
pS in 500 mM NaCl at 50 mV (a), and 38 2
pS in 500 mM KCl at 100 mV (c). For NMDAR M2, single-channel
conductances of 20 2
pS NaCl (e), and 40 3
pS in 500 mM KCl (g) were measured. Both NMDAR traces were
recorded at 100 mV. In the corresponding histograms for AChR M2
( b, d) and for NMDAR M2 (f, h), the Gaussian fits of the data
in NaCl (b, f) or KCl (d, h) indicate the respective
probabilities of the open- (O) versus closed- (C) channel states.
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Figure 4.
Figure 4. Superposition of the backbone heavy atoms for the 10
lowest energy structures of a, AChR M2 and b, NMDAR M2,
determined by solution NMR in DPC micelles. The four residues
preceding the native sequence of NMDA M2 were not constrained in
the structure calculations and are not shown. c, Superposition
of the average structure of the AChR M2 calculated from the
solution NMR distance constraints (black), and the average
structure determined from the solid-state NMR orientational
constraints (cyan). Both structures are shown in the bilayer
membrane, in the exact overall orientation determined from
solid-state NMR. d, Average structure of NMDAR M2, calculated
from solution NMR experiments. The peptide is shown in the
transmembrane orientation (gray tube) determined from the
one-dimensional solid-state NMR spectrum. The exact tilt in the
membrane is not determined because of the limited ^15N
chemical-shift data for this peptide. e,f, Side (e) and top ( f)
views of the average structure of AChR M2 in lipid bilayers,
determined from solid-state NMR orientational constraints. The
peptide is shown in its exact overall orientation within the
lipid bilayer. The N-terminus is on top in (e), and in front in
(f). The C  atoms
of Ser 8 and Gln 13 are highlighted in yellow. The helix long
axis (red arrow) is tilted 12° from the membrane normal
(black arrow). The helix rotation about its long axis (blue
arrow) is such that the polar residues Ser 8 and Gln 13 face the
N-terminal side of the lipid bilayer. In (c), (d) and ( e) the
lipid bilayer membrane is shown in gray.
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nat Struct Biol
(1999,
6,
374-379)
copyright 1999.
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Figures were
selected
by an automated process.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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D.T.Murray,
Y.Lu,
T.A.Cross,
and
J.R.Quine
(2011).
Geometry of kinked protein helices from NMR data.
|
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J Magn Reson,
210,
82-89.
|
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G.J.Lu,
W.S.Son,
and
S.J.Opella
(2011).
A general assignment method for oriented sample (OS) solid-state NMR of proteins based on the correlation of resonances through heteronuclear dipolar couplings in samples aligned parallel and perpendicular to the magnetic field.
|
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J Magn Reson,
209,
195-206.
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S.Hwang,
and
C.Hilty
(2011).
Folding determinants of disulfide bond forming protein B explored by solution nuclear magnetic resonance spectroscopy.
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Proteins,
79,
1365-1375.
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PDB codes:
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A.Holt,
and
J.A.Killian
(2010).
Orientation and dynamics of transmembrane peptides: the power of simple models.
|
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Eur Biophys J,
39,
609-621.
|
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|
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T.Cui,
C.G.Canlas,
Y.Xu,
and
P.Tang
(2010).
Anesthetic effects on the structure and dynamics of the second transmembrane domains of nAChR alpha4beta2.
|
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Biochim Biophys Acta,
1798,
161-166.
|
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|
|
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|
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T.Gopinath,
R.Verardi,
N.J.Traaseth,
and
G.Veglia
(2010).
Sensitivity enhancement of separated local field experiments: application to membrane proteins.
|
| |
J Phys Chem B,
114,
5089-5095.
|
|
|
|
|
|
|
J.P.Newstadt,
D.J.Mayo,
J.J.Inbaraj,
N.Subbaraman,
and
G.A.Lorigan
(2009).
Determining the helical tilt of membrane peptides using electron paramagnetic resonance spectroscopy.
|
| |
J Magn Reson,
198,
1-7.
|
|
|
|
|
|
|
J.W.Klingelhoefer,
T.Carpenter,
and
M.S.Sansom
(2009).
Peptide nanopores and lipid bilayers: interactions by coarse-grained molecular-dynamics simulations.
|
| |
Biophys J,
96,
3519-3528.
|
|
|
|
|
|
|
N.J.Traaseth,
L.Shi,
R.Verardi,
D.G.Mullen,
G.Barany,
and
G.Veglia
(2009).
Structure and topology of monomeric phospholamban in lipid membranes determined by a hybrid solution and solid-state NMR approach.
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Proc Natl Acad Sci U S A,
106,
10165-10170.
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PDB code:
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R.C.Page,
S.Lee,
J.D.Moore,
S.J.Opella,
and
T.A.Cross
(2009).
Backbone structure of a small helical integral membrane protein: A unique structural characterization.
|
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Protein Sci,
18,
134-146.
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PDB code:
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E.B.Gonzales,
C.L.Bell-Horner,
M.I.Dibas,
R.Q.Huang,
and
G.H.Dillon
(2008).
Stoichiometric analysis of the TM2 6' phenylalanine mutation on desensitization in alpha1beta2 and alpha1beta2gamma2 GABA A receptors.
|
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Neurosci Lett,
431,
184-189.
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R.C.Page,
S.Kim,
and
T.A.Cross
(2008).
Transmembrane helix uniformity examined by spectral mapping of torsion angles.
|
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Structure,
16,
787-797.
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C.M.Franzin,
X.M.Gong,
K.Thai,
J.Yu,
and
F.M.Marassi
(2007).
NMR of membrane proteins in micelles and bilayers: the FXYD family proteins.
|
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Methods,
41,
398-408.
|
|
|
|
|
|
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I.Köper
(2007).
Insulating tethered bilayer lipid membranes to study membrane proteins.
|
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Mol Biosyst,
3,
651-657.
|
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|
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|
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J.Hu,
H.Qin,
C.Li,
M.Sharma,
T.A.Cross,
and
F.P.Gao
(2007).
Structural biology of transmembrane domains: efficient production and characterization of transmembrane peptides by NMR.
|
| |
Protein Sci,
16,
2153-2165.
|
|
|
|
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|
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M.B.Ulmschneider,
J.P.Ulmschneider,
M.S.Sansom,
and
A.Di Nola
(2007).
A generalized born implicit-membrane representation compared to experimental insertion free energies.
|
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Biophys J,
92,
2338-2349.
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|
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S.A.McNeill,
P.L.Gor'kov,
J.Struppe,
W.W.Brey,
and
J.R.Long
(2007).
Optimizing ssNMR experiments for dilute proteins in heterogeneous mixtures at high magnetic fields.
|
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Magn Reson Chem,
45,
S209-S220.
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V.Bondarenko,
Y.Xu,
and
P.Tang
(2007).
Structure of the first transmembrane domain of the neuronal acetylcholine receptor beta2 subunit.
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Biophys J,
92,
1616-1622.
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PDB code:
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X.M.Gong,
C.M.Franzin,
K.Thai,
J.Yu,
and
F.M.Marassi
(2007).
Nuclear magnetic resonance structural studies of membrane proteins in micelles and bilayers.
|
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Methods Mol Biol,
400,
515-529.
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|
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Y.Z.Tang,
and
C.E.Carr
(2007).
Development of N-methyl-D-aspartate receptor subunits in avian auditory brainstem.
|
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J Comp Neurol,
502,
400-413.
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|
|
|
|
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D.G.Hill,
and
J.E.Baenziger
(2006).
The net orientation of nicotinic receptor transmembrane alpha-helices in the resting and desensitized states.
|
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Biophys J,
91,
705-714.
|
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|
|
|
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J.J.Inbaraj,
T.B.Cardon,
M.Laryukhin,
S.M.Grosser,
and
G.A.Lorigan
(2006).
Determining the topology of integral membrane peptides using EPR spectroscopy.
|
| |
J Am Chem Soc,
128,
9549-9554.
|
|
|
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|
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J.K.Rainey,
L.Fliegel,
and
B.D.Sykes
(2006).
Strategies for dealing with conformational sampling in structural calculations of flexible or kinked transmembrane peptides.
|
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Biochem Cell Biol,
84,
918-929.
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|
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J.M.Johnston,
G.A.Cook,
J.M.Tomich,
and
M.S.Sansom
(2006).
Conformation and environment of channel-forming peptides: a simulation study.
|
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Biophys J,
90,
1855-1864.
|
|
|
|
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L.Malavolta,
M.R.Pinto,
J.H.Cuvero,
and
C.R.Nakaie
(2006).
Interpretation of the dissolution of insoluble peptide sequences based on the acid-base properties of the solvent.
|
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Protein Sci,
15,
1476-1488.
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M.B.Ulmschneider,
M.S.Sansom,
and
A.Di Nola
(2006).
Evaluating tilt angles of membrane-associated helices: comparison of computational and NMR techniques.
|
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Biophys J,
90,
1650-1660.
|
|
|
|
|
|
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R.Xue,
S.Wang,
C.Wang,
T.Zhu,
F.Li,
and
H.Sun
(2006).
HFIP-induced structures and assemblies of the peptides from the transmembrane domain 4 of membrane protein Nramp1.
|
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Biopolymers,
84,
329-339.
|
|
|
|
|
|
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S.H.Park,
A.A.De Angelis,
A.A.Nevzorov,
C.H.Wu,
and
S.J.Opella
(2006).
Three-dimensional structure of the transmembrane domain of Vpu from HIV-1 in aligned phospholipid bicelles.
|
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Biophys J,
91,
3032-3042.
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PDB codes:
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Y.Smurnyy,
and
S.J.Opella
(2006).
Calculating protein structures directly from anisotropic spin interaction constraints.
|
| |
Magn Reson Chem,
44,
283-293.
|
|
|
|
|
|
|
Z.Chen,
and
Y.Xu
(2006).
Energetics and stability of transmembrane helix packing: a replica-exchange simulation with a knowledge-based membrane potential.
|
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Proteins,
62,
539-552.
|
|
|
|
|
|
|
A.C.Saladino,
Y.Xu,
and
P.Tang
(2005).
Homology modeling and molecular dynamics simulations of transmembrane domain structure of human neuronal nicotinic acetylcholine receptor.
|
| |
Biophys J,
88,
1009-1017.
|
|
|
|
|
|
|
A.Hung,
K.Tai,
and
M.S.Sansom
(2005).
Molecular dynamics simulation of the M2 helices within the nicotinic acetylcholine receptor transmembrane domain: structure and collective motions.
|
| |
Biophys J,
88,
3321-3333.
|
|
|
|
|
|
|
D.W.Bleile,
W.R.Scott,
and
S.K.Straus
(2005).
Can PISEMA experiments be used to extract structural parameters for mobile beta-barrels?
|
| |
J Biomol NMR,
32,
101-111.
|
|
|
|
|
|
|
H.Li,
F.Li,
M.Kwan,
Q.Y.He,
and
H.Sun
(2005).
NMR structures and orientation of the fourth transmembrane domain of the rat divalent metal transporter (DMT1) with G185D mutation in SDS micelles.
|
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Biopolymers,
77,
173-183.
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|
|
|
|
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L.Saiz,
and
M.L.Klein
(2005).
The transmembrane domain of the acetylcholine receptor: insights from simulations on synthetic peptide models.
|
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Biophys J,
88,
959-970.
|
|
|
|
|
|
|
M.B.Ulmschneider,
M.S.Sansom,
and
A.Di Nola
(2005).
Properties of integral membrane protein structures: derivation of an implicit membrane potential.
|
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Proteins,
59,
252-265.
|
|
|
|
|
|
|
N.Sinha,
C.V.Grant,
K.S.Rotondi,
L.Feduik-Rotondi,
L.M.Gierasch,
and
S.J.Opella
(2005).
Peptides and the development of double- and triple-resonance solid-state NMR of aligned samples.
|
| |
J Pept Res,
65,
605-620.
|
|
|
|
|
|
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P.T.Williamson,
G.Zandomeneghi,
F.J.Barrantes,
A.Watts,
and
B.H.Meier
(2005).
Structural and dynamic studies of the gamma-M4 trans-membrane domain of the nicotinic acetylcholine receptor.
|
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Mol Membr Biol,
22,
485-496.
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|
|
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|
|
R.Soong,
and
P.M.Macdonald
(2005).
Lateral diffusion of PEG-Lipid in magnetically aligned bicelles measured using stimulated echo pulsed field gradient 1H NMR.
|
| |
Biophys J,
88,
255-268.
|
|
|
|
|
|
|
S.Amiri,
K.Tai,
O.Beckstein,
P.C.Biggin,
and
M.S.Sansom
(2005).
The alpha7 nicotinic acetylcholine receptor: molecular modelling, electrostatics, and energetics.
|
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Mol Membr Biol,
22,
151-162.
|
|
|
|
|
|
|
S.Matsuda,
Y.Kamiya,
and
M.Yuzaki
(2005).
Roles of the N-terminal domain on the function and quaternary structure of the ionotropic glutamate receptor.
|
| |
J Biol Chem,
280,
20021-20029.
|
|
|
|
|
|
|
S.S.Antollini,
Y.Xu,
H.Jiang,
and
F.J.Barrantes
(2005).
Fluorescence and molecular dynamics studies of the acetylcholine receptor gammaM4 transmembrane peptide in reconstituted systems.
|
| |
Mol Membr Biol,
22,
471-483.
|
|
|
|
|
|
|
S.Tanizaki,
and
M.Feig
(2005).
A generalized Born formalism for heterogeneous dielectric environments: application to the implicit modeling of biological membranes.
|
| |
J Chem Phys,
122,
124706.
|
|
|
|
|
|
|
F.J.Barrantes
(2004).
Structural basis for lipid modulation of nicotinic acetylcholine receptor function.
|
| |
Brain Res Brain Res Rev,
47,
71-95.
|
|
|
|
|
|
|
G.Zandomeneghi,
and
B.H.Meier
(2004).
Adiabatic-passage cross polarization in N-15 NMR spectroscopy of peptides weakly associated to phospholipids: determination of large RDC.
|
| |
J Biomol NMR,
30,
303-309.
|
|
|
|
|
|
|
H.G.Breitinger,
H.Lanig,
C.Vohwinkel,
C.Grewer,
U.Breitinger,
T.Clark,
and
C.M.Becker
(2004).
Molecular dynamics simulation links conformation of a pore-flanking region to hyperekplexia-related dysfunction of the inhibitory glycine receptor.
|
| |
Chem Biol,
11,
1339-1350.
|
|
|
|
|
|
|
H.Li,
F.Li,
Z.M.Qian,
and
H.Sun
(2004).
Structure and topology of the transmembrane domain 4 of the divalent metal transporter in membrane-mimetic environments.
|
| |
Eur J Biochem,
271,
1938-1951.
|
|
|
|
|
|
|
I.Kass,
E.Arbely,
and
I.T.Arkin
(2004).
Modeling sample disorder in site-specific dichroism studies of uniaxial systems.
|
| |
Biophys J,
86,
2502-2507.
|
|
|
|
|
|
|
J.Yang,
M.Prorok,
F.J.Castellino,
and
D.P.Weliky
(2004).
Oligomeric beta-structure of the membrane-bound HIV-1 fusion peptide formed from soluble monomers.
|
| |
Biophys J,
87,
1951-1963.
|
|
|
|
|
|
|
K.Nomura,
G.Corzo,
T.Nakajima,
and
T.Iwashita
(2004).
Orientation and pore-forming mechanism of a scorpion pore-forming peptide bound to magnetically oriented lipid bilayers.
|
| |
Biophys J,
87,
2497-2507.
|
|
|
|
|
|
|
S.K.Straus
(2004).
Recent developments in solid-state magic-angle spinning, nuclear magnetic resonance of fully and significantly isotopically labelled peptides and proteins.
|
| |
Philos Trans R Soc Lond B Biol Sci,
359,
997.
|
|
|
|
|
|
|
S.Kim,
A.K.Chamberlain,
and
J.U.Bowie
(2004).
A model of the closed form of the nicotinic acetylcholine receptor m2 channel pore.
|
| |
Biophys J,
87,
792-799.
|
|
|
|
|
|
|
S.Ye,
J.Strzalka,
I.Y.Churbanova,
S.Zheng,
J.S.Johansson,
and
J.K.Blasie
(2004).
A model membrane protein for binding volatile anesthetics.
|
| |
Biophys J,
87,
4065-4074.
|
|
|
|
|
|
|
U.Breitinger,
H.G.Breitinger,
F.Bauer,
K.Fahmy,
D.Glockenhammer,
and
C.M.Becker
(2004).
Conserved high affinity ligand binding and membrane association in the native and refolded extracellular domain of the human glycine receptor alpha1-subunit.
|
| |
J Biol Chem,
279,
1627-1636.
|
|
|
|
|
|
|
A.C.Zeri,
M.F.Mesleh,
A.A.Nevzorov,
and
S.J.Opella
(2003).
Structure of the coat protein in fd filamentous bacteriophage particles determined by solid-state NMR spectroscopy.
|
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Proc Natl Acad Sci U S A,
100,
6458-6463.
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PDB code:
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A.Kessel,
D.Shental-Bechor,
T.Haliloglu,
and
N.Ben-Tal
(2003).
Interactions of hydrophobic peptides with lipid bilayers: Monte Carlo simulations with M2delta.
|
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Biophys J,
85,
3431-3444.
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A.Kessel,
T.Haliloglu,
and
N.Ben-Tal
(2003).
Interactions of the M2delta segment of the acetylcholine receptor with lipid bilayers: a continuum-solvent model study.
|
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Biophys J,
85,
3687-3695.
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|
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A.M.Torres,
P.S.Bansal,
M.Sunde,
C.E.Clarke,
J.A.Bursill,
D.J.Smith,
A.Bauskin,
S.N.Breit,
T.J.Campbell,
P.F.Alewood,
P.W.Kuchel,
and
J.I.Vandenberg
(2003).
Structure of the HERG K+ channel S5P extracellular linker: role of an amphipathic alpha-helix in C-type inactivation.
|
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J Biol Chem,
278,
42136-42148.
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PDB code:
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F.M.Marassi,
and
K.J.Crowell
(2003).
Hydration-optimized oriented phospholipid bilayer samples for solid-state NMR structural studies of membrane proteins.
|
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J Magn Reson,
161,
64-69.
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|
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F.M.Marassi,
and
S.J.Opella
(2003).
Simultaneous assignment and structure determination of a membrane protein from NMR orientational restraints.
|
| |
Protein Sci,
12,
403-411.
|
|
|
PDB code:
|
|
|
|
|
|
|
|
J.M.Sonner,
J.F.Antognini,
R.C.Dutton,
P.Flood,
A.T.Gray,
R.A.Harris,
G.E.Homanics,
J.Kendig,
B.Orser,
D.E.Raines,
I.J.Rampil,
J.Trudell,
B.Vissel,
and
E.I.Eger
(2003).
Inhaled anesthetics and immobility: mechanisms, mysteries, and minimum alveolar anesthetic concentration.
|
| |
Anesth Analg,
97,
718-740.
|
|
|
|
|
|
|
J.Torres,
T.J.Stevens,
and
M.Samsó
(2003).
Membrane proteins: the 'Wild West' of structural biology.
|
| |
Trends Biochem Sci,
28,
137-144.
|
|
|
|
|
|
|
R.J.Law,
D.P.Tieleman,
and
M.S.Sansom
(2003).
Pores formed by the nicotinic receptor m2delta Peptide: a molecular dynamics simulation study.
|
| |
Biophys J,
84,
14-27.
|
|
|
|
|
|
|
V.E.Yushmanov,
Y.Xu,
and
P.Tang
(2003).
NMR structure and dynamics of the second transmembrane domain of the neuronal acetylcholine receptor beta 2 subunit.
|
| |
Biochemistry,
42,
13058-13065.
|
|
|
PDB code:
|
|
|
|
|
|
|
|
C.Ma,
F.M.Marassi,
D.H.Jones,
S.K.Straus,
S.Bour,
K.Strebel,
U.Schubert,
M.Oblatt-Montal,
M.Montal,
and
S.J.Opella
(2002).
Expression, purification, and activities of full-length and truncated versions of the integral membrane protein Vpu from HIV-1.
|
| |
Protein Sci,
11,
546-557.
|
|
|
|
|
|
|
C.Tian,
K.Tobler,
R.A.Lamb,
L.H.Pinto,
and
T.A.Cross
(2002).
Expression and initial structural insights from solid-state NMR of the M2 proton channel from influenza A virus.
|
| |
Biochemistry,
41,
11294-11300.
|
|
|
|
|
|
|
D.Asthagiri,
and
D.Bashford
(2002).
Continuum and atomistic modeling of ion partitioning into a peptide nanotube.
|
| |
Biophys J,
82,
1176-1189.
|
|
|
|
|
|
|
F.M.Marassi,
and
S.J.Opella
(2002).
Using pisa pies to resolve ambiguities in angular constraints from PISEMA spectra of aligned proteins.
|
| |
J Biomol NMR,
23,
239-242.
|
|
|
|
|
|
|
P.Tang,
P.K.Mandal,
and
Y.Xu
(2002).
NMR structures of the second transmembrane domain of the human glycine receptor alpha(1) subunit: model of pore architecture and channel gating.
|
| |
Biophys J,
83,
252-262.
|
|
|
|
|
|
|
R.K.Salinas,
C.S.Shida,
T.A.Pertinhez,
A.Spisni,
C.R.Nakaie,
A.C.Paiva,
and
S.Schreier
(2002).
Trifluoroethanol and binding to model membranes stabilize a predicted turn in a peptide corresponding to the first extracellular loop of the angiotensin II AT(1A) receptor.
|
| |
Biopolymers,
65,
21-31.
|
|
|
|
|
|
|
S.J.Opella,
A.Nevzorov,
M.F.Mesleh,
and
F.M.Marassi
(2002).
Structure determination of membrane proteins by NMR spectroscopy.
|
| |
Biochem Cell Biol,
80,
597-604.
|
|
|
|
|
|
|
V.Helms
(2002).
Attraction within the membrane. Forces behind transmembrane protein folding and supramolecular complex assembly.
|
| |
EMBO Rep,
3,
1133-1138.
|
|
|
|
|
|
|
A.Arora,
and
L.K.Tamm
(2001).
Biophysical approaches to membrane protein structure determination.
|
| |
Curr Opin Struct Biol,
11,
540-547.
|
|
|
|
|
|
|
D.F.Mierke,
and
C.Giragossian
(2001).
Peptide hormone binding to G-protein-coupled receptors: structural characterization via NMR techniques.
|
| |
Med Res Rev,
21,
450-471.
|
|
|
|
|
|
|
D.Macdonald,
D.F.Mierke,
H.Li,
M.Pellegrini,
B.Sachais,
J.E.Krause,
S.E.Leeman,
and
N.D.Boyd
(2001).
Photoaffinity labeling of mutant neurokinin-1 receptors reveals additional structural features of the substance P/NK-1 receptor complex.
|
| |
Biochemistry,
40,
2530-2539.
|
|
|
|
|
|
|
F.M.Marassi
(2001).
A simple approach to membrane protein secondary structure and topology based on NMR spectroscopy.
|
| |
Biophys J,
80,
994.
|
|
|
|
|
|
|
K.K.Tai,
S.E.Blondelle,
J.M.Ostresh,
R.A.Houghten,
and
M.Montal
(2001).
An N-methyl-D-aspartate receptor channel blocker with neuroprotective activity.
|
| |
Proc Natl Acad Sci U S A,
98,
3519-3524.
|
|
|
|
|
|
|
M.Bak,
R.P.Bywater,
M.Hohwy,
J.K.Thomsen,
K.Adelhorst,
H.J.Jakobsen,
O.W.Sørensen,
and
N.C.Nielsen
(2001).
Conformation of alamethicin in oriented phospholipid bilayers determined by (15)N solid-state nuclear magnetic resonance.
|
| |
Biophys J,
81,
1684-1698.
|
|
|
|
|
|
|
R.Tycko
(2001).
Biomolecular solid state NMR: advances in structural methodology and applications to peptide and protein fibrils.
|
| |
Annu Rev Phys Chem,
52,
575-606.
|
|
|
|
|
|
|
T.Yamakura,
E.Bertaccini,
J.R.Trudell,
and
R.A.Harris
(2001).
Anesthetics and ion channels: molecular models and sites of action.
|
| |
Annu Rev Pharmacol Toxicol,
41,
23-51.
|
|
|
|
|
|
|
Y.Hori,
M.Demura,
M.Iwadate,
A.S.Ulrich,
T.Niidome,
H.Aoyagi,
and
T.Asakura
(2001).
Interaction of mastoparan with membranes studied by 1H-NMR spectroscopy in detergent micelles and by solid-state 2H-NMR and 15N-NMR spectroscopy in oriented lipid bilayers.
|
| |
Eur J Biochem,
268,
302-309.
|
|
|
PDB code:
|
|
|
|
|
|
|
|
A.Piserchio,
A.Bisello,
M.Rosenblatt,
M.Chorev,
and
D.F.Mierke
(2000).
Characterization of parathyroid hormone/receptor interactions: structure of the first extracellular loop.
|
| |
Biochemistry,
39,
8153-8160.
|
|
|
|
|
|
|
C.L.Boon,
and
A.Chakrabartty
(2000).
Nonpolar contributions to conformational specificity in assemblies of designed short helical peptides.
|
| |
Protein Sci,
9,
1011-1023.
|
|
|
|
|
|
|
H.J.de Groot
(2000).
Solid-state NMR spectroscopy applied to membrane proteins.
|
| |
Curr Opin Struct Biol,
10,
593-600.
|
|
|
|
|
|
|
M.S.Sansom,
and
H.Weinstein
(2000).
Hinges, swivels and switches: the role of prolines in signalling via transmembrane alpha-helices.
|
| |
Trends Pharmacol Sci,
21,
445-451.
|
|
|
|
|
|
|
P.J.Corringer,
N.Le Novère,
and
J.P.Changeux
(2000).
Nicotinic receptors at the amino acid level.
|
| |
Annu Rev Pharmacol Toxicol,
40,
431-458.
|
|
|
|
|
|
|
R.J.Law,
L.R.Forrest,
K.M.Ranatunga,
P.La Rocca,
D.P.Tieleman,
and
M.S.Sansom
(2000).
Structure and dynamics of the pore-lining helix of the nicotinic receptor: MD simulations in water, lipid bilayers, and transbilayer bundles.
|
| |
Proteins,
39,
47-55.
|
|
|
|
|
|
|
B.Bechinger
(1999).
The structure, dynamics and orientation of antimicrobial peptides in membranes by multidimensional solid-state NMR spectroscopy.
|
| |
Biochim Biophys Acta,
1462,
157-183.
|
|
|
|
|
|
|
F.Kotzyba-Hibert,
T.Grutter,
and
M.Goeldner
(1999).
Molecular investigations on the nicotinic acetylcholine receptor: conformational mapping and dynamic exploration using photoaffinity labeling.
|
| |
Mol Neurobiol,
20,
45-59.
|
|
|
|
|
|
|
F.M.Marassi,
C.Ma,
H.Gratkowski,
S.K.Straus,
K.Strebel,
M.Oblatt-Montal,
M.Montal,
and
S.J.Opella
(1999).
Correlation of the structural and functional domains in the membrane protein Vpu from HIV-1.
|
| |
Proc Natl Acad Sci U S A,
96,
14336-14341.
|
|
|
|
|
|
|
F.M.Marassi,
S.J.Opella,
P.Juvvadi,
and
R.B.Merrifield
(1999).
Orientation of cecropin A helices in phospholipid bilayers determined by solid-state NMR spectroscopy.
|
| |
Biophys J,
77,
3152-3155.
|
|
|
|
|
|
|
G.Siegal,
J.van Duynhoven,
and
M.Baldus
(1999).
Biomolecular NMR: recent advances in liquids, solids and screening.
|
| |
Curr Opin Chem Biol,
3,
530-536.
|
|
|
|
|
|
|
M.Pellegrini,
and
D.F.Mierke
(1999).
Structural characterization of peptide hormone/receptor interactions by NMR spectroscopy.
|
| |
Biopolymers,
51,
208-220.
|
|
|
|
|
|
|
P.C.Driscoll,
and
A.L.Vuidepot
(1999).
Peripheral membrane proteins: FYVE sticky fingers.
|
| |
Curr Biol,
9,
R857-R860.
|
|
|
|
|
|
The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
codes are
shown on the right.
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|
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